R5F21266SNFP [RENESAS]
RENESAS 16-BIT SINGLE-CHIP MCU R8C FAMILY / R8C/2x SERIES; 瑞萨16位单片机MCU R8C族/ R8C / 2X系列型号: | R5F21266SNFP |
厂家: | RENESAS TECHNOLOGY CORP |
描述: | RENESAS 16-BIT SINGLE-CHIP MCU R8C FAMILY / R8C/2x SERIES |
文件: | 总485页 (文件大小:4669K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
Hardware Manual
16
RENESAS 16-BIT SINGLE-CHIP MCU
R8C FAMILY / R8C/2x SERIES
All information contained in these materials, including products and product specifications,
represents information on the product at the time of publication and is subject to change by
Renesas Technology Corp. without notice. Please review the latest information published
by Renesas Technology Corp. through various means, including the Renesas Technology
Corp. website (http://www.renesas.com).
Rev.2.10
Revision Date: Sep 26, 2008
www.renesas.com
Notes regarding these materials
1. This document is provided for reference purposes only so that Renesas customers may select the appropriate
Renesas products for their use. Renesas neither makes warranties or representations with respect to the
accuracy or completeness of the information contained in this document nor grants any license to any
intellectual property rights or any other rights of Renesas or any third party with respect to the information in
this document.
2. Renesas shall have no liability for damages or infringement of any intellectual property or other rights arising
out of the use of any information in this document, including, but not limited to, product data, diagrams, charts,
programs, algorithms, and application circuit examples.
3. You should not use the products or the technology described in this document for the purpose of military
applications such as the development of weapons of mass destruction or for the purpose of any other military
use. When exporting the products or technology described herein, you should follow the applicable export
control laws and regulations, and procedures required by such laws and regulations.
4. All information included in this document such as product data, diagrams, charts, programs, algorithms, and
application circuit examples, is current as of the date this document is issued. Such information, however, is
subject to change without any prior notice. Before purchasing or using any Renesas products listed in this
document, please confirm the latest product information with a Renesas sales office. Also, please pay regular
and careful attention to additional and different information to be disclosed by Renesas such as that disclosed
through our website. (http://www.renesas.com )
5. Renesas has used reasonable care in compiling the information included in this document, but Renesas
assumes no liability whatsoever for any damages incurred as a result of errors or omissions in the information
included in this document.
6. When using or otherwise relying on the information in this document, you should evaluate the information in
light of the total system before deciding about the applicability of such information to the intended application.
Renesas makes no representations, warranties or guaranties regarding the suitability of its products for any
particular application and specifically disclaims any liability arising out of the application and use of the
information in this document or Renesas products.
7. With the exception of products specified by Renesas as suitable for automobile applications, Renesas
products are not designed, manufactured or tested for applications or otherwise in systems the failure or
malfunction of which may cause a direct threat to human life or create a risk of human injury or which require
especially high quality and reliability such as safety systems, or equipment or systems for transportation and
traffic, healthcare, combustion control, aerospace and aeronautics, nuclear power, or undersea communication
transmission. If you are considering the use of our products for such purposes, please contact a Renesas
sales office beforehand. Renesas shall have no liability for damages arising out of the uses set forth above.
8. Notwithstanding the preceding paragraph, you should not use Renesas products for the purposes listed below:
(1) artificial life support devices or systems
(2) surgical implantations
(3) healthcare intervention (e.g., excision, administration of medication, etc.)
(4) any other purposes that pose a direct threat to human life
Renesas shall have no liability for damages arising out of the uses set forth in the above and purchasers who
elect to use Renesas products in any of the foregoing applications shall indemnify and hold harmless Renesas
Technology Corp., its affiliated companies and their officers, directors, and employees against any and all
damages arising out of such applications.
9. You should use the products described herein within the range specified by Renesas, especially with respect
to the maximum rating, operating supply voltage range, movement power voltage range, heat radiation
characteristics, installation and other product characteristics. Renesas shall have no liability for malfunctions or
damages arising out of the use of Renesas products beyond such specified ranges.
10. Although Renesas endeavors to improve the quality and reliability of its products, IC products have specific
characteristics such as the occurrence of failure at a certain rate and malfunctions under certain use
conditions. Please be sure to implement safety measures to guard against the possibility of physical injury, and
injury or damage caused by fire in the event of the failure of a Renesas product, such as safety design for
hardware and software including but not limited to redundancy, fire control and malfunction prevention,
appropriate treatment for aging degradation or any other applicable measures. Among others, since the
evaluation of microcomputer software alone is very difficult, please evaluate the safety of the final products or
system manufactured by you.
11. In case Renesas products listed in this document are detached from the products to which the Renesas
products are attached or affixed, the risk of accident such as swallowing by infants and small children is very
high. You should implement safety measures so that Renesas products may not be easily detached from your
products. Renesas shall have no liability for damages arising out of such detachment.
12. This document may not be reproduced or duplicated, in any form, in whole or in part, without prior written
approval from Renesas.
13. Please contact a Renesas sales office if you have any questions regarding the information contained in this
document, Renesas semiconductor products, or if you have any other inquiries.
General Precautions in the Handling of MPU/MCU Products
The following usage notes are applicable to all MPU/MCU products from Renesas. For detailed usage notes
on the products covered by this manual, refer to the relevant sections of the manual. If the descriptions under
General Precautions in the Handling of MPU/MCU Products and in the body of the manual differ from each
other, the description in the body of the manual takes precedence.
1. Handling of Unused Pins
Handle unused pins in accord with the directions given under Handling of Unused Pins in the
manual.
The input pins of CMOS products are generally in the high-impedance state. In operation
with an unused pin in the open-circuit state, extra electromagnetic noise is induced in the
vicinity of LSI, an associated shoot-through current flows internally, and malfunctions occur
due to the false recognition of the pin state as an input signal become possible. Unused
pins should be handled as described under Handling of Unused Pins in the manual.
2. Processing at Power-on
The state of the product is undefined at the moment when power is supplied.
The states of internal circuits in the LSI are indeterminate and the states of register
settings and pins are undefined at the moment when power is supplied.
In a finished product where the reset signal is applied to the external reset pin, the states
of pins are not guaranteed from the moment when power is supplied until the reset
process is completed.
In a similar way, the states of pins in a product that is reset by an on-chip power-on reset
function are not guaranteed from the moment when power is supplied until the power
reaches the level at which resetting has been specified.
3. Prohibition of Access to Reserved Addresses
Access to reserved addresses is prohibited.
The reserved addresses are provided for the possible future expansion of functions. Do
not access these addresses; the correct operation of LSI is not guaranteed if they are
accessed.
4. Clock Signals
After applying a reset, only release the reset line after the operating clock signal has become
stable. When switching the clock signal during program execution, wait until the target clock
signal has stabilized.
When the clock signal is generated with an external resonator (or from an external
oscillator) during a reset, ensure that the reset line is only released after full stabilization of
the clock signal. Moreover, when switching to a clock signal produced with an external
resonator (or by an external oscillator) while program execution is in progress, wait until
the target clock signal is stable.
5. Differences between Products
Before changing from one product to another, i.e. to one with a different part number, confirm
that the change will not lead to problems.
The characteristics of MPU/MCU in the same group but having different part numbers may
differ because of the differences in internal memory capacity and layout pattern. When
changing to products of different part numbers, implement a system-evaluation test for
each of the products.
How to Use This Manual
1. Purpose and Target Readers
This manual is designed to provide the user with an understanding of the hardware functions and electrical
characteristics of the MCU. It is intended for users designing application systems incorporating the MCU. A basic
knowledge of electric circuits, logical circuits, and MCUs is necessary in order to use this manual.
The manual comprises an overview of the product; descriptions of the CPU, system control functions, peripheral
functions, and electrical characteristics; and usage notes.
Particular attention should be paid to the precautionary notes when using the manual. These notes occur
within the body of the text, at the end of each section, and in the Usage Notes section.
The revision history summarizes the locations of revisions and additions. It does not list all revisions. Refer
to the text of the manual for details.
The following documents apply to the R8C/26 Group, R8C/27 Group. Make sure to refer to the latest versions of these
documents. The newest versions of the documents listed may be obtained from the Renesas Technology Web site.
Document Type
Datasheet
Description
Document Title
Document No.
REJ03B0168
Hardware overview and electrical characteristics R8C/26, R8C/27
Group Datasheet
Hardware manual Hardware specifications (pin assignments,
memory maps, peripheral function
R8C/26 Group,
R8C/27 Group
Hardware Manual
This hardware
manual
specifications, electrical characteristics, timing
charts) and operation description
Note: Refer to the application notes for details on
using peripheral functions.
Software manual Description of CPU instruction set
R8C/Tiny Series
Software Manual
REJ09B0001
Application note Information on using peripheral functions and
application examples
Available from Renesas
Technology Web site.
Sample programs
Information on writing programs in assembly
language and C
Renesas
Product specifications, updates on documents,
technical update etc.
2. Notation of Numbers and Symbols
The notation conventions for register names, bit names, numbers, and symbols used in this manual are described
below.
(1) Register Names, Bit Names, and Pin Names
Registers, bits, and pins are referred to in the text by symbols. The symbol is accompanied by the word
“register,” “bit,” or “pin” to distinguish the three categories.
Examples the PM03 bit in the PM0 register
P3_5 pin, VCC pin
(2) Notation of Numbers
The indication “b” is appended to numeric values given in binary format. However, nothing is appended to the
values of single bits. The indication “h” is appended to numeric values given in hexadecimal format. Nothing
is appended to numeric values given in decimal format.
Examples Binary: 11b
Hexadecimal: EFA0h
Decimal: 1234
3. Register Notation
The symbols and terms used in register diagrams are described below.
*1
XXX Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
XXX
Address
XXX
After Reset
00h
0
RW
RW
Bit Symbol
XXX0
Bit Name
XXX bits
Function
*2
b1 b0
1 0: XXX
0 1: XXX
1 0: Do not set.
1 1: XXX
XXX1
(b2)
RW
Nothing is assigned. If necessary, set to 0.
When read, the content is undefined.
*3
Reserved bits
XXX bits
Set to 0.
RW
(b3)
XXX4
XXX5
*4
Function varies according to the operating
mode.
RW
WO
RW
RO
XXX6
XXX7
0: XXX
1: XXX
XXX bit
*1
*2
Blank: Set to 0 or 1 according to the application.
0: Set to 0.
1: Set to 1.
X: Nothing is assigned.
RW: Read and write.
RO: Read only.
WO: Write only.
−: Nothing is assigned.
*3
*4
• Reserved bit
Reserved bit. Set to specified value.
• Nothing is assigned
Nothing is assigned to the bit. As the bit may be used for future functions, if necessary, set to 0.
• Do not set to a value
Operation is not guaranteed when a value is set.
• Function varies according to the operating mode.
The function of the bit varies with the peripheral function mode. Refer to the register diagram for information
on the individual modes.
4. List of Abbreviations and Acronyms
Abbreviation
Full Form
ACIA
bps
Asynchronous Communication Interface Adapter
bits per second
CRC
DMA
DMAC
GSM
Hi-Z
Cyclic Redundancy Check
Direct Memory Access
Direct Memory Access Controller
Global System for Mobile Communications
High Impedance
IEBus
I/O
Inter Equipment Bus
Input / Output
IrDA
LSB
Infrared Data Association
Least Significant Bit
MSB
NC
Most Significant Bit
Non-Connect
PLL
Phase Locked Loop
PWM
SIM
Pulse Width Modulation
Subscriber Identity Module
Universal Asynchronous Receiver / Transmitter
Voltage Controlled Oscillator
UART
VCO
All trademarks and registered trademarks are the property of their respective owners.
Table of Contents
SFR Page Reference ........................................................................................................................... B - 1
1.
Overview ......................................................................................................................................... 1
1.1
1.2
1.3
1.4
1.5
1.6
Applications ............................................................................................................................................... 1
Performance Overview .............................................................................................................................. 2
Block Diagram .......................................................................................................................................... 4
Product Information .................................................................................................................................. 5
Pin Assignments ........................................................................................................................................ 9
Pin Functions ........................................................................................................................................... 10
2.
Central Processing Unit (CPU) ..................................................................................................... 12
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
Data Registers (R0, R1, R2, and R3) ...................................................................................................... 13
Address Registers (A0 and A1) ............................................................................................................... 13
Frame Base Register (FB) ....................................................................................................................... 13
Interrupt Table Register (INTB) .............................................................................................................. 13
Program Counter (PC) ............................................................................................................................. 13
User Stack Pointer (USP) and Interrupt Stack Pointer (ISP) .................................................................. 13
Static Base Register (SB) ........................................................................................................................ 13
Flag Register (FLG) ................................................................................................................................ 13
2.8.1
2.8.2
Carry Flag (C) ..................................................................................................................................... 13
Debug Flag (D) ................................................................................................................................... 13
Zero Flag (Z) ....................................................................................................................................... 13
Sign Flag (S) ....................................................................................................................................... 13
Register Bank Select Flag (B) ............................................................................................................ 13
Overflow Flag (O) .............................................................................................................................. 13
Interrupt Enable Flag (I) ..................................................................................................................... 14
Stack Pointer Select Flag (U) .............................................................................................................. 14
Processor Interrupt Priority Level (IPL) ............................................................................................. 14
2.8.3
2.8.4
2.8.5
2.8.6
2.8.7
2.8.8
2.8.9
2.8.10 Reserved Bit ........................................................................................................................................ 14
3.
Memory ......................................................................................................................................... 15
3.1
R8C/26 Group ......................................................................................................................................... 15
R8C/27 Group ......................................................................................................................................... 16
3.2
4.
5.
Special Function Registers (SFRs) ............................................................................................... 17
Resets ........................................................................................................................................... 24
5.1
Hardware Reset ....................................................................................................................................... 28
5.1.1
5.1.2
When Power Supply is Stable ............................................................................................................. 28
Power On ............................................................................................................................................ 28
Power-On Reset Function ....................................................................................................................... 30
Voltage Monitor 0 Reset (N, D Version) ................................................................................................ 32
Voltage Monitor 1 Reset (N, D Version) ................................................................................................ 32
Voltage Monitor 1 Reset (J, K Version) .................................................................................................. 32
Voltage Monitor 2 Reset ......................................................................................................................... 33
Watchdog Timer Reset ............................................................................................................................ 33
Software Reset ......................................................................................................................................... 33
5.2
5.3
5.4
5.5
5.6
5.7
5.8
A - 1
6.
Voltage Detection Circuit .............................................................................................................. 34
6.1
6.1.1
6.1.2
6.1.3
6.2
VCC Input Voltage .................................................................................................................................. 45
Monitoring Vdet0 ............................................................................................................................... 45
Monitoring Vdet1 ............................................................................................................................... 45
Monitoring Vdet2 ............................................................................................................................... 45
Voltage Monitor 0 Reset (For N, D Version Only) ................................................................................. 46
Voltage Monitor 1 Interrupt and Voltage Monitor 1 Reset (N, D Version) ............................................ 47
Voltage Monitor 1 Reset (J, K Version) .................................................................................................. 49
Voltage Monitor 2 Interrupt and Voltage Monitor 2 Reset ..................................................................... 50
6.3
6.4
6.5
7.
Programmable I/O Ports ............................................................................................................... 52
7.1
7.2
7.3
7.4
7.5
Functions of Programmable I/O Ports ..................................................................................................... 52
Effect on Peripheral Functions ................................................................................................................ 53
Pins Other than Programmable I/O Ports ................................................................................................ 53
Port Setting .............................................................................................................................................. 65
Unassigned Pin Handling ........................................................................................................................ 76
8.
9.
Processor Mode ............................................................................................................................ 77
8.1
Processor Modes ...................................................................................................................................... 77
Bus ................................................................................................................................................ 78
10. Clock Generation Circuit ............................................................................................................... 79
10.1
10.2
XIN Clock ............................................................................................................................................... 89
On-Chip Oscillator Clocks ...................................................................................................................... 90
10.2.1 Low-Speed On-Chip Oscillator Clock ................................................................................................ 90
10.2.2 High-Speed On-Chip Oscillator Clock ............................................................................................... 90
10.3
10.4
XCIN Clock (For N, D Version Only) .................................................................................................... 91
CPU Clock and Peripheral Function Clock ............................................................................................. 92
10.4.1 System Clock ...................................................................................................................................... 92
10.4.2 CPU Clock .......................................................................................................................................... 92
10.4.3 Peripheral Function Clock (f1, f2, f4, f8, and f32) ............................................................................. 92
10.4.4 fOCO ................................................................................................................................................... 92
10.4.5 fOCO40M ........................................................................................................................................... 92
10.4.6 fOCO-F ............................................................................................................................................... 92
10.4.7 fOCO-S ............................................................................................................................................... 92
10.4.8 fC4 and fC32 ....................................................................................................................................... 93
10.4.9 fOCO128 ............................................................................................................................................. 93
10.5
Power Control .......................................................................................................................................... 94
10.5.1 Standard Operating Mode ................................................................................................................... 94
10.5.2 Wait Mode .......................................................................................................................................... 96
10.5.3 Stop Mode ......................................................................................................................................... 100
10.6 Oscillation Stop Detection Function ..................................................................................................... 104
10.6.1 How to Use Oscillation Stop Detection Function ............................................................................. 104
10.7
Notes on Clock Generation Circuit ....................................................................................................... 108
10.7.1 Stop Mode ......................................................................................................................................... 108
10.7.2 Wait Mode ........................................................................................................................................ 108
10.7.3 Oscillation Stop Detection Function ................................................................................................. 108
10.7.4 Oscillation Circuit Constants ............................................................................................................ 108
A - 2
11.
Protection .................................................................................................................................... 109
12. Interrupts ...................................................................................................................................... 110
12.1 Interrupt Overview ................................................................................................................................ 110
12.1.1 Types of Interrupts ............................................................................................................................ 110
12.1.2 Software Interrupts ........................................................................................................................... 111
12.1.3 Special Interrupts .............................................................................................................................. 112
12.1.4 Peripheral Function Interrupt ............................................................................................................ 112
12.1.5 Interrupts and Interrupt Vectors ........................................................................................................ 113
12.1.6 Interrupt Control ............................................................................................................................... 115
12.2
INT Interrupt ......................................................................................................................................... 124
12.2.1 INTi Interrupt (i = 0, 1, 3) ................................................................................................................. 124
12.2.2 INTi Input Filter (i = 0, 1, 3) ............................................................................................................. 126
12.3
Key Input Interrupt ................................................................................................................................ 127
Address Match Interrupt ........................................................................................................................ 129
12.4
12.5
2
Timer RC Interrupt, Clock Synchronous Serial I/O with Chip Select Interrupts, and I C bus Interface
Interrupt (Interrupts with Multiple Interrupt Request Sources) ............................................................ 131
12.6
Notes on Interrupts ................................................................................................................................ 133
12.6.1 Reading Address 00000h .................................................................................................................. 133
12.6.2 SP Setting .......................................................................................................................................... 133
12.6.3 External Interrupt and Key Input Interrupt ....................................................................................... 133
12.6.4 Changing Interrupt Sources .............................................................................................................. 134
12.6.5 Changing Interrupt Control Register Contents ................................................................................. 135
13. Watchdog Timer .......................................................................................................................... 136
13.1
13.2
Count Source Protection Mode Disabled .............................................................................................. 139
Count Source Protection Mode Enabled ............................................................................................... 140
14. Timers ......................................................................................................................................... 141
14.1 Timer RA ............................................................................................................................................... 143
14.1.1 Timer Mode ...................................................................................................................................... 146
14.1.2 Pulse Output Mode ........................................................................................................................... 148
14.1.3 Event Counter Mode ......................................................................................................................... 150
14.1.4 Pulse Width Measurement Mode ...................................................................................................... 152
14.1.5 Pulse Period Measurement Mode ..................................................................................................... 155
14.1.6 Notes on Timer RA ........................................................................................................................... 158
14.2
Timer RB ............................................................................................................................................... 159
14.2.1 Timer Mode ...................................................................................................................................... 163
14.2.2 Programmable Waveform Generation Mode .................................................................................... 166
14.2.3 Programmable One-shot Generation Mode ...................................................................................... 169
14.2.4 Programmable Wait One-Shot Generation Mode ............................................................................. 173
14.2.5 Notes on Timer RB ........................................................................................................................... 177
14.3
Timer RC ............................................................................................................................................... 181
14.3.1 Overview ........................................................................................................................................... 181
14.3.2 Registers Associated with Timer RC ................................................................................................ 183
14.3.3 Common Items for Multiple Modes ................................................................................................. 193
14.3.4 Timer Mode (Input Capture Function) ............................................................................................. 199
14.3.5 Timer Mode (Output Compare Function) ......................................................................................... 204
14.3.6 PWM Mode ....................................................................................................................................... 210
A - 3
14.3.7 PWM2 Mode ..................................................................................................................................... 215
14.3.8 Timer RC Interrupt ........................................................................................................................... 221
14.3.9 Notes on Timer RC ........................................................................................................................... 222
14.4
Timer RE ............................................................................................................................................... 223
14.4.1 Real-Time Clock Mode (For N, D Version Only) ............................................................................ 224
14.4.2 Output Compare Mode ..................................................................................................................... 232
14.4.3 Notes on Timer RE ........................................................................................................................... 238
15. Serial Interface ............................................................................................................................ 241
15.1
Clock Synchronous Serial I/O Mode ..................................................................................................... 248
15.1.1 Polarity Select Function .................................................................................................................... 251
15.1.2 LSB First/MSB First Select Function ............................................................................................... 251
15.1.3 Continuous Receive Mode ................................................................................................................ 252
15.2 Clock Asynchronous Serial I/O (UART) Mode .................................................................................... 253
15.2.1 Bit Rate ............................................................................................................................................. 257
15.3
Notes on Serial Interface ....................................................................................................................... 258
16. Clock Synchronous Serial Interface ............................................................................................ 259
16.1
16.2
Mode Selection ...................................................................................................................................... 259
Clock Synchronous Serial I/O with Chip Select (SSU) ........................................................................ 260
16.2.1 Transfer Clock .................................................................................................................................. 270
16.2.2 SS Shift Register (SSTRSR) ............................................................................................................. 272
16.2.3 Interrupt Requests ............................................................................................................................. 273
16.2.4 Communication Modes and Pin Functions ....................................................................................... 274
16.2.5 Clock Synchronous Communication Mode ...................................................................................... 275
16.2.6 Operation in 4-Wire Bus Communication Mode .............................................................................. 282
16.2.7 SCS Pin Control and Arbitration ...................................................................................................... 288
16.2.8 Notes on Clock Synchronous Serial I/O with Chip Select ............................................................... 289
2
16.3
I C bus Interface .................................................................................................................................... 290
16.3.1 Transfer Clock .................................................................................................................................. 300
16.3.2 Interrupt Requests ............................................................................................................................. 301
2
16.3.3 I C bus Interface Mode ..................................................................................................................... 302
16.3.4 Clock Synchronous Serial Mode ...................................................................................................... 313
16.3.5 Noise Canceller ................................................................................................................................. 316
16.3.6 Bit Synchronization Circuit .............................................................................................................. 317
16.3.7 Examples of Register Setting ............................................................................................................ 318
2
16.3.8 Notes on I C bus Interface ................................................................................................................ 322
17. Hardware LIN .............................................................................................................................. 323
17.1
17.2
17.3
17.4
Features ................................................................................................................................................. 323
Input/Output Pins .................................................................................................................................. 324
Register Configuration .......................................................................................................................... 325
Functional Description .......................................................................................................................... 327
17.4.1 Master Mode ..................................................................................................................................... 327
17.4.2 Slave Mode ....................................................................................................................................... 330
17.4.3 Bus Collision Detection Function ..................................................................................................... 334
17.4.4 Hardware LIN End Processing ......................................................................................................... 335
17.5
17.6
Interrupt Requests .................................................................................................................................. 336
Notes on Hardware LIN ........................................................................................................................ 337
A - 4
18. A/D Converter ............................................................................................................................. 338
18.1
18.2
18.3
18.4
18.5
18.6
18.7
One-Shot Mode ..................................................................................................................................... 342
Repeat Mode .......................................................................................................................................... 345
Sample and Hold ................................................................................................................................... 348
A/D Conversion Cycles ......................................................................................................................... 348
Internal Equivalent Circuit of Analog Input .......................................................................................... 349
Output Impedance of Sensor under A/D Conversion ............................................................................ 350
Notes on A/D Converter ........................................................................................................................ 351
19. Flash Memory ............................................................................................................................. 352
19.1
19.2
19.3
Overview ............................................................................................................................................... 352
Memory Map ......................................................................................................................................... 353
Functions to Prevent Rewriting of Flash Memory ................................................................................ 355
19.3.1 ID Code Check Function .................................................................................................................. 355
19.3.2 ROM Code Protect Function ............................................................................................................ 356
19.4
CPU Rewrite Mode ............................................................................................................................... 357
19.4.1 EW0 Mode ........................................................................................................................................ 358
19.4.2 EW1 Mode ........................................................................................................................................ 358
19.4.3 Software Commands ......................................................................................................................... 367
19.4.4 Status Registers ................................................................................................................................. 372
19.4.5 Full Status Check .............................................................................................................................. 373
19.5
19.6
19.7
Standard Serial I/O Mode ...................................................................................................................... 375
19.5.1 ID Code Check Function .................................................................................................................. 375
Parallel I/O Mode .................................................................................................................................. 378
19.6.1 ROM Code Protect Function ............................................................................................................ 378
Notes on Flash Memory ........................................................................................................................ 379
19.7.1 CPU Rewrite Mode ........................................................................................................................... 379
20. Electrical Characteristics ............................................................................................................ 382
20.1
20.2
N, D Version .......................................................................................................................................... 382
J, K Version ........................................................................................................................................... 407
21. Usage Notes ............................................................................................................................... 427
21.1 Notes on Clock Generation Circuit ....................................................................................................... 427
21.1.1 Stop Mode ......................................................................................................................................... 427
21.1.2 Wait Mode ........................................................................................................................................ 427
21.1.3 Oscillation Stop Detection Function ................................................................................................. 427
21.1.4 Oscillation Circuit Constants ............................................................................................................ 427
21.2
Notes on Interrupts ................................................................................................................................ 428
21.2.1 Reading Address 00000h .................................................................................................................. 428
21.2.2 SP Setting .......................................................................................................................................... 428
21.2.3 External Interrupt and Key Input Interrupt ....................................................................................... 428
21.2.4 Changing Interrupt Sources .............................................................................................................. 429
21.2.5 Changing Interrupt Control Register Contents ................................................................................. 430
21.3
Notes on Timers .................................................................................................................................... 431
21.3.1 Notes on Timer RA ........................................................................................................................... 431
21.3.2 Notes on Timer RB ........................................................................................................................... 432
21.3.3 Notes on Timer RC ........................................................................................................................... 436
21.3.4 Notes on Timer RE ........................................................................................................................... 437
A - 5
21.4
21.5
Notes on Serial Interface ....................................................................................................................... 440
Notes on Clock Synchronous Serial Interface ....................................................................................... 441
21.5.1 Notes on Clock Synchronous Serial I/O with Chip Select ............................................................... 441
2
21.5.2 Notes on I C bus Interface ................................................................................................................ 441
21.6
Notes on Hardware LIN ........................................................................................................................ 442
Notes on A/D Converter ........................................................................................................................ 443
Notes on Flash Memory ........................................................................................................................ 444
21.7
21.8
21.8.1 CPU Rewrite Mode ........................................................................................................................... 444
21.9
Notes on Noise ...................................................................................................................................... 447
21.9.1 Inserting a Bypass Capacitor between VCC and VSS Pins as a Countermeasure against Noise and
Latch-up ............................................................................................................................................ 447
21.9.2 Countermeasures against Noise Error of Port Control Registers ..................................................... 447
22. Notes for On-Chip Debugger ...................................................................................................... 448
Appendix 1. Package Dimensions ........................................................................................................ 449
Appendix 2. Connection Examples between Serial Writer and On-Chip Debugging Emulator ............ 450
Appendix 3. Example of Oscillation Evaluation Circuit ......................................................................... 451
Index ..................................................................................................................................................... 452
A - 6
SFR Page Reference
Address
0000h
0001h
0002h
0003h
Register
Symbol
Page
Address
0040h
0041h
0042h
0043h
0044h
0045h
0046h
Register
Symbol
Page
0004h Processor Mode Register 0
PM0
77
77
81
82
0005h Processor Mode Register 1
PM1
CM0
CM1
0006h System Clock Control Register 0
0007h System Clock Control Register 1
0047h Timer RC Interrupt Control Register
TRCIC
116
115
0008h
0048h
0009h
0049h
000Ah Protect Register
PRCR
109
004Ah Timer RE Interrupt Control Register
TREIC
KUPIC
000Bh
004Bh
000Ch Oscillation Stop Detection Register
OCD
83
004Ch
000Dh Watchdog Timer Reset Register
WDTR
WDTS
WDC
138
138
137
130
004Dh Key Input Interrupt Control Register
115
115
116
000Eh Watchdog Timer Start Register
004Eh A/D Conversion Interrupt Control Register ADIC
000Fh Watchdog Timer Control Register
004Fh SSU/IIC bus Interrupt Control Register
0050h
SSUIC/IICIC
0010h Address Match Interrupt Register 0
RMAD0
0011h
0051h UART0 Transmit Interrupt Control Register S0TIC
0052h UART0 Receive Interrupt Control Register S0RIC
0053h UART1 Transmit Interrupt Control Register S1TIC
0054h UART1 Receive Interrupt Control Register S1RIC
0055h
115
115
115
115
0012h
0013h Address Match Interrupt Enable Register
AIER
130
130
0014h Address Match Interrupt Register 1
RMAD1
0015h
0016h
0056h Timer RA Interrupt Control Register
TRAIC
115
0017h
0057h
0018h
0058h Timer RB Interrupt Control Register
TRBIC
INT1IC
INT3IC
115
117
117
0019h
0059h INT1 Interrupt Control Register
001Ah
005Ah INT3 Interrupt Control Register
001Bh
005Bh
001Ch Count Source Protection Mode Register
CSPR
138
005Ch
001Dh
001Eh
001Fh
0020h
0021h
0022h
005Dh INT0 Interrupt Control Register
INT0IC
117
005Eh
005Fh
0060h
0061h
0062h
0063h
0064h
0065h
0066h
0067h
0068h
0069h
006Ah
006Bh
006Ch
006Dh
006Eh
006Fh
0070h
0071h
0072h
0073h
0074h
0075h
0076h
0077h
0078h
0079h
007Ah
007Bh
007Ch
007Dh
007Eh
007Fh
0023h High-Speed On-Chip Oscillator Control
Register 0
FRA0
FRA1
FRA2
84
84
85
0024h High-Speed On-Chip Oscillator Control
Register 1
0025h High-Speed On-Chip Oscillator Control
Register 2
0026h
0027h
0028h Clock Prescaler Reset Flag
CPSRF
FRA4
86
85
0029h High-Speed On-Chip Oscillator Control
Register 4
002Ah
002Bh High-Speed On-Chip Oscillator Control
Register 6
FRA6
FRA7
85
85
002Ch High-Speed On-Chip Oscillator Control
Register 7
0030h
0031h Voltage Detection Register 1
0032h Voltage Detection Register 2
VCA1
VCA2
39
39, 40,
86, 87
0033h
0034h
0035h
0036h Voltage Monitor 1 Circuit Control Register
VW1C
VW2C
VW0C
42, 43
44
0037h Voltage Monitor 2 Circuit Control Register
0038h Voltage Monitor 0 Circuit Control Register
41
0039h
003Ah
003Bh
003Ch
003Dh
003Eh
003Fh
NOTE:
1. The blank regions are reserved. Do not access locations in these
regions.
B - 1
Address
0080h
0081h
0082h
0083h
0084h
0085h
0086h
0087h
0088h
0089h
008Ah
008Bh
008Ch
008Dh
008Eh
008Fh
0090h
0091h
0092h
0093h
0094h
0095h
0096h
0097h
0098h
0099h
009Ah
009Bh
009Ch
009Dh
009Eh
009Fh
Register
Symbol
Page
Address
00C0h A/D Register
00C1h
Register
Symbol
AD
Page
341
00C2h
00C3h
00C4h
00C5h
00C6h
00C7h
00C8h
00C9h
00CAh
00CBh
00CCh
00CDh
00CEh
00CFh
00D0h
00D1h
00D2h
00D3h
00D4h A/D Control Register 2
ADCON2
341
00D5h
00D6h A/D Control Register 0
ADCON0
ADCON1
340
341
00D7h A/D Control Register 1
00D8h
00D9h
00DAh
00DBh
00DCh
00DDh
00DEh
00DFh
00A0h UART0 Transmit/Receive Mode Register
00A1h UART0 Bit Rate Register
00A2h UART0 Transmit Buffer Register
00A3h
U0MR
244
244
243
00E0h Port P0 Register
00E1h Port P1 Register
00E2h Port P0 Direction Register
00E3h Port P1 Direction Register
00E4h
P0
61
61
60
60
U0BRG
U0TB
P1
PD0
PD1
00A4h UART0 Transmit/Receive Control Register 0 U0C0
00A5h UART0 Transmit/Receive Control Register 1 U0C1
245
246
243
00E5h Port P3 Register
00E6h
P3
61
00A6h UART0 Receive Buffer Register
00A7h
U0RB
00E7h Port P3 Direction Register
00E8h Port P4 Register
00E9h Port P5 Register
00EAh Port P4 Direction Register
00EBh Port P5 Direction Register
00ECh
PD3
P4
60
61
61
60
60
00A8h UART1 Transmit/Receive Mode Register
00A9h UART1 Bit Rate Register
00AAh UART1 Transmit Buffer Register
00ABh
U1MR
U1BRG
U1TB
244
244
243
P5
PD4
PD5
00ACh UART1 Transmit/Receive Control Register 0 U1C0
00ADh UART1 Transmit/Receive Control Register 1 U1C1
245
246
243
00EDh
00AEh UART1 Receive Buffer Register
U1RB
00EEh
00AFh
00B0h
00B1h
00B2h
00B3h
00B4h
00B5h
00B6h
00B7h
00EFh
00F0h
00F1h
00F2h
00F3h
00F4h
00F5h Pin Select Register 1
00F6h Pin Select Register 2
00F7h Pin Select Register 3
00F8h Port Mode Register
PINSR1
PINSR2
PINSR3
PMR
62, 247
62
62
00B8h SS Control Register H / IIC bus Control Register 1 SSCRH / ICCR1 262, 293
00B9h SS Control Register L / IIC bus Control Register 2 SSCRL / ICCR2 263, 294
63, 247, 269,
299
00F9h External Input Enable Register
00FAh INT Input Filter Select Register
00FBh Key Input Enable Register
00FCh Pull-Up Control Register 0
00FDh Pull-Up Control Register 1
00FEh Port P1 Drive Capacity Control Register
00FFh
INTEN
INTF
124
125
128
64
00BAh SS Mode Register / IIC bus Mode Register
SSMR / ICMR
264, 295
265, 296
00BBh SS Enable Register / IIC bus Interrupt Enable SSER / ICIER
Register
KIEN
00BCh SS Status Register / IIC bus Status Register
SSSR / ICSR
266, 297
267, 298
PUR0
PUR1
P1DRR
00BDh SS Mode Register 2 / Slave Address Register SSMR2 / SAR
64
00BEh SS Transmit Data Register / IIC bus Transmit SSTDR / ICDRT 268, 298
Data Register
64
00BFh SS Receive Data Register / IIC bus Receive
Data Register
SSRDR / ICDRR 268, 298
NOTE:
1. The blank regions are reserved. Do not access locations in these
regions.
B - 2
Address
Register
Symbol
TRACR
Page
144
Address
Register
Symbol
TRCCR2
TRCDF
Page
189
0100h Timer RA Control Register
0130h Timer RC Control Register 2
0101h Timer RA I/O Control Register
TRAIOC
144, 146, 149,
151, 153, 156
0131h Timer RC Digital Filter Function Select
Register
190
0102h Timer RA Mode Register
0103h Timer RA Prescaler Register
0104h Timer RA Register
TRAMR
TRAPRE
TRA
145
145
145
0132h Timer RC Output Master Enable Register TRCOER
191
0133h
0134h
0135h
0136h
0137h
0138h
0139h
013Ah
013Bh
013Ch
013Dh
013Eh
013Fh
0140h
0141h
0142h
0143h
0144h
0145h
0146h
0147h
0148h
0149h
014Ah
014Bh
014Ch
014Dh
014Eh
014Fh
0150h
0151h
0152h
0153h
0154h
0155h
0156h
0157h
0158h
0159h
015Ah
015Bh
015Ch
015Dh
015Eh
015Fh
0160h
0161h
0162h
0163h
0164h
0165h
0166h
0167h
0168h
0169h
016Ah
016Bh
016Ch
016Dh
016Eh
016Fh
0105h
0106h LIN Control Register
0107h LIN Status Register
LINCR
325
326
160
160
LINST
0108h Timer RB Control Register
0109h Timer RB One-Shot Control Register
010Ah Timer RB I/O Control Register
TRBCR
TRBOCR
TRBIOC
161, 163, 167,
170, 175
010Bh Timer RB Mode Register
TRBMR
TRBPRE
TRBSC
TRBPR
161
162
162
162
010Ch Timer RB Prescaler Register
010Dh Timer RB Secondary Register
010Eh Timer RB Primary Register
010Fh
0110h
0111h
0112h
0113h
0114h
0115h
0116h
0117h
0118h Timer RE Second Data Register / Counter TRESEC
Data Register
226, 234
226, 234
0119h Timer RE Minute Data Register / Compare TREMIN
Data Register
011Ah Timer RE Hour Data Register
011Bh Timer RE Day of Week Data Register
011Ch Timer RE Control Register 1
011Dh Timer RE Control Register 2
011Eh Timer RE Count Source Select Register
011Fh
TREHR
227
TREWK
TRECR1
TRECR2
TRECSR
227
228, 235
229, 235
230, 236
0120h Timer RC Mode Register
0121h Timer RC Control Register 1
TRCMR
184
TRCCR1
185, 208, 212,
217
0122h Timer RC Interrupt Enable Register
0123h Timer RC Status Register
0124h Timer RC I/O Control Register 0
0125h Timer RC I/O Control Register 1
0126h Timer RC Counter
0127h
TRCIER
TRCSR
TRCIOR0
TRCIOR1
TRC
186
187
192, 201, 206
192, 202, 207
188
0128h Timer RC General Register A
0129h
TRCGRA
TRCGRB
TRCGRC
TRCGRD
188
188
188
188
012Ah Timer RC General Register B
012Bh
012Ch Timer RC General Register C
012Dh
012Eh Timer RC General Register D
012Fh
NOTE:
1. The blank regions are reserved. Do not access locations in these
regions.
B - 3
Address
0170h
0171h
0172h
0173h
0174h
0175h
0176h
0177h
0178h
0179h
017Ah
017Bh
017Ch
017Dh
017Eh
017Fh
0180h
0181h
0182h
0183h
0184h
0185h
0186h
0187h
0188h
0189h
018Ah
018Bh
018Ch
018Dh
018Eh
018Fh
0190h
0191h
0192h
0193h
0194h
0195h
0196h
0197h
0198h
0199h
019Ah
019Bh
019Ch
019Dh
019Eh
019Fh
01A0h
01A1h
01A2h
01A3h
01A4h
01A5h
01A6h
01A7h
01A8h
01A9h
01AAh
01ABh
01ACh
01ADh
01AEh
01AFh
Register
Symbol
Page
Address
01B0h
01B1h
01B2h
Register
Symbol
Page
01B3h Flash Memory Control Register 4
FMR4
363
362
361
01B4h
01B5h Flash Memory Control Register 1
FMR1
FMR0
01B6h
01B7h Flash Memory Control Register 0
01B8h
01B9h
01BAh
01BBh
01BCh
01BDh
01BEh
FFFFh Option Function Select Register
OFS
27, 137, 356
NOTE:
1. The blank regions are reserved. Do not access locations in these
regions.
B - 4
R8C/26 Group, R8C/27 Group
SINGLE-CHIP 16-BIT CMOS MCU
REJ09B0278-0210
Rev.2.10
Sep 26, 2008
1. Overview
These MCUs are fabricated using a high-performance silicon gate CMOS process, embedding the R8C CPU core, and
are packaged in a 32-pin molded-plastic LQFP. It implements sophisticated instructions for a high level of instruction
efficiency. With 1 Mbyte of address space, they are capable of executing instructions at high speed.
Furthermore, the R8C/27 Group has on-chip data flash (1 KB × 2 blocks).
The difference between the R8C/26 Group and R8C/27 Group is only the presence or absence of data flash.
Their peripheral functions are the same.
1.1
Applications
Electronic household appliances, office equipment, audio equipment, consumer products, automotive, etc.
Rev.2.10 Sep 26, 2008 Page 1 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
1.Overview
1.2
Performance Overview
Table 1.1 outlines the Functions and Specifications for R8C/26 Group and Table 1.2 outlines the Functions and
Specifications for R8C/27 Group.
Table 1.1
Functions and Specifications for R8C/26 Group
Item
Specification
CPU
Number of
fundamental
89 instructions
instructions
Minimum instruction
50 ns (f(XIN) = 20 MHz, VCC = 3.0 to 5.5 V) (other than K version)
62.5 ns (f(XIN) = 16 MHz, VCC = 3.0 to 5.5 V) (K version)
100 ns (f(XIN) = 10 MHz, VCC = 2.7 to 5.5 V)
200 ns (f(XIN) = 5 MHz, VCC = 2.2 to 5.5 V) (N, D version)
Single-chip
execution time
Operating mode
Address space
Memory capacity
Ports
LED drive ports
Timers
1 Mbyte
Refer to Table 1.3 Product Information for R8C/26 Group
I/O ports: 25 pins, Input port: 3 pins
I/O ports: 8 pins (N, D version)
Peripheral
Functions
Timer RA: 8 bits × 1 channel
Timer RB: 8 bits × 1 channel
(Each timer equipped with 8-bit prescaler)
Timer RC: 16 bits × 1 channel
(Input capture and output compare circuits)
Timer RE: With real-time clock and compare match function
(For J, K version, compare match function only.)
2 channels (UART0, UART1)
Serial interfaces
Clock synchronous serial I/O, UART
Clock synchronous
serial interface
1 channel
I C bus Interface
2
(1)
Clock synchronous serial I/O with chip select
Hardware LIN: 1 channel (timer RA, UART0)
10-bit A/D converter: 1 circuit, 12 channels
15 bits × 1 channel (with prescaler)
LIN module
A/D converter
Watchdog timer
Start-on-reset selectable
Interrupts
Internal: 15 sources, External: 4 sources,
Software: 4 sources, Priority levels: 7 levels
3 circuits
• XIN clock generation circuit (with on-chip feedback resistor)
• On-chip oscillator (high speed, low speed)
High-speed on-chip oscillator has a frequency adjustment function
• XCIN clock generation circuit (32 kHz) (N, D version)
• Real-time clock (timer RE) (N, D version)
XIN clock oscillation stop detection function
Clock generation
circuits
Oscillation-stopped
detector
Voltage detection
circuit
On-chip
Power-on reset circuit On-chip
Electrical
Characteristics
Supply voltage VCC = 3.0 to 5.5 V (f(XIN) = 20 MHz) (other than K version)
VCC = 3.0 to 5.5 V (f(XIN) = 16 MHz) (K version)
VCC = 2.7 to 5.5 V (f(XIN) = 10 MHz)
VCC = 2.2 to 5.5 V (f(XIN) = 5 MHz) (N, D version)
Current consumption Typ. 10 mA (VCC = 5.0 V, f(XIN) = 20 MHz)
(N, D version)
Typ. 6 mA (VCC = 3.0 V, f(XIN) = 10 MHz)
Typ. 2.0 µA (VCC = 3.0 V, wait mode (f(XCIN) = 32 kHz)
Typ. 0.7 µA (VCC = 3.0 V, stop mode)
VCC = 2.7 to 5.5 V
Flash Memory
Programming and
erasure voltage
Programming and
erasure endurance
100 times
Operating Ambient Temperature
-20 to 85°C (N version)
-40 to 85°C (D, J version)(2), -40 to 125°C (K version)(2)
Package
NOTES:
32-pin molded-plastic LQFP
1. I2C bus is a trademark of Koninklijke Philips Electronics N. V.
2. Specify the D, K version if D, K version functions are to be used.
Rev.2.10 Sep 26, 2008 Page 2 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
1.Overview
Table 1.2
Functions and Specifications for R8C/27 Group
Item
Specification
CPU
Number of fundamental 89 instructions
instructions
Minimum instruction
execution time
50 ns (f(XIN) = 20 MHz, VCC = 3.0 to 5.5 V) (other than K version)
62.5 ns (f(XIN) = 16 MHz, VCC = 3.0 to 5.5 V) (K version)
100 ns (f(XIN) = 10 MHz, VCC = 2.7 to 5.5 V)
200 ns (f(XIN) = 5 MHz, VCC = 2.2 to 5.5 V) (N, D version)
Single-chip
Operating mode
Address space
Memory capacity
Ports
LED drive ports
Timers
1 Mbyte
Refer to Table 1.4 Product Information of R8C/27 Group
I/O ports: 25 pins, Input port: 3 pins
I/O ports: 8 pins (N, D version)
Peripheral
Functions
Timer RA: 8 bits × 1 channel
Timer RB: 8 bits × 1 channel
(Each timer equipped with 8-bit prescaler)
Timer RC: 16 bits × 1 channel
(Input capture and output compare circuits)
Timer RE: With real-time clock and compare match function
(For J, K version, compare match function only.)
2 channels (UART0, UART1)
Serial interfaces
Clock synchronous serial I/O, UART
Clock synchronous
serial interface
1 channel
2
(1)
I C bus Interface
Clock synchronous serial I/O with chip select
Hardware LIN: 1 channel (timer RA, UART0)
10-bit A/D converter: 1 circuit, 12 channels
15 bits × 1 channel (with prescaler)
LIN module
A/D converter
Watchdog timer
Start-on-reset selectable
Interrupts
Internal: 15 sources, External: 4 sources,
Software: 4 sources, Priority levels: 7 levels
3 circuits
• XIN clock generation circuit (with on-chip feedback resistor)
• On-chip oscillator (high speed, low speed)
High-speed on-chip oscillator has a frequency adjustment function
• XCIN clock generation circuit (32 kHz) (N, D version)
• Real-time clock (timer RE) (N, D version)
XIN clock oscillation stop detection function
Clock generation
circuits
Oscillation-stopped
detector
Voltage detection circuit On-chip
Power-on reset circuit
Supply voltage
On-chip
Electrical
Characteristics
VCC = 3.0 to 5.5 V (f(XIN) = 20 MHz) (other than K version)
VCC = 3.0 to 5.5 V (f(XIN) = 16 MHz) (K version)
VCC = 2.7 to 5.5 V (f(XIN) = 10 MHz)
VCC = 2.2 to 5.5 V (f(XIN) = 5 MHz) (N, D version)
Typ. 10 mA (VCC = 5.0 V, f(XIN) = 20 MHz)
Typ. 6 mA (VCC = 3.0 V, f(XIN) = 10 MHz)
Typ. 2.0 µA (VCC = 3.0 V, wait mode (f(XCIN) = 32 kHz)
Typ. 0.7 µA (VCC = 3.0 V, stop mode)
VCC = 2.7 to 5.5 V
Current consumption
(N, D version)
Flash Memory
Programming and
erasure voltage
Programming and
erasure endurance
10,000 times (data flash)
1,000 times (program ROM)
Operating Ambient Temperature
-20 to 85°C (N version)
-40 to 85°C (D, J version)(2), -40 to 125°C (K version)(2)
Package
NOTES:
32-pin molded-plastic LQFP
1. I2C bus is a trademark of Koninklijke Philips Electronics N. V.
2. Specify the D, K version if D, K version functions are to be used.
Rev.2.10 Sep 26, 2008 Page 3 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
1.Overview
1.3
Block Diagram
Figure 1.1 shows a Block Diagram.
8
8
1
3
6
2
Port P0
Port P1
I/O ports
Port P3
Port P4
Port P5
Peripheral functions
System clock
generation circuit
A/D converter
(10 bits × 12 channels)
Timers
XIN-XOUT
High-speed on-chip oscillator
Low-Speed on-chip oscillator
XCIN-XCOUT(3)
Timer RA (8 bits)
Timer RB (8 bits)
Timer RC
(16 bits × 1 channel)
Timer RE (8 bits)
UART or
clock synchronous serial I/O
(8 bits × 2 channels)
I2C bus interface or clock synchronous
serial I/O with chip select
(8 bits × 1 channel)
LIN module
(1 channel)
Watchdog timer
(15 bits)
Memory
R8C CPU core
ROM(1)
R0H
R1H
R0L
R1L
SB
USP
ISP
INTB
PC
FLG
R2
R3
RAM(2)
A0
A1
FB
Multiplier
NOTES:
1. ROM size varies with MCU type.
2. RAM size varies with MCU type.
3. XCIN, XCOUT can be used only for N or D version.
Figure 1.1
Block Diagram
Rev.2.10 Sep 26, 2008 Page 4 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
1.Overview
1.4
Product Information
Table 1.3 lists the Product Information for R8C/26 Group and Table 1.4 lists the Product Information for R8C/27
Group.
Table 1.3
Product Information for R8C/26 Group
Current of Sep. 2008
ROM
Capacity
RAM
Capacity
512 bytes
1 Kbyte
Part No.
Package Type
Remarks
R5F21262SNFP
8 Kbytes
PLQP0032GB-A N version
PLQP0032GB-A
R5F21264SNFP
16 Kbytes
24 Kbytes
32 Kbytes
8 Kbytes
R5F21265SNFP
1.5 Kbytes PLQP0032GB-A
1.5 Kbytes PLQP0032GB-A
R5F21266SNFP
R5F21262SDFP
512 bytes
1 Kbyte
PLQP0032GB-A D version
PLQP0032GB-A
R5F21264SDFP
16 Kbytes
24 Kbytes
32 Kbytes
16 Kbytes
32 Kbytes
16 Kbytes
32 Kbytes
8 Kbytes
R5F21265SDFP
1.5 Kbytes PLQP0032GB-A
1.5 Kbytes PLQP0032GB-A
R5F21266SDFP
R5F21264JFP
1 Kbyte
PLQP0032GB-A J version
R5F21266JFP
1.5 Kbytes PLQP0032GB-A
R5F21264KFP
1 Kbyte
PLQP0032GB-A K version
R5F21266KFP
1.5 Kbytes PLQP0032GB-A
R5F21262SNXXXFP
R5F21264SNXXXFP
R5F21265SNXXXFP
R5F21266SNXXXFP
R5F21262SDXXXFP
R5F21264SDXXXFP
R5F21265SDXXXFP
R5F21266SDXXXFP
R5F21264JXXXFP
R5F21266JXXXFP
R5F21264KXXXFP
R5F21266KXXXFP
512 bytes
1 Kbyte
PLQP0032GB-A N version
PLQP0032GB-A
Factory
programming
16 Kbytes
24 Kbytes
32 Kbytes
8 Kbytes
(1)
product
1.5 Kbytes PLQP0032GB-A
1.5 Kbytes PLQP0032GB-A
512 bytes
1 Kbyte
PLQP0032GB-A D version
PLQP0032GB-A
16 Kbytes
24 Kbytes
32 Kbytes
16 Kbytes
32 Kbytes
16 Kbytes
32 Kbytes
1.5 Kbytes PLQP0032GB-A
1.5 Kbytes PLQP0032GB-A
1 Kbyte
PLQP0032GB-A J version
1.5 Kbytes PLQP0032GB-A
1 Kbyte
PLQP0032GB-A K version
1.5 Kbytes PLQP0032GB-A
NOTE:
1. The user ROM is programmed before shipment.
Rev.2.10 Sep 26, 2008 Page 5 of 453
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R8C/26 Group, R8C/27 Group
1.Overview
Part No. R 5 F 21 26 6 S N XXX FP
Package type:
FP: PLQP0032GB-A
ROM number
Classification
N: Operating ambient temperature -20 to 85°C (N version)
D: Operating ambient temperature -40 to 85°C (D version)
J: Operating ambient temperature -40 to 85°C (J version)
K: Operating ambient temperature -40 to 125°C (K version)
S: Low-voltage version (other no symbols)
ROM capacity
2: 8 KB
4: 16 KB
5: 24 KB
6: 32 KB
R8C/26 Group
R8C/2x Series
Memory type
F: Flash memory
Renesas MCU
Renesas semiconductor
Figure 1.2
Part Number, Memory Size, and Package of R8C/26 Group
Rev.2.10 Sep 26, 2008 Page 6 of 453
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1.Overview
Table 1.4
Product Information for R8C/27 Group
Current of Sep. 2008
ROM Capacity
Program
ROM
RAM
Capacity
Part No.
Package Type
Remarks
Data flash
R5F21272SNFP
R5F21274SNFP
R5F21275SNFP
R5F21276SNFP
R5F21272SDFP
R5F21274SDFP
R5F21275SDFP
R5F21276SDFP
R5F21274JFP
8 Kbytes 1 Kbyte × 2 512 bytes PLQP0032GB-A N version
16 Kbytes 1 Kbyte × 2 1 Kbyte PLQP0032GB-A
24 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
8 Kbytes 1 Kbyte × 2 512 bytes PLQP0032GB-A D version
16 Kbytes 1 Kbyte × 2 1 Kbyte
PLQP0032GB-A
24 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
16 Kbytes 1 Kbyte × 2 1 Kbyte
PLQP0032GB-A J version
R5F21276JFP
32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
R5F21274KFP
R5F21276KFP
R5F21272SNXXXFP
16 Kbytes 1 Kbyte × 2 1 Kbyte
PLQP0032GB-A K version
32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
8 Kbytes 1 Kbyte × 2 512 bytes PLQP0032GB-A N version Factory
programming
R5F21274SNXXXFP 16 Kbytes 1 Kbyte × 2 1 Kbyte
PLQP0032GB-A
(1)
product
R5F21275SNXXXFP 24 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
R5F21276SNXXXFP 32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
R5F21272SDXXXFP
8 Kbytes 1 Kbyte × 2 512 bytes PLQP0032GB-A D version
PLQP0032GB-A
R5F21274SDXXXFP 16 Kbytes 1 Kbyte × 2 1 Kbyte
R5F21275SDXXXFP 24 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
R5F21276SDXXXFP 32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
R5F21274JXXXFP
R5F21276JXXXFP
R5F21274KXXXFP
R5F21276KXXXFP
NOTE:
16 Kbytes 1 Kbyte × 2 1 Kbyte
PLQP0032GB-A J version
32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
16 Kbytes 1 Kbyte × 2 1 Kbyte
PLQP0032GB-A K version
32 Kbytes 1 Kbyte × 2 1.5 Kbytes PLQP0032GB-A
1. The user ROM is programmed before shipment.
Rev.2.10 Sep 26, 2008 Page 7 of 453
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1.Overview
Part No. R 5 F 21 27 6 S N XXX FP
Package type:
FP: PLQP0032GB-A
ROM number
Classification
N: Operating ambient temperature -20 to 85°C (N version)
D: Operating ambient temperature -40 to 85°C (D version)
J: Operating ambient temperature -40 to 85°C (J version)
K: Operating ambient temperature -40 to 125°C (K version)
S: Low-voltage version (other no symbols)
ROM capacity
2: 8 KB
4: 16 KB
5: 24 KB
6: 32 KB
R8C/27 Group
R8C/2x Series
Memory type
F: Flash memory
Renesas MCU
Renesas semiconductor
Figure 1.3
Part Number, Memory Size, and Package of R8C/27 Group
Rev.2.10 Sep 26, 2008 Page 8 of 453
REJ09B0278-0210
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1.Overview
1.5
Pin Assignments
Figure 1.4 shows Pin Assignments (Top View).
24 23 22 21 20 19 18 17
P1_5/RXD0/(TRAIO)/(INT1)(2)
P1_6/CLK0/(SSI)(2)
P5_3/TRCIOC
25
26
27
28
29
16
15
14
13
12
11
10
9
P0_7/AN0
P0_6/AN1
P0_5/AN2/CLK1
P0_4/AN3/TREO
P0_3/AN4
R8C/26 Group
R8C/27 Group
P5_4/TRCIOD
P3_1/TRBO
P3_6/(TXD1)/(RXD1)/(INT1)(2)
P1_7/TRAIO/INT1
P4_5/INT0/(RXD1)(2)
30
31
32
P0_2/AN5
PLQP0032GB-A
(32P6U-A)
P0_1/AN6
P0_0/AN7/(TXD1)(2)
(top view)
1
2
3
4
5
6
7
8
NOTES:
1. P4_7 is an input-only port.
2. Can be assigned to the pin in parentheses by a program.
3. XCIN, XCOUT can be used only for N or D version.
4. Confirm the pin 1 position on the package by referring to the package dimensions.
Figure 1.4
Pin Assignments (Top View)
Rev.2.10 Sep 26, 2008 Page 9 of 453
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1.Overview
1.6
Pin Functions
Table 1.5 lists Pin Functions.
Table 1.5
Type
Power supply input VCC, VSS
Pin Functions
Symbol
I/O Type
I
Description
Apply 2.2 to 5.5 V (J, K version are 2.7 to 5.5 V) to the VCC
pin. Apply 0 V to the VSS pin.
Analog power
supply input
AVCC, AVSS
I
Power supply for the A/D converter.
Connect a capacitor between AVCC and AVSS.
Reset input
MODE
I
I
I
Input “L” on this pin resets the MCU.
Connect this pin to VCC via a resistor.
RESET
MODE
XIN
XIN clock input
These pins are provided for XIN clock generation circuit I/O.
Connect a ceramic resonator or a crystal oscillator between the
XIN and XOUT pins. To use an external clock, input it to the
XIN pin and leave the XOUT pin open.
XIN clock output
XOUT
XCIN
O
XCIN clock input
(N, D version)
I
These pins are provided for XCIN clock generation circuit I/O.
Connect a crystal oscillator between the XCIN and XCOUT
pins. To use an external clock, input it to the XCIN pin and
leave the XCOUT pin open.
XCIN clock output XCOUT
(N, D version)
O
INT interrupt input INT0, INT1, INT3
I
I
INT interrupt input pins
Key input interrupt input pins
Timer RA output pin
Key input interrupt
Timer RA
KI0 to KI3
TRAO
O
I/O
O
I
TRAIO
Timer RA I/O pin
Timer RB
Timer RC
TRBO
Timer RB output pin
TRCCLK
TRCTRG
External clock input pin
External trigger input pin
I
TRCIOA, TRCIOB,
TRCIOC, TRCIOD
I/O
Sharing output-compare output / input-capture input / PWM /
PWM2 output pins
Timer RE
TREO
O
I/O
I
Timer RE output pin
Clock I/O pin
Serial interface
CLK0, CLK1
RXD0, RXD1
TXD0, TXD1
SCL
Receive data input pin
Transmit data output pin
Clock I/O pin
O
I2C bus interface
I/O
I/O
I/O
I/O
I/O
I/O
I
SDA
Data I/O pin
Clock synchronous SSI
serial I/O with chip
select
SSCK
Data I/O pin
Chip-select signal I/O pin
Clock I/O pin
SCS
SSO
Data I/O pin
Reference voltage VREF
input
Reference voltage input pin to A/D converter
A/D converter
I/O port
AN0 to AN11
I
Analog input pins to A/D converter
P0_0 to P0_7,
P1_0 to P1_7,
P3_1, P3_3 to
P3_7,
I/O
CMOS I/O ports. Each port has an I/O select direction register,
allowing each pin in the port to be directed for input or output
individually.
Any port set to input can be set to use a pull-up resistor or not
by a program.
P4_5,
P5_3, P5_4
P1_0 to P1_7 also function as LED drive ports (N, D version).
Input port
P4_2, P4_6, P4_7
I
Input-only ports
I: Input
O: Output
I/O: Input and output
Rev.2.10 Sep 26, 2008 Page 10 of 453
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1.Overview
Table 1.6
Pin Name Information by Pin Number
I/O Pin Functions for of Peripheral Modules
Clock
Pin
Number
I2C bus
Control Pin
Port
Serial
Interface
Synchronous
Serial I/O with
Chip Select
A/D
Converter
Interrupt
Timer
Interface
(TRCIOD)(1)
TRAO
1
2
P3_5
P3_7
SSCK
SCL
RXD1/
(TXD1)(1, 3)
SSO
3
RESET
XOUT/XCOUT(2)
VSS/AVSS
XIN/XCIN(2)
VCC/AVCC
MODE
4
5
6
7
8
9
P4_7
P4_6
(RXD1)(1, 3)
P4_5
P1_7
INT0
INT1
10
11
TRAIO
(TXD1)/
(RXD1)(1, 3)
(INT1)(1)
P3_6
12
13
14
15
16
P3_1
P5_4
P5_3
P1_6
TRBO
TRCIOD
TRCIOC
(SSI)(1)
CLK0
RXD0
TXD0
(TRAIO)(1)
(INT1)(1)
P1_5
P1_4
P1_3
17
18
(TRBO)
TRCIOB
AN11
AN10
KI3
KI2
19
P1_2
P4_2
P1_1
20
21
VRFF
TRCIOA/
TRCTRG
AN9
AN8
KI1
22
23
24
P1_0
P3_3
KI0
TRCCLK
SSI
INT3
(TRCIOC)(1)
P3_4
P0_7
P0_6
P0_5
P0_4
P0_3
P0_2
P0_1
P0_0
SDA
SCS
25
26
27
28
29
30
31
32
AN0
AN1
AN2
AN3
AN4
AN5
AN6
AN7
CLK1
TREO
(TXD1)(1, 3)
NOTES:
1. This can be assigned to the pin in parentheses by a program.
2. XCIN, XCOUT can be used only for N or D version.
3. For the combination of using pins TXD1 and RXD1, refer to Figure 15.7 Registers PINSR1 and
PMR.
Rev.2.10 Sep 26, 2008 Page 11 of 453
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2. Central Processing Unit (CPU)
2. Central Processing Unit (CPU)
Figure 2.1 shows the CPU Registers. The CPU contains 13 registers. R0, R1, R2, R3, A0, A1, and FB configure a
register bank. There are two sets of register bank.
b31
b15
b8b7
b0
R0H (high-order of R0) R0L (low-order of R0)
R1H (high-order of R1) R1L (low-order of R1)
R2
R2
R3
Data registers(1)
R3
A0
Address registers(1)
A1
FB
Frame base register(1)
b19
b15
b0
b0
Interrupt table register
Program counter
INTBH
INTBL
The 4 high order bits of INTB are INTBH and
the 16 low order bits of INTB are INTBL.
b19
PC
b15
b0
User stack pointer
Interrupt stack pointer
Static base register
USP
ISP
SB
b15
b0
b0
Flag register
FLG
b15
b8
b7
IPL
U I O B S Z D C
Carry flag
Debug flag
Zero flag
Sign flag
Register bank select flag
Overflow flag
Interrupt enable flag
Stack pointer select flag
Reserved bit
Processor interrupt priority level
Reserved bit
NOTE:
1. These registers comprise a register bank. There are two register banks.
Figure 2.1
CPU Registers
Rev.2.10 Sep 26, 2008 Page 12 of 453
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2. Central Processing Unit (CPU)
2.1
Data Registers (R0, R1, R2, and R3)
R0 is a 16-bit register for transfer, arithmetic, and logic operations. The same applies to R1 to R3. R0 can be split
into high-order bits (R0H) and low-order bits (R0L) to be used separately as 8-bit data registers. R1H and R1L are
analogous to R0H and R0L. R2 can be combined with R0 and used as a 32-bit data register (R2R0). R3R1 is
analogous to R2R0.
2.2
Address Registers (A0 and A1)
A0 is a 16-bit register for address register indirect addressing and address register relative addressing. It is also
used for transfer, arithmetic, and logic operations. A1 is analogous to A0. A1 can be combined with A0 to be used
as a 32-bit address register (A1A0).
2.3
Frame Base Register (FB)
FB is a 16-bit register for FB relative addressing.
2.4
Interrupt Table Register (INTB)
INTB is a 20-bit register that indicates the start address of an interrupt vector table.
2.5
Program Counter (PC)
PC is 20 bits wide and indicates the address of the next instruction to be executed.
2.6
User Stack Pointer (USP) and Interrupt Stack Pointer (ISP)
The stack pointers (SP), USP, and ISP, are each 16 bits wide. The U flag of FLG is used to switch between
USP and ISP.
2.7
Static Base Register (SB)
SB is a 16-bit register for SB relative addressing.
2.8
Flag Register (FLG)
FLG is an 11-bit register indicating the CPU state.
2.8.1
Carry Flag (C)
The C flag retains carry, borrow, or shift-out bits that have been generated by the arithmetic and logic unit.
2.8.2
Debug Flag (D)
The D flag is for debugging only. Set it to 0.
2.8.3
Zero Flag (Z)
The Z flag is set to 1 when an arithmetic operation results in 0; otherwise to 0.
2.8.4
Sign Flag (S)
The S flag is set to 1 when an arithmetic operation results in a negative value; otherwise to 0.
2.8.5
Register Bank Select Flag (B)
Register bank 0 is selected when the B flag is 0. Register bank 1 is selected when this flag is set to 1.
2.8.6
Overflow Flag (O)
The O flag is set to 1 when an operation results in an overflow; otherwise to 0.
Rev.2.10 Sep 26, 2008 Page 13 of 453
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2. Central Processing Unit (CPU)
2.8.7
Interrupt Enable Flag (I)
The I flag enables maskable interrupts.
Interrupt are disabled when the I flag is set to 0, and are enabled when the I flag is set to 1. The I flag is set to 0
when an interrupt request is acknowledged.
2.8.8
Stack Pointer Select Flag (U)
ISP is selected when the U flag is set to 0; USP is selected when the U flag is set to 1.
The U flag is set to 0 when a hardware interrupt request is acknowledged or the INT instruction of software
interrupt numbers 0 to 31 is executed.
2.8.9
Processor Interrupt Priority Level (IPL)
IPL is 3 bits wide and assigns processor interrupt priority levels from level 0 to level 7.
If a requested interrupt has higher priority than IPL, the interrupt is enabled.
2.8.10 Reserved Bit
If necessary, set to 0. When read, the content is undefined.
Rev.2.10 Sep 26, 2008 Page 14 of 453
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3.Memory
3. Memory
3.1
R8C/26 Group
Figure 3.1 is a Memory Map of R8C/26 Group. The R8C/26 group has 1 Mbyte of address space from addresses
00000h to FFFFFh.
The internal ROM is allocated lower addresses, beginning with address 0FFFFh. For example, a 16-Kbyte internal
ROM area is allocated addresses 0C000h to 0FFFFh.
The fixed interrupt vector table is allocated addresses 0FFDCh to 0FFFFh. They store the starting address of each
interrupt routine.
The internal RAM is allocated higher addresses beginning with address 00400h. For example, a 1-Kbyte internal
RAM area is allocated addresses 00400h to 007FFh. The internal RAM is used not only for storing data but also for
calling subroutines and as stacks when interrupt requests are acknowledged.
Special function registers (SFRs) are allocated addresses 00000h to 002FFh. The peripheral function control
registers are allocated here. All addresses within the SFR, which have nothing allocated are reserved for future use
and cannot be accessed by users.
00000h
SFR
(Refer to 4. Special
Function Registers
(SFRs))
002FFh
00400h
Internal RAM
0XXXh
0FFDCh
Undefined instruction
Overflow
BRK instruction
Address match
Single step
Watchdog timer/oscillation stop detection/voltage monitor
0YYYYh
(Reserved)
Internal ROM
(program ROM)
(Reserved)
Reset
0FFFFh
0FFFFh
FFFFFh
NOTE:
1. The blank regions are reserved. Do not access locations in these regions.
Internal ROM
Part Number
Internal RAM
Size
Address 0YYYYh
Size
Address 0XXXXh
005FFh
R5F21262SNFP, R5F21262SDFP,
R5F21262SNXXXFP, R5F21262SDXXXFP
R5F21264SNFP, R5F21264SDFP,
R5F21264JFP, R5F21264KFP,
8 Kbytes
0E000h
512 bytes
1 Kbyte
16 Kbytes
24 Kbytes
32 Kbytes
0C000h
0A000h
08000h
007FFh
009FFh
009FFh
R5F21264SNXXXFP, R5F21264SDXXXFP,
R5F21264JXXXFP, R5F21264KXXXFP
R5F21265SNFP, R5F21265SDFP
1.5 Kbytes
1.5 Kbytes
R5F21265SNXXXFP, R5F21265SDXXXFP
R5F21266SNFP, R5F21266SDFP,
R5F21266JFP, R5F21266KFP,
R5F21266SNXXXFP, R5F21266SDXXXFP,
R5F21266JXXXFP, R5F21266KXXXFP
Figure 3.1
Memory Map of R8C/26 Group
Rev.2.10 Sep 26, 2008 Page 15 of 453
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3.Memory
3.2
R8C/27 Group
Figure 3.2 is a Memory Map of R8C/27 Group. The R8C/27 group has 1 Mbyte of address space from addresses
00000h to FFFFFh.
The internal ROM (program ROM) is allocated lower addresses, beginning with address 0FFFFh. For example, a
16-Kbyte internal ROM area is allocated addresses 0C000h to 0FFFFh.
The fixed interrupt vector table is allocated addresses 0FFDCh to 0FFFFh. They store the starting address of each
interrupt routine.
The internal ROM (data flash) is allocated addresses 02400h to 02BFFh.
The internal RAM area is allocated higher addresses, beginning with address 00400h. For example, a 1-Kbyte
internal RAM is allocated addresses 00400h to 007FFh. The internal RAM is used not only for storing data but also
for calling subroutines and as stacks when interrupt requests are acknowledged.
Special function registers (SFRs) are allocated addresses 00000h to 002FFh. The peripheral function control
registers are allocated here. All addresses within the SFR, which have nothing allocated are reserved for future use
and cannot be accessed by users.
00000h
SFR
(Refer to 4. Special
Function Registers
(SFRs))
002FFh
00400h
Internal RAM
0XXXXh
02400h
0FFDCh
Internal ROM
Undefined instruction
(data flash)(1)
Overflow
02BFFh
0YYYYh
BRK instruction
Address match
Single step
Watchdog timer/oscillation stop detection/voltage monitor
(Reserved)
Internal ROM
(program ROM)
(Reserved)
Reset
0FFFFh
0FFFFh
FFFFFh
NOTES:
1. Data flash block A (1 Kbyte) and B (1 Kbyte) are shown.
2. The blank regions are reserved. Do not access locations in these regions.
Internal ROM
Part Number
Internal RAM
Size
Address 0YYYYh
Size
Address 0XXXXh
R5F21272SNFP, R5F21272SDFP,
R5F21272SNXXXFP, R5F21272SDXXXFP
R5F21274SNFP, R5F21274SDFP,
R5F21274JFP, R5F21274KFP,
8 Kbytes
0E000h
512 bytes
1 Kbyte
005FFh
16 Kbytes
24 Kbytes
32 Kbytes
0C000h
0A000h
08000h
007FFh
009FFh
009FFh
R5F21274SNXXXFP, R5F21274SDXXXFP,
R5F21274JXXXFP, R5F21274KXXXFP
R5F21275SNFP, R5F21275SDFP,
R5F21275SNXXXFP, R5F21275SDXXXFP
R5F21276SNFP, R5F21276SDFP,
R5F21276JFP, R5F21276KFP,
1.5 Kbytes
1.5 Kbytes
R5F21276SNXXXFP, R5F21276SDXXXFP,
R5F21276JXXXFP, R5F21276KXXXFP
Figure 3.2
Memory Map of R8C/27 Group
Rev.2.10 Sep 26, 2008 Page 16 of 453
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4. Special Function Registers (SFRs)
4. Special Function Registers (SFRs)
An SFR (special function register) is a control register for a peripheral function. Tables 4.1 to 4.7 list the special
function registers.
(1)
Table 4.1
SFR Information (1)
Address
0000h
0001h
0002h
0003h
0004h
0005h
0006h
0007h
0008h
0009h
000Ah
000Bh
000Ch
000Dh
000Eh
000Fh
0010h
0011h
0012h
0013h
0014h
0015h
0016h
0017h
0018h
0019h
001Ah
001Bh
001Ch
Register
Symbol
After reset
Processor Mode Register 0
Processor Mode Register 1
System Clock Control Register 0
System Clock Control Register 1
PM0
PM1
CM0
CM1
00h
00h
01101000b
00100000b
Protect Register
PRCR
00h
Oscillation Stop Detection Register
Watchdog Timer Reset Register
Watchdog Timer Start Register
Watchdog Timer Control Register
Address Match Interrupt Register 0
OCD
00000100b
XXh
WDTR
WDTS
WDC
XXh
00X11111b
00h
RMAD0
00h
00h
00h
00h
00h
00h
Address Match Interrupt Enable Register
Address Match Interrupt Register 1
AIER
RMAD1
Count Source Protection Mode Register
CSPR
00h
(2)
10000000b
001Dh
001Eh
001Fh
0020h
0021h
0022h
0023h
0024h
0025h
0026h
0027h
0028h
0029h
002Ah
002Bh
002Ch
002Dh
002Eh
002Fh
High-Speed On-Chip Oscillator Control Register 0
High-Speed On-Chip Oscillator Control Register 1
High-Speed On-Chip Oscillator Control Register 2
FRA0
FRA1
FRA2
00h
When shipping
00h
Clock Prescaler Reset Flag
CPSRF
FRA4
00h
When shipping
(3)
High-Speed On-Chip Oscillator Control Register 4
(3)
(3)
FRA6
FRA7
When shipping
When shipping
High-Speed On-Chip Oscillator Control Register 6
High-Speed On-Chip Oscillator Control Register 7
X: Undefined
NOTES:
1. The blank regions are reserved. Do not access locations in these regions.
2. The CSPROINI bit in the OFS register is set to 0.
3. In J, K version these regions are reserved. Do not access locations in these regions.
Rev.2.10 Sep 26, 2008 Page 17 of 453
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4. Special Function Registers (SFRs)
(1)
Table 4.2
SFR Information (2)
Address
0030h
0031h
0032h
Register
Symbol
After reset
(2)
(2)
VCA1
VCA2
00001000b
• N, D version 00h
00100000b
Voltage Detection Register 1
Voltage Detection Register 2
(3)
(4)
(8)
(7)
• J, K version 00h
01000000b
0033h
0034h
0035h
0036h
(5)
VW1C
• N, D version 00001000b
Voltage Monitor 1 Circuit Control Register
(7)
• J, K version 0000X000b
(8)
0100X001b
00h
(5)
(6)
0037h
0038h
VW2C
VW0C
Voltage Monitor 2 Circuit Control Register
Voltage Monitor 0 Circuit Control Register
(3)
0000X000b
(4)
0100X001b
0039h
003Fh
0040h
0041h
0042h
0043h
0044h
0045h
0046h
0047h
0048h
0049h
004Ah
004Bh
004Ch
004Dh
004Eh
004Fh
0050h
0051h
0052h
0053h
0054h
0055h
0056h
0057h
0058h
0059h
005Ah
005Bh
005Ch
005Dh
005Eh
005Fh
0060h
Timer RC Interrupt Control Register
Timer RE Interrupt Control Register
TRCIC
TREIC
XXXXX000b
XXXXX000b
Key Input Interrupt Control Register
A/D Conversion Interrupt Control Register
KUPIC
ADIC
SSUIC/IICIC
XXXXX000b
XXXXX000b
XXXXX000b
(9)
SSU/IIC bus Interrupt Control Register
UART0 Transmit Interrupt Control Register
UART0 Receive Interrupt Control Register
UART1 Transmit Interrupt Control Register
UART1 Receive Interrupt Control Register
S0TIC
S0RIC
S1TIC
S1RIC
XXXXX000b
XXXXX000b
XXXXX000b
XXXXX000b
Timer RA Interrupt Control Register
TRAIC
XXXXX000b
Timer RB Interrupt Control Register
INT1 Interrupt Control Register
INT3 Interrupt Control Register
TRBIC
INT1IC
INT3IC
XXXXX000b
XX00X000b
XX00X000b
INT0 Interrupt Control Register
INT0IC
XX00X000b
006Fh
0070h
007Fh
X: Undefined
NOTES:
1. The blank regions are reserved. Do not access locations in these regions.
2. (N, D version) Software reset, watchdog timer reset, voltage monitor 1 reset, or voltage monitor 2 reset do not affect this register.
(J, K version) Software reset, watchdog timer reset, or voltage monitor 2 reset do not affect this register.
3. The LVD0ON bit in the OFS register is set to 1 and hardware reset.
4. Power-on reset, voltage monitor 0 reset or the LVD0ON bit in the OFS register is set to 0, and hardware reset.
5. (N, D version) Software reset, watchdog timer reset, voltage monitor 1 reset, or voltage monitor 2 reset do not affect b2 and b3.
(J, K version) Software reset, watchdog timer reset, or voltage monitor 2 reset do not affect b2 and b3.
6. (N, D version) Software reset, watchdog timer reset, voltage monitor 1 reset, or voltage monitor 2 reset do not affect this register.
(J, K version) These regions are reserved. Do not access locations in these regions.
7. The LVD1ON bit in the OFS register is set to 1 and hardware reset.
8. Power-on reset, voltage monitor 1 reset, or the LVD1ON bit in the OFS register is set to 0 and hardware reset.
9. Selected by the IICSEL bit in the PMR register.
Rev.2.10 Sep 26, 2008 Page 18 of 453
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R8C/26 Group, R8C/27 Group
4. Special Function Registers (SFRs)
(1)
Table 4.3
SFR Information (3)
Address
0080h
0081h
0082h
0083h
0084h
0085h
0086h
0087h
0088h
0089h
008Ah
008Bh
008Ch
008Dh
008Eh
008Fh
0090h
0091h
0092h
0093h
0094h
0095h
0096h
0097h
0098h
0099h
009Ah
009Bh
009Ch
009Dh
009Eh
009Fh
00A0h
00A1h
00A2h
00A3h
00A4h
00A5h
00A6h
00A7h
00A8h
00A9h
00AAh
00ABh
00ACh
00ADh
00AEh
00AFh
00B0h
00B1h
00B2h
00B3h
00B4h
00B5h
00B6h
00B7h
00B8h
00B9h
00BAh
00BBh
00BCh
00BDh
00BEh
00BFh
Register
Symbol
After reset
UART0 Transmit/Receive Mode Register
UART0 Bit Rate Register
U0MR
00h
XXh
XXh
XXh
U0BRG
U0TB
UART0 Transmit Buffer Register
UART0 Transmit/Receive Control Register 0
UART0 Transmit/Receive Control Register 1
UART0 Receive Buffer Register
U0C0
U0C1
U0RB
00001000b
00000010b
XXh
XXh
00h
XXh
XXh
UART1 Transmit/Receive Mode Register
UART1 Bit Rate Register
U1MR
U1BRG
U1TB
UART1 Transmit Buffer Register
XXh
UART1 Transmit/Receive Control Register 0
UART1 Transmit/Receive Control Register 1
UART1 Receive Buffer Register
U1C0
U1C1
U1RB
00001000b
00000010b
XXh
XXh
(2)
SSCRH / ICCR1
SSCRL / ICCR2
SSMR / ICMR
SSER / ICIER
SSSR / ICSR
00h
SS Control Register H / IIC bus Control Register 1
(2)
01111101b
00011000b
00h
SS Control Register L / IIC bus Control Register 2
(2)
SS Mode Register / IIC bus Mode Register
(2)
SS Enable Register / IIC bus Interrupt Enable Register
(2)
00h / 0000X000b
00h
SS Status Register / IIC bus Status Register
(2)
SSMR2 / SAR
SSTDR / ICDRT
SSRDR / ICDRR
SS Mode Register 2 / Slave Address Register
(2)
FFh
SS Transmit Data Register / IIC bus Transmit Data Register
(2)
FFh
SS Receive Data Register / IIC bus Receive Data Register
X: Undefined
NOTES:
1. The blank regions are reserved. Do not access locations in these regions.
2. Selected by the IICSEL bit in the PMR register.
Rev.2.10 Sep 26, 2008 Page 19 of 453
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4. Special Function Registers (SFRs)
(1)
Table 4.4
SFR Information (4)
Address
00C0h
00C1h
00C2h
00C3h
00C4h
00C5h
00C6h
00C7h
00C8h
00C9h
00CAh
00CBh
00CCh
00CDh
00CEh
00CFh
00D0h
00D1h
00D2h
00D3h
00D4h
00D5h
00D6h
00D7h
00D8h
00D9h
00DAh
00DBh
00DCh
00DDh
00DEh
00DFh
00E0h
00E1h
00E2h
00E3h
00E4h
00E5h
00E6h
00E7h
00E8h
00E9h
00EAh
00EBh
00ECh
00EDh
00EEh
00EFh
00F0h
00F1h
00F2h
00F3h
00F4h
00F5h
00F6h
00F7h
00F8h
00F9h
00FAh
00FBh
00FCh
00FDh
00FEh
00FFh
Register
Symbol
After reset
A/D Register
AD
XXh
XXh
A/D Control Register 2
ADCON2
00h
A/D Control Register 0
A/D Control Register 1
ADCON0
ADCON1
00h
00h
Port P0 Register
Port P1 Register
Port P0 Direction Register
Port P1 Direction Register
P0
P1
PD0
PD1
00h
00h
00h
00h
Port P3 Register
P3
00h
Port P3 Direction Register
Port P4 Register
Port P5 Register
Port P4 Direction Register
Port P5 Direction Register
PD3
P4
P5
PD4
PD5
00h
00h
00h
00h
00h
Pin Select Register 1
Pin Select Register 2
Pin Select Register 3
Port Mode Register
PINSR1
PINSR2
PINSR3
PMR
INTEN
INTF
00h
00h
00h
00h
00h
00h
00h
00h
00h
00h
External Input Enable Register
INT Input Filter Select Register
Key Input Enable Register
Pull-Up Control Register 0
Pull-Up Control Register 1
Port P1 Drive Capacity Control Register
KIEN
PUR0
PUR1
P1DRR
(2)
X: Undefined
NOTES:
1. The blank regions are reserved. Do not access locations in these regions.
2. In J, K version these regions are reserved. Do not access locations in these regions.
Rev.2.10 Sep 26, 2008 Page 20 of 453
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4. Special Function Registers (SFRs)
(1)
Table 4.5
SFR Information (5)
Address
0100h
0101h
0102h
0103h
0104h
0105h
0106h
0107h
0108h
0109h
010Ah
010Bh
010Ch
010Dh
010Eh
010Fh
0110h
0111h
0112h
0113h
0114h
0115h
0116h
0117h
0118h
0119h
011Ah
011Bh
011Ch
011Dh
011Eh
011Fh
0120h
0121h
0122h
0123h
0124h
0125h
0126h
0127h
0128h
0129h
012Ah
012Bh
012Ch
012Dh
012Eh
012Fh
0130h
0131h
0132h
0133h
0134h
0135h
0136h
0137h
0138h
0139h
013Ah
013Bh
013Ch
013Dh
013Eh
013Fh
Register
Symbol
TRACR
TRAIOC
TRAMR
TRAPRE
TRA
After reset
Timer RA Control Register
Timer RA I/O Control Register
Timer RA Mode Register
Timer RA Prescaler Register
Timer RA Register
00h
00h
00h
FFh
FFh
LIN Control Register
LIN Status Register
Timer RB Control Register
Timer RB One-Shot Control Register
Timer RB I/O Control Register
Timer RB Mode Register
Timer RB Prescaler Register
Timer RB Secondary Register
Timer RB Primary Register
LINCR
LINST
00h
00h
00h
00h
00h
00h
FFh
FFh
FFh
TRBCR
TRBOCR
TRBIOC
TRBMR
TRBPRE
TRBSC
TRBPR
Timer RE Second Data Register / Counter Data Register
Timer RE Minute Data Register / Compare Data Register
TRESEC
TREMIN
TREHR
00h
00h
00h
00h
00h
00h
(2)
Timer RE Hour Data Register
(2)
TREWK
TRECR1
TRECR2
TRECSR
Timer RE Day of Week Data Register
Timer RE Control Register 1
Timer RE Control Register 2
Timer RE Count Source Select Register
00001000b
Timer RC Mode Register
TRCMR
TRCCR1
TRCIER
TRCSR
TRCIOR0
TRCIOR1
TRC
01001000b
00h
Timer RC Control Register 1
Timer RC Interrupt Enable Register
Timer RC Status Register
Timer RC I/O Control Register 0
Timer RC I/O Control Register 1
Timer RC Counter
01110000b
01110000b
10001000b
10001000b
00h
00h
FFh
FFh
FFh
FFh
FFh
FFh
FFh
Timer RC General Register A
Timer RC General Register B
Timer RC General Register C
Timer RC General Register D
TRCGRA
TRCGRB
TRCGRC
TRCGRD
FFh
Timer RC Control Register 2
TRCCR2
TRCDF
TRCOER
00011111b
00h
01111111b
Timer RC Digital Filter Function Select Register
Timer RC Output Master Enable Register
NOTES:
1. The blank regions are reserved. Do not access locations in these regions.
2. In J, K version these regions are reserved. Do not access locations in these regions.
Rev.2.10 Sep 26, 2008 Page 21 of 453
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R8C/26 Group, R8C/27 Group
4. Special Function Registers (SFRs)
(1)
Table 4.6
SFR Information (6)
Address
0140h
0141h
0142h
0143h
0144h
0145h
0146h
0147h
0148h
0149h
014Ah
014Bh
014Ch
014Dh
014Eh
014Fh
0150h
0151h
0152h
0153h
0154h
0155h
0156h
0157h
0158h
0159h
015Ah
015Bh
015Ch
015Dh
015Eh
015Fh
0160h
0161h
0162h
0163h
0164h
0165h
0166h
0167h
0168h
0169h
016Ah
016Bh
016Ch
016Dh
016Eh
016Fh
0170h
0171h
0172h
0173h
0174h
0175h
0176h
0177h
0178h
0179h
017Ah
017Bh
017Ch
017Dh
017Eh
017Fh
Register
Symbol
After reset
NOTE:
1. The blank regions are reserved. Do not access locations in these regions.
Rev.2.10 Sep 26, 2008 Page 22 of 453
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4. Special Function Registers (SFRs)
(1)
Table 4.7
SFR Information (7)
Address
0180h
0181h
0182h
0183h
0184h
0185h
0186h
0187h
0188h
0189h
018Ah
018Bh
018Ch
018Dh
018Eh
018Fh
0190h
0191h
0192h
0193h
0194h
0195h
0196h
0197h
0198h
0199h
019Ah
019Bh
019Ch
019Dh
019Eh
019Fh
01A0h
01A1h
01A2h
01A3h
01A4h
01A5h
01A6h
01A7h
01A8h
01A9h
01AAh
01ABh
01ACh
01ADh
01AEh
01AFh
01B0h
01B1h
01B2h
01B3h
01B4h
01B5h
01B6h
01B7h
01B8h
01B9h
01BAh
01BBh
01BCh
01BDh
01BEh
01BFh
Register
Symbol
After reset
Flash Memory Control Register 4
Flash Memory Control Register 1
Flash Memory Control Register 0
FMR4
FMR1
FMR0
01000000b
1000000Xb
00000001b
FFFFh
Option Function Select Register
OFS
(Note 2)
X: Undefined
NOTES:
1. The blank regions are reserved. Do not access locations in these regions.
2. The OFS register cannot be changed by a program. Use a flash programmer to write to it.
Rev.2.10 Sep 26, 2008 Page 23 of 453
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R8C/26 Group, R8C/27 Group
5.Resets
5. Resets
The following resets are implemented: hardware reset, power-on reset, voltage monitor 0 reset (for N, D version only),
voltage monitor 1 reset, voltage monitor 2 reset, watchdog timer reset, and software reset.
Table 5.1 lists the Reset Names and Sources. Figure 5.1 shows the Block Diagram of Reset Circuit (N, D Version), and
Figure 5.2 shows the Block Diagram of Reset Circuit (J, K Version).
Table 5.1
Reset Names and Sources
Reset Name
Source
Hardware reset
Input voltage of RESET pin is held “L”
VCC rises
Power-on reset
(1)
VCC falls (monitor voltage: Vdet0)
VCC falls (monitor voltage: Vdet1)
VCC falls (monitor voltage: Vdet2)
Underflow of watchdog timer
Write 1 to PM03 bit in PM0 register
Voltage monitor 0 reset
Voltage monitor 1 reset
Voltage monitor 2 reset
Watchdog timer reset
Software reset
NOTE:
1. For N, D version only.
Hardware reset
RESET
SFRs
Bits VCA25,
VW0C0, and
VW0C6
Power-on reset
Power-on reset
VCC
circuit
Voltage monitor 0 reset
Voltage monitor 1 reset
SFRs
Voltage
detection
circuit
Bits VCA13, VCA26, VCA27,
VW1C2, VW1C3,
VW2C2, VW2C3,
VW0C1, VW0F0,
VW0F1, and VW0C7
Voltage monitor 2
reset
Watchdog timer
reset
Watchdog
timer
Pin, CPU, and
SFR bits other than
those listed above
CPU
Software reset
VCA13: Bit in VCA1 register
VCA25, VCA26, VCA27: Bits in VCA2 register
VW0C0, VW0C1, VW0C6, VW0F0, VW0F1, VW0C7: Bits in VW0C register
VW1C2, VW1C3: Bits in VW1C register
VW2C2, VW2C3: Bits in VW2C register
Figure 5.1
Block Diagram of Reset Circuit (N, D Version)
Rev.2.10 Sep 26, 2008 Page 24 of 453
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5.Resets
Hardware reset
RESET
SFRs
Bits VCA26,
VW1C0, and
VW1C6
Power-on reset
Power-on reset
VCC
circuit
Voltage monitor 1 reset
Voltage monitor 2 reset
SFR
Voltage
detection
circuit
Bits VCA13, VCA27,
VW2C2, VW2C3,
VW1C1, VW1F0,
VW1F1, and VW1C7
Watchdog timer
reset
Watchdog
timer
Pin, CPU, and
SFR bits other than
those listed above
CPU
Software reset
VCA13: Bit in VCA1 register
VCA26, VCA27: Bits in VCA2 register
VW1C0, VW1C1, VW1F0, VW1F1, VW1C6, VW1C7: Bits in VW1C register
VW2C2, VW2C3: Bits in VW2C register
Figure 5.2
Block Diagram of Reset Circuit (J, K Version)
Rev.2.10 Sep 26, 2008 Page 25 of 453
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5.Resets
Table 5.2 shows the Pin Functions while RESET Pin Level is “L”, Figure 5.3 shows the CPU Register Status after
Reset, Figure 5.4 shows the Reset Sequence, and Figure 5.5 shows the OFS Register.
Table 5.2
Pin Functions while RESET Pin Level is “L”
Pin Name Pin Functions
P0, P1
Input port
Input port
Input port
Input port
P3_1, P3_3 to P3_7
P4_2, P4_5 to P4_7
P5_3, P5_4
b15
b0
0000h
0000h
0000h
Data register(R0)
Data register(R1)
Data register(R2)
Data register(R3)
0000h
0000h
0000h
0000h
Address register(A0)
Address register(A1)
Frame base register(FB)
b19
b0
00000h
Content of addresses 0FFFEh to 0FFFCh
Interrupt table register(INTB)
Program counter(PC)
b15
b0
User stack pointer(USP)
Interrupt stack pointer(ISP)
Static base register(SB)
0000h
0000h
0000h
b15
b0
b0
Flag register(FLG)
0000h
b15
b8
b7
IPL
U I O B S Z D C
Figure 5.3
CPU Register Status after Reset
fOCO-S
RESET pin
10 cycles or more are needed(1)
fOCO-S clock × 32 cycles(2)
Internal reset
signal
Start time of flash memory
(CPU clock × 14 cycles)
CPU clock × 28 cycles
CPU clock
0FFFCh
0FFFEh
Address
(internal address
signal)
Content of reset vector
0FFFDh
NOTES:
1. Hardware reset.
2. When the “L” input width to the RESET pin is set to fOCO-S clock × 32 cycles or more, setting the RESET pin to “H” also sets the internal
reset signal to “H” at the same.
Figure 5.4
Reset Sequence
Rev.2.10 Sep 26, 2008 Page 26 of 453
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5.Resets
Option Function Select Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
1
1
Symbol
OFS
Address
0FFFFh
When Shipping
FFh(3)
Bit Symbol
Bit Name
Function
RW
RW
Watchdog timer start
select bit
0 : Starts w atchdog timer automatically after reset
1 : Watchdog timer is inactive after reset
WDTON
—
(b1)
Reserved bit
Set to 1.
RW
RW
RW
RW
ROM code protect
disabled bit
0 : ROM code protect disabled
1 : ROMCP1 enabled
ROMCR
ROM code protect bit
0 : ROM code protect enabled
1 : ROM code protect disabled
ROMCP1
—
(b4)
Reserved bit
Set to 1.
Voltage detection 0
circuit start bit(2, 4)
0 : Voltage monitor 0 reset enabled after hardw are
reset
LVD0ON
RW
1 : Voltage monitor 0 reset disabled after hardw are
reset
Voltage detection 1
circuit start bit(5, 6)
0 : Voltage monitor 1 reset enabled after hardw are
reset
LVD1ON
CSPROINI
RW
RW
1 : Voltage monitor 1 reset disabled after hardw are
reset
Count source protect
mode after reset select 1 : Count source protect mode disabled after reset
bit
0 : Count source protect mode enabled after reset
NOTES:
1. The OFS register is on the flash memory. Write to the OFS register w ith a program. After w riting is completed, do not
w rite additions to the OFS register.
2. The LVD0ON bit setting is valid only by a hardw are reset. To use the pow er-on reset, set the LVD0ON bit to 0
(voltage monitor 0 reset enabled after hardw are reset).
3. If the block including the OFS register is erased, FFh is set to the OFS register.
4. For N, D version only. For J, K version, set the LVD0ON bit to 1 (voltage monitor 0 reset disabled after hardw are
reset).
5. The LVD1ON bit setting is valid only by a hardw are reset. When the pow er-on reset function is used, set the
LVD1ON bit to 0 (voltage monitor 1 reset enabled after hardw are reset).
6. For J, K version only. For N, D version, set the LVD1ON bit to 1 (voltage monitor 1 reset disabled after hardw are
reset).
Figure 5.5
OFS Register
Rev.2.10 Sep 26, 2008 Page 27 of 453
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5.Resets
5.1
Hardware Reset
A reset is applied using the RESET pin. When an “L” signal is applied to the RESET pin while the supply voltage
meets the recommended operating conditions, pins, CPU, and SFRs are all reset (refer to Table 5.2 Pin Functions
while RESET Pin Level is “L”). When the input level applied to the RESET pin changes from “L” to “H”, a
program is executed beginning with the address indicated by the reset vector. After reset, the low-speed on-chip
oscillator clock divided by 8 is automatically selected as the CPU clock.
Refer to 4. Special Function Registers (SFRs) for the state of the SFRs after reset.
The internal RAM is not reset. If the RESET pin is pulled “L” while writing to the internal RAM is in progress, the
contents of internal RAM will be undefined.
Figure 5.6 shows an Example of Hardware Reset Circuit and Operation and Figure 5.7 shows an Example of
Hardware Reset Circuit (Usage Example of External Supply Voltage Detection Circuit) and Operation.
5.1.1
When Power Supply is Stable
(1) Apply “L” to the RESET pin.
(2) Wait for 10 µs or more.
(3) Apply “H” to the RESET pin.
5.1.2
Power On
(1) Apply “L” to the RESET pin.
(2) Let the supply voltage increase until it meets the recommended operating conditions.
(3) Wait for td(P-R) or more to allow the internal power supply to stabilize (refer to 20. Electrical
Characteristics).
(4) Wait for 10 µs or more.
(5) Apply “H” to the RESET pin.
Rev.2.10 Sep 26, 2008 Page 28 of 453
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5.Resets
2.2 V
(2.7 V for
VCC J, K version)
VCC
0 V
RESET
RESET
0 V
0.2 VCC or below
td(P-R) + 10 µs or more
NOTE:
1. Refer to 20. Electrical Characteristics.
Figure 5.6
Example of Hardware Reset Circuit and Operation
5 V
Supply voltage
2.2 V
detection circuit
VCC
(2.7 V for
RESET
VCC
J, K version)
0 V
5 V
RESET
0 V
td(P-R) + 10 µs or more
Example when
VCC = 5 V
NOTE:
1. Refer to 20. Electrical Characteristics.
Figure 5.7
Example of Hardware Reset Circuit (Usage Example of External Supply Voltage
Detection Circuit) and Operation
Rev.2.10 Sep 26, 2008 Page 29 of 453
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5.Resets
5.2
Power-On Reset Function
When the RESET pin is connected to the VCC pin via a pull-up resistor, and the VCC pin voltage level rises while
the rise gradient is trth or more, the power-on reset function is enabled and the MCU resets its pins, CPU, and SFR.
When a capacitor is connected to the RESET pin, too, always keep the voltage to the RESET pin 0.8VCC or more.
When the input voltage to the VCC pin reaches theVdet0 (Vdet1 for J, K version) level or above, the low-speed on-
chip oscillator clock starts counting. When the low-speed on-chip oscillator clock count reaches 32, the internal
reset signal is held “H” and the MCU enters the reset sequence (refer to Figure 5.4). The low-speed on-chip
oscillator clock divided by 8 is automatically selected as the CPU clock after reset.
Refer to 4. Special Function Registers (SFRs) for the states of the SFR after power-on reset.
The voltage monitor 0 reset is enabled after power-on reset.
Figure 5.8 and Figure 5.9 shows the Example of Power-On Reset Circuit and Operation.
VCC
4.7 kΩ
(reference)
RESET
(3)
Vdet0
(3)
Vdet0
2.2 V
trth
trth
External
Power VCC
Vpor2
Vpor1
Sampling time(1, 2)
tw(por1)
Internal
reset signal
(“L” valid)
1
1
× 32
× 32
fOCO-S
fOCO-S
NOTES:
1. When using the voltage monitor 0 digital filter, ensure that the voltage is within the MCU operation voltage
range (2.2 V or above) during the sampling time.
2. The sampling clock can be selected. Refer to 6. Voltage Detection Circuit for details.
3. Vdet0 indicates the voltage detection level of the voltage detection 0 circuit. Refer to 6. Voltage Detection
Circuit for details.
4. Refer to 20. Electrical Characteristics.
5. To use the power-on reset function, enable voltage monitor 0 reset by setting the LVD0ON bit in the OFS
register to 0, the VW0C0 and VW0C6 bits in the VW0C register to 1 respectively, and the VCA25 bit in the
VCA2 register to 1.
Figure 5.8
Example of Power-On Reset Circuit and Operation (N, D version)
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5.Resets
VCC
4.7 kΩ
(reference)
RESET
(3)
(3)
Vdet1
Vdet1
trth
trth
2.0 V
External
power VCC
td(Vdet1-A)
Vpor2
Vpor1
tw(por1)
Sampling time(1, 2)
Internal reset
signal
(“L” valid)
1
1
× 32
× 32
fOCO-S
fOCO-S
NOTES:
1. When using the voltage monitor 1 digital filter, ensure VCC is 2.0 V or higher during the sampling time.
2. The sampling clock can be selected. Refer to 6. Voltage Detection Circuit for details.
3. Vdet1 indicates the voltage detection level of the voltage detection 1 circuit. Refer to 6. Voltage Detection
Circuit for details.
4. Refer to 20. Electrical Characteristics.
5. To use the power-on reset function, enable voltage monitor 1 reset by setting the LVD1ON bit in the OFS
register to 0, the VW1C0 and VW1C6 bits in the VW1C register to 1 respectively, and the VCA26 bit in the
VCA2 register to 1.
Figure 5.9
Example of Power-On Reset Circuit and Operation (J, K version)
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5.Resets
5.3
Voltage Monitor 0 Reset (N, D Version)
A reset is applied using the on-chip voltage detection 0 circuit. The voltage detection 0 circuit monitors the input
voltage to the VCC pin. The voltage to monitor is Vdet0.
When the input voltage to the VCC pin reaches the Vdet0 level or below, the pins, CPU, and SFR are reset.
When the input voltage to the VCC pin reaches the Vdet0 level or above, the low-speed on-chip oscillator clock
start counting. When the low-speed on-chip oscillator clock count reaches 32, the internal reset signal is held “H”
and the MCU enters the reset sequence (refer to Figure 5.4). The low-speed on-chip oscillator clock divided by 8 is
automatically selected as the CPU clock after reset.
The LVD0ON bit in the OFS register can be used to enable or disable voltage monitor 0 reset after a hardware reset.
Setting the LVD0ON bit is only valid after a hardware reset.
To use the power-on reset function, enable voltage monitor 0 reset by setting the LVD0ON bit in the OFS register
to 0, the VW0C0 and VW0C6 bits in the VW0C register to 1 respectively, and the VCA25 bit in the VCA2 register
to 1.
The LVD0ON bit cannot be changed by a program. To set the LVD0ON bit, write 0 (voltage monitor 0 reset
enabled after hardware reset) or 1 (voltage monitor 0 reset disabled after hardware reset) to bit 5 of address 0FFFFh
using a flash programmer.
Refer to Figure 5.5 OFS Register for details of the OFS register.
Refer to 4. Special Function Registers (SFRs) for the status of the SFR after voltage monitor 0 reset.
The internal RAM is not reset. When the input voltage to the VCC pin reaches the Vdet0 level or below while
writing to the internal RAM is in progress, the contents of internal RAM are undefined.
Refer to 6. Voltage Detection Circuit for details of voltage monitor 0 reset.
5.4
Voltage Monitor 1 Reset (N, D Version)
A reset is applied using the on-chip voltage detection 1 circuit. The voltage detection 1 circuit monitors the input
voltage to the VCC pin. The voltage to monitor is Vdet1.
When the input voltage to the VCC pin drops the Vdet1 level or below, the pins, CPU, and SFR are reset and a program
is executed beginning with the address indicated by the reset vector. After reset, the low-speed on-chip oscillator
clock divided by 8 is automatically selected as the CPU clock.
The voltage monitor 1 does not reset some portions of the SFR. Refer to 4. Special Function Registers (SFRs) for
details.
The internal RAM is not reset. When the input voltage to the VCC pin reaches the Vdet1 level or below while
writing to the internal RAM is in progress, the contents of internal RAM are undefined.
Refer to 6. Voltage Detection Circuit for details of voltage monitor 1 reset.
5.5
Voltage Monitor 1 Reset (J, K Version)
A reset is applied using the on-chip voltage detection 1 circuit. The voltage detection 1 circuit monitors the input
voltage to the VCC pin. The voltage to monitor is Vdet1.
When the input voltage to the VCC pin reaches the Vdet1 level or below, the pins, CPU, and SFR are reset.
When the input voltage to the VCC pin reaches the Vdet1 level or above, the low-speed on-chip oscillator clock
start counting. When the low-speed on-chip oscillator clock count reaches 32, the internal reset signal is held “H”
and the MCU enters the reset sequence (refer to Figure 5.4). The low-speed on-chip oscillator clock divided by 8 is
automatically selected as the CPU clock after reset.
The LVD1ON bit in the OFS register can be used to enable or disable voltage monitor 1 reset. Setting the LVD1ON
bit is only valid after a hardware reset.
To use the power-on reset function, enable voltage monitor 1 reset by setting the LVD1ON bit in the OFS register
to 0, the VW1C0 and VW1C6 bits in the VW1C register to 1 respectively, and the VCA26 bit in the VCA2 register
to 1.
The LVD1ON bit cannot be changed by a program. To set the LVD1ON bit, write 0 (voltage monitor 1 reset
enabled after hardware reset) or 1 (voltage monitor 1 reset disabled after hardware reset) to bit 6 of address 0FFFFh
using a flash programmer.
Refer to Figure 5.5 OFS Register for details of the OFS register.
Refer to 4. Special Function Registers (SFRs) for the status of the SFR after voltage monitor 1 reset.
The internal RAM is not reset. When the input voltage to the VCC pin reaches the Vdet1 level or below while
writing to the internal RAM is in progress, the contents of internal RAM are undefined.
Refer to 6. Voltage Detection Circuit for details of voltage monitor 1 reset.
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5.Resets
5.6
Voltage Monitor 2 Reset
A reset is applied using the on-chip voltage detection 2 circuit. The voltage detection 2 circuit monitors the input
voltage to the VCC pin. The voltage monitored is Vdet2.
When the input voltage to the VCC pin drops the Vdet2 level or below, the pins, CPU, and SFR are reset and the
program beginning with the address indicated by the reset vector is executed. After reset, the low-speed on-chip
oscillator clock divided by 8 is automatically selected as the CPU clock.
The voltage monitor 2 does not reset some SFRs. Refer to 4. Special Function Registers (SFRs) for details.
The internal RAM is not reset. When the input voltage to the VCC pin reaches the Vdet2 level or below while
writing to the internal RAM is in progress, the contents of internal RAM are undefined.
Refer to 6. Voltage Detection Circuit for details of voltage monitor 2 reset.
5.7
Watchdog Timer Reset
When the PM12 bit in the PM1 register is set to 1 (reset when watchdog timer underflows), the MCU resets its pins,
CPU, and SFR if the watchdog timer underflows. Then the program beginning with the address indicated by the
reset vector is executed. After reset, the low-speed on-chip oscillator clock divided by 8 is automatically selected as
the CPU clock.
The watchdog timer reset does not reset some SFRs. Refer to 4. Special Function Registers (SFRs) for details.
The internal RAM is not reset. When the watchdog timer underflows, the contents of internal RAM are undefined.
Refer to 13. Watchdog Timer for details of the watchdog timer.
5.8
Software Reset
When the PM03 bit in the PM0 register is set to 1 (MCU reset), the MCU resets its pins, CPU, and SFR. The
program beginning with the address indicated by the reset vector is executed. After reset, the low-speed on-chip
oscillator clock divided by 8 is automatically selected for the CPU clock.
The software reset does not reset some SFRs. Refer to 4. Special Function Registers (SFRs) for details.
The internal RAM is not reset.
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6. Voltage Detection Circuit
6. Voltage Detection Circuit
The voltage detection circuit monitors the input voltage to the VCC pin. This circuit can be used to monitor the VCC
input voltage by a program. Alternately, voltage monitor 0 reset (for N, D version only), voltage monitor 1 interrupt
(for N, D version only), voltage monitor 1 reset, voltage monitor 2 interrupt, and voltage monitor 2 reset can also be
used.
Table 6.1 lists the Specifications of Voltage Detection Circuit (N, D version) and Table 6.2 lists the Specifications of
Voltage Detection Circuit (J, K Version). Figures 6.1 to 6.6 show the Block Diagrams. Figures 6.7 to 6.12 show the
associated registers.
Table 6.1
Specifications of Voltage Detection Circuit (N, D version)
Item Voltage Detection 0 Voltage Detection 1
VCC Monitor Voltage to monitor Vdet0 Vdet1
Passing through Vdet1 by Passing through Vdet2 by
Voltage Detection 2
Vdet2
Detection target
Whether passing
through Vdet0 by rising rising or falling
rising or falling
or falling
Monitor
None
VW1C3 bit in VW1C
register
VCA13 bit in VCA1
register
Whether VCC is higher or Whether VCC is higher or
lower than Vdet1
lower than Vdet2
Process
Reset
Voltage monitor 0 reset Voltage monitor 1 reset
Voltage monitor 2 reset
When Voltage
is Detected
Reset at Vdet0 > VCC; Reset at Vdet1 > VCC;
restart CPU operation at restart CPU operation
Reset at Vdet2 > VCC;
restart CPU operation
after a specified time
VCC > Vdet0
after a specified time
Interrupt
None
Voltage monitor 1 interrupt Voltage monitor 2 interrupt
Interrupt request at Vdet1 Interrupt request at Vdet2
> VCC and VCC > Vdet1 > VCC and VCC > Vdet2
when digital filter is
enabled;
when digital filter is
enabled;
interrupt request at Vdet1 interrupt request at Vdet2
> VCC or VCC > Vdet1
when digital filter is
disabled
> VCC or VCC > Vdet2
when digital filter is
disabled
Digital Filter
Switch
Available
Available
Available
enabled/disabled
Sampling time
(Divide-by-n of fOCO-S) (Divide-by-n of fOCO-S)
(Divide-by-n of fOCO-S)
× 4
× 4
× 4
n: 1, 2, 4, and 8
n: 1, 2, 4, and 8
n: 1, 2, 4, and 8
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6. Voltage Detection Circuit
Table 6.2
Specifications of Voltage Detection Circuit (J, K Version)
Item Voltage Detection 1
VCC Monitor Voltage to monitor Vdet1
Voltage Detection 2
Vdet2
Detection target
Whether passing through Vdet1 Passing through Vdet2 by rising or falling
by rising or falling
Monitor
None
VCA13 bit in VCA1 register
Whether VCC is higher or lower than Vdet2
Voltage monitor 2 reset
Process
When Voltage
is Detected
Reset
Voltage monitor 1 reset
Reset at Vdet1 > VCC;
Reset at Vdet2 > VCC; restart CPU operation
restart CPU operation at VCC > after a specified time
Vdet1
Interrupt
None
Voltage monitor 2 interrupt
Interrupt request at Vdet2 > VCC and VCC >
Vdet2 when digital filter is enabled;
interrupt request at Vdet2 > VCC or VCC >
Vdet2 when digital filter is disabled
Digital Filter
Switch
Available
Available
enabled/disabled
Sampling time
(Divide-by-n of fOCO-S) × 4
n: 1, 2, 4, and 8
(Divide-by-n of fOCO-S) × 4
n: 1, 2, 4, and 8
VCA27
VCC
Voltage detection 2
signal
Noise
filter
+
-
Internal
reference
voltage
≥ Vdet2
VCA1 register
b3
VCA26
VCA13 bit
Voltage detection 1
signal
Noise
filter
+
-
≥ Vdet1
VW1C register
b3
VW1C3 bit
VCA25
Voltage detection 0
signal
+
-
≥ Vdet0
Figure 6.1
Block Diagram of Voltage Detection Circuit (N, D version)
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6. Voltage Detection Circuit
VCA27
VCC
Voltage detection 2
signal
Noise
filter
+
-
Internal
reference
voltage
≥ Vdet2
VCA1 register
b3
VCA26
VCA13 bit
Voltage detection 1
signal
Noise
filter
+
-
≥ Vdet1
Figure 6.2
Block Diagram of Voltage Detection Circuit (J, K version)
Voltage monitor 0 reset generation circuit
VW0F1 to VW0F0
= 00b
= 01b
Voltage detection 0 circuit
= 10b
= 11b
fOCO-S
1/2
1/2
1/2
VCA25
VW0C1
VCC
+
-
Digital
filter
Internal
reference
voltage
Voltage
detection 0
signal
Voltage detection 0
signal is held “H” when
VCA25 bit is set to 0
(disabled)
Voltage monitor 0
reset signal
VW0C1
VW0C0
VW0C6
VW0C7
VW0C0 to VW0C1, VW0F0 to VW0F1, VW0C6, VW0C7: Bits in VW0C register
VCA25: Bit in VCA2 register
Figure 6.3
Block Diagram of Voltage Monitor 0 Reset Generation Circuit (For N, D Version Only)
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6. Voltage Detection Circuit
Voltage monitor 1 interrupt/reset generation circuit
VW1F1 to VW1F0
= 00b
= 01b
Voltage detection 1 circuit
VW1C2 bit is set to 0 (not detected) by
writing 0 by a program.
When VCA26 bit is set to 0 (voltage
detection 1 circuit disabled), VW1C2
bit is set to 0
= 10b
= 11b
fOCO-S
1/2
1/2
1/2
VCA26
VW1C1
VW1C3
Watchdog
timer interrupt
signal
VCC
+
-
Digital
filter
Noise filter
(Filter width: 200 ns)
Voltage
detection
1 signal
Internal
reference
voltage
VW1C2
Voltage detection 1 signal
is held “H” when VCA26 bit
is set to 0 (disabled)
Voltage monitor 1
interrupt signal
Non-maskable
interrupt signal
VW1C1
Oscillation stop
detection
interrupt signal
VW1C7
VW1C0
VW1C6
Voltage monitor 1
reset signal
VW1C0 to VW1C3, VW1F0, VW1F1, VW1C6, VW1C7: Bits in VW1C register
VCA26: Bit in VCA2 register
Figure 6.4
Block Diagram of Voltage Monitor 1 Interrupt/Reset Generation Circuit (N, D version)
Voltage monitor 1 interrupt/reset generation circuit
VW1F1 to VW1F0
= 00b
= 01b
Voltage detection 1 circuit
VCA26
VW1C2 bit is set to 0 (not detected) by
= 10b
writing 0 by a program.
= 11b
When VCA26 bit is set to 0 (voltage
detection 1 circuit disabled), VW1C2
bit is set to 0
fOCO-S
1/2
1/2
1/2
VW1C1
VW1C3
VCC
+
-
Digital
filter
Noise filter
Voltage
detection
1 signal
Internal
reference
voltage
VW1C2
(Filter width: 200 ns)
Voltage detection 1 signal
is held “H” when VCA26 bit
is set to 0 (disabled)
VW1C1
VW1C7
VW1C0
VW1C6
Voltage monitor 1
reset signal
VW1C0 to VW1C3, VW1F0, VW1F1, VW1C6, VW1C7: Bits in VW1C register
VCA26: Bit in VCA2 register
Figure 6.5
Block Diagram of Voltage Monitor 1 Reset Generation Circuit (J, K version)
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6. Voltage Detection Circuit
Voltage monitor 2 interrupt/reset generation circuit
VW2F1 to VW2F0
= 00b
= 01b
Voltage detection 2 circuit
= 10b
= 11b
VW2C2 bit is set to 0 (not detected) by
writing 0 by a program.
When VCA27 bit is set to 0 (voltage
detection 2 circuit disabled), VW2C2
bit is set to 0
fOCO-S
1/2
1/2
1/2
VCA27
VW2C1
VCA13
Watchdog
timer interrupt
signal
VCC
+
-
Digital
filter
Noise filter
(Filter width: 200 ns)
Voltage
detection
2 signal
Internal
reference
voltage
VW2C2
Voltage detection 2 signal
is held “H” when VCA27 bit
is set to 0 (disabled)
Voltage monitor 2
interrupt signal
Non-maskable
interrupt signal
VW2C1
Oscillation stop
detection
interrupt signal
Watchdog timer block
VW2C3
VW2C7
Watchdog timer
underflow signal
VW2C0
VW2C6
This bit is set to 0 (not detected) by writing
by a program.
0
Voltage monitor 2
reset signal
VW2C0 to VW2C3, VW2F0, VW2F1, VW2C6, VW2C7: Bits in VW2C register
VCA13: Bit in VCA1 register
VCA27: Bit in VCA2 register
Figure 6.6
Block Diagram of Voltage Monitor 2 Interrupt/Reset Generation Circuit
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6. Voltage Detection Circuit
Voltage Detection Register 1
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0
0 0 0
Symbol
Address
0031h
After Reset(2)
00001000b
Function
VCA1
Bit Symbol
—
Bit Name
RW
RW
Reserved bits
Set to 0.
(b2-b0)
Voltage detection 2 signal monitor
flag(1)
0 : VCC < Vdet2
1 : VCC Vdet2 or voltage detection 2
≥
VCA13
RO
circuit disabled
—
(b7-b4)
Reserved bits
Set to 0.
RW
NOTES:
1. The VCA13 bit is enabled w hen the VCA27 bit in the VCA2 register is set to 1 (voltage detection 2 circuit enabled).
The VCA13 bit is set to 1 (VCC Vdet 2) w hen the VCA27 bit in the VCA2 register is set to 0 (voltage detection 2
≥
circuit disabled).
2. The softw are reset, w atchdog timer reset, voltage monitor 1 reset, and voltage monitor 2 reset do not affect this
register.
Voltage Detection Register 2(1) (N, D Version)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0
Symbol
Address
After Reset(5)
The LVD0ON bit in the OFS register is
set to 1 and hardw are reset
: 00h
Pow er-on reset, voltage monitor 0 reset
or LVD0ON bit in the OFS register is
set to 0, and hardw are reset
: 00100000b
VCA2
0032h
Bit Name
Internal pow er low
consumption enable bit(6)
Bit Symbol
Function
0 : Disables low consumption
1 : Enables low consumption
RW
RW
VCA20
—
(b4-b1)
Reserved bits
Set to 0.
RW
RW
RW
RW
Voltage detection 0 enable 0 : Voltage detection 0 circuit disabled
bit(2)
1 : Voltage detection 0 circuit enabled
Voltage detection 1 enable 0 : Voltage detection 1 circuit disabled
bit(3)
1 : Voltage detection 1 circuit enabled
Voltage detection 2 enable 0 : Voltage detection 2 circuit disabled
bit(4)
1 : Voltage detection 2 circuit enabled
VCA25
VCA26
VCA27
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (w rite enable) before w riting to the VCA2 register.
2. To use the voltage monitor 0 reset, set the VCA25 bit to 1.
After the VCA25 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
3. To use the voltage monitor 1 interrupt/reset or the VW1C3 bit in the VW1C register, set the VCA26 bit to 1.
After the VCA26 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
4. To use the voltage monitor 2 interrupt/reset or the VCA13 bit in the VCA1 register, set the VCA27 bit to 1.
After the VCA27 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
5. Softw are reset, w atchdog timer reset, voltage monitor 1 reset, and voltage monitor 2 reset do not affect this
register.
6. Use the VCA20 bit only w hen entering to w ait mode. To set the VCA20 bit, follow the procedure show n in
Figure
.
10.10 Procedure for Enabling Reduced Internal Power Consumption Using VCA20 bit
Figure 6.7
Registers VCA1 and VCA2 (N, D version)
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6. Voltage Detection Circuit
Voltage Detection Register 2(1) (J, K Version)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0
Symbol
Address
After Reset(4)
The LVD1ON bit in the OFS register is
set to 1 and hardw are reset
: 00h
Pow er-on reset, voltage monitor 1 reset
or LVD1ON bit in the OFS register is
set to 0, and hardw are reset
: 0100000b
VCA2
Bit Symbol
0032h
Bit Name
Internal pow er low
consumption enable bit(5)
Function
0 : Disables low consumption
1 : Enables low consumption
RW
RW
VCA20
—
(b5-b1)
Reserved bits
Set to 0.
RW
RW
RW
Voltage detection 1 enable 0 : Voltage detection 1 circuit disabled
bit(2)
1 : Voltage detection 1 circuit enabled
Voltage detection 2 enable 0 : Voltage detection 2 circuit disabled
bit(3)
1 : Voltage detection 2 circuit enabled
VCA26
VCA27
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (w rite enable) before w riting to the VCA2 register.
2. To use the voltage monitor 1 reset, set the VCA26 bit to 1.
After the VCA26 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
3. To use the voltage monitor 2 interrupt/reset or the VCA13 bit in the VCA1 register, set the VCA27 bit to 1.
After the VCA27 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
4. Softw are reset, w atchdog timer reset, or voltage monitor 2 reset do not affect this register.
5. Use the VCA20 bit only w hen entering to w ait mode. To set the VCA20 bit, follow the procedure show n in
Figure
.
10.10 Procedure for Enabling Reduced Internal Power Consumption Using VCA20 bit
Figure 6.8
VCA2 Register (J, K Version)
Rev.2.10 Sep 26, 2008 Page 40 of 453
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6. Voltage Detection Circuit
Voltage Monitor 0 Circuit Control Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
After Reset(2)
0
Symbol
Address
The LVD0ON bit in the OFS register is
set to 1 and hardw are reset
: 0000X000b
: 0100X001b
Pow er-on reset, voltage monitor 0 reset
or LVD0ON bit in the OFS register is set
to 0, and hardw are reset
VW0C
0038h
Bit Symbol
Bit Name
Function
RW
RW
Voltage monitor 0 reset
enable bit(3)
0 : Disable
1 : Enable
VW0C0
VW0C1
VW0C2
Voltage monitor 0 digital filter 0 : Digital filter enabled mode
disable mode select bit
(digital filter circuit enabled)
1 : Digital filter disabled mode
(digital filter circuit disabled)
RW
Reserved bit
Set to 0.
RW
RO
—
(b3)
Reserved bit
When read, the content is undefined.
Sampling clock select bits
b5 b4
VW0F0
VW0F1
RW
RW
0 0 : fOCO-S divided by 1
0 1 : fOCO-S divided by 2
1 0 : fOCO-S divided by 4
1 1 : fOCO-S divided by 8
Voltage monitor 0 circuit
mode select bit
When the VW0C0 bit is set to 1 (voltage monitor 0
reset enabled), set to 1.
VW0C6
VW0C7
RW
RW
Voltage monitor 0 reset
generation condition select disabled mode), set to 1.
bit(4)
When the VW0C1 bit is set to 1 (digital filter
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (w rite enable) before w riting to the VW0C register.
2. The value remains unchanged after a softw are reset, w atchdog timer reset, voltage monitor 1 reset, and voltage
monitor 2 reset.
3. The VW0C0 bit is enabled w hen the VCA25 bit in the VCA2 register is set to 1 (voltage detection 0 circuit
enabled). Set the VW0C0 bit to 0 (disable), w hen the VCA25 bit is set to 0 (voltage detection 0 circuit disabled).
4. The VW0C7 bit is enabled w hen the VW0C1 bit set to 1 (digital filter disabled mode).
Figure 6.9
VW0C Register (For N, D Version Only)
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6. Voltage Detection Circuit
Voltage Monitor 1 Circuit Control Register(1) (N, D Version)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
VW1C
Address
After Reset(8)
0036h
00001000b
Function
Bit Symbol
Bit Name
RW
RW
Voltage monitor 1 interrupt/reset 0 : Disable
VW1C0
VW1C1
enable bit(6)
1 : Enable
Voltage monitor 1 digital filter
disable mode select bit(2)
0 : Digital filter enabled mode
(digital filter circuit enabled)
1 : Digital filter disabled mode
(digital filter circuit disabled)
RW
Voltage change detection
flag(3, 4, 8)
0 : Not detected
1 : Vdet1 pass detected
VW1C2
VW1C3
RW
RO
Voltage detection 1 signal
monitor flag(3, 8)
0 : VCC < Vdet1
1 : VCC Vdet1 or voltage detection 1
≥
circuit disabled
Sampling clock select bits
b5 b4
VW1F0
RW
0 0 : fOCO-S divided by 1
0 1 : fOCO-S divided by 2
1 0 : fOCO-S divided by 4
1 1 : fOCO-S divided by 8
VW1F1
VW1C6
RW
RW
Voltage monitor 1 circuit mode 0 : Voltage monitor 1 interrupt mode
select bit(5)
1 : Voltage monitor 1 reset mode
Voltage monitor 1 interrupt/reset 0 : When VCC reaches Vdet1 or above
generation condition select
bit(7,9)
1 : When VCC reaches Vdet1 or below
VW1C7
RW
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (rew rite enable) before w riting to the VW1C register.
2. To use the voltage monitor 1 interrupt to exit stop mode and to return again, w rite 0 to the VW1C1 bit before w riting
1.
3. Bits VW1C2 and VW1C3 are enabled w hen the VCA26 bit in the VCA2 register is set to 1 (voltage detection 1 circuit
enabled).
4. Set this bit to 0 by a program. When 0 is w ritten by a program, it is set to 0 (and remains unchanged even if 1 is
w ritten to it).
5. The VW1C6 bit is enabled w hen the VW1C0 bit is set to 1 (voltage monitor 1 interrupt/enabled reset).
6. The VW1C0 bit is enabled w hen the VCA26 bit in the VCA2 register is set to 1 (voltage detection 1 circuit enabled).
Set the VW1C0 bit to 0 (disable) w hen the VCA26 bit is set to 0 (voltage detection 1 circuit disabled).
7. The VW1C7 bit is enabled w hen the VW1C1 bit is set to 1 (digital filter disabled mode).
8. Bits VW1C2 and VW1C3 remain unchanged after a softw are reset, w atchdog timer reset, voltage monitor 1 reset, or
voltage monitor 2 reset.
9. When the VW1C6 bit is set to 1 (voltage monitor 1 reset mode), set the VW1C7 bit to 1 (w hen VCC reaches Vdet1 or
below ). (Do not set to 0.)
Figure 6.10
VW1C Register (N, D Version)
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6. Voltage Detection Circuit
Voltage Monitor 1 Circuit Control Register(1) (J, K Version)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
After Reset(6)
The LVD1ON bit in the OFS register is
set to 1 and hardw are reset
Pow er-on reset, voltage monitor 1 reset
or LVD1ON bit in the OFS register is set
to 0, and hardw are reset
: 0000X000b
: 0100X001b
VW1C
0036h
Bit Symbol
Bit Name
Function
RW
RW
Voltage monitor 1 reset
enable bit(4)
0 : Disable
1 : Enable
VW1C0
VW1C1
Voltage monitor 1 digital filter 0 : Digital filter enabled mode
disable mode select bit(2)
(digital filter circuit enabled)
1 : Digital filter disabled mode
(digital filter circuit disabled)
RW
—
(b2)
Reserved bit
Set to 0.
RW
RO
—
(b3)
Reserved bit
When read, the content is undefined.
Sampling clock select bits
b5 b4
VW1F0
RW
0 0 : fOCO-S divided by 1
0 1 : fOCO-S divided by 2
1 0 : fOCO-S divided by 4
1 1 : fOCO-S divided by 8
VW1F1
VW1C6
RW
RW
Voltage monitor 1 circuit
mode select bit(3)
When the VW1C0 bit is 1(voltage monitor 1 reset
enabled), set to 1.
Voltage monitor 1 reset
When the VW1C1 bit is 1(digital filter disabled
generation condition select mode), set to 1.
bit(5, 7)
VW1C7
RW
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (rew rite enable) before w riting to the VW1C register.
2. To use the voltage monitor 1 interrupt to exit stop mode and to return again, w rite 0 to the VW1C1 bit before w riting
1.
3. The VW1C6 bit is enabled w hen the VW1C0 bit is set to 1 (voltage monitor 1 reset enabled).
4. The VW1C0 bit is enabled w hen the VCA26 bit in the VCA2 register is set to 1 (voltage detection 1 circuit enabled).
Set the VW1C0 bit to 0 (disable) w hen the VCA26 bit is set to 0 (voltage detection 1 circuit disabled).
5. The VW1C7 bit is enabled w hen the VW1C1 bit is set to 1 (digital filter disabled mode).
6. Softw are reset, w atchdog timer reset, or voltage monitor 2 reset do not affect this register.
7. When the VW1C6 bit is set to 1 (voltage monitor 1 reset mode), set the VW1C7 bit to 1 (w hen VCC reaches Vdet1 or
below ). (Do not set to 0.)
Figure 6.11
VW1C Register (J, K version)
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6. Voltage Detection Circuit
Voltage Monitor 2 Circuit Control Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
VW2C
Address
After Reset(8)
0037h
00h
Bit Symbol
Bit Name
Function
RW
RW
Voltage monitor 2 interrupt/reset 0 : Disable
VW2C0
VW2C1
enable bit(6)
1 : Enable
Voltage monitor 2 digital filter
disable mode select bit(2)
0 : Digital filter enabled mode
(digital filter circuit enabled)
1 : Digital filter disabled mode
(digital filter circuit disabled)
RW
Voltage change detection
flag(3,4,8)
WDT detection flag(4,8)
0 : Not detected
1 : VCC has crossed Vdet2
VW2C2
VW2C3
RW
RW
0 : Not detected
1 : Detected
Sampling clock select bits
b5 b4
VW2F0
RW
0 0 : fOCO-S divided by 1
0 1 : fOCO-S divided by 2
1 0 : fOCO-S divided by 4
VW2F1
VW2C6
RW
RW
1 1 : fOCO-S divided by 8
Voltage monitor 2 circuit mode 0 : Voltage monitor 2 interrupt mode
select bit(5)
1 : Voltage monitor 2 reset mode
Voltage monitor 2 interrupt/reset 0 : When VCC reaches Vdet2 or above
generation condition select
bit(7,9)
1 : When VCC reaches Vdet2 or below
VW2C7
RW
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (w rite enable) before w riting to the VW2C register.
2. To use the voltage monitor 2 interrupt to exit stop mode and to return again, w rite 0 to the VW2C1
bit before w riting 1.
3. The VW2C2 bit is enabled w hen the VCA27 bit in the VCA2 register is set to 1 (voltage detection 2 circuit
enabled).
4. Set this bit to 0 by a program. When 0 is w ritten by a program, it is set to 0 (and remains unchanged even if 1 is
w ritten to it).
5. The VW2C6 bit is enabled w hen the VW2C0 bit is set to 1 (voltage monitor 2 interrupt/enables reset).
6. The VW2C0 bit is enabled w hen the VCA27 bit in the VCA2 register is set to 1 (voltage detection 2 circuit
enabled). Set the VW2C0 bit to 0 (disable) w hen the VCA27 bit is set to 0 (voltage detection 2 circuit disabled).
7. The VW2C7 bit is enabled w hen the VW2C1 bit is set to 1 (digital filter disabled mode).
8. Bits VW2C2 and VW2C3 remain unchanged after a softw are reset, w atchdog timer reset, voltage monitor 1 reset
(for N, D version only), or voltage monitor 2 reset.
9. When the VW2C6 bit is set to 1 (voltage monitor 2 reset mode), set the VW2C7 bit to 1 (w hen VCC reaches Vdet2 or
below ). (Do not set to 0.)
Figure 6.12
VW2C Register
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6. Voltage Detection Circuit
6.1
6.1.1
VCC Input Voltage
Monitoring Vdet0
Vdet0 cannot be monitored.
6.1.2
Monitoring Vdet1
Set the VCA26 bit in the VCA2 register to 1 (voltage detection 1 circuit enabled). After td(E-A) has elapsed
(refer to 20. Electrical Characteristics), Vdet1 can be monitored by the VW1C3 bit in the VW1C register.
6.1.3
Monitoring Vdet2
Set the VCA27 bit in the VCA2 register to 1 (voltage detection 2 circuit enabled). After td(E-A) has elapsed
(refer to 20. Electrical Characteristics), Vdet2 can be monitored by the VCA13 bit in the VCA1 register.
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6. Voltage Detection Circuit
6.2
Voltage Monitor 0 Reset (For N, D Version Only)
Table 6.3 lists the Procedure for Setting Bits Associated with Voltage Monitor Reset and Figure 6.13 shows an
Example of Voltage Monitor 0 Reset Operation. To use the voltage monitor 0 reset to exit stop mode, set the
VW0C1 bit in the VW0C register to 1 (digital filter disabled).
Table 6.3
Step
Procedure for Setting Bits Associated with Voltage Monitor Reset
When Using Digital Filter
When Not Using Digital Filter
1
2
Set the VCA25 bit in the VCA2 register to 1 (voltage detection 0 circuit enabled)
Wait for td(E-A)
Select the sampling clock of the digital filter Set the VW0C7 bit in the VW0C register to
by the VW0F0 to VW0F1 bits in the VW0C 1
3
register
Set the VW0C1 bit in the VW0C register to Set the VW0C1 bit in the VW0C register to
(1)
4
0 (digital filter enabled)
1 (digital filter disabled)
(1)
Set the VW0C6 bit in the VW0C register to 1 (voltage monitor 0 reset mode)
Set the VW0C2 bit in the VW0C register to 0
5
6
7
Set the CM14 bit in the CM1 register to 0
(low-speed on-chip oscillator on)
Wait for 4 cycles of the sampling clock of
the digital filter
−
8
9
− (No wait time required)
Set the VW0C0 bit in the VW0C register to 1 (voltage monitor 0 reset enabled)
NOTE:
1. When the VW0C0 bit is set to 0, steps 3, 4, and 5 can be executed simultaneously (with 1
instruction).
VCC
Vdet0
1
× 32
Sampling clock of
digital filter × 4 cycles
fOCO-S
When the VW0C1 bit is set
to 0 (digital filter enabled)
Internal reset signal
1
× 32
fOCO-S
When the VW0C1 bit is set
to 1 (digital filter disabled)
and the VW0C7 bit is set
to 1
Internal reset signal
VW0C1 and VW0C7: Bits in VW0C register
The above applies under the following conditions.
• VCA25 bit in VCA2 register = 1 (voltage detection 0 circuit enabled)
• VW0C0 bit in VW0C register = 1 (voltage monitor 0 reset enabled)
• VW0C6 bit in VW0C register = 1 (voltage monitor 0 reset mode)
When the internal reset signal is held “L”, the pins, CPU and SFR are reset.
The internal reset signal level changes from “L” to “H”, and a program is executed beginning with the address indicated by
the reset vector.
Refer to 4. Special Function Registers (SFRs) for the SFR status after reset.
Figure 6.13
Example of Voltage Monitor 0 Reset Operation
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6. Voltage Detection Circuit
6.3
Voltage Monitor 1 Interrupt and Voltage Monitor 1 Reset (N, D Version)
Table 6.4 lists the Procedure for Setting Bits Associated with Voltage Monitor 1 Interrupt and Reset. Figure 6.14
shows an Example of Voltage Monitor 1 Interrupt and Voltage Monitor 1 Reset Operation (N, D Version). To use
the voltage monitor 1 interrupt or voltage monitor 1 reset to exit stop mode, set the VW1C1 bit in the VW1C
register to 1 (digital filter disabled).
Table 6.4
Procedure for Setting Bits Associated with Voltage Monitor 1 Interrupt and Reset
When Using Digital Filter When Not Using Digital Filter
Voltage Monitor 1 Voltage Monitor 1
Interrupt Reset
Step
Voltage Monitor 1
Interrupt
Voltage Monitor 1
Reset
1
2
Set the VCA26 bit in the VCA2 register to 1 (voltage detection 1 circuit enabled)
Wait for td(E-A)
Select the sampling clock of the digital filter Select the timing of the interrupt and reset
by the VW1F0 to VW1F1 bits in the VW1C
register
request by the VW1C7 bit in the VW1C
3
(1)
register
Set the VW1C1 bit in the VW1C register to 0 Set the VW1C1 bit in the VW1C register to 1
(digital filter enabled) (digital filter disabled)
(2)
4
(2)
Set the VW1C6 bit in Set the VW1C6 bit in Set the VW1C6 bit in Set the VW1C6 bit in
the VW1C register to the VW1C register to the VW1C register to the VW1C register to
0 (voltage monitor 1 1 (voltage monitor 1 0 (voltage monitor 1 1 (voltage monitor 1
5
interrupt mode)
reset mode)
interrupt mode)
reset mode)
6
7
Set the VW1C2 bit in the VW1C register to 0 (passing of Vdet1 is not detected)
Set the CM14 bit in the CM1 register to 0
(low-speed on-chip oscillator on)
−
8
Wait for 4 cycles of the sampling clock of the − (No wait time required)
digital filter
9
Set the VW1C0 bit in the VW1C register to 1 (voltage monitor 1 interrupt/reset enabled)
NOTES:
1. Set the VW1C7 bit to 1 (when VCC reaches Vdet1 or below) for the voltage monitor 1 reset.
2. When the VW1C0 bit is set to 0, steps 3, 4, and 5 can be executed simultaneously (with 1
instruction).
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6. Voltage Detection Circuit
VCC
Vdet1
2.2 V(1)
1
0
VW1C3 bit
4 cycles of sampling clock of digital filter
4 cycles of sampling clock of digital filter
1
0
VW1C2 bit
Set to 0 by a program
When the VW1C1 bit is set
to 0 (digital filter enabled)
Set to 0 by interrupt request
acknowledgement
Voltage monitor 1
interrupt request
(VW1C6 = 0)
Internal reset signal
(VW1C6 = 1)
Set to 0 by a program
1
0
VW1C2 bit
When the VW1C1 bit is
set to 1 (digital filter
disabled) and the
VW1C7 bit is set to 0
(Vdet1 or above)
Set to 0 by interrupt
request
acknowledgement
Voltage monitor 1
interrupt request
(VW1C6 = 0)
Set to 0 by a program
1
0
VW1C2 bit
Set to 0 by interrupt
When the VW1C1 bit is
set to 1 (digital filter
disabled) and the
VW1C7 bit is set to 1
(Vdet1 or below)
request acknowledgement
Voltage monitor 1
interrupt request
(VW1C6 = 0)
Internal reset signal
(VW1C6 = 1)
VW1C1, VW1C2, VW1C3, VW1C6, VW1C7: Bit in VW1C Register
The above applies under the following conditions.
• VCA26 bit in VCA2 register = 1 (voltage detection 1 circuit enabled)
• VW1C0 bit in VW1C register = 1 (voltage monitor 1 interrupt and voltage monitor 1 reset enabled)
NOTE:
1. If voltage monitor 0 reset is not used, set the power supply to VCC ≥ 2.2.
Figure 6.14
Example of Voltage Monitor 1 Interrupt and Voltage Monitor 1 Reset Operation (N, D
Version)
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6. Voltage Detection Circuit
6.4
Voltage Monitor 1 Reset (J, K Version)
Table 6.5 lists the Procedure for Setting Bits Associated with Voltage Monitor 1 Reset. Figure 6.15 shows an
Example of Voltage Monitor 1 Reset Operation (J, K Version). To use the voltage monitor 1 reset to exit stop mode,
set the VW1C1 bit in the VW1C register to 1 (digital filter disabled).
Table 6.5
Procedure for Setting Bits Associated with Voltage Monitor 1 Reset
Step
When Using Digital Filter
When Not Using Digital Filter
1
2
Set the VCA26 bit in the VCA2 register to 1 (voltage detection 1 circuit enabled)
Wait for td(E-A)
Select the sampling clock of the digital filter Set the VW1C7 bit in the VW1C register to 1
by the VW1F0 to VW1F1 bits in the VW1C
3
register
Set the VW1C1 bit in the VW1C register to 0 Set the VW1C1 bit in the VW1C register to 1
(1)
4
(digital filter enabled)
(digital filter disabled)
(1)
Set the VW1C6 bit in the VW1C register to 1 (voltage monitor 1 reset mode)
Set the VW1C2 bit in the VW1C register to 0
5
6
7
Set the CM14 bit in the CM1 register to 0
(low-speed on-chip oscillator on)
−
8
Wait for 4 cycles of the sampling clock of the − (No wait time required)
digital filter
9
Set the VW1C0 bit in the VW1C register to 1 (voltage monitor 1 reset enabled)
NOTE:
1. When the VW1C0 bit is set to 0, steps 3, 4, and 5 can be executed simultaneously (with 1
instruction).
VCC
Vdet1
1
× 32
Sampling clock of
digital filter × 4 cycles
fOCO-S
When the VW1C1 bit is set
to 0 (digital filter enabled)
Internal reset signal
1
× 32
fOCO-S
When the VW1C1 bit is set
to 1 (digital filter disabled)
and the VW1C7 bit is set
to 1
Internal reset signal
VW1C1 and VW1C7: Bits in VW1C register
The above applies under the following conditions.
• VCA26 bit in VCA2 register = 1 (voltage detection 1 circuit enabled)
• VW1C0 bit in VW1C register = 1 (voltage monitor 1 reset enabled)
• VW1C6 bit in VW1C register = 1 (voltage monitor 1 reset mode)
When the internal reset signal is held “L”, the pins, CPU and SFR are reset.
The internal reset signal level changes from “L” to “H”, and a program is executed beginning with the address indicated by
the reset vector.
Refer to 4. Special Function Registers (SFRs) for the SFR status after reset.
Figure 6.15
Example of Voltage Monitor 1 Reset Operation (J, K Version)
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6. Voltage Detection Circuit
6.5
Voltage Monitor 2 Interrupt and Voltage Monitor 2 Reset
Table 6.6 lists the Procedure for Setting Bits Associated with Voltage Monitor 2 Interrupt and Reset. Figure 6.16
shows an Example of Voltage Monitor 2 Interrupt and Voltage Monitor 2 Reset Operation. To use the voltage
monitor 2 interrupt or voltage monitor 2 reset to exit stop mode, set the VW2C1 bit in the VW2C register to 1
(digital filter disabled).
Table 6.6
Procedure for Setting Bits Associated with Voltage Monitor 2 Interrupt and Reset
When Using Digital Filter When Not Using Digital Filter
Voltage Monitor 2 Voltage Monitor 2
Interrupt Reset
Step
Voltage Monitor 2
Interrupt
Voltage Monitor 2
Reset
1
2
Set the VCA27 bit in the VCA2 register to 1 (voltage detection 2 circuit enabled)
Wait for td(E-A)
Select the sampling clock of the digital filter Select the timing of the interrupt and reset
by the VW2F0 to VW2F1 bits in the VW2C
register
request by the VW2C7 bit in the VW2C
3
(1)
register
Set the VW2C1 bit in the VW2C register to 0 Set the VW2C1 bit in the VW2C register to 1
(digital filter enabled) (digital filter disabled)
4
(2)
Set the VW2C6 bit in Set the VW2C6 bit in Set the VW2C6 bit in Set the VW2C6 bit in
the VW2C register to the VW2C register to the VW2C register to the VW2C register to
0 (voltage monitor 2 1 (voltage monitor 2 0 (voltage monitor 2 1 (voltage monitor 2
5
interrupt mode)
reset mode)
interrupt mode)
reset mode)
6
7
Set the VW2C2 bit in the VW2C register to 0 (passing of Vdet2 is not detected)
Set the CM14 bit in the CM1 register to 0
(low-speed on-chip oscillator on)
−
8
Wait for 4 cycles of the sampling clock of the − (No wait time required)
digital filter
9
Set the VW2C0 bit in the VW2C register to 1 (voltage monitor 2 interrupt/reset enabled)
NOTES:
1. Set the VW2C7 bit to 1 (when VCC reaches Vdet2 or below) for the voltage monitor 2 reset.
2. When the VW2C0 bit is set to 0, steps 3, 4, and 5 can be executed simultaneously (with 1
instruction).
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6. Voltage Detection Circuit
VCC
Vdet2
2.2 V(1)
1
0
VCA13 bit
4 cycles of sampling clock of digital filter
4 cycles of sampling clock of digital filter
1
0
VW2C2 bit
Set to 0 by a program
When the VW2C1 bit is set
to 0 (digital filter enabled)
Set to 0 by interrupt request
acknowledgement
Voltage monitor 2
interrupt request
(VW2C6 = 0)
Internal reset signal
(VW2C6 = 1)
Set to 0 by a program
1
0
VW2C2 bit
When the VW2C1 bit is
set to 1 (digital filter
disabled) and the
VW2C7 bit is set to 0
(Vdet2 or above)
Set to 0 by interrupt
request
acknowledgement
Voltage monitor 2
interrupt request
(VW2C6 = 0)
Set to 0 by a program
1
0
VW2C2 bit
Set to 0 by interrupt
When the VW2C1 bit is
set to 1 (digital filter
disabled) and the
VW2C7 bit is set to 1
(Vdet2 or below)
request acknowledgement
Voltage monitor 2
interrupt request
(VW2C6 = 0)
Internal reset signal
(VW2C6 = 1)
VCA13: Bit in VCA1 register
VW2C1, VW2C2, VW2C6, VW2C7: Bits in VW2C register
The above applies under the following conditions.
• VCA27 bit in VCA2 register = 1 (voltage detection 2 circuit enabled)
• VW2C0 bit in VW2C register = 1 (voltage monitor 2 interrupt and voltage monitor 2 reset enabled)
NOTE:
1. When voltage monitor 0 reset is not used, set the power supply to VCC ≥ 2.2.
Figure 6.16
Example of Voltage Monitor 2 Interrupt and Voltage Monitor 2 Reset Operation
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7. Programmable I/O Ports
7. Programmable I/O Ports
There are 25 programmable Input/Output ports (I/O ports) P0, P1, P3_1, P3_3 to P3_7, P4_5, P5_3, and P5_4. Also,
(1)
P4_6 and P4_7 can be used as input-only ports if the XIN clock oscillation circuit and XCIN clock oscillation circuit
is not used, and the P4_2 can be used as an input-only port if the A/D converter is not used.
Table 7.1 lists an Overview of Programmable I/O Ports.
NOTE:
1. The XCIN clock oscillation circuit cannot be used for J, K version.
Table 7.1
Overview of Programmable I/O Ports
I/O Type of Output
I/O CMOS3 State
P3_1, P3_3 to P3_7 I/O CMOS3 State
Ports
I/O Setting
Set per bit
Internal Pull-Up Resister
(1)
P0, P1
Set every 4 bits
(1)
Set per bit
Set per bit
Set per bit
Set every 2 bits, 4 bits
(1)
P4_5
I/O CMOS3 State
I/O CMOS3 State
Set every bit
(1)
P5_3, P5_4
Set every bit
(2)
P4_2
I
(No output function)
None
None
(3)
P4_6, P4_7
NOTES:
1. In input mode, whether an internal pull-up resistor is connected or not can be selected by registers
PUR0 and PUR1.
2. When the A/D converter is not used, this port can be used as the input-only port.
3. When the XIN clock oscillation circuit and XCIN clock oscillation circuit (for N, D version only) is not
used, these ports can be used as the input-only ports.
7.1
Functions of Programmable I/O Ports
The PDi_j (j = 0 to 7) bit in the PDi (i = 0, 1, 3 to 5) register controls I/O of the ports P0, P1, P3_1, P3_3 to P3_7,
P4_5, P5_3, and P5_4. The Pi register consists of a port latch to hold output data and a circuit to read pin states.
Figures 7.1 to 7.6 show the Configurations of Programmable I/O Ports. Table 7.2 lists the Functions of
Programmable I/O Ports. Also, Figure 7.8 shows the PDi (i = 0, 1, and 3 to 5) Register. Figure 7.9 shows the Pi (i =
0, 1, and 3 to 5) Register, Figure 7.10 shows Registers PINSR1, PINSR2, and PINSR3, Figure 7.11 shows the PMR
Register, Figure 7.12 shows Registers PUR0 and PUR1, and Figure 7.13 shows the P1DRR Register.
Table 7.2
Functions of Programmable I/O Ports
(1)
Operation When
Accessing
Pi Register
Reading
Value of PDi_j Bit in PDi Register
When PDi_j Bit is Set to 0 (Input Mode) When PDi_j Bit is Set to 1 (Output Mode)
Read pin input level
Write to the port latch
Read the port latch
Write to the port latch. The value written to
the port latch is output from the pin.
Writing
i = 0, 1, 3 to 5, j = 0 to 7
NOTE:
1. Nothing is assigned to bits PD3_0, PD3_2, PD4_0 to PD4_4, PD4_6, and PD4_7.
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7. Programmable I/O Ports
7.2
Effect on Peripheral Functions
Programmable I/O ports function as I/O ports for peripheral functions (refer to Table 1.6 Pin Name Information
by Pin Number).
Table 7.3 lists the Setting of PDi_j Bit when Functioning as I/O Ports for Peripheral Functions (i = 0, 1, 3 to 5, j =
0 to 7). Refer to the description of each function for information on how to set peripheral functions.
Table 7.3
Setting of PDi_j Bit when Functioning as I/O Ports for Peripheral Functions (i = 0, 1, 3 to 5, j = 0 to 7)
I/O of Peripheral Functions
PDi_j Bit Settings for Shared Pin Functions
Set this bit to 0 (input mode).
This bit can be set to either 0 or 1 (output regardless of the port setting)
Input
Output
7.3
Pins Other than Programmable I/O Ports
Figure 7.7 shows the Configuration of I/O Pins.
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7. Programmable I/O Ports
Pull-up selection
P0
Direction
register
(Note 1)
(Note 1)
Data bus
Port latch
Analog input
Drive capacity select
(For N, D version only)
P1_0 to P1_3
Pull-up selection
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Input to individual peripheral function
Analog input
Drive capacity select
(For N, D version only)
Drive capacity select
(For N, D version only)
P1_4
Pull-up selection
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Drive capacity select
(For N, D version only)
NOTE:
1.
symbolizes a parasitic diode.
Ensure the input voltage to each port does not exceed VCC.
Figure 7.1
Configuration of Programmable I/O Ports (1)
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7. Programmable I/O Ports
Drive capacity select
(For N, D version only)
P1_5 and P1_7
Pull-up selection
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Digital
filter
Input to external interrupt
Input to individual peripheral function
Drive capacity select
(For N, D version only)
Drive capacity select
(For N, D version only)
P1_6
Pull-up selection
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Input to individual peripheral function
Drive capacity select
(For N, D version only)
NOTE:
1.
symbolizes a parasitic diode.
Ensure the input voltage to each port does not exceed VCC.
Figure 7.2
Configuration of Programmable I/O Ports (2)
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7. Programmable I/O Ports
P3_1
Pull-up selection
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Pull-up selection
P3_3 and P3_6
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Input to individual peripheral function
Input to external interrupt
Digital
filter
P3_4, P3_5, and P3_7
Pull-up selection
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Input to individual peripheral function
NOTE:
1.
symbolizes a parasitic diode.
Ensure the input voltage to each port does not exceed VCC.
Figure 7.3
Configuration of Programmable I/O Ports (3)
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7. Programmable I/O Ports
(Note 1)
P4_2/VREF
Data bus
(Note 1)
Pull-up selection
P4_5
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Input to individual peripheral function
Input to external interrupt
Digital
filter
NOTE:
1.
symbolizes a parasitic diode.
Ensure the input voltage to each port does not exceed VCC.
Figure 7.4
Configuration of Programmable I/O Ports (4)
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7. Programmable I/O Ports
(N, D Version)
P4_6/XIN
(Note 1)
(Note 1)
Data bus
CM01
1
CM13
0
XIN
oscillation
circuit
XCIN
oscillation
circuit
CM04
CM05
CM11
RfXIN
CM12
RfXCIN
P4_7/XOUT
(Note 2)
(Note 1)
(Note 1)
0
1
CM01
Data bus
(J, K Version)
P4_6/XIN
(Note 1)
(Note 1)
Data bus
CM13
XIN
oscillation
circuit
CM05
CM11
RfXIN
P4_7/XOUT
(Note 2)
(Note 1)
(Note 1)
Data bus
NOTES:
1.
symbolizes a parasitic diode.
Ensure the input voltage to each port does not exceed VCC.
2. This pin is pulled up in one of the following conditions:
• CM01 = CM05 = CM13 = 1
• CM01 = CM04 = 1
• CM01 = CM10 = CM13 = 1
• CM01 = CM10 = CM04 = 1
CM01, CM04, CM05: Bits in CM0 register
CM10, CM13: Bits in CM1 register
Figure 7.5
Configuration of Programmable I/O Ports (5)
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7. Programmable I/O Ports
P5_3 and P5_4
Pull-up selection
Direction
register
1
(Note 1)
(Note 1)
Output from individual peripheral function
Port latch
Data bus
Input to individual peripheral function
NOTE:
1.
symbolizes a parasitic diode.
Ensure the input voltage to each port does not exceed VCC.
Figure 7.6
Configuration of Programmable I/O Ports (5)
MODE
MODE signal input
(Note 1)
RESET
RESET signal input
(Note 1)
NOTE:
1.
symbolizes a parasitic diode.
Ensure the input voltage to each port does not exceed VCC.
Figure 7.7
Configuration of I/O Pins
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7. Programmable I/O Ports
Port Pi Direction Register (i = 0, 1, 3 to 5)(1, 2, 3, 4)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
PD0
Address
00E2h
After Reset
00h
00h
00E3h
PD1
00E7h
00h
PD3
00EAh
00EBh
Bit Name
00h
PD4
00h
PD5
Bit Symbol
PDi_0
PDi_1
PDi_2
PDi_3
PDi_4
PDi_5
PDi_6
PDi_7
Function
RW
RW
RW
RW
RW
RW
RW
RW
RW
Port Pi_0 direc tion bit
0 : Input mode
(functions as an input port)
1 : Output mode
Port Pi_1 direc tion bit
Port Pi_2 direc tion bit
Port Pi_3 direction bit
Port Pi_4 direc tion bit
Port Pi_5 direc tion bit
Port Pi_6 direc tion bit
Port Pi_7 direction bit
(functions as an output port)
NOTES:
1. Set the PD0 register by using the next instruction after setting the PRC2 bit in the PRCR register to 1 (w rite enable).
2. Bits PD3_0 and PD3_2 in the PD3 register are unavailable on this MCU.
If it is necessary to set bits PD3_0 and PD3_2, set to 0 (input mode). When read, the content is 0.
3. Bits PD4_0 to PD4_4, PD4_6, and PD4_7 in the PD4 register are unavailable on this MCU.
If it is necessary to set bits PD4_0 to PD4_4, PD4_6, and PD4_7, set to 0 (input mode). When read, the content is 0.
4. Bits PD5_0 to PD5_2 and PD5_5 to PD5_7 in the PD5 register are unavailable on this MCU.
If it is necessary to set bits PD5_0 to PD5_2 and PD5_5 to PD5_7, set to 0 (input mode). When read, the content is 0.
Figure 7.8
PDi (i = 0, 1, and 3 to 5) Register
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7. Programmable I/O Ports
Port Pi Register (i = 0, 1, 3 to 5)(1, 2, 3)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00E0h
After Reset
00h
00h
P0
00E1h
P1
P3
00E5h
00h
00E8h
00h
P4
00E9h
00h
P5
Bit Symbol
Bit Name
Function
RW
RW
RW
RW
RW
RW
RW
RW
RW
Pi_0
Pi_1
Pi_2
Pi_3
Pi_4
Pi_5
Pi_6
Pi_7
Port Pi_0 bit
The pin level of any I/O port w hich is set
to input mode can be read by reading the
corresponding bit in this register. The pin
level of any I/O port w hich is set to output
mode can be controlled by w riting to the
corresponding bit in this register.
0 : “L” level
Port Pi_1 bit
Port Pi_2 bit
Port Pi_3 bit
Port Pi_4 bit
Port Pi_5 bit
Port Pi_6 bit
Port Pi_7 bit
1 : “H” level
NOTES:
1. Bits P3_0 and P3_2 in the P3 register are unavailable on this MCU.
If it is necessary to set bits P3_0 and P3_2, set to 0 (“L” level). When read, the content is 0.
2. Bits P4_0, P4_1, P4_3, and P4_4, in the P4 register are unavailable on this MCU.
If it is necessary to set bits P4_0, P4_1, P4_3, and P4_4, set to 0 (“L” level). When read, the content is 0.
3. Bits P5_0 to P5_2, P5_5 to P5_7 in the P5 register are unavailable on this MCU.
If it is necessary to set bits P5_0 to P5_2, P5_5 to P5_7, set to 0 (“L” level). When read, the content is 0.
Figure 7.9
Pi (i = 0, 1, and 3 to 5) Register
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Pin Select Register 1
7. Programmable I/O Ports
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0 1
Symbol
Address
00F5h
After Reset
00h
PINSR1
Bit Symbol
Bit Name
TXD1/RXD1 pin select bit(1)
Function
RW
RW
b1 b0
0 0 : P3_7(TXD1/RXD1)
0 1 : P3_7(TXD1), P4_5(RXD1)
1 0 : P3_6(TXD1/RXD1)
1 1 : Do not set.
UART1SEL0
UART1SEL1
RW
—
(b2)
Reserved bit
Reserved bits
Set to 1. When read, the content is 0.
Set to 0. When read, the content is 0.
RW
RW
—
(b7-b3)
NOTE:
1. The UART1 pins can be selected by using bits U1PINSEL, TXD1SEL and TXD1EN in the PMR register. Refer to
Figure
.
7.11 PMR Regis ter
Pin Select Register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
0 0 0 0 0 0
Symbol
Address
00F6h
After Reset
00h
Function
PINSR2
Bit Symbol
—
Bit Name
Reserved bits
RW
RW
Set to 0. When read, the content is 0.
(b5-b0)
TRBO pin select bit
Reserved bit
0 : P3_1
1 : P1_3
TRBOSEL
RW
RW
—
(b7)
Set to 0. When read, the content is 0.
Pin Select Register 3
b7 b6 b5 b4 b3 b2 b1 b0
1
1 1 1
Symbol
Address
00F7h
After Reset
00h
Function
PINSR3
Bit Symbol
—
Bit Name
Reserved bits
RW
RW
Set to 1. When read, the content is 0.
(b2-b0)
TRCIOC pin select bit
TRCIOD pin select bit
Reserved bit
0 : P5_3
1 : P3_4
TRCIOCSEL
TRCIODSEL
RW
RW
RW
—
0 : P5_4
1 : P3_5
—
(b5)
Set to 1. When read, the content is 0.
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Figure 7.10
Registers PINSR1, PINSR2, and PINSR3
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7. Programmable I/O Ports
Port Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00F8h
After Reset
00h
PMR
Bit Symbol
Bit Name
Function
RW
RW
____
0 : P1_5, P1_7
1 : P3_6
INT1 pin select bit
INT1SEL
—
(b2-b1)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
SSI pin select bit
0 : P3_3
1 : P1_6
SSISEL
U1PINSEL
TXD1SEL
TXD1EN
IICSEL
RW
RW
RW
RW
RW
TXD1 pin sw itch bit(1)
Port/TXD1 pin sw itch bit(1)
TXD1/RXD1 select bit(1)
SSU / I2C bus pin sw itch bit
0 : P0_0
1 : P3_6, P3_7
0 : Programmable I/O port
1 : TXD1
0 : RXD1
1 : TXD1
0 : Selects SSU function
1 : Selects I2C bus function
NOTE:
1. The UART1 pins can be selected by using bits U1PINSEL, TXD1SEL and TXD1EN, and bits UART1SEL1 and
UART1SEL0 in the PINSR1 register.
Pin Function
PINSR1 Register
UART1SEL1,
PMR Register
U1PINSEL bit TXD1SEL bit
TXD1EN bit
UART1SEL0 bit
P3_7(TXD1)
P3_7(RXD1)
P0_0(TXD1)
P3_7(TXD1)
P4_5(RXD1)
P3_6(TXD1)
P3_6(RXD1)
P0_0(TXD1)
1
0
×
×
0
1
×
00b
01b
1
1
×
×
1
0
×
×
0
×
1
10b
×: 0 or 1
Figure 7.11
PMR Register
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Pull-Up Control Register 0
7. Programmable I/O Ports
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
Address
00FCh
After Reset
00h
PUR0
Bit Symbol
PU00
Bit Name
Function
RW
RW
RW
RW
RW
P0_0 to P0_3 pull-up(1)
P0_4 to P0_7 pull-up(1)
P1_0 to P1_3 pull-up(1)
P1_4 to P1_7 pull-up(1)
Reserved bits
0 : Not pulled up
1 : Pulled up
PU01
PU02
PU03
—
Set to 0. When read, the content is 0.
RW
(b5-b4)
PU06
PU07
P3_1 and P3_3 pull-up(1)
P3_4 to P3_7 pull-up(1)
0 : Not pulled up
1 : Pulled up
RW
RW
NOTE:
1. When this bit is set to 1 (pulled up), the pin w hose direction bit is set to 0 (input mode) is pulled up.
Pull-Up Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
0 0
0
Symbol
PUR1
Bit Symbol
Address
00FDh
After Reset
00h
Function
Bit Name
RW
RW
—
(b0)
Reserved bit
Set to 0. When read, the content is 0.
PU11
PU12
PU13
P4_5 pull-up(1)
P5_3 pull-up(1)
P5_4 pull-up(1)
Reserved bits
0 : Not pulled up
1 : Pulled up
RW
RW
RW
—
(b5-b4)
Set to 0. When read, the content is 0.
RW
—
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. When this bit is set to 1 (pulled up), the pin w hose direction bit is set to 0 (input mode) is pulled up.
Figure 7.12
Registers PUR0 and PUR1
Port P1 Drive Capacity Control Register (For N, D Version Only)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
P1DRR
Address
00FEh
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
RW
RW
RW
RW
RW
RW
RW
P1DRR0 P1_0 drive capacity
P1DRR1 P1_1 drive capacity
P1DRR2 P1_2 drive capacity
P1DRR3 P1_3 drive capacity
P1DRR4 P1_4 drive capacity
P1DRR5 P1_5 drive capacity
P1DRR6 P1_6 drive capacity
P1DRR7 P1_7 drive capacity
Set P1 output transistor drive capacity
0 : Low
1 : High(1)
NOTE:
1. Both “H” and “L” output are set to high drive capacity.
Figure 7.13
P1DRR Register
Rev.2.10 Sep 26, 2008 Page 64 of 453
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7. Programmable I/O Ports
7.4
Port Setting
Table 7.4 to Table 7.40 list the port setting.
Table 7.4
Port P0_0/AN7/(TXD1)
Register
Bit
PD0
U1MR
ADCON0
Function
PD0_0
SMD2
SMD1
SMD0
CH2
X
CH1
CH0
X
ADGSEL0
Input port(1, 2)
0
1
0
X
X
X
0
X
X
X
X
X
X
1
0
1
0
X
X
1
X
X
0
Output port(1)
X
X
A/D converter input (AN7)(1)
1
1
Setting
value
0
1
TXD1 output(3, 4)
X
X
X
X
X
1
X: 0 or 1
NOTES:
1. When the U1PINSEL bit is set to 0 (P0_0) and TXD1SEL bit is set to 1 (TXD1) in the PMR register, set bits SMD2 to SMD0 in
the U1MR register to 000b (serial interface disabled).
2. Pulled up by setting the PU00 bit in the PUR0 register to 1.
3. This is enabled when bits UART1SEL1 and UART1SEL0 in the PINSR1 register are set to 00b or 10b, and the U1PINSEL bit
is set to 0 (P0_0) and TXD1SEL bit is set to 1 (TXD1) in the PMR register.
4. N-channel open drain output by setting the NCH bit in the U1C0 register to 1.
Table 7.5
Port P0_1/AN6
Register
Bit
PD0
ADCON0
Function
PD0_1
CH2
X
CH1
X
CH0
X
ADGSEL0
Input port(1)
Output port
0
1
0
X
X
0
Setting
value
X
X
X
1
1
0
A/D converter input (AN6)
X: 0 or 1
NOTE:
1. Pulled up by setting the PU00 bit in the PUR0 register to 1.
Table 7.6
Port P0_2/AN5
Register
Bit
PD0
ADCON0
Function
PD0_2
CH2
X
CH1
X
CH0
X
ADGSEL0
Input port(1)
0
1
0
X
X
0
Setting
value
X
X
X
Output port
1
0
1
A/D converter input (AN5)
X: 0 or 1
NOTE:
1. Pulled up by setting the PU00 bit in the PUR0 register to 1.
Table 7.7
Port P0_3/AN4
Register
Bit
PD0
ADCON0
Function
PD0_3
CH2
X
CH1
X
CH0
X
ADGSEL0
Input port(1)
0
1
0
X
X
0
Setting
value
X
X
X
Output port
1
0
0
A/D converter input (AN4)
X: 0 or 1
NOTE:
1. Pulled up by setting the PU00 bit in the PUR0 register to 1.
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7. Programmable I/O Ports
Table 7.8
Port P0_4/AN3/TREO
Register
Bit
PD0
TRECR1
ADCON0
Function
PD0_4
TOENA
CH2
X
CH1
X
CH0
X
ADGSEL0
Input port(1)
0
1
0
X
0
0
0
1
X
X
0
X
X
X
Output port
Setting
value
0
1
1
A/D converter input (AN3)
TREO output
X
X
X
X
X: 0 or 1
NOTE:
1. Pulled up by setting the PU01 bit in the PUR0 register to 1.
Table 7.9
Port P0_5/AN2/CLK1
Register
Bit
PD0
U1MR
SMD1 SMD0 CKDIR
ADCON0
CH1 CH0 ADGSEL0
Function
PD0_5
SMD2
CH2
X
Other than 001b
X
1
X
X
X
1
X
X
X
0
X
X
X
0
Input port(1)
0
X
X
X
X
1
0
X
0
Other than 001b
X
X
0
X
Output port
Setting
value
Other than 001b
0
A/D converter input (AN2)
CLK1 output
0
0
1
X
X
X
X
X
X
X
CLK1 input(1)
X
X
X
1
X
X: 0 or 1
NOTE:
1. Pulled up by setting the PU01 bit in the PUR0 register to 1.
Table 7.10
Port P0_6/AN1
Register
Bit
PD0
ADCON0
Function
PD0_6
CH2
X
CH1
X
CH0
X
ADGSEL0
Input port(1)
Output port
0
1
0
X
X
0
Setting
value
X
X
X
0
0
1
A/D converter input (AN1)
X: 0 or 1
NOTE:
1. Pulled up by setting the PU01 bit in the PUR0 register to 1.
Table 7.11
Port P0_7/AN0
Register
Bit
PD0
ADCON0
Function
PD0_7
CH2
X
CH1
X
CH0
X
ADGSEL0
Input port(1)
0
1
0
X
X
0
Setting
value
X
X
X
Output port
0
0
0
A/D converter input (AN0)
X: 0 or 1
NOTE:
1. Pulled up by setting the PU01 bit in the PUR0 register to 1.
Table 7.12
Port P1_0/KI0/AN8
Register
Bit
PD1
KIEN
ADCON0
CH1 CH0
Function
PD1_0
KI0EN
CH2
X
ADGSEL0
Input port(1)
Output port
0
1
0
0
X
X
X
0
X
X
X
0
X
X
X
1
X
Setting
value
KI0 input(1)
0
0
1
0
X
1
A/D converter input (AN8)
X: 0 or 1
NOTE:
1. Pulled up by setting the PU02 bit in the PUR0 register to 1.
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7. Programmable I/O Ports
Table 7.13
Port P1_1/KI1/AN9/TRCIOA/TRCTRG
Register
Bit
PD1
KIEN
Timer RC Setting
−
ADCON0
Function
PD1_1 KI1EN
CH2 CH1 CH0 ADGSEL0
Input port(1)
0
1
0
0
0
0
Other than TRCIOA usage conditions
Other than TRCIOA usage conditions
Other than TRCIOA usage conditions
X
X
1
X
X
0
X
X
1
X
X
1
Output port
A/D converter input (AN9)
Setting
value
KI1 input(1)
0
1
Other than TRCIOA usage conditions
X
X
X
X
Refer to Table 7.14 TRCIOA Pin
X
0
X
X
X
X
TRCIOA output
Setting
Refer to Table 7.14 TRCIOA Pin
TRCIOA input(1)
0
0
X
X
X
X
Setting
X: 0 or 1
NOTE:
1. Pulled up by setting the PU02 bit in the PUR0 register to 1.
Table 7.14
TRCIOA Pin Setting
Register
Bit
TRCOER TRCMR
TRCIOR0
TRCCR2
Function
EA
PWM2
IOA2
IOA1
IOA0
TCEG1
TCEG0
0
0
0
1
1
X
X
X
X
0
X
X
X
X
1
Timer waveform output
(output compare function)
0
1
X
0
1
1
0
1
X
X
X
Timer mode (input capture function)
Setting
value
1
X
X
PWM2 mode TRCTRG input
1
X
Other than above
Other than TRCIOA usage conditions
X: 0 or 1
Table 7.15
Port P1_2/KI2/AN10/TRCIOB
Register
Bit
PD1
KIEN
Timer RC Setting
ADCON0
Function
PD1_2 KI2EN
−
CH2 CH1 CH0 ADGSEL0
Input port(1)
0
1
0
0
0
0
Other than TRCIOB usage conditions
Other than TRCIOB usage conditions
Other than TRCIOB usage conditions
X
X
1
X
X
1
X
X
0
X
X
1
Output port
A/D converter input (AN10)
Setting
value
KI2 input(1)
0
1
Other than TRCIOB usage conditions
X
X
X
X
Refer to Table 7.16 TRCIOB Pin
X
0
X
X
X
X
TRCIOB output
Setting
Refer to Table 7.16 TRCIOB Pin
TRCIOB input(1)
0
0
X
X
X
X
Setting
X: 0 or 1
NOTE:
1. Pulled up by setting the PU02 bit in the PUR0 register to 1.
Table 7.16
TRCIOB Pin Setting
Register
Bit
TRCOER
TRCMR
TRCIOR0
Function
EB
0
PWM2
PWMB
IOB2
IOB1
IOB0
0
1
X
1
X
X
0
X
X
0
X
X
1
PWM2 mode waveform output
PWM mode waveform output
0
Timer waveform output (output compare
function)
0
1
1
0
0
Setting
value
0
1
X
0
1
1
X
X
Timer mode (input capture function)
Other than TRCIOB usage conditions
Other than above
X: 0 or 1
Rev.2.10 Sep 26, 2008 Page 67 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
Table 7.17
Port P1_3/KI3/AN11/(TRBO)
Register
Bit
PD1
KIEN
Timer RB Setting
−
ADCON0
Function
PD1_3 KI3EN
CH2 CH1 CH0 ADGSEL0
Input port(1)
Output port
0
1
0
0
0
0
Other than TRBO usage conditions
Other than TRBO usage conditions
Other than TRBO usage conditions
X
X
1
X
X
1
X
X
1
X
X
1
Setting
value
A/D converter input (AN11)
KI3 input
0
1
0
Other than TRBO usage conditions
X
X
X
X
X
X
X
X
Refer to Table 7.18 TRBO Pin
X
TRBO output
Setting
X: 0 or 1
NOTE:
1. Pulled up by setting the PU02 bit in the PUR0 register to 1.
Table 7.18
TRBO Pin Setting
Register
Bit
PINSR2
TRBIOC
TRBMR
Function
TOCNT(1)
TRBOSEL
TMOD1
TMOD0
1
1
1
1
0
0
0
1
0
1
1
0
1
0
1
1
Programmable waveform generation mode
Programmable one-shot generation mode
Programmable wait one-shot generation mode
P1_3 output port
Setting
value
Other than above
Other than TRBO usage conditions
NOTE:
1. Set the TOCNT bit in the TRBIOC register to 0 in modes except for programmable waveform generation mode.
Table 7.19
Port P1_4/TXD0
Register
Bit
PD1
U0MR
Function
PD1_4
SMD2
SMD1
SMD0
Input port(1)
Output port
0
1
0
0
0
1
1
1
0
0
0
0
0
1
0
0
1
0
1
0
Setting
value
TXD0 output(2)
X
X: 0 or 1
NOTES:
1. Pulled up by setting the PU03 bit in the PUR0 register to 1.
2. N-channel open drain output by setting the NCH bit in the U0C0 register to 1.
Rev.2.10 Sep 26, 2008 Page 68 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
Table 7.20
Port P1_5/RXD0/(TRAIO)/(INT1)
Register
PD1
TRAIOC
TRAMR
TMOD1
INTEN
TOPCR(3
Function
Bit
PD1_5
TIOSEL
TMOD2
TMOD0
INT1EN
)
0
1
1
0
1
0
1
1
1
1
X
1
0
X
0
X
0
0
0
1
X
0
0
X
0
X
X
X
1
0
X
0
X
X
0
0
X
X
X
0
0
1
1
Input port(1)
0
1
0
0
X
Output port
0
X
Setting
value
RXD0 input(1)
TRAIO input(1)
INT1(2)
Other than 001b
Other than 000b, 001b
0
0
0
0
0
0
1
TRAIO input/INT1(1, 2)
TRAIO pulse output
1
1
0
0
Other than 000b, 001b
1
X
0
0
1
X
X: 0 or 1
NOTES:
1. Pulled up by setting the PU03 bit in the PUR0 register to 1.
2. Set the INT1SEL bit in the PMR register to 0 (P1_5, P1_7).
3. Set the TOPCR bit in the TRAIOC register to 0 in modes except for pulse output mode.
Table 7.21
Port P1_6/CLK0/(SSI)
Clock Synchronous Serial I/O with Chip
Select (Refer to Table 16.4
Association between
Communication Modes and I/O Pins.)
Register
Bit
PD1
U0MR
PMR
Function(3)
PD1_6 CKDIR SMD2 SMD1 SMD0 IICSEL SSI output control
SSI input control
Input port(1)
0
1
X
X
0
X
X
X
X
X
X
X
0
0
0
0
0
1
0
0
0
0
0
0
1
Other than 001b
Output port
X
0
0
X
X
X
0
X
X
X
1
X
X
X
CLK0 output
CLK0 input(1)
SSI output(2)
SSI input(1, 2)
Setting
value
1
X
X
X
X
0
X: 0 or 1
NOTES:
1. Pulled up by setting the PU03 bit in the PUR0 register to 1.
2. Set the SSISEL bit in the PMR register to 1 (P1_6).
3. When the SOOS bit is set to 1 (N-channel open drain output) and BIDE bit is set to 0 (standard mode) in the SSMR2 register,
this pin is set to N-channel open drain output.
Table 7.22
Port P1_7/TRAIO/INT1
Register
Bit
PD1
TRAIOC
TRAMR
INTEN
Function
TOPCR(3)
PD1_7
0
TIOSEL
TMOD2
TMOD1
TMOD0
INT1EN
1
0
0
1
0
0
0
0
X
1
0
X
0
0
0
1
X
0
0
X
0
X
0
0
X
0
X
1
0
X
0
X
0
0
X
X
0
1
1
Input port(1)
Output port
1
Setting
value
TRAIO input(1)
INT1(2)
Other than 000b, 001b
0
0
0
0
0
0
1
TRAIO input/INT1(1, 2)
TRAIO pulse output
0
0
0
0
Other than 000b, 001b
1
X
0
0
1
X
X: 0 or 1
NOTES:
1. Pulled up by setting the PU03 bit in the PUR0 register to 1.
2. Set the INT1SEL bit in the PMR register to 0 (P1_5, P1_7).
Rev.2.10 Sep 26, 2008 Page 69 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
3. Set the TOPCR bit in the TRAIOC register to 0 in modes except for pulse output mode.
Table 7.23
Port P3_1/TRBO
Register
Bit
PD3
Timer RB Setting
Function
PD3_1
−
Input port(1)
Output port
TRBO output
0
1
X
Other than TRBO usage conditions
Other than TRBO usage conditions
Refer to Table 7.24 TRBO Pin Setting
Setting
value
X: 0 or 1
NOTE:
1. Pulled up by setting the PU06 bit in the PUR0 register to 1.
Table 7.24
TRBO Pin Setting
Register
Bit
PINSR2
TRBIOC
TOCNT(1)
TRBMR
Function
TRBOSEL
TMOD1
TMOD0
0
0
0
0
0
0
0
1
0
1
1
0
1
0
1
1
Programmable waveform generation mode
Programmable one-shot generation mode
Programmable wait one-shot generation mode
Setting
value
P3_1 output port
Other than above
Other than TRBO usage conditions
NOTE:
1. Set the TOCNT bit in the TRBIOC register to 0 in modes except for programmable waveform generation mode.
Table 7.25
Port P3_3/INT3/SSI/TRCCLK
Clock Synchronous Serial I/O with Chip
Select (Refer to Table 16.4
Association between
Communication Modes and I/O Pins.)
Register
Bit
PD3
PMR
TRCCR1
INTEN
Function(3)
PD3_3 IICSEL SSI output control
SSI input control
TCK2 TCK1 TCK0 INT3EN
Input port(1)
Output port
0
1
0
X
X
X
0
0
0
0
0
0
Other than 101b
Other than 101b
Other than 101b
0
0
1
INT3 input(1)
TRCCLK input(1)
SSI output(2)
SSI input(2)
Setting
value
0
X
X
X
0
0
0
1
0
0
0
1
1
0
1
0
0
0
Other than 101b
Other than 101b
X: 0 or 1
NOTES:
1. Pulled up by setting the PU06 bit in the PUR0 register to 1.
2. Set the SSISEL bit in the PMR register to 0 (P3_3).
3. When the SOOS bit is set to 1 (N-channel open drain output) and BIDE bit is set to 0 (standard mode) in the SSMR2 register,
this pin is set to N-channel open drain output.
Table 7.26
Port P3_4/SDA/SCS/(TRCIOC)
Register
Bit
PD3
PMR
ICCR1
SSMR2
Timer RC setting
−
Function(2)
Input port(1)
Output port
PD3_4
IICSEL
ICE
X
CSS1
CSS0
0
1
0
1
X
X
0
0
0
0
0
0
0
0
0
0
0
0
Other than TRCIOC usage conditions
Other than TRCIOC usage conditions
Other than TRCIOC usage conditions
Other than TRCIOC usage conditions
0
1
0
X
0
Setting
value
X
0
0
Refer to Table 7.27 TRCIOC Pin Setting TRCIOC output
TRCIOC input(1)
0
Refer to Table 7.27 TRCIOC Pin Setting
Other than TRCIOC usage conditions
Other than TRCIOC usage conditions
Other than TRCIOC usage conditions
X
0
0
1
X
X
1
1
1
0
1
X
SCS output
SCS input(1)
X
X
X
SDA input/output
X: 0 or 1
NOTES:
1. Pulled up by setting the PU07 bit in the PUR0 register to 1.
2. N-channel open drain output by setting the CSOS bit in the SSMR2 register to 1 (N-channel open drain output).
Rev.2.10 Sep 26, 2008 Page 70 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
Table 7.27
TRCIOC Pin Setting
Register
Bit
PINSR3
TRCOER
TRCMR
TRCIOR1
Function
TRCIOCSEL
EC
0
PWM2 PWMC
IOC2
IOC1
IOC0
1
1
1
1
1
1
1
X
0
0
X
0
1
X
1
PWM mode waveform output
Timer waveform output (output compare
function)
0
1
0
X
Setting
value
0
1
1
0
1
X
X
Timer mode (input capture function)
Other than TRCIOC usage conditions
Other than above
X: 0 or 1
Table 7.28
Port P3_5/SCL/SSCK/(TRCIOD)
Clock Synchronous Serial I/O with Chip
Select (Refer to Table 16.4
Association between Communication
Modes and I/O Pins.)
Register
Bit
PD3
PMR ICCR1
Timer RC setting
Function(2)
SSCK output
control
SSCK input
control
PD3_5 IICSEL
ICE
X
0
−
Other than TRCIOD
usage conditions
0
0
0
0
0
0
0
1
0
X
0
0
0
0
0
0
0
1
X
Input port(1)
0
Other than TRCIOD
usage conditions
1
Other than TRCIOD
usage conditions
0
X
0
1
Output port
Other than TRCIOD
usage conditions
1
Setting
value
Refer to Table 7.29
TRCIOD Pin Setting
X
0
X
X
0
0
1
0
TRCIOD output
TRCIOD input(1)
SSCK output(2)
SSCK input(1)
Refer to Table 7.29
TRCIOD Pin Setting
0
Other than TRCIOD
usage conditions
X
X
X
X
X
1
Other than TRCIOD
usage conditions
Other than TRCIOD
usage conditions
SCL input/output
X: 0 or 1
NOTES:
1. Pulled up by setting the PU07 bit in the PUR0 register to 1.
2. N-channel open drain output by setting the SCKOS bit in the SSMR2 register to 1 (N-channel open drain output).
Table 7.29
TRCIOD Pin Setting
Register
Bit
PINSR3
TRCOER
TRCMR
TRCIOR1
Function
TRCIODSEL
EC
0
PWM2
PWMD
1
IOD2
IOD1
IOD0
1
1
1
1
1
1
X
0
0
X
0
1
X
1
PWM mode waveform output
Timer waveform output (output
compare function)
0
1
0
0
X
Setting
value
0
1
1
1
X
X
Timer mode (input capture function)
Other than TRCIOD usage conditions
Other than above
X: 0 or 1
Rev.2.10 Sep 26, 2008 Page 71 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
Table 7.30
Port P3_6/(TXD1)/(RXD1)/(INT1)
Register
Bit
PD3
PMR
U1MR
INTEN
Function
PD3_6
TXD1EN
SMD2
SMD1
SMD0
INT1EN
0
X
0
X
0
X
0
X
0
0
1
1
1
X
X
0
X
0
X
0
0
0
0
1
X
X
0
X
0
X
0
1
0
1
0
X
0
0
0
0
1
1
0
0
0
0
0
Input port(1)
0
1
0
Output port
X
0
Setting
value
INT1 input(1, 2)
X
TXD1 output(3, 4)
RXD1 input(1)
X
0
1
0
X: 0 or 1
NOTES:
1. Pulled up by setting the PU07 bit in the PUR0 register to 1.
2. Set the INT1SEL bit in the PMR register to 1 (P3_6).
3. Set bits UART1SEL1 and UART1SEL0 in the PINSR1 register to 10b.
4. N-channel open drain output by setting the NCH bit in the U1C0 register to 1.
Table 7.31
Port P3_7/TRAO/SSO/RXD1/(TXD1)
Clock Synchronous Serial I/O with Chip
Select (Refer to Table 16.4
Association between
Communication Modes and I/O Pins.)
Register
Bit
PD3
PMR
TRAMR
UART1 setting
Function(3)
PD3_7 IICSEL SSO output control SSO input control TOENA
−
Other than TXD1, RXD1
usage conditions
Input port(1)
0
1
X
X
0
0
0
0
0
0
Other than TXD1, RXD1
usage conditions
Output port
Refer to Table 7.32 Port
P3_7 UART1 Setting
Condition
TXD1 output(4)
X
0
X
X
0
0
0
0
X
0
Setting
value
Refer to Table 7.32 Port
P3_7 UART1 Setting
Condition
RXD1 input(1)
Other than TXD1, RXD1
usage conditions
X
X
X
X
0
0
0
1
0
0
0
1
1
X
X
TRAO output
SSO output(2)
SSO input(2)
Other than TXD1, RXD1
usage conditions
Other than TXD1, RXD1
usage conditions
X: 0 or 1
NOTES:
1. Pulled up by setting the PU07 bit in the PUR0 register to 1.
2. Set the SSISEL bit in the PMR register to 0 (P3_3).
3. N-channel open drain output by setting the SOOS bit in the SSMR2 register to 1 (N-channel open drain output).
4. N-channel open drain output by setting the NCH bit in the U1C0 register to 1.
Rev.2.10 Sep 26, 2008 Page 72 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
Table 7.32
Port P3_7 UART1 Setting Condition
Register
Bit
PINSR1
PMR
U1MR
Function
UART1SEL1 UART1SEL0 U1PINSEL TXD1SEL TXD1EN SMD2 SMD1 SMD0
0
1
1
1
0
1
1
1
X
0
0
0
1
0
0
0
1
X
1
0
1
0
1
0
1
0
X
0
X
X
1
1
TXD1 output
RXD1 input
0
Setting
value
1
0
1
X
0
X
X
Other than TXD1,
RXD1 usage conditions
Other than above
X: 0 or 1
Table 7.33
Port P4_2/VREF
Register
Bit
ADCON1
Function
VCUT
0
1
Input port
Setting
value
Input port/VREF input
Table 7.34
Port P4_5/INT0/(RXD1)
Register
Bit
PD4
INTEN
PINSR1
UART1SEL1
PMR
U1PINSEL
Function
PD4_5
INT0EN
UART1SEL0
Other than 011b
Other than 011b
Other than 011b
Input port(1)
Output port
0
1
0
0
Setting
value
INT0 input(1)
RXD1(1)
0
0
1
0
0
1
1
NOTE:
1. Pulled up by setting the PU11 bit in the PUR1 register to 1.
Rev.2.10 Sep 26, 2008 Page 73 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
Table 7.35
Port P4_6/XIN/XCIN
Register
CM0
CM1
Circuit specifications
Oscillation Feedback
Function
Bit
CM01 CM04 CM05 CM13 CM12 CM11 CM10
buffer
resistor
X
0
0
1
0
0
1
X
X
X
0
0
0
OFF
−
Input port
XIN clock oscillation (on-chip
feedback resistor enabled)
ON
ON
XIN clock oscillation (on-chip
feedback resistor disabled)
1
0
0
ON
OFF
OFF
OFF
ON
External clock input
X
XIN clock oscillation stop (on-chip
feedback resistor enabled)
ON
1
XIN clock oscillation stop (on-chip
feedback resistor disabled)
1
1
OFF
OFF
ON
OFF
OFF
ON
XIN clock oscillation stop (stop
mode)
1
0
1
Setting
value
XCIN clock oscillation (on-chip
feedback resistor enabled)(1)
XCIN clock oscillation (on-chip
feedback resistor disabled)(1)
External XCIN clock input(1)
XCIN clock oscillation stop (on-
chip feedback resistor enabled)(1)
XCIN clock oscillation stop (on-
chip feedback resistor disabled)(1)
XCIN clock oscillation stop (stop
mode)(1)
0
1
0
1
0
0
ON
OFF
OFF
OFF
ON
1
X
X
X
ON
1
1
OFF
OFF
OFF
OFF
X: 0 or 1
NOTE:
1. For N, D version only.
Table 7.36
Port P4_7/XOUT/XCOUT
Register
CM0
CM1
Circuit specifications
Oscillation Feedback
Function
Bit
CM01 CM04 CM05 CM13 CM12 CM11 CM10
buffer
resistor
X
0
1
0
X
X
0
0
0
1
OFF
−
Input port
XIN clock oscillation (on-chip
feedback resistor enabled)
ON
ON
0
XIN clock oscillation (on-chip
feedback resistor disabled)
1
0
0
ON
OFF
OFF
OFF
ON
External clock input
0
X
1
X
XIN clock oscillation stop (on-chip
feedback resistor enabled)
ON
1
XIN clock oscillation stop (on-chip
feedback resistor disabled)
XOUT pulled up(2)
1
1
OFF
OFF
ON
OFF
OFF
ON
Setting
value
XCIN clock oscillation (on-chip
feedback resistor enabled)(1, 2)
XCIN clock oscillation (on-chip
feedback resistor disabled)(1, 2)
0
1
0
1
0
0
ON
OFF
OFF
OFF
ON
External XCIN clock input(2)
0
1
1
X
X
X
XCIN clock oscillation stop (on-
chip feedback resistor enabled)(2)
XCIN clock oscillation stop (on-
chip feedback resistor disabled)(2)
ON
1
1
OFF
OFF
OFF
OFF
XCOUT pulled up(2)
X: 0 or 1
NOTES:
1. Since the XCIN-XCOUT oscillation buffer operates with internal step-down power, the XCOUT output level cannot be used as
the CMOS level signal directly.
2. For N, D version only.
Rev.2.10 Sep 26, 2008 Page 74 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
7. Programmable I/O Ports
Table 7.37
Port P5_3/TRCIOC
Register
Bit
PD5
Timer RC setting
−
Function
PD5_3
Input port(1)
Output port
0
1
X
0
Other than TRCIOC usage conditions
Other than TRCIOC usage conditions
Setting
value
Refer to Table 7.38 TRCIOC Pin Setting TRCIOC output
Refer to Table 7.38 TRCIOC Pin Setting
TRCIOC input(1)
X: 0 or 1
NOTE:
1. Pulled up by setting the PU12 bit in the PUR1 register to 1.
Table 7.38
TRCIOC Pin Setting
Register
Bit
PINSR3
TRCOER
TRCMR
TRCIOR1
Function
TRCIOCSEL
EC
0
PWM2
PWMC
1
IOC2
IOC1
IOC0
0
0
0
0
0
1
X
0
0
X
0
1
X
1
PWM mode waveform output
Timer waveform output (output
compare function)
0
1
0
0
X
Setting
value
0
1
1
1
X
X
Timer mode (input capture function)
Other than TRCIOC usage conditions
Other than above
X: 0 or 1
Table 7.39
Port P5_4/TRCIOD
Register
Bit
PD5
Timer RC setting
Function
PD5_4
−
Input port(1)
Output port
0
1
X
0
Other than TRCIOD usage conditions
Other than TRCIOD usage conditions
Setting
value
Refer to Table 7.40 TRCIOD Pin Setting TRCIOD output
TRCIOD input(1)
Refer to Table 7.40 TRCIOD Pin Setting
X: 0 or 1
NOTE:
1. Pulled up by setting the PU13 bit in the PUR1 register to 1.
Table 7.40
TRCIOD Pin Setting
Register
Bit
PINSR3
TRCOER
TRCMR
TRCIOR1
Function
TRCIODSEL
ED
0
PWM2
PWMD
1
IOD2
IOD1
IOD0
0
0
0
0
0
1
X
0
0
X
0
1
X
1
PWM mode waveform output
Timer waveform output (output
compare function)
0
1
0
0
X
Setting
value
0
1
1
1
X
X
Timer mode (input capture function)
Other than TRCIOD usage conditions
Other than above
X: 0 or 1
Rev.2.10 Sep 26, 2008 Page 75 of 453
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7. Programmable I/O Ports
7.5
Unassigned Pin Handling
Table 7.41 lists the Unassigned Pin Handling.
Table 7.41
Unassigned Pin Handling
Pin Name
Connection
Ports P0, P1, P3_1, P3_3 to P3_7, • After setting to input mode, connect each pin to VSS via a resistor
(2)
P4_3 to P4_5, P5_3, P5_4
(pull-down) or connect each pin to VCC via a resistor (pull-up).
(1, 2)
• After setting to output mode, leave these pins open.
(2)
Ports P4_6, P4_7
Port P4_2, VREF
Connect to VCC via a pull-up resistor
Connect to VCC
(2)
(3)
Connect to VCC via a pull-up resistor
RESET
NOTES:
1. If these ports are set to output mode and left open, they remain in input mode until they are switched
to output mode by a program. The voltage level of these pins may be undefined and the power
current may increase while the ports remain in input mode.
The content of the direction registers may change due to noise or program runaway caused by
noise. In order to enhance program reliability, the program should periodically repeat the setting of
the direction registers.
2. Connect these unassigned pins to the MCU using the shortest wire length (2 cm or less) possible.
3. When the power-on reset function is in use.
MCU
Port P0, P1,
P3_1, P3_3 to P3_7,
P4_3 to P4_5,
(Input mode )
:
:
:
:
(Input mode)
P5_3, P5_4
(Output mode)
Open
Port P4_6, P4_7
RESET(1)
Port P4_2/VREF
NOTE:
1. When the power-on reset function is in use.
Figure 7.14
Unassigned Pin Handling
Rev.2.10 Sep 26, 2008 Page 76 of 453
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8. Processor Mode
8. Processor Mode
8.1
Processor Modes
Single-chip mode can be selected as the processor mode.
Table 8.1 lists Features of Processor Mode. Figure 8.1 shows the PM0 Register and Figure 8.2 shows the PM1
Register.
Table 8.1
Features of Processor Mode
Accessible Areas
Processor Mode
Pins Assignable as I/O Port Pins
Single-chip mode
SFR, internal RAM, internal ROM All pins are I/O ports or peripheral
function I/O pins
Processor Mode Register 0(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0
Symbol
PM0
Address
0004h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
—
(b2-b0)
Reserved bits
Set to 0.
Softw are reset bit
The MCU is reset w hen this bit is set to 1.
When read, the content is 0.
PM03
RW
—
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. Set the PRC1 bit in the PRCR register to 1 (w rite enable) before rew riting the PM0 register.
Figure 8.1
PM0 Register
Processor Mode Register 1(1)
b7 b6 b5 b4 b3 b2 b1 b0
0
0 0
Symbol
PM1
Address
0005h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
—
(b1-b0)
Reserved bits
Set to 0.
WDT interrupt/reset sw itch bit
0 : Watchdog timer interrupt
1 : Watchdog timer reset(2)
PM12
RW
—
—
(b6-b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
(b7)
Reserved bit
Set to 0.
RW
NOTES:
1. Set the PRC1 bit in the PRCR register to 1 (w rite enable) before rew riting the PM1 register.
2. The PM12 bit is set to 1 by a program (It remains unchanged even if 0 is w ritten to it).
When the CSPRO bit in the CSPR register is set to 1 (count source protect mode enabled), the PM12 bit is
automatically set to 1.
Figure 8.2
PM1 Register
Rev.2.10 Sep 26, 2008 Page 77 of 453
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9.Bus
9. Bus
The bus cycles differ when accessing ROM/RAM, and when accessing SFR.
Table 9.1 lists Bus Cycles by Access Space of the R8C/26 Group and Table 9.2 lists Bus Cycles by Access Space of the
R8C/27 Group.
ROM/RAM and SFR are connected to the CPU by an 8-bit bus. When accessing in word (16-bit) units, these areas are
accessed twice in 8-bit units.
Table 9.3 lists Access Units and Bus Operations.
Table 9.1
Bus Cycles by Access Space of the R8C/26 Group
Access Area
Bus Cycle
2 cycles of CPU clock
1 cycle of CPU clock
SFR
ROM/RAM
Table 9.2
Bus Cycles by Access Space of the R8C/27 Group
Access Area
Bus Cycle
2 cycles of CPU clock
1 cycle of CPU clock
SFR/Data flash
Program ROM/RAM
Table 9.3
Access Units and Bus Operations
SFR, data flash
Area
ROM (program ROM), RAM
CPU clock
Even address
Byte access
CPU clock
Even
Data
Even
Odd
Address
Data
Address
Data
Data
Odd address
Byte access
CPU clock
CPU clock
Address
Data
Odd
Data
Address
Data
Data
Even address
Word access
CPU clock
CPU clock
Address
Data
Address
Data
Even
Data
Even+1
Data
Even
Data
Even+1
Data
Odd address
Word access
CPU clock
CPU clock
Address
Data
Odd
Odd+1
Data
Odd+1
Data
Odd
Address
Data
Data
Data
However, only following SFRs are connected with the 16-bit bus:
Timer RC: registers TRC, TRCGRA, TRCGRB, TRCGRC, and TRCGRD
Therefore, when accessing in word (16-bit) unit, 16-bit data is accessed at a time. The bus operation is the same as
“Area: SFR, data flash, even address byte access” in Table 9.3 Access Units and Bus Operations, and 16-bit data is
accessed at a time.
Rev.2.10 Sep 26, 2008 Page 78 of 453
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10. Clock Generation Circuit
10. Clock Generation Circuit
The clock generation circuit has:
• XIN clock oscillation circuit
• XCIN clock oscillation circuit (For N, D version only)
• Low-speed on-chip oscillator
• High-speed on-chip oscillator
However, use one of the XIN clock oscillation circuit or the XCIN clock oscillation circuit because they share the
XIN/XCIN pin and the XOUT/XCOUT pin. (For J, K version, the XCIN clock oscillation circuit cannot be used.)
Table 10.1 lists the Specifications of Clock Generation Circuit. Figure 10.1 shows a Clock Generation Circuit. Figures
10.2 to 10.9 show clock associated registers. Figure 10.10 shows a Procedure for Enabling Reduced Internal Power
Consumption Using VCA20 bit.
Table 10.1
Specifications of Clock Generation Circuit
On-Chip Oscillator
XCIN Clock Oscillation
XIN Clock Oscillation
Circuit
Item
High-Speed On-Chip
Low-Speed On-Chip
Oscillator
Circuit
(For N, D Version Only)
Oscillator
Applications
• CPU clock source
• Peripheral function • Peripheral function
clock source
• CPU clock source
• CPU clock source
• Peripheral function
clock source
• CPU clock source
• Peripheral function
clock source
clock source
• CPU and peripheral
function clock
• CPU and peripheral
function clock
sources when XIN
sources when XIN
clock stops oscillating clock stops oscillating
Approx. 40 MHz(5)
Clock frequency 0 to 20 MHz
32.768 kHz
Approx. 125 kHz
Connectable
oscillator
• Ceramic resonator
• Crystal oscillator
XIN, XOUT(1)
• Crystal oscillator
−
−
XCIN, XCOUT(1)
Usable
−
−
(1)
(1)
Oscillator
connect pins
Oscillation stop, Usable
restart function
Usable
Stop
−
Usable
Oscillate
−
Oscillator status Stop
after reset
Stop
Others
• Externally
generated clock can
be input(2, 3)
• On-chip feedback
resistor RfXIN
(connected/ not
connected,
• Externally generated
clock can be input(4)
• On-chip feedback
resistor RfXCIN
(connected/ not
connected, selectable)
selectable)
NOTES:
1. These pins can be used as P4_6 or P4_7 when using the on-chip oscillator clock as the CPU clock while the
XIN clock oscillation circuit and XCIN clock oscillation circuit is not used.
2. Set the CM01 bit in the CM0 register to 0 (XIN clock), the CM05 bit in the CM0 register to 1 (XIN clock stopped),
and the CM13 bit in the CM1 register to 1 (XIN-XOUT pin) when an external clock is input.
3. When 32.768 kHz is used as an external clock, set the CM01 bit in the CM0 register to 1 (XCIN clock). In other
cases, set the CM01 bit in the CM0 register to 0 (XIN clock).
4. Set the CM01 bit in the CM0 register to 1 (XCIN clock) and the CM04 bit in the CM0 register to 1 (XCIN clock
oscillator) when an external clock is input.
5. The clock frequency is automatically set to up to 20 MHz by a divider when using the high-speed on-chip
oscillator as the CPU clock source.
Rev.2.10 Sep 26, 2008 Page 79 of 453
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10. Clock Generation Circuit
Clock prescaler
fC4
fC32
fC
1/4
1/8
FRA1 register
Frequency adjustable
High-speed
on-chip
oscillator
FRA00
fOCO40M
FRA2 register
Divider
fOCO128
Divider
SSU /
Watchdog
timer
I2C bus
fOCO-F
A/D
converter
On-chip oscillator
clock
FRA01 = 1
FRA01 = 0
INT0
Timer RA Timer RB Timer RC Timer RE
UART0 UART1
fOCO
Stop signal
Low-speed
on-chip
oscillator
Power-on
reset circuit
CM14
fOCO-S
Voltage
detection
circuit
XOUT/XCOUT(1)
XIN/XCIN(1)
CM01 = 0
CM13
CM05
f1
b
f2
f4
f8
c
Oscillation
stop
detection
d
e
g
OCD2 = 1
OCD2 = 0
f32
CM01 = 0
a
CPU clock
Divider
CM04
CM01
XIN
clock
CM01 = 1
XCIN
clock
System clock
CM02
CM10 = 1 (stop mode)
Q
Q
S
R
RESET
Power-on reset
Software reset
Interrupt request
g
e
d
c
b
S
R
1/2
1/2
a
1/2
1/2
1/2
WAIT instruction
CM06 = 0
CM17 to CM16 = 11b
CM06 = 1
h
CM06 = 0
CM17 to CM16 = 10b
CM01, CM02, CM04, CM05, CM06: Bits in CM0 register
CM10, CM13, CM14, CM16, CM17: Bits in CM1 register
OCD0, OCD1, OCD2: Bits in OCD register
CM06 = 0
CM17 to CM16 = 01b
FRA00, FRA01: Bits in FRA0 register
CM06 = 0
CM17 to CM16 = 00b
Detail of divider
Oscillation Stop Detection Circuit
Forcible discharge when OCD0 = 0
Pulse generation
circuit for clock
Charge,
discharge
circuit
Oscillation stop detection
interrupt generation
circuit detection
XIN clock
edge detection and
charge, discharge
control circuit
Oscillation stop detection,
Watchdog timer,
Voltage monitor 1 interrupt,
Voltage monitor 2 interrupt
Watchdog timer
OCD1
interrupt
Voltage monitor 1
interrupt
Voltage monitor 2
interrupt
OCD2 bit switch signal
CM14 bit switch signal
NOTE:
1. For J, K version, the XCIN clock oscillation circuit cannot be used.
Figure 10.1
Clock Generation Circuit
Rev.2.10 Sep 26, 2008 Page 80 of 453
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10. Clock Generation Circuit
System Clock Control Register 0(1)
b7 b6 b5 b4 b3 b2 b1 b0
0
0
Symbol
CM0
Bit Symbol
Address
0006h
After Reset
01101000b
Function
Bit Name
RW
RW
—
(b0)
Reserved bit
Set to 0.
XIN-XCIN sw itch bit(12)
0 : XIN clock
1 : XCIN clock
CM01
CM02
RW
RW
WAIT peripheral function clock 0 : Peripheral function clock does not stop
stop bit
in w ait mode
1 : Peripheral function clock stops in w ait
mode
XCIN-XCOUT drive capacity
select bit(2)
0 : Low
1 : High
CM03
CM04
CM05
CM06
RW
RW
RW
RW
RW
XCIN clock (XCIN-XCOUT)
oscillate bit(3, 4, 5, 12)
0 : XCIN clock stops
1 : XCIN clock oscillates(6, 7)
0 : XIN clock oscillates(9)
1 : XIN clock stops(10)
XIN clock (XIN-XOUT)
stop bit(3, 8)
System clock division select bit 0 : CM16, CM17 enabled
0(11)
1 : Divide-by-8 mode
—
(b7)
Reserved bit
Set to 0.
NOTES:
1. Set the PRC0 bit in the PRCR register to 1 (w rite enable) before rew riting the CM0 register.
2. The MCU enters stop mode, the CM03 bit is set to 1 (high). Rew rite the CM03 bit w hile the XCIN clock oscillation
stabilizes.
3. P4_6 and P4_7 can be used as input ports w hen the CM04 bit is set to 0 (XCIN clock stops), the CM05 bit is set to 1
(XIN clock stops) and the CM13 bit in the CM1 register is set to 0 (P4_6, P4_7).
4. The CM04 bit can be set to 1 by a program but cannot be set to 0.
5. When the CM10 bit is set to 1 (stop mode) and the CM04 bit is set to 1 (XCIN clock oscillates), the XCOUT (P4_7) pin
goes “H”.
When the CM04 bit is set to 0 (XCIN clock stops), P4_7 (XCOUT) enters input mode.
6. To use the XCIN clock, set the CM04 bit to 1. Also, set ports P4_6 and P4_7 as input ports w ithout pull-up.
7. Set the CM01 bit to 1 (XCIN clock).
8. The CM05 bit stops the XIN clock w hen the high-speed on-chip oscillator mode, low -speed on-chip oscillator mode is
selected. Do not use this bit to detect w hether the XIN clock is stopped. To stop the XIN clock, set the bits in the
follow ing order:
(a) Set bits OCD1 to OCD0 in the OCD register to 00b.
(b) Set the OCD2 bit to 1 (selects on-chip oscillator clock).
9. Set the CM01 bit to 0 (XIN clock).
10. During external clock input, only the clock oscillation buffer is turned off and clock input is acknow ledged.
11. When entering stop mode, the CM06 bit is set to 1 (divide-by-8 mode).
12. For J, K version, the XCIN clock oscillation circuit cannot be used. Do not set to 1.
Figure 10.2
CM0 Register
Rev.2.10 Sep 26, 2008 Page 81 of 453
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10. Clock Generation Circuit
System Clock Control Register 1(1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
CM1
Bit Symbol
Address
0007h
After Reset
00100000b
Function
Bit Name
RW
RW
All clock stop control bit(4, 7, 8)
0 : Clock operates
1 : Stops all clocks (stop mode)
XIN-XOUT on-chip feedback resistor 0 : On-chip feedback resistor enabled
CM10
CM11
CM12
CM13
CM14
CM15
RW
RW
RW
RW
RW
select bit
1 : On-chip feedback resistor disabled
XCIN-XCOUT on-chip feedback
resistor select bit(10)
Port XIN-XOUT sw itch bit(7, 9)
0 : On-chip feedback resistor enabled
1 : On-chip feedback resistor disabled
0 : Input ports P4_6, P4_7
1 : XIN-XOUT pin
Low -speed on-chip oscillation stop 0 : Low -speed on-chip oscillator on
bit(5, 6, 8)
1 : Low -speed on-chip oscillator off
XIN-XOUT drive capacity select bit(2) 0 : Low
1 : High
Systemclock division select bits 1(3)
b7 b6
0 0 : No division mode
CM16
CM17
RW
RW
0 1 : Divide-by-2 mode
1 0 : Divide-by-4 mode
1 1 : Divide-by-16 mode
NOTES:
1. Set the PRC0 bit in the PRCR register to 1 (w rite enable) before rew riting the CM1 register.
2. When entering stop mode, the CM15 bit is set to 1 (drive capacity high).
3. When the CM06 bit is set to 0 (bits CM16, CM17 enabled), bits CM16 to CM17 are enabled.
4. If the CM10 bit is set to 1 (stop mode), the on-chip feedback resistor is disabled.
5. When the OCD2 bit is set to 0 (XIN clock selected), the CM14 bit is set to 1 (low -speed on-chip oscillator stopped).
When the OCD2 bit is set to 1 (on-chip oscillator clock selected), the CM14 bit is set to 0 (low -speed on-chip
oscillator on). It remains unchanged even if 1 is w ritten to it.
6. When using the voltage monitor 1 interrupt or voltage monitor 2 interrupt (w hen using the digital filter), set the CM14
bit to 0 (low -speed on-chip oscillator on).
7. When the CM10 bit is set to 1 (stop mode) and the CM13 bit is set to 1 (XIN-XOUT pin), the XOUT (P4_7) pin goes “H”.
When the CM13 bit is set to 0 (input ports, P4_6, P4_7), P4_7 (XOUT) enters input mode.
8. In count source protect mode (refer to
), the value remains
13.2 Count Source Protection Mode Enabled
unchanged even if bits CM10 and CM14 are set.
9. Once the CM13 bit is set to 1 by a program, it cannot be set to 0.
10. For J, K version, the XCIN clock oscillation circuit cannot be used. Set to 0.
Figure 10.3
CM1 Register
Rev.2.10 Sep 26, 2008 Page 82 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
10. Clock Generation Circuit
Oscillation Stop Detection Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0
Symbol
Address
000Ch
After Reset
00000100b
Function
OCD
Bit Symbol
Bit Name
RW
RW
Oscillation stop detection enable 0 : Oscillation stop detection function
bit(7)
disabled(2)
OCD0
1 : Oscillation stop detection function
enabled
Oscillation stop detection
interrupt enable bit
Systemclock select bit(4)
0 : Disabled(2)
1 : Enabled
0 : Selects XIN clock(7)
1 : Selects on-chip oscillator clock(3)
OCD1
OCD2
OCD3
RW
RW
RO
RW
Clock monitor bit(5, 6)
Reserved bits
0 : XIN clock oscillates
1 : XIN clock stops
—
(b7-b4)
Set to 0.
NOTES:
1. Set the PRC0 bit in the PRCR register to 1 (w rite enable) before rew riting to the OCD register.
2. Set bits OCD1 to OCD0 to 00b before entering stop mode, high-speed on-chip oscillator mode, or low -speed on-chip
oscillator mode (XIN clock stops).
3. The CM14 bit is set to 0 (low -speed on-chip oscillator on) if the OCD2 bit is set to 1 (on-chip oscillator clock
selected).
4. The OCD2 bit is automatically set to 1 (on-chip oscillator clock selected) if a XIN clock oscillation stop is detected
w hile bits OCD1 to OCD0 are set to 11b. If the OCD3 bit is set to 1 (XIN clock stopped), the OCD2 bit remains
unchanged even w hen set to 0 (XIN clock selected).
5. The OCD3 bit is enabled w hen the OCD0 bit is set to 1 (oscillation stop detection function enabled).
6. The OCD3 bit remains 0 (XIN clock oscillates) if bits OCD1 to OCD0 are set to 00b.
7. Ref er to
Figure 10.18 Procedure for Switching Clock Source from Low-Speed On-Chip Oscillator to XIN
for the sw itching procedure w hen the XIN clock re-oscillates after detecting an oscillation stop.
Clock
Figure 10.4
OCD Register
Rev.2.10 Sep 26, 2008 Page 83 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
10. Clock Generation Circuit
High-Speed On-Chip Oscillator Control Register 0(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0 0
Symbol
FRA0
Address
0023h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
High-speed on-chip oscillator
enable bit
0 : High-speed on-chip oscillator off
1 : High-speed on-chip oscillator on
0 : Selects low -speed on-chip oscillator(3)
1 : Selects high-speed on-chip oscillator
FRA00
FRA01
High-speed on-chip oscillator
select bit(2)
RW
RW
—
(b7-b2)
Reserved bits
Set to 0.
NOTES:
Set the PRC0 bit in the PRCR register to 1 (w rite enable) before rew riting the FRA0 register.
1.
2. Change the FRA01 bit under the follow ing conditions.
• FRA00 = 1 (high-speed on-chip oscillation)
• The CM14 bit in the CM1 register = 0 (low -speed on-chip oscillator on)
• Bits FRA22 to FRA20 in the FRA2 register:
All divide ratio mode settings are supported w hen VCC = 3.0 to 5.5 V
Divide ratio of 4 or more w hen VCC = 2.7 to 5.5 V or K version
000b to 111b (other than K version)
010b to 111b
Divide ratio of 8 or more w hen VCC = 2.2 to 5.5 V (for N, D version only) 110b to 111b
3. When setting the FRA01 bit to 0 (low -speed on-chip oscillator selected), do not set the FRA00 bit to 0 (high-speed
on-chip oscillator off) at the same time. Set the FRA00 bit to 0 after setting the FRA01 bit to 0.
High-Speed On-Chip Oscillator Control Register 1(1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
FRA1
Address
0024h
After Reset
When Shipping
Function
RW
RW
The frequency of the high-speed on-chip oscillator is adjusted w ith bits 0 to 7.
High-speed on-chip oscillator frequency = 40 MHz (FRA1 register = value w hen shipping)
Setting the FRA1 register to a low er value results in a higher frequency.
Setting the FRA1 register to a higher value results in a low er frequency.(2)
NOTES:
1. Set the PRC0 bit in the PRCR register to 1 (w rite enable) before rew riting the FRA1 register.
2. When changing the values of the FRA1 register, adjust the FRA1 register so that the frequency of the high-speed
on-chip oscillator clock w ill be 40 MHz or less.
Figure 10.5
Registers FRA0 and FRA1
Rev.2.10 Sep 26, 2008 Page 84 of 453
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R8C/26 Group, R8C/27 Group
10. Clock Generation Circuit
High-Speed On-Chip Oscillator Control Register 2(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0
Symbol
FRA2
Address
0025h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
High-speed on-chip oscillator
frequency sw itching bits
Selects the dividing ratio for the high-
speed on-chip oscillator clock.
b2 b1 b0
FRA20
FRA21
FRA22
0 0 0: Divide-by-2 mode(2)
0 0 1: Divide-by-3 mode(2)
0 1 0: Divide-by-4 mode
0 1 1: Divide-by-5 mode
1 0 0: Divide-by-6 mode
1 0 1: Divide-by-7 mode
1 1 0: Divide-by-8 mode
1 1 1: Divide-by-9 mode
RW
RW
RW
—
(b7-b3)
Reserved bits
Set to 0.
NOTES:
1. Set the PRC0 bit in the PRCR register to 1 (w rite enable) before rew riting the FRA2 register.
2. Do not set in K version.
High-Speed On-Chip Oscillator Control Register 4 (For N, D Version Only)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
FRA4
Address
0029h
After Reset
When Shipping
Function
RW
RO
Stores data for frequency correction w hen VCC = 2.7 to 5.5 V. (The value is the same as that
of the FRA1 register after a reset.) Optimal frequency correction to match the voltage
conditions can be achieved by transferring this value to the FRA1 register.
High-Speed On-Chip Oscillator Control Register 6 (For N, D Version Only)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
FRA6
Address
002Bh
After Reset
When Shipping
Function
RW
RO
Stores data for frequency correction w hen VCC = 2.2 to 5.5 V. Optimal frequency correction
to match the voltage conditions can be achieved by transferring this value to the FRA1
register.
High-Speed On-Chip Oscillator Control Register 7 (For N, D Version Only)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
FRA7
Address
002Ch
After Reset
When Shipping
Function
36.864 MHz frequency correction data is stored.
The oscillation frequency of the high-speed on-chip oscillator can be adjusted to 36.864 MHz
by transferring this value to the FRA1 register.
RW
RO
Figure 10.6
Registers FRA2, FRA4, FRA6, and FRA7
Rev.2.10 Sep 26, 2008 Page 85 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
10. Clock Generation Circuit
Clock Prescaler Reset Flag (For N, D Version Only)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0 0 0
Symbol
CPSRF
Address
0028h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
—
(b6-b0)
Reserved bits
Set to 0.
Clock prescaler reset flag(1)
Setting this bit to 1 initializes the clock
prescaler. (When read, the content is 0)
CPSR
RW
NOTE:
1. Only w rite 1 to this bit w hen selecting the XCIN clock as the CPU clock, .
Figure 10.7
CPSRF Register
Voltage Detection Register 2(1) (N, D Version)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0
Symbol
Address
After Reset(5)
The LVD0ON bit in the OFS register is
set to 1 and hardw are reset
: 00h
Pow er-on reset, voltage monitor 0 reset
or LVD0ON bit in the OFS register is
set to 0, and hardw are reset
: 00100000b
VCA2
Bit Symbol
0032h
Bit Name
Function
0 : Disables low consumption
1 : Enables low consumption
RW
RW
Internal pow er low
consumption enable bit(6)
VCA20
—
(b4-b1)
Reserved bits
Set to 0.
RW
RW
RW
RW
Voltage detection 0 enable 0 : Voltage detection 0 circuit disabled
bit(2)
1 : Voltage detection 0 circuit enabled
Voltage detection 1 enable 0 : Voltage detection 1 circuit disabled
bit(3)
1 : Voltage detection 1 circuit enabled
Voltage detection 2 enable 0 : Voltage detection 2 circuit disabled
bit(4)
1 : Voltage detection 2 circuit enabled
VCA25
VCA26
VCA27
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (w rite enable) before w riting to the VCA2 register.
2. To use the voltage monitor 0 reset, set the VCA25 bit to 1.
After the VCA25 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
3. To use the voltage monitor 1 interrupt/reset or the VW1C3 bit in the VW1C register, set the VCA26 bit to 1.
After the VCA26 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
4. To use the voltage monitor 2 interrupt/reset or the VCA13 bit in the VCA1 register, set the VCA27 bit to 1.
After the VCA27 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
5. Softw are reset, w atchdog timer reset, voltage monitor 1 reset, and voltage monitor 2 reset do not affect this
register.
6. Use the VCA20 bit only w hen entering to w ait mode. To set the VCA20 bit, follow the procedure show n in
Figure
.
10.10 Procedure for Enabling Reduced Internal Power Consumption Using VCA20 bit
Figure 10.8
VCA2 Register (N, D Version)
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10. Clock Generation Circuit
Voltage Detection Register 2(1) (J, K Version)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0
Symbol
Address
After Reset(4)
The LVD1ON bit in the OFS register is
set to 1 and hardw are reset
: 00h
Pow er-on reset, voltage monitor 1 reset
or LVD1ON bit in the OFS register is
set to 0, and hardw are reset
: 0100000b
VCA2
Bit Symbol
0032h
Bit Name
Internal pow er low
consumption enable bit(5)
Function
0 : Disables low consumption
1 : Enables low consumption
RW
RW
VCA20
—
(b5-b1)
Reserved bits
Set to 0.
RW
RW
RW
Voltage detection 1 enable 0 : Voltage detection 1 circuit disabled
bit(2)
1 : Voltage detection 1 circuit enabled
Voltage detection 2 enable 0 : Voltage detection 2 circuit disabled
bit(3)
1 : Voltage detection 2 circuit enabled
VCA26
VCA27
NOTES:
1. Set the PRC3 bit in the PRCR register to 1 (w rite enable) before w riting to the VCA2 register.
2. To use the voltage monitor 1 reset, set the VCA26 bit to 1.
After the VCA26 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
3. To use the voltage monitor 2 interrupt/reset or the VCA13 bit in the VCA1 register, set the VCA27 bit to 1.
After the VCA27 bit is set to 1 from 0, the voltage detection circuit w aits for td(E-A) to elapse before starting
operation.
4. Softw are reset, w atchdog timer reset, or voltage monitor 2 reset do not affect this register.
5. Use the VCA20 bit only w hen entering to w ait mode. To set the VCA20 bit, follow the procedure show n in
Figure
.
10.10 Procedure for Enabling Reduced Internal Power Consumption Using VCA20 bit
Figure 10.9
VCA2 Register (J, K Version)
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10. Clock Generation Circuit
Exit wait mode by interrupt
(Note 1)
Handling procedure of internal power
low consumption enabled by VCA20 bit
In interrupt routine
Enter low-speed clock mode or low-speed
on-chip oscillator mode
VCA20 ← 0 (internal power low consumption
Step (1)
Step (2)
Step (3)
Step (4)
Step (5)
Step (6)
Step (7)
Step (8)
disabled)(2)
If it is necessary to start
the high-speed clock or
the high-speed on-chip
oscillator in the interrupt
routine, execute steps (5)
to (7) in the interrupt
routine.
Stop XIN clock and high-speed on-chip
oscillator clock
Start XIN clock or high-speed on-chip
oscillator clock
VCA20 ← 1 (internal power low consumption
(Wait until XIN clock oscillation stabilizes)
enabled)(2, 3)
Enter high-speed clock mode or
high-speed on-chip oscillator mode
Enter wait mode(4)
Interrupt handling
VCA20 ← 0 (internal power low consumption
Step (5)
Step (6)
Step (7)
Step (8)
disabled)(2)
Enter low-speed clock mode or
low-speed on-chip oscillator mode
Step (1)
Step (2)
Step (3)
Start XIN clock or high-speed on-chip
oscillator clock
If the high-speed clock or
high-speed on-chip
oscillator is started in the
interrupt routine, execute
steps (1) to (3) at the last of
the interrupt routine.
Stop XIN clock and high-speed on-chip
oscillator clock
(Wait until XIN clock oscillation stabilizes)
VCA20 ← 1 (internal power low consumption
enabled)(2, 3)
Enter high-speed clock mode or
high-speed on-chip oscillator mode
Interrupt handling completed
NOTES:
1. Execute this routine to handle all interrupts generated in wait mode.
However, this does not apply if it is not necessary to start the high-speed clock or high-speed on-chip oscillator during the interrupt routine.
2. Do not set the VCA20 bit to 0 with the instruction immediately after setting the VCA20 bit to 1. Also, do not do the opposite.
3. When the VCA20 bit is set to 1, do not set the CM10 bit to 1 (stop mode).
4. When entering wait mode, follow 10.7.2 Wait Mode.
VCA20: Bit in VCA2 register
Figure 10.10 Procedure for Enabling Reduced Internal Power Consumption Using VCA20 bit
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10. Clock Generation Circuit
The clocks generated by the clock generation circuits are described below.
10.1 XIN Clock
This clock is supplied by the XIN clock oscillation circuit. This clock is used as the clock source for the CPU and
peripheral function clocks. The XIN clock oscillation circuit is configured by connecting a resonator between the
XIN and XOUT pins. The XIN clock oscillation circuit includes an on-chip feedback resistor, which is
disconnected from the oscillation circuit in stop mode in order to reduce the amount of power consumed by the
chip. The XIN clock oscillation circuit may also be configured by feeding an externally generated clock to the XIN
pin.
Figure 10.11 shows Examples of XIN Clock Connection Circuit.
In reset and after reset, the XIN clock stops.
The XIN clock starts oscillating when the CM05 bit in the CM0 register is set to 0 (XIN clock oscillates) after
setting the CM01 bit in the CM0 register to 1 (XIN clock) and the CM13 bit in the CM1 register to 1 (XIN- XOUT
pin).
To use the XIN clock for the CPU clock source, set the OCD2 bit in the OCD register to 0 (select XIN clock) after
the XIN clock is oscillating stably.
The power consumption can be reduced by setting the CM05 bit in the CM0 register to 1 (XIN clock stops) if the
OCD2 bit is set to 1 (select on-chip oscillator clock).
When an external clock is input to the XIN pin are input, the XIN clock does not stop if the CM05 bit is set to 1. If
necessary, use an external circuit to stop the clock.
This MCU has an on-chip feedback resistor and on-chip resistor disable/enable switching is possible by the CM11
bit in the CM1 register.
In stop mode, all clocks including the XIN clock stop. Refer to 10.5 Power Control for details.
MCU
MCU
(on-chip feedback resistor)
(on-chip feedback resistor)
XIN
XIN
XOUT
XOUT
Open
Rf(1)
Rd(1)
Externally derived clock
CIN
COUT
VCC
VSS
External clock input circuit
Ceramic resonator external circuit
NOTE:
1. Insert a damping resistor if required. The resistance will vary depending on the oscillator and the oscillation drive
capacity setting. Use the value recommended by the manufacturer of the oscillator.
Use high drive when oscillation starts and, if it is necessary to switch the oscillation drive capacity, do so after
oscillation stabilizes.
When the oscillation drive capacity is set to low, check that oscillation is stable. Also, if the oscillator manufacturer's
data sheet specifies that a feedback resistor be added to the chip externally, insert a feedback resistor between XIN
and XOUT following the instructions.
To use this MCU of N, D version with supply voltage below VCC = 2.7 V, it is recommended to set the CM11 bit in
the CM1 register to 1 (on-chip feedback resistor disabled), the CM15 bit to 1 (high drive capacity), and connect the
feedback resistor to the chip externally.
Figure 10.11 Examples of XIN Clock Connection Circuit
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10. Clock Generation Circuit
10.2 On-Chip Oscillator Clocks
These clocks are supplied by the on-chip oscillators (high-speed on-chip oscillator and a low-speed on-chip
oscillator). The on-chip oscillator clock is selected by the FRA01 bit in the FRA0 register.
10.2.1 Low-Speed On-Chip Oscillator Clock
The clock generated by the low-speed on-chip oscillator is used as the clock source for the CPU clock,
peripheral function clock, fOCO, and fOCO-S.
After reset, the on-chip oscillator clock generated by the low-speed on-chip oscillator divided by 8 is selected as
the CPU clock.
If the XIN clock stops oscillating when bits OCD1 to OCD0 in the OCD register are set to 11b, the low-speed
on-chip oscillator automatically starts operating, supplying the necessary clock for the MCU.
The frequency of the low-speed on-chip oscillator varies depending on the supply voltage and the operating
ambient temperature. Application products must be designed with sufficient margin to allow for frequency
changes.
10.2.2 High-Speed On-Chip Oscillator Clock
The clock generated by the high-speed on-chip oscillator is used as the clock source for the CPU clock,
peripheral function clock, fOCO, fOCO-F, and fOCO40M.
To use the high-speed on-chip oscillator clock as the clock source for the CPU clock, peripheral clock, fOCO,
and fOCO-F, set bits FRA20 to FRA22 in the FRA2 register as follows:
• All divide ratio mode settings are supported when VCC = 3.0 to 5.5 V
000b to 111b
(other than K version)
010b to 111b
• Divide ratio of 4 or more when VCC = 2.7 to 5.5 V or K version
• Divide ratio of 8 or more when VCC = 2.2 to 5.5 V (for N, D version only) 110b to 111b
After reset, the on-chip oscillator clock generated by the high-speed on-chip oscillator stops. Oscillation is
started by setting the FRA00 bit in the FRA0 register to 1 (high-speed on-chip oscillator on). The frequency can
be adjusted by registers FRA1 and FRA2.
The frequency correction data (the value is the same as that of the FRA1 register after a reset) corresponding to
the supply voltage ranges VCC = 2.7 to 5.5 V is stored in FRA4 register. Furthermore, the frequency correction
data corresponding to the supply voltage ranges VCC = 2.2 to 5.5 V is stored in FRA6 register (for N, D version
only). To use separate correction values to match these voltage ranges, transfer them from FRA4 or FRA6
register to the FRA1 register.
The frequency correction data of 36.864 MHz is stored in the FRA7 register (for N, D version only). To set the
frequency of the high-speed on-chip oscillator to 36.864 MHz, transfer the correction value in the FRA7
register to the FRA1 register before use. This enables the setting errors of bit rates such as 9600 bps and 38400
bps to be 0% when the serial interface is used in UART mode (refer to Table 15.7 Bit Rate Setting Example in
UART Mode (Internal Clock Selected)).
Since there are differences in the amount of frequency adjustment among the bits in the FRA1 register, make
adjustments by changing the settings of individual bits. Adjust the FRA1 register so that the frequency of the
high-speed on-chip oscillator clock will be 40 MHz or less.
Rev.2.10 Sep 26, 2008 Page 90 of 453
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10. Clock Generation Circuit
10.3 XCIN Clock (For N, D Version Only)
This clock is supplied by the XCIN clock oscillation circuit. This clock is used as the clock source for the CPU
clock, peripheral function clock. The XCIN clock oscillation circuit is configured by connecting a resonator
between the XCIN and XCOUT pins. The XCIN clock oscillation circuit includes an on-chip a feedback resistor,
which is disconnected from the oscillation circuit in stop mode in order to reduce the amount of power consumed in
the chip. The XCIN clock oscillation circuit may also be configured by feeding an externally generated clock to the
XCIN pin.
Figure 10.12 shows Examples of XCIN Clock Connection Circuits.
During and after reset, the XCIN clock stops.
The XCIN clock starts oscillating when the CM01 bit in the CM0 register is set to 1 (XCIN clock) and the CM04
bit in the CM0 register is set to 1 (XCIN-XCOUT pin).
To use the XCIN clock for the CPU clock source, set the OCD2 bit in the OCD register to 0 (selects XIN clock)
after the XCIN clock is oscillating stably.
This MCU has an on-chip feedback resistor and on-chip resistor disable/enable switching is possible by the CM12
bit in the CM1 register.
In stop mode, all clocks including the XCIN clock stop. Refer to 10.5 Power Control for details.
MCU
MCU
(on-chip feedback resistor)
(on-chip feedback resistor)
XCIN
XCIN
XCOUT
XCOUT
Open
Rf(1)
Rd(1)
Externally derived clock
CIN
COUT
VCC
VSS
External clock input circuit
External crystal oscillator circuit
NOTE:
1. Insert a damping resistor and feedback resistor if required. The resistance will vary depending on the oscillator and
the oscillation drive capacity setting. Use the value recommended by the manufacturer of the oscillator.
When the oscillation drive capacity is set to low, check that oscillation is stable. Also, if the oscillator manufacturer's
data sheet specifies that a feedback resistor be added to the chip externally, insert a feedback resistor between
XCIN and XCOUT following the instructions.
Figure 10.12 Examples of XCIN Clock Connection Circuits
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10. Clock Generation Circuit
10.4 CPU Clock and Peripheral Function Clock
There are a CPU clock to operate the CPU and a peripheral function clock to operate the peripheral functions. Refer
to Figure 10.1 Clock Generation Circuit.
10.4.1 System Clock
The system clock is the clock source for the CPU and peripheral function clocks. Either the XIN clock and
XCIN clock or the on-chip oscillator clock can be selected. (For J, K version, the XCIN clock cannot be
selected.)
10.4.2 CPU Clock
The CPU clock is an operating clock for the CPU and watchdog timer.
The system clock can be divided by 1 (no division), 2, 4, 8, or 16 to produce the CPU clock. Use the CM06 bit
in the CM0 register and bits CM16 to CM17 in the CM1 register to select the value of the division.
Use the XCIN clock while the XCIN clock oscillation stabilizes.
After reset, the low-speed on-chip oscillator clock divided by 8 provides the CPU clock.
When entering stop mode from high-speed clock mode, the CM06 bit is set to 1 (divide-by-8 mode).
(For J, K version, the XCIN clock cannot be selected.)
10.4.3 Peripheral Function Clock (f1, f2, f4, f8, and f32)
The peripheral function clock is the operating clock for the peripheral functions.
The clock fi (i = 1, 2, 4, 8, and 32) is generated by the system clock divided by i. The clock fi is used for timers
RA, RB, RC, and RE, the serial interface and the A/D converter.
When the WAIT instruction is executed after setting the CM02 bit in the CM0 register to 1 (peripheral function
clock stops in wait mode), the clock fi stop.
10.4.4 fOCO
fOCO is an operating clock for the peripheral functions.
fOCO runs at the same frequency as the on-chip oscillator clock and can be used as the source for timer RA.
When the WAIT instruction is executed, the clocks fOCO does not stop.
10.4.5 fOCO40M
fOCO40M is used as the count source for timer RC. fOCO40M is generated by the high-speed on-chip
oscillator and supplied by setting the FRA00 bit to 1.
When the WAIT instruction is executed, the clock fOCO40M does not stop.
fOCO40M can be used with supply voltage VCC = 3.0 to 5.5 V.
10.4.6 fOCO-F
fOCO-F is used as the count source for the A/D converter. fOCO-F is generated by the high-speed on-chip
oscillator and supplied by setting the FRA00 bit to 1.
When the WAIT instruction is executed, the clock fOCO-F does not stop.
10.4.7 fOCO-S
fOCO-S is an operating clock for the watchdog timer and voltage detection circuit. fOCO-S is supplied by
setting the CM14 bit to 0 (low-speed on-chip oscillator on) and uses the clock generated by the low-speed on-
chip oscillator. When the WAIT instruction is executed or in count source protect mode of the watchdog timer,
fOCO-S does not stop.
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10. Clock Generation Circuit
10.4.8 fC4 and fC32
The clock fC4 is used for timer RE and the clock fC32 is used for timer RA.
Use fC4 and fC32 while the XCIN clock oscillation stabilizes.
(For J, K version, fC4 and fC32 cannot be used.)
10.4.9 fOCO128
fOCO128 is generated by fOCO divided by 128.
The clock fOCO128 is used for capture signal of timer RC’s TRCGRA register.
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10. Clock Generation Circuit
10.5 Power Control
There are three power control modes. All modes other than wait mode and stop mode are referred to as standard
operating mode.
10.5.1 Standard Operating Mode
Standard operating mode is further separated into four modes.
In standard operating mode, the CPU clock and the peripheral function clock are supplied to operate the CPU
and the peripheral function clocks. Power consumption control is enabled by controlling the CPU clock
frequency. The higher the CPU clock frequency, the more processing power increases. The lower the CPU
clock frequency, the more power consumption decreases. When unnecessary oscillator circuits stop, power
consumption is further reduced.
Before the clock sources for the CPU clock can be switched over, the new clock source needs to be oscillating
and stable. If the new clock source is the XIN clock or XCIN clock, allow sufficient wait time in a program
until oscillation is stabilized before exiting.
Table 10.2
Settings and Modes of Clock Associated Bits
OCD
CM1 Register
Register
CM0 Register
FRA0 Register
Modes
CM17,
CM16
OCD2
CM14 CM13 CM06 CM05 CM04 CM01 FRA01 FRA00
High-speed No division
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
00b
01b
10b
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
0
0
0
0
0
1
1
1
1
1
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
0
0
0
1
0
0
0
0
1
0
0
0
0
1
0
0
0
0
1
0
0
0
0
0
0
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
1
1
1
1
1
−
−
−
−
−
−
−
−
−
−
0
0
0
0
0
1
1
1
1
1
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
1
1
1
1
1
0
0
0
0
0
−
−
−
−
−
−
−
−
−
−
1
1
1
1
1
−
−
−
−
−
clock mode
Divide-by-2
Divide-by-4
Divide-by-8
Divide-by-16
11b
00b
01b
10b
−
Low-speed No division
clock
Divide-by-2
mode(1)
Divide-by-4
Divide-by-8
Divide-by-16
11b
00b
01b
10b
−
High-speed No division
on-chip
oscillator
mode
Divide-by-2
Divide-by-4
Divide-by-8
Divide-by-16
11b
00b
01b
10b
−
Low-speed No division
on-chip
oscillator
mode
Divide-by-2
Divide-by-4
Divide-by-8
Divide-by-16
11b
−: Can be 0 or 1, no change in outcome
NOTE:
1. For N, D version only.
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10. Clock Generation Circuit
10.5.1.1 High-Speed Clock Mode
The XIN clock divided by 1 (no division), 2, 4, 8, or 16 provides the CPU clock. Set the CM06 bit to 1 (divide-
by-8 mode) when transiting to high-speed on-chip oscillator mode, low-speed on-chip oscillator mode. If the
CM14 bit is set to 0 (low-speed on-chip oscillator on) or the FRA00 bit in the FRA0 register is set to 1 (high-
speed on-chip oscillator on), fOCO can be used as timer RA. When the FRA00 bit is set to 1, fOCO40M can be
used as timer RC.
When the CM14 bit is set to 0 (low-speed on-chip oscillator on), fOCO-S can be used as the watchdog timer
and voltage detection circuit.
10.5.1.2 Low-Speed Clock Mode (For N, D Version Only)
The XCIN clock divided by 1 (no division), 2, 4, 8, or 16 provides the CPU clock. Set the CM06 bit to 1 (divide
by-8 mode) when transiting to high-speed on-chip oscillator mode, low-speed on-chip oscillator mode. If the
CM14 bit is set to 0 (low-speed on-chip oscillator on) or the FRA00 bit in the FRA0 register is set to 1 (high
speed on-chip oscillator on), fOCO can be used as timer RA. When the FRA00 bit is set to 1, fOCO40M can be
used as timer RC.
When the CM14 bit is set to 0 (low-speed on-chip oscillator on), fOCO-S can be used as the watchdog timer
and voltage detection circuit.
In this mode, stopping the XIN clock and high-speed on-chip oscillator, and setting the FMR47 bit in the FMR4
register to 1 (flash memory low consumption current read mode enabled) enables low consumption operation.
To enter wait mode from low-speed clock mode, setting the VCA20 bit in the VCA2 register to 1 (internal
power low consumption enabled) enables lower consumption current in wait mode.
When enabling reduced internal power consumption using the VCA20 bit, follow Figure 10.14 Procedure for
Enabling Reduced Internal Power Consumption Using VCA20 bit.
10.5.1.3 High-Speed On-Chip Oscillator Mode
The high-speed on-chip oscillator is used as the on-chip oscillator clock when the FRA00 bit in the FRA0
register is set to 1 (high-speed on-chip oscillator on) and the FRA01 bit in the FRA0 register is set to 1. The on-
chip oscillator divided by 1 (no division), 2, 4, 8, or 16 provides the CPU clock. Set the CM06 bit to 1 (divide-
by-8 mode) when transiting to high-speed clock mode. If the FRA00 bit is set to 1, fOCO40M can be used as
timer RC.
When the CM14 bit is set to 0 (low-speed on-chip oscillator on), fOCO-S can be used as the watchdog timer
and voltage detection circuit.
10.5.1.4 Low-Speed On-Chip Oscillator Mode
If the CM14 bit in the CM1 register is set to 0 (low-speed on-chip oscillator on) or the FRA01bit in the FRA0
register is set to 0, the low-speed on-chip oscillator provides the on-chip oscillator clock.
The on-chip oscillator clock divided by 1 (no division), 2, 4, 8 or 16 provides the CPU clock. The on-chip
oscillator clock is also the clock source for the peripheral function clocks. Set the CM06 bit to 1 (divide-by-8
mode) when transiting to high-speed clock mode. When the FRA00 bit is set to 1, fOCO40M can be used as
timer RC.
When the CM14 bit is set to 0 (low-speed on-chip oscillator on), fOCO-S can be used as the watchdog timer
and voltage detection circuit.
In this mode, stopping the XIN clock and high-speed on-chip oscillator, and setting the FMR47 bit in the FMR4
register to 1 (flash memory low consumption current read mode enabled) enables low consumption operation.
To enter wait mode from low-speed on-chip oscillator mode, setting the VCA20 bit in the VCA2 register to 1
(internal power low consumption enabled) enables lower consumption current in wait mode.
When enabling reduced internal power consumption using the VCA20 bit, follow Figure 10.14 Procedure for
Enabling Reduced Internal Power Consumption Using VCA20 bit.
Rev.2.10 Sep 26, 2008 Page 95 of 453
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10. Clock Generation Circuit
10.5.2 Wait Mode
Since the CPU clock stops in wait mode, the CPU, which operates using the CPU clock, and the watchdog
timer, when count source protection mode is disabled, stop. The XIN clock, XCIN clock, and on-chip oscillator
clock do not stop and the peripheral functions using these clocks continue operating.
10.5.2.1 Peripheral Function Clock Stop Function
If the CM02 bit is set to 1 (peripheral function clock stops in wait mode), the f1, f2, f4, f8, and f32 clocks stop
in wait mode. This reduces power consumption.
10.5.2.2 Entering Wait Mode
The MCU enters wait mode when the WAIT instruction is executed.
When the OCD2 bit in the OCD register is set to 1 (on-chip oscillator selected as system clock), set the OCD1
bit in the OCD register to 0 (oscillation stop detection interrupt disabled) before executing the WAIT
instruction.
If the MCU enters wait mode while the OCD1 bit is set to 1 (oscillation stop detection interrupt enabled),
current consumption is not reduced because the CPU clock does not stop.
10.5.2.3 Pin Status in Wait Mode
The I/O port is the status before wait mode was entered is maintained.
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10. Clock Generation Circuit
10.5.2.4 Exiting Wait Mode
The MCU exits wait mode by a reset or a peripheral function interrupt.
The peripheral function interrupts are affected by the CM02 bit. When the CM02 bit is set to 0 (peripheral
function clock does not stop in wait mode), all peripheral function interrupts can be used to exit wait mode.
When the CM02 bit is set to 1 (peripheral function clock stops in wait mode), the peripheral functions using the
peripheral function clock stop operating and the peripheral functions operated by external signals or on-chip
oscillator clock can be used to exit wait mode.
Table 10.3 lists Interrupts to Exit Wait Mode and Usage Conditions.
Table 10.3
Interrupts to Exit Wait Mode and Usage Conditions
Interrupt
Serial interface interrupt
CM02 = 0
CM02 = 1
Usable when operating with external
clock
Usable when operating with
internal or external clock
Clock synchronous serial I/O Usable in all modes
with chip select interrupt /
(Do not use)
2
I C bus interface interrupt
Key input interrupt
Usable
Usable
A/D conversion interrupt
Timer RA interrupt
Usable in one-shot mode
Usable in all modes
(Do not use)
Can be used if there is no filter in
event counter mode.
(1)
Usable by selecting fOCO or fC32
as count source.
Timer RB interrupt
Timer RC interrupt
Timer RE interrupt
Usable in all modes
Usable in all modes
Usable in all modes
(Do not use)
(Do not use)
Usable when operating in real time
(1)
clock mode
Usable
INT interrupt
Usable (INT0, INT1, INT3 can be used
if there is no filter.)
Usable
Voltage monitor 1 interrupt
Voltage monitor 2 interrupt
Oscillation stop detection
interrupt
Usable
Usable
Usable
Usable
(Do not use)
NOTE:
1. For N, D version only.
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Figure 10.13 shows the Time from Wait Mode to Interrupt Routine Execution.
When using a peripheral function interrupt to exit wait mode, set up the following before executing the WAIT
instruction.
(1) Set the interrupt priority level in bits ILVL2 to ILVL0 in the interrupt control registers of the peripheral
function interrupts to be used for exiting wait mode. Set bits ILVL2 to ILVL0 of the peripheral function
interrupts that are not to be used for exiting wait mode to 000b (interrupt disabled).
(2) Set the I flag to 1.
(3) Operate the peripheral function to be used for exiting wait mode.
When exiting by a peripheral function interrupt, the time (number of cycles) between interrupt request
generation and interrupt routine execution is determined by the settings of the FMSTP bit in the FMR0 register,
as described in Figure 10.13.
The CPU clock, when exiting wait mode by a peripheral function interrupt, is the same clock as the CPU clock
when the WAIT instruction is executed.
FMR0 Register
FMSTP Bit
Time until Flash Memory Time until CPU Clock Time for Interrupt
Remarks
is Activated (T1)
is Supplied (T2)
Sequence (T3)
Following total
time is the time
from wait mode
until an interrupt
routine is
0
Period of system clock
Period of CPU clock Period of CPU clock
× 12 cycles + 30 µs (max.)
× 6 cycles
× 20 cycles
(flash memory operates)
1
Period of system clock
Same as above
Same as above
× 12 cycles
(flash memory stops)
executed.
T1
T2
T3
Flash memory
activation sequence
Wait mode
CPU clock restart sequence
Interrupt sequence
Interrupt request generated
Figure 10.13 Time from Wait Mode to Interrupt Routine Execution
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10. Clock Generation Circuit
10.5.2.5 Reducing Internal Power Consumption
Internal power consumption can be reduced by using low-speed clock mode (for N, D version only) or low-
speed on-chip oscillator mode. Figure 10.14 shows the Procedure for Enabling Reduced Internal Power
Consumption Using VCA20 bit.
When enabling reduced internal power consumption using the VCA20 bit, follow Figure 10.14 Procedure for
Enabling Reduced Internal Power Consumption Using VCA20 bit.
Exit wait mode by interrupt
(Note 1)
Handling procedure of internal power
In interrupt routine
low consumption enabled by VCA20 bit
Enter low-speed clock mode or low-speed
on-chip oscillator mode
VCA20 ← 0 (internal power low consumption
Step (1)
Step (2)
Step (3)
Step (4)
Step (5)
Step (6)
Step (7)
Step (8)
disabled)(2)
If it is necessary to start
the high-speed clock or
the high-speed on-chip
oscillator in the interrupt
routine, execute steps (5)
to (7) in the interrupt
routine.
Stop XIN clock and high-speed on-chip
oscillator clock
Start XIN clock or high-speed on-chip
oscillator clock
VCA20 ← 1 (internal power low consumption
(Wait until XIN clock oscillation stabilizes)
enabled)(2, 3)
Enter high-speed clock mode or
high-speed on-chip oscillator mode
Enter wait mode(4)
Interrupt handling
VCA20 ← 0 (internal power low consumption
Step (5)
Step (6)
Step (7)
Step (8)
disabled)(2)
Enter low-speed clock mode or
low-speed on-chip oscillator mode
Step (1)
Step (2)
Step (3)
Start XIN clock or high-speed on-chip
oscillator clock
If the high-speed clock or
high-speed on-chip
oscillator is started in the
interrupt routine, execute
steps (1) to (3) at the last of
the interrupt routine.
Stop XIN clock and high-speed on-chip
oscillator clock
(Wait until XIN clock oscillation stabilizes)
VCA20 ← 1 (internal power low consumption
enabled)(2, 3)
Enter high-speed clock mode or
high-speed on-chip oscillator mode
Interrupt handling completed
NOTES:
1. Execute this routine to handle all interrupts generated in wait mode.
However, this does not apply if it is not necessary to start the high-speed clock or high-speed on-chip oscillator during the interrupt routine.
2. Do not set the VCA20 bit to 0 with the instruction immediately after setting the VCA20 bit to 1. Also, do not do the opposite.
3. When the VCA20 bit is set to 1, do not set the CM10 bit to 1 (stop mode).
4. When entering wait mode, follow 10.7.2 Wait Mode.
VCA20: Bit in VCA2 register
Figure 10.14 Procedure for Enabling Reduced Internal Power Consumption Using VCA20 bit
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10. Clock Generation Circuit
10.5.3 Stop Mode
Since the oscillator circuits stop in stop mode, the CPU clock and peripheral function clock stop and the CPU
and peripheral functions that use these clocks stop operating. The least power required to operate the MCU is in
stop mode. If the voltage applied to the VCC pin is VRAM or more, the contents of internal RAM is
maintained.
The peripheral functions clocked by external signals continue operating.
Table 10.4 lists Interrupts to Exit Stop Mode and Usage Conditions.
Table 10.4
Interrupts to Exit Stop Mode and Usage Conditions
Interrupt Usage Conditions
Key input interrupt
−
INT0, INT1, INT3 interrupt
Timer RA interrupt
Can be used if there is no filter
When there is no filter and external pulse is counted in event counter
mode
Serial interface interrupt
When external clock is selected
(1)
Usable in digital filter disabled mode (VW1C1 bit in VW1C register is set
Voltage monitor 1 interrupt
to 1)
Voltage monitor 2 interrupt
Usable in digital filter disabled mode (VW2C1 bit in VW2C register is set
to 1)
NOTE:
1. For N, D version only.
10.5.3.1 Entering Stop Mode
The MCU enters stop mode when the CM10 bit in the CM1 register is set to 1 (all clocks stop). At the same
time, the CM06 bit in the CM0 register is set to 1 (divide-by-8 mode), the CM03 bit in the CM0 register is set to
1 (XCIN clock oscillator circuit drive capacity high), and the CM15 bit in the CM1 register is set to 1 (XIN
clock oscillator circuit drive capacity high).
When using stop mode, set bits OCD1 to OCD0 to 00b before entering stop mode.
10.5.3.2 Pin Status in Stop Mode
The status before wait mode was entered is maintained.
However, when the CM01 bit in the CM0 register is set to 0 (XIN clock) and the CM13 bit in the CM1 register
is set to 1 (XIN-XOUT pins), the XOUT(P4_7) pin is held “H”. When the CM13 bit is set to 0 (input ports P4_6
and P4_7), the P4_7(XOUT pin) is held in input status.
When the CM01 bit in the CM0 register is set to 1 (XCIN clock) and the CM04 bit in the CM0 register is set to
1 (XCIN clock oscillates), the XCOUT(P4_7) pin is held “H”. When the CM04 bit is set to 0 (XIN clock stops),
the P4_7(XOUT pin) is held in input status.
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10. Clock Generation Circuit
10.5.3.3 Exiting Stop Mode
The MCU exits stop mode by a reset or peripheral function interrupt.
Figure 10.15 shows the Time from Stop Mode to Interrupt Routine Execution.
When using a peripheral function interrupt to exit stop mode, set up the following before setting the CM10 bit
to 1.
(1) Set the interrupt priority level in bits ILVL2 to ILVL0 of the peripheral function interrupts to be used for
exiting stop mode. Set bits ILVL2 to ILVL0 of the peripheral function interrupts that are not to be used
for exiting stop mode to 000b (interrupt disabled).
(2) Set the I flag to 1.
(3) Operates the peripheral function to be used for exiting stop mode.
When exiting by a peripheral function interrupt, the interrupt sequence is executed when an interrupt request is
generated and the CPU clock supply is started.
If the clock used immediately before stop mode is a system clock and stop mode is exited by a peripheral
function interrupt, the CPU clock becomes the previous system clock divided by 8.
FMR0 Register
FMSTP Bit
Time until Flash Memory Time until CPU Clock
Time for Interrupt
Sequence (T4)
Remarks
is Activated (T2)
is Supplied (T3)
Following total
time of T0 to T4 is
the time from stop
mode until an
interrupt handling
is executed.
0
Period of system clock
Period of CPU clock Period of CPU clock
(flash memory operates) × 12 cycles + 30 µs (max.)
× 6 cycles
× 20 cycles
1
Period of system clock
Same as above
Same as above
(flash memory stops)
× 12 cycles
T0
T1
T2
T3
T4
Oscillation time of
Internal
power
stability time
Stop
mode
Flash memory
activation sequence
CPU clock restart
sequence
CPU clock source
used immediately
before stop mode
Interrupt sequence
150 µs
(max.)
Interrupt
request
generated
Figure 10.15 Time from Stop Mode to Interrupt Routine Execution
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10. Clock Generation Circuit
Figure 10.16 shows the State Transitions in Power Control Mode (When the CM01 bit in the CM0 register is set
to 0 (XIN clock)). Figure 10.17 shows the State Transitions in Power Control Mode (When the CM01 bit in the
CM0 register is set to 1 (XCIN clock)).
State Transitions in Power Control Mode
(When the CM01 bit in the CM0 register is set to 0 (XIN clock))
Reset
Standard operating mode
Low-speed on-chip oscillator mode
CM14 = 0
OCD2 = 1
FRA01 = 0
CM14 = 0
OCD2 = 1
FRA01 = 0
CM05 = 0
CM13 = 1
OCD2 = 0
High-speed clock mode
CM05 = 0
FRA00 = 1
FRA01 = 1
CM14 = 0
FRA01 = 0
CM13 = 1
OCD2 = 0
OCD2 = 1
FRA00 = 1
FRA01 = 1
CM05 = 0
CM13 = 1
OCD2 = 0
High-speed on-chip oscillator mode
OCD2 = 1
FRA00 = 1
FRA01 = 1
Interrupt
WAIT instruction
Interrupt
CM10 = 1
Wait mode
Stop mode
All oscillators stop
CPU operation stops
CM05: Bit in CM0 register
CM13, CM14: Bits in CM1 register
OCD2: Bit in OCD register
FRA00, FRA01: Bits in FRA0 register
Figure 10.16 State Transitions in Power Control Mode (When the CM01 bit in the CM0 register is
set to 0 (XIN clock))
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10. Clock Generation Circuit
State Transitions in Power Control Mode
(When the CM01 bit in the CM0 register is set to 1 (XCIN clock)) (For N, D version only)
Reset
Standard operating mode
Low-speed on-chip oscillator mode
CM14 = 0
OCD2 = 1
FRA01 = 0
CM04 = 1
OCD2 = 0
CM14 = 0
OCD2 = 1
FRA01 = 0
Low-speed clock mode
CM04 = 1
FRA00 = 1
FRA01 = 1
CM14 = 0
FRA01 = 0
OCD2 = 0
CM04 = 1
OCD2 = 0
OCD2 = 1
FRA00 = 1
FRA01 = 1
High-speed on-chip oscillator mode
OCD2 = 1
FRA00 = 1
FRA01 = 1
Interrupt
WAIT instruction
Interrupt
CM10 = 1
Wait mode
Stop mode
CPU operation stops
All oscillators stop
CM04: Bit in CM0 register
CM14: Bit in CM1 register
OCD2: Bit in OCD register
FRA00, FRA01: Bits in FRA0 register
Figure 10.17 State Transitions in Power Control Mode (When the CM01 bit in the CM0 register is
set to 1 (XCIN clock))
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10. Clock Generation Circuit
10.6 Oscillation Stop Detection Function
The oscillation stop detection function detects the stop of the XIN clock oscillating circuit. The oscillation stop
detection function can be enabled and disabled by the OCD0 bit in the OCD register.
Table 10.5 lists the Specifications of Oscillation Stop Detection Function.
When the XIN clock is the CPU clock source and bits OCD1 to OCD0 are set to 11b, the system is placed in the
following state if the XIN clock stops.
• OCD2 bit in OCD register = 1 (on-chip oscillator clock selected)
• OCD3 bit in OCD register = 1 (XIN clock stops)
• CM14 bit in CM1 register = 0 (low-speed on-chip oscillator oscillates)
• Oscillation stop detection interrupt request is generated.
Table 10.5
Specifications of Oscillation Stop Detection Function
Item Specification
Oscillation stop detection clock and
frequency bandwidth
f(XIN) ≥ 2 MHz
Enabled condition for oscillation stop
detection function
Set bits OCD1 to OCD0 to 11b
Oscillation stop detection interrupt is generated
Operation at oscillation stop detection
10.6.1 How to Use Oscillation Stop Detection Function
• The oscillation stop detection interrupt shares a vector with the voltage monitor 1 interrupt, the voltage
monitor 2 interrupt, and the watchdog timer interrupt. When using the oscillation stop detection interrupt
and watchdog timer interrupt, the interrupt source needs to be determined.
Table 10.6 lists the Determining Interrupt Source for Oscillation Stop Detection, Watchdog Timer, Voltage
Monitor 1, and Voltage Monitor 2 Interrupts. Figure 10.19 shows the Example of Determining Interrupt
Source for Oscillation Stop Detection, Watchdog Timer, Voltage Monitor 1, or Voltage Monitor 2 Interrupt
(N, D Version). Figure 10.20 shows the Example of Determining Interrupt Source for Oscillation Stop
Detection, Watchdog Timer, Voltage Monitor 1, or Voltage Monitor 2 Interrupt (J, K Version).
• When the XIN clock restarts after oscillation stop, switch the XIN clock to the clock source of the CPU
clock and peripheral functions by a program.
Figure 10.18 shows the Procedure for Switching Clock Source from Low-Speed On-Chip Oscillator to
XIN Clock.
• To enter wait mode while using the oscillation stop detection function, set the CM02 bit to 0 (peripheral
function clock does not stop in wait mode).
• Since the oscillation stop detection function is a function for cases where the XIN clock is stopped by an
external cause, set bits OCD1 to OCD0 to 00b when the XIN clock stops or is started by a program, (stop
mode is selected or the CM05 bit is changed).
• This function cannot be used when the XIN clock frequency is 2 MHz or below. In this case, set bits OCD1
to OCD0 to 00b.
• To use the low-speed on-chip oscillator clock for the CPU clock and clock sources of peripheral functions
after detecting the oscillation stop, set the FRA01 bit in the FRA0 register to 0 (low-speed on-chip
oscillator selected) and bits OCD1 to OCD0 to 11b.
To use the high-speed on-chip oscillator clock for the CPU clock and clock sources of peripheral functions
after detecting the oscillation stop, set the FRA00 bit to 1 (high-speed on-chip oscillator on) and the FRA01
bit to 1 (high-speed on-chip oscillator selected) and then set bits OCD1 to OCD0 to 11b.
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10. Clock Generation Circuit
Table 10.6
Determining Interrupt Source for Oscillation Stop Detection, Watchdog Timer,
Voltage Monitor 1, and Voltage Monitor 2 Interrupts
Generated Interrupt Source
Oscillation stop detection
((a) or (b))
Bit Showing Interrupt Cause
(a) OCD3 bit in OCD register = 1
(b) OCD1 to OCD0 bits in OCD register = 11b and OCD2 bit = 1
VW2C3 bit in VW2C register = 1
Watchdog timer
(1)
VW1C2 bit in VW1C register = 1
Voltage monitor 1
Voltage monitor 2
VW2C2 bit in VW2C register = 1
NOTE:
1. For N, D version only.
Switch to XIN clock
Multiple confirmations
that OCD3 bit is set to 0 (XIN
clock oscillates) ?
NO
YES
Set OCD1 to OCD0 bits to 00b
Set OCD2 bit to 0
(select XIN clock)
End
OCD3 to OCD0: Bits in OCD register
Figure 10.18 Procedure for Switching Clock Source from Low-Speed On-Chip Oscillator to XIN
Clock
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10. Clock Generation Circuit
Interrupt sources judgement
NO
OCD3 = 1 ?
(XIN clock stopped)
YES
OCD1 = 1
(oscillation stop detection
NO
interrupt enabled) and OCD2 = 1
(on-chip oscillator clock selected
as system clock) ?
YES
VW2C3 = 1 ?
(Watchdog timer
underflow)
NO
YES
NO
VW2C2 = 1 ?
(passing Vdet2)
YES
Set OCD1 bit to 0 (oscillation stop
detection interrupt disabled).(1)
To oscillation stop detection
interrupt routine
To watchdog timer
interrupt routine
To voltage monitor 2
interrupt routine
To voltage monitor 1
interrupt routine
NOTE:
1. This disables multiple oscillation stop detection interrupts.
OCD1 to OCD3: Bits in OCD register
VW2C2, VW2C3: Bits in VW2C register
Figure 10.19 Example of Determining Interrupt Source for Oscillation Stop Detection, Watchdog
Timer, Voltage Monitor 1, or Voltage Monitor 2 Interrupt (N, D Version)
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10. Clock Generation Circuit
Interrupt sources judgement
NO
OCD3 = 1 ?
(XIN clock stopped)
YES
OCD1 = 1
(oscillation stop detection
NO
interrupt enabled) and OCD2 = 1
(on-chip oscillator clock selected
as system clock) ?
YES
VW2C3 = 1 ?
(Watchdog timer
underflow)
NO
YES
Set OCD1 bit to 0 (oscillation stop
detection interrupt disabled).(1)
To oscillation stop detection
interrupt routine
To watchdog timer
interrupt routine
To voltage monitor 2
interrupt routine
NOTE:
1. This disables multiple oscillation stop detection interrupts.
OCD1 to OCD3: Bits in OCD register
VW2C3: Bit in VW2C register
Figure 10.20 Example of Determining Interrupt Source for Oscillation Stop Detection, Watchdog
Timer, Voltage Monitor 1, or Voltage Monitor 2 Interrupt (J, K Version)
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10. Clock Generation Circuit
10.7 Notes on Clock Generation Circuit
10.7.1 Stop Mode
When entering stop mode, set the FMR01 bit in the FMR0 register to 0 (CPU rewrite mode disabled) and the
CM10 bit in the CM1 register to 1 (stop mode). An instruction queue pre-reads 4 bytes from the instruction
which sets the CM10 bit to 1 (stop mode) and the program stops.
Insert at least 4 NOP instructions following the JMP.B instruction after the instruction which sets the CM10 bit
to 1.
• Program example to enter stop mode
BCLR
BSET
FSET
BSET
JMP.B
1,FMR0
0,PRCR
I
0,CM1
LABEL_001
; CPU rewrite mode disabled
; Protect disabled
; Enable interrupt
; Stop mode
LABEL_001 :
NOP
NOP
NOP
NOP
10.7.2 Wait Mode
When entering wait mode, set the FMR01 bit in the FMR0 register to 0 (CPU rewrite mode disabled) and
execute the WAIT instruction. An instruction queue pre-reads 4 bytes from the WAIT instruction and the
program stops. Insert at least 4 NOP instructions after the WAIT instruction.
• Program example to execute the WAIT instruction
BCLR
FSET
WAIT
NOP
1,FMR0
I
; CPU rewrite mode disabled
; Enable interrupt
; Wait mode
NOP
NOP
NOP
10.7.3 Oscillation Stop Detection Function
Since the oscillation stop detection function cannot be used if the XIN clock frequency is 2 MHz or below, set
bits OCD1 to OCD0 to 00b.
10.7.4 Oscillation Circuit Constants
Ask the manufacturer of the oscillator to specify the best oscillation circuit constants for your system.
To use this MCU with supply voltage below VCC = 2.7 V, it is recommended to set the CM11 bit in the CM1
register to 1 (on-chip feedback resistor disabled), the CM15 bit to 1 (high drive capacity), and connect the
feedback resistor to the chip externally.
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11.Protection
11. Protection
The protection function protects important registers from being easily overwritten when a program runs out of control.
Figure 11.1 shows the PRCR Register. The registers protected by the PRCR register are listed below.
• Registers protected by PRC0 bit: Registers CM0, CM1, OCD, FRA0, FRA1, and FRA2
• Registers protected by PRC1 bit: Registers PM0 and PM1
• Registers protected by PRC2 bit: PD0 register
• Registers protected by PRC3 bit: Registers VCA2, VW0C, VW1C, and VW2C
Protect Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
PRCR
Address
000Ah
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
Protect bit 0
Writing to registers CM0, CM1, OCD, FRA0, FRA1,
and FRA2 is enabled.
PRC0
0 : Disables w riting
1 : Enables w riting
Protect bit 1
Protect bit 2
Protect bit 3
Writing to registers PM0 and PM1 is enabled.
0 : Disables w riting
1 : Enables w riting
PRC1
PRC2
RW
RW
Writing to the PD0 register is enabled.
0 : Disables w riting
1 : Enables w riting(1)
Writing to registers VCA2, VW0C, VW1C, and
VW2C is enabled.
0 : Disables w riting
PRC3
RW
1 : Enables w riting
—
(b5-b4)
Reserved bits
Reserved bits
Set to 0.
RW
RO
—
(b7-b6)
When read, the content is 0.
NOTE:
1. This bit is set to 0 after w riting 1 to the PRC2 bit and executing a w rite to any address. Since the other bits are not
set to 0, set them to 0 by a program.
Figure 11.1
PRCR Register
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12.Interrupts
12. Interrupts
12.1 Interrupt Overview
12.1.1 Types of Interrupts
Figure 12.1 shows the Types of Interrupts.
Undefined instruction (UND instruction)
Overflow (INTO instruction)
BRK instruction
INT instruction
Software
(non-maskable interrupts)
Watchdog timer
Oscillation stop detection
Voltage monitor 1
Voltage monitor 2
Single step(2)
Interrupts
Special
(non-maskable interrupts)
Address break(2)
Address match
Hardware
Peripheral functions(1)
(maskable interrupts)
NOTES:
1. Peripheral function interrupts in the MCU are used to generate peripheral interrupts.
2. Do not use this interrupt. This is for use with development tools only.
Figure 12.1
Types of Interrupts
• Maskable Interrupts:
• Non-Maskable Interrupts:
The interrupt enable flag (I flag) enables or disables these interrupts. The
interrupt priority order can be changed based on the interrupt priority level.
The interrupt enable flag (I flag) does not enable or disable these interrupts.
The interrupt priority order cannot be changed based on interrupt priority
level.
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12.Interrupts
12.1.2 Software Interrupts
A software interrupt is generated when an instruction is executed. Software interrupts are non-maskable.
12.1.2.1 Undefined Instruction Interrupt
The undefined instruction interrupt is generated when the UND instruction is executed.
12.1.2.2 Overflow Interrupt
The overflow interrupt is generated when the O flag is set to 1 (arithmetic operation overflow) and the INTO
instruction is executed. Instructions that set the O flag are: ABS, ADC, ADCF, ADD, CMP, DIV, DIVU, DIVX,
NEG, RMPA, SBB, SHA, and SUB.
12.1.2.3 BRK Interrupt
A BRK interrupt is generated when the BRK instruction is executed.
12.1.2.4 INT Instruction Interrupt
An INT instruction interrupt is generated when the INT instruction is executed. The INT instruction can select
software interrupt numbers 0 to 63. Software interrupt numbers 3 to 31 are assigned to the peripheral function
interrupt. Therefore, the MCU executes the same interrupt routine when the INT instruction is executed as
when a peripheral function interrupt is generated. For software interrupt numbers 0 to 31, the U flag is saved to
the stack during instruction execution and the U flag is set to 0 (ISP selected) before the interrupt sequence is
executed. The U flag is restored from the stack when returning from the interrupt routine. For software interrupt
numbers 32 to 63, the U flag does not change state during instruction execution, and the selected SP is used.
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12.Interrupts
12.1.3 Special Interrupts
Special interrupts are non-maskable.
12.1.3.1 Watchdog Timer Interrupt
The watchdog timer interrupt is generated by the watchdog timer. For details of the watchdog timer, refer to 13.
Watchdog Timer.
12.1.3.2 Oscillation Stop Detection Interrupt
The oscillation stop detection interrupt is generated by the oscillation stop detection function. For details of the
oscillation stop detection function, refer to 10. Clock Generation Circuit.
12.1.3.3 Voltage Monitor 1 Interrupt (For N, D Version Only)
The voltage monitor 1 interrupt is generated by the voltage detection circuit. For details of the voltage detection
circuit, refer to 6. Voltage Detection Circuit.
12.1.3.4 Voltage Monitor 2 Interrupt
The voltage monitor 2 interrupt is generated by the voltage detection circuit. For details of the voltage detection
circuit, refer to 6. Voltage Detection Circuit.
12.1.3.5 Single-Step Interrupt, and Address Break Interrupt
Do not use these interrupts. They are for use by development tools only.
12.1.3.6 Address Match Interrupt
The address match interrupt is generated immediately before executing an instruction that is stored at an
address indicated by registers RMAD0 to RMAD1 when the AIER0 or AIER1 bit in the AIER register is set to
1 (address match interrupt enable). For details of the address match interrupt, refer to 12.4 Address Match
Interrupt.
12.1.4 Peripheral Function Interrupt
The peripheral function interrupt is generated by the internal peripheral function of the MCU and is a maskable
interrupt. Refer to Table 12.2 Relocatable Vector Tables for sources of the peripheral function interrupt. For
details of peripheral functions, refer to the descriptions of individual peripheral functions.
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12.Interrupts
12.1.5 Interrupts and Interrupt Vectors
There are 4 bytes in each vector. Set the starting address of an interrupt routine in each interrupt vector. When
an interrupt request is acknowledged, the CPU branches to the address set in the corresponding interrupt vector.
Figure 12.2 shows an Interrupt Vector.
MSB
LSB
Vector address (L)
Low address
Mid address
0 0 0 0
0 0 0 0
High address
0 0 0 0
Vector address (H)
Figure 12.2
Interrupt Vector
12.1.5.1 Fixed Vector Tables
The fixed vector tables are allocated addresses 0FFDCh to 0FFFFh.
Table 12.1 lists the Fixed Vector Tables. The vector addresses (H) of fixed vectors are used by the ID code
check function. For details, refer to 19.3 Functions to Prevent Rewriting of Flash Memory.
Table 12.1
Fixed Vector Tables
Vector Addresses
Address (L) to (H)
Interrupt Source
Remarks
Reference
Undefined instruction
0FFDCh to 0FFDFh Interrupt on UND
instruction
R8C/Tiny Series Software
Manual
Overflow
0FFE0h to 0FFE3h Interrupt on INTO
instruction
BRK instruction
0FFE4h to 0FFE7h If the content of address
0FFE7h is FFh,
program execution
starts from the address
shown by the vector in
the relocatable vector
table.
Address match
0FFE8h to 0FFEBh
12.4 Address Match
Interrupt
(1)
0FFECh to 0FFEFh
0FFF0h to 0FFF3h
Single step
Watchdog timer,
13. Watchdog Timer
Oscillation stop detection,
10. Clock Generation Circuit
6. Voltage Detection Circuit
(2)
Voltage monitor 1
Voltage monitor 2
,
(1)
0FFF4h to 0FFF7h
0FFF8h to 0FFFBh
0FFFCh to 0FFFFh
Address break
(Reserved)
Reset
5. Resets
NOTES:
1. Do not use these interrupts. They are for use by development tools only.
2. For N, D version only.
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12.Interrupts
12.1.5.2 Relocatable Vector Tables
The relocatable vector tables occupy 256 bytes beginning from the starting address set in the INTB register.
Table 12.2 lists the Relocatable Vector Tables.
Table 12.2
Relocatable Vector Tables
Software
Interrupt
Number
Vector Addresses(1)
Address (L) to Address (H)
Interrupt Control
Register
Interrupt Source
Reference
BRK instruction(3)
+0 to +3 (0000h to 0003h)
0
−
R8C/Tiny Series Software
Manual
(Reserved)
(Reserved)
Timer RC
(Reserved)
Timer RE
(Reserved)
Key input
A/D
1 to 2
3 to 6
7
−
−
−
−
+28 to +31 (001Ch to 001Fh)
+40 to +43 (0028h to 002Bh)
TRCIC
−
14.3 Timer RC
8 to 9
10
−
TREIC
−
14.4 Timer RE
−
11 to 12
13
+52 to +55 (0034h to 0037h)
+56 to +59 (0038h to 003Bh)
+60 to +63 (003Ch to 003Fh)
KUPIC
ADIC
SSUIC/IICIC
12.3 Key Input Interrupt
18. A/D Converter
14
Clock synchronous
serial I/O with chip
select / I2C bus
interface(2)
15
16.2 Clock Synchronous
Serial I/O with Chip
Select (SSU),
16.3 I2C bus Interface
(Reserved)
16
17
18
19
20
21
22
23
24
25
−
−
UART0 transmit
UART0 receive
UART1 transmit
UART1 receive
(Reserved)
+68 to +71 (0044h to 0047h)
+72 to +75 (0048h to 004Bh)
+76 to +79 (004Ch to 004Fh)
+80 to +83 (0050h to 0053h)
S0TIC
S0RIC
S1TIC
S1RIC
−
15. Serial Interface
−
Timer RA
+88 to +91 (0058h to 005Bh)
TRAIC
−
14.1 Timer RA
−
(Reserved)
Timer RB
+96 to +99 (0060h to 0063h)
+100 to +103 (0064h to 0067h)
TRBIC
INT1IC
14.2 Timer RB
INT1
12.2 INT Interrupt
+104 to +107 (0068h to 006Bh)
26
INT3IC
INT3
(Reserved)
(Reserved)
27
28
29
−
−
−
−
+116 to +119 (0074h to 0077h)
INT0IC
INT0
12.2 INT Interrupt
(Reserved)
(Reserved)
Software interrupt(3)
30
31
−
−
−
−
−
+128 to +131 (0080h to 0083h) to 32 to 63
+252 to +255 (00FCh to 00FFh)
R8C/Tiny Series Software
Manual
NOTES:
1. These addresses are relative to those in the INTB register.
2. The IICSEL bit in the PMR register switches functions.
3. The I flag does not disable these interrupts.
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12.Interrupts
12.1.6 Interrupt Control
The following describes enabling and disabling the maskable interrupts and setting the priority for
acknowledgement. The explanation does not apply to nonmaskable interrupts.
Use the I flag in the FLG register, IPL, and bits ILVL2 to ILVL0 in each interrupt control register to enable or
disable maskable interrupts. Whether an interrupt is requested is indicated by the IR bit in each interrupt control
register.
Figure 12.3 shows the Interrupt Control Register, Figure 12.4 shows Registers TRCIC and SSUIC/IICIC and
Figure 12.5 shows the INTiIC Register (i=0, 1, 3).
Interrupt Control Register(2)
Symbol
TREIC
Address
004Ah
004Dh
004Eh
0051h
0052h
0053h
0054h
0056h
After Reset
XXXXX000b
XXXXX000b
XXXXX000b
XXXXX000b
XXXXX000b
XXXXX000b
XXXXX000b
XXXXX000b
KUPIC
ADIC
S0TIC
S0RIC
S1TIC
S1RIC
TRAIC
b7 b6 b5 b4 b3 b2 b1 b0
0058h
XXXXX000b
TRBIC
Bit Symbol
Bit Name
Interrupt priority level select bits
Function
RW
RW
b2 b1 b0
0 0 0 : Level 0 (interrupt disable)
0 0 1 : Level 1
ILVL0
ILVL1
0 1 0 : Level 2
0 1 1 : Level 3
1 0 0 : Level 4
1 0 1 : Level 5
1 1 0 : Level 6
1 1 1 : Level 7
RW
RW
ILVL2
IR
Interrupt request bit
0 : Requests no interrupt
1 : Requests interrupt
RW(1)
—
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is undefined.
NOTES:
1. Only 0 can be w ritten to the IR bit. Do not w rite 1.
2. Rew rite the interrupt control register w hen the interrupt request w hich is applicable for its register is not generated.
Ref er to
.
12.6.5 Changing Interrupt Control Register Contents
Figure 12.3
Interrupt Control Register
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Interrupt Control Register(1)
12.Interrupts
Symbol
TRCIC
SSUIC/IICIC
Address
0047h
After Reset
XXXXX000b
b7 b6 b5 b4 b3 b2 b1 b0
(2)
004Fh
XXXXX000b
Bit Symbol
Bit Name
Interrupt priority level select bits
Function
RW
RW
b2 b1 b0
0 0 0 : Level 0 (interrupt disable)
0 0 1 : Level 1
ILVL0
ILVL1
0 1 0 : Level 2
0 1 1 : Level 3
1 0 0 : Level 4
1 0 1 : Level 5
RW
RW
1 1 0 : Level 6
ILVL2
IR
1 1 1 : Level 7
Interrupt request bit
0 : Requests no interrupt
1 : Requests interrupt
RO
—
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is undefined.
NOTES:
1. Rew rite the interrupt control register w hen the interrupt request w hich is applicable for the register is not generated.
Ref er to
.
12.6.5 Changing Interrupt Control Register Contents
2. The IICSEL bit in the PMR register sw itches functions.
Figure 12.4
Registers TRCIC and SSUIC/IICIC
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12.Interrupts
INTi Interrupt Control Register (i=0, 1, 3)(2)
Symbol
INT1IC
Address
0059h
After Reset
XX00X000b
XX00X000b
005Ah
INT3IC
b7 b6 b5 b4 b3 b2 b1 b0
0
INT0IC
005Dh
XX00X000b
Bit Symbol
ILVL0
Bit Name
Function
RW
RW
b2 b1 b0
Interrupt priority level select bits
0 0 0 : Level 0 (interrupt disable)
0 0 1 : Level 1
0 1 0 : Level 2
0 1 1 : Level 3
1 0 0 : Level 4
1 0 1 : Level 5
1 1 0 : Level 6
ILVL1
ILVL2
RW
RW
1 1 1 : Level 7
Interrupt request bit
Polarity sw itch bit(4)
Reserved bit
0 : Requests no interrupt
1 : Requests interrupt
IR
RW(1)
RW
RW
—
0 : Selects falling edge
1 : Selects rising edge(3)
POL
—
(b5)
Set to 0.
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is undefined.
NOTES:
1. Only 0 can be w ritten to the IR bit. (Do not w rite 1.)
2. Rew rite the interrupt control register w hen the interrupt request w hich is applicable for the register is not generated.
Ref er to
.
12.6.5 Changing Interrupt Control Register Contents
3. If the INTiPL bit in the INTEN register is set to 1 (both edges), set the POL bit to 0 (selects falling edge).
4. The IR bit may be set to 1 (requests interrupt) w hen the POL bit is rew ritten. Refer to
12.6.4 Changing Interrupt
Sources.
Figure 12.5
INTiIC Register (i=0, 1, 3)
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12.Interrupts
12.1.6.1 I Flag
The I flag enables or disables maskable interrupts. Setting the I flag to 1 (enabled) enables maskable interrupts.
Setting the I flag to 0 (disabled) disables all maskable interrupts.
12.1.6.2 IR Bit
The IR bit is set to 1 (interrupt requested) when an interrupt request is generated. Then, when the interrupt
request is acknowledged and the CPU branches to the corresponding interrupt vector, the IR bit is set to 0 (=
interrupt not requested).
The IR bit can be set to 0 by a program. Do not write 1 to this bit.
However, the IR bit operations of the timer RC Interrupt, Clock Synchronous Serial I/O with Chip Select
2
Interrupt and the I C bus Interface Interrupt are different. Refer to 12.5 Timer RC Interrupt, Clock
2
Synchronous Serial I/O with Chip Select Interrupts, and I C bus Interface Interrupt (Interrupts with
Multiple Interrupt Request Sources).
12.1.6.3 ILVL2 to ILVL0 Bits and IPL
Interrupt priority levels can be set using bits ILVL2 to ILVL0.
Table 12.3 lists the Settings of Interrupt Priority Levels and Table 12.4 lists the Interrupt Priority Levels
Enabled by IPL.
The following are conditions under which an interrupt is acknowledged:
• I flag = 1
• IR bit = 1
• Interrupt priority level > IPL
The I flag, IR bit, bits ILVL2 to ILVL0, and IPL are independent of each other. They do not affect one another.
Table 12.3
Settings of Interrupt Priority
Levels
Table 12.4
Interrupt Priority Levels Enabled by
IPL
ILVL2 to ILVL0 Bits
Interrupt Priority Level
Priority Order
IPL
000b
Enabled Interrupt Priority Levels
Interrupt level 1 and above
Interrupt level 2 and above
Interrupt level 3 and above
Interrupt level 4 and above
Interrupt level 5 and above
Interrupt level 6 and above
Interrupt level 7 and above
All maskable interrupts are disabled
000b
001b
010b
011b
100b
101b
110b
111b
Level 0 (interrupt disabled)
−
Level 1
Level 2
Level 3
Level 4
Level 5
Level 6
Level 7
Low
001b
010b
011b
100b
101b
110b
High
111b
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12.Interrupts
12.1.6.4 Interrupt Sequence
An interrupt sequence is performed between an interrupt request acknowledgement and interrupt routine
execution.
When an interrupt request is generated while an instruction is being executed, the CPU determines its interrupt
priority level after the instruction is completed. The CPU starts the interrupt sequence from the following cycle.
However, for the SMOVB, SMOVF, SSTR, or RMPA instructions, if an interrupt request is generated while the
instruction is being executed, the MCU suspends the instruction to start the interrupt sequence. The interrupt
sequence is performed as indicated below.
Figure 12.6 shows the Time Required for Executing Interrupt Sequence.
(1) The CPU gets interrupt information (interrupt number and interrupt request level) by reading address
(2)
00000h. The IR bit for the corresponding interrupt is set to 0 (interrupt not requested).
(1)
(2) The FLG register is saved to a temporary register in the CPU immediately before entering the
interrupt sequence.
(3) The I, D and U flags in the FLG register are set as follows:
The I flag is set to 0 (interrupts disabled).
The D flag is set to 0 (single-step interrupt disabled).
The U flag is set to 0 (ISP selected).
However, the U flag does not change state if an INT instruction for software interrupt number 32 to 63
is executed.
(1)
(4) The CPU’s internal temporary register is saved to the stack.
(5) The PC is saved to the stack.
(6) The interrupt priority level of the acknowledged interrupt is set in the IPL.
(7) The starting address of the interrupt routine set in the interrupt vector is stored in the PC.
After the interrupt sequence is completed, instructions are executed from the starting address of the interrupt
routine.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
CPU Clock
Address Bus
Data Bus
RD
Address
0000h
Undefined
SP-2 SP-1 SP-4
SP-3
VEC
VEC+1
VEC+2
PC
Interrupt
information
SP-3
contents
VEC+1
contents
VEC+2
contents
SP-2
SP-1
SP-4
VEC
contents
Undefined
Undefined
contents contents contents
WR
The indeterminate state depends on the instruction queue buffer. A read cycle occurs when the instruction queue buffer is
ready to acknowledge instructions.
Figure 12.6
Time Required for Executing Interrupt Sequence
NOTES:
1. This register cannot be used by user.
2. Refer to 12.5 Timer RC Interrupt, Clock Synchronous Serial I/O with Chip Select Interrupts, and
2
I C bus Interface Interrupt (Interrupts with Multiple Interrupt Request Sources) for the IR bit
operations of the timer RC Interrupt, Clock Synchronous Serial I/O with Chip Select Interrupt, and the
2
I C bus Interface Interrupt.
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12.Interrupts
12.1.6.5 Interrupt Response Time
Figure 12.7 shows the Interrupt Response Time. The interrupt response time is the period between an interrupt
request generation and the execution of the first instruction in the interrupt routine. The interrupt response time
includes the period between interrupt request generation and the completion of execution of the instruction
(refer to (a) in Figure 12.7) and the period required to perform the interrupt sequence (20 cycles, refer to (b) in
Figure 12.7).
Interrupt request is generated. Interrupt request is acknowledged.
Time
Instruction in
interrupt routine
Instruction
Interrupt sequence
(a)
20 cycles (b)
Interrupt response time
(a) Period between interrupt request generation and the completion of execution of an
instruction. The length of time varies depending on the instruction being executed. The
DIVX instruction requires the longest time, 30 cycles (no wait and when the register is set
as the divisor)
(b) 21 cycles for address match and single-step interrupts.
Figure 12.7
Interrupt Response Time
12.1.6.6 IPL Change when Interrupt Request is Acknowledged
When an interrupt request of a maskable interrupt is acknowledged, the interrupt priority level of the
acknowledged interrupt is set in the IPL.
When a software interrupt or special interrupt request is acknowledged, the level listed in Table 12.5 is set in the
IPL.
Table 12.5 lists the IPL Value When Software or Special Interrupt Is Acknowledged.
Table 12.5
IPL Value When Software or Special Interrupt Is Acknowledged
Interrupt Source Value Set in IPL
(1)
7
Watchdog timer, oscillation stop detection, voltage monitor 1
voltage monitor 2, address break
,
Software, address match, single-step
Not changed
NOTE:
1. For N, D version only.
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12.Interrupts
12.1.6.7 Saving a Register
In the interrupt sequence, the FLG register and PC are saved to the stack.
After an extended 16 bits, 4 high-order bits in the PC and 4 high-order (IPL) and 8 low-order bits in the FLG
register, are saved to the stack, the 16 low-order bits in the PC are saved.
Figure 12.8 shows the Stack State Before and After Acknowledgement of Interrupt Request.
The other necessary registers are saved by a program at the beginning of the interrupt routine. The PUSHM
(1)
instruction can save several registers in the register bank being currently used with a single instruction.
NOTE:
1. Selectable from registers R0, R1, R2, R3, A0, A1, SB, and FB.
Stack
Stack
Address
Address
MSB
LSB
MSB
LSB
[SP]
New SP value
m−4
m−3
m−4
m−3
PCL
PCM
m−2
m−1
m
m−2
FLGL
m−1
FLGH
PCH
[SP]
m
SP value before
interrupt is generated
Previous stack contents
Previous stack contents
Previous stack contents
Previous stack contents
PCH
PCM
PCL
: 4 High-order bits of PC
: 8 Middle-order bits of PC
: 8 Low-order bits of PC
m+1
m+1
FLGH : 4 High-order bits of FLG
FLGL : 8 Low-order bits of FLG
Stack state before interrupt request
is acknowledged
Stack state after interrupt request
is acknowledged
NOTE:
1. When executing software number 32 to 63 INT instructions,
this SP is specified by the U flag. Otherwise it is ISP.
Figure 12.8
Stack State Before and After Acknowledgement of Interrupt Request
The register saving operation, which is performed as part of the interrupt sequence, saved in 8 bits at a time in
four steps.
Figure 12.9 shows the Register Saving Operation.
Stack
Address
Sequence in which
order registers are
saved
[SP]−5
[SP]−4
[SP]−3
(3)
(4)
PCL
PCM
Saved, 8 bits at a time
[SP]−2
[SP]−1
(1)
(2)
FLGL
FLGH
PCH
PCH
PCM
PCL
: 4 High-order bits of PC
: 8 Middle-order bits of PC
: 8 Low-order bits of PC
[SP]
FLGH : 4 High-order bits of FLG
FLGL : 8 Low-order bits of FLG
Completed saving
registers in four
operations.
NOTE:
1. [SP] indicates the initial value of the SP when an interrupt request is acknowledged.
After registers are saved, the SP content is [SP] minus 4. When executing software
number 32 to 63 INT instructions, this SP is specified by the U flag. Otherwise it is
ISP.
Figure 12.9
Register Saving Operation
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12.Interrupts
12.1.6.8 Returning from an Interrupt Routine
When the REIT instruction is executed at the end of an interrupt routine, the FLG register and PC, which have
been saved to the stack, are automatically restored. The program, that was running before the interrupt request
was acknowledged, starts running again.
Restore registers saved by a program in an interrupt routine using the POPM instruction or others before
executing the REIT instruction.
12.1.6.9 Interrupt Priority
If two or more interrupt requests are generated while a single instruction is being executed, the interrupt with
the higher priority is acknowledged.
Set bits ILVL2 to ILVL0 to select the desired priority level for maskable interrupts (peripheral functions).
However, if two or more maskable interrupts have the same priority level, their interrupt priority is resolved by
hardware, and the higher priority interrupts acknowledged.
The priority levels of special interrupts, such as reset (reset has the highest priority) and watchdog timer, are set
by hardware.
Figure 12.10 shows the Priority Levels of Hardware Interrupts.
The interrupt priority does not affect software interrupts. The MCU jumps to the interrupt routine when the
instruction is executed.
High
Reset
Address break
Watchdog timer
Oscillation stop detection
Voltage monitor 1(1)
Voltage monitor 2
Peripheral function
Single step
Address match
Low
NOTE:
1. For N, D version only.
Figure 12.10 Priority Levels of Hardware Interrupts
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12.Interrupts
12.1.6.10 Interrupt Priority Judgement Circuit
The interrupt priority judgement circuit selects the highest priority interrupt, as shown in Figure 12.11.
Priority level of interrupt
Highest
Level 0 (default value)
INT3
Timer RB
Timer RA
INT0
INT1
Timer RC
Priority of peripheral function interrupts
(if priority levels are same)
UART1 receive
UART0 receive
A/D conversion
Timer RE
UART1 transmit
UART0 transmit
SSU / I2C bus(1)
Key input
Lowest
IPL
Interrupt request level
judgment output signal
Interrupt request
acknowledged
I flag
Address match
Watchdog timer
Oscillation stop detection
Voltage monitor 1(2)
Voltage monitor 2
NOTES:
1. The IICSEL bit in the PMR register switches functions.
2. For N, D version only.
Figure 12.11 Interrupt Priority Level Judgement Circuit
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12.Interrupts
12.2 INT Interrupt
12.2.1 INTi Interrupt (i = 0, 1, 3)
The INTi interrupt is generated by an INTi input. When using the INTi interrupt, the INTiEN bit in the INTEN
register is set to 1 (enable). The edge polarity is selected using the INTiPL bit in the INTEN register and the
POL bit in the INTiIC register.
Inputs can be passed through a digital filter with three different sampling clocks.
Table 12.6 lists the Pin Configuration of INT Interrupt. Figure 12.12 shows the INTEN Register. Figure 12.13
shows the INTF Register.
Table 12.6
Pin Configuration of INT Interrupt
Pin name Input/Output
Input
Function
INT0 (P4_5)
INT0 interrupt input, Timer RB external trigger input,
Timer RC pulse output forced cutoff input
(1)
Input
Input
INT1 interrupt input
INT3 interrupt input
INT1 (P1_5, P1_7, or P3_6)
INT3 (P3_3)
NOTE:
1. The INT1 pin is selected by the INT1SEL bit in the PMR register and the TIOSEL bit in the TRAIOC
register. Refer to 7. Programmable I/O Ports for details.
External Input Enable Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
INTEN
Address
00F9h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
____
0 : Disable
1 : Enable
INT0 input enable bit
INT0EN
INT0PL
INT1EN
INT1PL
____
INT0 input polarity select bit(1,2)
0 : One edge
1 : Both edges
RW
RW
RW
RW
RW
RW
____
0 : Disable
1 : Enable
INT1 input enable bit
____
INT1 input polarity select bit(1,2)
0 : One edge
1 : Both edges
—
(b5-b4)
Reserved bits
Set to 0.
____
0 : Disable
1 : Enable
INT3 input enable bit
INT3EN
INT3PL
____
INT3 input polarity select bit(1,2)
0 : One edge
1 : Both edges
NOTES:
1. When setting the INTiPL bit (i = 0 to 3) to 1 (both edges), set the POL bit in the INTiIC register to 0 (selects falling
edge).
2. The IR bit in the INTiIC register may be set to 1 (requests interrupt) w hen the INTiPL bit is rew ritten. Refer to
12.6.4
Changing Interrupt Sources.
Figure 12.12 INTEN Register
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______
INT0 Input Filter Select Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
Address
00FAh
After Reset
00h
INTF
Bit Symbol
Bit Name
Function
RW
RW
_____
b1 b0
INT0 input filter select bits
0 0 : No filter
INT0F0
INT0F1
INT1F0
INT1F1
0 1 : Filter w ith f1 sampling
1 0 : Filter w ith f8 sampling
1 1 : Filter w ith f32 sampling
RW
RW
_____
b3 b2
INT1 input filter select bits
0 0 : No filter
0 1 : Filter w ith f1 sampling
1 0 : Filter w ith f8 sampling
1 1 : Filter w ith f32 sampling
RW
RW
RW
—
(b5-b4)
Reserved bits
Set to 0.
_____
b7 b6
INT3 input filter select bits
0 0 : No filter
INT3F0
INT3F1
0 1 : Filter w ith f1 sampling
1 0 : Filter w ith f8 sampling
1 1 : Filter w ith f32 sampling
RW
Figure 12.13 INTF Register
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12.Interrupts
12.2.2 INTi Input Filter (i = 0, 1, 3)
The INTi input contains a digital filter. The sampling clock is selected by bits INTiF1 to INTiF0 in the INTF
register. The IR bit in the INTiIC register is set to 1 (interrupt requested) when the INTi level is sampled for
every sampling clock and the sampled input level matches three times.
Figure 12.14 shows the Configuration of INTi Input Filter. Figure 12.15 shows an Operating Example of INTi
Input Filter.
INTiF1 to INTiF0
= 01b
f1
Sampling clock
= 10b
f8
= 11b
INTiEN
f32
Other than
INTiF1 to INTiF0
= 00b
INTi
INTi interrupt
Digital filter
(input level
matches 3x)
Port direction
register(1)
= 00b
INTiPL = 0
INTiPL = 1
Both edges
detection
circuit
INTiF0, INTiF1: Bits in INTF register
INTiEN, INTiPL: Bits in INTEN register
i = 0, 1, 3
NOTE:
1. INT0: Port P4_5 direction register
INT1: Port P1_5 direction register when using the P1_5 pin
Port P1_7 direction register when using the P1_7 pin
INT3: Port P3_3 direction register
Figure 12.14 Configuration of INTi Input Filter
INTi input
Sampling
timing
IR bit in
INTiIC register
Set to 0 in program
This is an operation example when bits INTiF1 to INTiF0 in the
INTiF register are set to 01b, 10b, or 11b (passing digital filter).
i = 0, 1, 3
Figure 12.15 Operating Example of INTi Input Filter
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12.Interrupts
12.3 Key Input Interrupt
A key input interrupt request is generated by one of the input edges of the K10 to K13 pins. The key input interrupt
can be used as a key-on wake-up function to exit wait or stop mode.
The KIiEN (i = 0 to 3) bit in the KIEN register can select whether the pins are used as KIi input. The KIiPL bit in
the KIEN register can select the input polarity.
When inputting “L” to the KIi pin which sets the KIiPL bit to 0 (falling edge), the input of the other pins K10 to
K13 is not detected as interrupts. Also, when inputting “H” to the KIi pin, which sets the KIiPL bit to 1 (rising
edge), the input of the other pins K10 to K13 is not detected as interrupts.
Figure 12.16 shows a Block Diagram of Key Input Interrupt.
PU02 bit in PUR0 register
KUPIC register
Pull-up
transistor
PD1_3 bit in PD1 register
KI3EN bit
PD1_3 bit
KI3PL = 0
KI3
KI3PL = 1
KI2EN bit
Pull-up
transistor
PD1_2 bit
KI2PL = 0
Interrupt control
circuit
Key input interrupt
request
KI2
KI1
KI0
KI2PL = 1
KI1EN bit
PD1_1 bit
Pull-up
transistor
KI1PL = 0
KI1PL = 1
KI0EN, KI1EN, KI2EN, KI3EN,
KI0PL, KI1PL, KI2PL, KI3PL: Bits in KIEN register
PD1_0, PD1_1, PD1_2, PD1_3: Bits in PD1 register
KI0EN bit
PD1_0 bit
Pull-up
transistor
KI0PL = 0
KI0PL = 1
Figure 12.16 Block Diagram of Key Input Interrupt
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12.Interrupts
Key Input Enable Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
KIEN
Address
00FBh
After Reset
00h
Bit Symbol
Bit Name
KI0 input enable bit
Function
RW
RW
0 : Disable
1 : Enable
KI0EN
KI0PL
KI1EN
KI1PL
KI2EN
KI2PL
KI3EN
KI0 input polarity select bit
KI1 input enable bit
0 : Falling edge
1 : Rising edge
RW
RW
RW
RW
RW
RW
RW
0 : Disable
1 : Enable
KI1 input polarity select bit
KI2 input enable bit
0 : Falling edge
1 : Rising edge
0 : Disable
1 : Enable
KI2 input polarity select bit
KI3 input enable bit
0 : Falling edge
1 : Rising edge
0 : Disable
1 : Enable
KI3 input polarity select bit
0 : Falling edge
1 : Rising edge
KI3PL
NOTE:
1. The IR bit in the KUPIC register may be set to 1 (requests interrupt) w hen the KIEN register is rew ritten.
Ref er to
12.6.4 Changing Interrupt Sources.
Figure 12.17 KIEN Register
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12.Interrupts
12.4 Address Match Interrupt
An address match interrupt request is generated immediately before execution of the instruction at the address
indicated by the RMADi register (i = 0 or 1). This interrupt is used as a break function by the debugger. When
using the on-chip debugger, do not set an address match interrupt (registers of AIER, RMAD0, and RMAD1 and
fixed vector tables) in a user system.
Set the starting address of any instruction in the RMADi register. Bits AIER0 and AIER1 in the AIER0 register can
be used to select enable or disable of the interrupt. The I flag and IPL do not affect the address match interrupt.
The value of the PC (refer to 12.1.6.7 Saving a Register for the value of the PC) which is saved to the stack when
an address match interrupt is acknowledged varies depending on the instruction at the address indicated by the
RMADi register. (The appropriate return address is not saved on the stack.) When returning from the address match
interrupt, return by one of the following means:
• Change the content of the stack and use the REIT instruction.
• Use an instruction such as POP to restore the stack as it was before the interrupt request was acknowledged.
Then use a jump instruction.
Table 12.7 lists the Values of PC Saved to Stack when Address Match Interrupt is Acknowledged.
Figure 12.18 shows Registers AIER and RMAD0 to RMAD1.
Table 12.7
Values of PC Saved to Stack when Address Match Interrupt is Acknowledged
Address Indicated by RMADi Register (i = 0 or 1) PC Value Saved
(1)
• Instruction with 2-byte operation code(2)
Address indicated by
RMADi register + 2
(2)
• Instruction with 1-byte operation code
ADD.B:S
OR.B:S
STNZ
CMP.B:S
JMPS
#IMM8,dest SUB.B:S #IMM8,dest AND.B:S #IMM8,dest
#IMM8,dest MOV.B:S #IMM8,dest STZ
#IMM8,dest STZX #IMM81,#IMM82,dest
#IMM8,dest PUSHM src POPM
#IMM8 JSRS #IMM8
#IMM,dest (however, dest = A0 or A1)
#IMM8,dest
dest
MOV.B:S
Instructions other than the above
Address indicated by
RMADi register + 1
NOTES:
1. Refer to the 12.1.6.7 Saving a Register for the PC value saved.
2. Operation code: Refer to the R8C/Tiny Series Software Manual (REJ09B0001).
Chapter 4. Instruction Code/Number of Cycles contains diagrams showing
operation code below each syntax. Operation code is shown in the bold frame in
the diagrams.
Table 12.8
Correspondence Between Address Match Interrupt Sources and Associated Registers
Address Match Interrupt Source Address Match Interrupt Enable Bit Address Match Interrupt Register
Address match interrupt 0
Address match interrupt 1
AIER0
AIER1
RMAD0
RMAD1
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Address Match Interrupt Enable Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
AIER
Address
0013h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
Address match interrupt 0 enable bit 0 : Disable
1 : Enable
AIER0
AIER1
Address match interrupt 1 enable bit 0 : Disable
1 : Enable
RW
—
—
(b7-b2)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Address Match Interrupt Register i (i = 0 or 1)
(b23)
b7
(b19)
b3
(b16) (b15)
b0 b7
(b8)
b0 b7
b0
Symbol
RMAD0
RMAD1
Address
0012h-0010h
0016h-0014h
After Reset
000000h
000000h
Function
Setting Range
RW
Address setting register for address match interrupt
00000h to FFFFFh
RW
—
—
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
(b7-b4)
Figure 12.18 Registers AIER and RMAD0 to RMAD1
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12.Interrupts
12.5 Timer RC Interrupt, Clock Synchronous Serial I/O with Chip Select
2
Interrupts, and I C bus Interface Interrupt (Interrupts with Multiple Interrupt
Request Sources)
2
The timer RC interrupt, clock synchronous serial I/O with chip select interrupt, and I C bus interface interrupt each
have multiple interrupt request sources. An interrupt request is generated by the logical OR of several interrupt
request factors and is reflected in the IR bit in the corresponding interrupt control register. Therefore, each of these
peripheral functions has its own interrupt request source status register (status register) and interrupt request source
enable register (enable register) to control the generation of interrupt requests (change the IR bit in the interrupt
control register). Table 12.9 lists the Registers Associated with Timer RC Interrupt, Clock Synchronous Serial I/O
2
with Chip Select Interrupt, and I C bus Interface Interrupt and Figure 12.19 shows a Block Diagram of Timer RC
Interrupt.
Table 12.9
Registers Associated with Timer RC Interrupt, Clock Synchronous Serial I/O with
2
Chip Select Interrupt, and I C bus Interface Interrupt
Status Register of
Interrupt Request Source Interrupt Request Source
Enable Register of
Interrupt Control
Register
Timer RC
TRCSR
TRCIER
SSER
TRCIC
Clock synchronous serial SSSR
SSUIC
I/O with chip select
2
ICSR
ICIER
IICIC
I C bus interface
IMFA bit
Timer RC
IMIEA bit
interrupt request
(IR bit in TRCIC register)
IMFB bit
IMIEB bit
IMFC bit
IMIEC bit
IMFD bit
IMIED bit
OVF bit
OVIE bit
IMFA, IMFB, IMFC, IMFD, OVF: Bits in TRCSR register
IMIEA, IMIEB, IMIEC, IMIED, OVIE: Bits in TRCIER register
Figure 12.19 Block Diagram of Timer RC Interrupt
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12.Interrupts
As with other maskable interrupts, the timer RC interrupt, clock synchronous serial I/O with chip select interrupt,
2
and I C bus interface interrupt are controlled by the combination of the I flag, IR bit, bits ILVL0 to ILVL2, and IPL.
However, since each interrupt source is generated by a combination of multiple interrupt request sources, the
following differences from other maskable interrupts apply:
• When bits in the enable register corresponding to bits set to 1 in the status register are set to 1 (enable
interrupt), the IR bit in the interrupt control register is set to 1 (interrupt requested).
• When either bits in the status register or bits in the enable register corresponding to bits in the status register, or
both, are set to 0, the IR bit is set to 0 (interrupt not requested). Basically, even though the interrupt is not
acknowledged after the IR bit is set to 1, the interrupt request will not be maintained. Also, the IR bit is not set
to 0 even if 0 is written to the IR bit.
• Individual bits in the status register are not automatically set to 0 even if the interrupt is acknowledged.
Therefore, the IR bit is also not automatically set to 0 when the interrupt is acknowledged. Set each bit in the
status register to 0 in the interrupt routine. Refer to the status register figure for how to set individual bits in the
status register to 0.
• When multiple bits in the enable register are set to 1 and other request sources are generated after the IR bit is
set to 1, the IR bit remains 1.
• When multiple bits in the enable register are set to 1, determine by the status register which request source
causes an interrupt.
Refer to chapters of the individual peripheral functions (14.3 Timer RC, 16.2 Clock Synchronous Serial I/O with
2
Chip Select (SSU) and 16.3 I C bus Interface) for the status register and enable register.
Refer to 12.1.6 Interrupt Control for the interrupt control register.
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12.Interrupts
12.6 Notes on Interrupts
12.6.1 Reading Address 00000h
Do not read address 00000h by a program. When a maskable interrupt request is acknowledged, the CPU reads
interrupt information (interrupt number and interrupt request level) from 00000h in the interrupt sequence. At
this time, the acknowledged interrupt IR bit is set to 0.
If address 00000h is read by a program, the IR bit for the interrupt which has the highest priority among the
enabled interrupts is set to 0. This may cause the interrupt to be canceled, or an unexpected interrupt to be
generated.
12.6.2 SP Setting
Set any value in the SP before an interrupt is acknowledged. The SP is set to 0000h after reset. Therefore, if an
interrupt is acknowledged before setting a value in the SP, the program may run out of control.
12.6.3 External Interrupt and Key Input Interrupt
Either “L” level or an “H” level of width shown in the Electrical Characteristics is necessary for the signal input
to pins INT0, INT1, INT3 and pins KI0 to KI3, regardless of the CPU clock.
For details, refer to Table 20.21 (VCC = 5V), Table 20.27 (VCC = 3V), Table 20.33 (VCC = 2.2V), Table
20.52 (VCC = 5V), Table 20.58 (VCC = 3V) External Interrupt INTi (i = 0, 1, 3) Input.
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12.Interrupts
12.6.4 Changing Interrupt Sources
The IR bit in the interrupt control register may be set to 1 (interrupt requested) when the interrupt source
changes. When using an interrupt, set the IR bit to 0 (no interrupt requested) after changing the interrupt source.
In addition, changes of interrupt sources include all factors that change the interrupt sources assigned to
individual software interrupt numbers, polarities, and timing. Therefore, if a mode change of a peripheral
function involves interrupt sources, edge polarities, and timing, set the IR bit to 0 (no interrupt requested) after
the change. Refer to the individual peripheral function for its related interrupts.
Figure 12.20 shows an Example of Procedure for Changing Interrupt Sources.
Interrupt source change
Disable interrupts(2, 3)
Change interrupt source (including mode
of peripheral function)
Set the IR bit to 0 (interrupt not requested)
using the MOV instruction(3)
Enable interrupts(2, 3)
Change completed
IR bit:
The interrupt control register bit of an
interrupt whose source is changed.
NOTES:
1. Execute the above settings individually. Do not execute two
or more settings at once (by one instruction).
2. To prevent interrupt requests from being generated, disable
the peripheral function before changing the interrupt
source. In this case, use the I flag if all maskable interrupts
can be disabled. If all maskable interrupts cannot be
disabled, use bits ILVL0 to ILVL2 of the interrupt whose
source is changed.
3. Refer to 12.6.5 Changing Interrupt Control Register
Contents for the instructions to be used and usage notes.
Figure 12.20 Example of Procedure for Changing Interrupt Sources
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12.Interrupts
12.6.5 Changing Interrupt Control Register Contents
(a) The contents of an interrupt control register can only be changed while no interrupt requests
corresponding to that register are generated. If interrupt requests may be generated, disable interrupts
before changing the interrupt control register contents.
(b) When changing the contents of an interrupt control register after disabling interrupts, be careful to
choose appropriate instructions.
Changing any bit other than IR bit
If an interrupt request corresponding to a register is generated while executing the instruction, the IR bit
may not be set to 1 (interrupt requested), and the interrupt request may be ignored. If this causes a
problem, use the following instructions to change the register: AND, OR, BCLR, BSET
Changing IR bit
If the IR bit is set to 0 (interrupt not requested), it may not be set to 0 depending on the instruction used.
Therefore, use the MOV instruction to set the IR bit to 0.
(c) When disabling interrupts using the I flag, set the I flag as shown in the sample programs below. Refer
to (b) regarding changing the contents of interrupt control registers by the sample programs.
Sample programs 1 to 3 are for preventing the I flag from being set to 1 (interrupts enabled) before the interrupt
control register is changed for reasons of the internal bus or the instruction queue buffer.
Example 1: Use NOP instructions to prevent I flag from being set to 1 before interrupt control register
is changed
INT_SWITCH1:
FCLR
I
; Disable interrupts
AND.B #00H,0056H
NOP
NOP
; Set TRAIC register to 00h
;
FSET
I
; Enable interrupts
Example 2: Use dummy read to delay FSET instruction
INT_SWITCH2:
FCLR
AND.B #00H,0056H
MOV.W MEM,R0
I
; Disable interrupts
; Set TRAIC register to 00h
; Dummy read
FSET
I
; Enable interrupts
Example 3: Use POPC instruction to change I flag
INT_SWITCH3:
PUSHC FLG
FCLR
AND.B #00H,0056H
POPC FLG
I
; Disable interrupts
; Set TRAIC register to 00h
; Enable interrupts
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13. Watchdog Timer
13. Watchdog Timer
The watchdog timer is a function that detects when a program is out of control. Use of the watchdog timer is
recommended to improve the reliability of the system. The watchdog timer contains a 15-bit counter and allows
selection of count source protection mode enable or disable.
Table 13.1 lists information on the Count Source Protection Mode.
Refer to 5.7 Watchdog Timer Reset for details on the watchdog timer.
Figure 13.1 shows the Block Diagram of Watchdog Timer. Figure 13.2 shows Registers OFS and WDC. Figure 13.3
shows Registers WDTR, WDTS, and CSPR.
Table 13.1
Count Source Protection Mode
Count Source Protection
Mode Disabled
CPU clock
Count Source Protection
Mode Enabled
Item
Count source
Low-speed on-chip oscillator
clock
Count operation
Decrement
Count start condition
Either of the following can be selected
• After reset, count starts automatically
• Count starts by writing to WDTS register
Count stop condition
Reset condition of watchdog
timer
Stop mode, wait mode
• Reset
• Write 00h to the WDTR register before writing FFh
• Underflow
None
Operation at the time of underflow Watchdog timer interrupt or
watchdog timer reset
Watchdog timer reset
Prescaler
WDC7 = 0
1/16
CSPRO = 0
PM12 = 0
Watchdog timer
interrupt request
CPU clock
1/128
Watchdog timer
WDC7 = 1
PM12 = 1
Watchdog
timer reset
fOCO-S
CSPRO = 1
Set to
7FFFh(1)
Write to WDTR register
Internal reset signal
CSPRO: Bit in CSPR register
WDC7: Bit in WDC register
PM12: Bit in PM1 register
NOTE:
1. When the CSPRO bit is set to 1 (count source protection mode enabled), 0FFFh is set.
Figure 13.1
Block Diagram of Watchdog Timer
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13. Watchdog Timer
Option Function Select Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
1
1
Symbol
OFS
Address
0FFFFh
When Shipping
FFh(3)
Bit Symbol
Bit Name
Function
RW
Watchdog timer start
select bit
0 : Starts w atchdog timer automatically after reset
1 : Watchdog timer is inactive after reset
WDTON
RW
RW
RW
RW
RW
—
(b1)
Reserved bit
Set to 1.
ROM code protect
disabled bit
0 : ROM code protect disabled
1 : ROMCP1 enabled
ROMCR
ROM code protect bit
0 : ROM code protect enabled
1 : ROM code protect disabled
ROMCP1
—
(b4)
Reserved bit
Set to 1.
Voltage detection 0
circuit start bit(2, 4)
0 : Voltage monitor 0 reset enabled after hardw are
reset
LVD0ON
RW
1 : Voltage monitor 0 reset disabled after hardw are
reset
Voltage detection 1
circuit start bit(5, 6)
0 : Voltage monitor 1 reset enabled after hardw are
reset
LVD1ON
CSPROINI
RW
RW
1 : Voltage monitor 1 reset disabled after hardw are
reset
Count source protect
mode after reset select 1 : Count source protect mode disabled after reset
bit
0 : Count source protect mode enabled after reset
NOTES:
1. The OFS register is on the flash memory. Write to the OFS register w ith a program. After w riting is completed, do not
w rite additions to the OFS register.
2. The LVD0ON bit setting is valid only by a hardw are reset. To use the pow er-on reset, set the LVD0ON bit to 0
(voltage monitor 0 reset enabled after hardw are reset).
3. If the block including the OFS register is erased, FFh is set to the OFS register.
4. For N, D version only. For J, K version, set the LVD0ON bit to 1 (voltage monitor 0 reset disabled after hardw are
reset).
5. The LVD1ON bit setting is valid only by a hardw are reset. When the pow er-on reset function is used, set the
LVD1ON bit to 0 (voltage monitor 1 reset enabled after hardw are reset).
6. For J, K version only. For N, D version, set the LVD1ON bit to 1 (voltage monitor 1 reset disabled after hardw are
reset).
Watchdog Timer Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
WDC
Bit Symbol
Address
000Fh
After Reset
00X11111b
Function
Bit Name
RW
RO
—
(b4-b0)
High-order bits of w atchdog timer
—
(b5)
Reserved bit
Set to 0. When read, the content is undefined.
Set to 0.
RW
RW
RW
—
(b6)
Reserved bit
Prescaler select bit
0 : Divide-by-16
1 : Divide-by-128
WDC7
Figure 13.2
Registers OFS and WDC
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Watchdog Timer Reset Register
13. Watchdog Timer
b7
b0
Symbol
WDTR
Address
000Dh
After Reset
Undefined
Function
RW
WO
When 00h is w ritten before w riting FFh, the w atchdog timer is reset.(1)
The default value of the w atchdog timer is 7FFFh w hen count source protection
mode is disabled and 0FFFh w hen count source protection mode is enabled.(2)
NOTES:
1. Do not generate an interrupt betw een w hen 00h and FFh are w ritten.
2. When the CSPRO bit in the CSPR register is set to 1 (count source protection mode enabled),
0FFFh is set in the w atchdog timer.
Watchdog Timer Start Register
b7
b0
Symbol
WDTS
Address
000Eh
After Reset
Undefined
Function
The w atchdog timer starts counting after a w rite instruction to this register.
RW
WO
Count Source Protection Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0 0 0
Symbol
Address
001Ch
After Reset(1)
00h
CSPR
Bit Symbol
Bit Name
Function
RW
RW
—
(b6-b0)
Reserved Bits
Set to 0.
Count Source Protection Mode 0 : Count source protection mode disabled
Select Bit(2)
1 : Count source protection mode enabled
CSPRO
RW
NOTES:
1. When 0 is w ritten to the CSPROINI bit in the OFS register, the value after reset is 10000000b.
2. Write 0 before w riting 1 to set the CSPRO bit to 1.
0 cannot be set by a program.
Figure 13.3
Registers WDTR, WDTS, and CSPR
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13. Watchdog Timer
13.1 Count Source Protection Mode Disabled
The count source of the watchdog timer is the CPU clock when count source protection mode is disabled.
Table 13.2 lists the Specifications of Watchdog Timer (with Count Source Protection Mode Disabled).
Table 13.2
Specifications of Watchdog Timer (with Count Source Protection Mode Disabled)
Item Specification
Count source
CPU clock
Decrement
Count operation
Period
(1)
Division ratio of prescaler (n) × count value of watchdog timer (32768)
CPU clock
n: 16 or 128 (selected by WDC7 bit in WDC register)
Example: When the CPU clock frequency is 16 MHz and prescaler
divides by 16, the period is approximately 32.8 ms
(2)
Count start condition
The WDTON bit in the OFS register (0FFFFh) selects the operation
of the watchdog timer after a reset
• When the WDTON bit is set to 1 (watchdog timer is in stop state after
reset)
The watchdog timer and prescaler stop after a reset and the count
starts when the WDTS register is written to
• When the WDTON bit is set to 0 (watchdog timer starts automatically
after exiting)
The watchdog timer and prescaler start counting automatically after a
reset
Reset condition of watchdog
timer
• Reset
• Write 00h to the WDTR register before writing FFh
• Underflow
Count stop condition
Stop and wait modes (inherit the count from the held value after exiting
modes)
Operation at time of underflow • When the PM12 bit in the PM1 register is set to 0
Watchdog timer interrupt
• When the PM12 bit in the PM1 register is set to 1
Watchdog timer reset (Refer to 5.7 Watchdog Timer Reset)
NOTES:
1. The watchdog timer is reset when 00h is written to the WDTR register before FFh. The prescaler is
reset after the MCU is reset. Some errors in the period of the watchdog timer may be caused by the
prescaler.
2. The WDTON bit cannot be changed by a program. To set the WDTON bit, write 0 to bit 0 of address
0FFFFh with a flash programmer.
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13. Watchdog Timer
13.2 Count Source Protection Mode Enabled
The count source of the watchdog timer is the low-speed on-chip oscillator clock when count source protection
mode is enabled. If the CPU clock stops when a program is out of control, the clock can still be supplied to the
watchdog timer.
Table 13.3 lists the Specifications of Watchdog Timer (with Count Source Protection Mode Enabled).
Table 13.3
Specifications of Watchdog Timer (with Count Source Protection Mode Enabled)
Item Specification
Low-speed on-chip oscillator clock
Count source
Count operation
Period
Decrement
Count value of watchdog timer (4096)
Low-speed on-chip oscillator clock
Example: Period is approximately 32.8 ms when the low-speed on-chip
oscillator clock frequency is 125 kHz
(1)
Count start condition
The WDTON bit in the OFS register (0FFFFh) selects the operation
of the watchdog timer after a reset.
• When the WDTON bit is set to 1 (watchdog timer is in stop state after
reset)
The watchdog timer and prescaler stop after a reset and the count
starts when the WDTS register is written to
• When the WDTON bit is set to 0 (watchdog timer starts automatically
after reset)
The watchdog timer and prescaler start counting automatically after a
reset
Reset condition of watchdog
timer
• Reset
• Write 00h to the WDTR register before writing FFh
• Underflow
Count stop condition
None (The count does not stop in wait mode after the count starts. The
MCU does not enter stop mode.)
Operation at time of underflow Watchdog timer reset (Refer to 5.7 Watchdog Timer Reset)
Registers, bits
• When setting the CSPPRO bit in the CSPR register to 1 (count source
(2)
protection mode is enabled) , the following are set automatically
- Set 0FFFh to the watchdog timer
- Set the CM14 bit in the CM1 register to 0 (low-speed on-chip
oscillator on)
- Set the PM12 bit in the PM1 register to 1 (The watchdog timer is
reset when watchdog timer underflows)
• The following conditions apply in count source protection mode
- Writing to the CM10 bit in the CM1 register is disabled (It remains
unchanged even if it is set to 1. The MCU does not enter stop
mode.)
- Writing to the CM14 bit in the CM1 register is disabled (It remains
unchanged even if it is set to 1. The low-speed on-chip oscillator
does not stop.)
NOTES:
1. The WDTON bit cannot be changed by a program. To set the WDTON bit, write 0 to bit 0 of address
0FFFFh with a flash programmer.
2. Even if 0 is written to the CSPROINI bit in the OFS register, the CSPRO bit is set to 1. The
CSPROINI bit cannot be changed by a program. To set the CSPROINI bit, write 0 to bit 7 of address
0FFFFh with a flash programmer.
Rev.2.10 Sep 26, 2008 Page 140 of 453
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14.Timers
14. Timers
The microcomputer contains two 8-bit timers with 8-bit prescaler, a 16-bit timer, and a timer with a 4-bit counter, and
an 8-bit counter. The two 8-bit timers with the 8-bit prescaler contain Timer RA and Timer RB. These timers contain a
reload register to memorize the default value of the counter. The 16-bit timer is Timer RC which contains the input
capture and output compare. The 4 and 8-bit counters are Timer RE which contains the output compare. All these
timers operate independently.
Table 14.1 lists Functional Comparison of Timers.
Rev.2.10 Sep 26, 2008 Page 141 of 453
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14.Timers
Table 14.1
Functional Comparison of Timers
Item Timer RA
8-bit timer with 8- 8-bit timer with 8- 16-bit free-run timer (with 4-bit counter
Timer RB
Timer RC
Timer RE
Configuration
bit prescaler (with bit prescaler (with input capture and output
8-bit counter
reload register)
Decrement
• f1
reload register)
Decrement
• f1
compare)
Increment
• f1
Count
Count source(1)
Increment
• f4
• f2
• f2
• f2
• f8
• f8
• f8
• f4
• f32
• fOCO
• fC32
• Timer RA
underflow
• f8
• f32
• fC4
• fOCO40M
• TRCCLK
provided
Function Timer Mode
provided
provided
not provided
(input capture function,
output compare function)
not provided
not provided
Pulse Output Mode provided
not provided
not provided
not provided
not provided
Event Counter
Mode
provided
Pulse Width
provided
not provided
not provided
provided
not provided
not provided
not provided
not provided
not provided
not provided
Measurement Mode
Pulse Period
Measurement Mode
Programmable
Waveform
provided
not provided
Generation Mode
Programmable
One-Shot
generation Mode
Programmable Wait not provided
One-Shot
not provided
provided
provided
not provided
not provided
not provided
not provided
Generation Mode
Input Capture Mode not provided
not provided
not provided
provided
provided
not provided
provided
Output Compare
Mode
not provided
PWM Mode
PWM2 Mode
Real-Time Clock
Mode
not provided
not provided
not provided
not provided
not provided
not provided
provided
provided
not provided
not provided
not provided
provided(2)
Input Pin
TRAIO
−
INT0
INT0, TRCCLK, TRCTRG
TRCIOA, TRCIOB,
TRCIOC, TRCIOD
TRCIOA, TRCIOB,
TRCIOC, TRCIOD
Output Pin
TRAO
TRAIO
TRBO
TREO
Related Interrupt
Timer RA interrupt Timer RB interrupt Compare Match / Input
Timer RE
interrupt
INT1 interrupt
INT0 interrupt
Capture A to D interrupt
Overflow interrupt
INT0 interrupt
Timer Stop
NOTES:
provided
provided
provided
provided
1. For J, K version, fC4 and fC32 cannot be selected.
2. For N, D version only.
Rev.2.10 Sep 26, 2008 Page 142 of 453
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14.Timers
14.1 Timer RA
Timer RA is an 8-bit timer with an 8-bit prescaler.
The prescaler and timer each consist of a reload register and counter. The reload register and counter are allocated
at the same address, and can be accessed when accessing registers TRAPRE and TRA (refer to Tables 14.2 to 14.6
the Specifications of Each Mode).
The count source for timer RA is the operating clock that regulates the timing of timer operations such as counting
and reloading.
Figure 14.1 shows a Block Diagram of Timer RA. Figures 14.2 and 14.3 show the registers associated with timer
RA.
Timer RA contains the following five operating modes:
• Timer mode:
The timer counts the internal count source.
• Pulse output mode:
The timer counts the internal count source and outputs pulses which
invert the polarity by underflow of the timer.
• Event counter mode:
The timer counts external pulses.
• Pulse width measurement mode:
• Pulse period measurement mode:
The timer measures the pulse width of an external pulse.
The timer measures the pulse period of an external pulse.
Data bus
TCK2 to TCK0 bit
Reload
register
Reload
register
= 000b
TCKCUT TCSTF
bit bit
TMOD2 to TMOD0
= other than 010b
f1
= 001b
f8
= 010b
fOCO
Underflow signal
Timer RA interrupt
= 011b
Counter
TRAPRE register
(prescaler)
Counter
TRA register
(timer)
f2
fC32(1)
= 100b
TMOD2 to TMOD0
= 010b
TIPF1 to TIPF0 bits
= 01b
f1
f8
= 10b
= 11b
TMOD2 to TMOD0
= 011b or 100b
f32
TIPF1 to TIPF0 bits
= other than
000b
TIOSEL = 0
INT1/TRAIO (P1_7) pin
Digital
filter
Polarity
switching
Count control
circle
Measurement completion
signal
INT1/TRAIO (P1_5) pin
= 00b
TIOSEL = 1
TMOD2 to TMOD0 = 001b
TEDGSEL = 1
TOPCR bit
Toggle
flip-flop
Q
Q
CK
CLR
TOENA bit
TEDGSEL = 0
Write to TRAMR register
Write 1 to TSTOP bit
TRAO pin
TCSTF, TSTOP: TRACR register
TEDGSEL, TOPCR, TOENA, TIOSEL, TIPF1, TIPF0: TRAIOC register
TMOD2 to TMOD0, TCK2 to TCK0, TCKCUT: TRAMR register
NOTE:
1. For J, K version, fC32 cannot be selected.
Figure 14.1
Block Diagram of Timer RA
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14.Timers
Timer RA Control Register(4)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRACR
Address
0100h
After Reset
00h
Bit Symbol
Bit Name
Timer RA count start bit(1)
Function
RW
RW
0 : Count stops
1 : Count starts
TSTART
TCSTF
TSTOP
Timer RA count status flag(1) 0 : Count stops
1 : During count
RO
RW
—
Timer RA count forcible stop When this bit is set to 1, the count is forcibly
bit(2)
stopped. When read, its content is 0.
—
(b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Active edge judgment
flag(3, 5)
0 : Active edge not received
1 : Active edge received
TEDGF
TUNDF
RW
(end of measurement period)
Timer RA underflow flag(3, 5) 0 : No underflow
1 : Underflow
RW
—
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTES:
1. Ref er to
for precautions regarding bits TSTART and TCSTF.
14.1.6 Notes on Timer RA
2. When the TSTOPbit is set to 1, bits TSTART and TCSTF and registers TRAPREand TRA are set to the values after a
reset.
3. Bits TEDGF and TUNDF can be set to 0 by w riting 0 to these bits by a program. How ever, their value remains
unchanged w hen 1 is w ritten.
4. In pulse w idth measurement mode and pulse period measurement mode, use the MOV instruction to set the TRACR
register. If it is necessary to avoid changing the values of bits TEDGF and TUNDF, w rite 1 to them.
5. Set to 0 in timer mode, pulse output mode, and event counter mode.
Timer RA I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRAIOC
Bit Symbol
Address
0101h
After Reset
00h
Function
Bit Name
RW
RW
TRAIO polarity sw itch bit
Function varies depending on operating mode.
TEDGSEL
TOPCR
TOENA
TIOSEL
TRAIO output control bit
TRAO output enable bit
RW
RW
RW
RW
—
____
INT1/TRAIO select bit
TIPF0
TIPF1
TRAIO input filter select bits
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Figure 14.2
Registers TRACR and TRAIOC
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14.Timers
Timer RA Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
0102h
After Reset
00h
TRAMR
Bit Symbol
Bit Name
Function
RW
RW
Timer RA operating mode
select bits(1)
b2 b1 b0
0 0 0 : Timer mode
TMOD0
TMOD1
TMOD2
0 0 1 : Pulse output mode
0 1 0 : Event counter mode
0 1 1 : Pulse w idth measurement mode
1 0 0 : Pulse period measurement mode
1 0 1 :
RW
1 1 0 : Do not set.
1 1 1 :
RW
—
—
(b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Timer RA count source
b6 b5 b4
select bits
0 0 0 : f1
0 0 1 : f8
0 1 0 : fOCO
0 1 1 : f2
1 0 0 : fC32(2)
1 0 1 :
TCK0
TCK1
RW
RW
1 1 0 : Do not set.
1 1 1 :
TCK2
RW
RW
Timer RA count source
cutoff bit
0 : Provides count source
1 : Cuts off count source
TCKCUT
NOTES:
1. When both the TSTART and TCSTF bits in the TRACR register are set to 0 (count stops), rew rite this register.
2. For J, K version, fC32 cannot be selected.
Timer RA Prescaler Register
b7
b0
Symbol
TRAPRE
Mode
Address
0103h
After Reset
FFh(1)
Function
Counts an internal count source
Setting Range
00h to FFh
00h to FFh
00h to FFh
RW
RW
RW
RW
Timer mode
Pulse output mode
Event counter mode
Counts an external count source
Pulse w idth
measurement mode
Measure pulse w idth of input pulses from
external (counts internal count source)
00h to FFh
00h to FFh
RW
RW
Pulse period
measurement mode
Measure pulse period of input pulses from
external (counts internal count source)
NOTE:
1. When the TSTOPbit in the TRACR register is set to 1, the TRAPREregister is set to FFh.
Timer RA Register
b7
b0
Symbol
TRA
Address
0104h
After Reset
FFh(1)
Mode
Function
Counts on underflow of timer RA prescaler
register
Setting Range
RW
RW
All modes
00h to FFh
NOTE:
1. When the TSTOPbit in the TRACR register is set to 1, the TRA register is set to FFh.
Figure 14.3
Registers TRAMR, TRAPRE, and TRA
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14.Timers
14.1.1 Timer Mode
In this mode, the timer counts an internally generated count source (refer to Table 14.2 Specifications of
Timer Mode).
Figure 14.4 shows the TRAIOC Register in Timer Mode.
Table 14.2
Specifications of Timer Mode
Item
Specification
(1)
Count sources
f1, f2, f8, fOCO, fC32
Count operations
• Decrement
• When the timer underflows, the contents of the reload register are reloaded
and the count is continued.
Divide ratio
1/(n+1)(m+1)
n: Value set in TRAPRE register, m: Value set in TRA register
1 (count starts) is written to the TSTART bit in the TRACR register.
• 0 (count stops) is written to the TSTART bit in the TRACR register.
• 1 (count forcibly stops) is written to the TSTOP bit in the TRACR register.
When timer RA underflows [timer RA interrupt].
Count start condition
Count stop conditions
Interrupt request
generation timing
INT1/TRAIO pin function Programmable I/O port, or INT1 interrupt input
Programmable I/O port
TRAO pin function
Read from timer
Write to timer
The count value can be read by reading registers TRA and TRAPRE.
• When registers TRAPRE and TRA are written while the count is stopped,
values are written to both the reload register and counter.
• When registers TRAPRE and TRA are written during the count, values are
written to the reload register and counter (refer to 14.1.1.1 Timer Write
Control during Count Operation).
NOTE:
1. For J, K version, fC32 cannot be selected.
Timer RA I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
0 0 0
Symbol
TRAIOC
Address
0101h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
TRAIO polarity sw itch bit
Set to 0 in timer mode.
TEDGSEL
TOPCR
TOENA
TIOSEL
TRAIO output control bit
TRAO output enable bit
RW
RW
RW
RW
—
____
____
INT1/TRAIO select bit
0 : INT1/TRAIO pin (P1_7)
____
1 : INT1/TRAIO pin (P1_5)
TIPF0
TIPF1
TRAIO input filter select bits Set to 0 in timer mode.
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Figure 14.4
TRAIOC Register in Timer Mode
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14.Timers
14.1.1.1 Timer Write Control during Count Operation
Timer RA has a prescaler and a timer (which counts the prescaler underflows). The prescaler and timer each
consist of a reload register and a counter. When writing to the prescaler or timer, values are written to both the
reload register and counter.
However, values are transferred from the reload register to the counter of the prescaler in synchronization with
the count source. In addition, values are transferred from the reload register to the counter of the timer in
synchronization with prescaler underflows. Therefore, if the prescaler or timer is written to when count
operation is in progress, the counter value is not updated immediately after the WRITE instruction is executed.
Figure 14.5 shows an Operating Example of Timer RA when Counter Value is Rewritten during Count
Operation.
Set 01h to the TRAPRE register and 25h to
the TRA register by a program.
Count source
After writing, the reload register is
written to at the first count source.
Reloads register of
timer RA prescaler
Previous value
New value (01h)
Reload at
second count
source
Reload at
underflow
Counter of
timer RA prescaler
06h
05h
04h
01h
00h
01h
00h
01h
00h
01h
00h
After writing, the reload register is
written to at the first underflow.
Reloads register of
timer RA
Previous value
New value (25h)
Reload at the second underflow
25h 24h
Counter of timer RA
03h
02h
IR bit in TRAIC
register
0
The IR bit remains unchanged until underflow is
generated by a new value.
The above applies under the following conditions.
Both bits TSTART and TCSTF in the TRACR register are set to 1 (During count).
Figure 14.5
Operating Example of Timer RA when Counter Value is Rewritten during Count
Operation
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14.Timers
14.1.2 Pulse Output Mode
In pulse output mode, the internally generated count source is counted, and a pulse with inverted polarity is
output from the TRAIO pin each time the timer underflows (refer to Table 14.3 Specifications of Pulse
Output Mode).
Figure 14.6 shows the TRAIOC Register in Pulse Output Mode.
Table 14.3
Specifications of Pulse Output Mode
Item
Specification
(2)
Count sources
f1, f2, f8, fOCO, fC32
• Decrement
Count operations
• When the timer underflows, the contents in the reload register is reloaded
and the count is continued.
Divide ratio
1/(n+1)(m+1)
n: Value set in TRAPRE register, m: Value set in TRA register
1 (count starts) is written to the TSTART bit in the TRACR register.
• 0 (count stops) is written to the TSTART bit in the TRACR register.
• 1 (count forcibly stops) is written to the TSTOP bit in the TRACR register.
When timer RA underflows [timer RA interrupt].
Count start condition
Count stop conditions
Interrupt request
generation timing
(1)
INT1/TRAIO pin function
TRAO pin function
Pulse output, programmable output port, or INT1 interrupt
(1)
Programmable I/O port or inverted output of TRAIO
The count value can be read by reading registers TRA and TRAPRE.
Read from timer
Write to timer
• When registers TRAPRE and TRA are written while the count is stopped,
values are written to both the reload register and counter.
• When registers TRAPRE and TRA are written during the count, values are
written to the reload register and counter (refer to 14.1.1.1 Timer Write
Control during Count Operation).
Select functions
• TRAIO signal polarity switch function
The TEDGSEL bit in the TRAIOC register selects the level at the start of
(1)
pulse output.
• TRAO output function
Pulses inverted from the TRAIO output polarity can be output from the TRAO
pin (selectable by the TOENA bit in the TRAIOC register).
• Pulse output stop function
Output from the TRAIO pin is stopped by the TOPCR bit in the TRAIOC
register.
• INT1/TRAIO pin select function
P1_7 or P1_5 is selected by the TIOSEL bit in the TRAIOC register.
NOTES:
1. The level of the output pulse becomes the level when the pulse output starts when the TRAMR
register is written to.
2. For J, K version, fC32 cannot be selected.
Rev.2.10 Sep 26, 2008 Page 148 of 453
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14.Timers
Timer RA I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
Address
0101h
After Reset
00h
TRAIOC
Bit Symbol
Bit Name
TRAIO polarity sw itch bit
Function
0 : TRAIO output starts at “H”
1 : TRAIO output starts at “L”
RW
RW
TEDGSEL
TOPCR
TOENA
TIOSEL
TRAIO output control bit
TRAO output enable bit
0 : TRAIO output
1 : Port P1_7 or P1_5
RW
RW
RW
0 : Port P3_7
1 : TRAO output (inverted TRAIO output from P3_7)
____
____
INT1/TRAIO select bit
0 : INT1/TRAIO pin (P1_7)
____
1 : INT1/TRAIO pin (P1_5)
TIPF0
TIPF1
TRAIO input filter select bits Set to 0 in pulse output mode.
RW
RW
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
Figure 14.6
TRAIOC Register in Pulse Output Mode
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14.Timers
14.1.3 Event Counter Mode
In event counter mode, external signal inputs to the INT1/TRAIO pin are counted (refer to Table 14.4
Specifications of Event Counter Mode).
Figure 14.7 shows the TRAIOC Register in Event Counter Mode.
Table 14.4
Specifications of Event Counter Mode
Item
Count source
Specification
External signal which is input to TRAIO pin (active edge selectable by a
program)
Count operations
Divide ratio
• Decrement
• When the timer underflows, the contents of the reload register are reloaded
and the count is continued.
1/(n+1)(m+1)
n: setting value of TRAPRE register, m: setting value of TRA register
1 (count starts) is written to the TSTART bit in the TRACR register.
• 0 (count stops) is written to the TSTART bit in the TRACR register.
• 1 (count forcibly stops) is written to the TSTOP bit in the TRACR register.
• When timer RA underflows [timer RA interrupt].
Count start condition
Count stop conditions
Interrupt request
generation timing
INT1/TRAIO pin function Count source input (INT1 interrupt input)
(1)
Programmable I/O port or pulse output
TRAO pin function
Read from timer
Write to timer
The count value can be read by reading registers TRA and TRAPRE.
• When registers TRAPRE and TRA are written while the count is stopped,
values are written to both the reload register and counter.
• When registers TRAPRE and TRA are written during the count, values are
written to the reload register and counter (refer to 14.1.1.1 Timer Write
Control during Count Operation).
Select functions
• INT1 input polarity switch function
The TEDGSEL bit in the TRAIOC register selects the active edge of the
count source.
• Count source input pin select function
P1_7 or P1_5 is selected by the TIOSEL bit in the TRAIOC register.
• Pulse output function
Pulses of inverted polarity can be output from the TRAO pin each time the
(1)
timer underflows (selectable by the TOENA bit in the TRAIOC register).
• Digital filter function
Bits TIPF0 and TIPF1 in the TRAIOC register enable or disable the digital
filter and select the sampling frequency.
NOTE:
1. The level of the output pulse becomes the level when the pulse output starts when the TRAMR
register is written to.
Rev.2.10 Sep 26, 2008 Page 150 of 453
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14.Timers
Timer RA I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
0101h
After Reset
00h
TRAIOC
Bit Symbol
Bit Name
TRAIO polarity sw itch bit
Function
RW
RW
0 : Starts counting at rising edge of the TRAIO
input or TRAIO starts output at “L”
1 : Starts counting at falling edge of the TRAIO
input or TRAIO starts output at “H”
TEDGSEL
TRAIO output control bit
TRAO output enable bit
Set to 0 in event counter mode.
TOPCR
TOENA
TIOSEL
RW
RW
RW
0 : Port P3_7
1 : TRAO output
____
____
INT1/TRAIO select bit
0 : INT1/TRAIO pin (P1_7)
____
1 : INT1/TRAIO pin (P1_5)
TRAIO input filter select
bits(1)
b5 b4
0 0 : No filter
TIPF0
TIPF1
0 1 : Filter w ith f1 sampling
1 0 : Filter w ith f8 sampling
1 1 : Filter w ith f32 sampling
RW
—
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. When the same value from the TRAIO pin is sampled three times continuously, the input is determined.
Figure 14.7
TRAIOC Register in Event Counter Mode
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14.Timers
14.1.4 Pulse Width Measurement Mode
In pulse width measurement mode, the pulse width of an external signal input to the INT1/TRAIO pin is
measured (refer to Table 14.5 Specifications of Pulse Width Measurement Mode).
Figure 14.8 shows the TRAIOC Register in Pulse Width Measurement Mode and Figure 14.9 shows an
Operating Example of Pulse Width Measurement Mode.
Table 14.5
Specifications of Pulse Width Measurement Mode
Item Specification
(1)
Count sources
f1, f2, f8, fOCO, fC32
• Decrement
Count operations
• Continuously counts the selected signal only when measurement pulse is “H”
level, or conversely only “L” level.
• When the timer underflows, the contents of the reload register are reloaded
and the count is continued.
Count start condition
Count stop conditions
1 (count starts) is written to the TSTART bit in the TRACR register.
• 0 (count stops) is written to the TSTART bit in the TRACR register.
• 1 (count forcibly stops) is written to the TSTOP bit in the TRACR register.
• When timer RA underflows [timer RA interrupt].
• Rising or falling of the TRAIO input (end of measurement period) [timer RA
interrupt]
Interrupt request
generation timing
INT1/TRAIO pin function Measured pulse input (INT1 interrupt input)
Programmable I/O port
TRAO pin function
Read from timer
Write to timer
The count value can be read by reading registers TRA and TRAPRE.
• When registers TRAPRE and TRA are written while the count is stopped,
values are written to both the reload register and counter.
• When registers TRAPRE and TRA are written during the count, values are
written to the reload register and counter (refer to 14.1.1.1 Timer Write
Control during Count Operation).
Select functions
• Measurement level select
The TEDGSEL bit in the TRAIOC register selects the “H” or “L” level period.
• Measured pulse input pin select function
P1_7 or P1_5 is selected by the TIOSEL bit in the TRAIOC register.
• Digital filter function
Bits TIPF0 and TIPF1 in the TRAIOC register enable or disable the digital
filter and select the sampling frequency.
NOTE:
1. For J, K version, fC32 cannot be selected.
Rev.2.10 Sep 26, 2008 Page 152 of 453
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14.Timers
Timer RA I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
Address
0101h
After Reset
00h
TRAIOC
Bit Symbol
Bit Name
TRAIO polarity sw itch bit
Function
0 : TRAIO input starts at “L”
1 : TRAIO input starts at “H”
RW
RW
TEDGSEL
TOPCR
TOENA
TIOSEL
TRAIO output control bit
TRAO output enable bit
Set to 0 in pulse w idth measurement mode.
RW
RW
RW
____
____
INT1/TRAIO select bit
0 : INT1/TRAIO pin (P1_7)
____
1 : INT1/TRAIO pin (P1_5)
TRAIO input filter select
bits(1)
b5 b4
0 0 : No filter
TIPF0
TIPF1
0 1 : Filter w ith f1 sampling
1 0 : Filter w ith f8 sampling
1 1 : Filter w ith f32 sampling
RW
—
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. When the same value from the TRAIO pin is sampled three times continuously, the input is determined.
Figure 14.8
TRAIOC Register in Pulse Width Measurement Mode
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n = high level: the contents of TRA register, low level: the contents of TRAPRE register
FFFFh
n
Count start
Underflow
Count stop
Count stop
Count start
Count start
Period
0000h
Set to 1 by program
1
0
TSTART bit in
TRACR register
1
0
Measured pulse
(TRAIO pin input)
Set to 0 when interrupt request is acknowledged, or set by program
1
0
IR bit in TRAIC
register
Set to 0 by program
1
0
TEDGF bit in
TRACR register
Set to 0 by program
1
0
TUNDF bit in
TRACR register
The above applies under the following conditions.
• “H” level width of measured pulse is measured. (TEDGSEL = 1)
• TRAPRE = FFh
Figure 14.9
Operating Example of Pulse Width Measurement Mode
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14.Timers
14.1.5 Pulse Period Measurement Mode
In pulse period measurement mode, the pulse period of an external signal input to the INT1/TRAIO pin is
measured (refer to Table 14.6 Specifications of Pulse Period Measurement Mode).
Figure 14.10 shows the TRAIOC Register in Pulse Period Measurement Mode and Figure 14.11 shows an
Operating Example of Pulse Period Measurement Mode.
Table 14.6
Specifications of Pulse Period Measurement Mode
Item Specification
(2)
Count sources
f1, f2, f8, fOCO, fC32
• Decrement
Count operations
• After the active edge of the measured pulse is input, the contents of the read-
out buffer are retained at the first underflow of timer RA prescaler. Then timer
RA reloads the contents in the reload register at the second underflow of
timer RA prescaler and continues counting.
Count start condition
Count stop conditions
1 (count start) is written to the TSTART bit in the TRACR register.
• 0 (count stop) is written to TSTART bit in the TRACR register.
• 1 (count forcibly stops) is written to the TSTOP bit in the TRACR register.
• When timer RA underflows or reloads [timer RA interrupt].
• Rising or falling of the TRAIO input (end of measurement period) [timer RA
interrupt]
Interrupt request
generation timing
(1)
INT1/TRAIO pin function
Measured pulse input (INT1 interrupt input)
Programmable I/O port
TRAO pin function
Read from timer
Write to timer
The count value can be read by reading registers TRA and TRAPRE.
• When registers TRAPRE and TRA are written while the count is stopped,
values are written to both the reload register and counter.
• When registers TRAPRE and TRA are written during the count, values are
written to the reload register and counter (refer to 14.1.1.1 Timer Write
Control during Count Operation).
Select functions
• Measurement period select
The TEDGSEL bit in the TRAIOC register selects the measurement period of
the input pulse.
• Measured pulse input pin select function
P1_7 or P1_5 is selected by the TIOSEL bit in the TRAIOC register.
• Digital filter function
Bits TIPF0 and TIPF1 in the TRAIOC register enable or disable the digital
filter and select the sampling frequency.
NOTES:
1. Input a pulse with a period longer than twice the timer RA prescaler period. Input a pulse with a
longer “H” and “L” width than the timer RA prescaler period. If a pulse with a shorter period is input to
the TRAIO pin, the input may be ignored.
2. For J, K version, fC32 cannot be selected.
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Timer RA I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
Address
0101h
After Reset
00h
TRAIOC
Bit Symbol
Bit Name
TRAIO polarity sw itch bit
Function
RW
RW
0 : Measures measurement pulse from one
rising edge to next rising edge
1 : Measures measurement pulse from one
falling edge to next falling edge
TEDGSEL
TRAIO output control bit
TRAO output enable bit
Set to 0 in pulse period measurement mode.
TOPCR
TOENA
TIOSEL
RW
RW
RW
____
____
INT1/TRAIO select bit
0 : INT1/TRAIO pin (P1_7)
____
1 : INT1/TRAIO pin (P1_5)
TRAIO input filter select
bits(1)
b5 b4
0 0 : No filter
TIPF0
TIPF1
0 1 : Filter w ith f1 sampling
1 0 : Filter w ith f8 sampling
1 1 : Filter w ith f32 sampling
RW
—
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. When the same value from the TRAIO pin is sampled three times continuously, the input is determined.
Figure 14.10 TRAIOC Register in Pulse Period Measurement Mode
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Underflow signal of
timer RA prescaler
Set to 1 by program
1
TSTART bit in
TRACR register
0
Starts counting
1
0
Measurement pulse
(TRAIO pin input)
TRA reloads
TRA reloads
Contents of TRA
0Fh 0Eh 0Dh 0Fh 0Eh 0Dh 0Ch 0Bh 0Ah 09h 0Fh 0Eh 0Dh
01h 00h 0Fh 0Eh
Underflow
Retained
0Dh
Retained
09h
Contents of read-out
buffer(1)
0Fh 0Eh
0Bh 0Ah
0Dh
01h 00h 0Fh 0Eh
TRA read(3)
(Note 2)
(Note 2)
(Note 4)
1
0
TEDGF bit in
TRACR register
Set to 0 by program
(Note 6)
1
0
TUNDF bit in
TRACR register
Set to 0 by program
(Note 5)
1
0
IR bit in TRAIC
register
Set to 0 when interrupt request is acknowledged, or set by program
Conditions: The period from one rising edge to the next rising edge of the measured pulse is measured (TEDGSEL = 0) with
the default value of the TRA register as 0Fh.
NOTES:
1. The contents of the read-out buffer can be read by reading the TRA register in pulse period measurement mode.
2. After an active edge of the measured pulse is input, the TEDGF bit in the TRACR register is set to 1 (active edge found) when the timer
RA prescaler underflows for the second time.
3. The TRA register should be read before the next active edge is input after the TEDGF bit is set to 1 (active edge found).
The contents in the read-out buffer are retained until the TRA register is read. If the TRA register is not read before the next active edge
is input, the measured result of the previous period is retained.
4. To set to 0 by a program, use a MOV instruction to write 0 to the TEDGF bit in the TRACR register. At the same time, write 1 to the
TUNDF bit in the TRACR register.
5. To set to 0 by a program, use a MOV instruction to write 0 to the TUNDF bit. At the same time, write 1 to the TEDGF bit.
6. Bits TUNDF and TEDGF are both set to 1 if timer RA underflows and reloads on an active edge simultaneously.
Figure 14.11 Operating Example of Pulse Period Measurement Mode
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14.Timers
14.1.6 Notes on Timer RA
• Timer RA stops counting after a reset. Set the values in the timer RA and timer RA prescalers before the
count starts.
• Even if the prescaler and timer RA are read out in 16-bit units, these registers are read 1 byte at a time by
the MCU. Consequently, the timer value may be updated during the period when these two registers are
being read.
• In pulse period measurement mode, bits TEDGF and TUNDF in the TRACR register can be set to 0 by
writing 0 to these bits by a program. However, these bits remain unchanged if 1 is written. When using the
READ-MODIFY-WRITE instruction for the TRACR register, the TEDGF or TUNDF bit may be set to 0
although these bits are set to 1 while the instruction is being executed. In this case, write 1 to the TEDGF or
TUNDF bit which is not supposed to be set to 0 with the MOV instruction.
• When changing to pulse period measurement mode from another mode, the contents of bits TEDGF and
TUNDF are undefined. Write 0 to bits TEDGF and TUNDF before the count starts.
• The TEDGF bit may be set to 1 by the first timer RA prescaler underflow generated after the count starts.
• When using the pulse period measurement mode, leave two or more periods of the timer RA prescaler
immediately after the count starts, then set the TEDGF bit to 0.
• The TCSTF bit retains 0 (count stops) for 0 to 1 cycle of the count source after setting the TSTART bit to 1
(count starts) while the count is stopped.
During this time, do not access registers associated with timer RA other than the TCSTF bit. Timer RA
(1)
starts counting at the first valid edge of the count source after The TCSTF bit is set to 1 (during count).
The TCSTF bit remains 1 for 0 to 1 cycle of the count source after setting the TSTART bit to 0 (count
stops) while the count is in progress. Timer RA counting is stopped when the TCSTF bit is set to 0.
(1)
During this time, do not access registers associated with timer RA other than the TCSTF bit.
NOTE:
1. Registers associated with timer RA: TRACR, TRAIOC, TRAMR, TRAPRE, and TRA.
• When the TRAPRE register is continuously written during count operation (TCSTF bit is set to 1), allow
three or more cycles of the count source clock for each write interval.
• When the TRA register is continuously written during count operation (TCSTF bit is set to 1), allow three
or more cycles of the prescaler underflow for each write interval.
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14.Timers
14.2 Timer RB
Timer RB is an 8-bit timer with an 8-bit prescaler.
The prescaler and timer each consist of a reload register and counter (refer to Tables 14.7 to 14.10 the
Specifications of Each Mode).
Timer RB has timer RB primary and timer RB secondary as reload registers.
The count source for timer RB is the operating clock that regulates the timing of timer operations such as counting
and reloading.
Figure 14.12 shows a Block Diagram of Timer RB. Figures 14.13 to 14.15 show the registers associated with timer
RB.
Timer RB has four operation modes listed as follows:
• Timer mode:
The timer counts an internal count source (peripheral
function clock or timer RA underflows).
• Programmable waveform generation mode:
• Programmable one-shot generation mode:
• Programmable wait one-shot generation mode:
The timer outputs pulses of a given width successively.
The timer outputs a one-shot pulse.
The timer outputs a delayed one-shot pulse.
Data bus
TRBSC
register
TRBPR
register
Reload
register
Reload
register
Reload
register
TCK1 to TCK0 bits
TCKCUT bit
= 00b
f1
Timer RB interrupt
= 01b
f8
Timer RA underflow
f2
Counter
Counter (timer RB)
(Timer)
= 10b
= 11b
TRBPRE register
(prescaler)
TMOD1 to TMOD0 bits
= 10b or 11b
TSTART bit
TOSSTF bit
INT0 interrupt
Input polarity
selected to be one
edge or both edges
INT0 pin
Digital filter
Polarity
select
INT0PL bit
INT0EN bit
INOSEG bit
INOSTG bit
TMOD1 to TMOD0 bits
= 01b, 10b, 11b
TOPL = 1
Toggle
flip-flop
TRBOSEL = 0
Q
Q
TOCNT = 0
TRBO (P3_1) pin
TRBO (P1_3) pin
CK
CLR
P3_1 bit in P3 register
TOPL = 0
TRBOSEL = 1
TOCNT = 1
TCSTF bit
TMOD1 to TMOD0 bits
= 01b, 10b, 11b
TSTART, TCSTF: Bits in TRBCR register
TOSSTF: Bit in TRBOCR register
TOPL, TOCNT, INOSTG, INOSEG: Bits in TRBIOC register
TMOD1 to TMOD0, TCK1 to TCK0, TCKCUT: Bits in TRBMR register
TRBOSEL: Bit in PINSR2 register
Figure 14.12 Block Diagram of Timer RB
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Timer RB Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
0108h
After Reset
00h
TRBCR
Bit Symbol
Bit Name
Function
RW
RW
Timer RB count start bit(1)
0 : Count stops
1 : Count starts
TSTART
TCSTF
TSTOP
Timer RB count status flag(1) 0 : Count stops
1 : During count(3)
RO
RW
—
Timer RB count forcible stop When this bit is set to 1, the count is forcibly
bit(1, 2)
stopped. When read, its content is 0.
—
(b7-b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTES:
1. Ref er to
for precautions regarding bits TSTART, TCSTF and TSTOP.
14.2.5 Notes on Timer RB
2. When the TSTOPbit is set to 1, registers TRBPRE, TRBSC, TRBPR, and bits TSTART and TCSTF, and the TOSSTF bit
in the TRBOCR register are set to values after a reset.
3. Indicates that count operation is in progress in timer mode or programmable w aveform mode. In programmable one-
shot generation mode or programmable w ait one-shot generation mode, indicates that a one-shot pulse trigger has
been acknow ledged.
Timer RB One-Shot Control Register(2)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRBOCR
Bit Symbol
Address
0109h
After Reset
00h
Bit Name
Function
RW
RW
Timer RB one-shot start bit When this bit is set to 1, one-shot trigger
generated. When read, its content is 0.
TOSST
TOSSP
TOSSTF
Timer RB one-shot stop bit When this bit is set to 1, counting of one-shot
pulses (including programmable w ait one-shot
RW
pulses) stops. When read, its content is 0.
Timer RB one-shot status
flag(1)
0 : One-shot stopped
1 : One-shot operating (Including w ait period)
RO
—
—
(b7-b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTES:
1. When 1 is set to the TSTOPbit in the TRBCR register, the TOSSTF bit is set to 0.
2. This register is enabled w hen bits TMOD1 to TMOD0 in the TRBMR register is set to 10b (programmable one-shot
generation mode) or 11b (programmable w ait one-shot generation mode).
Figure 14.13 Registers TRBCR and TRBOCR
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Timer RB I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRBIOC
Address
010Ah
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
Timer RB output level select Function varies depending on operating mode.
bit
TOPL
Timer RB output sw itch bit
TOCNT
INOSTG
INOSEG
RW
RW
RW
—
One-shot trigger control bit
One-shot trigger polarity
select bit
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Timer RB Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRBMR
Address
010Bh
After Reset
00h
Bit Symbol
Bit Name
Timer RB operating mode
select bits(1)
Function
RW
RW
b1 b0
0 0 : Timer mode
TMOD0
TMOD1
0 1 : Programmable w aveform generation mode
1 0 : Programmable one-shot generation mode
1 1 : Programmable w ait one-shot generation mode
RW
—
(b2)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
Timer RB w rite control bit(2) 0 : Write to reload register and counter
1 : Write to reload register only
TWRC
RW
Timer RB count source
select bits(1)
b5 b4
0 0 : f1
TCK0
RW
RW
0 1 : f8
1 0 : Timer RA underflow
1 1 : f2
TCK1
—
(b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
Timer RB count source
cutoff bit(1)
0 : Provides count source
1 : Cuts off count source
TCKCUT
RW
NOTES:
1. Change bits TMOD1 and TMOD0; TCK1 and TCK0; and TCKCUT w hen both the TSTART and TCSTF bits in the TRBCR
register set to 0 (count stops).
2. The TWRC bit can be set to either 0 or 1 in timer mode. In programmable w aveform generation mode, programmable
one-shot generation mode, or programmable w ait one-shot generation mode, the TWRC bit must be set to 1 (w rite to
reload register only).
Figure 14.14 Registers TRBIOC and TRBMR
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Timer RB Prescaler Register(1)
14.Timers
b7
b0
Symbol
TRBPRE
Mode
Address
010Ch
After Reset
FFh
Function
Counts an internal count source or timer RA
underflow s
Setting Range
00h to FFh
RW
RW
Timer mode
Programmable w aveform
generation mode
00h to FFh
00h to FFh
00h to FFh
RW
RW
RW
Programmable one-shot
generation mode
Programmable w ait one-shot
generation mode
NOTE:
1. When the TSTOPbit in the TRBCR register is set to 1, the TRBPRE register is set to FFh.
Timer RB Secondary Register(3, 4)
b7
b0
Symbol
TRBSC
Mode
Address
010Dh
After Reset
FFh
Function
Setting Range
00h to FFh
RW
—
Disabled
Timer mode
Programmable w aveform
generation mode
Counts timer RB prescaler underflow s(1)
Disabled
00h to FFh
00h to FFh
00h to FFh
WO(2)
—
Programmable one-shot
generation mode
Programmable w ait one-shot Counts timer RB prescaler underflow s
generation mode (one-shot w idth is counted)
WO(2)
NOTES:
1. The values of registers TRBPR and TRBSC are reloaded to the counter alternately and counted.
2. The count value can be read out by reading the TRBPR register even w hen the secondary period is being counted.
3. When the TSTOPbit in the TRBCR register is set to 1, the TRBSC register is set to FFh.
4. To w rite to the TRBSC register, perform the follow ing steps.
(1) Write the value to the TRBSC register.
(2) Write the value to the TRBPR register. (If the value does not change, w rite the same value second time.)
Timer RB Primary Register(2)
b7
b0
Symbol
TRBPR
Mode
Address
010Eh
Function
After Reset
FFh
Setting Range
00h to FFh
RW
RW
Counts timer RB prescaler underflow s
Timer mode
Programmable w aveform
generation mode
Counts timer RB prescaler underflow s(1)
00h to FFh
00h to FFh
00h to FFh
RW
RW
RW
Programmable one-shot
generation mode
Counts timer RB prescaler underflow s
(one-shot w idth is counted)
Programmable w ait one-shot Counts timer RB prescaler underflow s
generation mode (w ait period w idth is counted)
NOTES:
1. The values of registers TRBPR and TRBSC are reloaded to the counter alternately and counted.
2. When the TSTOPbit in the TRBCR register is set to 1, the TRBPR register is set to FFh.
Figure 14.15 Registers TRBPRE, TRBSC, and TRBPR
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14.Timers
14.2.1 Timer Mode
In timer mode, a count source which is internally generated or timer RA underflows are counted (refer to Table
14.7 Specifications of Timer Mode). Registers TRBOCR and TRBSC are not used in timer mode.
Figure 14.16 shows the TRBIOC Register in Timer Mode.
Table 14.7
Specifications of Timer Mode
Item
Count sources
Count operations
Specification
f1, f2, f8, timer RA underflow
• Decrement
• When the timer underflows, it reloads the reload register contents before the
count continues (when timer RB underflows, the contents of timer RB primary
reload register is reloaded).
Divide ratio
1/(n+1)(m+1)
n: setting value in TRBPRE register, m: setting value in TRBPR register
1 (count starts) is written to the TSTART bit in the TRBCR register.
• 0 (count stops) is written to the TSTART bit in the TRBCR register.
• 1 (count forcibly stop) is written to the TSTOP bit in the TRBCR register.
When timer RB underflows [timer RB interrupt]
Count start condition
Count stop conditions
Interrupt request
generation timing
TRBO pin function
Programmable I/O port
INT0 pin function
Read from timer
Write to timer
Programmable I/O port or INT0 interrupt input
The count value can be read out by reading registers TRBPR and TRBPRE.
• When registers TRBPRE and TRBPR are written while the count is stopped,
values are written to both the reload register and counter.
• When registers TRBPRE and TRBPR are written to while count operation is
in progress:
If the TWRC bit in the TRBMR register is set to 0, the value is written to both
the reload register and the counter.
If the TWRC bit is set to 1, the value is written to the reload register only.
(Refer to 14.2.1.1 Timer Write Control during Count Operation.)
Timer RB I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0
Symbol
Address
010Ah
After Reset
00h
TRBIOC
Bit Symbol
Bit Name
Function
RW
RW
Timer RB output level select Set to 0 in timer mode.
bit
TOPL
Timer RB output sw itch bit
TOCNT
INOSTG
INOSEG
RW
RW
RW
—
One-shot trigger control bit
One-shot trigger polarity
select bit
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Figure 14.16 TRBIOC Register in Timer Mode
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14.Timers
14.2.1.1 Timer Write Control during Count Operation
Timer RB has a prescaler and a timer (which counts the prescaler underflows). The prescaler and timer each
consist of a reload register and a counter. In timer mode, the TWRC bit in the TRBMR register can be used to
select whether writing to the prescaler or timer during count operation is performed to both the reload register
and counter or only to the reload register.
However, values are transferred from the reload register to the counter of the prescaler in synchronization with
the count source. In addition, values are transferred from the reload register to the counter of the timer in
synchronization with prescaler underflows. Therefore, even if the TWRC bit is set for writing to both the reload
register and counter, the counter value is not updated immediately after the WRITE instruction is executed. In
addition, if the TWRC bit is set for writing to the reload register only, the synchronization of the writing will be
shifted if the prescaler value changes. Figure 14.17 shows an Operating Example of Timer RB when Counter
Value is Rewritten during Count Operation.
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14.Timers
When the TWRC bit is set to 0 (write to reload register and counter)
Set 01h to the TRBPRE register and 25h to
the TRBPR register by a program.
Count source
After writing, the reload register is
written with the first count source.
Reloads register of
Previous value
New value (01h)
timer RB prescaler
Reload with
the second
count source
Reload on
underflow
Counter of
timer RB prescaler
06h
05h
04h
01h
00h
01h
00h
01h
00h
01h
00h
After writing, the reload register is
written on the first underflow.
Reloads register of
timer RB
Previous value
New value (25h)
Reload on the second
underflow
Counter of timer RB
03h
02h
25h
24h
IR bit in TRBIC
register
0
The IR bit remains unchanged until underflow
is generated by a new value.
When the TWRC bit is set to 1 (write to reload register only)
Set 01h to the TRBPRE register and 25h to
the TRBPR register by a program.
Count source
After writing, the reload register is
written with the first count source.
Reloads register of
timer RB prescaler
Previous value
New value (01h)
Reload on
underflow
Counter of
timer RB prescaler
06h
05h
04h
03h
02h
01h
00h
01h
00h
01h
00h
01h
00h
01h
After writing, the reload register is
written on the first underflow.
Reloads register of
timer RB
Previous value
New value (25h)
Reload on
underflow
Counter of timer RB
03h
02h
01h
00h
25h
IR bit in TRBIC
register
0
Only the prescaler values are updated,
extending the duration until timer RB underflow.
The above applies under the following conditions.
Both bits TSTART and TCSTF in the TRBCR register are set to 1 (During count).
Figure 14.17 Operating Example of Timer RB when Counter Value is Rewritten during Count
Operation
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14.Timers
14.2.2 Programmable Waveform Generation Mode
In programmable waveform generation mode, the signal output from the TRBO pin is inverted each time the
counter underflows, while the values in registers TRBPR and TRBSC are counted alternately (refer to Table
14.8 Specifications of Programmable Waveform Generation Mode). Counting starts by counting the setting
value in the TRBPR register. The TRBOCR register is unused in this mode.
Figure 14.18 shows the TRBIOC Register in Programmable Waveform Generation Mode. Figure 14.19 shows
an Operating Example of Timer RB in Programmable Waveform Generation Mode.
Table 14.8
Specifications of Programmable Waveform Generation Mode
Item Specification
Count sources
f1, f2, f8, timer RA underflow
• Decrement
Count operations
• When the timer underflows, it reloads the contents of the primary reload and
secondary reload registers alternately before the count continues.
Primary period: (n+1)(m+1)/fi
Width and period of
output waveform
Secondary period: (n+1)(p+1)/fi
Period: (n+1){(m+1)+(p+1)}/fi
fi: Count source frequency
n: Value set in TRBPRE register, m: Value set in TRBPR register
p: Value set in TRBSC register
Count start condition
Count stop conditions
1 (count start) is written to the TSTART bit in the TRBCR register.
• 0 (count stop) is written to the TSTART bit in the TRBCR register.
• 1 (count forcibly stop) is written to the TSTOP bit in the TRBCR register.
In half a cycle of the count source, after timer RB underflows during the
secondary period (at the same time as the TRBO output change) [timer RB
interrupt]
Interrupt request
generation timing
TRBO pin function
Programmable output port or pulse output
INT0 pin function
Read from timer
Write to timer
Programmable I/O port or INT0 interrupt input
(1)
The count value can be read out by reading registers TRBPR and TRBPRE.
• When registers TRBPRE, TRBSC, and TRBPR are written while the count is
stopped, values are written to both the reload register and counter.
• When registers TRBPRE, TRBSC, and TRBPR are written to during count
(2)
operation, values are written to the reload registers only.
Select functions
• Output level select function
The TOPL bit in the TRBIOC register selects the output level during primary
and secondary periods.
• TRBO pin output switch function
Timer RB pulse output or P3_1 (P1_3) latch output is selected by the
(3)
TOCNT bit in the TRBIOC register.
• TRBO pin select function
P3_1 or P1_3 is selected by the TRBOSEL bit in the PINSR2 register.
NOTES:
1. Even when counting the secondary period, the TRBPR register may be read.
2. The set values are reflected in the waveform output beginning with the following primary period after
writing to the TRBPR register.
3. The value written to the TOCNT bit is enabled by the following.
• When counting starts.
• When a timer RB interrupt request is generated.
The contents after the TOCNT bit is changed are reflected from the output of the following
primary period.
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Timer RB I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
Address
010Ah
After Reset
00h
TRBIOC
Bit Symbol
Bit Name
Function
RW
RW
Timer RB output level select 0 : Outputs “H” for primary period
bit
Outputs “L” for secondary period
Outputs “L” w hen the timer is stopped
1 : Outputs “L” for primary period
Outputs “H” for secondary period
Outputs “H” w hen the timer is stopped
TOPL
Timer RB output sw itch bit
0 : Outputs timer RB w aveform
1 : Outputs value in P3_1 (P1_3) port register
TOCNT
INOSTG
INOSEG
RW
RW
RW
—
One-shot trigger control bit Set to 0 in programmable w aveform generation
mode.
One-shot trigger polarity
select bit
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Figure 14.18 TRBIOC Register in Programmable Waveform Generation Mode
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Set to 1 by program
1
0
TSTART bit in TRBCR
register
Count source
Timer RB prescaler
underflow signal
Timer RB secondary reloads
Timer RB primary reloads
Counter of timer RB
01h
00h
02h
01h
00h
01h
00h
02h
Set to 0 when interrupt
request is acknowledged,
or set by program.
1
0
IR bit in TRBIC
register
Set to 0 by program
1
0
TOPL bit in TRBIO
register
Waveform
output starts
Waveform output inverted
Waveform output starts
1
0
TRBO pin output
Primary period
Secondary period
Primary period
Initial output is the same level
as during secondary period.
The above applies under the following conditions.
TRBPRE = 01h, TRBPR = 01h, TRBSC = 02h
TRBIOC register TOCNT = 0 (timer RB waveform is output from the TRBO pin)
Figure 14.19 Operating Example of Timer RB in Programmable Waveform Generation Mode
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14.2.3 Programmable One-shot Generation Mode
In programmable one-shot generation mode, a one-shot pulse is output from the TRBO pin by a program or an
external trigger input (input to the INT0 pin) (refer to Table 14.9 Specifications of Programmable One-Shot
Generation Mode). When a trigger is generated, the timer starts operating from the point only once for a given
period equal to the set value in the TRBPR register. The TRBSC register is not used in this mode.
Figure 14.20 shows the TRBIOC Register in Programmable One-Shot Generation Mode. Figure 14.21 shows
an Operating Example of Programmable One-Shot Generation Mode.
Table 14.9
Specifications of Programmable One-Shot Generation Mode
Item Specification
Count sources
f1, f2, f8, timer RA underflow
Count operations
• Decrement the setting value in the TRBPR register
• When the timer underflows, it reloads the contents of the reload register
before the count completes and the TOSSTF bit is set to 0 (one-shot stops).
• When the count stops, the timer reloads the contents of the reload register
before it stops.
One-shot pulse output
time
(n+1)(m+1)/fi
fi: Count source frequency,
(2)
n: Setting value in TRBPRE register, m: Setting value in TRBPR register
Count start conditions
• The TSTART bit in the TRBCR register is set to 1 (count starts) and the next
trigger is generated
• Set the TOSST bit in the TRBOCR register to 1 (one-shot starts)
• Input trigger to the INT0 pin
Count stop conditions
• When reloading completes after timer RB underflows during primary period
• When the TOSSP bit in the TRBOCR register is set to 1 (one-shot stops)
• When the TSTART bit in the TRBCR register is set to 0 (stops counting)
• When the TSTOP bit in the TRBCR register is set to 1 (forcibly stops
counting)
Interrupt request
generation timing
TRBO pin function
In half a cycle of the count source, after the timer underflows (at the same time
as the TRBO output ends) [timer RB interrupt]
Pulse output
INT0 pin functions
• When the INOSTG bit in the TRBIOC register is set to 0 (INT0 one-shot
trigger disabled): programmable I/O port or INT0 interrupt input
• When the INOSTG bit in the TRBIOC register is set to 1 (INT0 one-shot
trigger enabled): external trigger (INT0 interrupt input)
Read from timer
Write to timer
The count value can be read out by reading registers TRBPR and TRBPRE.
• When registers TRBPRE and TRBPR are written while the count is stopped,
values are written to both the reload register and counter.
• When registers TRBPRE and TRBPR are written during the count, values are
written to the reload register only (the data is transferred to the counter at the
(1)
following reload).
Select functions
• Output level select function
The TOPL bit in the TRBIOC register selects the output level of the one-shot
pulse waveform.
• One-shot trigger select function
Refer to 14.2.3.1 One-Shot Trigger Selection.
• TRBO pin select function
P3_1 or P1_3 is selected by the TRBOSEL bit in the PINSR2 register.
NOTES:
1. The set value is reflected at the following one-shot pulse after writing to the TRBPR register.
2. Do not set both the TRBPRE and TRBPR registers to 00h.
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Timer RB I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
010Ah
After Reset
00h
TRBIOC
Bit Symbol
Bit Name
Timer RB Output Level
Select Bit
Function
0 : Outputs one-shot pulse “H”
Outputs “L” w hen the timer is stopped
1 : Outputs one-shot pulse “L”
RW
RW
TOPL
Outputs “H” w hen the timer is stopped
Timer RB Output Sw itch Bit Set to 0 in programmable one-shot generation
TOCNT
INOSTG
INOSEG
RW
RW
RW
—
mode.
____
One-Shot Trigger Control
Bit(1)
0 : INT0 pin one-shot trigger disabled
____
1 : INT0 pin one-shot trigger enabled
One-Shot Trigger Polarity
Select Bit(1)
0 : Falling edge trigger
1 : Rising edge trigger
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, its content is 0.
NOTE:
1. Ref er to
.
14.2.3.1 One-Shot Trigger Selection
Figure 14.20 TRBIOC Register in Programmable One-Shot Generation Mode
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Set to 1 by program
1
0
TSTART bit in TRBCR
register
Set to 0 when
counting ends
Set to 1 by INT0 pin
input trigger
Set to 1 by program
1
0
TOSSTF bit in TRBOCR
register
INT0 pin input
Count source
Timer RB prescaler
underflow signal
Timer RB primary reloads
Timer RB primary reloads
Count starts
Count starts
Counter of timer RB
01h
00h
01h
00h
01h
Set to 0 when interrupt request is
acknowledged, or set by program
1
0
IR bit in TRBIC
register
Set to 0 by program
1
0
TOPL bit in
TRBIOC register
Waveform output starts Waveform output ends
Waveform output starts Waveform output ends
1
0
TRBIO pin output
The above applies under the following conditions.
TRBPRE = 01h, TRBPR = 01h
TRBIOC register TOPL = 0, TOCNT = 0
INOSTG = 1 (INT0 one-shot trigger enabled)
INOSEG = 1 (edge trigger at rising edge)
Figure 14.21 Operating Example of Programmable One-Shot Generation Mode
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14.2.3.1 One-Shot Trigger Selection
In programmable one-shot generation mode and programmable wait one-shot generation mode, operation starts
when a one-shot trigger is generated while the TCSTF bit in the TRBCR register is set to 1 (count starts).
A one-shot trigger can be generated by either of the following causes:
• 1 is written to the TOSST bit in the TRBOCR register by a program.
• Trigger input from the INT0 pin.
When a one-shot trigger occurs, the TOSSTF bit in the TRBOCR register is set to 1 (one-shot operation in
progress) after one or two cycles of the count source have elapsed. Then, in programmable one-shot generation
mode, count operation begins and one-shot waveform output starts. (In programmable wait one-shot generation
mode, count operation starts for the wait period.) If a one-shot trigger occurs while the TOSSTF bit is set to 1,
no retriggering occurs.
To use trigger input from the INT0 pin, input the trigger after making the following settings:
• Set the PD4_5 bit in the PD4 register to 0 (input port).
• Select the INT0 digital filter with bits INT0F1 and INT0F0 in the INTF register.
• Select both edges or one edge with the INT0PL bit in INTEN register. If one edge is selected, further select
falling or rising edge with the INOSEG bit in TRBIOC register.
• Set the INT0EN bit in the INTEN register to 0 (enabled).
• After completing the above, set the INOSTG bit in the TRBIOC register to 1 (INT pin one-shot trigger
enabled).
Note the following points with regard to generating interrupt requests by trigger input from the INT0 pin.
• Processing to handle the interrupts is required. Refer to 12. Interrupts, for details.
• If one edge is selected, use the POL bit in the INT0IC register to select falling or rising edge. (The
INOSEG bit in the TRBIOC register does not affect INT0 interrupts).
• If a one-shot trigger occurs while the TOSSTF bit is set to 1, timer RB operation is not affected, but the
value of the IR bit in the INT0IC register changes.
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14.2.4 Programmable Wait One-Shot Generation Mode
In programmable wait one-shot generation mode, a one-shot pulse is output from the TRBO pin by a program
or an external trigger input (input to the INT0 pin) (refer to Table 14.10 Specifications of Programmable Wait
One-Shot Generation Mode). When a trigger is generated from that point, the timer outputs a pulse only once
for a given length of time equal to the setting value in the TRBSC register after waiting for a given length of
time equal to the setting value in the TRBPR register.
Figure 14.22 shows the TRBIOC Register in Programmable Wait One-Shot Generation Mode. Figure 14.23
shows an Operating Example of Programmable Wait One-Shot Generation Mode.
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Table 14.10 Specifications of Programmable Wait One-Shot Generation Mode
Item
Count sources
Count operations
Specification
f1, f2, f8, timer RA underflow
• Decrement the timer RB primary setting value.
• When a count of the timer RB primary underflows, the timer reloads the
contents of timer RB secondary before the count continues.
• When a count of the timer RB secondary underflows, the timer reloads the
contents of timer RB primary before the count completes and the TOSSTF
bit is set to 0 (one-shot stops).
• When the count stops, the timer reloads the contents of the reload register
before it stops.
Wait time
(n+1)(m+1)/fi
fi: Count source frequency
(2)
n: Value set in the TRBPRE register, m Value set in the TRBPR register
One-shot pulse output time (n+1)(p+1)/fi
fi: Count source frequency
n: Value set in the TRBPRE register, p: Value set in the TRBSC register
• The TSTART bit in the TRBCR register is set to 1 (count starts) and the
next trigger is generated.
Count start conditions
• Set the TOSST bit in the TRBOCR register to 1 (one-shot starts).
• Input trigger to the INT0 pin
Count stop conditions
• When reloading completes after timer RB underflows during secondary
period.
• When the TOSSP bit in the TRBOCR register is set to 1 (one-shot stops).
• When the TSTART bit in the TRBCR register is set to 0 (starts counting).
• When the TSTOP bit in the TRBCR register is set to 1 (forcibly stops
counting).
Interrupt request
generation timing
In half a cycle of the count source after timer RB underflows during
secondary period (complete at the same time as waveform output from the
TRBO pin) [timer RB interrupt]
TRBO pin function
INT0 pin functions
Pulse output
• When the INOSTG bit in the TRBIOC register is set to 0 (INT0 one-shot
trigger disabled): programmable I/O port or INT0 interrupt input
• When the INOSTG bit in the TRBIOC register is set to 1 (INT0 one-shot
trigger enabled): external trigger (INT0 interrupt input)
Read from timer
Write to timer
The count value can be read out by reading registers TRBPR and TRBPRE.
• When registers TRBPRE, TRBSC, and TRBPR are written while the count
stops, values are written to both the reload register and counter.
• When registers TRBPRE, TRBSC, and TRBPR are written to during count
(1)
operation, values are written to the reload registers only.
Select functions
• Output level select function
The TOPL bit in the TRBIOC register selects the output level of the one-
shot pulse waveform.
• One-shot trigger select function
Refer to 14.2.3.1 One-Shot Trigger Selection.
• TRBO pin select function
P3_1 or P1_3 is selected by the TRBOSEL bit in the PINSR2 register.
NOTES:
1. The set value is reflected at the following one-shot pulse after writing to registers TRBSC and
TRBPR.
2. Do not set both the TRBPRE and TRBPR registers to 00h.
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Timer RB I/O Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
010Ah
After Reset
00h
TRBIOC
Bit Symbol
Bit Name
Function
RW
RW
Timer RB output level select 0 : Outputs one-shot pulse “H”.
bit
Outputs “L” w hen the timer stops or during
w ait.
TOPL
1 : Outputs one-shot pulse “L”.
Outputs “H” w hen the timer stops or during
w ait.
Timer RB output sw itch bit
One-shot trigger control bit(1)
Set to 0 in programmable w ait one-shot generation
TOCNT
INOSTG
INOSEG
RW
RW
RW
—
mode.
____
0 : INT0 pin one-shot trigger disabled
____
1 : INT0 pin one-shot trigger enabled
0 : Falling edge trigger
1 : Rising edge trigger
One-shot trigger polarity
select bit(1)
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. Ref er to
.
14.2.3.1 One-Shot Trigger Selection
Figure 14.22 TRBIOC Register in Programmable Wait One-Shot Generation Mode
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Set to 1 by program
1
0
TSTART bit in TRBCR
register
Set to 1 by setting 1 to TOSST bit in TRBOCR
register, or INT0 pin input trigger.
Set to 0 when
counting ends
1
0
TOSSTF bit in TRBOCR
register
INT0 pin input
Count source
Timer RB prescaler
underflow signal
Timer RB secondary reloads
Timer RB primary reloads
Count starts
Counter of timer RB
01h
00h
04h
03h
02h
01h
00h
01h
Set to 0 when interrupt request is
acknowledged, or set by program.
1
0
IR bit in TRBIC
register
Set to 0 by program
1
0
TOPL bit in
TRBIOC register
Wait starts
Waveform output starts
Waveform output ends
1
0
TRBIO pin output
Wait
(primary period)
One-shot pulse
(secondary period)
The above applies under the following conditions.
TRBPRE = 01h, TRBPR = 01h, TRBSC = 04h
INOSTG = 1 (INT0 one-shot trigger enabled)
INOSEG = 1 (edge trigger at rising edge)
Figure 14.23 Operating Example of Programmable Wait One-Shot Generation Mode
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14.2.5 Notes on Timer RB
• Timer RB stops counting after a reset. Set the values in the timer RB and timer RB prescalers before the
count starts.
• Even if the prescaler and timer RB is read out in 16-bit units, these registers are read 1 byte at a time by the
MCU. Consequently, the timer value may be updated during the period when these two registers are being
read.
• In programmable one-shot generation mode and programmable wait one-shot generation mode, when
setting the TSTART bit in the TRBCR register to 0, 0 (stops counting) or setting the TOSSP bit in the
TRBOCR register to 1 (stops one-shot), the timer reloads the value of reload register and stops. Therefore,
in programmable one-shot generation mode and programmable wait one-shot generation mode, read the
timer count value before the timer stops.
• The TCSTF bit remains 0 (count stops) for 1 to 2 cycles of the count source after setting the TSTART bit to
1 (count starts) while the count is stopped.
During this time, do not access registers associated with timer RB other than the TCSTF bit. Timer RB
(1)
starts counting at the first valid edge of the count source after the TCSTF bit is set to 1 (during count).
The TCSTF bit remains 1 for 1 to 2 cycles of the count source after setting the TSTART bit to 0 (count
stops) while the count is in progress. Timer RB counting is stopped when the TCSTF bit is set to 0.
(1)
During this time, do not access registers associated with timer RB other than the TCSTF bit.
NOTE:
1. Registers associated with timer RB: TRBCR, TRBOCR, TRBIOC, TRBMR, TRBPRE, TRBSC, and
TRBPR.
• If the TSTOP bit in the TRBCR register is set to 1 during timer operation, timer RB stops immediately.
• If 1 is written to the TOSST or TOSSP bit in the TRBOCR register, the value of the TOSSTF bit changes
after one or two cycles of the count source have elapsed. If the TOSSP bit is written to 1 during the period
between when the TOSST bit is written to 1 and when the TOSSTF bit is set to 1, the TOSSTF bit may be
set to either 0 or 1 depending on the content state. Likewise, if the TOSST bit is written to 1 during the
period between when the TOSSP bit is written to 1 and when the TOSSTF bit is set to 0, the TOSSTF bit
may be set to either 0 or 1.
14.2.5.1 Timer mode
The following workaround should be performed in timer mode.
To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the following
points:
• When the TRBPRE register is written continuously, allow three or more cycles of the count source for each
write interval.
• When the TRBPR register is written continuously, allow three or more cycles of the prescaler underflow
for each write interval.
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14.2.5.2 Programmable waveform generation mode
The following three workarounds should be performed in programmable waveform generation mode.
(1) To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the
following points:
• When the TRBPRE register is written continuously, allow three or more cycles of the count source for each
write interval.
• When the TRBPR register is written continuously, allow three or more cycles of the prescaler underflow
for each write interval.
(2) To change registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), synchronize
the TRBO output cycle using a timer RB interrupt, etc. This operation should be preformed only once in
the same output cycle. Also, make sure that writing to the TRBPR register does not occur during period
A shown in Figures 14.24 and 14.25.
The following shows the detailed workaround examples.
• Workaround example (a):
As shown in Figure 14.24, write to registers TRBSC and TRBPR in the timer RB interrupt routine. These
write operations must be completed by the beginning of period A.
Period A
Count source/
prescaler
underflow signal
Primary period
Secondary period
TRBO pin output
IR bit in
TRBIC register
Interrupt request is
acknowledged
(a)
Ensure sufficient time
(b)
Interrupt
Instruction in
Set the secondary and then
the primary register immediately
Interrupt request
is generated
sequence interrupt routine
(a) Period between interrupt request generation and the completion of execution of an instruction. The length of time
varies depending on the instruction being executed.
The DIVX instruction requires the longest time, 30 cycles (assuming no wait states and that a register is set as
the divisor).
(b) 20 cycles. 21 cycles for address match and single-step interrupts.
Figure 14.24 Workaround Example (a) When Timer RB interrupt is Used
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• Workaround example (b):
As shown in Figure 14.25 detect the start of the primary period by the TRBO pin output level and write to
registers TRBSC and TRBPR. These write operations must be completed by the beginning of period A.
If the port register’s bit value is read after the port direction register’s bit corresponding to the TRBO pin is
set to 0 (input mode), the read value indicates the TRBO pin output value.
Period A
Count source/
prescaler
underflow signal
Primary period
Secondary period
TRBO pin output
Read value of the port register’s
bit corresponding to the TRBO pin
(when the bit in the port direction
register is set to 0)
(i) (ii) (iii)
Ensure sufficient time
The TRBO output inversion
is detected at the end of the
secondary period.
Upon detecting (i), set the secondary and
then the primary register immediately.
Figure 14.25 Workaround Example (b) When TRBO Pin Output Value is Read
(3) To stop the timer counting in the primary period, use the TSTOP bit in the TRBCR register. In this case,
registers TRBPRE and TRBPR are initialized and their values are set to the values after reset.
14.2.5.3 Programmable one-shot generation mode
The following two workarounds should be performed in programmable one-shot generation mode.
(1) To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the
following points:
• When the TRBPRE register is written continuously during count operation (TCSTF bit is set to 1), allow
three or more cycles of the count source for each write interval.
• When the TRBPR register is written continuously during count operation (TCSTF bit is set to 1), allow
three or more cycles of the prescaler underflow for each write interval.
(2) Do not set both the TRBPRE and TRBPR registers to 00h.
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14.2.5.4 Programmable wait one-shot generation mode
The following three workarounds should be performed in programmable wait one-shot generation mode.
(1) To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the
following points:
• When the TRBPRE register is written continuously, allow three or more cycles of the count source for each
write interval.
• When the TRBPR register is written continuously, allow three or more cycles of the prescaler underflow
for each write interval.
(2) Do not set both the TRBPRE and TRBPR registers to 00h.
(3) Set registers TRBSC and TRBPR using the following procedure.
(a) To use “INT0 pin one-shot trigger enabled” as the count start condition
Set the TRBSC register and then the TRBPR register. At this time, after writing to the TRBPR
register, allow an interval of 0.5 or more cycles of the count source before trigger input from the
INT0 pin.
(b) To use “writing 1 to TOSST bit” as the start condition
Set the TRBSC register, the TRBPR register, and then TOSST bit. At this time, after writing to the
TRBPR register, allow an interval of 0.5 or more cycles of the count source before writing to the
TOSST bit.
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14.3 Timer RC
14.3.1 Overview
Timer RC is a 16-bit timer with four I/O pins.
Timer RC uses either f1 or fOCO40M as its operation clock. Table 14.11 lists the Timer RC Operation Clock.
Table 14.11 Timer RC Operation Clock
Condition
Timer RC Operation Clock
Count source is f1, f2, f4, f8, f32, or TRCCLK input (bits TCK2 to TCK0 in f1
TRCCR1 register are set to a value from 000b to 101b)
Count source is fOCO40M (bits TCK2 to TCK0 in TRCCR1 register are set fOCO40M
to 110b)
Table 14.12 lists the Timer RC I/O Pins, and Figure 14.26 shows a Timer RC Block Diagram.
Timer RC has three modes.
• Timer mode
- Input capture function
The counter value is captured to a register, using an external signal as the trigger.
- Output compare function Matches between the counter and register values are detected. (Pin output state
changes when a match is detected.)
The following two modes use the output compare function.
• PWM mode
• PWM2 mode
Pulses of a given width are output continuously.
A one-shot waveform or PWM waveform is output following the trigger after
the wait time has elapsed.
Input capture function, output compare function, and PWM mode settings may be specified independently for
each pin.
In PWM2 mode waveforms are output based on a combination of the counter or the register.
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f1, f2, f4, f8, f32,
fOCO40M
TRCMR register
TRCCR1 register
TRCIER register
TRCSR register
TRCIOR0 register
TRCIOR1 register
TRC register
INT0
Count source
select circuit
TRCCLK
TRCIOA/TRCTRG
TRCIOB
Timer RC control circuit
TRCIOC
TRCGRA register
TRCGRB register
TRCGRC register
TRCGRD register
TRCCR2 register
TRCIOD
TRCDF register
Timer RC interrupt
request
TRCOER register
Figure 14.26 Timer RC Block Diagram
Table 14.12 Timer RC I/O Pins
Pin Name
TRCIOA(P1_1)
TRCIOB(P1_2)
I/O
Function
I/O
Function differs according to the mode. Refer to descriptions
of individual modes for details
(1)
(1)
TRCIOC(P5_3 or P3_4)
TRCIOD(P5_4 or P3_5)
TRCCLK(P3_3)
Input
Input
External clock input
TRCTRG(P1_1)
PWM2 mode external trigger input
NOTE:
1. The pins used for TRCIOC and TRCIOD are selectable. Refer to the description of the bits
TRCIOCSEL and TRCIODSEL in the PINSR3 register in Figure 7.10 Registers PINSR1, PINSR2,
and PINSR3 for details.
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14.Timers
14.3.2 Registers Associated with Timer RC
Table 14.13 lists the Registers Associated with Timer RC. Figures 14.27 to 14.36 show details of the registers
associated with timer RC.
Table 14.13 Registers Associated with Timer RC
Mode
Timer
Address Symbol
Related Information
Input
Capture Compare
Function Function
Output
PWM
PWM2
0120h
0121h
TRCMR
Valid
Valid
Valid
Valid
Valid
Timer RC mode register
Figure 14.27 TRCMR Register
TRCCR1 Valid
Valid
Valid
Timer RC control register 1
Figure 14.28 TRCCR1 Register
Figure 14.49 TRCCR1 Register for Output
Compare Function
Figure 14.52 TRCCR1 Register in PWM Mode
Figure 14.56 TRCCR1 Register in PWM2 Mode
0122h
0123h
0124h
TRCIER
TRCSR
Valid
Valid
Valid
Valid
Valid
Valid
Valid
−
Valid
Valid
−
Timer RC interrupt enable register
Figure 14.29 TRCIER Register
Timer RC status register
Figure 14.30 TRCSR Register
TRCIOR0 Valid
Timer RC I/O control register 0, timer RC I/O
control register 1
Figure 14.36 Registers TRCIOR0 and TRCIOR1
Figure 14.43 TRCIOR0 Register for Input
Capture Function
Figure 14.44 TRCIOR1 Register for Input
Capture Function
0125h
TRCIOR1
Figure 14.47 TRCIOR0 Register for Output
Compare Function
Figure 14.48 TRCIOR1 Register for Output
Compare Function
0126h
0127h
TRC
Valid
Valid
Valid
Valid
Valid
Valid
Valid
Timer RC counter
Figure 14.31 TRC Register
0128h
0129h
TRCGRA Valid
TRCGRB
Timer RC general registers A, B, C, and D
Figure 14.32 Registers TRCGRA, TRCGRB,
TRCGRC, and TRCGRD
012Ah
012Bh
012Ch TRCGRC
012Dh
012Eh
012Fh
TRCGRD
TRCCR2
TRCDF
0130h
0131h
0132h
−
−
−
Valid
Valid
Valid
Timer RC control register 2
Figure 14.33 TRCCR2 Register
Valid
−
−
Timer RC digital filter function select register
Figure 14.34 TRCDF Register
TRCOER
−
Valid
Valid
Timer RC output mask enable register
Figure 14.35 TRCOER Register
− : Invalid
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14.Timers
Timer RC Mode Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
0120h
After Reset
01001000b
Function
TRCMR
Bit Symbol
Bit Name
RW
RW
PWM mode of TRCIOB select bit(2) 0 : Timer mode
PWMB
PWMC
PWMD
PWM2
BFC
1 : PWM mode
PWM mode of TRCIOC select bit(2) 0 : Timer mode
1 : PWM mode
PWM mode of TRCIOD select bit(2) 0 : Timer mode
1 : PWM mode
RW
RW
RW
RW
RW
—
PWM2 mode select bit
0 : PWM 2 mode
1 : Timer mode or PWM mode
TRCGRC register function select
bit(3)
0 : General register
1 : Buffer register of TRCGRA register
TRCGRD register function select
bit
0 : General register
1 : Buffer register of TRCGRB register
BFD
—
(b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
TRC count start bit
0 : Count stops
1 : Count starts
TSTART
RW
NOTES:
1. For notes on PWM2 mode, refer to
.
14.3.9.5 TRCMR Register in PWM2 Mode
2. These bits are enabled w hen the PWM2 bit is set to 1 (timer mode or PWM mode).
3. Set the BFC bit to 0 (general register) in PWM2 mode.
Figure 14.27 TRCMR Register
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14.Timers
Timer RC Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCCR1
Address
0121h
After Reset
00h
Bit Symbol
Bit Name
TRCIOA output level select bit(1)
Function
RW
RW
Function varies according to the
operating mode (function).(2)
TOA
TOB
TOC
TOD
TRCIOB output level select bit(1)
TRCIOC output level select bit(1)
TRCIOD output level select bit(1)
Count source select bits(1)
RW
RW
RW
b6 b5 b4
0 0 0 : f1
0 0 1 : f2
0 1 0 : f4
0 1 1 : f8
TCK0
TCK1
TCK2
RW
RW
RW
1 0 0 : f32
1 0 1 : TRCCLK input rising edge
1 1 0 : fOCO40M
1 1 1 : Do not set.
TRC counter clear select bit(2, 3)
0 : Disable clear (free-running
operation)
CCLR
RW
1 : Clear by compare match in the
TRCGRA register
NOTES:
1. Set to these bits w hen the TSTART bit in the TRCMR register is set to 0 (count stops).
2. Bits CCLR, TOA, TOB, TOC and TOD are disabled for the input capture function of the timer mode.
3. The TRC counter performs free-running operation for the input capture function of the timer mode independent of the
CCLR bit setting.
Figure 14.28 TRCCR1 Register
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14.Timers
Timer RC Interrupt Enable Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCIER
Address
0122h
After Reset
01110000b
Bit Symbol
Bit Name
Function
RW
RW
Input capture / compare match
interrupt enable bit A
0 : Disable interrupt (IMIA) by the
IMFA bit
1 : Enable interrupt (IMIA) by the
IMFA bit
IMIEA
IMIEB
IMIEC
IMIED
Input capture / compare match
interrupt enable bit B
0 : Disable interrupt (IMIB) by the
IMFB bit
1 : Enable interrupt (IMIB) by the
IMFB bit
RW
RW
Input capture / compare match
interrupt enable bit C
0 : Disable interrupt (IMIC) by the
IMFC bit
1 : Enable interrupt (IMIC) by the
IMFC bit
Input capture / compare match
interrupt enable bit D
0 : Disable interrupt (IMID) by the
IMFD bit
1 : Enable interrupt (IMID) by the
IMFD bit
RW
—
—
(b6-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
Overflow interrupt enable bit
0 : Disable interrupt (OVI) by the
OVF bit
OVIE
RW
1 : Enable interrupt (OVI) by the
OVF bit
Figure 14.29 TRCIER Register
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14.Timers
Timer RC Status Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCSR
Bit Symbol
Address
0123h
Bit Name
After Reset
01110000b
Function
RW
RW
Input capture / compare match flag [Source for setting this bit to 0]
A
IMFA
IMFB
IMFC
IMFD
Write 0 after read.(1)
[Source for setting this bit to 1]
Refer to the table below .
Input capture / compare match flag
B
RW
RW
RW
—
Input capture / compare match flag
C
Input capture / compare match flag
D
—
(b6-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
Overflow flag
[Source for setting this bit to 0]
Write 0 after read.(1)
OVF
RW
[Source for setting this bit to 1]
Refer to the table below .
NOTE:
1. The w riting results are as follow s:
• This bit is set to 0 w hen the read result is 1 and 0 is w ritten to the same bit.
• This bit remains unchanged even if the read result is 0 and 0 is w ritten to the same bit. (This bit remains 1
even if it is set to 1 from 0 after reading, and w riting 0.)
• This bit remains unchanged if 1 is w ritten to it.
Timer Mode
Bit Symbol
PWM Mode
PWM2 Mode
Input capture Function
Output Compare
Function
TRCIOA pin input edge(1)
When the values of the registers TRC and TRCGRA match.
When the values of the registers TRC and TRCGRB match.
IMFA
IMFB
IMFC
IMFD
OVF
TRCIOB pin input edge(1)
TRCIOC pin input edge(1)
TRCIOD pin input edge(1)
When the values of the registers TRC and TRCGRC
match.(2)
When the values of the registers TRC and TRCGRD
match.(2)
When the TRC register overflow s.
NOTES:
1. Edge selected by bits IOj1 to IOj0 (j = A, B, C, or D).
2. Includes the condition that bits BFC and BFD are set to 1 (buffer registers of registers TRCGRA
and TRCGRB).
Figure 14.30 TRCSR Register
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Timer RC Counter(1)
14.Timers
(b15)
b7
(b8)
b0
b7
b0
Symbol
TRC
Address
0127h-0126h
After Reset
0000h
Function
Setting Range
RW
RW
Count a count source. Count operation is incremented.
When an overflow occurs, the OVF bit in the TRCSR register is set to 1.
0000h to FFFFh
NOTE:
1. Access the TRC register in 16-bit units. Do not access it in 8-bit units.
Figure 14.31 TRC Register
Timer RC General Register A, B, C and D(1)
(b15)
b7
(b8)
b0
b7
b0
Symbol
TRCGRA
TRCGRB
TRCGRC
TRCGRD
Address
After Reset
FFFFh
FFFFh
FFFFh
FFFFh
0129h-0128h
012Bh-012Ah
012Dh-012Ch
012Fh-012Eh
Function
Function varies according to the operating mode.
RW
RW
NOTE:
1. Access registers TRCGRA to TRCGRD in 16-bit units. Do not access them in 8-bit units.
Figure 14.32 Registers TRCGRA, TRCGRB, TRCGRC, and TRCGRD
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14.Timers
Timer RC Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCCR2
Address
0130h
After Reset
00011111b
Bit Symbol
Bit Name
Function
RW
—
—
(b4-b0)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
TRC count operation select
bit(1, 2)
0 : Count continues at compare match w ith
the TRCGRA register
1 : Count stops at compare match w ith
the TRCGRA register
CSEL
RW
TRCTRG input edge select bits(3)
b7 b6
0 0 : Disable the trigger input from the
TRCTRG pin
0 1 : Rising edge selected
1 0 : Falling edge selected
1 1 : Both edges selected
TCEG0
RW
RW
TCEG1
NOTES:
1. For notes on PWM2 mode, refer to
.
14.3.9.5 TRCMR Register in PWM2 Mode
2. In timer mode and PWM mode this bit is disabled (the count operation continues independent of the CSEL bit setting).
3. In timer mode and PWM mode these bits are disabled.
Figure 14.33 TRCCR2 Register
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14.Timers
Timer RC Digital Filter Function Select Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCDF
Address
0131h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
TRCIOA pin digital filter function
select bit(1)
0 : Function is not used
1 : Function is used
DFA
DFB
TRCIOB pin digital filter function
select bit(1)
RW
RW
RW
RW
—
TRCIOC pin digital filter function
select bit(1)
DFC
TRCIOD pin digital filter function
select bit(1)
DFD
TRCTRG pin digital filter function
select bit(2)
DFTRG
—
(b5)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
b7 b6
Clock select bits for digital filter
function(1, 2)
0 0 : f32
DFCK0
DFCK1
RW
RW
0 1 : f8
1 0 : f1
1 1 : Count source (clock selected by
bits TCK2 to TCK0 in the
TRCCR1 register)
NOTES:
1. These bits are enabled for the input capture function.
2. These bits are enabled w hen in PWM2 mode and bits TCEG1 to TCEG0 in the TRCCR2 register are set to 01b, 10b, or
11b (TRCTRG trigger input enabled).
Figure 14.34 TRCDF Register
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14.Timers
Timer RC Output Master Enable Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCOER
Bit Symbol
Address
0132h
After Reset
01111111b
Function
Bit Name
TRCIOA output disable bit(1)
RW
RW
0 : Enable output
1 : Disable output (The TRCIOA pin is
used as a programmable I/O port.)
EA
EB
EC
ED
TRCIOB output disable bit(1)
TRCIOC output disable bit(1)
TRCIOD output disable bit(1)
0 : Enable output
1 : Disable output (The TRCIOB pin is
used as a programmable I/O port.)
RW
RW
0 : Enable output
1 : Disable output (The TRCIOC pin is
used as a programmable I/O port.)
0 : Enable output
1 : Disable output (The TRCIOD pin is
used as a programmable I/O port.)
RW
—
—
(b6-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
____
INT0 of pulse output forced
cutoff signal input enabled
bit
0 : Pulse output forced cutoff input disabled
1 : Pulse output forced cutoff input enabled
(Bits EA, EB, EC, and ED are set to 1
RW
PTO
(disable output) w hen “L” is applied to the
____
INT0 pin)
NOTE:
1. These bits are disabled for input pins set to the input capture function.
Figure 14.35 TRCOER Register
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14.Timers
Timer RC I/O Control Register 0(1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCIOR0
Bit Symbol
Address
0124h
After Reset
10001000b
Function
Bit Name
RW
IOA0
IOA1
TRCGRA control bits
Function varies according to the operating mode RW
(function).
RW
TRCGRA mode select bit(2)
0 : Output compare function
1 : Input capture function
IOA2
IOA3
RW
TRCGRA input capture input
sw itch bit(4)
0 : fOCO128 signal
1 : TRCIOA pin input
RW
IOB0
IOB1
TRCGRB control bits
Function varies according to the operating mode RW
(function).
RW
TRCGRB mode select bit(3)
0 : Output compare function
1 : Input capture function
IOB2
RW
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
—
NOTES:
1. The TRCIOR0 register is enabled in timer mode. It is disabled in modes PWM and PWM2.
2. When the BFC bit in the TRCMR register is set to 1 (buffer register of TRCGRA register), set the IOC2 bit in the
TRCIOR1 register to the same value as the IOA2 bit in the TRCIOR0 register.
3. When the BFD bit in the TRCMR register is set to 1 (buffer register of TRCGRB register), set the IOD2 bit in the
TRCIOR1 register to the same value as the IOB2 bit in the TRCIOR0 register.
4. The IOA3 bit is enabled w hen the IOA2 bit is set to 1 (input capture function).
Timer RC I/O Control Register 1(1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCIOR1
Bit Symbol
IOC0
Address
0125h
After Reset
10001000b
Function
Bit Name
RW
TRCGRC control bits
Function varies according to the operating mode RW
(function).
IOC1
RW
TRCGRC mode select bit(2)
0 : Output compare function
1 : Input capture function
IOC2
RW
—
(b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
—
IOD0
IOD1
TRCGRD control bits
Function varies according to the operating mode RW
(function).
RW
TRCGRD mode select bit(3)
0 : Output compare function
1 : Input capture function
IOD2
RW
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
—
NOTES:
1. The TRCIOR1 register is enabled in timer mode. It is disabled in modes PWM and PWM2.
2. When the BFC bit in the TRCMR register is set to 1 (buffer register of TRCGRA register), set the IOC2 bit in the
TRCIOR1 register to the same value as the IOA2 bit in the TRCIOR0 register.
3. When the BFD bit in the TRCMR register is set to 1 (buffer register of TRCGRB register), set the IOD2 bit in the
TRCIOR1 register to the same value as the IOB2 bit in the TRCIOR0 register.
Figure 14.36 Registers TRCIOR0 and TRCIOR1
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14.Timers
14.3.3 Common Items for Multiple Modes
14.3.3.1 Count Source
The method of selecting the count source is common to all modes.
Table 14.14 lists the Count Source Selection, and Figure 14.37 shows a Count Source Block Diagram.
Table 14.14 Count Source Selection
Count Source
f1, f2, f4, f8, f32
fOCO40M
Selection Method
Count source selected using bits TCK2 to TCK0 in TRCCR1 register
FRA00 bit in FRA0 register set to 1 (high-speed on-chip oscillator on) and bits
TCK2 to TCK0 in TRCCR1 register are set to 110b (fOCO40M)
External signal input Bits TCK2 to TCK0 in TRCCR1 register are set to 101b (count source is rising edge
to TRCCLK pin
of external clock) and PD3_3 bit in PD3 register is set to 0 (input mode)
TCK2 to TCK0
= 000b
f1
= 001b
f2
= 010b
f4
f8
Count source
= 011b
= 100b
TRC register
f32
= 101b
TRCCLK
= 110b
fOCO40M
TCK2 to TCK0: Bits in TRCCR1 register
Figure 14.37 Count Source Block Diagram
The pulse width of the external clock input to the TRCCLK pin should be three cycles or more of the timer RC
operation clock (refer to Table 14.11 Timer RC Operation Clock).
To select fOCO40M as the count source, set the FRA00 bit in the FRA0 register set to 1 (high-speed on-chip
oscillator on), and then set bits TCK2 to TCK0 in the TRCCR1 register to 110b (fOCO40M).
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14.Timers
14.3.3.2 Buffer Operation
Bits BFC and BFD in the TRCMR register are used to select the TRCGRC or TRCGRD register as the buffer
register for the TRCGRA or TRCGRB register.
• Buffer register for TRCGRA register: TRCGRC register
• Buffer register for TRCGRB register: TRCGRD register
Buffer operation differs depending on the mode.
Table 14.15 lists the Buffer Operation in Each Mode, Figure 14.38 shows the Buffer Operation for Input
Capture Function, and Figure 14.39 shows the Buffer Operation for Output Compare Function.
Table 14.15 Buffer Operation in Each Mode
Function, Mode
Transfer Timing
Transfer Destination Register
Contents of TRCGRA (TRCGRB)
register are transferred to buffer
register
Input capture function
Input capture signal input
Output compare function Compare match between TRC
Contents of buffer register are
transferred to TRCGRA (TRCGRB)
register
register and TRCGRA (TRCGRB)
PWM mode
register
PWM2 mode
• Compare match between TRC
register and TRCGRA register
• TRCTRG pin trigger input
Contents of buffer register (TRCGRD)
are transferred to TRCGRB register
TRCIOA input
(input capture signal)
TRCGRC
register
TRCGRA
register
TRC
TRCIOA input
TRC register
n
n-1
n+1
Transfer
Transfer
TRCGRA register
m
n
TRCGRC register
(buffer)
m
The above applies under the following conditions:
• The BFC bit in the TRCMR register is set to 1 (the TRCGRC register functions as the buffer register for the TRCGRA register).
• Bits IOA2 to IOA0 in the TRCIOR0 register are set to 100b (input capture at the rising edge).
Figure 14.38 Buffer Operation for Input Capture Function
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14.Timers
Compare match signal
TRCGRA
TRCGRC
register
Comparator
TRC
register
m
TRC register
m-1
m+1
n
TRCGRA register
m
Transfer
TRCGRC register
(buffer)
n
TRCIOA output
The above applies under the following conditions:
• The BFC bit in the TRCMR register is set to 1 (the TRCGRC register functions as the buffer register for the TRCGRA register).
• Bits IOA2 to IOA0 in the TRCIOR0 register are set to 001b (“L” output at compare match).
Figure 14.39 Buffer Operation for Output Compare Function
Make the following settings in timer mode.
• To use the TRCGRC register as the buffer register for the TRCGRA register:
Set the IOC2 bit in the TRCIOR1 register to the same value as the IOA2 bit in the TRCIOR0 register.
• To use the TRCGRD register as the buffer register for the TRCGRB register:
Set the IOD2 bit in the TRCIOR1 register to the same value as the IOB2 bit in the TRCIOR0 register.
The output compare function, PWM mode, or PWM2 mode, and the TRCGRC or TRCGRD register is
functioning as a buffer register, the IMFC bit or IMFD bit in the TRCSR register is set to 1 when a compare
match with the TRC register occurs.
The input capture function and the TRCGRC register or TRCGRD register is functioning as a buffer register,
the IMFC bit or IMFD bit in the TRCSR register is set to 1 at the input edge of a signal input to the TRCIOC pin
or TRCIOD pin.
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14.Timers
14.3.3.3 Digital Filter
The input to TRCTRG or TRCIOj (j = A, B, C, or D) is sampled, and the level is considered to be determined
when three matches occur. The digital filter function and sampling clock are selected using the TRCDF register.
Figure 14.40 shows a Block Diagram of Digital Filter.
TCK2 to TCK0
DFCK1 to DFCK0
f1
= 000b
= 00b
f32
= 001b
f2
= 01b
f8
= 010b
= 10b
= 11b
f4
f8
f1
= 011b
= 100b
Count source
f32
IOA2 to IOA0
IOB2 to IOB0
IOC2 to IOC0
IOD2 to IOD0
(or TCEG1 to TCEG0)
= 101b
= 110b
TRCCLK
fOCO40M
Sampling clock
DFj (or DFTRG)
1
C
C
C
C
Match detect
circuit
Edge detect
circuit
TRCIOj input signal
(or TRCTRG input
signal)
D
Q
D
Q
D
Q
D
Q
Latch
Latch
Latch
Latch
0
Timer RC operation clock
f1 or fOCO40M
C
D
Q
Latch
Clock cycle selected by
TCK2 to TCK0
(or DFCK1 to DFCK0)
Sampling clock
TRCIOj input signal
(or TRCTRG input signal)
Three matches occur and a
signal change is confirmed.
Input signal after passing
through digital filter
Maximum signal transmission
delay is five sampling clock
pulses.
If fewer than three matches occur,
the matches are treated as noise
and no transmission is performed.
j = A, B, C, or D
TCK0 to TCK2: Bits in TRCCR1 register
DFTRG, DFCK0 to DFCK1, DFj: Bits in TRCDF register
IOA0 to IOA2, IOB0 to IOB2: Bits in TRCIOR0 register
IOC0 to IOC2, IOD0 to IOD2: Bits in TRCIOR1 register
TCEG1 to TCEG0: Bits in TRCCR2 register
Figure 14.40 Block Diagram of Digital Filter
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14.Timers
14.3.3.4 Forced Cutoff of Pulse Output
When using the timer mode’s output compare function, the PWM mode, or the PWM2 mode, pulse output from
the TRCIOj (j = A, B, C, or D) output pin can be forcibly cut off and the TRCIOj pin set to function as a
programmable I/O port by means of input to the INT0 pin.
A pin used for output by the timer mode’s output compare function, the PWM mode, or the PWM2 mode can be
set to function as the timer RC output pin by setting the Ej bit in the TRCOER register to 0 (timer RC output
enabled). If “L” is input to the INT0 pin while the PTO bit in the TRCOER register is set to 1 (pulse output
forced cutoff signal input INT0 enabled), bits EA, EB, EC, and ED in the TRCOER register are all set to 1
(timer RC output disabled, TRCIOj output pin functions as the programmable I/O port). When one or two
cycles of the timer RC operation clock after “L” input to the INT0 pin (refer to Table 14.11 Timer RC
Operation Clock) has elapsed, the TRCIOj output pin becomes a programmable I/O port.
Make the following settings to use this function.
• Set the pin state following forced cutoff of pulse output (high impedance (input), “L” output, or “H”
output) (refer to 7. Programmable I/O Ports).
• Set the INT0EN bit to 1 (INT0 input enabled) and the INT0PL bit to 0 (one edge) in the INTEN register.
• Set the PD4_5 bit in the PD4 register to 0 (input mode).
• Select the INT0 digital filter by means of bits INT0F1 to INT0F0 in the INTF register.
• Set the PTO bit in the TRCOER register to 1 (pulse output forced cutoff signal input INT0 enabled).
The IR bit in the INT0IC register is set to 1 (interrupt request) in accordance with the setting of the POL bit and
a change in the INT0 pin input (refer to 12.6 Notes on Interrupts).
For details on interrupts, refer to 12. Interrupts.
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14.Timers
EA bit
Q
EA bit
write value
D
S
Timer RC
output data
INT0 input
TRCIOA
TRCIOB
TRCIOC
TRCIOD
Port P1_1
output data
PTO bit
Port P1_1
input data
EB bit
EB bit
write value
Q
D
S
Timer RC
output data
Port P1_2
output data
Port P1_2
input data
EC bit
Q
EC bit
write value
D
S
Timer RC
output data
Port P5_3 (P3_4)(1)
output data
Port P5_3 (P3_4)(1)
input data
ED bit
ED bit
write value
Q
D
S
Timer RC
output data
Port P5_4 (P3_5)(1)
output data
Port P5_4 (P3_5)(1)
input data
EA, EB, EC, ED, PTO: Bits in TRCOER register
NOTE:
1. The pin in parentheses ( ) can be assigned by a program.
Figure 14.41 Forced Cutoff of Pulse Output
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14.Timers
14.3.4 Timer Mode (Input Capture Function)
This function measures the width or period of an external signal. An external signal input to the TRCIOj (j = A,
B, C, or D) pin acts as a trigger for transferring the contents of the TRC register (counter) to the TRCGRj
register (input capture). The input capture function, or any other mode or function, can be selected for each
individual pin.
The TRCGRA register can also select fOCO128 signal as input-capture trigger input.
Table 14.16 lists the Specifications of Input Capture Function, Figure 14.42 shows a Block Diagram of Input
Capture Function, Figures 14.43 and 14.44 show the registers associated with the input capture function, Table
14.17 lists the Functions of TRCGRj Register when Using Input Capture Function, and Figure 14.45 shows an
Operating Example of Input Capture Function.
Table 14.16 Specifications of Input Capture Function
Item
Count source
Specification
f1, f2, f4, f8, f32, fOCO40M, or external signal (rising edge) input to
TRCCLK pin
Count operation
Count period
Increment
1/fk × 65,536 fk: Count source frequency
Count start condition
Count stop condition
1 (count starts) is written to the TSTART bit in the TRCMR register.
0 (count stops) is written to the TSTART bit in the TRCMR register.
The TRC register retains a value before count stops.
• Input capture (valid edge of TRCIOj input or fOCO128 signal edge)
• The TRC register overflows.
Interrupt request generation
timing
TRCIOA, TRCIOB, TRCIOC, Programmable I/O port or input capture input (selectable individually by
and TRCIOD pin functions
pin)
INT0 pin function
Read from timer
Write to timer
Programmable I/O port or INT0 interrupt input
The count value can be read by reading TRC register.
The TRC register can be written to.
Select functions
• Input capture input pin select
One or more of pins TRCIOA, TRCIOB, TRCIOC, and TRCIOD
• Input capture input valid edge selected
Rising edge, falling edge, or both rising and falling edges
• Buffer operation (Refer to 14.3.3.2 Buffer Operation.)
• Digital filter (Refer to 14.3.3.3 Digital Filter.)
• Input-capture trigger selected
fOCO128 can be selected for input-capture trigger input of the
TRCGRA register.
j = A, B, C, or D
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14.Timers
fOCO128
IOA3 = 0
Divided
fOCO
by 128
Input capture signal(3)
TRCIOA
IOA3 = 1
TRCGRA
register
TRC register
(Note 1)
TRCGRC
register
TRCIOC
TRCIOB
Input capture signal
Input capture signal
TRCGRB
register
(Note 2)
TRCGRD
register
TRCIOD
Input capture signal
IOA3: Bit in TRCIOR0 register
NOTES:
1. The BFC bit in the TRCMR register is set to 1 (TRCGRC register functions as the buffer register for the TRCGRA register)
2. The BFD bit in the TRCMR register is set to 1 (TRCGRD register functions as the buffer register for the TRCGRB register)
3. The trigger input of the TRCGRA register can select the TRCIOA pin input or fOCO128 signal.
Figure 14.42 Block Diagram of Input Capture Function
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14.Timers
Timer RC I/O Control Register 0
b7 b6 b5 b4 b3 b2 b1 b0
1
1
Symbol
TRCIOR0
Bit Symbol
Address
0124h
After Reset
10001000b
Function
Bit Name
RW
RW
b1 b0
TRCGRA control bits
0 0 : Input capture to the TRCGRA register
at the rising edge
0 1 : Input capture to the TRCGRA register
at the falling edge
IOA0
IOA1
1 0 : Input capture to the TRCGRA register
at both edges
RW
1 1 : Do not set.
TRCGRA mode select bit(1)
Set to 1 (input capture) in the input capture
function.
IOA2
IOA3
RW
RW
TRCGRA input capture input
sw itch bit(3)
0 : fOCO128 signal
1 : TRCIOA pin input
b5 b4
TRCGRB control bits
0 0 : Input capture to the TRCGRB register
at the rising edge
0 1 : Input capture to the TRCGRB register
at the falling edge
IOB0
RW
RW
1 0 : Input capture to the TRCGRB register
at both edges
1 1 : Do not set.
IOB1
IOB2
TRCGRB mode select bit(2)
Set to 1 (input capture) in the input capture
function.
RW
—
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
NOTES:
1. When the BFC bit in the TRCMR register is set to 1 (buffer register of TRCGRA register), set the IOC2 bit in the
TRCIOR1 register to the same value as the IOA2 bit in the TRCIOR0 register.
2. When the BFD bit in the TRCMR register is set to 1 (buffer register of TRCGRB register), set the IOD2 bit in the
TRCIOR1 register to the same value as the IOB2 bit in the TRCIOR0 register.
3. The IOA3 bit is enabled w hen the IOA2 bit is set to 1 (input capture function).
Figure 14.43 TRCIOR0 Register for Input Capture Function
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14.Timers
Timer RC I/O Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
1
1
Symbol
TRCIOR1
Bit Symbol
Address
0125h
After Reset
10001000b
Function
Bit Name
RW
RW
b1 b0
TRCGRC control bits
0 0 : Input capture to the TRCGRC register
at the rising edge
IOC0
0 1 : Input capture to the TRCGRC register
at the falling edge
1 0 : Input capture to the TRCGRC register
at both edges
1 1 : Do not set.
IOC1
IOC2
RW
TRCGRC mode select bit(1)
Set to 1 (input capture) in the input capture
function.
RW
—
—
(b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
b5 b4
TRCGRD control bits
0 0 : Input capture to the TRCGRD register
IOD0
RW
RW
at the rising edge
0 1 : Input capture to the TRCGRD register
at the falling edge
1 0 : Input capture to the TRCGRD register
at both edges
1 1 : Do not set.
IOD1
IOD2
TRCGRD mode select bit(2)
Set to 1 (input capture) in the input capture
function.
RW
—
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
NOTES:
1. When the BFC bit in the TRCMR register is set to 1 (buffer register of TRCGRA register), set the IOC2 bit in the
TRCIOR1 register to the same value as the IOA2 bit in the TRCIOR0 register.
2. When the BFD bit in the TRCMR register is set to 1 (buffer register of TRCGRB register), set the IOD2 bit in the
TRCIOR1 register to the same value as the IOB2 bit in the TRCIOR0 register.
Figure 14.44 TRCIOR1 Register for Input Capture Function
Table 14.17 Functions of TRCGRj Register when Using Input Capture Function
Input Capture
Input Pin
General register. Can be used to read the TRC register value TRCIOA
at input capture.
General register. Can be used to read the TRC register value TRCIOC
at input capture.
Buffer registers. Can be used to hold transferred value from TRCIOA
the general register. (Refer to 14.3.3.2 Buffer Operation.)
Register
Setting
Register Function
TRCGRA
TRCGRB
TRCGRC
TRCGRD
TRCGRC
TRCGRD
−
TRCIOB
TRCIOD
TRCIOB
BFC = 0
BFD = 0
BFC = 1
BFD = 1
j = A, B, C, or D
BFC, BFD: Bits in TRCMR register
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14.Timers
TRCCLK input
count source
TRC register
count value
FFFFh
0006h
0003h
0000h
1
0
TSTART bit in
TRCMR register
65536
TRCIOA input
TRCGRA register
TRCGRC register
0006h
0003h
Transfer
0006h
Transfer
1
0
IMFA bit in
TRCSR register
Set to 0 by a program
1
0
OVF bit in
TRCSR register
The above applies under the following conditions:
• Bits TCK2 to TCK0 in the TRCCR1 register are set to 101b (the count source is TRCCLK input).
• Bits IOA2 to IOA0 in the TRCIORA register are set to 101b (input capture at the falling edge of the TRCIOA input).
• The BFC bit in the TRCMR register is set to 1 (the TRCGRC register functions as the buffer register for the TRCGRA register).
Figure 14.45 Operating Example of Input Capture Function
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14.Timers
14.3.5 Timer Mode (Output Compare Function)
This function detects when the contents of the TRC register (counter) and the TRCGRj register (j = A, B, C, or
D) match (compare match). When a match occurs a signal is output from the TRCIOj pin at a given level. The
output compare function, or other mode or function, can be selected for each individual pin.
Table 14.18 lists the Specifications of Output Compare Function, Figure 14.46 shows a Block Diagram of
Output Compare Function, Figures 14.47 to 14.49 show the registers associated with the output compare
function, Table 14.19 lists the Functions of TRCGRj Register when Using Output Compare Function, and
Figure 14.50 shows an Operating Example of Output Compare Function.
Table 14.18 Specifications of Output Compare Function
Item
Count source
Specification
f1, f2, f4, f8, f32, fOCO40M, or external signal (rising edge) input to
TRCCLK pin
Count operation
Count period
Increment
• The CCLR bit in the TRCCR1 register is set to 0 (free running
operation):
1/fk × 65,536
fk: Count source frequency
• The CCLR bit in the TRCCR1 register is set to 1 (TRC register set to
0000h at TRCGRA compare match):
1/fk × (n + 1)
n: TRCGRA register setting value
Waveform output timing
Count start condition
Count stop condition
Compare match
1 (count starts) is written to the TSTART bit in the TRCMR register.
0 (count stops) is written to the TSTART bit in the TRCMR register.
The output compare output pin retains output level before count stops,
the TRC register retains a value before count stops.
• Compare match (contents of registers TRC and TRCGRj match)
• The TRC register overflows.
Interrupt request generation
timing
TRCIOA, TRCIOB, TRCIOC, Programmable I/O port or output compare output (selectable individually
and TRCIOD pin functions
by pin)
INT0 pin function
Programmable I/O port, pulse output forced cutoff signal input, or INT0
interrupt input
Read from timer
Write to timer
The count value can be read by reading the TRC register.
The TRC register can be written to.
Select functions
• Output compare output pin selected
One or more of pins TRCIOA, TRCIOB, TRCIOC, and TRCIOD
• Compare match output level select
“L” output, “H” output, or toggle output
• Initial output level select
Sets output level for period from count start to compare match
• Timing for clearing the TRC register to 0000h
Overflow or compare match with the TRCGRA register
• Buffer operation (Refer to 14.3.3.2 Buffer Operation.)
• Pulse output forced cutoff signal input (Refer to 14.3.3.4 Forced Cutoff
of Pulse Output.)
• Can be used as an internal timer by disabling timer RC output
j = A, B, C, or D
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14.Timers
TRC
Compare match signal
Compare match signal
Compare match signal
Compare match signal
Output
TRCIOA
control
Comparator
Comparator
Comparator
Comparator
TRCGRA
TRCGRC
TRCGRB
TRCGRD
Output
TRCIOC
control
Output
TRCIOB
control
Output
TRCIOD
control
Figure 14.46 Block Diagram of Output Compare Function
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Timer RC I/O Control Register 0
b7 b6 b5 b4 b3 b2 b1 b0
0
1 0
Symbol
TRCIOR0
Bit Symbol
Address
0124h
After Reset
10001000b
Function
Bit Name
RW
RW
b1 b0
TRCGRA control bits
0 0 : Disable pin output by compare
match (TRCIOA pin functions as the
programmable I/O port)
IOA0
IOA1
0 1 : “L” output by compare match in
the TRCGRA register
1 0 : “H” output by compare match in
the TRCGRA register
1 1 : Toggle output by compare match
in the TRCGRA register
RW
TRCGRA mode select bit(1)
Set to 0 (output compare) in the output compare
function.
IOA2
IOA3
RW
RW
TRCGRA input capture input
sw itch bit
Set to 1.
b5 b4
TRCGRB control bits
0 0 : Disable pin output by compare
match (TRCIOB pin functions as the
programmable I/O port)
0 1 : “L” output by compare match in
the TRCGRB register
1 0 : “H” output by compare match in
the TRCGRB register
1 1 : Toggle output by compare match
in the TRCGRB register
IOB0
RW
RW
IOB1
IOB2
TRCGRB mode select bit(2)
Set to 0 (output compare) in the output compare
function.
RW
—
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
NOTES:
1. When the BFC bit in the TRCMR register is set to 1 (buffer register of TRCGRA register), set the IOC2 bit in the
TRCIOR1 register to the same value as the IOA2 bit in the TRCIOR0 register.
2. When the BFD bit in the TRCMR register is set to 1 (buffer register of TRCGRB register), set the IOD2 bit in the
TRCIOR1 register to the same value as the IOB2 bit in the TRCIOR0 register.
Figure 14.47 TRCIOR0 Register for Output Compare Function
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14.Timers
Timer RC I/O Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
0
0
Symbol
TRCIOR1
Bit Symbol
Address
0125h
After Reset
10001000b
Function
Bit Name
RW
RW
b1 b0
TRCGRC control bits
0 0 : Disable pin output by compare
match
0 1 : “L” output by compare match in
the TRCGRC register
IOC0
1 0 : “H” output by compare match in
the TRCGRC register
1 1 : Toggle output by compare match
in the TRCGRC register
IOC1
IOC2
RW
TRCGRC mode select bit(1)
Set to 0 (output compare) in the output compare
function.
RW
—
—
(b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
b5 b4
TRCGRD control bits
0 0 : Disable pin output by compare
match
IOD0
RW
RW
0 1 : “L” output by compare match in
the TRCGRD register
1 0 : “H” output by compare match in
the TRCGRD register
1 1 : Toggle output by compare match
in the TRCGRD register
IOD1
IOD2
TRCGRD mode select bit(2)
Set to 0 (output compare) in the output compare
function.
RW
—
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
NOTES:
1. When the BFC bit in the TRCMR register is set to 1 (buffer register of TRCGRA register), set the IOC2 bit in the
TRCIOR1 register to the same value as the IOA2 bit in the TRCIOR0 register.
2. When the BFD bit in the TRCMR register is set to 1 (buffer register of TRCGRB register), set the IOD2 bit in the
TRCIOR1 register to the same value as the IOB2 bit in the TRCIOR0 register.
Figure 14.48 TRCIOR1 Register for Output Compare Function
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14.Timers
Timer RC Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCCR1
Address
0121h
After Reset
00h
Bit Symbol
Bit Name
TRCIOA output level select bit(1, 2)
Function
RW
RW
0 : Initial output “L”
1 : Initial output “H”
TOA
TOB
TOC
TOD
TRCIOB output level select bit(1, 2)
TRCIOC output level select bit(1, 2)
TRCIOD output level select bit(1, 2)
Count source select bits(1)
RW
RW
RW
b6 b5 b4
0 0 0 : f1
0 0 1 : f2
0 1 0 : f4
0 1 1 : f8
1 0 0 : f32
1 0 1 : TRCCLK input rising edge
TCK0
TCK1
TCK2
RW
RW
RW
1 1 0 : fOCO40M
1 1 1 : Do not set.
TRC counter clear select bit
0 : Disable clear (free-running
operation)
CCLR
RW
1 : Clear by compare match in the
TRCGRA register
NOTES:
1. Set to these bits w hen the TSTART bit in the TRCMR register is set to 0 (count stops).
2. If the pin function is set for w aveform output (refer to to
,
to
, and
Tables 7.37
Tables 7.13 7.16 Tables 7.26 7.29
to
), the initial output level is output w hen the TRCCR1 register is set.
7.40
Figure 14.49 TRCCR1 Register for Output Compare Function
Table 14.19 Functions of TRCGRj Register when Using Output Compare Function
Output Compare
Output Pin
Register
Setting
Register Function
TRCGRA
TRCGRB
TRCGRC
TRCGRD
TRCGRC
TRCGRD
−
General register. Write a compare value to one of these TRCIOA
registers.
General register. Write a compare value to one of these TRCIOC
TRCIOB
BFC = 0
BFD = 0
BFC = 1
BFD = 1
registers.
TRCIOD
TRCIOA
TRCIOB
Buffer register. Write the next compare value to one of
these registers. (Refer to 14.3.3.2 Buffer Operation.)
j = A, B, C, or D
BFC, BFD: Bits in TRCMR register
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14.Timers
Count source
TRC register value
m
n
p
Count
restarts
Count
stops
1
0
TSTART bit in
TRCMR register
m+1
m+1
Output level held
TRCIOA output
Output inverted at
compare match
Initial output “L”
1
0
IMFA bit in
TRCSR register
Output level held
Set to 0 by a program
n+1
TRCIOB output
“H” output at
compare match
Initial output “L”
1
0
IMFB bit in
TRCSR register
Set to 0 by a program
P+1
Output level held
“L” output at compare match
TRCIOC output
Initial output “H”
1
0
IMFC bit in
TRCSR register
Set to 0 by a program
m: TRCGRA register setting value
n: TRCGRB register setting value
p: TRCGRC register setting value
The above applies under the following conditions:
• Bits BFC and BFD in the TRCMR register are set to 0 (TRCGRC and TRCGRD do not operate as buffers).
• Bits EA, EB, and EC in the TRCOER register are set to 0 (output from TRCIOA, TRCIOB, and TRCIOC enabled).
• The CCLR bit in the TRCCR1 register is set to 1 (set the TRC register to 0000h by TRCGRA compare match).
• In the TRCCR1 register, bits TOA and TOB are set to 0 (“L” initial output until compare match) and the TOC bit is set to 1 (“H” initial output until
compare match).
• Bits IOA2 to IOA0 in the TRCIOR0 register are set to 011b (TRCIOA output inverted at TRCGRA compare match).
• Bits IOB2 to IOB0 in the TRCIOR0 register are set to 010b (“H” TRCIOB output at TRCGRB compare match).
• Bits IOC2 to IOC2 in the TRCIOR1 register are set to 001b (“L” TRCIOC output at TRCGRC compare match).
Figure 14.50 Operating Example of Output Compare Function
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14.Timers
14.3.6 PWM Mode
This mode outputs PWM waveforms. A maximum of three PWM waveforms with the same period are output.
The PWM mode, or the timer mode, can be selected for each individual pin. (However, since the TRCGRA
register is used when using any pin for the PWM mode, the TRCGRA register cannot be used for the timer
mode.)
Table 14.20 lists the Specifications of PWM Mode, Figure 14.51 shows a Block Diagram of PWM Mode,
Figure 14.52 shows the register associated with the PWM mode, Table 14.21 lists the Functions of TRCGRj
Register in PWM Mode, and Figures 14.53 and 14.54 show Operating Examples of PWM Mode.
Table 14.20 Specifications of PWM Mode
Item
Count source
Specification
f1, f2, f4, f8, f32, fOCO40M, or external signal (rising edge) input to
TRCCLK pin
Count operation
PWM waveform
Increment
PWM period: 1/fk × (m + 1)
Active level width: 1/fk × (m - n)
Inactive width: 1/fk × (n + 1)
fk: Count source frequency
m: TRCGRA register setting value
n: TRCGRj register setting value
m+1
(“L” is active level)
n+1
m-n
Count start condition
Count stop condition
1 (count starts) is written to the TSTART bit in the TRCMR register.
0 (count stops) is written to the TSTART bit in the TRCMR register.
PWM output pin retains output level before count stops, TRC register
retains value before count stops.
Interrupt request generation
timing
• Compare match (contents of registers TRC and TRCGRh match)
• The TRC register overflows.
TRCIOA pin function
TRCIOB, TRCIOC, and
TRCIOD pin functions
Programmable I/O port
Programmable I/O port or PWM output (selectable individually by pin)
INT0 pin function
Programmable I/O port, pulse output forced cutoff signal input, or INT0
interrupt input
Read from timer
Write to timer
The count value can be read by reading the TRC register.
The TRC register can be written to.
Select functions
• One to three pins selectable as PWM output pins per channel
One or more of pins TRCIOB, TRCIOC, and TRCIOD
• Active level selectable by individual pin
• Buffer operation (Refer to 14.3.3.2 Buffer Operation.)
• Pulse output forced cutoff signal input (Refer to 14.3.3.4 Forced Cutoff
of Pulse Output.)
j = B, C, or D
h = A, B, C, or D
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14.Timers
TRC
Compare match signal
Compare match signal
Compare match signal
Compare match signal
Comparator
Comparator
Comparator
Comparator
TRCGRA
TRCGRB
TRCGRC
TRCGRD
TRCIOB
(Note 1)
Output
control
TRCIOC
TRCIOD
(Note 2)
NOTES:
1. The BFC bit in the TRCMR register is set to 1 (TRCGRC register functions as the buffer register for the TRCGRA register)
2. The BFD bit in the TRCMR register is set to 1 (TRCGRD register functions as the buffer register for the TRCGRB register)
Figure 14.51 Block Diagram of PWM Mode
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Timer RC Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCCR1
Address
0121h
After Reset
00h
Bit Symbol
Bit Name
TRCIOA output level select bit(1)
Function
RW
RW
Disabled in PWM mode
TOA
TOB
TRCIOB output level select bit(1, 2)
TRCIOC output level select bit(1, 2)
TRCIOD output level select bit(1, 2)
Count source select bits(1)
0 : Active level “H”
(Initial output “L”
“H” output by compare match in
the TRCGRj register
RW
RW
RW
“L” output by compare match in
the TRCGRA register
1 : Active level “L”
TOC
TOD
(Initial output “H”
“L” output by compare match in
the TRCGRj register
“H” output by compare match in
the TRCGRA register
b6 b5 b4
0 0 0 : f1
0 0 1 : f2
0 1 0 : f4
0 1 1 : f8
TCK0
TCK1
TCK2
CCLR
RW
RW
RW
RW
1 0 0 : f32
1 0 1 : TRCCLK input rising edge
1 1 0 : fOCO40M
1 1 1 : Do not set.
TRC counter clear select bit
0 : Disable clear (free-running operation)
1 : Clear by compare match in the
TRCGRA register
j = B, C or D
NOTES:
1. Set to these bits w hen the TSTART bit in the TRCMR register is set to 0 (count stops).
2. If the pin function is set for w aveform output (refer to
,
,
to
, and
Table 7.15 Table 7.16 Tables 7.26 7.29 Tables
to
), the initial output level is output w hen the TRCCR1 register is set.
7.37 7.40
Figure 14.52 TRCCR1 Register in PWM Mode
Table 14.21 Functions of TRCGRj Register in PWM Mode
Register
TRCGRA
TRCGRB
TRCGRC
TRCGRD
TRCGRC
Setting
Register Function
PWM Output Pin
−
−
General register. Set the PWM period.
−
General register. Set the PWM output change point.
General register. Set the PWM output change point.
TRCIOB
TRCIOC
TRCIOD
−
BFC = 0
BFD = 0
BFC = 1
Buffer register. Set the next PWM period. (Refer to 14.3.3.2
Buffer Operation.)
TRCGRD
BFD = 1
Buffer register. Set the next PWM output change point. (Refer to TRCIOB
14.3.3.2 Buffer Operation.)
j = A, B, C, or D
BFC, BFD: Bits in TRCMR register
NOTE:
1. The output level does not change even when a compare match occurs if the TRCGRA register value (PWM
period) is the same as the TRCGRB, TRCGRC, or TRCGRD register value.
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Count source
TRC register value
m
n
p
q
m+1
n+1
m-n
Active level is “H”
Inactive level is “L”
p+1
TRCIOB output
TRCIOC output
TRCIOD output
m-p
“L” initial output until
compare match
q+1
m-q
Active level is “L”
“H” initial output until
compare match
1
0
IMFA bit in
TRCSR register
Set to 0 by a program
Set to 0 by a program
1
0
IMFB bit in
TRCSR register
1
0
IMFC bit in
TRCSR register
Set to 0 by a program
Set to 0 by a program
1
0
IMFD bit in
TRCSR register
m: TRCGRA register setting value
n: TRCGRB register setting value
p: TRCGRC register setting value
q: TRCGRD register setting value
The above applies under the following conditions:
• Bits BFC and BFD in the TRCMR register are set to 0 (registers TRCGRC and TRCGRD do not operate as buffers).
• Bits EB, EC, and ED in the TRCOER register are set to 0 (output from TRCIOB, TRCIOC, and TRCIOD enabled).
• In the TRCCR1 register, bits TOB and TOC are set to 0 (active level is “H”) and the TOD bit is set to 1 (active level is “L”).
Figure 14.53 Operating Example of PWM Mode
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TRC register value
p
m
q
n
0000h
1
0
TSTART bit in
TRCMR register
TRCIOB output does not switch to “L” because
no compare match with the TRCGRB register
has occurred
Duty 0%
TRCIOB output
TRCGRB register
n
p (p>m)
Rewritten by a program
q
1
0
IMFA bit in
TRCSR register
Set to 0 by a program
Set to 0 by a program
1
0
IMFB bit in
TRCSR register
TRC register value
m
p
n
0000h
1
0
TSTART bit in
TRCMR register
If compare matches occur simultaneously with registers TRCGRA and
TRCGRB, the compare match with the TRCGRB register has priority.
TRCIOB output switches to “L”. (In other words, no change).
Duty 100%
TRCIOB output
TRCIOB output switches to “L” at compare match with the
TRCGRB register. (In other words, no change).
TRCGRB register
n
m
p
Rewritten by
a program
1
0
IMFA bit in
TRCSR register
Set to 0 by a program
Set to 0 by a program
1
0
IMFB bit in
TRCSR register
m: TRCGRA register setting value
The above applies under the following conditions:
• The EB bit in the TRCOER register is set to 0 (output from TRCIOB enabled).
• The TOB bit in the TRCCR1 register is set to 1 (active level is “L”).
Figure 14.54 Operating Example of PWM Mode (Duty 0% and Duty 100%)
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14.Timers
14.3.7 PWM2 Mode
This mode outputs a single PWM waveform. After a given wait duration has elapsed following the trigger, the
pin output switches to active level. Then, after a given duration, the output switches back to inactive level.
Furthermore, the counter stops at the same time the output returns to inactive level, making it possible to use
PWM2 mode to output a programmable wait one-shot waveform.
Since timer RC uses multiple general registers in PWM2 mode, other modes cannot be used in conjunction with
it.
Figure 14.55 shows a Block Diagram of PWM2 Mode, Table 14.22 lists the Specifications of PWM2 Mode,
Figure 14.56 shows the register associated with PWM2 mode, Table 14.23 lists the Functions of TRCGRj
Register in PWM2 Mode, and Figures 14.57 to 14.59 show Operating Examples of PWM2 Mode.
Trigger signal
Compare match signal
Count clear signal
(Note 1)
Input
control
TRCTRG
TRCIOB
TRC
Comparator
Comparator
Comparator
TRCGRA
TRCGRB
TRCGRC
TRCGRD
register
Output
control
NOTE:
1. The BFD bit in the TRCMR register is set to 1 (the TRCGRD register functions as the buffer register for the TRCGRB register).
Figure 14.55 Block Diagram of PWM2 Mode
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Table 14.22 Specifications of PWM2 Mode
Item
Specification
Count source
f1, f2, f4, f8, f32, fOCO40M, or external signal (rising edge) input to TRCCLK pin
Increment TRC register
Count operation
PWM waveform
PWM period: 1/fk × (m + 1) (no TRCTRG input)
Active level width: 1/fk × (n - p)
Wait time from count start or trigger: 1/fk × (p + 1)
fk: Count source frequency
m: TRCGRA register setting value
n: TRCGRB register setting value
p: TRCGRC register setting value
TRCTRG input
m+1
n+1
p+1
n+1
p+1
TRCIOB output
n-p
n-p
(TRCTRG: Rising edge, active level is “H”)
Count start conditions
Count stop conditions
• Bits TCEG1 to TCEG0 in the TRCCR2 register are set to 00b (TRCTRG trigger
disabled) or the CSEL bit in the TRCCR2 register is set to 0 (count continues).
1 (count starts) is written to the TSTART bit in the TRCMR register.
• Bits TCEG1 to TCEG0 in the TRCCR2 register are set to 01b, 10b, or 11b
(TRCTRG trigger enabled) and the TSTART bit in the TRCMR register is set to 1
(count starts).
A trigger is input to the TRCTRG pin
• 0 (count stops) is written to the TSTART bit in the TRCMR register while the CSEL
bit in the TRCCR2 register is set to 0 or 1.
The TRCIOB pin outputs the initial level in accordance with the value of the TOB
bit in the TRCCR1 register. The TRC register retains the value before count stops.
• The count stops due to a compare match with TRCGRA while the CSEL bit in the
TRCCR2 register is set to 1
The TRCIOB pin outputs the initial level. The TRC register retains the value before
count stops if the CCLR bit in the TRCCR1 register is set to 0. The TRC register is
set to 0000h if the CCLR bit in the TRCCR1 register is set to 1.
Interrupt request
generation timing
• Compare match (contents of TRC and TRCGRj registers match)
• The TRC register overflows
TRCIOA/TRCTRG pin
function
Programmable I/O port or TRCTRG input
TRCIOB pin function
PWM output
TRCIOC and TRCIOD
pin functions
Programmable I/O port
INT0 pin function
Programmable I/O port, pulse output forced cutoff signal input, or INT0 interrupt
input
Read from timer
Write to timer
The count value can be read by reading the TRC register.
The TRC register can be written to.
Select functions
• External trigger and valid edge selected
The edge or edges of the signal input to the TRCTRG pin can be used as the
PWM output trigger: rising edge, falling edge, or both rising and falling edges
• Buffer operation (Refer to 14.3.3.2 Buffer Operation.)
• Pulse output forced cutoff signal input (Refer to 14.3.3.4 Forced Cutoff of Pulse
Output.)
• Digital filter (Refer to 14.3.3.3 Digital Filter.)
j = A, B, or C
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Timer RC Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TRCCR1
Address
0121h
After Reset
00h
Bit Symbol
Bit Name
TRCIOA output level select bit(1)
Function
RW
RW
Disabled in the PWM2 mode
TOA
TRCIOB output level select bit(1, 2)
0 : Active level “H”
(Initial output “L”
“H” output by compare match in the
TRCGRC register
“L” output by compare match in the
TRCGRB register
1 : Active level “L”
TOB
RW
(Initial output “H”
“L” output by compare match in the
TRCGRC register
“H” output by compare match in the
TRCGRB register
TRCIOC output level select bit(1)
TRCIOD output level select bit(1)
Count source select bits(1)
Disabled in the PWM2 mode
TOC
TOD
RW
RW
b6 b5 b4
0 0 0 : f1
0 0 1 : f2
TCK0
TCK1
TCK2
RW
RW
RW
RW
0 1 0 : f4
0 1 1 : f8
1 0 0 : f32
1 0 1 : TRCCLK input rising edge
1 1 0 : fOCO40M
1 1 1 : Do not set.
TRC counter clear select bit
0 : Disable clear (free-running operation)
1 : Clear by compare match in the
TRCGRA register
CCLR
NOTES:
1. Set to these bits w hen the TSTART bit in the TRCMR register is set to 0 (count stops).
2. If the pin function is set for w aveform output (refer to
w hen the TRCCR1 register is set.
and
), the initial output level is output
Table 7.16
Table 7.15
Figure 14.56 TRCCR1 Register in PWM2 Mode
Table 14.23 Functions of TRCGRj Register in PWM2 Mode
Register
TRCGRA
TRCGRB
TRCGRC
Setting
Register Function
PWM2 Output Pin
TRCIOB pin
−
−
General register. Set the PWM period.
General register. Set the PWM output change point.
BFC = 0
General register. Set the PWM output change point (wait time
after trigger).
TRCGRD
TRCGRD
BFD = 0
BFD = 1
(Not used in PWM2 mode)
−
Buffer register. Set the next PWM output change point. (Refer to TRCIOB pin
14.3.3.2 Buffer Operation.)
j = A, B, C, or D
BFC, BFD: Bits in TRCMR register
NOTE:
1. Do not set the TRCGRB and TRCGRC registers to the same value.
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Count source
TRC register value
FFFFh
m
TRC register cleared
at TRCGRA register
compare match
n
Previous value held if the
TSTRAT bit is set to 0
Set to 0000h
by a program
p
0000h
Count stops
because the
CSEL bit is
set to 1
1
0
TSTART bit in
TRCMR register
Set to 1 by
a program
TSTART bit
is set to 0
1
0
CSEL bit in
TRCCR2 register
m+1
n+1
p+1
p+1
Return to initial output
if the TSTART bit is
set to 0
“H” output at TRCGRC
register compare match
“L” output at TRCGRB
register compare match
No change
“L” initial output
No change
TRCIOB output
“H” output at TRCGRC register
compare match
1
0
IMFA bit in
TRCSR register
Set to 0 by a program
1
0
IMFB bit in
TRCSR register
Set to 0 by a program
Set to 0 by a program
1
0
IMFC bit in
TRCSR register
TRCGRB register
TRCGRD register
n
Transfer
Transfer
n
Next data
Transfer from buffer register to general register
m: TRCGRA register setting value
n: TRCGRB register setting value
p: TRCGRC register setting value
The above applies under the following conditions:
• The TOB bit in the TRCCR1 register is set to 0 (initial level is “L”, “H” output at compare match with the TRCGRC register, “L” output at compare
match with the TRCGRB register).
• Bits TCEG1 and TCEG0 in the TRCCR2 register are set to 00b (TRCTRG trigger input disabled).
Figure 14.57 Operating Example of PWM2 Mode (TRCTRG Trigger Input Disabled)
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Count source
TRC register value
TRC register cleared
at TRCGRA register
compare match
FFFFh
m
TRC register (counter)
cleared at TRCTRG pin
trigger input
Previous value
held if the
TSTART bit is
set to 0
n
Set to 0000h
by a program
p
0000h
Count stops
because the
CSEL bit is
set to 1
Count starts at
TRCTRG pin
trigger input
TRCTRG input
Count starts
when TSTART
bit is set to 1
Changed by a program
The TSTART
bit is set to 0
1
0
TSTART bit in
TRCMR register
1
0
CSEL bit in
TRCCR2 register
Set to 1 by
a program
m+1
n+1
p+1
n+1
p+1
p+1
“L” output at
TRCGRB register
compare match
“H” output at
TRCGRC register
compare match
“L” initial output
TRCIOB output
Active level so TRCTRG
input is disabled
Inactive level so
TRCTRG input is
enabled
Return to initial value if the
TSTART bit is set to 0
1
0
IMFA bit in
TRCSR register
Set to 0 by
a program
1
0
IMFB bit in
TRCSR register
Set to 0 by
a program
Set to 0 by
a program
Set to 0 by
a program
1
0
IMFC bit in
TRCSR register
TRCGRB register
TRCGRD register
n
n
n
n
Transfer
Transfer
Transfer
Transfer
n
Next data
Transfer from buffer register to general register
Transfer from buffer register to general register
m: TRCGRA register setting value
n: TRCGRB register setting value
p: TRCGRC register setting value
The above applies under the following conditions:
• The TOB bit in the TRCCR1 register is set to 0 (initial level is “L”, “H” output at compare match with the TRCGRC register, “L” output at compare match with the
TRCGRB register).
• Bits TCEG1 and TCEG0 in the TRCCR2 register are set to 11b (trigger at both rising and falling edges of TRCTRG input).
Figure 14.58 Operating Example of PWM2 Mode (TRCTRG Trigger Input Enabled)
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• TRCGRB register setting value greater than TRCGRA
register setting value
• TRCGRC register setting value greater than TRCGRA
register setting value
TRC register value
TRC register value
n
p
m
m
n
p
0000h
0000h
1
0
1
0
TSTART bit in
TRCMR register
TSTART bit in
TRCMR register
p+1
n+1
m+1
m+1
No compare match with
TRCGRB register, so
“H” output continues
“L” output at
No compare match
with TRCGRC register,
so “L” output continues
TRCGRB register
compare match
with no change
TRCIOB output
TRCIOB output
“H” output at TRCGRC register
compare match
“L” initial
output
“L” initial
output
1
0
1
IMFA bit in
TRCSR register
IMFA bit in
TRCSR register
0
1
0
1
0
IMFB bit in
TRCSR register
IMFB bit in
TRCSR register
Set to 0 by a
program
1
0
1
0
IMFC bit in
TRCSR register
IMFC bit in
TRCSR register
m: TRCGRA register setting value
n: TRCGRB register setting value
p: TRCGRC register setting value
The above applies under the following conditions:
• The TOB bit in the TRCCR1 register is set to 0 (initial level is “L”, “H” output at compare match with the TRCGRC register, “L” output at compare
match with the TRCGRB register).
• Bits TCEG1 and TCEG0 in the TRCCR2 register are set to 00b (TRCTRG trigger input disabled).
Figure 14.59 Operating Example of PWM2 Mode (Duty 0% and Duty 100%)
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14.Timers
14.3.8 Timer RC Interrupt
Timer RC generates a timer RC interrupt request from five sources. The timer RC interrupt uses the single
TRCIC register (bits IR and ILVL0 to ILVL2) and a single vector.
Table 14.24 lists the Registers Associated with Timer RC Interrupt, and Figure 14.60 shows a Block Diagram of
Timer RC Interrupt.
Table 14.24 Registers Associated with Timer RC Interrupt
Timer RC Status Register Timer RC Interrupt Enable Register Timer RC Interrupt Control Register
TRCSR
TRCIER
TRCIC
IMFA bit
IMIEA bit
Timer RC interrupt request
(IR bit in TRCIC register)
IMFB bit
IMIEB bit
IMFC bit
IMIEC bit
IMFD bit
IMIED bit
OVF bit
OVIE bit
IMFA, IMFB, IMFC, IMFD, OVF: Bits in TRCSR register
IMIEA, IMIEB, IMIEC, IMIED, OVIE: Bits in TRCIER register
Figure 14.60 Block Diagram of Timer RC Interrupt
Like other maskable interrupts, the timer RC interrupt is controlled by the combination of the I flag, IR bit, bits
ILVL0 to ILVL2, and IPL. However, it differs from other maskable interrupts in the following respects because
a single interrupt source (timer RC interrupt) is generated from multiple interrupt request sources.
• The IR bit in the TRCIC register is set to 1 (interrupt requested) when a bit in the TRCSR register is set to
1 and the corresponding bit in the TRCIER register is also set to 1 (interrupt enabled).
• The IR bit is set to 0 (no interrupt request) when the bit in the TRCSR register or the corresponding bit in
the TRCIER register is set to 0, or both are set to 0. In other words, the interrupt request is not maintained
if the IR bit is once set to 1 but the interrupt is not acknowledged.
• If after the IR bit is set to 1 another interrupt source is triggered, the IR bit remains set to 1 and does not
change.
• If multiple bits in the TRCIER register are set to 1, use the TRCSR register to determine the source of the
interrupt request.
• The bits in the TRCSR register are not automatically set to 0 when an interrupt is acknowledged. Set them
to 0 within the interrupt routine. Refer to Figure 14.30 TRCSR Register, for the procedure for setting
these bits to 0.
Refer to Figure 14.29 TRCIER Register, for details of the TRCIER register.
Refer to 12.1.6 Interrupt Control, for details of the TRCIC register and 12.1.5.2 Relocatable Vector Tables,
for information on interrupt vectors.
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14.3.9 Notes on Timer RC
14.3.9.1 TRC Register
• The following note applies when the CCLR bit in the TRCCR1 register is set to 1 (clear TRC register at
compare match with TRCGRA register).
When using a program to write a value to the TRC register while the TSTART bit in the TRCMR register is
set to 1 (count starts), ensure that the write does not overlap with the timing with which the TRC register is
set to 0000h.
If the timing of the write to the TRC register and the setting of the TRC register to 0000h coincide, the
write value will not be written to the TRC register and the TRC register will be set to 0000h.
• Reading from the TRC register immediately after writing to it can result in the value previous to the write
being read out. To prevent this, execute the JMP.B instruction between the read and the write instructions.
Program Example
MOV.W
JMP.B
MOV.W
#XXXXh, TRC
L1
TRC,DATA
;Write
;JMP.B instruction
;Read
L1:
14.3.9.2 TRCSR Register
Reading from the TRCSR register immediately after writing to it can result in the value previous to the write
being read out. To prevent this, execute the JMP.B instruction between the read and the write instructions.
Program Example
MOV.B
JMP.B
MOV.B
#XXh, TRCSR
L1
TRCSR,DATA
;Write
;JMP.B instruction
;Read
L1:
14.3.9.3 Count Source Switching
• Stop the count before switching the count source.
Switching procedure
(1) Set the TSTART bit in the TRCMR register to 0 (count stops).
(2) Change the settings of bits TCK2 to TCK0 in the TRCCR1 register.
• After switching the count source from fOCO40M to another clock, allow a minimum of two cycles of f1 to
elapse after changing the clock setting before stopping fOCO40M.
Switching procedure
(1) Set the TSTART bit in the TRCMR register to 0 (count stops).
(2) Change the settings of bits TCK2 to TCK0 in the TRCCR1 register.
(3) Wait for a minimum of two cycles of f1.
(4) Set the FRA00 bit in the FRA0 register to 0 (high-speed on-chip oscillator off).
14.3.9.4 Input Capture Function
• The pulse width of the input capture signal should be three cycles or more of the timer RC operation clock
(refer to Table 14.11 Timer RC Operation Clock).
• The value of the TRC register is transferred to the TRCGRj register one or two cycles of the timer RC
operation clock after the input capture signal is input to the TRCIOj (j = A, B, C, or D) pin (when the
digital filter function is not used).
14.3.9.5 TRCMR Register in PWM2 Mode
When the CSEL bit in the TRCCR2 register is set to 1 (count stops at compare match with the TRCGRA
register), do not set the TRCMR register at compare match timing of registers TRC and TRCGRA.
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14.Timers
14.4 Timer RE
Timer RE has the 4-bit counter and 8-bit counter. Timer RE has the following 2 modes:
• Real-time clock mode
Generate 1-second signal from fC4 and count seconds, minutes, hours, and days of
the week.
• Output compare mode
Count a count source and detect compare matches.
(For J, K version, timer RE can be used only in output compare mode.)
The count source for timer RE is the operating clock that regulates the timing of timer operations.
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14.Timers
14.4.1 Real-Time Clock Mode (For N, D Version Only)
In real-time clock mode, a 1-second signal is generated from fC4 using a divide-by-2 frequency divider, 4-bit
counter, and 8-bit counter and used to count seconds, minutes, hours, and days of the week. Figure 14.61 shows
a Block Diagram of Real-Time Clock Mode and Table 14.25 lists the Specifications of Real-Time Clock Mode.
Figures 14.62 to 14.66 and 14.68 and 14.69 show the registers associated with real-time clock mode. Table
14.26 lists the Interrupt Sources, Figure 14.67 shows the Definition of Time Representation, and Figure 14.70
shows the Operating Example in Real-Time Clock Mode.
(1/16)
(1/256)
(1s)
Overflow
1/2
fC4
4-bit counter
8-bit counter
Data bus
Overflow
Overflow
Overflow
TRESEC
register
TREMIN
register
TREHR
register
TREWK
register
000
H12_H24 PM
WKIE
bit
bit
Timing
control
Timer RE interrupt
DYIE
HRIE
INT
bit
MNIE
SEIE
BSY
bit
H12_H24, PM, INT: Bits in TRECR1 register
BSY: Bit in registers TRESEC, TREMIN, TREHR, and TREWK
Figure 14.61 Block Diagram of Real-Time Clock Mode
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14.Timers
Table 14.25 Specifications of Real-Time Clock Mode
Item
Specification
Count source
fC4
Count operation
Count start condition
Count stop condition
Interrupt request
generation timing
Increment
1 (count starts) is written to TSTART bit in TRECR1 register
0 (count stops) is written to TSTART bit in TRECR1 register
Select any one of the following:
• Update second data
• Update minute data
• Update hour data
• Update day of week data
• When day of week data is set to 000b (Sunday)
Programmable I/O ports or output of f2, f4, or f8
TREO pin function
Read from timer
When reading TRESEC, TREMIN, TREHR, or TREWK register, the count
value can be read. The values read from registers TRESEC, TREMIN, and
TREHR are represented by the BCD code.
Write to timer
When bits TSTART and TCSTF in the TRECR1 register are set to 0 (timer
stops), the value can be written to registers TRESEC, TREMIN, TREHR,
and TREWK. The values written to registers TRESEC, TREMIN, and
TREHR are represented by the BCD codes.
Select function
• 12-hour mode/24-hour mode switch function
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14.Timers
Timer RE Second Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
0118h
After Reset
00h
TRESEC
Setting
Range
Bit Symbol
Bit Name
Function
RW
SC00
SC01
SC02
SC03
SC10
SC11
SC12
1st digit of second count bits
Count 0 to 9 every second. When the 0 to 9
digit moves up, 1 is added to the 2nd (BCD
RW
RW
RW
RW
RW
RW
RW
digit of second.
code)
2nd digit of second count bits When counting 0 to 5, 60 seconds
are counted.
0 to 5
(BCD
code)
Timer REbusy flag
This bit is set to 1 w hile registers TRESEC,
TREMIN, TREHR, and TREWK are updated.
BSY
RO
Figure 14.62 TRESEC Register in Real-Time Clock Mode
Timer RE Minute Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TREMIN
Address
0119h
After Reset
00h
Setting
Range
Bit Symbol
Bit Name
Function
RW
MN00
MN01
MN02
MN03
MN10
MN11
MN12
1st digit of minute count bits
Count 0 to 9 every minute. When the 0 to 9
digit moves up, 1 is added to the 2nd (BCD
RW
RW
RW
RW
RW
RW
RW
digit of minute.
code)
2nd digit of minute count bits
Timer REbusy flag
When counting 0 to 5, 60 minutes are 0 to 5
counted.
(BCD
code)
This bit is set to 1 w hile registers TRESEC,
TREMIN, TREHR, and TREWK are updated.
BSY
RO
Figure 14.63 TREMIN Register in Real-Time Clock Mode
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14.Timers
Timer RE Hour Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TREHR
Address
011Ah
After Reset
00h
Setting
Range
Bit Symbol
Bit Name
Function
RW
HR00
HR01
HR02
HR03
1st digit of hour count bits
Count 0 to 9 every hour. When the
digit moves up, 1 is added to the 2nd (BCD
digit of hour. code)
0 to 9
RW
RW
RW
RW
2nd digit of hour count bits
Count 0 to 1 w hen the H12_H24 bit is 0 to 2
set to 0 (12-hour mode). (BCD
Count 0 to 2 w hen the H12_H24 bit is code)
set to 1 (24-hour mode).
HR10
HR11
RW
RW
—
—
(b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Timer REbusy flag
This bit is set to 1 w hile registers TRESEC,
TREMIN, TREHR, and TREWK are updated.
BSY
RO
Figure 14.64 TREHR Register in Real-Time Clock Mode
Timer RE Day of Week Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TREWK
Address
011Bh
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
b2 b1 b0
Day of w eek count bits
0 0 0 : Sunday
0 0 1 : Monday
0 1 0 : Tuesday
WK0
0 1 1 : Wednesday
1 0 0 : Thursday
1 0 1 : Friday
1 1 0 : Saturday
1 1 1 : Do not set
WK1
WK2
RW
RW
—
—
(b6-b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Timer REbusy flag
This bit is set to 1 w hile registers TRESEC,
TREMIN, TREHR, and TREWK are updated.
BSY
RO
Figure 14.65 TREWK Register in Real-Time Clock Mode
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14.Timers
Timer RE Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
011Ch
After Reset
00h
TRECR1
Bit Symbol
Bit Name
Function
RW
—
—
(b0)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Timer REcount status flag
TREO pin output enable bit
Interrupt request timing bit
Timer REreset bit
0 : Count stopped
1 : Counting
TCSTF
TOENA
INT
RO
RW
RW
0 : Disable clock output
1 : Enable clock output
Set to 1 in real-time clock mode.
When setting this bit to 0, after setting it to 1, the
follow ings w ill occur.
• Registers TRESEC, TREMIN, TREHR, TREWK,
and TRECR2 are set to 00h.
TRERST
RW
RW
• Bits TCSTF, INT, PM, H12_H24, and TSTART
in the TRECR1 register are set to 0.
• The 8-bit counter is set to 00h and
the 4-bit counter is set to 0h.
A.m./p.m. bit
When the H12_H24 bit is set to 0
(12-hour mode)(1)
0 : a.m.
1 : p.m.
PM
When the H12_H24 bit is set to 1 (24-hour
mode), its value is undefined.
Operating mode select bit
Timer REcount start bit
0 : 12-hour mode
1 : 24-hour mode
H12_H24
RW
RW
0 : Count stops
1 : Count starts
TSTART
NOTE:
1. This bit is automatically modified w hile timer REcounts.
Figure 14.66 TRECR1 Register in Real-Time Clock Mode
Noon
H12_H24 bit = 1
(24-hour mode)
0
0
1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
9
9
10 11 12 13 14 15 16 17
10 11
Contents of
TREHR Register
H12_H24 bit = 0
(12-hour mode)
0
1
2
3
4
5
0 (a.m.)
1 (p.m.)
Contents of PM bit
000 (Sunday)
Contents in TREWK register
Date changes
H12_H24 bit = 1
(24-hour mode)
18 19 20 21 22 23
10 11
0
0
1
1
2
2
3
3
⋅⋅⋅
⋅⋅⋅
Contents of
TREHR Register
H12_H24 bit = 0
(12-hour mode)
6
7
8
9
1 (p.m.)
0 (a.m.)
⋅⋅⋅
⋅⋅⋅
Contents of PM bit
000 (Sunday)
001 (Monday)
Contents in TREWK register
PM bit and H12_H24 bits: Bits in TRECR1 register
The above applies to the case when count starts from a.m. 0 on Sunday.
Figure 14.67 Definition of Time Representation
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14.Timers
Timer RE Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
011Dh
After Reset
00h
TRECR2
Bit Symbol
Bit Name
Function
RW
RW
Periodic interrupt triggered every
second enable bit(1)
0 : Disable periodic interrupt triggered
every second
1 : Enable periodic interrupt triggered
every second
SEIE
MNIE
HRIE
DYIE
Periodic interrupt triggered every
minute enable bit(1)
0 : Disable periodic interrupt triggered
every minute
1 : Enable periodic interrupt triggered
every minute
RW
RW
RW
RW
Periodic interrupt triggered every
hour enable bit(1)
0 : Disable periodic interrupt triggered
every hour
1 : Enable periodic interrupt triggered
every hour
Periodic interrupt triggered every day 0 : Disable periodic interrupt triggered
enable bit(1)
every day
1 : Enable periodic interrupt triggered
every day
Periodic interrupt triggered every
w eek enable bit(1)
0 : Disable periodic interrupt triggered
every w eek
1 : Enable periodic interrupt triggered
every w eek
WKIE
Compare match interrupt enable bit
Set to 0 in real-time clock mode.
COMIE
RW
—
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. Do not set multiple enable bits to 1 (enable interrupt).
Figure 14.68 TRECR2 Register in Real-Time Clock Mode
Table 14.26 Interrupt Sources
Factor
Interrupt Source
Value in TREWK register is set to 000b (Sunday)
(1-week period)
Interrupt Enable Bit
Periodic interrupt
triggered every week
Periodic interrupt
triggered every day
Periodic interrupt
triggered every hour
Periodic interrupt
WKIE
DYIE
HRIE
MNIE
SEIE
TREWK register is updated (1-day period)
TREHR register is updated (1-hour period)
TREMIN register is updated (1-minute period)
TRESEC register is updated (1-second period)
triggered every minute
Periodic interrupt
triggered every second
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14.Timers
Timer RE Count Source Select Register
b7 b6 b5 b4 b3 b2 b1 b0
1 0 0 0
Symbol
Address
011Eh
After Reset
00001000b
TRECSR
Bit Symbol
Bit Name
Function
RW
RW
RW
RW
RW
—
Count source select bits
Set to 00b in real-time clock mode.
RCS0
RCS1
RCS2
RCS3
4-bit counter select bit
Set to 0 in real-time clock mode.
Set to 1 in real-time clock mode.
Real-time clock mode select bit
—
(b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Clock output select bits(1)
b6 b5
0 0 : f2
RCS5
RCS6
RW
0 1 : f4
1 0 : f8
1 1 : Do not set.
RW
—
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. Write to bits RCS5 to RCS6 w hen the TOENA bit in the TRECR1 register is set to 0 (disable clock output).
Figure 14.69 TRECSR Register in Real-Time Clock Mode
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14.Timers
1s
Approx.
62.5 ms
Approx.
62.5 ms
BSY bit
Bits SC12 to SC00 in
TRESEC register
58
59
00
04
Bits MN12 to MN00 in
TREMIN register
03
Bits HR11 to HR00 in
TREHR register
(Not changed)
1
0
PM bit in
TRECR1 register
(Not changed)
(Not changed)
Bits WK2 to WK0 in
TREWK register
Set to 0 by acknowledgement
of interrupt request
or a program
1
0
IR bit in TREIC register
(when SEIE bit in TRECR2 register is set
to 1 (enable periodic interrupt triggered
every second))
1
0
IR bit in TREIC register
(when MNIE bit in TRECR2 register is set
to 1 (enable periodic interrupt triggered
every minute))
BSY: Bit in registers TRESEC, TREMIN, TREHR, and TREWK
Figure 14.70 Operating Example in Real-Time Clock Mode
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14.Timers
14.4.2 Output Compare Mode
In output compare mode, the internal count source divided by 2 is counted using the 4-bit or 8-bit counter and
compare value match is detected with the 8-bit counter. Figure 14.71 shows a Block Diagram of Output
Compare Mode and Table 14.27 lists the Specifications of Output Compare Mode. Figures 14.72 to 14.76 show
the registers associated with output compare mode, and Figure 14.77 shows the Operating Example in Output
Compare Mode.
f4
f8
RCS6 to RCS5
= 00b
TOENA
RCS1 to RCS0
= 00b
f2
= 01b
TREO pin
= 10b
= 01b
= 10b
= 11b
RCS2 = 1
RCS2 = 0
4-bit
counter
1/2
= 11b
8-bit
counter
T Q
f32
fC4(1)
R
Reset
TRERST bit
Match
signal
Comparison
circuit
Timer RE interrupt
COMIE
TRERST, TOENA: Bits in TRECR1 register
COMIE: Bit in TRECR2 register
TRESEC
TREMIN
RCS0 to RCS2, RCS5 to RCS6: Bits in TRECSR register
Data bus
NOTE:
1. For J, K version, fC4 cannot be selected.
Figure 14.71 Block Diagram of Output Compare Mode
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14.Timers
Table 14.27 Specifications of Output Compare Mode
Item
Specification
(1)
Count sources
f4, f8, f32, fC4
• Increment
Count operations
• When the 8-bit counter content matches with the TREMIN register content,
the value returns to 00h and count continues. The count value is held while
count stops.
Count period
• When RCS2 = 0 (4-bit counter is not used)
1/fi x 2 x (n+1)
• When RCS2 = 1 (4-bit counter is used)
1/fi x 32 x (n+1)
fi: Frequency of count source
n: Setting value of TREMIN register
Count start condition
Count stop condition
Interrupt request
1 (count starts) is written to the TSTART bit in the TRECR1 register
0 (count stops) is written to the TSTART bit in the TRECR1 register
When the 8-bit counter content matches with the TREMIN register content
generation timing
TREO pin function
Select any one of the following:
• Programmable I/O ports
• Output f2, f4, or f8
• Compare output
Read from timer
Write to timer
When reading the TRESEC register, the 8-bit counter value can be read.
When reading the TREMIN register, the compare value can be read.
Writing to the TRESEC register is disabled.
When bits TSTART and TCSTF in the TRECR1 register are set to 0 (timer
stops), writing to the TREMIN register is enabled.
• Select use of 4-bit counter
Select functions
• Compare output function
Every time the 8-bit counter value matches the TREMIN register value,
TREO output polarity is reversed. The TREO pin outputs “L” after reset is
deasserted and the timer RE is reset by the TRERST bit in the TRECR1
register. Output level is held by setting the TSTART bit to 0 (count stops).
NOTE:
1. For J, K version, fC4 cannot be selected.
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14.Timers
Timer RE Counter Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
0118h
After Reset
00h
TRESEC
Function
RW
RO
8-bit counter data can be read.
Although Timer RE stops counting, the count value is held.
The TRESEC register is set to 00h at the compare match.
Figure 14.72 TRESEC Register in Output Compare Mode
Timer RE Compare Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TREMIN
Address
0119h
After Reset
00h
Function
RW
RW
8-bit compare data is stored.
Figure 14.73 TREMIN Register in Output Compare Mode
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14.Timers
Timer RE Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
0 0
0
Symbol
Address
011Ch
After Reset
00h
TRECR1
Bit Symbol
Bit Name
Function
RW
—
—
(b0)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Timer RE count status flag
TREO pin output enable bit
Interrupt request timing bit
Timer REreset bit
0 : Count stopped
1 : Counting
TCSTF
TOENA
INT
RO
RW
RW
0 : Disable clock output
1 : Enable clock output
Set to 0 in output compare mode.
When setting this bit to 0, after setting it to 1, the
follow ing w ill occur.
• Registers TRESEC, TREMIN, TREHR, TREWK,
and TRECR2 are set to 00h.
• Bits TCSTF, INT, PM, H12_H24, and
TSTART in the TRECR1 register are
set to 0.
• The 8-bit counter is set to 00h and
the 4-bit counter is set to 0h.
TRERST
PM
RW
A.m./p.m. bit
Set to 0 in output compare mode.
RW
RW
H12_H24 Operating mode select bit
Timer REcount start bit
TSTART
0 : Count stops
1 : Count starts
RW
Figure 14.74 TRECR1 Register in Output Compare Mode
Timer RE Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0
Symbol
Address
011Dh
After Reset
00h
TRECR2
Bit Symbol
SEIE
Bit Name
Function
RW
RW
RW
RW
RW
RW
RW
—
Periodic interrupt triggered every
second enable bit
Set to 0 in output compare mode.
Periodic interrupt triggered every
minute enable bit
MNIE
Periodic interrupt triggered every
hour enable bit
HRIE
Periodic interrupt triggered every
day enable bit
DYIE
Periodic interrupt triggered every
w eek enable bit
WKIE
Compare match interrupt enable bit
0 : Disable compare match interrupt
1 : Enable compare match interrupt
COMIE
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Figure 14.75 TRECR2 Register in Output Compare Mode
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14.Timers
Timer RE Count Source Select Register
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
011Eh
After Reset
00001000b
TRECSR
Bit Symbol
Bit Name
Function
RW
RW
b1 b0
Count source select bits
0 0 : f4
0 1 : f8
1 0 : f32
1 1 : fC4(2)
RCS0
RCS1
RW
4-bit counter select bit
0 : Not used
1 : Used
RCS2
RCS3
RW
RW
—
Real-time clock mode select bit
Set to 0 in output compare mode.
—
(b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Clock output select bits(1)
b6 b5
0 0 : f2
RCS5
RCS6
RW
0 1 : f4
1 0 : f8
1 1 : Compare output
RW
—
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTES:
1. Write to bits RCS5 to RCS6 w hen the TOENA bit in the TRECR1 register is set to 0 (disable clock output).
2. For J, K version, fC4 cannot be selected.
Figure 14.76 TRECSR Register in Output Compare Mode
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14.Timers
Count starts
Matched
Matched
Matched
TREMIN register
setting value
00h
Time
Set to 1 by a program
1
0
TSTART bit in
TRECR1 register
2 cycles of maximum count source
1
0
TCSTF bit in
TRECR1 register
Set to 0 by acknowledgement of interrupt request or a program
1
0
IR bit in
TREIC register
1
0
TREO output
Output polarity is inverted
when the compare matches
The above applies under the following conditions.
TOENA bit in TRECR1 register = 1 (enable clock output)
COMIE bit in TRECR2 register = 1 (enable compare match interrupt)
RCS6 to RCS5 bits in TRECSR register = 11b (compare output)
Figure 14.77 Operating Example in Output Compare Mode
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14.Timers
14.4.3 Notes on Timer RE
14.4.3.1 Starting and Stopping Count
Timer RE has the TSTART bit for instructing the count to start or stop, and the TCSTF bit, which indicates
count start or stop. Bits TSTART and TCSTF are in the TRECR1 register.
Timer RE starts counting and the TCSTF bit is set to 1 (count starts) when the TSTART bit is set to 1 (count
starts). It takes up to 2 cycles of the count source until the TCSTF bit is set to 1 after setting the TSTART bit to
(1)
1. During this time, do not access registers associated with timer RE other than the TCSTF bit.
Also, timer RE stops counting when setting the TSTART bit to 0 (count stops) and the TCSTF bit is set to 0
(count stops). It takes the time for up to 2 cycles of the count source until the TCSTF bit is set to 0 after setting
the TSTART bit to 0. During this time, do not access registers associated with timer RE other than the TCSTF
bit.
NOTE:
1. Registers associated with timer RE: TRESEC, TREMIN, TREHR, TREWK, TRECR1, TRECR2, and
TRECSR.
14.4.3.2 Register Setting
Write to the following registers or bits when timer RE is stopped.
• Registers TRESEC, TREMIN, TREHR, TREWK, and TRECR2
• Bits H12_H24, PM, and INT in TRECR1 register
• Bits RCS0 to RCS3 in TRECSR register
Timer RE is stopped when bits TSTART and TCSTF in the TRECR1 register are set to 0 (timer RE stopped).
Also, set all above-mentioned registers and bits (immediately before timer RE count starts) before setting the
TRECR2 register.
Figure 14.78 shows a Setting Example in Real-Time Clock Mode.
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14.Timers
TSTART in TRECR1 = 0
Stop timer RE operation
TCSTF in TRECR1 = 0?
TREIC ← 00h
(disable timer RE interrupt)
TRERST in TRECR1 = 1
TRERST in TRECR1 = 0
Timer RE register
and control circuit reset
Setting of registers TRECSR,
TRESEC, TREMIN, TREHR,
TREWK, and bits H12_H24, PM,
and INT in TRECR1 register
Select clock output
Select clock source
Seconds, minutes, hours, days of week, operating mode
Set a.m./p.m., interrupt timing
Setting of TRECR2
Select interrupt source
Setting of TREIC (IR bit ← 0,
select interrupt priority level)
TSTART in TRECR1 = 1
TCSTF in TRECR1 = 1?
Start timer RE operation
Figure 14.78 Setting Example in Real-Time Clock Mode
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14.Timers
14.4.3.3 Time Reading Procedure of Real-Time Clock Mode
In real-time clock mode, read registers TRESEC, TREMIN, TREHR, and TREWK when time data is updated
and read the PM bit in the TRECR1 register when the BSY bit is set to 0 (not while data is updated).
Also, when reading several registers, an incorrect time will be read if data is updated before another register is
read after reading any register.
In order to prevent this, use the reading procedure shown below.
• Using an interrupt
Read necessary contents of registers TRESEC, TREMIN, TREHR, and TREWK and the PM bit in the
TRECR1 register in the timer RE interrupt routine.
• Monitoring with a program 1
Monitor the IR bit in the TREIC register with a program and read necessary contents of registers TRESEC,
TREMIN, TREHR, and TREWK and the PM bit in the TRECR1 register after the IR bit in the TREIC
register is set to 1 (timer RE interrupt request generated).
• Monitoring with a program 2
(1) Monitor the BSY bit.
(2) Monitor until the BSY bit is set to 0 after the BSY bit is set to 1 (approximately 62.5 ms while the BSY
bit is set to 1).
(3) Read necessary contents of registers TRESEC, TREMIN, TREHR, and TREWK and the PM bit in the
TRECR1 register after the BSY bit is set to 0.
• Using read results if they are the same value twice
(1) Read necessary contents of registers TRESEC, TREMIN, TREHR, and TREWK and the PM bit in the
TRECR1 register.
(2) Read the same register as (1) and compare the contents.
(3) Recognize as the correct value if the contents match. If the contents do not match, repeat until the read
contents match with the previous contents.
Also, when reading several registers, read them as continuously as possible.
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15. Serial Interface
15. Serial Interface
The serial interface consists of two channels (UART0 and UART1). Each UARTi (i = 0 or 1) has an exclusive timer to
generate the transfer clock and operates independently.
Figure 15.1 shows a UARTi (i = 0 or 1) Block Diagram. Figure 15.2 shows a UARTi Transmit/Receive Unit.
UARTi has two modes: clock synchronous serial I/O mode and clock asynchronous serial I/O mode (UART mode).
Figures 15.3 to 15.7 show the registers associated with UARTi.
(UART0)
RXD0
TXD0
UART reception
Receive
clock
1/16
Reception control
circuit
CKDIR = 0
Internal
CLK1 to CLK0 = 00b
Clock
Transmit/
receive
unit
synchronous type
f1
f8
= 01b
= 10b
U0BRG register
1/(n0+1)
UART transmission
Transmit
clock
1/16
1/2
f32
Transmission
control circuit
Clock
synchronous type
External
CKDIR = 1
CKDIR = 0
CKDIR = 1
Clock synchronous type
(when internal clock is selected)
Clock synchronous type
(when external clock is selected)
Clock synchronous type
(when internal clock is selected)
CLK
polarity
switch
circuit
CLK0
TXD1EN
(UART1)
RXD1
TXD1
UART reception
Receive
clock
1/16
Reception control
circuit
CLK1 to CLK0 = 00b
f1
CKDIR = 0
Internal
Clock
Transmit/
receive
unit
synchronous type
= 01b
U1BRG register
1/(n0+1)
f8
Transmit
clock
UART transmission
= 10b
f32
1/16
1/2
Transmission
control circuit
Clock
synchronous type
External
CKDIR = 1
CKDIR=0
CKDIR=1
Clock synchronous type
(when internal clock is selected)
Clock synchronous type
(when external clock is selected)
U1PINSEL
Clock synchronous type
(when internal clock is selected)
U1PINSEL
CLK
polarity
CLK1
switch
circuit
Figure 15.1
UARTi (i = 0 or 1) Block Diagram
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15. Serial Interface
Clock
synchronous
type
PRYE = 0
PAR
disabled
Clock
synchronous
type
UART (7 bits)
UART (8 bits)
1SP
UART (7 bits)
UARTi receive register
SP
PAR
RXDi
SP
PAR
Clock
synchronous
type
UART
2SP
UART (9 bits)
enabled
PRYE = 1
UART (8 bits)
UART (9 bits)
UiRB register
D7 D6 D5 D4 D3 D2 D1 D0
0
0
0
0
0
0
0
D8
MSB/LSB conversion circuit
Data bus high-order bits
Data bus low-order bits
MSB/LSB conversion circuit
UiTB register
D8
D7 D6 D5 D4 D3 D2 D1 D0
UART (8 bits)
UART (9 bits)
Clock
synchronous
type
PRYE = 1
PAR
enabled
UART (9 bits)
UART
2SP
1SP
SP
PAR
TXDi
SP
Clock
synchronous
type
PAR
UART (7 bits)
UART (8 bits)
UARTi transmit register
i = 0 or 1
SP: Stop bit
PAR: Parity bit
UART (7 bits)
disabled
PRYE = 0
Clock
synchronous
type
0
Figure 15.2
UARTi Transmit/Receive Unit
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15. Serial Interface
UARTi Transmit Buffer Register (i = 0 or 1)(1, 2)
(b15)
b7
(b8)
b0
b7
b0
Symbol
U0TB
Address
After Reset
00A3h-00A2h
00ABh-00AAh
Undefined
Undefined
U1TB
Function
RW
WO
—
Transmit data
(b8-b0)
—
(b15-b9)
Nothing is assigned. If necessary, set to 0.
When read, the content is undefined.
—
NOTES:
1. When the transfer data length is 9 bits, w rite data to high byte first, then low byte.
2. Use the MOV instruction to w rite to this register.
UARTi Receive Buffer Register (i = 0 or 1)(1)
(b15)
(b8)
b7
b0
b7
b0
Symbol
U0RB
U1RB
Address
00A7h-00A6h
00AFh-00AEh
After Reset
Undefined
Undefined
Function
Bit Symbol
—
(b7-b0)
Bit Name
RW
RO
Receive data (D7 to D0)
Receive data (D8)
—
—
—
(b8)
RO
—
—
(b11-b9)
Nothing is assigned. If necessary, set to 0.
When read, the content is undefined.
Overrun error flag(2)
Framing error flag(2)
Parity error flag(2)
Error sumflag(2)
0 : No overrun error
1 : Overrun error
OER
FER
PER
SUM
RO
RO
RO
RO
0 : No framing error
1 : Framing error
0 : No parity error
1 : Parity error
0 : No error
1 : Error
NOTES:
1. Read out the UiRB register in 16-bit units.
2. Bits SUM, PER, FER, and OER are set to 0 (no error) w hen bits SMD2 to SMD0 in the UiMR register are set to 000b
(serial interface disabled) or the REbit in the UiC1 register is set to 0 (receive disabled). The SUM bit is set to 0 (no
error) w hen bits PER, FER, and OER are set to 0 (no error). Bits PER and FER are set to 0 even w hen the higher byte
of the UiRB register is read out.
Also, bits PER and FER are set to 0 w hen reading the high-order byte of the UiRB register.
Figure 15.3
Registers U0TB to U1TB and U0RB to U1RB
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15. Serial Interface
UARTi Bit Rate Register (i = 0 or 1)(1, 2, 3)
b7
b0
Symbol
U0BRG
U1BRG
Address
00A1h
00A9h
After Reset
Undefined
Undefined
Function
Assuming the set value is n, UiBRG divides the count source by n+1
Setting Range
00h to FFh
RW
WO
NOTES:
1. Write to this register w hile the serial I/O is neither transmitting nor receiving.
2. Use the MOV instruction to w rite to this register.
3. After setting the CLK0 to CLK1 bits of the UiC0 register, w rite to the UiBRG register.
UARTi Transmit/Receive Mode Register (i = 0 or 1)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
U0MR
Address
00A0h
After Reset
00h
00h
U1MR
00A8h
Bit Symbol
Bit Name
Function
RW
RW
Serial I/O mode select bits
b2 b1 b0
SMD0
SMD1
SMD2
0 0 0 : Serial interface disabled
0 0 1 : Clock synchronous serial I/O mode
1 0 0 : UART mode transfer data 7 bits long
1 0 1 : UART mode transfer data 8 bits long
1 1 0 : UART mode transfer data 9 bits long
Other than above : Do not set
RW
RW
Internal/external clock select bit 0 : Internal clock
1 : External clock(1)
CKDIR
STPS
RW
RW
Stop bit length select bit
0 : 1 stop bit
1 : 2 stop bits
Odd/even parity select bit
Enable w hen PRYE= 1
0 : Odd parity
PRY
RW
1 : Even parity
Parity enable bit
Reserved bit
0 : Parity disabled
1 : Parity enabled
PRY E
RW
RW
—
(b7)
Set to 0.
NOTE:
1. When the CLK0 pin is used, set the PD1_6 bit in the PD1 register to 0 (input). When the CLK1 pin is used, set the
PD0_5 bit in the PD0 register to 0 (input).
Figure 15.4
Registers U0BRG to U1BRG and U0MR to U1MR
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15. Serial Interface
UARTi Transmit/Receive Control Register 0 (i = 0 or 1)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
U0C0
Address
00A4h
After Reset
00001000b
00001000b
Function
00ACh
U1C0
Bit Symbol
Bit Name
RW
RW
BRG count source select
bits(1)
b1 b0
0 0 : Selects f1
CLK0
CLK1
0 1 : Selects f8
1 0 : Selects f32
1 1 : Do not set.
RW
RW
—
(b2)
Reserved bit
Set to 0.
Transmit register empty
flag
0 : Data in transmit register (during transmit)
1 : No data in transmit register (transmit completed)
TXEPT
RO
—
(b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
Data output select bit
0 : TXDi pin is for CMOS output
1 : TXDi pin is for N-channel open drain output
NCH
RW
CLK polarity select bit
0 : Transmit data is output at falling edge of transfer
clock and receive data is input at rising edge
1 : Transmit data is output at rising edge of transfer
clock and receive data is input at falling edge
CKPOL
RW
RW
Transfer format select bit 0 : LSB first
1 : MSB first
UFORM
NOTE:
1. If the BRG count source is sw itched, set the UiBRG register again.
Figure 15.5
Registers U0C0 to U1C0
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15. Serial Interface
UARTi Transmit/Receive Control Register 1 (i = 0 or 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
U0C1
Address
00A5h
After Reset
00000010b
00000010b
Function
U1C1
00ADh
Bit Symbol
Bit Name
RW
RW
Transmit enable bit(1)
0 : Disables transmission
1 : Enables transmission
TE
TI
Transmit buffer empty flag
Receive enable bit
0 : Data in UiTB register
1 : No data in UiTB register
RO
RW
RO
0 : Disables reception
1 : Enables reception
RE
Receive complete flag(1)
0 : No data in UiRB register
1 : Data in UiRB register
RI
UARTi transmit interrupt cause
select bit
0 : Transmission buffer empty (TI=1)
1 : Transmission completed (TXEPT=1)
UiIRS
UiRRM
RW
RW
—
UARTi continuous receive mode
enable bit(2)
0 : Disables continuous receive mode
1 : Enables continuous receive mode
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTES:
1. The RI bit is set to 0 w hen the higher byte of the UiRB register is read out.
2. Set the UiRRM bit to 0 (disables continuous receive mode) in UART mode.
Figure 15.6
Registers U0C1 to U1C1
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Pin Select Register 1
15. Serial Interface
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0 1
Symbol
Address
00F5h
After Reset
00h
PINSR1
Bit Symbol
Bit Name
TXD1/RXD1 pin select bit(1)
Function
RW
RW
b1 b0
0 0 : P3_7(TXD1/RXD1)
0 1 : P3_7(TXD1), P4_5(RXD1)
1 0 : P3_6(TXD1/RXD1)
1 1 : Do not set.
UART1SEL0
UART1SEL1
RW
—
(b2)
Reserved bit
Reserved bits
Set to 1. When read, the content is 0.
Set to 0. When read, the content is 0.
RW
RW
—
(b7-b3)
NOTE:
1. The UART1 pins can be selected by using bits U1PINSEL, TXD1SEL and TXD1EN in the PMR register.
Port Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
PMR
Address
00F8h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
____
0 : P1_5, P1_7
1 : P3_6
INT1 pin select bit
INT1SEL
—
(b2-b1)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
SSI pin select bit
0 : P3_3
1 : P1_6
SSISEL
U1PINSEL
TXD1SEL
TXD1EN
IICSEL
RW
RW
RW
RW
RW
TXD1 pin sw itch bit(1)
Port/TXD1 pin sw itch bit(1)
TXD1/RXD1 select bit(1)
SSU / I2C bus pin sw itch bit
0 : P0_0
1 : P3_6, P3_7
0 : Programmable I/O port
1 : TXD1
0 : RXD1
1 : TXD1
0 : Selects SSU function
1 : Selects I2C bus function
NOTE:
1. The UART1 pins can be selected by using bits U1PINSEL, TXD1SEL and TXD1EN, and bits UART1SEL1 and
UART1SEL0 in the PINSR1 register.
Pin Function
PINSR1 Register
UART1SEL1,
PMR Register
U1PINSEL bit TXD1SEL bit
TXD1EN bit
UART1SEL0 bit
P3_7(TXD1)
P3_7(RXD1)
P0_0(TXD1)
P3_7(TXD1)
P4_5(RXD1)
P3_6(TXD1)
P3_6(RXD1)
P0_0(TXD1)
1
0
×
×
0
1
×
00b
01b
1
1
×
×
1
0
×
×
0
×
1
10b
×: 0 or 1
Figure 15.7
Registers PINSR1 and PMR
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15. Serial Interface
15.1 Clock Synchronous Serial I/O Mode
In the clock synchronous serial I/O mode, data is transmitted and received using a transfer clock.
Table 15.1 lists the Specifications of Clock Synchronous Serial I/O Mode. Table 15.2 lists the Registers Used and
Settings in Clock Synchronous Serial I/O Mode.
Table 15.1
Specifications of Clock Synchronous Serial I/O Mode
Item Specification
Transfer data format
Transfer clocks
• Transfer data length: 8 bits
• CKDIR bit in UiMR register is set to 0 (internal clock): fi/(2(n+1))
fi = f1, f8, f32 n = value set in U0BRG register: 00h to FFh
• The CKDIR bit is set to 1 (external clock): input from CLKi pin
(1)
Transmit start conditions
Receive start conditions
• Before transmit starts, the following requirements must be met
- The TE bit in the UiC1 register is set to 1 (transmission enabled)
- The TI bit in the UiC1 register is set to 0 (data in the UiTB register)
(1)
• Before receive starts, the following requirements must be met
- The RE bit in the UiC1 register is set to 1 (reception enabled)
- The TE bit in the UiC1 register is set to 1 (transmission enabled)
- The TI bit in the UiC1 register is set to 0 (data in the UiTB register)
• When transmitting, one of the following conditions can be selected
- The UiIRS bit is set to 0 (transmit buffer empty):
When transferring data from the UiTB register to UARTi transmit register
(when transmission starts).
Interrupt request
generation timing
- The UiIRS bit is set to 1 (transmission completes):
When completing data transmission from UARTi transmit register.
• When receiving
When data transfer from the UARTi receive register to the UiRB register
(when reception completes).
(2)
Error detection
Select functions
• Overrun error
This error occurs if the serial interface starts receiving the next data item
before reading the UiRB register and receives the 7th bit of the next data.
• CLK polarity selection
Transfer data input/output can be selected to occur synchronously with
the rising or the falling edge of the transfer clock.
• LSB first, MSB first selection
Whether transmitting or receiving data begins with bit 0 or begins with bit 7
can be selected.
• Continuous receive mode selection
Receive is enabled immediately by reading the UiRB register.
i = 0 or 1
NOTES:
1. If an external clock is selected, ensure that the external clock is “H” when the CKPOL bit in the
U0C0 register is set to 0 (transmit data output at falling edge and receive data input at rising edge of
transfer clock), and that the external clock is “L” when the CKPOL bit is set to 1 (transmit data output
at rising edge and receive data input at falling edge of transfer clock).
2. If an overrun error occurs, the receive data (b0 to b8) of the UiRB register will be undefined. The IR
bit in the SiRIC register remains unchanged.
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15. Serial Interface
(1)
Table 15.2
Registers Used and Settings in Clock Synchronous Serial I/O Mode
Register
UiTB
Bit Function
0 to 7
0 to 7
OER
Set data transmission
UiRB
Data reception can be read
Overrun error flag
UiBRG
UiMR
0 to 7
Set bit rate
Set to 001b
SMD2 to SMD0
CKDIR
CLK1 to CLK0
TXEPT
NCH
Select the internal clock or external clock
Select the count source in the UiBRG register
Transmit register empty flag
UiC0
Select TXDi pin output mode
Select the transfer clock polarity
Select the LSB first or MSB first
Set this bit to 1 to enable transmission/reception
Transmit buffer empty flag
CKPOL
UFORM
TE
UiC1
TI
RE
Set this bit to 1 to enable reception
Reception complete flag
RI
UiIRS
Select the UARTi transmit interrupt source
Set this bit to 1 to use continuous receive mode
UiRRM
i = 0 or 1
NOTE:
1. Set bits which are not in this table to 0 when writing to the above registers in clock synchronous
serial I/O mode.
Table 15.3 lists the I/O Pin Functions in Clock Synchronous Serial I/O Mode. The TXDi (i = 0 or 1) pin outputs
“H” level between the operating mode selection of UARTi and transfer start. (If the NCH bit is set to 1 (N-channel
open-drain output), this pin is in a high-impedance state.)
Table 15.3
I/O Pin Functions in Clock Synchronous Serial I/O Mode
Pin Name
Function
Output serial data
Input serial data
Selection Method
TXD0 (P1_4)
RXD0 (P1_5)
(Outputs dummy data when performing reception only)
PD1_5 bit in PD1 register = 0
(P1_5 can be used as an input port when performing
transmission only)
CLK0 (P1_6)
Output transfer clock CKDIR bit in U0MR register = 0
Input transfer clock
CKDIR bit in U0MR register = 1
PD1_6 bit in PD1 register = 0
TXD1 (either P0_0,
P3_6, or P3_7)
Output serial data
Set registers PINSR1 and PMR (refer to Figure 15.7
Registers PINSR1 and PMR)
(Outputs dummy data when performing reception only)
Set registers PINSR1 and PMR (refer to Figure 15.7
Registers PINSR1 and PMR)
RXD1 (either P3_6,
P3_7, or P4_5)
Input serial data
Corresponding bit in each port direction register = 0
(Can be used as an input port when performing
transmission only)
CLK1 (P0_5)
Output transfer clock CKDIR bit in U1MR register = 0
Input transfer clock
PD0_5 bit in PD0 register = 0
CKDIR bit in U1MR register = 1
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15. Serial Interface
• Example of transmit timing (when internal clock is selected)
TC
Transfer clock
1
0
TE bit in UiC1
register
Set data in UiTB register
TI bit in UiC1
register
1
0
Transfer from UiTB register to UARTi transmit register
TCLK
Stop pulsing because the TE bit is set to 0
CLKi
TXDi
D0 D1 D2 D3 D4 D5 D6 D7 D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
TXEPT bit in
UiC0 register
1
0
IR bit in SiTIC
register
1
0
Set to 0 when interrupt request is acknowledged, or set by a program
TC = TCLK = 2(n+1)/fi
fi: Frequency of UiBRG count source (f1, f8, f32)
n: Setting value to UiBRG register
The above applies under the following settings:
• CKDIR bit in UiMR register = 0 (internal clock)
• CKPOL bit in UiC0 register = 0 (output transmit data at the falling edge and input receive data at the rising edge of the transfer clock)
• UiIRS bit in UiC1 register = 0 (an interrupt request is generated when the transmit buffer is empty)
• Example of receive timing (when external clock is selected)
RE bit in UiC1
register
1
0
TE bit in UiC1
register
1
0
Write dummy data to UiTB register
TI bit in UiC1
register
1
0
Transfer from UiTB register to UARTi transmit register
1/fEXT
CLKi
RXDi
Receive data is taken in
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5
Read out from UiRB register
Transfer from UARTi receive register to
UiRB register
RI bit in UiC1
register
1
0
1
0
IR bit in SiRIC
register
Set to 0 when interrupt request is acknowledged, or set by a program
The above applies under the following settings:
• CKDIR bit in UiMR register = 1 (external clock)
• CKPOL bit in UiC0 register = 0 (output transmit data at the falling edge and input receive data at the rising edge of the transfer clock)
The following conditions are met when “H” is applied to the CLKi pin before receiving data:
• TE bit in UiC1 register = 1 (enables transmit)
• RE bit in UiC1 register = 1 (enables receive)
• Write dummy data to the UiTB register
fEXT: Frequency of external clock
i = 0 or 1
Figure 15.8
Transmit and Receive Timing Example in Clock Synchronous Serial I/O Mode
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15. Serial Interface
15.1.1 Polarity Select Function
Figure 15.9 shows the Transfer Clock Polarity. Use the CKPOL bit in the UiC0 (i = 0 or 1) register to select the
transfer clock polarity.
• When the CKPOL bit in the UiC0 register = 0 (output transmit data at the falling
edge and input receive data at the rising edge of the transfer clock)
CLKi(1)
TXDi
RXDi
D0
D0
D1
D1
D2
D2
D3
D3
D4
D4
D5
D5
D6
D6
D7
D7
• When the CKPOL bit in the UiC0 register = 1 (output transmit data at the rising
edge and input receive data at the falling edge of the transfer clock)
CLKi(2)
TXDi
D0
D0
D1
D1
D2
D2
D3
D3
D4
D4
D5
D5
D6
D6
D7
D7
RXDi
NOTES:
1. When not transferring, the CLKi pin level is “H”.
2. When not transferring, the CLKi pin level is “L”.
i = 0 or 1
Figure 15.9
Transfer Clock Polarity
15.1.2 LSB First/MSB First Select Function
Figure 15.10 shows the Transfer Format. Use the UFORM bit in the UiC0 (i = 0 or 1) register to select the
transfer format.
• When UFORM bit in UiC0 register = 0 (LSB first)(1)
CLKi
TXDi
RXDi
D0
D0
D1
D1
D2
D2
D3
D3
D4
D4
D5
D5
D6
D6
D7
D7
• When UFORM bit in UiC0 register = 1 (MSB first)(1)
CLKi
TXDi
D7
D7
D6
D6
D5
D5
D4
D4
D3
D3
D2
D2
D1
D1
D0
D0
RXDi
NOTE:
1. The above applies when the CKPOL bit in the UiC0 register is
set to 0 (output transmit data at the falling edge and input receive
data at the rising edge of the transfer clock).
i = 0 or 1
Figure 15.10 Transfer Format
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15. Serial Interface
15.1.3 Continuous Receive Mode
Continuous receive mode is selected by setting the UiRRM (i = 0 or 1) bit in the UiC1 register to 1 (enables
continuous receive mode). In this mode, reading the UiRB register sets the TI bit in the UiC1 register to 0 (data
in the UiTB register). When the UiRRM bit is set to 1, do not write dummy data to the UiTB register by a
program.
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15. Serial Interface
15.2 Clock Asynchronous Serial I/O (UART) Mode
The UART mode allows data transmission and reception after setting the desired bit rate and transfer data format.
Table 15.4 lists the Specifications of UART Mode. Table 15.5 lists the Registers Used and Settings for UART
Mode.
Table 15.4
Specifications of UART Mode
Item
Specification
• Character bit (transfer data): Selectable among 7, 8 or 9 bits
• Start bit: 1 bit
Transfer data formats
• Parity bit: Selectable among odd, even, or none
• Stop bit: Selectable among 1 or 2 bits
Transfer clocks
• CKDIR bit in UiMR register is set to 0 (internal clock): fj/(16(n+1))
fj = f1, f8, f32 n = value set in UiBRG register: 00h to FFh
• CKDIR bit is set to 1 (external clock): fEXT/(16(n+1))
fEXT: Input from CLKi pin, n = value set in UiBRG register: 00h to FFh
• Before transmission starts, the following are required
- TE bit in UiC1 register is set to 1 (transmission enabled)
- TI bit in UiC1 register is set to 0 (data in UiTB register)
• Before reception starts, the following are required
- RE bit in UiC1 register is set to 1 (reception enabled)
- Start bit detected
Transmit start conditions
Receive start conditions
Interrupt request
generation timing
• When transmitting, one of the following conditions can be selected
- UiIRS bit is set to 0 (transmit buffer empty):
When transferring data from the UiTB register to UARTi transmit register
(when transmit starts).
- UiIRS bit is set to 1 (transfer ends):
When serial interfac.e completes transmitting data from the UARTi
transmit register
• When receiving
When transferring data from the UARTi receive register to UiRB register
(when receive ends).
(1)
Error detection
• Overrun error
This error occurs if the serial interface starts receiving the next data item
before reading the UiRB register and receive the bit preceding the final
stop bit of the next data item.
• Framing error
This error occurs when the set number of stop bits is not detected.
• Parity error
This error occurs when parity is enabled, and the number of 1’s in parity
and character bits do not match the number of 1’s set.
• Error sum flag
This flag is set is set to 1 when an overrun, framing, or parity error is
generated.
i = 0 or 1
NOTE:
1. If an overrun error occurs, the receive data (b0 to b8) of the UiRB register will be undefined. The IR
bit in the SiRIC register remains unchanged.
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15. Serial Interface
Table 15.5
Registers Used and Settings for UART Mode
Bit
Register
UiTB
Function
Set transmit data(1)
Receive data can be read(1, 2)
Error flag
0 to 8
0 to 8
UiRB
OER, FER, PER, SUM
0 to 7
UiBRG
UiMR
Set a bit rate
SMD2 to SMD0
Set to 100b when transfer data is 7 bits long.
Set to 101b when transfer data is 8 bits long.
Set to 110b when transfer data is 9 bits long.
CKDIR
Select the internal clock or external clock
Select the stop bit
STPS
PRY, PRYE
CLK0, CLK1
TXEPT
Select whether parity is included and whether odd or even
Select the count source for the UiBRG register
Transmit register empty flag
UiC0
UiC1
NCH
Select TXDi pin output mode
CKPOL
UFORM
Set to 0
LSB first or MSB first can be selected when transfer data is 8 bits long.
Set to 0 when transfer data is 7 or 9 bits long.
TE
Set to 1 to enable transmit
Transmit buffer empty flag
Set to 1 to enable receive
Receive complete flag
TI
RE
RI
UiIRS
UiRRM
Select the factor of UARTi transmit interrupt
Set to 0
i = 0 or 1
NOTES:
1. The bits used for transmit/receive data are as follows: Bits 0 to 6 when transfer data is 7 bits long; bits 0 to 7
when transfer data is 8 bits long; bits 0 to 8 when transfer data is 9 bits long.
2. The following bits are undefined: Bits 7 and 8 when transfer data is 7 bits long; bit 8 when transfer data is 8 bits
long.
Table 15.6 lists the I/O Pin Functions in UART Mode. After the UARTi (i = 0 or 1) operating mode is selected, the
TXDi pin outputs “H” level (If the NCH bit is set to 1 (N-channel open-drain output), this pin is in a high-
impedance state) until transfer starts.
Table 15.6
I/O Pin Functions in UART Mode
Pin name
Function
Selection Method
TXD0 (P1_4) Output serial data
RXD0 (P1_5) Input serial data
(Cannot be used as a port when performing reception only)
PD1_5 bit in PD1 register = 0
(P1_5 can be used as an input port when performing transmission only)
CLK0 (P1_6) Programmable I/O Port CKDIR bit in U0MR register = 0
Input transfer clock
CKDIR bit in U0MR register = 1
PD1_6 bit in PD1 register = 0
TXD1 (either Output serial data
P0_0, P3_6,
Set registers PINSR1 and PMR (refer to Figure 15.7 Registers PINSR1
and PMR)
or P3_7)
(Cannot be used as a port when performing reception only)
RXD1 (either Input serial data
P3_6, P3_7,
Set registers PINSR1 and PMR (refer to Figure 15.7 Registers PINSR1
and PMR)
or P4_5)
Corresponding bit in each port direction register = 0
(Can be used as an input port when performing transmission only)
CLK1 (P0_5) Programmable I/O Port CKDIR bit in U1MR register = 0
Input transfer clock
PD0_5 bit in PD0 register = 0
CKDIR bit in U1MR register = 1
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15. Serial Interface
• Transmit timing when transfer data is 8 bits long (parity enabled, 1 stop bit)
TC
Transfer clock
TE bit in UiC1
register
1
0
Write data to UiTB register
TI bit in UiC1
register
1
0
Transfer from UiTB register to UARTi transmit register
Stop pulsing because the TE bit is set to 0
Start
bit
Parity Stop
bit
bit
TXDi
ST D0 D1 D2 D3 D4 D5 D6 D7
P
ST D0 D1 D2 D3 D4 D5 D6 D7
P
SP
ST D0 D1
SP
1
0
TXEPT bit in
UiC0 register
IR bit SiTIC
register
1
0
Set to 0 when interrupt request is acknowledged, or set by a program
TC=16 (n + 1) / fj or 16 (n + 1) / fEXT
The above timing diagram applies under the following conditions:
• PRYE bit in UiMR register = 1 (parity enabled)
• STPS bit in UiMR register = 0 (1 stop bit)
fj: Frequency of UiBRG count source (f1, f8, f32)
fEXT: Frequency of UiBRG count source (external clock)
n: Setting value to UiBRG register
i = 0 or 1
• UiIRS bit in UiC1 register = 1 (an interrupt request is generated when transmit completes)
• Transmit timing when transfer data is 9 bits long (parity disabled, 2 stop bits)
TC
Transfer clock
TE bit in UiC1
register
1
0
Write data to UiTB register
1
0
TI bit in UiC1
register
Transfer from UiTB register to UARTi transmit register
Stop Stop
bit bit
Start
bit
TXDi
ST D0 D1 D2 D3 D4 D5 D6 D7 D8
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP SP
ST D0 D1
SP SP
TXEPT bit in
UiC0 register
1
0
IR bit in SiTIC
register
1
0
Set to 0 when interrupt request is acknowledged, or set by a program
The above timing diagram applies under the following conditions:
• PRYE bit in UiMR register = 0 (parity disabled)
• STPS bit in UiMR register = 1 (2 stop bits)
TC=16 (n + 1) / fj or 16 (n + 1) / fEXT
fj: Frequency of UiBRG count source (f1, f8, f32)
fEXT: Frequency of UiBRG count source (external clock)
n: Setting value to UiBRG register
i = 0 or 1
• UiIRS bit in UiC1 register = 0 (an interrupt request is generated when transmit buffer is empty)
Figure 15.11 Transmit Timing in UART Mode
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15. Serial Interface
• Example of receive timing when transfer data is 8 bits long (parity disabled, one stop bit)
UiBRG output
1
0
UiC1 register
RE bit
Stop bit
Start bit
RXDi
D0
D1
D7
Determined to be “L”
Receive data taken in
Transfer clock
Reception triggered when transfer clock
is generated by falling edge of start bit
Transferred from UARTi receive
register to UiRB register
UiC1 register
RI bit
1
0
SiRIC register
IR bit
1
0
Set to 0 when interrupt request is accepted, or set by a program
The above timing diagram applies when the register bits are set as follows:
• PRYE bit in UiMR register = 0 (parity disabled)
• STPS bit in UiMR register = 0 (1 stop bit)
i = 0 or 1
Figure 15.12 Receive Timing Example in UART Mode
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15. Serial Interface
15.2.1 Bit Rate
In UART mode, the bit rate is the frequency divided by the UiBRG (i = 0 or 1) register.
UART mode
• Internal clock selected
UiBRG register setting value =
fj
- 1
Bit Rate × 16
Fj: Count source frequency of the UiBRG register (f1, f8, or f32)
• External clock selected
UiBRG register setting value =
fEXT
Bit Rate × 16
- 1
fEXT: Count source frequency of the UiBRG register (external clock)
i = 0 or 1
Figure 15.13 Calculation Formula of UiBRG (i = 0 or 1) Register Setting Value
Table 15.7
Bit Rate Setting Example in UART Mode (Internal Clock Selected)
System Clock = 20 MHz System Clock = 8 MHz
Setting UiBRG Actual Setting
System Clock = 18.432 MHz(1)
UiBRG
BitRate
(bps)
UiBRG
Setting UiBRG
Count
ActualTime
(bps)
ActualTime
(bps)
Setting
Value
Error
(%)
Setting
Value
Error
(%)
Setting
Value
Time
(bps)
Error
(%)
Source
1200
2400
f8
f8
f8
f1
f1
f1
f1
f1
f1
f1
129 (81h)
1201.92
2403.85
0.16 119 (77h)
0.16 59 (3Bh)
1200.00
2400.00
0.00 51 (33h) 1201.92
0.00 25 (19h) 2403.85
0.00 12 (0Ch) 4807.69
0.00 51 (33h) 9615.38
0.16
0.16
0.16
0.16
64 (40h)
4800
32 (20h)
4734.85 -1.36 29 (1Dh)
9615.38 0.16 119 (77h)
14367.82 -0.22 79 (4Fh)
4800.00
9600
129 (81h)
9600.00
14400
19200
28800
38400
57600
115200
86 (56h)
14400.00
19200.00
28800.00
38400.00
57600.00
0.00 34 (22h) 14285.71 -0.79
64 (40h)
19230.77
29069.77
0.16 59 (3Bh)
0.94 39 (27h)
0.00 25 (19h) 19230.77
0.00 16 (10h) 29411.76
0.00 12 (0Ch) 38461.54
0.16
2.12
0.16
42 (2Ah)
32 (20h)
37878.79 -1.36 29 (1Dh)
56818.18 -1.36 19 (13h)
21 (15h)
0.00
0.00
8 (08h) 55555.56 -3.55
10 (0Ah) 113636.36 -1.36
9 (09h) 115200.00
−
−
−
i = 0 or 1
NOTE:
1. For the high-speed on-chip oscillator, the correction value in the FRA7 register should be written into the FRA1
register (for N, D version only).
This applies when the high-speed on-chip oscillator is selected as the system clock and bits FRA22 to FRA20 in
the FRA2 register are set to 000b (divide-by-2 mode). For the precision of the high-speed on-chip oscillator,
refer to 20. Electrical Characteristics.
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15. Serial Interface
15.3 Notes on Serial Interface
• When reading data from the UiRB (i = 0 or 1) register either in the clock synchronous serial I/O mode or in the
clock asynchronous serial I/O mode. Ensure the data is read in 16-bit units. When the high-order byte of the
UiRB register is read, bits PER and FER in the UiRB register and the RI bit in the UiC1 register are set to 0.
To check receive errors, read the UiRB register and then use the read data.
Example (when reading receive buffer register):
MOV.W
00A6H,R0
; Read the U0RB register
• When writing data to the UiTB register in the clock asynchronous serial I/O mode with 9-bit transfer data
length, write data to the high-order byte first then the low-order byte, in 8-bit units.
Example (when reading transmit buffer register):
MOV.B
MOV.B
#XXH,00A3H ; Write the high-order byte of U0TB register
#XXH,00A2H ; Write the low-order byte of U0TB register
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16. Clock Synchronous Serial Interface
16. Clock Synchronous Serial Interface
The clock synchronous serial interface is configured as follows.
Clock synchronous serial interface
Clock synchronous serial I/O with chip select (SSU)
Clock synchronous communication mode
4-wire bus communication mode
2
2
I C bus Interface
I C bus interface mode
Clock synchronous serial mode
The clock synchronous serial interface uses the registers at addresses 00B8h to 00BFh. Registers, bits, symbols, and
functions vary even for the same addresses depending on the mode. Refer to the register diagrams of each function for
details.
Also, the differences between clock synchronous communication mode and clock synchronous serial mode are the
options of the transfer clock, clock output format, and data output format.
16.1 Mode Selection
The clock synchronous serial interface has four modes.
Table 16.1lists the Mode Selections. Refer to 16.2 Clock Synchronous Serial I/O with Chip Select (SSU) and the
sections that follow for details of each mode.
Table 16.1
Mode Selections
Bit 0 in 00BDh
(SSUMS Bit in
SSMR2 Register, FS
Bit in SAR Register)
IICSEL Bit
in PMR
Register
Bit 7 in 00B8h
(ICE Bit in ICCR1
Function
Mode
Register)
0
0
0
Clock synchronous
serial I/O with chip
select
Clock synchronous communication
mode
0
1
1
0
1
1
1
0
1
4-wire bus communication mode
I2C bus interface mode
I2C bus interface
Clock synchronous serial mode
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16. Clock Synchronous Serial Interface
16.2 Clock Synchronous Serial I/O with Chip Select (SSU)
Clock synchronous serial I/O with chip select supports clock synchronous serial data communication.
Table 16.2 lists the Specifications of Clock Synchronous Serial I/O with Chip Select and Figure 16.1 shows a
Block Diagram of Clock Synchronous Serial I/O with Chip Select. Figures 16.2 to 16.9 show the registers
associated with clock synchronous serial I/O with chip select.
Table 16.2
Item
Specifications of Clock Synchronous Serial I/O with Chip Select
Specification
Transfer data format
• Transfer data length: 8 bits
Continuous transmission and reception of serial data are supported since both
transmitter and receiver have buffer structures.
Operating modes
• Clock synchronous communication mode
• 4-wire bus communication mode (including bidirectional communication)
Selectable
Master/slave device
I/O pins
SSCK (I/O): Clock I/O pin
SSI (I/O): Data I/O pin
SSO (I/O): Data I/O pin
SCS (I/O): Chip-select I/O pin
Transfer clocks
• When the MSS bit in the SSCRH register is set to 0 (operates as slave device),
external clock is selected (input from SSCK pin).
• When the MSS bit in the SSCRH register is set to 1 (operates as master
device), internal clock (selectable among f1/256, f1/128, f1/64, f1/32, f1/16, f1/8
and f1/4, output from SSCK pin) is selected.
• Clock polarity and phase of SSCK can be selected.
• Overrun error
Overrun error occurs during reception and completes in error. While the RDRF
bit in the SSSR register is set to 1 (data in the SSRDR register) and when next
serial data receive is completed, the ORER bit is set to 1.
• Conflict error
When the SSUMS bit in the SSMR2 register is set to 1 (4-wire bus
communication mode) and the MSS bit in the SSCRH register is set to 1
(operates as master device) and when starting a serial communication, the CE
bit in the SSSR register is set to 1 if “L” applies to the SCS pin input. When the
SSUMS bit in the SSMR2 register is set to 1 (4-wire bus communication
mode), the MSS bit in the SSCRH register is set to 0 (operates as slave
device) and the SCS pin input changes state from “L” to “H”, the CE bit in the
SSSR register is set to 1.
Receive error
detection
Multimaster error
detection
Interrupt requests
Select functions
5 interrupt requests (transmit-end, transmit-data-empty, receive-data-full,
(1)
overrun error, and conflict error).
• Data transfer direction
Selects MSB-first or LSB-first
• SSCK clock polarity
Selects “L” or “H” level when clock stops
• SSCK clock phase
Selects edge of data change and data download
• SSI pin select function
The SSISEL bit in the PMR register can select P3_3 or P1_6 as SSI pin.
NOTE:
1. Clock synchronous serial I/O with chip select has only one interrupt vector table.
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16. Clock Synchronous Serial Interface
f1
Internal clock (f1/i)
Multiplexer
Internal clock
generation
circuit
SSCK
SSMR register
SSCRL register
SSCRH register
SSER register
SSSR register
SSMR2 register
SSTDR register
Transmit/receive
control circuit
SCS
SSO
SSI
SSTRSR register
SSRDR register
Selector
Interrupt requests
(TXI, TEI, RXI, OEI, and CEI)
i = 4, 8, 16, 32, 64, 128, or 256
Figure 16.1
Block Diagram of Clock Synchronous Serial I/O with Chip Select
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16. Clock Synchronous Serial Interface
SS Control Register H
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00B8h
After Reset
00h
SSCRH
Bit Symbol
Bit Name
Transfer clock rate select bits(1)
Function
RW
RW
b2 b1 b0
0 0 0 : f1/256
0 0 1 : f1/128
0 1 0 : f1/64
0 1 1 : f1/32
1 0 0 : f1/16
1 0 1 : f1/8
1 1 0 : f1/4
CKS0
CKS1
CKS2
RW
RW
1 1 1 : Do not set.
—
(b4-b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
Master/slave device select bit(2)
0 : Operates as slave device
1 : Operates as master device
MSS
RW
Receive single stop bit(3)
0 : Maintains receive operation after
receiving 1 byte of data
RSSTP
RW
—
1 : Completes receive operation after
receiving 1 byte of data
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTES:
1. The set clock is used w hen the internal clock is selected.
2. The SSCK pin functions as the transfer clock output pin w hen the MSS bit is set to 1 (operates as master device).
The MSS bit is set to 0 (operates as slave device) w hen the CEbit in the SSSR register is set to 1 (conflict error
occurs).
3. The RSSTPbit is disabled w hen the MSS bit is set to 0 (operates as slave device).
Figure 16.2
SSCRH Register
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16. Clock Synchronous Serial Interface
SS Control Register L
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00B9h
After Reset
01111101b
SSCRL
Bit Symbol
Bit Name
Function
RW
—
—
(b0)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
Clock synchronous
serial I/O w ith chip
select control part
reset bit
When this bit is set to 1, the clock synchronous serial
I/O w ith chip select control block and SSTRSR register
are reset.
SRES
RW
The values of the registers(1) in the clock synchronous
serial I/O w ith chip select register are maintained.
—
(b3-b2)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
—
SOL w rite protect bit(2) The output level can be changed by the SOL bit w hen
this bit is set to 0.
SOLP
RW
The SOLPbit remains unchanged even if 1 is w ritten to
it. When read, the content is 1.
Serial data output value When read
setting bit
0 : The serial data output is set to “L”
1 : The serial data output is set to “H”
When w ritten(2, 3)
SOL
RW
0 : The data output is “L” after the serial data output
1 : The data output is “H” after the serial data output
—
(b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
—
—
—
(b7)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTES:
1. Registers SSCRH, SSCRL, SSMR, SSER, SSSR, SSMR2, SSTDR, and SSRDR.
2. The data output after serial data is output can be changed by w riting to the SOL bit before or after transfer. When
w riting to the SOL bit, set the SOLPbit to 0 and the SOL bit to 0 or 1 simultaneously by the MOV instruction.
3. Do not w rite to the SOL bit during data transfer.
Figure 16.3
SSCRL Register
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SS Mode Register
16. Clock Synchronous Serial Interface
b7 b6 b5 b4 b3 b2 b1 b0
1
Symbol
Address
00BAh
After Reset
00011000b
SSMR
Bit Symbol
Bit Name
Function
RW
RO
Bits counter 2 to 0
b2 b1 b0
0 0 0 : 8 bits left
0 0 1 : 1 bit left
0 1 0 : 2 bits left
0 1 1 : 3 bits left
1 0 0 : 4 bits left
1 0 1 : 5 bits left
BC0
BC1
BC2
RO
RO
1 1 0 : 6 bits left
1 1 1 : 7 bits left
—
(b3)
Reserved bit
Set to 1.
When read, the content is 1.
RW
—
—
(b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
SSCK clock phase select bit(1)
0 : Change data at odd edge
(Dow nload data at even edge)
1 : Change data at even edge
(Dow nload data at odd edge)
CPHS
RW
SSCK clock polarity select bit(1)
MSB first/LSB first select bit
0 : “H” w hen clock stops
1 : “L” w hen clock stops
CPOS
MLS
RW
RW
0 : Transfers data MSB first
1 : Transfers data LSB first
NOTE:
1. Ref er to
for the settings of the CPHS
16.2.1.1 Association between Transfer Clock Polarity, Phase, and Data
and CPOS bits.
Figure 16.4
SSMR Register
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16. Clock Synchronous Serial Interface
SS Enable Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00BBh
After Reset
00h
SSER
Bit Symbol
Bit Name
Function
RW
RW
Conflict error interrupt enable bit 0 : Disables conflict error interrupt request
1 : Enables conflict error interrupt request
CEIE
—
(b2-b1)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
Receive enable bit
0 : Disables receive
1 : Enables receive
RE
TE
RW
RW
Transmit enable bit
0 : Disables transmit
1 : Enables transmit
Receive interrupt enable bit
0 : Disables receive data full and overrun
error interrupt request
RIE
TEIE
TIE
RW
RW
RW
1 : Enables receive data full and overrun
error interrupt request
Transmit end interrupt enable bit 0 : Disables transmit end interrupt request
1 : Enables transmit end interrupt request
Transmit interrupt enable bit
0 : Disables transmit data empty interrupt
request
1 : Enables transmit data empty interrupt
request
Figure 16.5
SSER Register
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16. Clock Synchronous Serial Interface
SS Status Register(7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00BCh
After Reset
00h
SSSR
Bit Symbol
Bit Name
Conflict error flag(1)
Function
RW
RW
0 : No conflict errors generated
1 : Conflict errors generated(2)
CE
—
(b1)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
RW
—
Overrun error flag(1)
0 : No overrun errors generated
1 : Overrun errors generated(3)
ORER
—
(b4-b3)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Receive data register full
0 : No data in SSRDR register
1 : Data in SSRDR register
RDRF
TEND
RW
(1,4)
Transmit end(1, 5)
0 : The TDREbit is set to 0 w hen transmitting
the last bit of transmit data
RW
RW
1 : The TDREbit is set to 1 w hen transmitting
the last bit of transmit data
Transmit data empty(1, 5, 6)
0 : Data is not transferred from registers SSTDR to
SSTRSR
TDRE
1 : Data is transferred from registers SSTDR to
SSTRSR
NOTES:
1. Writing 1 to CE, ORER, RDRF, TEND, or TDREbits invalid. To set any of these bits to 0, first read 1 then w rite 0.
2. When the serial communication is started w hile the SSUMS bit in the SSMR2 register is set to 1 (four-w ire bus
communication mode) and the MSS bit in the SSCRH regis_te__r_is set to 1 (operates as master device), the CEbit is set
____
to 1 if “L” is applied to the SCS pin input. Refer to
.
16.2.7 SCS Pin Control and Arbitration for more information
When the SSUMS bit in the SSMR2 register is set to 1 (four-w ire bus communication mode), the MSS bit in the
____
SSCRH register is set to 0 (operates as slave device) and the SCS pin input changes the level from “L” to “H” during
transfer, the CEbit is set to 1.
3. Indicates w hen overrun errors occur and receive completes by error reception. If the next serial data receive
operation is completed w hile the RDRF bit is set to 1 (data in the SSRDR register), the ORER bit is set to 1. After the
ORER bit is set to 1 (overrun error), transmit and receive operations are disabled w hile the bit remains 1.
4. The RDRF bit is set to 0 w hen reading out the data from the SSRDR register.
5. Bits TEND and TDREare set to 0 w hen w riting data to the SSTDR register.
6. The TDREbit is set to 1 w hen the TEbit in the SSER register is set to 1 (transmit enabled).
7. When accessing the SSSR register continuously, insert one or more NOPinstructions betw een the instructions to
access it.
Figure 16.6
SSSR Register
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16. Clock Synchronous Serial Interface
SS Mode Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00BDh
After Reset
00h
SSMR2
Bit Symbol
Bit Name
Function
RW
RW
Clock synchronous serial I/O w ith 0 : Clock synchronous communication mode
chip select mode select bit(1)
1 : Four-w ire bus communication mode
SSUMS
____
0 : CMOS output
SCS pin open drain output
CSOS
SOOS
SCKOS
RW
RW
RW
1 : N-channel open drain output
Serial data pin open output drain 0 : CMOS output(5)
select bit
select bit(1)
1 : N-channel open drain output
SSCK pin open drain output
0 : CMOS output
1 : N-channel open drain output
select bit
____
SCS pin select bits(2)
b5 b4
0 0 : Functions as port
____
CSS0
RW
0 1 : Functions as SCS input pin
____
1 0 : Functions as SCS output pin(3)
____
1 1 : Functions as SCS output pin(3)
CSS1
SCKS
RW
RW
SSCK pin select bit
0 : Functions as port
1 : Functions as serial clock pin
Bidirectional mode enable bit(1, 4) 0 : Standard mode (communication using 2
pins of data input and data output)
BIDE
RW
1 : Bidirectional mode (communication using
1 pin of data input and data output)
NOTES:
1. Ref er to
for information on combinations of
16.2.2.1 Association between Data I/O Pins and SS Shift Register
data I/O pins.
____
2. The SCS pin functions as a port, regardless of the values of bits CSS0 and CSS1 w hen the SSUMS
bit is set to 0 (clock synchronous communication mode).
____
3. This bit functions as the SCS input pin before starting transfer.
4. The BIDEbit is disabled w hen the SSUMS bit is set to 0 (clock synchronous communication mode).
5. The SSI pin and SSO pin corresponding port direction bits are set to 0 (input mode) w hen the SOOS bit is set to 0
(CMOS output).
Figure 16.7
SSMR2 Register
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16. Clock Synchronous Serial Interface
SS Transmit Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
SSTDR
Address
00BEh
After Reset
FFh
Function
RW
Store the transmit data.
The stored transmit data is transferred to the SSTRSR register and transmission is started
w hen it is detected that the SSTRSR register is empty.
When the next transmit data is w ritten to the SSTDR register during the data transmission from
the SSTRSR register, the data can be transmitted continuously.
RW
When the MLS bit in the SSMR register is set to 1 (transfer data w ith LSB-first), the data in
w hich MSB and LSB are reversed is read, after w riting to the SSTDR register.
SS Receive Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
SSRDR
Address
00BFh
After Reset
FFh
Function
RW
RO
Store the receive data.(1)
The receive data is transferred to the SSRDR register and the receive operation is completed
w hen 1 byte of data has been received by the SSTRSR register. At this time, the next receive
operation is possible. Continuous reception is possible using registers SSTRSR and SSRDR.
NOTE:
1. The SSRDR register retains the data reception before an overrun error occurs (ORER bit in the SSSR register set to
1 (overrun error)). When an overrun error occurs, the receive data may contain errors and therefore should be
discarded.
Figure 16.8
Registers SSTDR and SSRDR
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16. Clock Synchronous Serial Interface
Port Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00F8h
After Reset
00h
PMR
Bit Symbol
Bit Name
Function
RW
RW
____
0 : P1_5, P1_7
1 : P3_6
INT1 pin select bit
INT1SEL
—
(b2-b1)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
SSI pin select bit
0 : P3_3
1 : P1_6
SSISEL
U1PINSEL
TXD1SEL
TXD1EN
IICSEL
RW
RW
RW
RW
RW
TXD1 pin sw itch bit(1)
Port/TXD1 pin sw itch bit(1)
TXD1/RXD1 select bit(1)
SSU / I2C bus pin sw itch bit
0 : P0_0
1 : P3_6, P3_7
0 : Programmable I/O port
1 : TXD1
0 : RXD1
1 : TXD1
0 : Selects SSU function
1 : Selects I2C bus function
NOTE:
1. The UART1 pins can be selected by using bits U1PINSEL, TXD1SEL and TXD1EN, and bits UART1SEL1 and
UART1SEL0 in the PINSR1 register.
Pin Function
PINSR1 Register
UART1SEL1,
PMR Register
U1PINSEL bit TXD1SEL bit
TXD1EN bit
UART1SEL0 bit
P3_7(TXD1)
P3_7(RXD1)
P0_0(TXD1)
P3_7(TXD1)
P4_5(RXD1)
P3_6(TXD1)
P3_6(RXD1)
P0_0(TXD1)
1
0
×
×
0
1
×
00b
01b
1
1
×
×
1
0
×
×
0
×
1
10b
×: 0 or 1
Figure 16.9
PMR Register
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16. Clock Synchronous Serial Interface
16.2.1 Transfer Clock
The transfer clock can be selected from among seven internal clocks (f1/256, f1/128, f1/64, f1/32, f1/16, f1/8,
and f1/4) and an external clock.
When using clock synchronous serial I/O with chip select, set the SCKS bit in the SSMR2 register to 1 and
select the SSCK pin as the serial clock pin.
When the MSS bit in the SSCRH register is set to 1 (operates as master device), an internal clock can be
selected and the SSCK pin functions as output. When transfer is started, the SSCK pin outputs clocks of the
transfer rate selected by bits CKS0 to CKS2 in the SSCRH register.
When the MSS bit in the SSCRH register is set to 0 (operates as slave device), an external clock can be selected
and the SSCK pin functions as input.
16.2.1.1 Association between Transfer Clock Polarity, Phase, and Data
The association between the transfer clock polarity, phase and data changes according to the combination of the
SSUMS bit in the SSMR2 register and bits CPHS and CPOS in the SSMR register.
Figure 16.10 shows the Association between Transfer Clock Polarity, Phase, and Transfer Data.
Also, the MSB-first transfer or LSB-first transfer can be selected by setting the MLS bit in the SSMR register.
When the MLS bit is set to 1, transfer is started from the LSB and proceeds to the MSB. When the MLS bit is
set to 0, transfer is started from the MSB and proceeds to the LSB.
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16. Clock Synchronous Serial Interface
• SSUMS = 0 (clock synchronous communication mode), CPHS bit = 0 (data change at odd
edge), and CPOS bit = 0 (“H” when clock stops)
SSCK
SSO, SSI
b0
b1
b2
b3
b4
b5
b6
b7
• SSUMS = 1 (4-wire bus communication mode) and CPHS = 0 (data change at odd edge)
SSCK
CPOS = 0
(“H” when clock stops)
SSCK
CPOS = 1
(“L” when clock stops)
SSO, SSI
SCS
b0
b1
b2
b3
b4
b5
b6
b7
• SSUMS = 1 (4-wire bus communication mode) and CPHS = 1 (data download at odd edge)
SSCK
CPOS = 0
(“H” when clock stops)
SSCK
CPOS = 1
(“L” when clock stops)
SSO, SSI
SCS
b0
b1
b2
b3
b4
b7
b5
b6
CPHS and CPOS: Bits in SSMR register, SSUMS: Bits in SSMR2 register
Figure 16.10 Association between Transfer Clock Polarity, Phase, and Transfer Data
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16. Clock Synchronous Serial Interface
16.2.2 SS Shift Register (SSTRSR)
The SSTRSR register is a shift register for transmitting and receiving serial data.
When transmit data is transferred from the SSTDR register to the SSTRSR register and the MLS bit in the
SSMR register is set to 0 (MSB-first), the bit 0 in the SSTDR register is transferred to bit 0 in the SSTRSR
register. When the MLS bit is set to 1 (LSB-first), bit 7 in the SSTDR register is transferred to bit 0 in the
SSTRSR register.
16.2.2.1 Association between Data I/O Pins and SS Shift Register
The connection between the data I/O pins and SSTRSR register (SS shift register) changes according to a
combination of the MSS bit in the SSCRH register and the SSUMS bit in the SSMR2 register. The connection
also changes according to the BIDE bit in the SSMR2 register.
Figure 16.11 shows the Association between Data I/O Pins and SSTRSR Register.
• SSUMS = 1 (4-wire bus communication mode),
BIDE = 0 (standard mode), and MSS = 1 (operates as
master device)
• SSUMS = 0
(clock synchronous communication mode)
SSTRSR register
SSTRSR register
SSO
SSI
SSO
SSI
• SSUMS = 1 (4-wire bus communication mode) and
BIDE = 1 (bidirectional mode)
• SSUMS = 1 (4-wire bus communication mode),
BIDE = 0 (standard mode), and MSS = 0 (operates
as slave device)
SSTRSR register
SSO
SSI
SSTRSR register
SSO
SSI
Figure 16.11 Association between Data I/O Pins and SSTRSR Register
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16. Clock Synchronous Serial Interface
16.2.3 Interrupt Requests
Clock synchronous serial I/O with chip select has five interrupt requests: transmit data empty, transmit end,
receive data full, overrun error, and conflict error. Since these interrupt requests are assigned to the clock
synchronous serial I/O with chip select interrupt vector table, determining interrupt sources by flags is required.
Table 16.3 shows the Clock Synchronous Serial I/O with Chip Select Interrupt Requests.
Table 16.3
Interrupt Request
Transmit data empty
Clock Synchronous Serial I/O with Chip Select Interrupt Requests
Abbreviation Generation Condition
TIE = 1, TDRE = 1
TXI
TEI
RXI
OEI
CEI
Transmit end
Receive data full
Overrun error
Conflict error
TEIE = 1, TEND = 1
RIE = 1, RDRF = 1
RIE = 1, ORER = 1
CEIE = 1, CE = 1
CEIE, RIE, TEIE and TIE: Bits in SSER register
ORER, RDRF, TEND and TDRE: Bits in SSSR register
If the generation conditions in Table 16.3 are met, a clock synchronous serial I/O with chip select interrupt request
is generated. Set each interrupt source to 0 by a clock synchronous serial I/O with chip select interrupt routine.
However, the TDRE and TEND bits are automatically set to 0 by writing transmit data to the SSTDR register and
the RDRF bit is automatically set to 0 by reading the SSRDR register. In particular, the TDRE bit is set to 1 (data
transmitted from registers SSTDR to SSTRSR) at the same time transmit data is written to the SSTDR register.
Setting the TDRE bit to 0 (data not transmitted from registers SSTDR to SSTRSR) can cause an additional byte of
data to be transmitted.
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16. Clock Synchronous Serial Interface
16.2.4 Communication Modes and Pin Functions
Clock synchronous serial I/O with chip select switches the functions of the I/O pins in each communication
mode according to the setting of the MSS bit in the SSCRH register and bits RE and TE in the SSER register.
Table 16.4 shows the Association between Communication Modes and I/O Pins.
Table 16.4
Association between Communication Modes and I/O Pins
Bit Setting
Pin State
SSO
Communication Mode
SSUMS
0
BIDE
MSS
TE
RE
SSI
Input
SSCK
Input
(1)
Clock synchronous
communication mode
Disabled
0
1
0
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
0
−
(1)
Output Input
−
Input
Input
Output Input
(1)
0
1
Output
−
(1)
Output Output
Output Output
−
Input
(1)
4-wire bus
communication mode
1
1
0
1
0
1
Input
Input
Input
Input
Output
−
(1)
Output
−
Output Input
(1)
0
1
Input
−
(1)
Output Output
Output Output
−
Input
(1)
4-wire bus
(bidirectional)
0
1
0
1
0
1
Input
Input
−
(1)
Output Input
−
(2)
communication mode
(1)
Input
Output
−
(1)
Output Output
−
NOTES:
1. This pin can be used as a programmable I/O port.
2. Do not set both bits TE and RE to 1 in 4-wire bus (bidirectional) communication mode.
SSUMS and BIDE: Bits in SSMR2 register
MSS: Bit in SSCRH register
TE and RE: Bits in SSER register
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16. Clock Synchronous Serial Interface
16.2.5 Clock Synchronous Communication Mode
16.2.5.1 Initialization in Clock Synchronous Communication Mode
Figure 16.12 shows the Initialization in Clock Synchronous Communication Mode. To initialize, set the TE bit
in the SSER register to 0 (transmit disabled) and the RE bit to 0 (receive disabled) before data transmission or
reception.
Set the TE bit to 0 and the RE bit to 0 before changing the communication mode or format.
Setting the RE bit to 0 does not change the contents of flags RDRF and ORER or the contents of the SSRDR
register.
Start
SSER register RE bit ← 0
TE bit ← 0
SSMR2 register SSUMS bit ← 0
SSMR register CPHS bit ← 0
CPOS bit ← 0
Set MLS bit
SSCRH register Set MSS bit
SSMR2 register
SSCRH register
SCKS bit ← 1
Set SOOS bit
Set bits CKS0 to CKS2
Set RSSTP bit
SSSR register ORER bit ← 0(1)
SSER register
RE bit ← 1 (receive)
TE bit ← 1 (transmit)
Set bits RIE, TEIE, and TIE
End
NOTE:
1. Write 0 after reading 1 to set the ORER bit to 0.
Figure 16.12 Initialization in Clock Synchronous Communication Mode
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16. Clock Synchronous Serial Interface
16.2.5.2 Data Transmission
Figure 16.13 shows an Example of Clock Synchronous Serial I/O with Chip Select Operation for Data
Transmission (Clock Synchronous Communication Mode). During data transmission, the clock synchronous
serial I/O with chip select operates as described below.
When clock synchronous serial I/O with chip select is set as a master device, it outputs a synchronous clock and
data. When clock synchronous serial I/O with chip select is set as a slave device, it outputs data synchronized
with the input clock.
When the TE bit is set to 1 (transmit enabled) before writing the transmit data to the SSTDR register, the TDRE
bit is automatically set to 0 (data not transferred from registers SSTDR to SSTRSR) and the data is transferred
from registers SSTDR to SSTRSR.
After the TDRE bit is set to 1 (data transferred from registers SSTDR to SSTRSR), transmission starts. When
the TIE bit in the SSER register is set to 1, the TXI interrupt request is generated. When one frame of data is
transferred while the TDRE bit is set to 0, data is transferred from registers SSTDR to SSTRSR and
transmission of the next frame is started. If the 8th bit is transmitted while the TDRE bit is set to 1, the TEND
bit in the SSSR register is set to 1 (the TDRE bit is set to 1 when the last bit of the transmit data is transmitted)
and the state is retained. The TEI interrupt request is generated when the TEIE bit in the SSER register is set to
1 (transmit-end interrupt request enabled). The SSCK pin is fixed “H” after transmit-end.
Transmit cannot be performed while the ORER bit in the SSSR register is set to 1 (overrun error). Confirm that
the ORER bit is set to 0 before transmission.
Figure 16.14 shows a Sample Flowchart of Data Transmission (Clock Synchronous Communication Mode).
• SSUMS = 0 (clock synchronous communication mode), CPHS = 0 (data change at
odd numbers), and CPOS = 0 (“H” when clock stops)
SSCK
SSO
b0
b1
b7
b0
b1
b7
1 frame
1 frame
1
0
TDRE bit in
SSSR register
TEI interrupt request
generation
1
0
TXI interrupt request generation
TEND bit in
SSSR register
Processing
by program
Write data to SSTDR register
Figure 16.13 Example of Clock Synchronous Serial I/O with Chip Select Operation for Data
Transmission (Clock Synchronous Communication Mode)
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16. Clock Synchronous Serial Interface
Start
Initialization
(1)
(1) After reading the SSSR register and confirming
Read TDRE bit in SSSR register
that the TDRE bit is set to 1, write the transmit
data to the SSTDR register. When the transmit
data is written to the SSTDR register, the TDRE
bit is automatically set to 0.
No
TDRE = 1 ?
Yes
Write transmit data to SSTDR register
Data
Yes
transmission
(2)
(3)
(2) Determine whether data transmission continues.
continues?
No
Read TEND bit in SSSR register
(3) When data transmission is completed, the TEND
bit is set to 1. Set the TEND bit to 0 and the TE bit
to 0 and complete transmit mode.
No
TEND = 1 ?
Yes
SSSR register
SSER register
TEND bit ← 0(1)
TE bit ← 0
End
NOTE:
1. Write 0 after reading 1 to set the TEND bit to 0.
Figure 16.14 Sample Flowchart of Data Transmission (Clock Synchronous Communication Mode)
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16. Clock Synchronous Serial Interface
16.2.5.3 Data Reception
Figure 16.15 shows an Example of Clock Synchronous Serial I/O with Chip Select Operation for Data
Reception (Clock Synchronous Communication Mode).
During data reception, clock synchronous serial I/O with chip select operates as described below. When the
clock synchronous serial I/O with chip select is set as the master device, it outputs a synchronous clock and
inputs data. When the clock synchronous serial I/O with chip select is set as a slave device, it inputs data
synchronized with the input clock.
When clock synchronous serial I/O with chip select is set as a master device, it outputs a receive clock and starts
receiving by performing dummy read of the SSRDR register.
After 8 bits of data are received, the RDRF bit in the SSSR register is set to 1 (data in the SSRDR register) and
receive data is stored in the SSRDR register. When the RIE bit in the SSER register is set to 1 (RXI and OEI
interrupt requests enabled), the RXI interrupt request is generated. If the SSDR register is read, the RDRF bit is
automatically set to 0 (no data in the SSRDR register).
Read the receive data after setting the RSSTP bit in the SSCRH register to 1 (after receiving 1 byte of data, the
receive operation is completed). Clock synchronous serial I/O with chip select outputs a clock for receiving 8
bits of data and stops. After that, set the RE bit in the SSER register to 0 (receive disabled) and the RSSTP bit to
0 (receive operation is continued after receiving the 1 byte of data) and read the receive data. If the SSRDR
register is read while the RE bit is set to 1 (receive enabled), a receive clock is output again.
When the 8th clock rises while the RDRF bit is set to 1, the ORER bit in the SSSR register is set to 1 (overrun
error: OEI) and the operation is stopped. When the ORER bit is set to 1, receive cannot be performed. Confirm
that the ORER bit is set to 0 before restarting receive.
Figure 16.16 shows a Sample Flowchart for Data Reception (MSS = 1) (Clock Synchronous Communication
Mode).
• SSUMS = 0 (clock synchronous communication mode), CPHS = 0 (data download at
even edges), and CPOS bit = 0 (“H” when clock stops)
SSCK
b0
b7
b0
b0
SSI
b7
b7
1 frame
1 frame
1
0
RDRF bit in
SSSR register
RXI interrupt request
generation
RXI interrupt request
generation
1
0
RSSTP bit in
SSCRH register
RXI interrupt request
generation
Dummy read in
SSRDR register
Read data in SSRDR
register
Read data in
SSRDR register
Processing
by program
Set RSSTP bit to 1
Figure 16.15 Example of Clock Synchronous Serial I/O with Chip Select Operation for Data
Reception (Clock Synchronous Communication Mode)
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16. Clock Synchronous Serial Interface
Start
Initialization
(1) After setting each register in the clock synchronous
serial I/O with chip select register, a dummy read of
the SSRDR register is performed and the receive
operation is started.
(1)
(2)
Dummy read of SSRDR register
Last data
received?
Yes
(2) Determine whether it is the last 1 byte of data to be
received. If so, set to stop after the data is received.
No
Read ORER bit in SSSR register
Yes
(3) If a receive error occurs, perform error
(3)
(4)
ORER = 1 ?
(6) Processing after reading the ORER bit. Then set
the ORER bit to 0. Transmission/reception cannot
be restarted while the ORER bit is set to 1.
No
Read RDRF bit in SSSR register
(4) Confirm that the RDRF bit is set to 1. If the RDRF
bit is set to 1, read the receive data in the SSRDR
register. When the SSRDR register is read, the
RDRF bit is automatically set to 0.
No
RDRF = 1 ?
Yes
Read receive data in SSRDR register
(5) Before the last 1 byte of data is received, set the
RSSTP bit to 1 and stop after the data is
received.
(5)
(6)
SSCRH register RSSTP bit ← 1
Read ORER bit in SSSR register
Yes
ORER = 1 ?
No
Read RDRF in SSSR register
(7) Confirm that the RDRF bit is set to 1. When the
receive operation is completed, set the RSSTP bit to
0 and the RE bit to 0 before reading the last 1 byte
of data. If the SSRDR register is read before setting
the RE bit to 0, the receive operation is restarted
again.
No
RDRF = 1 ?
(7)
Yes
SSCRH register RSSTP bit ← 0
Overrun
error
SSER register
RE bit ← 0
processing
Read receive data in SSRDR register
End
Figure 16.16 Sample Flowchart for Data Reception (MSS = 1) (Clock Synchronous Communication
Mode)
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16. Clock Synchronous Serial Interface
16.2.5.4 Data Transmission/Reception
Data transmission/reception is an operation combining data transmission and reception which were described
earlier. Transmission/reception is started by writing data to the SSTDR register.
When the 8th clock rises or the ORER bit is set to 1 (overrun error) while the TDRE bit is set to 1 (data is
transferred from registers SSTDR to SSTRSR), the transmit/receive operation is stopped.
When switching from transmit mode (TE = 1) or receive mode (RE = 1) to transmit/receive mode (Te = RE =
1), set the TE bit to 0 and RE bit to 0 before switching. After confirming that the TEND bit is set to 0 (the
TDRE bit is set to 0 when the last bit of the transmit data is transmitted), the RDRF bit is set to 0 (no data in the
SSRDR register), and the ORER bit is set to 0 (no overrun error), set bits TE and RE to 1.
Figure 16.17 shows a Sample Flowchart for Data Transmission/Reception (Clock Synchronous Communication
Mode).
When exiting transmit/receive mode after this mode is used (TE = RE = 1), a clock may be output if
transmit/receive mode is exited after reading the SSRDR register. To avoid any clock outputs, perform either of
the following:
- First set the RE bit to 0, and then set the TE bit to 0.
- Set bits TE and RE at the same time.
When subsequently switching to receive mode (TE = 0 and RE = 1), first set the SRES bit to 1, and set this bit
to 0 to reset the clock synchronous serial interface control unit and the SSTRSR register. Then, set the RE bit to
1.
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16. Clock Synchronous Serial Interface
Start
Initialization
(1)
(1) After reading the SSSR register and confirming
Read TDRE bit in SSSR register
that the TDRE bit is set to 1, write the transmit
data to the SSTDR register. When the transmit
data is written to the SSTDR register, the TDRE
bit is automatically set to 0.
No
TDRE = 1 ?
Yes
Write transmit data to SSTDR register
Read RDRF bit in SSSR register
(2)
(2) Confirm that the RDRF bit is set to 1. If the RDRF
bit is set to 1, read the receive data in the SSRDR
register. When reading the SSRDR register is
read, the RDRF bit is automatically set to 0.
No
RDRF = 1 ?
Yes
Read receive data in SSRDR register
Data
transmission
continues?
Yes
(3) Determine whether the data transmission
continues
(3)
(4)
No
(4) When the data transmission is completed, the
TEND bit in the SSSR register is set to 1.
Read TEND bit in SSSR register
No
TEND = 1 ?
Yes
(5) Set the TEND bit to 0 and bits RE and TE in
(6) the SSER register to 0 before ending transmit/
receive mode.
SSSR register
SSER register
TEND bit ← 0(1)
(5)
(6)
RE bit ← 0
TE bit ← 0
End
NOTE:
1. Write 0 after reading 1 to set the TEND bit to 0.
Figure 16.17 Sample Flowchart for Data Transmission/Reception (Clock Synchronous
Communication Mode)
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16. Clock Synchronous Serial Interface
16.2.6 Operation in 4-Wire Bus Communication Mode
In 4-wire bus communication mode, a 4-wire bus consisting of a clock line, a data input line, a data output line,
and a chip select line is used for communication. This mode includes bidirectional mode in which the data input
line and data output line function as a single pin.
The data input line and output line change according to the settings of the MSS bit in the SSCRH register and
the BIDE bit in the SSMR2 register. For details, refer to 16.2.2.1 Association between Data I/O Pins and SS
Shift Register. In this mode, clock polarity, phase, and data settings are performed by the CPOS and CPHS bits
in the SSMR register. For details, refer to 16.2.1.1 Association between Transfer Clock Polarity, Phase, and
Data.
When this MCU is set as the master device, the chip select line controls output. When the clock synchronous
serial I/O with chip select is set as a slave device, the chip select line controls input. When it is set as master
device, the chip select line controls output of the SCS pin or controls output of a general port according to the
setting of the CSS1 bit in the SSMR2 register. When the MCU is set as a slave device, the chip select line sets
the SCS pin as an input pin by setting bits CSS1 and CSS0 in the SSMR2 register to 01b.
In 4-wire bus communication mode, the MLS bit in the SSMR register is set to 0 and communication is
performed MSB-first.
16.2.6.1 Initialization in 4-Wire Bus Communication Mode
Figure 16.18 shows the Initialization in 4-Wire Bus Communication Mode. Before the data transit/receive
operation, set the TE bit in the SSER register to 0 (transmit disabled), the RE bit in the SSER register to 0
(receive disabled), and initialize the clock synchronous serial I/O with chip select.
To change the communication mode or format, set the TE bit to 0 and the RE bit to 0 before making the change.
Setting the RE bit to 0 does not change the settings of flags RDRF and ORER or the contents of the SSRDR
register.
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16. Clock Synchronous Serial Interface
Start
SSER register
RE bit ← 0
TE bit ← 0
SSMR2 register
SSUMS bit ← 1
(1) The MLS bit is set to 0 for MSB-first transfer.
(1)
SSMR register
Set bits CPHS and CPOS
MLS bits ← 0
The clock polarity and phase are set by bits
CPHS and CPOS.
SSCRH register
Set MSS bit
(2) Set the BIDE bit to 1 in bidirectional mode and
set the I/O of the SCS pin by bits CSS0 and
CSS1.
SSMR2 register
SSCRH register
SCKS bit ← 1
Set bits SOOS, CSS0 to
CSS1, and BIDE
(2)
Set bits CKS0 to CKS2
Set RSSTP bit
SSSR register
SSER register
ORER bit ← 0(1)
RE bit ← 1 (receive)
TE bit ← 1 (transmit)
Set bits RIE, TEIE, and TIE
End
NOTE:
1. Write 0 after reading 1 to set the ORER bit to 0.
Figure 16.18 Initialization in 4-Wire Bus Communication Mode
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16. Clock Synchronous Serial Interface
16.2.6.2 Data Transmission
Figure 16.19 shows an Example of Clock Synchronous Serial I/O with Chip Select Operation during Data
Transmission (4-Wire Bus Communication Mode). During the data transmit operation, the clock synchronous
serial I/O with chip select operates as described below.
When the MCU is set as the master device, it outputs a synchronous clock and data. When the MCU is set as a
slave device, it outputs data in synchronization with the input clock while the SCS pin is “L”.
When the transmit data is written to the SSTDR register after setting the TE bit to 1 (transmit enabled), the
TDRE bit is automatically set to 0 (data has not been transferred from the SSTDR to the SSTRSR register) and
the data is transferred from registers SSTDR to SSTRSR. After the TDRE bit is set to 1 (data is transferred from
registers SSTDR to SSTRSR), transmission starts. When the TIE bit in the SSER register is set to 1, a TXI
interrupt request is generated.
After 1 frame of data is transferred while the TDRE bit is set to 0, the data is transferred from registers SSTDR
to SSTRSR and transmission of the next frame is started. If the 8th bit is transmitted while TDRE is set to 1,
TEND in the SSSR register is set to 1 (when the last bit of the transmit data is transmitted, the TDRE bit is set
to 1) and the state is retained. If the TEIE bit in the SSER register is set to 1 (transmit-end interrupt requests
enabled), a TEI interrupt request is generated. The SSCK pin remains “H” after transmit-end and the SCS pin is
held “H”. When transmitting continuously while the SCS pin is held “L”, write the next transmit data to the
SSTDR register before transmitting the 8th bit.
Transmission cannot be performed while the ORER bit in the SSSR register is set to 1 (overrun error). Confirm
that the ORER bit is set to 0 before transmission.
In contrast to the clock synchronous communication mode, the SSO pin is placed in high-impedance state while
the SCS pin is placed in high-impedance state when operating as a master device and the SSI pin is placed in
high-impedance state while the SCS pin is placed in “H” input state when operating as a slave device.
The sample flowchart is the same as that for the clock synchronous communication mode (refer to Figure 16.14
Sample Flowchart of Data Transmission (Clock Synchronous Communication Mode)).
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16. Clock Synchronous Serial Interface
• CPHS bit = 0 (data change at odd edges) and CPOS bit = 0 (“H” when clock stops)
High-impedance
SCS
(output)
SSCK
SSO
b6
b7
b6
b0
b7
b0
1 frame
1 frame
1
0
TDRE bit in
SSSR register
TEI interrupt request is
generated
TXI interrupt request
is generated
TXI interrupt request
is generated
1
0
TEND bit in
SSSR register
Data write to SSTDR register
Processing
by program
• CPHS bit = 1 (data change at even edges) and CPOS bit = 0 (“H” when clock stops)
High-impedance
SCS
(output)
SSCK
b7
SSO
b6
b0
b7
1 frame
b6
b0
1 frame
1
TDRE bit in
SSSR register
TEI interrupt request is
generated
0
TXI interrupt request
is generated
TXI interrupt request
is generated
1
0
TEND bit in
SSSR register
Data write to SSTDR register
Processing
by program
CPHS, CPOS: Bits in SSMR register
Figure 16.19 Example of Clock Synchronous Serial I/O with Chip Select Operation during Data
Transmission (4-Wire Bus Communication Mode)
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16. Clock Synchronous Serial Interface
16.2.6.3 Data Reception
Figure 16.20 shows an Example of Clock Synchronous Serial I/O with Chip Select Operation during Data
Reception (4-Wire Bus Communication Mode). During data reception, clock synchronous serial I/O with chip
select operates as described below.
When the MCU is set as the master device, it outputs a synchronous clock and inputs data. When the MCU is
set as a slave device, it outputs data synchronized with the input clock while the SCS pin receives “L” input.
When the MCU is set as the master device, it outputs a receive clock and starts receiving by performing a
dummy read of the SSRDR register.
After the 8 bits of data are received, the RDRF bit in the SSSR register is set to 1 (data in the SSRDR register)
and receive data is stored in the SSRDR register. When the RIE bit in the SSER register is set to 1 (RXI and
OEI interrupt requests enabled), an RXI interrupt request is generated. When the SSRDR register is read, the
RDRF bit is automatically set to 0 (no data in the SSRDR register).
Read the receive data after setting the RSSTP bit in the SSCRH register to 1 (after receiving 1-byte data, the
receive operation is completed). Clock synchronous serial I/O with chip select outputs a clock for receiving 8
bits of data and stops. After that, set the RE bit in the SSER register to 0 (receive disabled) and the RSSTP bit to
0 (receive operation is continued after receiving 1-byte data) and read the receive data. When the SSRDR
register is read while the RE bit is set to 1 (receive enabled), a receive clock is output again.
When the 8th clock rises while the RDRF bit is set to 1, the ORER bit in the SSSR register is set to 1 (overrun
error: OEI) and the operation is stopped. When the ORER bit is set to 1, reception cannot be performed.
Confirm that the ORER bit is set to 0 before restarting reception.
The timing with which bits RDRF and ORER are set to 1 varies depending on the setting of the CPHS bit in the
SSMR register. Figure 16.20 shows when bits RDRF and ORER are set to 1.
When the CPHS bit is set to 1 (data download at the odd edges), bits RDRF and ORER are set to 1 at some
point during the frame.
The sample flowchart is the same as that for the clock synchronous communication mode (refer to Figure 16.16
Sample Flowchart for Data Reception (MSS = 1) (Clock Synchronous Communication Mode)).
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16. Clock Synchronous Serial Interface
• CPHS bit = 0 (data download at even edges) and CPOS bit = 0 (“H” when clock stops)
High-impedance
SCS
(output)
SSCK
SSI
b7
b0
b7
b0
b7
b0
1 frame
1 frame
1
0
RDRF bit in
SSSR register
RXI interrupt request
is generated
RXI interrupt request
is generated
1
0
RSSTP bit in
SSCRH register
RXI interrupt request
is generated
Dummy read in
SSRDR register
Data read in SSRDR
register
Set RSSTP
bit to 1
Data read in SSRDR
register
Processing
by program
• CPHS bit = 1 (data download at odd edges) and CPOS bit = 0 (“H” when clock stops)
High-impedance
SCS
(output)
SSCK
b7
SSI
b0
b7
b0
b7
b0
1 frame
1 frame
1
RDRF bit in
SSSR register
0
RXI interrupt request
is generated
RXI interrupt request
is generated
1
0
RSSTP bit in
SSCRH register
RXI interrupt request
is generated
Dummy read in
SSRDR register
Data read in SSRDR
register
Set RSSTP
bit to 1
Data read in SSRDR
register
Processing
by program
CPHS and CPOS: Bit in SSMR register
Figure 16.20 Example of Clock Synchronous Serial I/O with Chip Select Operation during Data
Reception (4-Wire Bus Communication Mode)
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16. Clock Synchronous Serial Interface
16.2.7 SCS Pin Control and Arbitration
When setting the SSUMS bit in the SSMR2 register to 1 (4-wire bus communication mode) and the CSS1 bit in
the SSMR2 register to 1 (functions as SCS output pin), set the MSS bit in the SSCRH register to 1 (operates as
the master device) and check the arbitration of the SCS pin before starting serial transfer. If clock synchronous
serial I/O with chip select detects that the synchronized internal SCS signal is held “L” in this period, the CE bit
in the SSSR register is set to 1 (conflict error) and the MSS bit is automatically set to 0 (operates as a slave
device).
Figure 16.21 shows the Arbitration Check Timing.
Future transmit operations are not performed while the CE bit is set to 1. Set the CE bit to 0 (no conflict error)
before starting transmission.
SCS input
Internal SCS
(synchronization)
1
MSS bit in
SSCRH register
0
Transfer start
Data write to
SSTDR register
CE
High-impedance
SCS output
Maximum time of SCS internal
synchronization
During arbitration detection
Figure 16.21 Arbitration Check Timing
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16. Clock Synchronous Serial Interface
16.2.8 Notes on Clock Synchronous Serial I/O with Chip Select
Set the IICSEL bit in the PMR register to 0 (select clock synchronous serial I/O with chip select function) to use
the clock synchronous serial I/O with chip select function.
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16. Clock Synchronous Serial Interface
2
16.3 I C bus Interface
2
The I C bus interface is the circuit that performs serial communication based on the data transfer format of the
2
Philips I C bus.
2
2
Table 16.5 lists the Specifications of I C bus Interface, Figure 16.22 shows a Block Diagram of I C bus Interface,
and Figure 16.23 shows the External Circuit Connection Example of Pins SCL and SDA. Figures 16.24 to 16.30
2
show the registers associated with the I C bus interface.
2
* I C bus is a trademark of Koninklijke Philips Electronics N. V.
2
Table 16.5
Specifications of I C bus Interface
Item
Specification
2
Communication formats
• I C bus format
- Selectable as master/slave device
- Continuous transmit/receive operation (because the shift register, transmit
data register, and receive data register are independent)
- Start/stop conditions are automatically generated in master mode
- Automatic loading of acknowledge bit during transmission
- Bit synchronization/wait function (In master mode, the state of the SCL
signal is monitored per bit and the timing is synchronized automatically. If
the transfer is not possible yet, the SCL signal goes “L” and the interface
stands by.)
- Support for direct drive of pins SCL and SDA (N-channel open drain output)
• Clock synchronous serial format
- Continuous transmit/receive operation (because the shift register, transmit
data register, and receive data register are independent)
SCL (I/O): Serial clock I/O pin
I/O pins
SDA (I/O): Serial data I/O pin
Transfer clocks
• When the MST bit in the ICCR1 register is set to 0
The external clock (input from the SCL pin)
• When the MST bit in the ICCR1 register is set to 1
The internal clock selected by bits CKS0 to CKS3 in the ICCR1 register
(output from the SCL pin)
Receive error detection • Overrun error detection (clock synchronous serial format)
Indicates an overrun error during reception. When the last bit of the next data
item is received while the RDRF bit in the ICSR register is set to 1 (data in the
ICDRR register), the AL bit is set to 1.
2
(1)
Interrupt sources
• I C bus format ................................ 6 sources
Transmit data empty (including when slave address matches), transmit ends,
receive data full (including when slave address matches), arbitration lost,
NACK detection, and stop condition detection.
(1)
• Clock synchronous serial format .... 4 sources
Transmit data empty, transmit ends, receive data full and overrun error
2
Select functions
NOTE:
• I C bus format
- Selectable output level for acknowledge signal during reception
• Clock synchronous serial format
- MSB-first or LSB-first selectable as data transfer direction
2
1. All sources use one interrupt vector for I C bus interface.
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16. Clock Synchronous Serial Interface
f1
Transfer clock
generation
circuit
Output
control
SCL
ICCR1 register
ICCR2 register
ICMR register
Transmit/receive
control circuit
Noise
canceller
ICDRT register
SAR register
Output
control
SDA
ICDRS register
ICDRR register
Noise
canceller
Address comparison
circuit
Bus state judgment
circuit
Arbitration judgment
circuit
ICSR register
ICIER register
Interrupt generation
circuit
Interrupt request
(TXI, TEI, RXI, STPI, NAKI)
2
Figure 16.22 Block Diagram of I C bus Interface
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16. Clock Synchronous Serial Interface
VCC
VCC
SCL
SCL
SCL input
SCL output
SDA
SDA
SDA input
SDA output
(Master)
SCL
SCL
SCL input
SCL input
SCL output
SCL output
SDA
SDA
SDA input
SDA input
SDA output
(Slave 1)
SDA output
(Slave 2)
Figure 16.23 External Circuit Connection Example of Pins SCL and SDA
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16. Clock Synchronous Serial Interface
IIC bus Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00B8h
After Reset
00h
ICCR1
Bit Symbol
Bit Name
Function
RW
RW
b3 b2 b1 b0
Transmit clock select bits 3 to
0(1)
0 0 0 0 : f1/28
CKS0
CKS1
CKS2
0 0 0 1 : f1/40
0 0 1 0 : f1/48
0 0 1 1 : f1/64
0 1 0 0 : f1/80
0 1 0 1 : f1/100
0 1 1 0 : f1/112
0 1 1 1 : f1/128
1 0 0 0 : f1/56
1 0 0 1 : f1/80
1 0 1 0 : f1/96
1 0 1 1 : f1/128
1 1 0 0 : f1/160
1 1 0 1 : f1/200
1 1 1 0 : f1/224
1 1 1 1 : f1/256
RW
RW
CKS3
RW
Transfer/receive select
bit(2, 3, 6)
b5 b4
0 0 : Slave Receive Mode(4)
0 1 : Slave Transmit Mode
1 0 : Master Receive Mode
1 1 : Master Transmit Mode
TRS
MST
RW
RW
Master/slave select bit(5, 6)
Receive disable bit
After reading the ICDRR register w hile the TRS bit
is set to 0
RCVD
ICE
RW
0 : Maintains the next receive operation
1 : Disables the next receive operation
IIC bus interface enable bit
0 : This module is halted
(Pins SCL and SDA are set to port function)
1 : This module is enabled for transfer
operations
RW
(Pins SCL and SDA are bus drive state)
NOTES:
1. Set according to the necessary transfer rate in master mode. Refer to
for the
Table 16.6 Transfer Rate Examples
transfer rate. This bit is used for maintaining of the setup time in transmit mode of slave mode. The time is 10Tcyc
w hen the CKS3 bit is set to 0 and 20Tcyc w hen the CKS3 bit is set to 1. (1Tcyc = 1/f1(s))
2. Rew rite the TRS bit betw een transfer frames.
3. When the first 7 bit after the start condition in slave receive mode match w ith the slave address set in the SAR
register and the 8th bit is set to 1, the TRS bit is set to 1.
In master mode w ith the I2C bus format, w hen arbitration is lost, bits MST and TRS are set to 0 and the IIC enters
slave receive mode.
4.
5. When an overrun error occurs in master receive mode of the clock synchronous serial format, the MST bit is set to 0
and the IIC enters slave receive mode.
6. In multimaster operation use the MOV instruction to set bits TRS and MST.
Figure 16.24 ICCR1 Register
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16. Clock Synchronous Serial Interface
IIC bus Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00B9h
After Reset
01111101b
ICCR2
Bit Symbol
Bit Name
Function
RW
—
—
(b0)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
IIC control part reset bit When hang-up occurs due to communication failure
during I2C bus interface operation, w rite 1, to reset the
control block of the I2C bus interface w ithout setting
ports or initializing registers.
IICRST
RW
—
(b2)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
—
SCL monitor flag
0 : SCL pin is set to “L”
1 : SCL pin is set to “H”
SCLO
RO
RW
SDAO w rite protect bit When rew rite to SDAO bit, w rite 0 simultaneously.(1)
When read, the content is 1.
SDAOP
SDA output value control When read
bit
0 : SDA pin output is held “L”
1 : SDA pin output is held “H”
When w ritten(1,2)
SDAO
SCP
RW
RW
0 : SDA pin output is changed to “L”
1 : SDA pin output is changed to high-impedance
(“H” output via external pull-up resistor)
Start/stop condition
generation disable bit
When w riting to the to BBSY bit, w rite 0
simultaneously.(3)
When read, the content is 1.
Writing 1 is invalid.
Bus busy bit(4)
When read
0 : Bus is in released state
(SDA signal changes from “L” to “H” w hile SCL
signal is in “H” state)
1 : Bus is in occupied state
(SDA signal changes from “H” to “L” w hile SCL
signal is in “H” state)
BBSY
RW
When w ritten(3)
0 : Generates stop condition
1 : Generates start condition
NOTES:
When w riting to the SDAO bit, w rite 0 to the SDAOPbit using the MOV instruction simultaneously.
Do not w rite during a transfer operation.
1.
2.
3. This bit is enabled in master mode. When w riting to the BBSY bit, w rite 0 to the SCPbit using the MOV
instruction simultaneously. Execute the same w ay w hen the start condition is regenerating.
This bit is disabled w hen the clock synchronous serial format is used.
4.
Figure 16.25 ICCR2 Register
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IIC bus Mode Register
16. Clock Synchronous Serial Interface
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
00BAh
After Reset
00011000b
ICMR
Bit Symbol
Bit Name
Function
RW
RW
Bits counter 2 to 0
I2C bus format (remaining transfer bit count w hen
read out and data bit count of next transfer w hen
w ritten).(1,2)
b2 b1 b0
0 0 0 : 9 bits(3)
BC0
0 0 1 : 2 bits
0 1 0 : 3 bits
0 1 1 : 4 bits
1 0 0 : 5 bits
1 0 1 : 6 bits
1 1 0 : 7 bits
1 1 1 : 8 bits
Clock synchronous serial format (w hen read, the
remaining transfer bit count and w hen w ritten
BC1
RW
000b).
b2 b1 b0
0 0 0 : 8 bits
0 0 1 : 1 bit
0 1 0 : 2 bits
0 1 1 : 3 bits
1 0 0 : 4 bits
1 0 1 : 5 bits
1 1 0 : 6 bits
1 1 1 : 7 bits
BC2
RW
RW
BC w rite protect bit
When rew riting bits BC0 to BC2, w rite 0
simultaneously.(2,4)
BCWP
When read, the content is 1.
—
(b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 1.
—
—
(b5)
Reserved bit
Set to 0.
RW
Wait insertion bit(5)
0 : No w ait
(Transfer data and acknow ledge bit
consecutively)
1 : Wait
WAIT
RW
RW
(After the clock falls for the final
data bit, “L” period is extended for tw o
transfer clocks cycles)
MSB-first/LSB-first select
bit
0 : Data transfer w ith MSB-first(6)
1 : Data transfer w ith LSB-first
MLS
NOTES:
1. Rew rite betw een transfer frames. When w riting values other than 000b, w rite w hen the SCL signal is “L”.
2. When w riting to bits BC0 to BC2, w rite 0 to the BCWPbit using the MOV instruction.
3. After data including the acknow ledge bit is transferred, these bits are automatically set to 000b. When the start
condition is detected, these bits are automatically set to 000b.
4. Do not rew rite w hen the clock synchronous serial format is used.
5. The setting value is enabled in master mode of the I2C bus format. It is disabled in slave mode of the I2C
bus format or w hen the clock synchronous serial format is used.
6. Set to 0 w hen the I2C bus format is used.
Figure 16.26 ICMR Register
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IIC bus Interrupt Enable Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
ICIER
Address
00BBh
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
Transmit acknow ledge
select bit
0 : 0 is transmitted as acknow ledge bit in
receive mode.
ACKBT
ACKBR
ACKE
STIE
1 : 1 is transmitted as acknow ledge bit in
receive mode.
Receive acknow ledge bit 0 : Acknow ledge bit received from
receive device in transmit mode is set to 0.
RO
RW
RW
RW
RW
1 : Acknow ledge bit received from
receive device in transmit mode is set to 1.
Acknow ledge bit judgment 0 : Value of receive acknow ledge bit is ignored
select bit
and continuous transfer is performed.
1 : When receive acknow ledge bit is set to 1,
continuous transfer is halted.
Stop condition detection
interrupt enable bit
0 : Disables stop condition detection interrupt
request
1 : Enables stop condition detection interrupt
request(2)
NACK receive interrupt
enable bit
0 : Disables NACK receive interrupt request and
arbitration lost/overrun error interrupt request
1 : Enables NACK receive interrupt request and
arbitration lost/overrun error interrupt request(1)
NAKIE
RIE
Receive interrupt enable 0 : Disables receive data full and overrun
bit
error interrupt request
1 : Enables receive data full and overrun
error interrupt request(1)
Transmit end interrupt
enable bit
0 : Disables transmit end interrupt request
1 : Enables transmit end interrupt request
TEIE
TIE
RW
RW
Transmit interrupt enable 0 : Disables transmit data empty interrupt request
bit 1 : Enables transmit data empty interrupt request
NOTES:
1. An overrun error interrupt request is generated w hen the clock synchronous format is used.
2. Set the STIEbit to 1 (enable stop condition detection interrupt request) w hen the STOPbit in the ICSR register is set
to 0.
Figure 16.27 ICIER Register
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IIC bus Status Register(7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00BCh
After Reset
0000X000b
ICSR
Bit Symbol
Bit Name
Function
RW
RW
General call address
recognition flag(1,2)
When the general call address is detected, this flag
is set to 1.
ADZ
AAS
Slave address recognition This flag is set to 1 w hen the first frame follow ing
flag(1)
start condition matches bits SVA0 to SVA6 in the
SAR register in slave receive mode. (Detect the
slave address and generate call address)
RW
Arbitration lost
flag/overrun error flag(1)
When the I2C bus format is used, this flag indicates
that arbitration has been lost in master mode. In the
follow ing cases, this flag is set to 1.(3)
• When the internal SDA signal and SDA pin
level do not match at the rise of the SCL signal
in master transmit mode
• When the start condition is detected and the
SDA pin is held “H” in master transmit/receive mode
This flag indicates an overrun error w hen the clock
synchronous format is used.
AL
RW
In the follow ing case, this flag is set to 1.
• When the last bit of the next data item is
received w hile the RDRF bit is set to 1
Stop condition detection
flag(1)
When the stop condition is detected after the frame
is transferred, this flag is set to 1
STOP
NACKF
RDRF
RW
RW
RW
No acknow ledge detection When no acknow ledge is detected from the receive
flag(1,4)
device after transmission, this flag is set to 1
Receive data register
full(1,5)
When receive data is transferred from in registers
ICDRS to ICDRR , this flag is set to 1
Transmit end(1,6)
When the 9th clock cycle of the SCL signal in the I2C
bus format occurs w hile the TDREbit is set to 1, this
flag is set to 1.
TEND
RW
This flag is set to 1 w hen the final bit of the transmit
frame is transmitted in the clock synchronous format.
Transmit data empty(1,6)
In the follow ing cases, this flag is set to 1.
• Data is transferred from registers ICDRT to ICDRS
and the ICDRT register is empty
• When setting the TRS bit in the ICCR1
register to 1 (transmit mode)
TDRE
RW
• When generating the start condition
(including retransmit)
• When changing from slave receive mode to
slave transmit mode
NOTES:
1. Each bit is set to 0 by reading 1 before w riting 0.
2. This flag is enabled in slave receive mode of the I2C bus format.
3. When tw o or more master devices attempt to occupy the bus at nearly the same time, if the I2C bus Interf ace
monitors the SDA pin and the data w hich the I2C bus Interface transmits is different, the AL flag is set to 1 and the
bus is occupied by the another master.
4. The NACKF bit is enabled w hen the ACKEbit in the ICIER register is set to 1 (w hen the receive acknow ledge bit is
set to 1, transfer is halted).
5. The RDRF bit is set to 0 w hen reading data from the ICDRR register.
6. Bits TEND and TDREare set to 0 w hen w riting data to the ICDRT register.
7. When accessing the ICSR register continuously, insert one or more NOPinstructions betw een the instructions to
access it.
Figure 16.28 ICSR Register
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16. Clock Synchronous Serial Interface
Slave Address Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00BDh
After Reset
00h
SAR
Bit Symbol
Bit Name
Function
RW
RW
Format select bit
0 : I2C bus format
FS
1 : Clock synchronous serial format
SVA0
SVA1
SVA2
SVA3
SVA4
SVA5
SVA6
Slave address 6 to 0
Set an address different from that of the other
slave devices w hich are connected to the I2C
bus. When the 7 high-order bits of the first
frame transmitted after the starting condition
match bits SVA0 to SVA6 in slave mode of the
I2C bus format, the MCU operates as a slave
device.
RW
RW
RW
RW
RW
RW
RW
IIC bus Transmit Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
ICDRT
Address
00BEh
After Reset
FFh
Function
RW
RW
Store transmit data
When it is detected that the ICDRS register is empty, the stored transmit data item is
transferred to the ICDRS register and data transmission starts.
When the next transmit data item is w ritten to the ICDRT register during transmission of the
data in the ICDRS register, continuous transmit is enabled. When the MLS bit in the ICMR
register is set to 1 (data transferred LSB-first) and after the data is w ritten to the ICDRT
register, the MSB-LSB inverted data is read.
IIC bus Receive Data Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
ICDRR
Address
00BFh
After Reset
FFh
Function
RW
RO
Store receive data
When the ICDRS register receives 1 byte of data, the receive data is transferred to the ICDRR
register and the next receive operation is enabled.
IIC bus Shift Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
ICDRS
Function
RW
—
This register is used to transmit and receive data.
The transmit data is transferred from registers ICRDT to the ICDRS and data is transmitted
from the SDA pin w hen transmitting.
After 1 byte of data is received, data is transferred from registers ICDRS to ICDRR w hile
receiving.
Figure 16.29 Registers SAR, ICDRT, ICDRR, and ICDRS
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16. Clock Synchronous Serial Interface
Port Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
00F8h
After Reset
00h
PMR
Bit Symbol
Bit Name
Function
RW
RW
____
0 : P1_5, P1_7
1 : P3_6
INT1 pin select bit
INT1SEL
—
(b2-b1)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
SSI pin select bit
0 : P3_3
1 : P1_6
SSISEL
U1PINSEL
TXD1SEL
TXD1EN
IICSEL
RW
RW
RW
RW
RW
TXD1 pin sw itch bit(1)
Port/TXD1 pin sw itch bit(1)
TXD1/RXD1 select bit(1)
SSU / I2C bus pin sw itch bit
0 : P0_0
1 : P3_6, P3_7
0 : Programmable I/O port
1 : TXD1
0 : RXD1
1 : TXD1
0 : Selects SSU function
1 : Selects I2C bus function
NOTE:
1. The UART1 pins can be selected by using bits U1PINSEL, TXD1SEL and TXD1EN, and bits UART1SEL1 and
UART1SEL0 in the PINSR1 register.
Pin Function
PINSR1 Register
UART1SEL1,
PMR Register
U1PINSEL bit TXD1SEL bit
TXD1EN bit
UART1SEL0 bit
P3_7(TXD1)
P3_7(RXD1)
P0_0(TXD1)
P3_7(TXD1)
P4_5(RXD1)
P3_6(TXD1)
P3_6(RXD1)
P0_0(TXD1)
1
0
×
×
0
1
×
00b
01b
1
1
×
×
1
0
×
×
0
×
1
10b
×: 0 or 1
Figure 16.30 PMR Register
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16. Clock Synchronous Serial Interface
16.3.1 Transfer Clock
When the MST bit in the ICCR1 register is set to 0, the transfer clock is the external clock input from the SCL
pin. When the MST bit in the ICCR1 register is set to 1, the transfer clock is the internal clock selected by bits
CKS0 to CKS3 in the ICCR1 register and the transfer clock is output from the SCL pin.
Table 16.6 lists the Transfer Rate Examples.
Table 16.6
ICCR1 Register
CKS3 CKS2 CKS1 CKS0
Transfer Rate Examples
Transfer
Clock
Transfer Rate
f1 = 5 MHz f1 = 8 MHz f1 = 10 MHz f1 = 16 MHz f1 = 20 MHz
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
f1/28
f1/40
179 kHz
125 kHz
104 kHz
78.1 kHz
62.5 kHz
50.0 kHz
44.6 kHz
39.1 kHz
89.3 kHz
62.5 kHz
52.1 kHz
39.1 kHz
31.3 kHz
25.0 kHz
22.3 kHz
19.5 kHz
286 kHz
200 kHz
167 kHz
125 kHz
100 kHz
80.0 kHz
71.4 kHz
62.5 kHz
143 kHz
100 kHz
83.3 kHz
62.5 kHz
50.0 kHz
40.0 kHz
35.7 kHz
31.3 kHz
357 kHz
250 kHz
208 kHz
156 kHz
125 kHz
100 kHz
89.3 kHz
78.1 kHz
179 kHz
125 kHz
104 kHz
78.1 kHz
62.5 kHz
50.0 kHz
44.6 kHz
39.1 kHz
571 kHz
400 kHz
333 kHz
250 kHz
200 kHz
160 kHz
143 kHz
125 kHz
286 kHz
200 kHz
167 kHz
125 kHz
100 kHz
80.0 kHz
71.4 kHz
62.5 kHz
714 kHz
500 kHz
417 kHz
313 kHz
250 kHz
200 kHz
179 kHz
156 kHz
357 kHz
250 kHz
208 kHz
156 kHz
125 kHz
100 kHz
89.3 kHz
78.1 kHz
f1/48
f1/64
f1/80
f1/100
f1/112
f1/128
f1/56
1
f1/80
f1/96
f1/128
f1/160
f1/200
f1/224
f1/256
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16. Clock Synchronous Serial Interface
16.3.2 Interrupt Requests
2
2
The I C bus interface has six interrupt requests when the I C bus format is used and four interrupt requests
when the clock synchronous serial format is used.
2
Table 16.7 lists the Interrupt Requests of I C bus Interface.
2
Since these interrupt requests are allocated at the I C bus interface interrupt vector table, determining the source
bit by bit is necessary.
2
Table 16.7
Interrupt Requests of I C bus Interface
Interrupt Request
Generation Condition
Format
2
Clock
I C bus
Synchronous
Serial
Transmit data empty
TXI
TIE = 1 and TDRE = 1
TEIE = 1 and TEND = 1
RIE = 1 and RDRF = 1
STIE = 1 and STOP = 1
NAKIE = 1 and AL = 1 (or
NAKIE = 1 and NACKF = 1)
Enabled
Enabled
Enabled
Enabled
Disabled
Disabled
Enabled
Transmit ends
TEI
Enabled
Enabled
Enabled
Enabled
Enabled
Receive data full
RXI
Stop condition detection
NACK detection
STPI
NAKI
Arbitration lost/overrun error
STIE, NAKIE, RIE, TEIE, TIE: Bits in ICIER register
AL, STOP, NACKF, RDRF, TEND, TDRE: Bits in ICSR register
2
When the generation conditions listed in Table 16.7 are met, an I C bus interface interrupt request is generated.
2
Set the interrupt generation conditions to 0 by the I C bus interface interrupt routine. However, bits TDRE and
TEND are automatically set to 0 by writing transmit data to the ICDRT register and the RDRF bit is
automatically set to 0 by reading the ICDRR register. When writing transmit data to the ICDRT register, the
TDRE bit is set to 0. When data is transferred from registers ICDRT to ICDRS, the TDRE bit is set to 1 and by
further setting the TDRE bit to 0, 1 additional byte may be transmitted.
Set the STIE bit to 1 (enable stop condition detection interrupt request) when the STOP bit is set to 0.
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16. Clock Synchronous Serial Interface
2
16.3.3 I C bus Interface Mode
2
16.3.3.1 I C bus Format
2
Setting the FS bit in the SAR register to 0 enable communication in I C bus format.
2
Figure 16.31 shows the I C bus Format and Bus Timing. The 1st frame following the start condition consists of
8 bits.
(1) I2C bus format
(a) I2C bus format (FS = 0)
S
1
SLA
7
R/W
1
A
1
DATA
n
A
1
A/A
1
P
1
Transfer bit count (n = 1 to 8)
1
m
Transfer frame count (m = from 1)
(b) I2C bus format (when start condition is retransmitted, FS = 0)
SLA
7
SLA
7
S
1
R/W
1
A
1
A/A
1
S
1
R/W
1
A
1
A/A
1
P
1
DATA
n1
DATA
n2
1
m2
1
m1
Upper: Transfer bit count (n1, n2 = 1 to 8)
Lower: Transfer frame count (m1, m2 = 1 or more)
(2) I2C bus timing
SDA
SCL
1 to 7
8
9
1 to 7
8
9
1 to 7
8
9
S
SLA
R/W
A
DATA
A
DATA
A
P
Explanation of symbols
S
: Start condition
The master device changes the SDA signal from “H” to “L” while the SCL signal is held “H”.
: Slave address
SLA
R/W : Indicates the direction of data transmit/receive
Data is transmitted from the slave device to the master device when R/W value is 1 and from the master device to the slave device when
R/W value is 0.
A
: Acknowledge
The receive device sets the SDA signal to “L”.
DATA : Transmit / receive data
P
: Stop condition
The master device changes the SDA signal from “L” to “H” while the SCL signal is held “H”.
2
Figure 16.31 I C bus Format and Bus Timing
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16. Clock Synchronous Serial Interface
16.3.3.2 Master Transmit Operation
In master transmit mode, the master device outputs the transmit clock and data, and the slave device returns an
acknowledge signal.
2
Figures 16.32 and 16.33 show the Operating Timing in Master Transmit Mode (I C bus Interface Mode).
The transmit procedure and operation in master transmit mode are as follows.
(1) Set the STOP bit in the ICSR register to 0 to reset it. Then set the ICE bit in the ICCR1 register to 1
(transfer operation enabled). Then set bits WAIT and MLS in the ICMR register and set bits CKS0 to
CKS3 in the ICCR1 register (initial setting).
(2) Read the BBSY bit in the ICCR2 register to confirm that the bus is free. Set bits TRS and MST in the
ICCR1 register to master transmit mode. The start condition is generated by writing 1 to the BBSY bit
and 0 to the SCP bit by the MOV instruction.
(3) After confirming that the TDRE bit in the ICSR register is set to 1 (data is transferred from registers
ICDRT to ICDRS), write transmit data to the ICDRT register (data in which a slave address and R/W
are indicated in the 1st byte). At this time, the TDRE bit is automatically set to 0, data is transferred
from registers ICDRT to ICDRS, and the TDRE bit is set to 1 again.
(4) When transmission of 1 byte of data is completed while the TDRE bit is set to 1, the TEND bit in the
ICSR register is set to 1 at the rise of the 9th transmit clock pulse. Read the ACKBR bit in the ICIER
register, and confirm that the slave is selected. Write the 2nd byte of data to the ICDRT register. Since
the slave device is not acknowledged when the ACKBR bit is set to 1, generate the stop condition. The
stop condition is generated by the writing 0 to the BBSY bit and 0 to the SCP bit by the MOV
instruction. The SCL signal is held “L” until data is available and the stop condition is generated.
(5) Write the transmit data after the 2nd byte to the ICDRT register every time the TDRE bit is set to 1.
(6) When writing the number of bytes to be transmitted to the ICDRT register, wait until the TEND bit is
set to 1 while the TDRE bit is set to 1. Or wait for NACK (the NACKF bit in the ICSR register is set to
1) from the receive device while the ACKE bit in the ICIER register is set to 1 (when the receive
acknowledge bit is set to 1, transfer is halted). Then generate the stop condition before setting bits
TEND and NACKF to 0.
(7) When the STOP bit in the ICSR register is set to 1, return to slave receive mode.
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16. Clock Synchronous Serial Interface
SCL
(master output)
1
2
3
4
5
6
7
8
9
1
2
SDA
(master output)
b4
b2
b0
b6
b6
b5
b1
b7
b7
b3
Slave address
R/W
SDA
(slave output)
A
1
TDRE bit in
ICSR register
0
1
TEND bit in
ICSR register
0
ICDRT register
ICDRS register
Address + R/W
Data 1
Data 2
Address + R/W
Data 1
(5) Data write to ICDRT
register (3rd byte)
(2) Instruction of
start condition
generation
Processing
by program
(3) Data write to ICDRT
register (1st byte)
(4) Data write to ICDRT
register (2nd byte)
2
Figure 16.32 Operating Timing in Master Transmit Mode (I C bus Interface Mode) (1)
SCL
(master output)
9
1
2
3
4
5
6
7
8
9
SDA
(master output)
b4
b6
b5
b2
b1
b0
b7
b3
SDA
(slave output)
A
A/A
1
0
1
0
TDRE bit in
ICSR register
TEND bit in
ICSR register
ICDRT register
ICDRS register
Data n
Data n
Processing
by program
(3) Data write to ICDRT
register
(6) Generate stop condition and
set TEND bit to 0
(7) Set to slave receive mode
2
Figure 16.33 Operating Timing in Master Transmit Mode (I C bus Interface Mode) (2)
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16. Clock Synchronous Serial Interface
16.3.3.3 Master Receive Operation
In master receive mode, the master device outputs the receive clock, receives data from the slave device, and
returns an acknowledge signal.
2
Figures 16.34 and 16.35 show the Operating Timing in Master Receive Mode (I C bus Interface Mode).
The receive procedure and operation in master receive mode are shown below.
(1) After setting the TEND bit in the ICSR register to 0, switch from master transmit mode to master
receive mode by setting the TRS bit in the ICCR1 register to 0. Also, set the TDRE bit in the ICSR
register to 0.
(2) When performing the dummy read of the ICDRR register and starting the receive operation, the receive
clock is output in synchronization with the internal clock and data is received. The master device
outputs the level set by the ACKBT bit in the ICIER register to the SDA pin at the rising edge of the 9th
clock cycle of the receive clock.
(3) The 1-frame data receive is completed and the RDRF bit in the ICSR register is set to 1 at the rise of the
9th clock cycle. At this time, when reading the ICDRR register, the received data can be read and the
RDRF bit is set to 0 simultaneously.
(4) Continuous receive operation is enabled by reading the ICDRR register every time the RDRF bit is set
to 1. If the 8th clock cycle falls after the ICDRR register is read by another process while the RDRF bit
is set to 1, the SCL signal is fixed “L” until the ICDRR register is read.
(5) If the next frame is the last receive frame and the RCVD bit in the ICCR1 register is set to 1 (disables
the next receive operation) before reading the ICDRR register, stop condition generation is enabled after
the next receive operation.
(6) When the RDRF bit is set to 1 at the rise of the 9th clock cycle of the receive clock, generate the stop
condition.
(7) When the STOP bit in the ICSR register is set to 1, read the ICDRR register and set the RCVD bit to 0
(maintain the following receive operation).
(8) Return to slave receive mode.
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16. Clock Synchronous Serial Interface
Master transmit mode
SCL
Master receive mode
9
1
2
3
4
5
6
7
8
9
1
(master output)
SDA
(master output)
A
SDA
(slave output)
b7
b0
A
b6
b4
b2
b1
b5
b3
b7
1
TDRE bit in
ICSR register
0
1
TEND bit in
ICSR register
0
1
TRS bit in
ICCR1 register
0
1
RDRF bit in
ICSR register
0
ICDRS register
ICDRR register
Data 1
Data 1
Processing
by program
(1) Set TEND and TRS bits to 0 before
setting TDRE bits to 0
(2) Read ICDRR register
(3) Read ICDRR register
2
Figure 16.34 Operating Timing in Master Receive Mode (I C bus Interface Mode) (1)
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16. Clock Synchronous Serial Interface
SCL
(master output)
9
1
2
3
4
5
6
7
8
9
SDA
(master output)
A
A/A
SDA
(slave output)
b0
b6
b4
b2
b1
b5
b3
b7
1
0
1
0
RDRF bit in
ICSR register
RCVD bit in
ICCR1 register
Data n-1
ICDRS register
ICDRR register
Data n
Data n-1
Data n
(6) Stop condition
generation
Processing
by program
(5) Set RCVD bit to 1 before
reading ICDRR register
(7) Read ICDRR register before
setting RCVD bit to 0
(8) Set to slave receive mode
2
Figure 16.35 Operating Timing in Master Receive Mode (I C bus Interface Mode) (2)
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16. Clock Synchronous Serial Interface
16.3.3.4 Slave Transmit Operation
In slave transmit mode, the slave device outputs the transmit data while the master device outputs the receive
clock and returns an acknowledge signal.
2
Figures 16.36 and 16.37 show the Operating Timing in Slave Transmit Mode (I C bus Interface Mode).
The transmit procedure and operation in slave transmit mode are as follows.
(1) Set the ICE bit in the ICCR1 register to 1 (transfer operation enabled). Set bits WAIT and MLS in the
ICMR register and bits CKS0 to CKS3 in the ICCR1 register (initial setting). Set bits TRS and MST in
the ICCR1 register to 0 and wait until the slave address matches in slave receive mode.
(2) When the slave address matches at the 1st frame after detecting the start condition, the slave device
outputs the level set by the ACKBT bit in the ICIER register to the SDA pin at the rise of the 9th clock
cycle. At this time, if the 8th bit of data (R/W) is 1, bits TRS and TDRE in the ICSR register are set to 1,
and the mode is switched to slave transmit mode automatically. Continuous transmission is enabled by
writing transmit data to the ICDRT register every time the TDRE bit is set to 1.
(3) When the TDRE bit in the ICDRT register is set to 1 after writing the last transmit data to the ICDRT
register, wait until the TEND bit in the ICSR register is set to 1 while the TDRE bit is set to 1. When the
TEND bit is set to 1, set the TEND bit to 0.
(4) The SCL signal is released by setting the TRS bit to 0 and performing a dummy read of the ICDRR
register to end the process.
(5) Set the TDRE bit to 0.
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16. Clock Synchronous Serial Interface
Slave receive mode
SCL
Slave transmit mode
9
1
2
3
4
5
6
7
8
9
1
(master output)
SDA
(master output)
A
SCL
(slave output)
SDA
(slave output)
b7
b0
b6
b4
b2
b1
b5
b3
A
b7
1
0
1
0
TDRE bit in
ICSR register
TEND bit in
ICSR register
1
0
TRS bit in
ICCR1 register
ICDRT register
ICDRS register
ICDRR register
Data 1
Data 3
Data 2
Data 1
Data 2
(2) Data write to ICDRT
register (data 3)
(2) Data write to ICDRT
register (data 2)
(1) Data write to ICDRT
register (data 1)
Processing
by program
2
Figure 16.36 Operating Timing in Slave Transmit Mode (I C bus Interface Mode) (1)
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16. Clock Synchronous Serial Interface
Slave receive
mode
Slave transmit mode
SCL
(master output)
9
1
2
3
4
5
6
7
8
9
SDA
(master output)
A
A
SCL
(slave output)
SDA
(slave output)
b4
b2
b0
b6
b5
b1
b7
b3
1
TDRE bit in
ICSR register
0
1
TEND bit in
ICSR register
0
1
TRS bit in
ICCR1 register
0
Data n
ICDRT register
Data n
ICDRS register
ICDRR register
Processing
by program
(3) Set the TEND bit to 0
(4) Dummy read of ICDRR register
after setting TRS bit to 0
(5) Set TDRE bit to 0
2
Figure 16.37 Operating Timing in Slave Transmit Mode (I C bus Interface Mode) (2)
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16. Clock Synchronous Serial Interface
16.3.3.5 Slave Receive Operation
In slave receive mode, the master device outputs the transmit clock and data, and the slave device returns an
acknowledge signal.
2
Figures 16.38 and 16.39 show the Operating Timing in Slave Receive Mode (I C bus Interface Mode).
The receive procedure and operation in slave receive mode are as follows.
(1) Set the ICE bit in the ICCR1 register to 1 (transfer operation enabled). Set bits WAIT and MLS in the
ICMR register and bits CKS0 to CKS3 in the ICCR1 register (initial setting). Set bits TRS and MST in
the ICCR1 register to 0 and wait until the slave address matches in slave receive mode.
(2) When the slave address matches at the 1st frame after detecting the start condition, the slave device
outputs the level set in the ACKBT bit in the ICIER register to the SDA pin at the rise of the 9th clock
cycle. Since the RDRF bit in the ICSR register is set to 1 simultaneously, perform the dummy-read (the
read data is unnecessary because it indicates the slave address and R/W).
(3) Read the ICDRR register every time the RDRF bit is set to 1. If the 8th clock cycle falls while the
RDRF bit is set to 1, the SCL signal is fixed “L” until the ICDRR register is read. The setting change of
the acknowledge signal returned to the master device before reading the ICDRR register takes affect
from the following transfer frame.
(4) Reading the last byte is performed by reading the ICDRR register in like manner.
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16. Clock Synchronous Serial Interface
SCL
(master output)
9
1
2
3
4
5
6
7
8
9
1
SDA
(master output)
b7
b0
b6
b4
b2
b1
b5
b3
b7
SCL
(slave output)
SDA
(slave output)
A
A
1
RDRF bit in
ICSR register
0
ICDRS register
Data 1
Data 2
ICDRR register
Processing
Data 1
(2) Dummy read of ICDRR register
(2) Read ICDRR register
by program
2
Figure 16.38 Operating Timing in Slave Receive Mode (I C bus Interface Mode) (1)
SCL
(master output)
9
1
2
3
4
5
6
7
8
9
SDA
(master output)
b0
b6
b4
b2
b1
b5
b3
b7
SCL
(slave output)
SDA
(slave output)
A
A
1
0
RDRF bit in
ICSR register
ICDRS register
ICDRR register
Data 1
Data 2
Data 1
Processing
by program
(3) Set ACKBT bit to 1
(3) Read ICDRR register
(4) Read ICDRR register
2
Figure 16.39 Operating Timing in Slave Receive Mode (I C bus Interface Mode) (2)
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16. Clock Synchronous Serial Interface
16.3.4 Clock Synchronous Serial Mode
16.3.4.1 Clock Synchronous Serial Format
Set the FS bit in the SAR register to 1 to use the clock synchronous serial format for communication.
Figure 16.40 shows the Transfer Format of Clock Synchronous Serial Format.
When the MST bit in the ICCR1 register is set to 1, the transfer clock is output from the SCL pin, and when the
MST bit is set to 0, the external clock is input.
The transfer data is output between successive falling edges of the SCL clock, and data is determined at the
rising edge of the SCL clock. MSB-first or LSB-first can be selected as the order of the data transfer by setting
the MLS bit in the ICMR register. The SDA output level can be changed by the SDAO bit in the ICCR2 register
during transfer standby.
SCL
SDA
b0
b1
b2
b3
b4
b5
b6
b7
Figure 16.40 Transfer Format of Clock Synchronous Serial Format
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16. Clock Synchronous Serial Interface
16.3.4.2 Transmit Operation
In transmit mode, transmit data is output from the SDA pin in synchronization with the falling edge of the
transfer clock. The transfer clock is output when the MST bit in the ICCR1 register is set to 1 and input when
the MST bit is set to 0.
Figure 16.41 shows the Operating Timing in Transmit Mode (Clock Synchronous Serial Mode).
The transmit procedure and operation in transmit mode are as follows.
(1) Set the ICE bit in the ICCR1 register to 1 (transfer operation enabled). Set bits CKS0 to CKS3 in the
ICCR1 register and set the MST bit (initial setting).
(2) The TDRE bit in the ICSR register is set to 1 by selecting transmit mode after setting the TRS bit in the
ICCR1 register to 1.
(3) Data is transferred from registers ICDRT to ICDRS and the TDRE bit is automatically set to 1 by
writing transmit data to the ICDRT register after confirming that the TDRE bit is set to 1. Continuous
transmission is enabled by writing data to the ICDRT register every time the TDRE bit is set to 1. When
switching from transmit to receive mode, set the TRS bit to 0 while the TDRE bit is set to 1.
SCL
1
2
7
8
1
7
8
1
SDA
(output)
b0
b1
b6
b7
b0
b6
b7
b0
1
0
1
TRS bit in
ICCR1 register
TDRE bit in
ICSR register
0
ICDRT register
ICDRS register
Data 1
Data 2
Data 3
Data 1
Data 3
Data 2
(3) Data write to
ICDRT register
(3) Data write to
ICDRT register
(3) Data write to
ICDRT register
(3) Data write to
ICDRT register
Processing
by program
(2) Set TRS bit to 1
Figure 16.41 Operating Timing in Transmit Mode (Clock Synchronous Serial Mode)
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16. Clock Synchronous Serial Interface
16.3.4.3 Receive Operation
In receive mode, data is latched at the rising edge of the transfer clock. The transfer clock is output when the
MST bit in the ICCR1 register is set to 1 and input when the MST bit is set to 0.
Figure 16.42 shows the Operating Timing in Receive Mode (Clock Synchronous Serial Mode).
The receive procedure and operation in receive mode are as follows.
(1) Set the ICE bit in the ICCR1 register to 1 (transfer operation enabled). Set bits CKS0 to CKS3 in the
ICCR1 register and set the MST bit (initial setting).
(2) The output of the receive clock starts when the MST bit is set to 1 while the transfer clock is being
output.
(3) Data is transferred from registers ICDRS to ICDRR and the RDRF bit in the ICSR register is set to 1,
when the receive operation is completed. Since the next byte of data is enabled when the MST bit is set
to 1, the clock is output continuously. Continuous receive is enabled by reading the ICDRR register
every time the RDRF bit is set to 1. An overrun is detected at the rise of the 8th clock cycle while the
RDRF bit is set to 1, and the AL bit in the ICSR register is set to 1. At this time, the last receive data is
retained in the ICDRR register.
(4) When the MST bit is set to 1, set the RCVD bit in the ICCR1 register to 1 (disables the next receive
operation) and read the ICDRR register. The SCL signal is fixed “H” after reception of the following
byte of data is completed.
SCL
1
2
7
8
1
7
8
1
2
SDA
(input)
b0
b1
b6
b7
b0
b6
b7
b0
1
0
MST bit in
ICCR1 register
1
0
1
TRS bit in
ICCR1 register
RDRF bit in
ICSR register
0
Data 1
Data 2
Data 3
ICDRS register
ICDRR register
Data 1
Data 2
Processing
by program
(2) Set MST bit to 1
(when transfer clock is output)
(3) Read ICDRR register
(3) Read ICDRR register
Figure 16.42 Operating Timing in Receive Mode (Clock Synchronous Serial Mode)
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16. Clock Synchronous Serial Interface
16.3.5 Noise Canceller
The states of pins SCL and SDA are routed through the noise canceller before being latched internally.
Figure 16.43 shows a Block Diagram of Noise Canceller.
The noise canceller consists of two cascaded latch and match detector circuits. When the SCL pin input signal
(or SDA pin input signal) is sampled on f1 and two latch outputs match, the level is passed forward to the next
circuit. When they do not match, the former value is retained.
f1 (sampling clock)
C
C
SCL or SDA
input signal
Match
detection
circuit
D
Q
D
Q
Internal SCL
or SDA signal
Latch
Latch
Period of f1
f1 (sampling clock)
Figure 16.43 Block Diagram of Noise Canceller
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16. Clock Synchronous Serial Interface
16.3.6 Bit Synchronization Circuit
2
When setting the I C bus interface to master mode, the high-level period may become shorter in the following
two cases:
• If the SCL signal is driven L level by a slave device
• If the rise speed of the SCL signal is reduced by a load (load capacity or pull-up resistor) on the SCL line.
Therefore, the SCL signal is monitored and communication is synchronized bit by bit.
Figure 16.44 shows the Timing of Bit Synchronization Circuit and Table 16.8 lists the Time between Changing
SCL Signal from “L” Output to High-Impedance and Monitoring of SCL Signal.
Reference clock of
SCL monitor timing
SCL
VIH
Internal SCL
Figure 16.44 Timing of Bit Synchronization Circuit
Table 16.8
Time between Changing SCL Signal from “L” Output to High-Impedance and
Monitoring of SCL Signal
ICCR1 Register
Time for Monitoring SCL
7.5Tcyc
CKS3
CKS2
0
0
1
0
1
19.5Tcyc
17.5Tcyc
41.5Tcyc
1
1Tcyc = 1/f1(s)
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16. Clock Synchronous Serial Interface
16.3.7 Examples of Register Setting
2
Figures 16.45 to 16.48 show Examples of Register Setting When Using I C bus interface.
Start
•
•
Set the STOP bit in the ICSR register to 0
Set the IICSEL bit in the PMR register to 1
Initial setting
Read BBSY bit in ICCR2 register
(1) Judge the state of the SCL and SDA lines
(2) Set to master transmit mode
(1)
No
BBSY = 0 ?
(3) Generate the start condition
Yes
(4) Set the transmit data of the 1st byte
(slave address + R/W)
ICCR1 register TRS bit ← 1
MST bit ← 1
(2)
(3)
(4)
(5) Wait for 1 byte to be transmitted
ICCR2 register SCP bit ← 0
BBSY bit ← 1
(6) Judge the ACKBR bit from the specified slave device
(7) Set the transmit data after 2nd byte (except the last byte)
(8) Wait until the ICRDT register is empty
(9) Set the transmit data of the last byte
(10) Wait for end of transmission of the last byte
(11) Set the TEND bit to 0
Write transmit data to ICDRT register
Read TEND bit in ICSR register
(5)
(6)
No
TEND = 1 ?
Yes
(12) Set the STOP bit to 0
Read ACKBR bit in ICIER register
(13) Generate the stop condition
No
(14) Wait until the stop condition is generated
ACKBR = 0 ?
(15) Set to slave receive mode
Set the TDRE bit to 0
Yes
Master receive
mode
Transmit
mode ?
No
Yes
(7)
(8)
Write transmit data to ICDRT register
Read TDRE bit in ICSR register
No
TDRE = 1 ?
Yes
No
Last byte ?
(9)
Yes
Write transmit data to ICDRT register
Read TEND bit in ICSR register
(10)
No
TEND = 1 ?
Yes
(11)
(12)
ICSR register
ICSR register
TEND bit ← 0
STOP bit ← 0
ICCR2 register SCP bit ← 0
BBSY bit ← 0
(13)
Read STOP bit in ICSR register
(14)
No
STOP = 1 ?
Yes
ICCR1 register TRS bit ← 0
MST bit ← 0
(15)
ICSR register TDRE bit ← 0
End
2
Figure 16.45 Example of Register Setting in Master Transmit Mode (I C bus Interface Mode)
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16. Clock Synchronous Serial Interface
Master receive mode
(1) Set the TEND bit to 0 and set to master receive mode.
Set the TDRE bit to 0(1,2)
ICSR register
ICCR1 register
ICSR register
TEND bit ← 0
TRS bit ← 0
TDRE bit ← 0
(2) Set the ACKBT bit to the transmit device(1)
(3) Dummy read the ICDRR register(1)
(4) Wait for 1 byte to be received
(5) Judge (last receive - 1)
(1)
ICIER register ACKBT bit ← 0
(2)
(3)
Dummy read in ICDRR register
(6) Read the receive data
(7) Set the ACKBT bit of the last byte and set to disable
continuous receive operation (RCVD = 1)(2)
Read RDRF bit in ICSR register
(4)
(8) Read the receive data of (last byte - 1)
(9) Wait until the last byte is received
(10) Set the STOP bit to 0
No
RDRF = 1 ?
Yes
Yes
Last receive
- 1 ?
(11) Generate the stop condition
(12) Wait until the stop condition is generated
(13) Read the receive data of the last byte
(14) Set the RCVD bit to 0
(5)
(6)
No
Read ICDRR register
ICIER register ACKBT bit ← 1
ICCR1 register RCVD bit ← 1
Read ICDRR register
(15) Set to slave receive mode
(7)
(8)
Read RDRF bit in ICSR register
(9)
No
RDRF = 1 ?
Yes
ICSR register
STOP bit ← 0
(10)
(11)
ICCR2 register
SCP bit ← 0
BBSY bit ← 0
Read STOP bit in ICSR register
(12)
(13)
No
STOP = 1 ?
Yes
Read ICDRR register
ICCR1 register
ICCR1 register
RCVD bit ← 0
MST bit ← 0
(14)
(15)
End
NOTES:
1. Do not generate the interrupt while processing steps (1) to (3).
2. When receiving 1 byte, skip steps (2) to (6) after (1) and jump to process of step (7).
processing of step (8) is dummy read of the ICDRR register.
2
Figure 16.46 Example of Register Setting in Master Receive Mode (I C bus Interface Mode)
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16. Clock Synchronous Serial Interface
Slave transmit mode
ICSR register AAS bit ← 0
(1) Set the AAS bit to 0
(1)
(2)
(2) Set the transmit data (except the last byte)
(3) Wait until the ICRDT register is empty
(4) Set the transmit data of the last byte
(5) Wait until the last byte is transmitted
(6) Set the TEND bit to 0
Write transmit data to ICDRT register
Read TDRE bit in ICSR register
(3)
(4)
TDRE = 1 ?
No
(7) Set to slave receive mode
Yes
(8) Dummy read the ICDRR register to release the
SCL signal
No
Last byte ?
(9) Set the TDRE bit to 0
Yes
Write transmit data to ICDRT register
Read TEND bit in ICSR register
No
(5)
TEND = 1 ?
Yes
ICSR register
TEND bit ← 0
(6)
(7)
ICCR1 register
TRS bit ← 0
Dummy read in ICDRR register
(8)
(9)
ICSR register
TDRE bit ← 0
End
2
Figure 16.47 Example of Register Setting in Slave Transmit Mode (I C bus Interface Mode)
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16. Clock Synchronous Serial Interface
Slave receive mode
ICSR register AAS bit ← 0
(1) Set the AAS bit to 0(1)
(1)
(2)
(3)
(2) Set the ACKBT bit to the transmit device
(3) Dummy read the ICDRR register
(4) Wait until 1 byte is received
ICIER register ACKBT bit ← 0
Dummy read ICDRR register
(5) Judge (last receive - 1)
Read RDRF bit in ICSR register
(6) Read the receive data
(7) Set the ACKBT bit of the last byte(1)
(8) Read the receive data of (last byte - 1)
(4)
No
RDRF = 1 ?
Yes
(9) Wait until the last byte is received
Yes
Last receive
(10) Read the receive data of the last byte
(5)
(6)
- 1 ?
No
Read ICDRR register
ICIER register ACKBT bit ← 1
(7)
(8)
Read ICDRR register
Read RDRF bit in ICSR register
(9)
No
RDRF = 1 ?
Yes
(10)
Read ICDRR register
End
NOTE:
1. When receiving 1 byte, skip steps (2) to (6) after (1) and jump to processing step (7).
Processing step (8) is dummy read of the ICDRR register.
2
Figure 16.48 Example of Register Setting in Slave Receive Mode (I C bus Interface Mode)
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16. Clock Synchronous Serial Interface
2
16.3.8 Notes on I C bus Interface
2
2
Set the IICSEL bit in the PMR register to 1 (select I C bus interface function) to use the I C bus interface.
16.3.8.1 Multimaster Operation
2
The following actions must be performed to use the I C bus interface in multimaster operation.
• Transfer rate
Set the transfer rate by 1/1.8 or faster than the fastest rate of the other masters. For example, if the fastest
2
transfer rate of the other masters is set to 400 kbps, the I C-bus transfer rate in this MCU should be set to
223 kbps (= 400/1.18) or more.
• Bits MST and TRS in the ICCR1 register setting
(a) Use the MOV instruction to set bits MST and TRS.
(b) When arbitration is lost, confirm the contents of bits MST and TRS. If the contents are other than the
MST bit set to 0 and the TRS bit set to 0 (slave receive mode), set the MST bit to 0 and the TRS bit to 0
again.
16.3.8.2 Master Receive Mode
2
Either of the following actions must be performed to use the I C bus interface in master receive mode.
(a) In master receive mode while the RDRF bit in the ICSR register is set to 1, read the ICDRR register
before the rising edge of the 8th clock.
(b) In master receive mode, set the RCVD bit in the ICCR1 register to 1 (disables the next receive
operation) to perform 1-byte communications.
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17. Hardware LIN
17. Hardware LIN
The hardware LIN performs LIN communication in cooperation with timer RA and UART0.
17.1 Features
The hardware LIN has the features listed below.
Figure 17.1 shows a Block Diagram of Hardware LIN.
Master mode
• Generates Synch Break
• Detects bus collision
Slave mode
• Detects Synch Break
• Measures Synch Field
• Controls Synch Break and Synch Field signal inputs to UART0
• Detects bus collision
NOTE:
1. The WakeUp function is detected by INT1.
Hardware LIN
Synch Field
RXD0 pin
control
circuit
Timer RA
TIOSEL = 0
TIOSEL = 1
RXD data
Timer RA
RXD0 input
control
LSTART bit
SBE bit
underflow signal
Timer RA
interrupt
circuit
LINE bit
Interrupt
control
circuit
Bus collision
detection
circuit
UART0
BCIE, SBIE,
and SFIE bits
UART0 transfer clock
UART0 TE bit
Timer RA output pulse
MST bit
UART0 TXD data
TXD0 pin
LINE, MST, SBE, LSTART, BCIE, SBIE, SFIE: Bits in LINCR register
TIOSEL: Bit in TRAIOC register
TE: Bit in U0C1 register
Figure 17.1
Block Diagram of Hardware LIN
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17. Hardware LIN
17.2 Input/Output Pins
The pin configuration of the hardware LIN is listed in Table 17.1.
Table 17.1
Pin Configuration
Abbreviation Input/Output
Name
Function
Receive data input
RXD0
TXD0
Input
Receive data input pin of the hardware LIN
Transmit data output pin of the hardware LIN
Transmit data output
Output
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17. Hardware LIN
17.3 Register Configuration
The hardware LIN contains the registers listed below.
These registers are detailed in Figures 17.2 and 17.3.
• LIN Control Register (LINCR)
• LIN Status Register (LINST)
LIN Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
LINCR
Address
0106h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
Synch Field measurement-
completed interrupt enable bit
0 : Disables Synch Field measurement-
completed interrupt
1 : Enables Synch Field measurement-
completed interrupt
SFIE
Synch Break detection interrupt 0 : Disables Synch Break detection interrupt
enable bit 1 : Enables Synch Break detection interrupt
Bus collision detection interrupt 0 : Disables bus collision detection interrupt
SBIE
BCIE
RW
RW
RO
enable bit
1 : Enables bus collision detection interrupt
RXD0 input status flag
0 : RXD0 input enabled
1 : RXD0 input disabled
RXDSF
Synch Break detection start bit(1) When this bit is set to 1, timer RA input is
enabled and RXD0 input is disabled.
LSTART
SBE
RW
RW
When read, the content is 0.
RXD0 input unmasking timing
select bit (effective only in slave 1 : Unmasked after Synch Field measurement
mode) is completed
0 : Unmasked after Synch Break is detected
LIN operation mode setting bit(2) 0 : Slave mode
(Synch Break detection circuit actuated)
MST
LINE
RW
RW
1 : Master mode
(Timer RA output OR’ed w ith TXD0)
LIN operation start bit
0 : Causes LIN to stop
1 : Causes LIN to start operating(3)
NOTES:
1. After setting the LSTART bit, confirm that the RXDSF flag is set to 1 before Synch Break input starts.
2. Before changing LIN operation modes, temporarily stop the LIN operation (LINEbit = 0).
3. Inputs to timer RA and UART0 are prohibited immediately after this bit is set to 1. (Refer to
Figure 17.5 Example of
and
Header Field Transmission Flowchart (1)
.)
Figure 17.9 Example of Header Field Reception Flowchart
(2)
Figure 17.2
LINCR Register
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17. Hardware LIN
LIN Status Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
0107h
After Reset
00h
LINST
Bit Symbol
Bit Name
Synch Field measurement-
completed flag
Function
RW
1 show s Synch Field measurement completed.
SFDCT
SBDCT
BCDCT
B0CLR
B1CLR
B2CLR
RO
RO
RO
RW
RW
RW
—
Synch Break detection flag 1 show s Synch Break detected or Synch Break
generation completed.
Bus collision detection flag
1 show s Bus collision detected.
SFDCT bit clear bit
When this bit is set to 1, the SFDCT bit is set to 0.
When read, the content is 0.
SBDCT bit clear bit
When this bit is set to 1, the SBDCT bit is set to 0.
When read, the content is 0.
BCDCT bit clear bit
When this bit is set to 1, the BCDCT bit is set to 0.
When read, the content is 0.
—
(b7-b6)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
Figure 17.3
LINST Register
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17. Hardware LIN
17.4 Functional Description
17.4.1 Master Mode
Figure 17.4 shows typical operation of the hardware LIN when transmitting a header field in master mode.
Figures 17.5 and 17.6 show an Example of Header Field Transmission Flowchart.
When transmitting a header field, the hardware LIN operates as described below.
(1) When the TSTART bit in the TRACR register for timer RA is set by writing 1 in software, the hardware
LIN outputs “L” level from the TXD0 pin for the period that is set in registers TRAPRE and TRA for
timer RA.
(2) When timer RA underflows upon reaching the terminal count, the hardware LIN reverses the output of
the TXD0 pin and sets the SBDCT flag in the LINST register to 1. Furthermore, if the SBIE bit in the
LINCR register is set to 1, it generates a timer RA interrupt.
(3) The hardware LIN transmits 55h via UART0.
(4) The hardware LIN transmits an ID field via UART0 after it finishes sending 55h.
(5) The hardware LIN performs communication for a response field after it finishes sending the ID field.
Synch Break
Synch Field
IDENTIFIER
1
0
TXD0 pin
Set by writing 1 to the
B1CLR bit in the LINST
register
SBDCT flag in the
LINST register
1
0
Cleared to 0 upon
acceptance of interrupt
request or by a program
IR bit in the TRAIC
register
1
0
(1)
(2) (3)
(4)
(5)
Shown above is the case where
LINE = 1, MST = 1, SBIE = 1
Figure 17.4
Typical Operation when Sending a Header Field
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Timer RA Set to timer mode
17. Hardware LIN
Bits TMOD0 to TMOD2 in TRAMR register ← 000b
Timer RA Set the pulse output level from low to start
TEDGSEL bit in TRAIOC register ← 1
For the hardware LIN
function, set the TIOSEL bit
in the TRAIOC register to 1.
Timer RA Set the INT1/TRAIO pin to P1_5
TIOSEL bit in TRAIOC register ← 1
Timer RA Set the count source (f1, f2, f8, fOCO)
Bits TCK0 to TCK2 in TRAMR register
Set the count source and
registers TRA and TRAPRE
as suitable for the Synch
Break period.
Timer RA Set the Synch Break width
TRAPRE register
TRA register
UART0 Set to transmit/receive mode
(Transfer data length: 8 bits, Internal clock, 1 stop bit,
Parity disabled)
U0MR register
UART0 Set the BRG count source (f1, f8, f32)
Bits CLK0 to CLK2 in U0C0 register
Set the BRG count source
and U0BRG register as
appropriate for the bit rate.
UART0 Set the bit rate
U0BRG register
Hardware LIN Set the LIN operation to stop
LINCR register LINE bit ← 0
Hardware LIN Set to master mode
MST bit in LINCR register ← 1
Hardware LIN Set the LIN operation to start
LINE bit in LINCR register ← 1
Hardware LIN Set the register to enable interrupts
(Bus collision detection, Synch Break detection,
Synch Field measurement)
Bits BCIE, SBIE, SFIE in LINCR register
During master mode, the
Synch Field measurement-
completed interrupt cannot be
used.
Hardware LIN Clear the status flags
(Bus collision detection, Synch Break detection,
Synch Field measurement)
Bits B2CLR, B1CLR, B0CLR in LINST register ← 1
A
Figure 17.5
Example of Header Field Transmission Flowchart (1)
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17. Hardware LIN
A
Timer RA generates Synch Break.
Timer RA Set the timer to start counting
TSTART bit in TRACR register ← 1
If registers TRAPRE and TRA for
timer RA do not need to be read or
the register settings do not need to be
changed after writing 1 to the
TSTART bit, the procedure for reading
TCSTF flag = 1 can be omitted.
Zero to one cycle of the timer RA
count source is required after timer
RA starts counting before the TCSTF
flag is set to 1.
Timer RA Read the count status flag
TCSTF flag in TRACR register
NO
TCSTF = 1 ?
YES
The timer RA interrupt may be used
to terminate generation of Synch
Break.
Hardware LIN Read the Synch Break detection flag
SBDCT flag in LINST register
One to two cycles of the CPU clock
are required after Synch Break
generation completes before the
SBDCT flag is set to 1.
NO
SBDCT = 1 ?
YES
After timer RA Synch Break is
generated, the timer should be made
to stop counting.
Timer RA Set the timer to stop counting
TSTART bit in TRACR register ← 0
If registers TRAPRE and TRA for timer
RA do not need to be read or the
register settings do not need to be
changed after writing 0 to the TSTART
bit, the procedure for reading TCSTF
flag = 0 can be omitted.
Zero to one cycle of the timer RA count
source is required after timer RA stops
counting before the TCSTF flag is set
to 0.
Timer RA Read the count status flag
TCSTF flag in TRACR register
NO
TCSTF = 0 ?
YES
UART0 Communication via UART0
TE bit in U0C1 register ← 1
U0TB register ← 0055h
Transmit the Synch Field.
UART0 Communication via UART0
Transmit the ID field.
U0TB register ← ID field
Figure 17.6
Example of Header Field Transmission Flowchart (2)
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17. Hardware LIN
17.4.2 Slave Mode
Figure 17.7 shows typical operation of the hardware LIN when receiving a header field in slave mode. Figure
17.8 through Figure 17.10 show an Example of Header Field Transmission Flowchart.
When receiving a header field, the hardware LIN operates as described below.
(1) Synch Break detection is enabled by writing 1 to the LSTART bit in the LINCR register of the hardware
LIN.
(2) When “L” level is input for a duration equal to or greater than the period set in timer RA, the hardware
LIN detects it as Synch Break. At this time, the SBDCT flag in the LINST register is set to 1.
Furthermore, if the SBIE bit in the LINCR register is set to 1, the hardware LIN generates a timer RA
interrupt. Then it goes to Synch Field measurement.
(3) The hardware LIN receives a Synch Field (55h). At this time, it measures the period of the start bit and
bits 0 to 6 by using timer RA. In this case, it is possible to select whether to input the Synch Field signal
to RXD0 of UART0 by setting the SBE bit in the LINCR register accordingly.
(4) The hardware LIN sets the SFDCT flag in the LINST register to 1 when it finishes measuring the Synch
Field. Furthermore, if the SFIE bit in the LINCR register is set to 1, it generates a timer RA interrupt.
(5) After it finishes measuring the Synch Field, calculate a transfer rate from the count value of timer RA
and set to UART0 and registers TRAPRE and TRA of timer RA again. Then it receives an ID field via
UART0.
(6) The hardware LIN performs communication for a response field after it finishes receiving the ID field.
Synch Break
Synch Field
IDENTIFIER
1
0
RXD0 pin
RXD0 input for
UART0
1
0
Set by writing 1 to
the LSTART bit in
the LINCR register
Cleared to 0 when Synch
Field measurement
finishes
RXDSF flag in the
LINCR register
1
0
Set by writing 1 to
the B1CLR bit in
the LINST register
SBDCT flag in the
LINST register
1
0
Set by writing 1 to the
B0CLR bit in the LINST
register
Measure this period
SFDCT flag in the
LINST register
1
0
Cleared to 0 upon
acceptance of
interrupt request or
by a program
IR bit in the TRAIC
register
1
0
(1)
(2) (3)
(4)
(5)
(6)
Shown above is the case where
LINE = 1, MST = 0, SBE = 1, SBIE = 1, SFIE = 1
Figure 17.7
Typical Operation when Receiving a Header Field
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17. Hardware LIN
Timer RA Set to pulse width measurement mode
Bits TMOD0 to TMOD2 in the TRAMR register ← 011b
Timer RA Set the pulse width measurement level low
TEDGSEL bit in the TRAIOC register ← 0
For the hardware LIN
function, set the TIOSEL bit
in the TRAIOC register to 1.
Timer RA Set the INT1/TRAIO pin to P1_5
TIOSEL bit in the TRAIOC register ← 1
Timer RA Set the count source (f1, f2, f8, fOCO)
Bits TCK0 to TCK2 in the TRAMR register
Set the count source and registers
TRA and TRAPRE as appropriate
for the Synch Break period.
Timer RA Set the Synch Break width
TRAPRE register
TRA register
Hardware LIN Set the LIN operation to stop
LINE bit in the LINCR register ← 0
Hardware LIN Set to slave mode
MST bit in the LINCR register ← 0
Hardware LIN Set the LIN operation to start
LINE bit in the LINCR register ← 1
Select the timing at which to
unmask the RXD0 input for UART0.
If the RXD0 input is chosen to be
unmasked after detection of Synch
Break, the Synch Field signal is
also input to UART0.
Hardware LIN Set the RXD0 input unmasking timing
(After Synch Break detection, or after Synch
Field measurement)
SBE bit in the LINCR register
Hardware LIN Set the register to enable interrupts
(Bus collision detection, Synch Break detection,
Synch Field measurement)
Bits BCIE, SBIE, SFIE in the LINCR register
A
Figure 17.8
Example of Header Field Reception Flowchart (1)
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17. Hardware LIN
A
Hardware LIN Clear the status flags
(Bus collision detection, Synch Break
detection, Synch Field measurement)
Bits B2CLR, B1CLR, B0CLR in the LINST
register ← 1
Timer RA waits until the timer starts
counting.
Timer RA Set to start a pulse width measurement
TSTART bit in the TRACR register ← 1
Timer RA Read the count status flag
TCSTF flag in the TRACR register
Zero to one cycle of the timer RA count
source is required after timer RA starts
counting before the TCSTF flag is set to
1.
NO
TCSTF = 1 ?
Hardware LIN waits until the RXD0
input for UART0 is masked.
Do not apply “L” level to the RXD pin
until the RXDSF flag reads 1 after
writing 1 to the LSTART bit. This is
because the signal applied during this
time is input directly to UART0.
One to two cycles of the CPU clock and
zero to one cycle of the timer RA count
source are required after the LSTART
bit is set to 1 before the RXDSF flag is
set to 1. After this, input to timer RA and
UART0 is enabled.
YES
Hardware LIN Set to start Synch Break detection
LSTART bit in the LINCR register ← 1
Hardware LIN Read the RXD0 input status flag
RXDSF flag in the LINCR register
NO
RXDSF = 1 ?
YES
Hardware LIN detects a Synch Break.
The interrupt of the timer RA may be
used.
Hardware LIN Read the Synch Break detection flag
SBDCT flag in the LINST register
When Synch Break is detected, timer
RA is reloaded with the initially set count
value.
Even if the duration of the input “L” level
is shorter than the set period, timer RA
is reloaded with the initially set count
value and waits until the next “L” level is
input.
NO
SBDCT = 1 ?
YES
B
One to two cycles of the CPU clock are
required after Synch Break detection
before the SBDCT flag is set to 1.
When the SBE bit in the LINCR register
is set to 0 (unmasked after Synch Break
is detected), timer RA can be used in
timer mode after the SBDCT flag in the
LINST register is set to 1 and the
RXDSF flag is set to 0.
Figure 17.9
Example of Header Field Reception Flowchart (2)
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17. Hardware LIN
Hardware LIN measures the Synch
Field.
B
YES
The interrupt of timer RA may be
used (the SBDCT flag is set when
the timer RA counter underflows
upon reaching the terminal count).
When the SBE bit in the LINCR
register is set to 1 (unmasked after
Synch Field measurement is
completed), timer RA may be used
in timer mode after the SFDCT bit
in the LINST register is set to 1.
Hardware LIN Read the Synch Field measurement-
completed flag
SFDCT flag in the LINST register
NO
SFDCT = 1 ?
YES
UART0 Set the UART0 communication rate
U0BRG register
Set a communication rate based on
the Synch Field measurement
result.
Timer RA Set the Synch Break width again
TRAPRE register
TRA register
Communication via UART0
UART0 Communication via UART0
Clock asynchronous serial interface (UART) mode
Transmit ID field
(The SBDCT flag is set when the
timer RA counter underflows upon
reaching the terminal count.)
Figure 17.10 Example of Header Field Reception Flowchart (3)
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17. Hardware LIN
17.4.3 Bus Collision Detection Function
The bus collision detection function can be used when UART0 is enabled for transmission (TE bit in the U0C1
register = 1).
Figure 17.11 shows the Typical Operation when a Bus Collision is Detected.
1
TXD0 pin
0
1
RXD0 pin
0
1
Transfer clock
0
Set to 1 by a program
LINE bit in the
LINCR register
1
0
Set to 1 by a program
TE bit in the U0C1
register
1
0
Set by writing 1 to
the B2CLR bit in the
LINST register
BCDCT flag in the
LINST register
1
0
Cleared to 0 upon
acceptance of interrupt
request or by a program
IR bit in the TRAIC
register
1
0
Figure 17.11 Typical Operation when a Bus Collision is Detected
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17. Hardware LIN
17.4.4 Hardware LIN End Processing
Figure 17.12 shows an Example of Hardware LIN Communication Completion Flowchart.
Use the following timing for hardware LIN end processing:
• If the hardware bus collision detection function is used
Perform hardware LIN end processing after checksum transmission completes.
• If the bus collision detection function is not used
Perform hardware LIN end processing after header field transmission and reception complete.
Timer RA Set the timer to stop counting
TSTART bit in TRACR register ← 0
Set the timer to stop counting.
Zero to one cycle of the timer
RA count source is required
after timer RA starts counting
before the TCSTF flag is set to
1.
Timer RA Read the count status flag
TCSTF flag in TRACR register
NO
TCSTF = 0 ?
YES
When the bus collision
detection function is not used,
end processing for the UART0
transmission is not required.
UART0 Complete transmission via UART0
Hardware LIN Clear the status flags
(Bus collision detection, Synch Break
detection, Synch Field measurement)
Bits B2CLR, B1CLR, B0CLR in the LINST
register ← 0
After clearing hardware LIN
status flag, stop the hardware
LIN operation.
Hardware LIN Set the LIN operation to stop
LINE bit in the LINCR register ← 0
Figure 17.12 Example of Hardware LIN Communication Completion Flowchart
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17. Hardware LIN
17.5 Interrupt Requests
There are four interrupt requests that are generated by the hardware LIN: Synch Break detection, Synch Break
generation completed, Synch Field measurement completed, and bus collision detection. These interrupts are
shared with timer RA.
Table 17.2 lists the Interrupt Requests of Hardware LIN.
Table 17.2
Interrupt Requests of Hardware LIN
Interrupt Request
Status Flag
SBDCT
Cause of Interrupt
Synch Break detection
Generated when timer RA has underflowed after measuring
the “L” level duration of RXD0 input, or when a “L” level is
input for a duration longer than the Synch Break period
during communication.
Synch Break generation
completed
Generated when “L” level output to TXD0 for the duration set
by timer RA completes.
Synch Field
measurement completed
SFDCT
BCDCT
Generated when measurement for 6 bits of the Synch Field
by timer RA is completed.
Bus collision detection
Generated when the RXD0 input and TXD0 output values
differed at data latch timing while UART0 is enabled for
transmission.
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17. Hardware LIN
17.6 Notes on Hardware LIN
For the time-out processing of the header and response fields, use another timer to measure the duration of time
with a Synch Break detection interrupt as the starting point.
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18. A/D Converter
18. A/D Converter
The A/D converter consists of one 10-bit successive approximation A/D converter circuit with a capacitive coupling
amplifier. The analog input shares pins P0_0 to P0_7, and P1_0 to P1_3. Therefore, when using these pins, ensure that
the corresponding port direction bits are set to 0 (input mode).
When not using the A/D converter, set the VCUT bit in the ADCON1 register to 0 (Vref unconnected) so that no
current will flow from the VREF pin into the resistor ladder. This helps to reduce the power consumption of the chip.
The result of A/D conversion is stored in the AD register.
Table 18.1 lists the Performance of A/D converter. Figure 18.1 shows a Block Diagram of A/D Converter.
Figures 18.2 and 18.3 show the A/D converter-related registers.
Table 18.1
Performance of A/D converter
Item
Performance
Successive approximation (with capacitive coupling amplifier)
0 V to AVCC
A/D conversion method
(1)
Analog input voltage
(2)
4.2 V ≤ AVCC ≤ 5.5 V f1, f2, f4, fOCO-F
2.2 V ≤ AVCC < 4.2 V f2, f4, fOCO-F (N, D version)
2.7 V ≤ AVCC < 4.2 V f2, f4, fOCO-F (J, K version)
8 bits or 10 bits selectable
Operating clock φAD
Resolution
Absolute accuracy
AVCC = Vref = 5 V, φAD = 10 MHz
• 8-bit resolution ±2 LSB
• 10-bit resolution ±3 LSB
AVCC = Vref = 3.3 V, φAD = 10 MHz
• 8-bit resolution ±2 LSB
• 10-bit resolution ±5 LSB
AVCC = Vref = 2.2 V, φAD = 5 MHz
• 8-bit resolution ±2 LSB
• 10-bit resolution ±5 LSB
(3)
Operating mode
Analog input pin
One-shot and repeat
12 pins (AN0 to AN11)
A/D conversion start condition Software trigger
Set the ADST bit in the ADCON0 register to 1 (A/D conversion starts)
Conversion rate per pin
• Without sample and hold function
8-bit resolution: 49φAD cycles, 10-bit resolution: 59φAD cycles
• With sample and hold function
8-bit resolution: 28φAD cycles, 10-bit resolution: 33φAD cycles
NOTES:
1. The analog input voltage does not depend on use of a sample and hold function.
When the analog input voltage is over the reference voltage, the A/D conversion result will be 3FFh
in 10-bit mode and FFh in 8-bit mode.
2. When 2.7 V ≤ AVCC ≤ 5.5 V, the frequency of φAD must be 10 MHz or below.
When 2.2 V ≤ AVCC < 2.7 V, the frequency of φAD must be 5 MHz or below.
Without a sample and hold function, the φAD frequency should be 250 kHz or above.
With a sample and hold function, the φAD frequency should be 1 MHz or above.
3. In repeat mode, only 8-bit mode can be used.
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18. A/D Converter
CKS0 = 1
CKS0 = 0
fOCO-F
A/D conversion rate selection
CKS1 = 1
f1
CKS0 = 1
φAD
f2
CKS1 = 0
f4
CKS0 = 0
VCUT = 0
VCUT = 1
AVSS
VREF
Resistor ladder
Successive conversion register
ADCON0
Vcom
AD register
Data bus
Decoder
Comparator
VIN
CH2 to CH0 = 000b
CH2 to CH0 = 001b
P0_7/AN0
P0_6/AN1
P0_5/AN2
P0_4/AN3
P0_3/AN4
P0_2/AN5
P0_1/AN6
P0_0/AN7
CH2 to CH0 = 010b
CH2 to CH0 = 011b
ADGSEL0 = 0
CH2 to CH0 = 100b
CH2 to CH0 = 101b
CH2 to CH0 = 110b
CH2 to CH0 = 111b
ADGSEL0 = 1
CH2 to CH0 = 100b
CH2 to CH0 = 101b
P1_0/AN8
P1_1/AN9
P1_2/AN10
P1_3/AN11
CH2 to CH0 = 110b
CH2 to CH0 = 111b
CH0 to CH2, ADGSEL0, CKS0: Bits in ADCON0 register
CKS1, VCUT: Bits in ADCON1 register
Figure 18.1
Block Diagram of A/D Converter
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A/D Control Register 0(1)
18. A/D Converter
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
ADCON0
Address
00D6h
After Reset
00h
Bit Symbol
Bit Name
Function
RW
RW
Analog input pin select bits (Note 4)
CH0
CH1
RW
RW
RW
RW
RW
RW
CH2
A/D operating mode select 0 : One-shot mode
MD
bit(2)
1 : Repeat mode
A/D input group select bit(4) 0 : Selects port P0 group (AN0 to AN7)
1 : Selects port P1 group (AN8 to AN11)
ADGSEL0
—
(b5)
Reserved bit
Set to 0.
A/D conversion start flag 0 : Stops A/D conversion
1 : Starts A/D conversion
ADST
Frequency select bit 0
[When CKS1 in ADCON1 register = 0]
0 : Select f4
1 : Select f2
[When CKS1 in ADCON1 register = 1]
0 : Select f1(3)
CKS0
RW
1 : Select fOCO-F
NOTES:
1. If the ADCON0 register is rew ritten during A/D conversion, the conversion result is undefined.
2. When changing A/D operation mode, set the analog input pin again.
3. Set øAD frequency to 10 MHz or below .
4. The analog input pin can be selected according to a combination of bits CH0 to CH2 and the ADGSEL0 bit.
CH2 to CH0 ADGSEL0 = 0
ADGSEL0 = 1
Do not set.
000b
001b
010b
011b
100b
101b
110b
111b
AN0
AN1
AN2
AN3
AN4
AN5
AN6
AN7
AN8
AN9
AN10
AN11
Figure 18.2
ADCON0 Register
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18. A/D Converter
A/D Control Register 1(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0
0 0 0
Symbol
ADCON1
Bit Symbol
Address
00D7h
After Reset
00h
Bit Name
Function
RW
RW
—
(b2-b0)
Reserved bits
Set to 0.
8/10-bit mode select bit(2)
Frequency select bit 1
VREF connect bit(3)
Reserved bits
0 : 8-bit mode
1 : 10-bit mode
BITS
CKS1
VCUT
RW
Refer to the description of the CKS0 bit in the
ADCON0 register function.
RW
RW
RW
0 : VREF not connected
1 : VREF connected
—
(b6-b7)
Set to 0.
NOTES:
1. If the ADCON1 register is rew ritten during A/D conversion, the conversion result is undefined.
2. Set the BITS bit to 0 (8-bit mode) in repeat mode.
3. When the VCUT bit is set to 1 (connected) from 0 (not connected), w ait for 1 µs or more before starting
A/D conversion.
A/D Control Register 2(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0
Symbol
ADCON2
Bit Symbol
Address
00D4h
After Reset
00h
Bit Name
Function
RW
RW
A/D conversion method select bit
0 : Without sample and hold
1 : With sample and hold
SMP
—
(b3-b1)
Reserved bits
Set to 0.
RW
—
—
(b7-b4)
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
NOTE:
1. If the ADCON2 register is rew ritten during A/D conversion, the conversion result is undefined.
A/D Register
(b15)
b7
(b8)
b0
b7
b0
Symbol
AD
Address
00C1h-00C0h
After Reset
Undefined
Function
When BITS bit in ADCON1 register is
set to 1 (10-bit mode).
When BITS bit in ADCON1 register is
set to 0 (8-bit mode).
RW
8 low -order bits in A/D conversion result
2 high-order bits in A/D conversion result
A/D conversion result
When read, the content is undefined.
RO
RO
Nothing is assigned. If necessary, set to 0.
When read, the content is 0.
—
Figure 18.3
Registers ADCON1, ADCON2, and AD
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18. A/D Converter
18.1 One-Shot Mode
In one-shot mode, the input voltage of one selected pin is A/D converted once.
Table 18.2 lists the Specifications of One-Shot Mode. Figure 18.4 shows the ADCON0 Register in One-Shot Mode
and Figure 18.5 shows the ADCON1 Register in One-Shot Mode.
Table 18.2
Specifications of One-Shot Mode
Item
Specification
Function
The input voltage of one pin selected by bits CH2 to CH0 and ADGSEL0 is
A/D converted once
Start condition
Stop condition
Set the ADST bit to 1 (A/D conversion starts)
• A/D conversion completes (ADST bit is set to 0)
• Set the ADST bit to 0
Interrupt request
generation timing
Input pin
A/D conversion completes
Select one of AN0 to AN11
Reading of A/D conversion Read AD register
result
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18. A/D Converter
A/D Control Register 0(1)
b7 b6 b5 b4 b3 b2 b1 b0
0
0
Symbol
ADCON0
Bit Symbol
Address
00D6h
After Reset
00h
Bit Name
Function
RW
RW
Analog input pin select bits (Note 4)
CH0
CH1
RW
RW
RW
RW
RW
RW
CH2
A/D operating mode select 0 : One-shot mode
bit(2)
A/D input group select bit(4) 0 : Selects port P0 group (AN0 to AN7)
1 : Selects port P1 group (AN8 to AN11)
MD
ADGSEL0
—
(b5)
Reserved bit
Set to 0.
A/D conversion start flag 0 : Stops A/D conversion
1 : Starts A/D conversion
ADST
Frequency select bit 0
[When CKS1 in ADCON1 register = 0]
0 : Select f4
1 : Select f2
[When CKS1 in ADCON1 register = 1]
0 : Select f1(3)
CKS0
RW
1 : Select fOCO-F
NOTES:
1. If the ADCON0 register is rew ritten during A/D conversion, the conversion result is undefined.
2. After changing the A/D operating mode, select the analog input pin again.
3. Set øAD frequency to 10 MHz or below .
4. The analog input pin can be selected according to a combination of bits CH0 to CH2 and the ADGSEL0 bit.
CH2 to CH0 ADGSEL0 = 0
ADGSEL0 = 1
Do not set.
000b
001b
010b
011b
100b
101b
110b
111b
AN0
AN1
AN2
AN3
AN4
AN5
AN6
AN7
AN8
AN9
AN10
AN11
Figure 18.4
ADCON0 Register in One-Shot Mode
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18. A/D Converter
A/D Control Register 1(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 1
0 0 0
Symbol
ADCON1
Bit Symbol
Address
00D7h
After Reset
00h
Bit Name
Function
RW
RW
—
(b2-b0)
Reserved bits
Set to 0.
8/10-bit mode select bit
Frequency select bit 1
VREF connect bit(2)
Reserved bits
0 : 8-bit mode
1 : 10-bit mode
BITS
CKS1
VCUT
RW
Refer to the description of the CKS0 bit in the
ADCON0 register function.
RW
RW
RW
1 : VREF connected
—
(b6-b7)
Set to 0.
NOTES:
1. If the ADCON1 register is rew ritten during A/D conversion, the conversion result is undefined.
2. When the VCUT bit is set to 1 (connected) from 0 (not connected), w ait for 1 µs or more before starting
A/D conversion.
Figure 18.5
ADCON1 Register in One-Shot Mode
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18. A/D Converter
18.2 Repeat Mode
In repeat mode, the input voltage of one selected pin is A/D converted repeatedly.
Table 18.3 lists the Specifications of Repeat Mode. Figure 18.6 shows the ADCON0 Register in Repeat Mode and
Figure 18.7 shows the ADCON1 Register in Repeat Mode.
Table 18.3
Specifications of Repeat Mode
Item
Specification
Function
The Input voltage of one pin selected by bits CH2 to CH0 and ADGSEL0 is
A/D converted repeatedly
Start conditions
Stop condition
Interrupt request
generation timing
Input pin
Set the ADST bit to 1 (A/D conversion starts)
Set the ADST bit to 0
Not generated
Select one of AN0 to AN11
Read AD register
Reading of result of A/D
converter
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18. A/D Converter
A/D Control Register 0(1)
b7 b6 b5 b4 b3 b2 b1 b0
0
1
Symbol
ADCON0
Bit Symbol
Address
00D6h
After Reset
00h
Bit Name
Function
RW
RW
Analog input pin select bits (Note 4)
CH0
CH1
RW
RW
RW
RW
RW
RW
CH2
A/D operating mode select 1 : Repeat mode
bit(2)
A/D input group select bit(4) 0 : Selects port P0 group (AN0 to AN7)
1 : Selects port P1 group (AN8 to AN11)
MD
ADGSEL0
—
(b5)
Reserved bit
Set to 0.
A/D conversion start flag 0 : Stops A/D conversion
1 : Starts A/D conversion
ADST
Frequency select bit 0
[When CKS1 in ADCON1 register = 0]
0 : Select f4
1 : Select f2
[When CKS1 in ADCON1 register = 1]
0 : Select f1(3)
CKS0
RW
1 : Do not set.
NOTES:
1. If the ADCON0 register is rew ritten during A/D conversion, the conversion result is undefined.
2. After changing A/D operation mode, select the analog input pin again.
3. Set øAD frequency to 10 MHz or below .
4. The analog input pin can be selected according to a combination of bits CH0 to CH2 and the ADGSEL0 bit.
CH2 to CH0 ADGSEL0 = 0
ADGSEL0 = 1
Do not set.
000b
001b
010b
011b
100b
101b
110b
111b
AN0
AN1
AN2
AN3
AN4
AN5
AN6
AN7
AN8
AN9
AN10
AN11
Figure 18.6
ADCON0 Register in Repeat Mode
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18. A/D Converter
A/D Control Register 1(1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 1
0 0 0 0
Symbol
ADCON1
Bit Symbol
Address
00D7h
After Reset
00h
Bit Name
Function
RW
RW
—
(b2-b0)
Reserved bits
Set to 0.
8/10-bit mode select bit(2)
Frequency select bit 1
VREF connect bit(3)
Reserved bits
0 : 8-bit mode
BITS
CKS1
VCUT
RW
Refer to the description of the CKS0 bit in the
ADCON0 register function.
RW
RW
RW
1 : VREF connected
—
(b6-b7)
Set to 0.
NOTES:
1. If the ADCON1 register is rew ritten during A/D conversion, the conversion result is undefined.
2. Set the BITS bit to 0 (8-bit mode) in repeat mode.
3. When the VCUT bit is set to 1 (connected) from 0 (not connected), w ait for 1 µs or more before starting
A/D conversion.
Figure 18.7
ADCON1 Register in Repeat Mode
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18. A/D Converter
18.3 Sample and Hold
When the SMP bit in the ADCON2 register is set to 1 (sample and hold function enabled), the A/D conversion rate
per pin increases. The sample and hold function is available in all operating modes. Start A/D conversion after
selecting whether the sample and hold circuit is to be used or not.
Figure 18.8 shows a Timing Diagram of A/D Conversion.
Sample and hold
disabled
Conversion time of 1st bit
2nd bit
Comparison
Comparison
time
Comparison
time
Sampling time
4ø AD cycles
Sampling time
2.5ø AD cycles
Sampling time
2.5ø AD cycles
time
* Repeat until conversion ends
Sample and hold
enabled
2nd bit
Conversion time of 1st bit
Comparison Comparison Comparison Comparison
time time time time
Sampling time
4ø AD cycles
* Repeat until conversion ends
Figure 18.8
Timing Diagram of A/D Conversion
18.4 A/D Conversion Cycles
Figure 18.9 shows the A/D Conversion Cycles.
Conversion time at the 2nd
bit and the follows
Conversion time at the 1st bit
End process
Conversion Sampling Comparison Sampling Comparison
End process
A/D Conversion Mode
Time
Time
4φAD
4φAD
4φAD
4φAD
Time
Time
Time
Without Sample & Hold
8 bits
10 bits
8 bits
49φAD
59φAD
28φAD
33φAD
2.0φAD
2.0φAD
2.5φAD
2.5φAD
2.5φAD
2.5φAD
0.0φAD
0.0φAD
2.5φAD
2.5φAD
2.5φAD
2.5φAD
8.0φAD
8.0φAD
4.0φAD
4.0φAD
Without Sample & Hold
With Sample & Hold
With Sample & Hold
10 bits
Figure 18.9
A/D Conversion Cycles
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18. A/D Converter
18.5 Internal Equivalent Circuit of Analog Input
Figure 18.10 shows the Internal Equivalent Circuit of Analog Input.
VCC
VCC VSS
AVCC
ON Resistor
Approx. 0.6kΩ
ON Resistor
Approx. 2kΩ
Parasitic Diode
AN0
Wiring Resistor
Approx. 0.2kΩ
C = Approx.1.5pF
AMP
Analog Input
Voltage
VIN
SW1
SW2
ON Resistor
Approx. 5kΩ
Parasitic Diode
Sampling
Control Signal
SW3
SW4
VSS
i=12
i Ladder-type
Switches
i Ladder-type
Wiring Resistors
Chopper-type
Amplifier
AVSS
ON Resistor
Wiring Resistor
Approx. 2kΩ
Approx. 0.2kΩ
AN11
SW1
A/D Successive
Conversion Register
b4 b2 b1 b0
Reference
Control Signal
A/D Control Register 0
Vref
VREF
Comparison
voltage
Approx. 0.6k f
SW5
Resistor
ladder
ON Resistor
A/D Conversion
Interrupt Request
AVSS
Comparison reference voltage
(Vref) generator
Sampling
Connect to
Comparison
SW1 conducts only on the ports selected for analog input.
SW2 and SW3 are open when A/D conversion is not in progress;
their status varies as shown by the waveforms in the diagrams on the left.
Control signal
for SW2
Connect to
Connect to
Connect to
SW4 conducts only when A/D conversion is not in progress.
SW5 conducts when compare operation is in progress.
Control signal
for SW3
NOTE:
1. Use only as a standard for designing this data.
Mass production may cause some changes in device characteristics.
Figure 18.10 Internal Equivalent Circuit of Analog Input
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18. A/D Converter
18.6 Output Impedance of Sensor under A/D Conversion
To carry out A/D conversion properly, charging the internal capacitor C shown in Figure 18.11 has to be completed
within a specified period of time. T (sampling time) as the specified time. Let output impedance of sensor
equivalent circuit be R0, internal resistance of microcomputer be R, precision (error) of the A/D converter be X,
and the resolution of A/D converter be Y (Y is 1024 in the 10-bit mode, and 256 in the 8-bit mode).
1
– -------------------------- t
C(R0 + R)
–
VC is generally
And when t = T,
e
VC= VIN
1
X
Y
X
Y
VC = VIN – --- VIN = VIN 1 – ---
1
– -------------------------- T
X
Y
C(R0 + R)
e
= ---
1
X
Y
– -------------------------- T= ln---
C(R0 + R)
T
Hence,
R0= – ------------------- – R
X
C • ln---
Y
Figure 18.11 shows the Analog Input Pin and External Sensor Equivalent Circuit. When the difference between
VIN and VC becomes 0.1LSB, we find impedance R0 when voltage between pins VC changes from 0 to VIN-
(0.1/1024) VIN in time T. (0.1/1024) means that A/D precision drop due to insufficient capacitor charge is held to
0.1LSB at time of A/D conversion in the 10-bit mode. Actual error however is the value of absolute precision
added to 0.1LSB.
When f(XIN) = 10 MHz, T = 0.25 µs in the A/D conversion mode without sample and hold. Output impedance R0
for sufficiently charging capacitor C within time T is determined as follows.
T = 0.25 µs, R = 2.8 kΩ, C = 6.0 pF, X = 0.1, and Y = 1024. Hence,
–6
3
3
0.25 × 10
R0= –--------------------------------------------------–2.8×10 ≈ 1.7×10
0.1
–12
6.0 × 10
• ln-----------
1024
Thus, the allowable output impedance of the sensor equivalent circuit, making the precision (error) 0.1LSB or less,
is approximately 1.7 kΩ. maximum.
MCU
Sensor equivalent
circuit
R0
R (2.8 kΩ)
VIN
C (6.0 pF)
VC
NOTE:
1. The capacity of the terminal is assumed to be 4.5 pF.
Figure 18.11 Analog Input Pin and External Sensor Equivalent Circuit
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18. A/D Converter
18.7 Notes on A/D Converter
• Write to each bit (other than bit 6) in the ADCON0 register, each bit in the ADCON1 register, or the SMP bit
in the ADCON2 register when A/D conversion is stopped (before a trigger occurs).
When the VCUT bit in the ADCON1 register is changed from 0 (VREF not connected) to 1 (VREF
connected), wait for at least 1 µs before starting the A/D conversion.
• After changing the A/D operating mode, select an analog input pin again.
• When using the one-shot mode, ensure that A/D conversion is completed before reading the AD register. The
IR bit in the ADIC register or the ADST bit in the ADCON0 register can be used to determine whether A/D
conversion is completed.
• When using the repeat mode, select the frequency of the A/D converter operating clock φAD or more for the
CPU clock during A/D conversion.
• If the ADST bit in the ADCON0 register is set to 0 (A/D conversion stops) by a program and A/D conversion
is forcibly terminated during an A/D conversion operation, the conversion result of the A/D converter will be
undefined. If the ADST bit is set to 0 by a program, do not use the value of the AD register.
• Connect 0.1 µF capacitor between the P4_2/VREF pin and AVSS pin.
• Do not enter stop mode during A/D conversion.
• Do not enter wait mode when the CM02 bit in the CM0 register is set to 1 (peripheral function clock stops in
wait mode) during A/D conversion.
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19. Flash Memory
19. Flash Memory
19.1 Overview
In the flash memory, rewrite operations to the flash memory can be performed in three modes: CPU rewrite,
standard serial I/O, and parallel I/O.
Table 19.1 lists the Flash Memory Performance (refer to Tables 1.1 and 1.2 Functions and Specifications for
items not listed in Table 19.1).
Table 19.1
Flash Memory Performance
Item
Specification
3 modes (CPU rewrite, standard serial I/O, and parallel I/O)
Refer to Figures 19.1 and 19.2
Flash memory operating mode
Division of erase block
Programming method
Byte unit
Erase method
Block erase
Programming and erasure control method(3)
Rewrite control method
Program and erase control by software command
Rewrite control for blocks 0 and 1 by FMR02 bit in FMR0 register
Rewrite control for block 0 by FMR15 bit and block 1 by FMR16 bit in
FMR1 register
Number of commands
5 commands
Programming and Blocks 0 and 1 (program R8C/26 Group: 100 times; R8C/27 Group: 1,000 times
erasure
ROM)
endurance(1)
Blocks A and B (data
flash)(2)
10,000 times
ID code check function
ROM code protect
Standard serial I/O mode supported
Parallel I/O mode supported
NOTES:
1. Definition of programming and erasure endurance
The programming and erasure endurance is defined on a per-block basis. If the programming and erasure
endurance is n (n = 100 or 10,000), each block can be erased n times. For example, if 1,024 1-byte writes are
performed to different addresses in block A, a 1-Kbyte block, and then the block is erased, the programming/
erasure endurance still stands at one. When performing 100 or more rewrites, the actual erase count can be
reduced by executing programming operations in such a way that all blank areas are used before performing an
erase operation. Avoid rewriting only particular blocks and try to average out the programming and erasure
endurance of the blocks. It is also advisable to retain data on the erasure endurance of each block and limit the
number of erase operations to a certain number.
2. Blocks A and B are implemented only in the R8C/27 group.
3. To perform programming and erasure, use VCC = 2.7 to 5.5 V as the supply voltage. Do not perform
programming and erasure at less than 2.7 V.
Table 19.2
Flash memory
Rewrite mode
Function
Flash Memory Rewrite Modes
Standard Serial I/O
Mode
CPU Rewrite Mode
Parallel I/O Mode
User ROM area is rewritten by executing User ROM area is User ROM area is
software commands from the CPU.
EW0 mode: Rewritable in the RAM
EW1 mode: Rewritable in flash memory programmer.
rewritten by a
dedicated serial
rewritten by a
dedicated parallel
programmer.
Areas which can User ROM area
be rewritten
User ROM area
User ROM area
Operating mode
Single chip mode
Boot mode
Parallel I/O mode
ROM Programmer None
Serial programmer Parallel programmer
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19. Flash Memory
19.2 Memory Map
The flash memory contains a user ROM area and a boot ROM area (reserved area).
Figure 19.1 shows the Flash Memory Block Diagram for R8C/26 Group. Figure 19.2 shows a Flash Memory Block
Diagram for R8C/27 Group.
The user ROM area of the R8C/27 Group contains an area (program ROM) which stores MCU operating programs
and blocks A and B (data flash) each 1 Kbyte in size.
The user ROM area is divided into several blocks. The user ROM area can be rewritten in CPU rewrite mode and
standard serial I/O and parallel I/O modes.
When rewriting blocks 0 and 1 in CPU rewrite mode, set the FMR02 bit in the FMR0 register to 1 (rewrite
enabled). When the FMR15 bit in the FMR1 register is set to 0 (rewrite enabled), block 0 is rewritable. When the
FMR16 bit is set to 0 (rewrite enabled), block 1 is rewritable.
The rewrite control program for standard serial I/O mode is stored in the boot ROM area before shipment. The boot
ROM area and the user ROM area share the same address, but have separate memory areas.
16 Kbytes ROM product
0C000h
8 Kbytes ROM product
Block 0: 8 Kbytes(1)
User ROM area
Block 0: 16 Kbytes(1)
Program ROM
0E000h
0FFFFh
0FFFFh
08000h
User ROM area
32 Kbytes ROM product
Block 1: 16 Kbytes(1)
24 Kbytes ROM product
Block 1: 8 Kbytes(1)
Program ROM
0A000h
0BFFFh
0C000h
0BFFFh
0C000h
Block 0: 16 Kbytes(1)
User ROM area
Block 0: 16 Kbytes(1)
User ROM area
0E000h
0FFFFh
8 Kbytes
0FFFFh
0FFFFh
Boot ROM area
(reserved area)(2)
NOTES:
1. When the FMR02 bit in the FMR0 register is set to 1 (rewrite enabled) and the FMR15 bit in the FMR1 register is set to 0
(rewrite enabled), block 0 is rewritable. When the FMR16 bit is set to 0 (rewrite enabled), block 1 is rewritable (only for CPU
rewrite mode).
2. This area is for storing the boot program provided by Renesas Technology.
Figure 19.1
Flash Memory Block Diagram for R8C/26 Group
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19. Flash Memory
16 Kbytes ROM product
8 Kbytes ROM product
Block A: 1 Kbyte
02400h
02400h
02BFFh
Block A: 1 Kbyte
Data flash
Block B: 1 Kbyte
02BFFh
Block B: 1 Kbyte
0C000h
Block 0: 16 Kbytes(1)
Program ROM
0E000h
0FFFFh
Block 0: 8 Kbytes(1)
User ROM area
0FFFFh
User ROM area
24 Kbytes ROM product
Block A: 1 Kbyte
32 Kbytes ROM product
02400h
02400h
02BFFh
Block A: 1 Kbyte
Data flash
Block B: 1 Kbyte
02BFFh
Block B: 1 Kbyte
08000h
Program ROM
Block 1: 16 Kbytes(1)
0A000h
Block 1: 8 Kbytes(1)
Block 0: 16 Kbytes(1)
0BFFFh
0C000h
0BFFFh
0C000h
Block 0: 16 Kbytes(1)
0E000h
0FFFFh
8 Kbytes
0FFFFh
0FFFFh
Boot ROM area
User ROM area
User ROM area
(reserved area)(2)
NOTES:
1. When the FMR02 bit in the FMR0 register is set to 1 (rewrite enabled) and the FMR15 bit in the FMR1 register is set to 0
(rewrite enabled), block 0 is rewritable. When the FMR16 bit is set to 0 (rewrite enabled), block 1 is rewritable (only for CPU
rewrite mode).
2. This area is for storing the boot program provided by Renesas Technology.
Figure 19.2
Flash Memory Block Diagram for R8C/27 Group
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19. Flash Memory
19.3 Functions to Prevent Rewriting of Flash Memory
Standard serial I/O mode has an ID code check function, and parallel I/O mode has a ROM code protect function to
prevent the flash memory from being read or rewritten easily.
19.3.1 ID Code Check Function
This function is used in standard serial I/O mode. Unless the flash memory is blank, the ID codes sent from the
programmer and the ID codes written in the flash memory are checked to see if they match. If the ID codes do
not match, the commands sent from the programmer are not acknowledged. The ID codes consist of 8 bits of
data each, the areas of which, beginning with the first byte, are 00FFDFh, 00FFE3h, 00FFEBh, 00FFEFh,
00FFF3h, 00FFF7h, and 00FFFBh. Write programs in which the ID codes are set at these addresses and write
them to the flash memory.
Address
00FFDFh to 00FFDCh
00FFE3h to 00FFE0h
00FFE7h to 00FFE4h
00FFEBh to 00FFE8h
00FFEFh to 00FFECh
00FFF3h to 00FFF0h
00FFF7h to 00FFF4h
00FFFBh to 00FFF8h
00FFFFh to 00FFFCh
ID1
ID2
Undefined instruction vector
Overflow vector
BRK instruction vector
Address match vector
Single step vector
ID3
ID4
ID5
ID6
ID7
Oscillation stop detection/watchdog
timer/voltage monitor 1 and voltage
monitor 2 vector
Address break
(Reserved)
(Note 1) Reset vector
4 bytes
NOTE:
1. The OFS register is assigned to 00FFFFh.
Refer to Figure 19.4 OFS Register for OFS register details.
Figure 19.3
Address for Stored ID Code
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19. Flash Memory
19.3.2 ROM Code Protect Function
The ROM code protect function disables reading or changing the contents of the on-chip flash memory by the
OFS register in parallel I/O mode.
Figure 19.4 shows the OFS Register.
The ROM code protect function is enabled by writing 0 to the ROMCP1 bit and 1 to the ROMCR bit. It disables
reading or changing the contents of the on-chip flash memory.
Once ROM code protect is enabled, the content in the internal flash memory cannot be rewritten in parallel I/O
mode. To disable ROM code protect, erase the block including the OFS register with CPU rewrite mode or
standard serial I/O mode.
Option Function Select Register(1)
b7 b6 b5 b4 b3 b2 b1 b0
1
1
Symbol
OFS
Address
0FFFFh
When Shipping
FFh(3)
Bit Symbol
Bit Name
Function
RW
RW
Watchdog timer start
select bit
0 : Starts w atchdog timer automatically after reset
1 : Watchdog timer is inactive after reset
WDTON
—
(b1)
Reserved bit
Set to 1.
RW
RW
RW
RW
ROM code protect
disabled bit
0 : ROM code protect disabled
1 : ROMCP1 enabled
ROMCR
ROM code protect bit
0 : ROM code protect enabled
1 : ROM code protect disabled
ROMCP1
—
(b4)
Reserved bit
Set to 1.
Voltage detection 0
circuit start bit(2, 4)
0 : Voltage monitor 0 reset enabled after hardw are
reset
LVD0ON
RW
1 : Voltage monitor 0 reset disabled after hardw are
reset
Voltage detection 1
circuit start bit(5, 6)
0 : Voltage monitor 1 reset enabled after hardw are
reset
LVD1ON
CSPROINI
RW
RW
1 : Voltage monitor 1 reset disabled after hardw are
reset
Count source protect
mode after reset select 1 : Count source protect mode disabled after reset
bit
0 : Count source protect mode enabled after reset
NOTES:
1. The OFS register is on the flash memory. Write to the OFS register w ith a program. After w riting is completed, do not
w rite additions to the OFS register.
2. The LVD0ON bit setting is valid only by a hardw are reset. To use the pow er-on reset, set the LVD0ON bit to 0
(voltage monitor 0 reset enabled after hardw are reset).
3. If the block including the OFS register is erased, FFh is set to the OFS register.
4. For N, D version only. For J, K version, set the LVD0ON bit to 1 (voltage monitor 0 reset disabled after hardw are
reset).
5. The LVD1ON bit setting is valid only by a hardw are reset. When the pow er-on reset function is used, set the
LVD1ON bit to 0 (voltage monitor 1 reset enabled after hardw are reset).
6. For J, K version only. For N, D version, set the LVD1ON bit to 1 (voltage monitor 1 reset disabled after hardw are
reset).
Figure 19.4
OFS Register
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19. Flash Memory
19.4 CPU Rewrite Mode
In CPU rewrite mode, the user ROM area can be rewritten by executing software commands from the CPU.
Therefore, the user ROM area can be rewritten directly while the MCU is mounted on a board without using a
ROM programmer. Execute the program and block erase commands only to blocks in the user ROM area.
The flash module has an erase-suspend function when an interrupt request is generated during an erase operation in
CPU rewrite mode. It performs an interrupt process after the erase operation is halted temporarily. During erase-
suspend, the user ROM area can be read by a program.
In case an interrupt request is generated during an auto-program operation in CPU rewrite mode, the flash module
contains a program-suspend function which performs the interrupt process after the auto-program operation is
suspended. During program-suspend, the user ROM area can be read by a program.
CPU rewrite mode has an erase write 0 mode (EW0 mode) and an erase write 1 mode (EW1 mode).
Table 19.3 lists the Differences between EW0 Mode and EW1 Mode.
Table 19.3
Differences between EW0 Mode and EW1 Mode
Item EW0 Mode
Single-chip mode
EW1 Mode
Single-chip mode
Operating mode
Areas in which a rewrite
control program can be
located
User ROM area
User ROM area
Areas in which a rewrite
control program can be
executed
Necessary to transfer to any area other
than the flash memory (e.g., RAM) before area possible
executing
Executing directly in user ROM or RAM
Areas which can be
rewritten
User ROM area
None
User ROM area
However, blocks which contain a rewrite
control program are excluded(1)
Software command
restrictions
• Program and block erase commands
Cannot be run on any block which
contains a rewrite control program
• Read status register command
Cannot be executed
Modes after program or
erase
Read status register mode
Read status register mode
Operating
Read array mode
Modes after read status
register
Do not execute this command
CPU status during auto-
write and auto-erase
Hold state (I/O ports hold state before the
command is executed)
Flash memory status
detection
• Read bits FMR00, FMR06, and FMR07 Read bits FMR00, FMR06, and FMR07 in
in the FMR0 register by a program
• Execute the read status register
command and read bits SR7, SR5, and
SR4 in the status register.
the FMR0 register by a program
Conditions for transition to
erase-suspend
Set bits FMR40 and FMR41 in the FMR4 The FMR40 bit in the FMR4 register is set
register to 1 by a program.
to 1 and the interrupt request of the
enabled maskable interrupt is generated
Conditions for transitions to Set bits FMR40 and FMR42 in the FMR4 The FMR40 bit in the FMR4 register is set
program-suspend
register to 1 by a program.
to 1 and the interrupt request of the
enabled maskable interrupt is generated
CPU clock
5 MHz or below
No restriction (on clock frequency to be
used)
NOTE:
1. When the FMR02 bit in the FMR0 register is set to 1 (rewrite enabled), rewriting block 0 is enabled by setting
the FMR15 bit in the FMR1 register to 0 (rewrite enabled), and rewriting block 1 is enabled by setting the
FMR16 bit to 0 (rewrite enabled).
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19. Flash Memory
19.4.1 EW0 Mode
The MCU enters CPU rewrite mode and software commands can be acknowledged by setting the FMR01 bit in
the FMR0 register to 1 (CPU rewrite mode enabled). In this case, since the FMR11 bit in the FMR1 register is
set to 0, EW0 mode is selected.
Use software commands to control program and erase operations. The FMR0 register or the status register can
be used to determine when program and erase operations complete.
During auto-erasure, set the FMR40 bit to 1 (erase-suspend enabled) and the FMR41 bit to 1 (request erase-
suspend). Wait for td(SR-SUS) and ensure that the FMR46 bit is set to 1 (read enabled) before accessing the
user ROM area. The auto-erase operation can be restarted by setting the FMR41 bit to 0 (erase restarts).
To enter program-suspend during the auto-program operation, set the FMR40 bit to 1 (suspend enabled) and the
FMR42 bit to 1 (request program-suspend). Wait for td(SR-SUS) and ensure that the FMR46 bit is set to 1 (read
enabled) before accessing the user ROM area. The auto-program operation can be restarted by setting the
FMR42 bit to 0 (program restarts).
19.4.2 EW1 Mode
The MCU is switched to EW1 mode by setting the FMR11 bit to 1 (EW1 mode) after setting the FMR01 bit to
1 (CPU rewrite mode enabled).
The FMR0 register can be used to determine when program and erase operations complete. Do not execute
commands that use the read status register in EW1 mode.
To enable the erase-suspend function during auto-erasure, execute the block erase command after setting the
FMR40 bit to 1 (erase-suspend enabled). The interrupt to enter erase-suspend should be in interrupt enabled
status. After waiting for td(SR-SUS) after the block erase command is executed, the interrupt request is
acknowledged.
When an interrupt request is generated, the FMR41 bit is automatically set to 1 (requests erase-suspend) and the
auto-erase operation suspends. If an auto-erase operation does not complete (FMR00 bit is 0) after an interrupt
process completes, the auto-erase operation restarts by setting the FMR41 bit to 0 (erasure restarts)
To enable the program-suspend function during auto-programming, execute the program command after setting
the FMR40 bit to 1 (suspend enabled). The interrupt to enter program-suspend should be in interrupt enabled
status. After waiting for td(SR-SUS) after the program command is executed, an interrupt request is
acknowledged.
When an interrupt request is generated, the FMR42 bit is automatically set to 1 (request program-suspend) and
the auto-program operation suspends. When the auto-program operation does not complete (FMR00 bit is 0)
after the interrupt process completes, the auto-program operation can be restarted by setting the FMR42 bit to 0
(programming restarts).
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19. Flash Memory
Figure 19.5 shows the FMR0 Register, Figure 19.6 shows the FMR1 Register and Figure 19.7 shows the FMR4
Register.
19.4.2.1 FMR00 Bit
This bit indicates the operating status of the flash memory. The bits value is 0 during programming, erasure
(including suspend periods), or erase-suspend mode; otherwise, it is 1.
19.4.2.2 FMR01 Bit
The MCU is made ready to accept commands by setting the FMR01 bit to 1 (CPU rewrite mode).
19.4.2.3 FMR02 Bit
Rewriting of block 0 and block 1 does not accept program or block erase commands if the FMR02 bit is set to 0
(rewrite disabled).
Rewriting of block 0 and block 1 is controlled by bits FMR15 and FMR16 if the FMR02 bit is set to 1 (rewrite
enabled).
19.4.2.4 FMSTP Bit
This bit is used to initialize the flash memory control circuits, and also to reduce the amount of current
consumed by the flash memory. Access to the flash memory is disabled by setting the FMSTP bit to 1.
Therefore, the FMSTP bit must be written to by a program transferred to the RAM.
In the following cases, set the FMSTP bit to 1:
• When flash memory access resulted in an error while erasing or programming in EW0 mode (FMR00 bit
not reset to 1 (ready))
• To provide lower consumption in high-speed on-chip oscillator mode, low-speed on-chip oscillator mode
(XIN clock stops), and low-speed clock mode (XIN clock stops).
Figure 19.11 shows the Process to Reduce Power Consumption in High-Speed On-Chip Oscillator Mode, Low-
Speed On-Chip Oscillator Mode (XIN Clock Stops) and Low-Speed Clock Mode (XIN Clock Stops). Handle
according to this flowchart. Note that when going to stop or wait mode while the CPU rewrite mode is disabled,
the FMR0 register does not need to be set because the power for the flash memory is automatically turned off
and is turned back on again after returning from stop or wait mode.
19.4.2.5 FMR06 Bit
This is a read-only bit indicating the status of an auto-program operation. The bit is set to 1 when a program
error occurs; otherwise, it is cleared to 0. For details, refer to the description in 19.4.5 Full Status Check.
19.4.2.6 FMR07 Bit
This is a read-only bit indicating the status of an auto-erase operation. The bit is set to 1 when an erase error
occurs; otherwise, it is set to 0. Refer to 19.4.5 Full Status Check for details.
19.4.2.7 FMR11 Bit
Setting this bit to 1 (EW1 mode) places the MCU in EW1 mode.
19.4.2.8 FMR15 Bit
When the FMR02 bit is set to 1 (rewrite enabled) and the FMR15 bit is set to 0 (rewrite enabled), block 0
accepts program and block erase commands.
19.4.2.9 FMR16 Bit
When the FMR02 bit is set to 1 (rewrite enabled) and the FMR16 bit is set to 0 (rewrite enabled), block 1
accepts program and block erase commands.
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19. Flash Memory
19.4.2.10 FMR40 Bit
The suspend function is enabled by setting the FMR40 bit to 1 (enable).
19.4.2.11 FMR41 Bit
In EW0 mode, the MCU enters erase-suspend mode when the FMR41 bit is set to 1 by a program. The FMR41
bit is automatically set to 1 (request erase-suspend) when an interrupt request of an enabled interrupt is
generated in EW1 mode, and then the MCU enters erase-suspend mode.
Set the FMR41 bit to 0 (erase restarts) when the auto-erase operation restarts.
19.4.2.12 FMR42 Bit
In EW0 mode, the MCU enters program-suspend mode when the FMR42 bit is set to 1 by a program. The
FMR42 bit is automatically set to 1 (request program-suspend) when an interrupt request of an enabled
interrupt is generated in EW1 mode, and then the MCU enters program-suspend mode.
Set the FMR42 bit to 0 (program restart) when the auto-program operation restarts.
19.4.2.13 FMR43 Bit
When the auto-erase operation starts, the FMR43 bit is set to 1 (erase execution in progress). The FMR43 bit
remains set to 1 (erase execution in progress) during erase-suspend operation.
When the auto-erase operation ends, the FMR43 bit is set to 0 (erase not executed).
19.4.2.14 FMR44 Bit
When the auto-program operation starts, the FMR44 bit is set to 1 (program execution in progress). The FMR44
bit remains set to 1 (program execution in progress) during program-suspend operation.
When the auto-program operation ends, the FMR44 bit is set to 0 (program not executed).
19.4.2.15 FMR46 Bit
The FMR46 bit is set to 0 (reading disabled) during auto-program or auto-erase execution and set to 1 (reading
enabled) in suspend mode. Do not access the flash memory while this bit is set to 0.
19.4.2.16 FMR47 Bit
Power consumption when reading the flash memory can be reduced by setting the FMR47 bit to 1 (enabled) in
low-speed clock mode (XIN clock stops) and low-speed on-chip oscillator mode (XIN clock stops).
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19. Flash Memory
Flash Memory Control Register 0
b7 b6 b5 b4 b3 b2 b1 b0
0 0
Symbol
Address
01B7h
After Reset
00000001b
FMR0
Bit Symbol
Bit Name
Function
RW
__
0 : Busy (w riting or erasing in progress)
1 : Ready
RY/BY status flag
FMR00
FMR01
FMR02
RO
RW
RW
CPU rew rite mode select bit(1)
Block 0, 1 rew rite enable bit(2, 6)
Flash memory stop bit(3, 5)
0 : CPU rew rite mode disabled
1 : CPU rew rite mode enabled
0 : Disables rew rite
1 : Enables rew rite
0 : Enables flash memory operation
1 : Stops flash memory
FMSTP
RW
(enters low -pow er consumption state
and flash memory is reset)
—
(b5-b4)
Reserved bits
Set to 0.
RW
RO
RO
Program status flag(4)
Erase status flag(4)
0 : Completed successfully
1 : Terminated by error
FMR06
FMR07
0 : Completed successfully
1 : Terminated by error
NOTES:
1. To set this bit to 1, set it to 1 immediately after setting it first to 0. Do not generate an interrupt betw een setting the bit
to 0 and setting it to 1. Enter read array mode and set this bit to 0.
2. Set this bit to 1 immediately after setting it first to 0 w hile the FMR01 bit is set to 1.
Do not generate an interrupt betw een setting the bit to 0 and setting it to 1.
3. Set this bit by a program transferred to the RAM.
4. This bit is set to 0 by executing the clear status command.
5. This bit is enabled w hen the FMR01 bit is set to 1 (CPU rew rite mode enabled). When the FMR01 bit is set to 0,
w riting 1 to the FMSTPbit causes the FMSTPbit to be set to 1. The flash memory does not enter low -pow er
consumption state nor is it reset.
6. When setting the FMR01 bit to 0 (CPU rew rite mode disabled), the FMR02 bit is set to 0 (disables rew rite).
Figure 19.5
FMR0 Register
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19. Flash Memory
Flash Memory Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
1
0 0 0
Symbol
FMR1
Bit Symbol
Address
01B5h
After Reset
1000000Xb
Function
Bit Name
RW
—
(b0)
Reserved bit
When read, the content is undefined.
RO
RW
RW
RW
RW
RW
EW1 mode select bit(1, 2)
Reserved bits
0 : EW0 mode
1 : EW1 mode
FMR11
—
(b4-b2)
Set to 0.
Block 0 rew rite disable bit(2,3)
Block 1 rew rite disable bit(2,3)
Reserved bit
0 : Enables rew rite
1 : Disables rew rite
FMR15
FMR16
0 : Enables rew rite
1 : Disables rew rite
—
(b7)
Set to 1.
NOTES:
1. To set this bit to 1, set it to 1 immediately after setting it first to 0 w hile the FMR01 bit is set to 1 (CPU rew rite mode
enable) . Do not generate an interrupt betw een setting the bit to 0 and setting it to 1.
2. This bit is set to 0 by setting the FMR01 bit to 0 (CPU rew rite mode disabled).
3. When the FMR01 bit is set to 1 (CPU rew rite mode enabled), bits FMR15 and FMR16 can be w ritten to.
To set this bit to 0, set it to 0 immediately after setting it first to 1.
To set this bit to 1, set it to 1.
Figure 19.6
FMR1 Register
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19. Flash Memory
Flash Memory Control Register 4
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
01B3h
After Reset
01000000b
Function
FMR4
Bit Symbol
Bit Name
RW
RW
Erase-suspend function
enable bit(1)
Erase-suspend request bit(2)
0 : Disable
1 : Enable
FMR40
FMR41
FMR42
FMR43
FMR44
0 : Erase restart
RW
RW
RO
RO
RO
RO
RW
1 : Erase-suspend request
Program-suspend request bit(3) 0 : Program restart
1 : Program-suspend request
0 : Erase not executed
Erase command flag
Program command flag
Reserved bit
1 : Erase execution in progress
0 : Program not executed
1 : Program execution in progress
—
(b5)
Set to 0.
Read status flag
0 : Disables reading
1 : Enables reading
FMR46
FMR47
Low -pow er consumption read 0 : Disable
mode enable bit (1, 4, 5)
1 : Enable
NOTES:
1. To set this bit to 1, set it to 1 immediately after setting it first to 0. Do not generate an interrupt betw een setting the bit
to 0 and setting it to 1.
2. This bit is enabled w hen the FMR40 bit is set to 1 (enable) and it can be w ritten to during the period betw een issuing
an erase command and completing the erase. (This bit is set to 0 during periods other than the above.)
In EW0 mode, it can be set to 0 or 1 by a program.
In EW1 mode, it is automatically set to 1 if a maskable interrupt is generated during an erase
operation w hile the FMR40 bit is set to 1. Do not set this bit to 1 by a program (0 can be w ritten).
3. The FMR42 bit is enabled only w hen the FMR40 bit is set to 1 (enable) and programming to the FMR42 bit is enabled
until auto-programming ends after a program command is generated. (This bit is set to 0 during periods other than the
above.)
In EW0 mode, 0 or 1 can be programmed to the FMR42 bit by a program.
In EW1 mode, the FMR42 bit is automatically set to 1 by generating a maskable interrupt during auto-programming
w hen the FMR40 bit is set to 1. 1 cannot be w ritten to the FMR42 bit by a program.
4. In high-speed clock mode and high-speed on-chip oscillator mode, set the FMR47 bit to 0 (disabled).
5. Set the FMR01 bit in the FMR0 register to 0 (CPU rew rite mode disabled) in low -pow er-consumption read mode.
Figure 19.7
FMR4 Register
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19. Flash Memory
Figure 19.8 shows the Timing of Suspend Operation.
Erasure
starts
Erasure
suspends
Programming Programming Programming Programming Erasure
starts suspends restarts ends restarts
Erasure
ends
During programming
During programming
During erasure
During erasure
1
0
FMR00 bit in
FMR0 register
Remains 0 during suspend
1
0
FMR46 bit in
FMR4 register
1
0
FMR44 bit in
FMR4 register
1
0
FMR43 bit in
FMR4 register
Remains 1 during suspend
Check that the
FMR43 bit is set to 1
(during erase
execution), and that
the erase-operation
has not ended.
Check that the
Check the status,
and that the
programming ends
normally.
Check the status,
and that the
erasure ends
normally.
FMR44 bit is set to 1
(during program
execution), and that
the program has not
ended.
The above figure shows an example of the use of program-suspend during programming following erase-suspend.
NOTE:
1. If program-suspend is entered during erase-suspend, always restart programming.
Figure 19.8
Timing of Suspend Operation
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19. Flash Memory
Figure 19.9 shows the How to Set and Exit EW0 Mode. Figure 19.10 shows the How to Set and Exit EW1
Mode.
EW0 Mode Operating Procedure
Rewrite control program
Write 0 to the FMR01 bit before writing 1
(CPU rewrite mode enabled)(2)
Set registers(1) CM0 and CM1
Execute software commands
Transfer a rewrite control program which uses CPU
Execute the read array command(3)
rewrite mode to the RAM.
Write 0 to the FMR01 bit
Jump to the rewrite control program which has been
transferred to the RAM.
(CPU rewrite mode disabled)
(The subsequent process is executed by the rewrite
control program in the RAM.)
Jump to a specified address in the flash memory
NOTES:
1. Select 5 MHz or below for the CPU clock by the CM06 bit in the CM0 register and bits CM16 to CM17 in the CM1 register.
2. To set the FMR01 bit to 1, write 0 to the FMR01 bit before writing 1. Do not generate an interrupt between writing 0 and 1.
Write to the FMR01 bit in the RAM.
3. Disable the CPU rewrite mode after executing the read array command.
Figure 19.9
How to Set and Exit EW0 Mode
EW1 Mode Operating Procedure
Program in ROM
Write 0 to the FMR01 bit before writing 1 (CPU
rewrite mode enabled)(1)
Write 0 to the FMR11 bit before writing 1 (EW1
mode)
Execute software commands
Write 0 to the FMR01 bit
(CPU rewrite mode disabled)
NOTE:
1. To set the FMR01 bit to 1, write 0 to the FMR01 bit before writing 1.
Do not generate an interrupt between writing 0 and 1.
Figure 19.10 How to Set and Exit EW1 Mode
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19. Flash Memory
High-speed on-chip oscillator mode,
low-speed on-chip oscillator mode
(XIN clock stops), and low-speed
clock mode (XIN clock stops)
program
Transfer a high-speed on-chip oscillator mode, low-
speed on-chip oscillator mode (XIN clock stops), and
low-speed clock mode (XIN clock stops) program to
the RAM.
Write 0 to the FMR01 bit before writing 1
(CPU rewrite mode enabled)
Write 1 to the FMSTP bit (flash memory stops.
Low power consumption mode)(1)
Jump to the high-speed on-chip oscillator mode, low-
speed on-chip oscillator mode (XIN clock stops), and
low-speed clock mode (XIN clock stops) program
which has been transferred to the RAM.
(The subsequent processing is executed by the
program in the RAM.)
Switch the clock source for the CPU clock.
Turn XIN off
Process in high-speed on-chip oscillator
mode, low-speed on-chip oscillator mode
(XIN clock stops), and low-speed clock
mode (XIN clock stops)
Turn XIN clock on → wait until oscillation
stabilizes → switch the clock source for CPU
clock(2)
Write 0 to the FMSTP bit
(flash memory operation)
Write 0 to the FMR01 bit
(CPU rewrite mode disabled)
NOTES:
1. Set the FMR01 bit to 1 (CPU rewrite mode enabled) before setting the
FMSTP bit to 1.
Wait until the flash memory circuit stabilizes
2. Before switching to a different clock source for the CPU, make sure
the designated clock is stable.
(30 µs)(3)
3. Insert a 30 µs wait time in a program. Do not access to the flash
memory during this wait time.
Jump to a specified address in the flash memory
Figure 19.11 Process to Reduce Power Consumption in High-Speed On-Chip Oscillator Mode,
Low-Speed On-Chip Oscillator Mode (XIN Clock Stops) and Low-Speed Clock Mode
(XIN Clock Stops)
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19. Flash Memory
19.4.3 Software Commands
The software commands are described below. Read or write commands and data in 8-bit units.
Table 19.4
Software Commands
First Bus Cycle
Address
Second Bus Cycle
Command
Data
(D7 to D0)
FFh
Data
Mode
Write
Mode
Address
(D7 to D0)
Read array
×
Read status register
Clear status register
Program
Write
Write
Write
Write
×
70h
Read
×
SRD
×
50h
WA
×
40h
Write
Write
WA
BA
WD
Block erase
20h
D0h
SRD: Status register data (D7 to D0)
WA: Write address (Ensure the address specified in the first bus cycle is the same address as the write
address specified in the second bus cycle.)
WD: Write data (8 bits)
BA: Given block address
×: Any specified address in the user ROM area
19.4.3.1 Read Array Command
The read array command reads the flash memory.
The MCU enters read array mode when FFh is written in the first bus cycle. When the read address is entered in
the following bus cycles, the content of the specified address can be read in 8-bit units.
Since the MCU remains in read array mode until another command is written, the contents of multiple
addresses can be read continuously.
In addition, the MCU enters read array mode after a reset.
19.4.3.2 Read Status Register Command
The read status register command is used to read the status register.
When 70h is written in the first bus cycle, the status register can be read in the second bus cycle (refer to 19.4.4
Status Registers). When reading the status register, specify an address in the user ROM area.
Do not execute this command in EW1 mode.
The MCU remains in read status register mode until the next read array command is written.
19.4.3.3 Clear Status Register Command
The clear status register command sets the status register to 0.
When 50h is written in the first bus cycle, bits FMR06 to FMR07 in the FMR0 register and SR4 to SR5 in the
status register are set to 0.
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19. Flash Memory
19.4.3.4 Program Command
The program command writes data to the flash memory in 1-byte units.
By writing 40h in the first bus cycle and data in the second bus cycle to the write address, an auto-program
operation (data program and verify) will start. Make sure the address value specified in the first bus cycle is the
same address as the write address specified in the second bus cycle.
The FMR00 bit in the FMR0 register can be used to determine whether auto-programming has completed.
When suspend function disabled, the FMR00 bit is set to 0 during auto-programming and set to 1 when auto-
programming completes.
When suspend function enabled, the FMR44 bit is set to 1 during auto-programming and set to 0 when auto-
programming completes.
The FMR06 bit in the FMR0 register can be used to determine the result of auto-programming after it has been
finished (refer to 19.4.5 Full Status Check).
Do not write additions to the already programmed addresses.
When the FMR02 bit in the FMR0 register is set to 0 (rewriting disabled) or the FMR02 bit is set to 1 (rewriting
enabled) and the FMR15 bit in the FMR1 register is set to 1 (rewriting disabled), program commands targeting
block 0 are not acknowledged. When the FMR16 bit is set to 1 (rewriting disabled), program commands
targeting block 1 are not acknowledged.
Figure 19.12 shows the Program Command (When Suspend Function Disabled). Figure 19.13 shows the
Program Command (When Suspend Function Enabled).
In EW1 mode, do not execute this command for any address which a rewrite control program is allocated.
In EW0 mode, the MCU enters read status register mode at the same time auto-programming starts and the
status register can be read. The status register bit 7 (SR7) is set to 0 at the same time auto-programming starts
and set back to 1 when auto-programming completes. In this case, the MCU remains in read status register
mode until the next read array command is written. The status register can be read to determine the result of
auto-programming after auto-programming has completed.
Start
Write the command code 40h to
the write address
Write data to the write address
No
FMR00 = 1?
Yes
Full status check
Program completed
Figure 19.12 Program Command (When Suspend Function Disabled)
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19. Flash Memory
Maskable interrupt(1)
FMR44 = 1 ?
EW0 Mode
Start
FMR40 = 1
No
Write the command code 40h
to the write address
Yes
FMR42 = 1(4)
I = 1 (enable interrupt)(3)
No
Access flash memory
FMR46 = 1 ?
Write data to the write address
Yes
Access flash memory
No
FMR44 = 0 ?
FMR42 = 0
REIT
Yes
Full status check
Program completed
Maskable interrupt (2)
Access flash memory
REIT
EW1 Mode
Start
FMR40 = 1
Write the command code 40h
I = 1 (enable interrupt)
Write data to the write address
FMR42 = 0
No
FMR44 = 0 ?
Yes
Full status check
Program completed
NOTES:
1. In EW0 mode, the interrupt vector table and interrupt routine for interrupts to be used should be allocated to the RAM area.
2. td(SR-SUS) is needed until the interrupt request is acknowledged after it is generated. The interrupt to enter suspend
should be in interrupt enabled status.
3. When no interrupt is used, the instruction to enable interrupts is not needed.
4. td(SR-SUS) is needed until program is suspended after the FMR42 bit in the FMR4 register is set to 1.
Figure 19.13 Program Command (When Suspend Function Enabled)
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19. Flash Memory
19.4.3.5 Block Erase
When 20h is written in the first bus cycle and D0h is written to a given address of a block in the second bus
cycle, an auto-erase operation (erase and verify) of the specified block starts.
The FMR00 bit in the FMR0 register can determine whether auto-erasure has completed.
The FMR00 bit is set to 0 during auto-erasure and set to 1 when auto-erasure completes.
The FMR07 bit in the FMR0 register can be used to determine the result of auto-erasure after auto-erasure has
completed (refer to 19.4.5 Full Status Check).
When the FMR02 bit in the FMR0 register is set to 0 (rewriting disabled) or the FMR02 bit is set to 1 (rewriting
enabled) and the FMR15 bit in the FMR1 register is set to 1 (rewriting disabled), the block erase commands
targeting block 0 are not acknowledged. When the FMR16 bit is set to 1 (rewriting disabled), the block erase
commands targeting block 1 are not acknowledged.
Do not use the block erase command during program-suspend.
Figure 19.14 shows the Block Erase Command (When Erase-Suspend Function Disabled). Figure 19.15 shows
the Block Erase Command (When Erase-Suspend Function Enabled).
In EW1 mode, do not execute this command for any address to which a rewrite control program is allocated.
In EW0 mode, the MCU enters read status register mode at the same time auto-erasure starts and the status
register can be read. The status register bit 7 (SR7) is set to 0 at the same time auto-erasure starts and set back to
1 when auto-erasure completes. In this case, the MCU remains in read status register mode until the next read
array command is written.
Start
Write the command code 20h
Write D0h to a given block
address
No
FMR00 = 1?
Yes
Full status check
Block erase completed
Figure 19.14 Block Erase Command (When Erase-Suspend Function Disabled)
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19. Flash Memory
EW0 Mode
Start
Maskable interrupt(1)
FMR43 = 1 ?
FMR40 = 1
No
Write the command code 20h
I = 1 (enable interrupt)(3)
Yes
FMR41 = 1(4)
No
Access flash memory
FMR46 = 1 ?
Write D0h to any block
address
Yes
Access flash memory
No
FMR00 = 1 ?
FMR41 = 0
REIT
Yes
Full status check
Block erase completed
Maskable interrupt (2)
Access flash memory
REIT
EW1 Mode
Start
FMR40 = 1
Write the command code 20h
I = 1 (enable interrupt)
Write D0h to any block
address
FMR41 = 0
No
FMR00 = 1 ?
Yes
Full status check
Block erase completed
NOTES:
1. In EW0 mode, the interrupt vector table and interrupt routine for interrupts to be used should be allocated to the RAM area.
2. td(SR-SUS) is needed until the interrupt request is acknowledged after it is generated. The interrupt to enter suspend
should be in interrupt enabled status.
3. When no interrupt is used, the instruction to enable interrupts is not needed.
4. td(SR-SUS) is needed until erase is suspended after the FMR41 bit in the FMR4 register is set to 1.
Figure 19.15 Block Erase Command (When Erase-Suspend Function Enabled)
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19. Flash Memory
19.4.4 Status Registers
The status register indicates the operating status of the flash memory and whether an erase or program operation
has completed normally or in error. Status of the status register can be read by bits FMR00, FMR06, and
FMR07 in the FMR0 register.
Table 19.5 lists the Status Register Bits.
In EW0 mode, the status register can be read in the following cases:
• When a given address in the user ROM area is read after writing the read status register command
• When a given address in the user ROM area is read after executing the program or block erase command
but before executing the read array command.
19.4.4.1 Sequencer Status (SR7 and FMR00 Bits)
The sequencer status bits indicate the operating status of the flash memory. SR7 is set to 0 (busy) during auto-
programming and auto-erasure, and is set to 1 (ready) at the same time the operation completes.
19.4.4.2 Erase Status (SR5 and FMR07 Bits)
Refer to 19.4.5 Full Status Check.
19.4.4.3 Program Status (SR4 and FMR06 Bits)
Refer to 19.4.5 Full Status Check.
Table 19.5
Status Register Bits
Description
FMR0 Register
Value after
Reset
Status Register Bit
Status Name
Bit
0
1
SR0 (D0)
SR1 (D1)
SR2 (D2)
SR3 (D3)
SR4 (D4)
−
−
−
−
Reserved
Reserved
Reserved
Reserved
−
−
−
−
−
−
−
−
−
0
−
−
−
FMR06
Program status Completed
normally
Error
SR5 (D5)
FMR07
Erase status
Completed
normally
−
Error
0
SR6 (D6)
SR7 (D7)
−
Reserved
Sequencer
status
−
−
FMR00
Busy
Ready
1
D0 to D7: Indicate the data bus which is read when the read status register command is executed.
Bits FMR07 (SR5) to FMR06 (SR4) are set to 0 by executing the clear status register command.
When the FMR07 bit (SR5) or FMR06 bit (SR4) is set to 1, the program and block erase commands cannot
be accepted.
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19. Flash Memory
19.4.5 Full Status Check
When an error occurs, bits FMR06 to FMR07 in the FMR0 register are set to 1, indicating the occurrence of an
error. Therefore, checking these status bits (full status check) can be used to determine the execution result.
Table 19.6 lists the Errors and FMR0 Register Status. Figure 19.16 shows the Full Status Check and Handling
Procedure for Individual Errors.
Table 19.6
Errors and FMR0 Register Status
FMR0 Register (Status
Register) Status
Error
Error Occurrence Condition
FMR07 (SR5) FMR06 (SR4)
1
1
Command
sequence
error
• When a command is not written correctly
• When invalid data other than that which can be written
in the second bus cycle of the block erase command is
written (i.e., other than D0h or FFh)(1)
• When the program command or block erase command
is executed while rewriting is disabled by the FMR02 bit
in the FMR0 register, or the FMR15 or FMR16 bit in the
FMR1 register.
• When an address not allocated in flash memory is input
during erase command input
• When attempting to erase the block for which rewriting
is disabled during erase command input.
• When an address not allocated in flash memory is input
during write command input.
• When attempting to write to a block for which rewriting
is disabled during the write command input.
• When the block erase command is executed but auto-
erasure does not complete correctly
1
0
0
1
Erase error
Program error • When the program command is executed but not auto-
programming does not complete.
NOTE:
1. The MCU enters read array mode when FFh is written in the second bus cycle of these commands.
At the same time, the command code written in the first bus cycle is disabled.
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19. Flash Memory
Command sequence error
Full status check
Execute the clear status register command
(set these status flags to 0)
FMR06 = 1
Yes
and
Command sequence error
FMR07 = 1?
Check if command is properly input
Re-execute the command
No
Yes
Erase error
FMR07 = 1?
Erase error
No
Execute the clear status register command
(set these status flags to 0)
Erase command
re-execution times ≤ 3 times?
No
Block targeting for erasure
cannot be used
Yes
Yes
FMR06 = 1?
Program error
Re-execute block erase command
No
Program error
Execute the clear status register
command
(set these status flags to 0)
Full status check completed
Specify the other address besides the
write address where the error occurs for
the program address(1)
NOTE:
1. To rewrite to the address where the program error occurs, check if the full
status check is complete normally and write to the address after the block
erase command is executed.
Re-execute program command
Figure 19.16 Full Status Check and Handling Procedure for Individual Errors
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19. Flash Memory
19.5 Standard Serial I/O Mode
In standard serial I/O mode, the user ROM area can be rewritten while the MCU is mounted on-board by using a
serial programmer which is suitable for the MCU.
There are three types of Standard serial I/O modes:
• Standard serial I/O mode 1 ............Clock synchronous serial I/O used to connect with a serial programmer
• Standard serial I/O mode 2 ............Clock asynchronous serial I/O used to connect with a serial programmer
• Standard serial I/O mode 3 ............Special clock asynchronous serial I/O used to connect with a serial
programmer
This MCU uses Standard serial I/O mode 2 and Standard serial I/O mode 3.
Refer to Appendix 2. Connection Examples between Serial Writer and On-Chip Debugging Emulator.
Contact the manufacturer of your serial programmer for details. Refer to the user’s manual of your serial
programmer for instructions on how to use it.
Table 19.7 lists the Pin Functions (Flash Memory Standard Serial I/O Mode 2), Table 19.8 lists the Pin Functions
(Flash Memory Standard Serial I/O Mode 3), and Figure 19.17 shows the Pin Connections for Standard Serial I/O
Mode 3.
After processing the pins shown in Table 19.8 and rewriting the flash memory using the programmer, apply “H” to
the MODE pin and reset the hardware to run a program in the flash memory in single-chip mode.
19.5.1 ID Code Check Function
The ID code check function determines whether the ID codes sent from the serial programmer and those written
in the flash memory match (refer to 19.3 Functions to Prevent Rewriting of Flash Memory).
Table 19.7
Pin
Pin Functions (Flash Memory Standard Serial I/O Mode 2)
Name
Power input
I/O
Description
VCC,VSS
Apply the voltage guaranteed for programming and
erasure to the VCC pin and 0 V to the VSS pin.
Reset input pin.
Reset input
I
RESET
P4_6/XIN/XCIN
P4_6 input/clock input
I
Connect a ceramic resonator or crystal oscillator
between the XIN/XCIN and XOUT/XCOUT pins.
P4_7/XOUT/XCOUT P4_7 input/clock output I/O
P0_0 to P0_7
P1_0 to P1_7
Input port P0
Input port P1
I
I
I
Input “H” or “L” level signal or leave the pin open.
P3_0, P3_1, P3_3 to Input port P3
P3_6
P4_2/VREF
P5_3, P5_4
MODE
Input port P4
Input port P5
MODE
I
I
I/O Input “L”.
P3_7
TXD output
RXD input
O
I
Serial data output pin.
Serial data input pin.
P4_5
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19. Flash Memory
Table 19.8
Pin
Pin Functions (Flash Memory Standard Serial I/O Mode 3)
Name I/O Description
Power input
VCC,VSS
Apply the voltage guaranteed for programming and
erasure to the VCC pin and 0 V to the VSS pin.
Reset input pin.
Reset input
I
RESET
P4_6/XIN/XCIN
P4_6 input/clock input
I
Connect a ceramic resonator or crystal oscillator
between the XIN/XCIN and XOUT/XCOUT pins
when connecting external oscillator. Apply “H” and
“L” or leave the pin open when using as input port.
P4_7/XOUT/XCOUT P4_7 input/clock output I/O
P0_0 to P0_7
P1_0 to P1_7
Input port P0
Input port P1
I
I
I
Input “H” or “L” level signal or leave the pin open.
P3_0, P3_1, P3_3 to Input port P3
P3_7
P4_2/VREF, P4_5
P5_3, P5_4
MODE
Input port P4
Input port P5
MODE
I
I
I/O Serial data I/O pin. Connect to the flash
programmer.
24 23 22 21 20 19 18 17
16
15
14
13
12
11
10
9
25
26
27
28
29
30
31
32
R8C/26 Group
R8C/27 Group
1
2
3
4
5
6
7
8
MODE
VSS
VCC
Connect oscillator circuit(1)
Value
Mode setting
Signal
Package: PLQP0032GB-A
Voltage from programmer
MODE
NOTE:
VSS → VCC
RESET
1. It is not necessary to connect an oscillating circuit
when operating with the on-chip oscillator clock.
Figure 19.17 Pin Connections for Standard Serial I/O Mode 3
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19. Flash Memory
19.5.1.1 Example of Circuit Application in the Standard Serial I/O Mode
Figure 19.18 shows an Example of Pin Processing in Standard Serial I/O Mode 2, Figure 19.19 shows an
Example of Pin Processing in Standard Serial I/O Mode 3. Since the controlled pins vary depending on the
programmer, refer to the manual of your serial programmer for details.
MCU
Data Output
Data Input
TXD
RXD
MODE
NOTES:
1. In this example, modes are switched between single-chip mode and
standard serial I/O mode by controlling the MODE input with a switch.
2. Connecting the oscillation is necessary. Set the main clock frequency 1
MHz to 20 MHz. Refer to Appendix Figure 2.1 Connection Example with
M16C Flash Starter (M3A-0806).
Figure 19.18 Example of Pin Processing in Standard Serial I/O Mode 2
MCU
MODE
MODE I/O
Reset input
RESET
User reset signal
NOTES:
1. Controlled pins and external circuits vary depending on the programmer.
Refer to the programmer manual for details.
2. In this example, modes are switched between single-chip mode and
standard serial I/O mode by connecting a programmer.
3. When operating with the on-chip oscillator clock, it is not necessary to
connect an oscillating circuit.
Figure 19.19 Example of Pin Processing in Standard Serial I/O Mode 3
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19. Flash Memory
19.6 Parallel I/O Mode
Parallel I/O mode is used to input and output software commands, addresses and data necessary to control (read,
program, and erase) the on-chip flash memory. Use a parallel programmer which supports this MCU. Contact the
manufacturer of the parallel programmer for more information, and refer to the user’s manual of the parallel
programmer for details on how to use it.
ROM areas shown in Figures 19.1 and 19.2 can be rewritten in parallel I/O mode.
19.6.1 ROM Code Protect Function
The ROM code protect function disables the reading and rewriting of the flash memory. (Refer to 19.3
Functions to Prevent Rewriting of Flash Memory.)
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19. Flash Memory
19.7 Notes on Flash Memory
19.7.1 CPU Rewrite Mode
19.7.1.1 Operating Speed
Before entering CPU rewrite mode (EW0 mode), select 5 MHz or below for the CPU clock using the CM06 bit
in the CM0 register and bits CM16 to CM17 in the CM1 register.
This does not apply to EW1 mode.
19.7.1.2 Prohibited Instructions
The following instructions cannot be used in EW0 mode because they reference internal data in flash memory:
UND, INTO, and BRK.
19.7.1.3 Interrupts
Table 19.9 lists the EW0 Mode Interrupts and Table 19.10 lists the EW1 Mode Interrupt.
Table 19.9
Mode
EW0 Mode Interrupts
When Watchdog Timer, Oscillation Stop
Detection, Voltage Monitor 1, or Voltage
Monitor 2 Interrupt Request is
When Maskable Interrupt
Request is Acknowledged
Status
Acknowledged
EW0 During auto-erasure Any interrupt can be used by
allocating a vector in RAM
Once an interrupt request is
acknowledged, the auto-programming
or auto-erasure is forcibly stopped
immediately and the flash memory is
reset. Interrupt handling starts after the
fixed period and the flash memory
restarts. Since the block during auto-
erasure or the address during auto-
programming is forcibly stopped, the
normal value may not be read. Execute
auto-erasure again and ensure it
completes normally.
Auto-programming
Since the watchdog timer does not stop
during the command operation,
interrupt requests may be generated.
Reset the watchdog timer regularly.
NOTES:
1. Do not use the address match interrupt while a command is being executed because the vector of
the address match interrupt is allocated in ROM.
2. Do not use a non-maskable interrupt while block 0 is being automatically erased because the fixed
vector is allocated in block 0.
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19. Flash Memory
Table 19.10 EW1 Mode Interrupt
When Watchdog Timer, Oscillation Stop
Detection, Voltage Monitor 1, or Voltage
Monitor 2 Interrupt Request is
Acknowledged
When Maskable Interrupt
Request is Acknowledged
Mode
Status
EW1 During auto-erasure Auto-erasure is suspended after Once an interrupt request is
(erase-suspend
function enabled)
td(SR-SUS) and interrupt
handling is executed. Auto-
erasure can be restarted by
setting the FMR41 bit in the
acknowledged, auto-programming or
auto-erasure is forcibly stopped
immediately and the flash memory is
reset. Interrupt handling starts after the
FMR4 register to 0 (erase restart) fixed period and the flash memory
after interrupt handling
completes.
restarts. Since the block during auto-
erasure or the address during auto-
programming is forcibly stopped, the
normal value may not be read. Execute
auto-erasure again and ensure it
completes normally.
Since the watchdog timer does not stop
during the command operation,
interrupt requests may be generated.
Reset the watchdog timer regularly
using the erase-suspend function.
During auto-erasure Auto-erasure has priority and the
(erase-suspend
function disabled)
interrupt request
acknowledgement is put on
standby. Interrupt handling is
executed after auto-erasure
completes.
During auto-
programming
(program suspend
function enabled)
Auto-programming is suspended
after td(SR-SUS) and interrupt
handling is executed.
Auto-programming can be
restarted by setting the FMR42 bit
in the FMR4 register to 0
(program restart) after interrupt
handling completes.
During auto-
programming
(program suspend
function disabled)
Auto-programming has priority
and the interrupt request
acknowledgement is put on
standby. Interrupt handling is
executed after auto-programming
completes.
NOTES:
1. Do not use the address match interrupt while a command is executing because the vector of the
address match interrupt is allocated in ROM.
2. Do not use a non-maskable interrupt while block 0 is being automatically erased because the fixed
vector is allocated in block 0.
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19. Flash Memory
19.7.1.4 How to Access
Write 0 before writing 1 when setting the FMR01, FMR02, or FMR11 bit to 1. Do not generate an interrupt
between writing 0 and 1.
19.7.1.5 Rewriting User ROM Area
In EW0 Mode, if the supply voltage drops while rewriting any block in which a rewrite control program is
stored, it may not be possible to rewrite the flash memory because the rewrite control program cannot be
rewritten correctly. In this case, use standard serial I/O mode.
19.7.1.6 Program
Do not write additions to the already programmed address.
19.7.1.7 Entering Stop Mode or Wait Mode
Do not enter stop mode or wait mode during erase-suspend.
19.7.1.8 Program and Erase Voltage for Flash Memory
To perform programming and erasure, use VCC = 2.7 to 5.5 V as the supply voltage. Do not perform
programming and erasure at less than 2.7 V.
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20. Electrical Characteristics
20. Electrical Characteristics
20.1 N, D Version
Table 20.1
Absolute Maximum Ratings
Symbol
Parameter
Supply voltage
Condition
Rated Value
Unit
V
VCC/AVCC
-0.3 to 6.5
-0.3 to VCC + 0.3
-0.3 to VCC + 0.3
500
VI
Input voltage
V
VO
Pd
Output voltage
V
Power dissipation
Topr = 25°C
mW
°C
Topr
Operating ambient temperature
-20 to 85 (N version) /
-40 to 85 (D version)
Tstg
Storage temperature
-65 to 150
°C
Table 20.2
Recommended Operating Conditions
Standard
Symbol
Parameter
Conditions
Unit
Min.
Typ.
−
Max.
5.5
VCC/AVCC Supply voltage
2.2
V
V
VSS/AVSS
VIH
Supply voltage
−
0
−
Input “H” voltage
0.8 VCC
−
VCC
V
VIL
Input “L” voltage
0
−
0.2 VCC
-160
V
IOH(sum)
Peak sum output Sum of all pins IOH(peak)
“H” current
−
−
mA
IOH(sum)
IOH(peak)
IOH(avg)
IOL(sum)
IOL(sum)
IOL(peak)
IOL(avg)
f(XIN)
Average sum
output “H” current
Peak output “H”
current
Sum of all pins IOH(avg)
−
−
-80
mA
Except P1_0 to P1_7
P1_0 to P1_7
−
−
−
−
−
−
−
−
−
−
-10
-40
-5
mA
mA
mA
mA
mA
Average output
“H” current
Except P1_0 to P1_7
P1_0 to P1_7
-20
160
Peak sum output Sum of all pins IOL(peak)
“L” currents
Average sum
output “L” currents
Peak output “L”
currents
Sum of all pins IOL(avg)
−
−
80
mA
Except P1_0 to P1_7
P1_0 to P1_7
−
−
−
−
0
0
0
0
0
0
0
−
−
−
10
40
5
mA
mA
Average output
“L” current
Except P1_0 to P1_7
P1_0 to P1_7
−
mA
−
20
20
10
5
mA
XIN clock input oscillation frequency
3.0 V ≤ VCC ≤ 5.5 V
2.7 V ≤ VCC < 3.0 V
2.2 V ≤ VCC < 2.7 V
2.2 V ≤ VCC ≤ 5.5 V
3.0 V ≤ VCC ≤ 5.5 V
2.7 V ≤ VCC < 3.0 V
2.2 V ≤ VCC < 2.7 V
−
MHz
MHz
MHz
kHz
MHz
MHz
MHz
kHz
−
−
f(XCIN)
XCIN clock input oscillation frequency
−
70
20
10
5
−
System clock
OCD2 = 0
XlN clock selected
−
−
−
OCD2 = 1
FRA01 = 0
125
−
Low-speed on-chip
oscillator clock selected
On-chip oscillator clock
selected
FRA01 = 1
−
−
−
−
−
−
20
10
5
MHz
MHz
MHz
High-speed on-chip
oscillator clock selected
3.0 V ≤ VCC ≤ 5.5 V
FRA01 = 1
High-speed on-chip
oscillator clock selected
2.7 V ≤ VCC ≤ 5.5 V
FRA01 = 1
High-speed on-chip
oscillator clock selected
2.2 V ≤ VCC ≤ 5.5 V
NOTES:
1. VCC = 2.2 to 5.5 V at Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
2. The average output current indicates the average value of current measured during 100 ms.
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20. Electrical Characteristics
Table 20.3
A/D Converter Characteristics
Standard
Unit
Symbol
Parameter
Conditions
Min.
−
Typ.
−
Max.
10
±3
±2
±5
±2
±5
±2
40
−
−
−
Resolution
Vref = AVCC
Bits
LSB
LSB
LSB
LSB
LSB
LSB
kΩ
Absolute
accuracy
10-bit mode
8-bit mode
10-bit mode
8-bit mode
10-bit mode
8-bit mode
φAD = 10 MHz, Vref = AVCC = 5.0 V
φAD = 10 MHz, Vref = AVCC = 5.0 V
φAD = 10 MHz, Vref = AVCC = 3.3 V
φAD = 10 MHz, Vref = AVCC = 3.3 V
φAD = 5 MHz, Vref = AVCC = 2.2 V
φAD = 5 MHz, Vref = AVCC = 2.2 V
Vref = AVCC
−
−
−
−
−
−
−
−
−
−
−
−
Rladder
Resistor ladder
10
3.3
2.8
2.2
0
−
tconv
Conversion time 10-bit mode
8-bit mode
φAD = 10 MHz, Vref = AVCC = 5.0 V
φAD = 10 MHz, Vref = AVCC = 5.0 V
−
µs
−
−
µs
Vref
VIA
−
Reference voltage
Analog input voltage(2)
−
AVCC
AVCC
10
10
5
V
−
V
A/D operating
clock frequency
Without sample and hold Vref = AVCC = 2.7 to 5.5 V
0.25
1
−
MHz
MHz
MHz
MHz
With sample and hold
Vref = AVCC = 2.7 to 5.5 V
−
Without sample and hold Vref = AVCC = 2.2 to 5.5 V
With sample and hold Vref = AVCC = 2.2 to 5.5 V
0.25
1
−
−
5
NOTES:
1. AVCC = 2.2 to 5.5 V at Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
2. When the analog input voltage is over the reference voltage, the A/D conversion result will be 3FFh in 10-bit mode and FFh in
8-bit mode.
P0
P1
30pF
P3
P4
P5
Figure 20.1
Ports P0, P1, and P3 to P5 Timing Measurement Circuit
Rev.2.10 Sep 26, 2008 Page 383 of 453
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20. Electrical Characteristics
Table 20.4
Flash Memory (Program ROM) Electrical Characteristics
Standard
Unit
Symbol
Parameter
Conditions
R8C/26 Group
Min.
100(3)
Typ.
−
Max.
−
Program/erase endurance(2)
−
times
times
µs
1,000(3)
R8C/27 Group
−
−
−
Byte program time
Block erase time
−
−
−
50
0.4
−
400
9
−
s
td(SR-SUS)
Time delay from suspend request until
suspend
97 + CPU clock
× 6 cycles
µs
−
−
−
Interval from erase start/restart until
following suspend request
650
0
−
−
−
−
µs
ns
µs
Interval from program start/restart until
following suspend request
−
Time from suspend until program/erase
restart
−
3 + CPU clock
× 4 cycles
−
−
−
−
Program, erase voltage
Read voltage
2.7
2.2
0
−
−
−
−
5.5
5.5
60
−
V
V
Program, erase temperature
Data hold time(7)
°C
Ambient temperature = 55°C
20
year
NOTES:
1. VCC = 2.7 to 5.5 V at Topr = 0 to 60°C, unless otherwise specified.
2. Definition of programming/erasure endurance
The programming and erasure endurance is defined on a per-block basis.
If the programming and erasure endurance is n (n = 100 or 1,000), each block can be erased n times. For example, if 1,024
1-byte writes are performed to different addresses in block A, a 1 Kbyte block, and then the block is erased, the
programming/erasure endurance still stands at one.
However, the same address must not be programmed more than once per erase operation (overwriting prohibited).
3. Endurance to guarantee all electrical characteristics after program and erase. (1 to Min. value can be guaranteed).
4. In a system that executes multiple programming operations, the actual erasure count can be reduced by writing to sequential
addresses in turn so that as much of the block as possible is used up before performing an erase operation. For example,
when programming groups of 16 bytes, the effective number of rewrites can be minimized by programming up to 128 groups
before erasing them all in one operation. It is also advisable to retain data on the erasure endurance of each block and limit
the number of erase operations to a certain number.
5. If an error occurs during block erase, attempt to execute the clear status register command, then execute the block erase
command at least three times until the erase error does not occur.
6. Customers desiring program/erase failure rate information should contact their Renesas technical support representative.
7. The data hold time includes time that the power supply is off or the clock is not supplied.
Rev.2.10 Sep 26, 2008 Page 384 of 453
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20. Electrical Characteristics
(4)
Table 20.5
Flash Memory (Data flash Block A, Block B) Electrical Characteristics
Standard
Unit
Symbol
Parameter
Conditions
Min.
10,000(3)
−
Typ.
−
Max.
−
Program/erase endurance(2)
−
−
times
Byte program time
50
400
µs
(program/erase endurance ≤ 1,000 times)
−
Byte program time
(program/erase endurance > 1,000 times)
−
−
65
0.2
0.3
−
−
9
−
µs
s
−
Block erase time
(program/erase endurance ≤ 1,000 times)
−
Block erase time
(program/erase endurance > 1,000 times)
−
s
td(SR-SUS)
Time delay from suspend request until
suspend
−
97 + CPU clock
× 6 cycles
µs
µs
ns
µs
−
−
−
Interval from erase start/restart until
following suspend request
650
0
−
−
Interval from program start/restart until
following suspend request
−
−
Time from suspend until program/erase
restart
−
−
3 + CPU clock
× 4 cycles
−
−
−
−
Program, erase voltage
Read voltage
2.7
2.2
-20(8)
20
−
−
−
−
5.5
5.5
85
−
V
V
Program, erase temperature
°C
Data hold time(9)
Ambient temperature = 55°C
year
NOTES:
1. VCC = 2.7 to 5.5 V at Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
2. Definition of programming/erasure endurance
The programming and erasure endurance is defined on a per-block basis.
If the programming and erasure endurance is n (n = 10,000), each block can be erased n times. For example, if 1,024 1-byte
writes are performed to different addresses in block A, a 1 Kbyte block, and then the block is erased, the
programming/erasure endurance still stands at one.
However, the same address must not be programmed more than once per erase operation (overwriting prohibited).
3. Endurance to guarantee all electrical characteristics after program and erase. (1 to Min. value can be guaranteed).
4. Standard of block A and block B when program and erase endurance exceeds 1,000 times. Byte program time to 1,000 times
is the same as that in program ROM.
5. In a system that executes multiple programming operations, the actual erasure count can be reduced by writing to sequential
addresses in turn so that as much of the block as possible is used up before performing an erase operation. For example,
when programming groups of 16 bytes, the effective number of rewrites can be minimized by programming up to 128 groups
before erasing them all in one operation. In addition, averaging the erasure endurance between blocks A and B can further
reduce the actual erasure endurance. It is also advisable to retain data on the erasure endurance of each block and limit the
number of erase operations to a certain number.
6. If an error occurs during block erase, attempt to execute the clear status register command, then execute the block erase
command at least three times until the erase error does not occur.
7. Customers desiring program/erase failure rate information should contact their Renesas technical support representative.
8. -40°C for D version.
9. The data hold time includes time that the power supply is off or the clock is not supplied.
Rev.2.10 Sep 26, 2008 Page 385 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Suspend request
(maskable interrupt request)
FMR46
Clock-dependent
time
Fixed time
Access restart
td(SR-SUS)
Figure 20.2
Time delay until Suspend
Table 20.6
Voltage Detection 0 Circuit Electrical Characteristics
Standard
Symbol
Parameter
Voltage detection level
Condition
Unit
Min.
Typ.
2.3
0.9
−
Max.
2.4
−
Vdet0
−
2.2
−
V
Voltage detection circuit self power consumption
Waiting time until voltage detection circuit operation
starts(2)
VCA25 = 1, VCC = 5.0 V
µA
µs
td(E-A)
−
300
Vccmin
MCU operating voltage minimum value
2.2
−
−
V
NOTES:
1. The measurement condition is VCC = 2.2 to 5.5 V and Topr = -20 to 85°C (N version) / -40 to 85°C (D version).
2. Necessary time until the voltage detection circuit operates when setting to 1 again after setting the VCA25 bit in the VCA2
register to 0.
Table 20.7
Voltage Detection 1 Circuit Electrical Characteristics
Standard
Typ.
2.85
40
Symbol
Vdet1
Parameter
Voltage detection level(4)
Voltage monitor 1 interrupt request generation time(2)
Voltage detection circuit self power consumption
Waiting time until voltage detection circuit operation
starts(3)
Condition
Unit
Min.
2.70
−
Max.
3.00
−
V
−
µs
µA
µs
−
VCA26 = 1, VCC = 5.0 V
−
0.6
−
td(E-A)
−
−
100
NOTES:
1. The measurement condition is VCC = 2.2 to 5.5 V and Topr = -20 to 85°C (N version) / -40 to 85°C (D version).
2. Time until the voltage monitor 1 interrupt request is generated after the voltage passes Vdet1.
3. Necessary time until the voltage detection circuit operates when setting to 1 again after setting the VCA26 bit in the VCA2
register to 0.
4. This parameter shows the voltage detection level when the power supply drops.
The voltage detection level when the power supply rises is higher than the voltage detection level when the power supply
drops by approximately 0.1 V.
Table 20.8
Voltage Detection 2 Circuit Electrical Characteristics
Standard
Typ.
3.6
Symbol
Vdet2
Parameter
Condition
Unit
Min.
3.3
−
Max.
3.9
−
V
Voltage detection level
Voltage monitor 2 interrupt request generation time(2)
Voltage detection circuit self power consumption
Waiting time until voltage detection circuit operation
starts(3)
−
40
µs
µA
µs
−
VCA27 = 1, VCC = 5.0 V
−
0.6
−
td(E-A)
−
−
100
NOTES:
1. The measurement condition is VCC = 2.2 to 5.5 V and Topr = -20 to 85°C (N version) / -40 to 85°C (D version).
2. Time until the voltage monitor 2 interrupt request is generated after the voltage passes Vdet2.
3. Necessary time until the voltage detection circuit operates after setting to 1 again after setting the VCA27 bit in the VCA2
register to 0.
Rev.2.10 Sep 26, 2008 Page 386 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
(3)
Table 20.9
Power-on Reset Circuit, Voltage Monitor 0 Reset Electrical Characteristics
Standard
Unit
Symbol
Parameter
Condition
Min.
−
Typ.
−
Max.
0.1
Power-on reset valid voltage(4)
Vpor1
Vpor2
V
V
Power-on reset or voltage monitor 0 reset valid
voltage
0
−
Vdet0
External power VCC rise gradient(2)
trth
20
−
−
mV/msec
NOTES:
1. The measurement condition is Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
2. This condition (external power VCC rise gradient) does not apply if VCC ≥ 1.0 V.
3. To use the power-on reset function, enable voltage monitor 0 reset by setting the LVD0ON bit in the OFS register to 0, the
VW0C0 and VW0C6 bits in the VW0C register to 1 respectively, and the VCA25 bit in the VCA2 register to 1.
4. tw(por1) indicates the duration the external power VCC must be held below the effective voltage (Vpor1) to enable a power on
reset. When turning on the power for the first time, maintain tw(por1) for 30 s or more if -20°C ≤ Topr ≤ 85°C, maintain tw(por1) for
3,000 s or more if -40°C ≤ Topr < -20°C.
(3)
Vdet0
(3)
Vdet0
2.2 V
trth
trth
External
Power VCC
Vpor2
Vpor1
Sampling time(1, 2)
tw(por1)
Internal
reset signal
(“L” valid)
1
1
× 32
× 32
fOCO-S
fOCO-S
NOTES:
1. When using the voltage monitor 0 digital filter, ensure that the voltage is within the MCU operation voltage
range (2.2 V or above) during the sampling time.
2. The sampling clock can be selected. Refer to 6. Voltage Detection Circuit for details.
3. Vdet0 indicates the voltage detection level of the voltage detection 0 circuit. Refer to 6. Voltage Detection
Circuit for details.
Figure 20.3
Reset Circuit Electrical Characteristics
Rev.2.10 Sep 26, 2008 Page 387 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.10 High-speed On-Chip Oscillator Circuit Electrical Characteristics
Standard
Typ.
Symbol
Parameter
Condition
Unit
Min.
39.2
Max.
40.8
fOCO40M
High-speed on-chip oscillator frequency
temperature • supply voltage dependence
VCC = 4.75 to 5.25 V
0°C ≤ Topr ≤ 60°C(2)
VCC = 3.0 to 5.5 V
40
MHz
38.8
38.4
38
40
40
40
40
40
40
40
40
41.2
41.6
42
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
-20°C ≤ Topr ≤ 85°C(2)
VCC = 3.0 to 5.5 V
-40°C ≤ Topr ≤ 85°C(2)
VCC = 2.7 to 5.5 V
-20°C ≤ Topr ≤ 85°C(2)
VCC = 2.7 to 5.5 V
37.6
35.2
34
42.4
44.8
46
-40°C ≤ Topr ≤ 85°C(2)
VCC = 2.2 to 5.5 V
-20°C ≤ Topr ≤ 85°C(3)
VCC = 2.2 to 5.5 V
-40°C ≤ Topr ≤ 85°C(3)
VCC = 5.0 V ± 10%
-20°C ≤ Topr ≤ 85°C(2)
VCC = 5.0 V ± 10%
-40°C ≤ Topr ≤ 85°C(2)
VCC = 5.0 V, Topr = 25°C
38.8
38.4
40.8
40.8
High-speed on-chip oscillator frequency when
correction value in FRA7 register is written to
FRA1 register(4)
−
36.864
−
MHz
%
VCC = 3.0 to 5.5 V
-20°C ≤ Topr ≤ 85°C
-3%
−
3%
08h(3)
F7h(3)
−
−
Value in FRA1 register after reset
−
−
Oscillation frequency adjustment unit of high-
speed on-chip oscillator
Adjust FRA1 register
(value after reset) to -1
−
+0.3
−
MHz
−
−
Oscillation stability time
−
−
10
100
µs
Self power consumption at oscillation
VCC = 5.0 V, Topr = 25°C
400
−
µA
NOTES:
1. VCC = 2.2 to 5.5 V, Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
2. These standard values show when the FRA1 register value after reset is assumed.
3. These standard values show when the corrected value of the FRA6 register is written to the FRA1 register.
4. This enables the setting errors of bit rates such as 9600 bps and 38400 bps to be 0% when the serial interface is used in
UART mode.
Table 20.11 Low-speed On-Chip Oscillator Circuit Electrical Characteristics
Standard
Symbol
fOCO-S
Parameter
Condition
Unit
Min.
30
−
Typ.
125
10
Max.
250
100
−
Low-speed on-chip oscillator frequency
Oscillation stability time
kHz
µs
−
−
Self power consumption at oscillation
VCC = 5.0 V, Topr = 25°C
−
15
µA
NOTE:
1. VCC = 2.2 to 5.5 V, Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
Table 20.12 Power Supply Circuit Timing Characteristics
Standard
Symbol
td(P-R)
Parameter
Condition
Unit
Min.
1
Typ.
Max.
2000
Time for internal power supply stabilization during
power-on(2)
−
µs
STOP exit time(3)
td(R-S)
−
−
150
µs
NOTES:
1. The measurement condition is VCC = 2.2 to 5.5 V and Topr = 25°C.
2. Waiting time until the internal power supply generation circuit stabilizes during power-on.
3. Time until system clock supply starts after the interrupt is acknowledged to exit stop mode.
Rev.2.10 Sep 26, 2008 Page 388 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
(1)
Table 20.13 Timing Requirements of Clock Synchronous Serial I/O with Chip Select
Standard
Unit
Symbol
tSUCYC
Parameter
Conditions
Min.
Typ.
−
Max.
−
(2)
tCYC
SSCK clock cycle time
SSCK clock “H” width
SSCK clock “L” width
4
tHI
0.4
−
0.6
0.6
1
tSUCYC
tSUCYC
tLO
0.4
−
(2)
tRISE
SSCK clock rising
time
Master
Slave
−
−
tCYC
−
−
1
µs
(2)
tFALL
SSCK clock falling
time
Master
Slave
−
−
1
tCYC
−
100
−
1
µs
tSU
SSO, SSI data input setup time
SSO, SSI data input hold time
−
−
ns
(2)
tH
1
−
−
tCYC
tLEAD
Slave
Slave
1tCYC + 50
−
−
ns
ns
SCS setup time
SCS hold time
tLAG
tOD
tSA
1tCYC + 50
−
−
(2)
SSO, SSI data output delay time
SSI slave access time
−
−
−
−
−
−
−
−
−
−
1
tCYC
2.7 V ≤ VCC ≤ 5.5 V
2.2 V ≤ VCC < 2.7 V
2.7 V ≤ VCC ≤ 5.5 V
2.2 V ≤ VCC < 2.7 V
1.5tCYC + 100
1.5tCYC + 200
1.5tCYC + 100
1.5tCYC + 200
ns
ns
ns
ns
tOR
SSI slave out open time
NOTES:
1. VCC = 2.2 to 5.5 V, VSS = 0 V at Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
2. 1tCYC = 1/f1(s)
Rev.2.10 Sep 26, 2008 Page 389 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
4-Wire Bus Communication Mode, Master, CPHS = 1
VIH or VOH
SCS (output)
VIH or VOH
tHI
tFALL
tRISE
SSCK (output)
(CPOS = 1)
tLO
tHI
SSCK (output)
(CPOS = 0)
tLO
tSUCYC
SSO (output)
SSI (input)
tOD
tSU
tH
4-Wire Bus Communication Mode, Master, CPHS = 0
VIH or VOH
SCS (output)
VIH or VOH
tHI
tFALL
tRISE
SSCK (output)
(CPOS = 1)
tLO
tHI
SSCK (output)
(CPOS = 0)
tLO
tSUCYC
SSO (output)
SSI (input)
tOD
tSU
tH
CPHS, CPOS: Bits in SSMR register
Figure 20.4
I/O Timing of Clock Synchronous Serial I/O with Chip Select (Master)
Rev.2.10 Sep 26, 2008 Page 390 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
4-Wire Bus Communication Mode, Slave, CPHS = 1
VIH or VOH
SCS (input)
VIH or VOH
tLEAD
tHI
tFALL
tRISE
tLAG
SSCK (input)
(CPOS = 1)
tLO
tHI
SSCK (input)
(CPOS = 0)
tLO
tSUCYC
SSO (input)
tSU
tH
SSI (output)
tSA
tOD
tOR
4-Wire Bus Communication Mode, Slave, CPHS = 0
VIH or VOH
SCS (input)
VIH or VOH
tHI
tFALL
tRISE
tLEAD
tLAG
SSCK (input)
(CPOS = 1)
tLO
tHI
SSCK (input)
(CPOS = 0)
tLO
tSUCYC
SSO (input)
tSU
tH
SSI (output)
tSA
tOD
tOR
CPHS, CPOS: Bits in SSMR register
Figure 20.5
I/O Timing of Clock Synchronous Serial I/O with Chip Select (Slave)
Rev.2.10 Sep 26, 2008 Page 391 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
tHI
VIH or VOH
VIH or VOH
SSCK
SSO (output)
SSI (input)
tLO
tSUCYC
tOD
tSU
tH
Figure 20.6
I/O Timing of Clock Synchronous Serial I/O with Chip Select (Clock Synchronous
Communication Mode)
Rev.2.10 Sep 26, 2008 Page 392 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
2
(1)
Table 20.14 Timing Requirements of I C bus Interface
Standard
Typ.
Unit
Symbol
tSCL
Parameter
SCL input cycle time
Condition
Min.
12tCYC + 600(2)
3tCYC + 300(2)
5tCYC + 500(2)
−
Max.
−
−
−
−
−
−
−
−
−
−
−
−
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
tSCLH
tSCLL
tsf
SCL input “H” width
−
SCL input “L” width
−
SCL, SDA input fall time
300
(2)
tSP
SCL, SDA input spike pulse rejection time
SDA input bus-free time
−
1tCYC
(2)
tBUF
−
−
−
−
−
−
5tCYC
(2)
tSTAH
tSTAS
tSTOP
tSDAS
tSDAH
Start condition input hold time
Retransmit start condition input setup time
Stop condition input setup time
Data input setup time
3tCYC
(2)
3tCYC
(2)
3tCYC
1tCYC + 20(2)
0
Data input hold time
NOTES:
1. VCC = 2.2 to 5.5 V, VSS = 0 V and Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.
2. 1tCYC = 1/f1(s)
VIH
SDA
VIL
tBUF
tSTAH
tSP
tSTOP
tSCLH
tSTAS
SCL
P(2)
S(1)
tsf
Sr(3)
P(2)
tSCLL
tsr
tSDAS
tSCL
tSDAH
NOTES:
1. Start condition
2. Stop condition
3. Retransmit start condition
2
Figure 20.7
I/O Timing of I C bus Interface
Rev.2.10 Sep 26, 2008 Page 393 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.15 Electrical Characteristics (1) [VCC = 5 V]
Standard
Unit
Symbol
VOH
Parameter
Condition
Min.
Typ.
−
Max.
VCC
VCC
VCC
VCC
VCC
VCC
2.0
Output “H” voltage Except P1_0 to P1_7, IOH = −5 mA
VCC - 2.0
V
V
V
V
V
V
V
V
V
V
V
V
V
XOUT
IOH = -200 µA
VCC - 0.5
−
P1_0 to P1_7
Drive capacity HIGH IOH = -20 mA
Drive capacity LOW IOH = -5 mA
Drive capacity HIGH IOH = -1 mA
Drive capacity LOW IOH = -500 µA
VCC - 2.0
−
VCC - 2.0
−
XOUT
VCC - 2.0
−
VCC - 2.0
−
VOL
Output “L” voltage Except P1_0 to P1_7, IOL = 5 mA
−
−
−
XOUT
IOL = 200 µA
−
0.45
2.0
P1_0 to P1_7
Drive capacity HIGH IOL = 20 mA
Drive capacity LOW IOL = 5 mA
Drive capacity HIGH IOL = 1 mA
Drive capacity LOW IOL = 500 µA
−
−
−
−
2.0
XOUT
−
−
2.0
−
−
2.0
VT+-VT-
Hysteresis
0.1
0.5
−
INT0, INT1, INT3,
KI0, KI1, KI2, KI3,
TRAIO, RXD0, RXD1,
CLK0, CLK1,
SSI, SCL, SDA, SSO
0.1
1.0
−
V
RESET
IIH
IIL
Input “H” current
Input “L” current
VI = 5 V, VCC = 5 V
VI = 0 V, VCC = 5 V
VI = 0 V, VCC = 5 V
−
−
−
−
5.0
-5.0
167
−
µA
µA
RPULLUP Pull-up resistance
30
−
50
1.0
kΩ
MΩ
RfXIN
Feedback
resistance
XIN
RfXCIN
Feedback
resistance
XCIN
−
18
−
−
MΩ
VRAM
RAM hold voltage
During stop mode
1.8
−
V
NOTE:
1. VCC = 4.2 to 5.5 V at Topr = -20 to 85°C (N version) / -40 to 85°C (D version), f(XIN) = 20 MHz, unless otherwise specified.
Rev.2.10 Sep 26, 2008 Page 394 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.16 Electrical Characteristics (2) [Vcc = 5 V]
(Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.)
Standard
Symbol
ICC
Parameter
Condition
Unit
mA
Min.
Typ.
10
Max.
17
Power supply current High-speed
XIN = 20 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
−
(VCC = 3.3 to 5.5 V)
Single-chip mode,
output pins are open,
other pins are VSS
clock mode
XIN = 16 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
−
−
−
−
−
−
−
−
−
−
−
9
6
15
−
mA
mA
mA
mA
mA
mA
mA
mA
mA
µA
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
XIN = 20 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
5
−
XIN = 16 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
4
−
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
2.5
10
4
−
High-speed
on-chip
oscillator
mode
XIN clock off
15
−
High-speed on-chip oscillator on fOCO = 20 MHz
Low-speed on-chip oscillator on = 125 kHz
No division
XIN clock off
High-speed on-chip oscillator on fOCO = 20 MHz
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
XIN clock off
5.5
2.5
130
130
10
−
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
No division
XIN clock off
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
Low-speed
on-chip
oscillator
mode
XIN clock off
300
300
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8, FMR47 = 1
Low-speed
clock mode
XIN clock off
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz
FMR47 = 1
XIN clock off
−
30
−
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz
Program operation on RAM
Flash memory off, FMSTP = 1
Rev.2.10 Sep 26, 2008 Page 395 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.17 Electrical Characteristics (3) [Vcc = 5 V]
(Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.)
Standard
Symbol
ICC
Parameter
Condition
XIN clock off
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock operation
Unit
Min.
Typ.
25
Max.
75
Power supply current Wait mode
(VCC = 3.3 to 5.5 V)
Single-chip mode,
output pins are open,
other pins are VSS
−
µA
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
−
−
−
23
4.0
2.2
60
µA
µA
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
−
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz (high drive)
While a WAIT instruction is executed
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
−
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz (low drive)
While a WAIT instruction is executed
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
Stop mode
XIN clock off, Topr = 25°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
−
−
0.8
1.2
3.0
µA
µA
XIN clock off, Topr = 85°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
−
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
Rev.2.10 Sep 26, 2008 Page 396 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Timing Requirements
(Unless Otherwise Specified: VCC = 5 V, VSS = 0 V at Topr = 25°C) [VCC = 5 V]
Table 20.18 XIN Input, XCIN Input
Standard
Unit
Symbol
tc(XIN)
Parameter
Min.
50
25
25
14
7
Max.
XIN input cycle time
XIN input “H” width
XIN input “L” width
XCIN input cycle time
XCIN input “H” width
XCIN input “L” width
−
−
−
−
−
−
ns
ns
ns
µs
µs
µs
tWH(XIN)
tWL(XIN)
tc(XCIN)
tWH(XCIN)
tWL(XCIN)
7
VCC = 5 V
tC(XIN)
tWH(XIN)
XIN input
tWL(XIN)
Figure 20.8
XIN Input and XCIN Input Timing Diagram when VCC = 5 V
Table 20.19 TRAIO Input
Standard
Max.
Symbol
Parameter
Unit
Min.
100
40
tc(TRAIO)
TRAIO input cycle time
TRAIO input “H” width
TRAIO input “L” width
−
−
−
ns
ns
ns
tWH(TRAIO)
tWL(TRAIO)
40
tC(TRAIO)
VCC = 5 V
tWH(TRAIO)
TRAIO input
tWL(TRAIO)
Figure 20.9
TRAIO Input Timing Diagram when VCC = 5 V
Rev.2.10 Sep 26, 2008 Page 397 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.20 Serial Interface
Standard
Unit
Symbol
Parameter
Min.
200
100
100
−
Max.
tc(CK)
CLKi input cycle time
CLKi input “H” width
CLKi input “L” width
TXDi output delay time
TXDi hold time
−
−
ns
ns
ns
ns
ns
ns
ns
tW(CKH)
tW(CKL)
td(C-Q)
th(C-Q)
tsu(D-C)
th(C-D)
−
50
−
0
RXDi input setup time
RXDi input hold time
50
−
90
−
i = 0 or 1
VCC = 5 V
tC(CK)
tW(CKH)
CLKi
tW(CKL)
th(C-Q)
TXDi
RXDi
td(C-Q)
tsu(D-C)
th(C-D)
i = 0 or 1
Figure 20.10 Serial Interface Timing Diagram when VCC = 5 V
Table 20.21 External Interrupt INTi (i = 0, 1, 3) Input
Standard
Symbol
tW(INH)
Parameter
Unit
Min.
Max.
250(1)
250(2)
−
ns
ns
INTi input “H” width
INTi input “L” width
tW(INL)
−
NOTES:
1. When selecting the digital filter by the INTi input filter select bit, use an INTi input HIGH width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
2. When selecting the digital filter by the INTi input filter select bit, use an INTi input LOW width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
VCC = 5 V
tW(INL)
INTi input
tW(INH)
i = 0, 1, 3
Figure 20.11 External Interrupt INTi Input Timing Diagram when VCC = 5 V
Rev.2.10 Sep 26, 2008 Page 398 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.22 Electrical Characteristics (3) [VCC = 3 V]
Standard
Unit
Symbol
VOH
Parameter
Output “H” voltage Except P1_0 to P1_7, IOH = -1 mA
Condition
Min.
Typ.
Max.
VCC
VCC - 0.5
−
V
V
V
V
V
V
V
V
V
V
V
XOUT
P1_0 to P1_7
Drive capacity
HIGH
IOH = -5 mA
IOH = -1 mA
VCC - 0.5
VCC - 0.5
−
−
VCC
VCC
VCC
VCC
0.5
0.5
0.5
0.5
0.5
−
Drive capacity
LOW
XOUT
Drive capacity
HIGH
IOH = -0.1 mA VCC - 0.5
−
Drive capacity
LOW
IOH = -50 µA
VCC - 0.5
−
VOL
Output “L” voltage
Except P1_0 to P1_7, IOL = 1 mA
XOUT
−
−
−
P1_0 to P1_7
Drive capacity
HIGH
IOL = 5 mA
IOL = 1 mA
IOL = 0.1 mA
IOL = 50 µA
−
Drive capacity
LOW
−
−
XOUT
Drive capacity
HIGH
−
−
Drive capacity
LOW
−
−
VT+-VT-
Hysteresis
0.1
0.3
INT0, INT1, INT3,
KI0, KI1, KI2, KI3,
TRAIO, RXD0, RXD1,
CLK0, CLK1,
SSI, SCL, SDA, SSO
0.1
0.4
−
V
RESET
IIH
IIL
Input “H” current
Input “L” current
VI = 3 V, VCC = 3 V
VI = 0 V, VCC = 3 V
VI = 0 V, VCC = 3 V
−
−
−
−
4.0
-4.0
500
−
µA
µA
kΩ
MΩ
MΩ
V
RPULLUP Pull-up resistance
66
−
160
3.0
18
−
RfXIN
Feedback resistance XIN
Feedback resistance XCIN
RAM hold voltage
RfXCIN
VRAM
−
−
During stop mode
1.8
−
NOTE:
1. VCC = 2.7 to 3.3 V at Topr = -20 to 85°C (N version) / -40 to 85°C (D version), f(XIN) = 10 MHz, unless otherwise specified.
Rev.2.10 Sep 26, 2008 Page 399 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.23 Electrical Characteristics (4) [Vcc = 3 V]
(Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.)
Standard
Symbol
ICC
Parameter
Condition
Unit
mA
Min.
Typ.
6
Max.
Power supply current High-speed
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
−
−
(VCC = 2.7 to 3.3 V)
Single-chip mode,
output pins are open,
other pins are VSS
clock mode
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
−
−
−
−
2
5
−
9
mA
mA
mA
µA
High-speed
on-chip
oscillator
mode
XIN clock off
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
No division
XIN clock off
2
−
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
Low-speed
on-chip
oscillator
mode
XIN clock off
130
300
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8, FMR47 = 1
Low-speed
clock mode
XIN clock off
−
−
130
30
300
µA
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz
FMR47 = 1
XIN clock off
−
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz
Program operation on RAM
Flash memory off, FMSTP = 1
Wait mode
XIN clock off
−
−
−
−
25
23
70
55
−
µA
µA
µA
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock operation
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
3.8
2.0
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz (high drive)
While a WAIT instruction is executed
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
−
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz (low drive)
While a WAIT instruction is executed
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
Stop mode
XIN clock off, Topr = 25°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
−
−
0.7
1.1
3.0
µA
µA
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
XIN clock off, Topr = 85°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
−
Rev.2.10 Sep 26, 2008 Page 400 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Timing requirements
(Unless Otherwise Specified: VCC = 3 V, VSS = 0 V at Topr = 25°C) [VCC = 3 V]
Table 20.24 XIN Input, XCIN Input
Standard
Unit
Symbol
tc(XIN)
Parameter
Min.
100
40
40
14
7
Max.
XIN input cycle time
XIN input “H” width
XIN input “L” width
XCIN input cycle time
XCIN input “H” width
XCIN input “L” width
−
−
−
−
−
−
ns
ns
ns
µs
µs
µs
tWH(XIN)
tWL(XIN)
tc(XCIN)
tWH(XCIN)
tWL(XCIN)
7
tC(XIN)
VCC = 3 V
tWH(XIN)
XIN input
tWL(XIN)
Figure 20.12 XIN Input and XCIN Input Timing Diagram when VCC = 3 V
Table 20.25 TRAIO Input
Standard
Symbol
Parameter
Unit
Min.
300
120
120
Max.
tc(TRAIO)
tWH(TRAIO)
tWL(TRAIO)
TRAIO input cycle time
TRAIO input “H” width
TRAIO input “L” width
−
−
−
ns
ns
ns
VCC = 3 V
tC(TRAIO)
tWH(TRAIO)
TRAIO input
tWL(TRAIO)
Figure 20.13 TRAIO Input Timing Diagram when VCC = 3 V
Rev.2.10 Sep 26, 2008 Page 401 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.26 Serial Interface
Standard
Unit
Symbol
Parameter
Min.
300
150
150
−
Max.
tc(CK)
CLKi input cycle time
CLKi input “H” width
CLKi Input “L” width
TXDi output delay time
TXDi hold time
−
−
ns
ns
ns
ns
ns
ns
ns
tW(CKH)
tW(CKL)
td(C-Q)
th(C-Q)
tsu(D-C)
th(C-D)
−
80
−
0
RXDi input setup time
RXDi input hold time
70
−
90
−
i = 0 or 1
tC(CK)
VCC = 3 V
tW(CKH)
CLKi
tW(CKL)
th(C-Q)
TXDi
RXDi
td(C-Q)
tsu(D-C)
th(C-D)
i = 0 or 1
Figure 20.14 Serial Interface Timing Diagram when VCC = 3 V
Table 20.27 External Interrupt INTi (i = 0, 1, 3) Input
Standard
Min. Max.
Symbol
tW(INH)
Parameter
Unit
380(1)
380(2)
−
−
ns
ns
INTi input “H” width
INTi input “L” width
tW(INL)
NOTES:
1. When selecting the digital filter by the INTi input filter select bit, use an INTi input HIGH width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
2. When selecting the digital filter by the INTi input filter select bit, use an INTi input LOW width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
VCC = 3 V
tW(INL)
INTi input
tW(INH)
i = 0, 1, 3
Figure 20.15 External Interrupt INTi Input Timing Diagram when VCC = 3 V
Rev.2.10 Sep 26, 2008 Page 402 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.28 Electrical Characteristics (5) [VCC = 2.2 V]
Standard
Unit
Symbol
VOH
Parameter
Output “H” voltage Except P1_0 to P1_7, IOH = -1 mA
Condition
Min.
Typ.
Max.
VCC
VCC - 0.5
−
V
V
V
V
V
V
V
V
V
V
V
XOUT
P1_0 to P1_7
Drive capacity
HIGH
IOH = -2 mA
IOH = -1 mA
VCC - 0.5
VCC - 0.5
−
−
VCC
VCC
VCC
VCC
0.5
0.5
0.5
0.5
0.5
−
Drive capacity
LOW
XOUT
Drive capacity
HIGH
IOH = -0.1 mA VCC - 0.5
−
Drive capacity
LOW
IOH = -50 µA
VCC - 0.5
−
VOL
Output “L” voltage
Except P1_0 to P1_7, IOL = 1 mA
XOUT
−
−
−
P1_0 to P1_7
Drive capacity
HIGH
IOL = 2 mA
IOL = 1 mA
IOL = 0.1 mA
IOL = 50 µA
−
Drive capacity
LOW
−
−
XOUT
Drive capacity
HIGH
−
−
Drive capacity
LOW
−
−
VT+-VT-
Hysteresis
0.05
0.3
INT0, INT1, INT3,
KI0, KI1, KI2, KI3,
TRAIO, RXD0, RXD1,
CLK0, CLK1,
SSI, SCL, SDA, SSO
0.05
0.15
−
V
RESET
IIH
IIL
Input “H” current
Input “L” current
VI = 2.2 V
VI = 0 V
VI = 0 V
−
−
−
−
4.0
-4.0
600
−
µA
µA
kΩ
MΩ
MΩ
V
RPULLUP Pull-up resistance
100
−
200
5
RfXIN
Feedback resistance XIN
Feedback resistance XCIN
RAM hold voltage
RfXCIN
VRAM
−
35
−
−
During stop mode
1.8
−
NOTE:
1. VCC = 2.2 V at Topr = -20 to 85°C (N version) / -40 to 85°C (D version), f(XIN) = 5 MHz, unless otherwise specified.
Rev.2.10 Sep 26, 2008 Page 403 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.29 Electrical Characteristics (6) [Vcc = 2.2 V]
(Topr = -20 to 85°C (N version) / -40 to 85°C (D version), unless otherwise specified.)
Standard
Symbol
ICC
Parameter
Condition
Unit
mA
Min.
Typ.
3.5
Max.
Power supply current High-speed
XIN = 5 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
−
−
(VCC = 2.2 to 2.7 V)
Single-chip mode,
output pins are open,
other pins are VSS
clock mode
XIN = 5 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
−
−
−
−
1.5
3.5
1.5
100
−
−
mA
mA
mA
µA
High-speed
on-chip
oscillator
mode
XIN clock off
High-speed on-chip oscillator on fOCO = 5 MHz
Low-speed on-chip oscillator on = 125 kHz
No division
XIN clock off
−
High-speed on-chip oscillator on fOCO = 5 MHz
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
Low-speed
on-chip
oscillator
mode
XIN clock off
230
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8, FMR47 = 1
Low-speed
clock mode
XIN clock off
−
−
100
25
230
µA
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz
FMR47 = 1
XIN clock off
−
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz
Program operation on RAM
Flash memory off, FMSTP = 1
Wait mode
XIN clock off
−
−
−
−
22
20
60
55
−
µA
µA
µA
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock operation
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
3.0
1.8
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz (high drive)
While a WAIT instruction is executed
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
−
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
XCIN clock oscillator on = 32 kHz (low drive)
While a WAIT instruction is executed
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
Stop mode
XIN clock off, Topr = 25°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
−
−
0.7
1.1
3.0
µA
µA
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
XIN clock off, Topr = 85°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
−
Rev.2.10 Sep 26, 2008 Page 404 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Timing requirements
(Unless Otherwise Specified: VCC = 2.2 V, VSS = 0 V at Topr = 25°C) [VCC = 2.2 V]
Table 20.30 XIN Input, XCIN Input
Standard
Symbol
tc(XIN)
Parameter
Unit
Min.
Max.
XIN input cycle time
XIN input “H” width
XIN input “L” width
XCIN input cycle time
XCIN input “H” width
XCIN input “L” width
200
90
90
14
7
−
−
−
−
−
−
ns
ns
ns
µs
µs
µs
tWH(XIN)
tWL(XIN)
tc(XCIN)
tWH(XCIN)
tWL(XCIN)
7
tC(XIN)
VCC = 2.2 V
tWH(XIN)
XIN input
tWL(XIN)
Figure 20.16 XIN Input and XCIN Input Timing Diagram when VCC = 2.2 V
Table 20.31 TRAIO Input
Standard
Symbol
Parameter
Unit
Min.
500
200
200
Max.
tc(TRAIO)
tWH(TRAIO)
tWL(TRAIO)
TRAIO input cycle time
TRAIO input “H” width
TRAIO input “L” width
−
−
−
ns
ns
ns
tC(TRAIO)
VCC = 2.2 V
tWH(TRAIO)
TRAIO input
tWL(TRAIO)
Figure 20.17 TRAIO Input Timing Diagram when VCC = 2.2 V
Rev.2.10 Sep 26, 2008 Page 405 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.32 Serial Interface
Standard
Unit
Symbol
Parameter
Min.
800
400
400
−
Max.
tc(CK)
CLKi input cycle time
CLKi input “H” width
CLKi input “L” width
TXDi output delay time
TXDi hold time
−
−
ns
ns
ns
ns
ns
ns
ns
tW(CKH)
tW(CKL)
td(C-Q)
th(C-Q)
tsu(D-C)
th(C-D)
−
200
−
0
RXDi input setup time
RXDi input hold time
150
90
−
−
i = 0 or 1
VCC = 2.2 V
tC(CK)
tW(CKH)
CLKi
tW(CKL)
th(C-Q)
TXDi
RXDi
td(C-Q)
tsu(D-C)
th(C-D)
i = 0 or 1
Figure 20.18 Serial Interface Timing Diagram when VCC = 2.2 V
Table 20.33 External Interrupt INTi (i = 0, 1, 3) Input
Standard
Min. Max.
Symbol
tW(INH)
Parameter
Unit
1000(1)
1000(2)
−
−
ns
ns
INTi input “H” width
INTi input “L” width
tW(INL)
NOTES:
1. When selecting the digital filter by the INTi input filter select bit, use an INTi input HIGH width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
2. When selecting the digital filter by the INTi input filter select bit, use an INTi input LOW width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
VCC = 2.2 V
tW(INL)
INTi input
tW(INH)
i = 0, 1, 3
Figure 20.19 External Interrupt INTi Input Timing Diagram when VCC = 2.2 V
Rev.2.10 Sep 26, 2008 Page 406 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
20.2 J, K Version
Table 20.34 Absolute Maximum Ratings
Symbol
Parameter
Condition
Rated Value
Unit
V
VCC/AVCC
Supply voltage
Input voltage
Output voltage
-0.3 to 6.5
-0.3 to VCC + 0.3
-0.3 to VCC + 0.3
300
VI
V
VO
Pd
V
Power dissipation
-40 °C ≤ Topr ≤ 85 °C
85 °C ≤ Topr ≤ 125 °C
mW
mW
°C
125
Topr
Tstg
Operating ambient temperature
Storage temperature
-40 to 85 (J version) /
-40 to 125 (K version)
-65 to 150
°C
Table 20.35 Recommended Operating Conditions
Standard
Symbol
Parameter
Conditions
Unit
Min.
Typ.
−
Max.
5.5
VCC/AVCC Supply voltage
2.7
V
V
VSS/AVSS
VIH
Supply voltage
−
0
−
Input “H” voltage
0.8 VCC
−
VCC
0.2 VCC
-60
V
VIL
Input “L” voltage
0
−
V
IOH(sum)
Peak sum output Sum of all pins
−
−
mA
“H” current
IOH(peak)
IOH(peak)
IOH(avg)
IOL(sum)
IOL(peak)
IOL(avg)
f(XIN)
Peak output “H”
current
−
−
−
−
−
0
−
−
−
−
−
−
-10
-5
mA
mA
mA
mA
mA
MHz
Average output
“H” current
Peak sum output Sum of all pins
“L” currents
60
10
5
IOL(peak)
Peak output “L”
currents
Average output
“L” current
XIN clock input oscillation frequency
3.0 V ≤ VCC ≤ 5.5 V (other than K
20
version)
3.0 V ≤ VCC ≤ 5.5 V (K version)
2.7 V ≤ VCC < 3.0 V
0
0
0
−
−
−
16
10
20
MHz
MHz
MHz
−
System clock
OCD2 = 0
3.0 V ≤ VCC ≤ 5.5 V (other than K
XlN clock selected version)
3.0 V ≤ VCC ≤ 5.5 V (K version)
0
0
−
−
−
16
10
−
MHz
MHz
kHz
2.7 V ≤ VCC < 3.0 V
OCD2 = 1
FRA01 = 0
125
On-chip oscillator Low-speed on-chip oscillator clock
clock selected
selected
FRA01 = 1
High-speed on-chip oscillator clock
selected (other than K version)
−
−
−
−
20
10
MHz
MHz
FRA01 = 1
High-speed on-chip oscillator clock
selected
NOTES:
1. VCC = 2.7 to 5.5 V at Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
2. The average output current indicates the average value of current measured during 100 ms.
Rev.2.10 Sep 26, 2008 Page 407 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.36 A/D Converter Characteristics
Standard
Unit
Symbol
Parameter
Conditions
Min.
−
Typ.
−
Max.
10
−
−
Resolution
Vref = AVCC
Bits
LSB
LSB
LSB
LSB
kΩ
Absolute
accuracy
10-bit mode
8-bit mode
10-bit mode
8-bit mode
φAD = 10 MHz, Vref = AVCC = 5.0 V
φAD = 10 MHz, Vref = AVCC = 5.0 V
φAD = 10 MHz, Vref = AVCC = 3.3 V
φAD = 10 MHz, Vref = AVCC = 3.3 V
Vref = AVCC
−
−
±3
−
−
±2
−
−
±5
−
−
±2
Rladder
Resistor ladder
10
3.3
2.8
2.7
0
−
40
tconv
Conversion time 10-bit mode
8-bit mode
φAD = 10 MHz, Vref = AVCC = 5.0 V
φAD = 10 MHz, Vref = AVCC = 5.0 V
−
−
µs
−
−
µs
Vref
VIA
−
Reference voltage
Analog input voltage(2)
−
AVCC
AVCC
10
V
−
V
A/D operating
clock frequency
Without sample and hold
With sample and hold
0.25
1
−
MHz
MHz
−
10
NOTES:
1. AVCC = 2.7 to 5.5 V at Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
2. When the analog input voltage is over the reference voltage, the A/D conversion result will be 3FFh in 10-bit mode and FFh in
8-bit mode.
P0
P1
30pF
P3
P4
P5
Figure 20.20 Ports P0, P1, and P3 to P5 Timing Measurement Circuit
Rev.2.10 Sep 26, 2008 Page 408 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.37 Flash Memory (Program ROM) Electrical Characteristics
Standard
Unit
Symbol
Parameter
Conditions
R8C/26 Group
Min.
100(3)
Typ.
−
Max.
−
Program/erase endurance(2)
−
times
times
µs
1,000(3)
R8C/27 Group
−
−
−
−
Byte program time
Block erase time
−
−
−
50
0.4
−
400
9
s
td(SR-SUS)
Time delay from suspend request until
suspend
97 + CPU clock
× 6 cycles
µs
−
−
−
Interval from erase start/restart until
following suspend request
650
0
−
−
−
−
µs
ns
µs
Interval from program start/restart until
following suspend request
−
Time from suspend until program/erase
restart
−
3 + CPU clock
× 4 cycles
−
−
−
−
Program, erase voltage
Read voltage
2.7
2.7
0
−
−
−
−
5.5
5.5
60
−
V
V
Program, erase temperature
Data hold time(7)
°C
Ambient temperature = 55°C
20
year
NOTES:
1. VCC = 2.7 to 5.5 V at Topr = 0 to 60°C, unless otherwise specified.
2. Definition of programming/erasure endurance
The programming and erasure endurance is defined on a per-block basis.
If the programming and erasure endurance is n (n = 100 or 1,000), each block can be erased n times. For example, if 1,024
1-byte writes are performed to different addresses in block A, a 1 Kbyte block, and then the block is erased, the
programming/erasure endurance still stands at one.
However, the same address must not be programmed more than once per erase operation (overwriting prohibited).
3. Endurance to guarantee all electrical characteristics after program and erase. (1 to Min. value can be guaranteed).
4. In a system that executes multiple programming operations, the actual erasure count can be reduced by writing to sequential
addresses in turn so that as much of the block as possible is used up before performing an erase operation. For example,
when programming groups of 16 bytes, the effective number of rewrites can be minimized by programming up to 128 groups
before erasing them all in one operation. It is also advisable to retain data on the erasure endurance of each block and limit
the number of erase operations to a certain number.
5. If an error occurs during block erase, attempt to execute the clear status register command, then execute the block erase
command at least three times until the erase error does not occur.
6. Customers desiring program/erase failure rate information should contact their Renesas technical support representative.
7. The data hold time includes time that the power supply is off or the clock is not supplied.
Rev.2.10 Sep 26, 2008 Page 409 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
(4)
Table 20.38 Flash Memory (Data flash Block A, Block B) Electrical Characteristics
Standard
Symbol
Parameter
Conditions
Unit
Min.
10,000(3)
−
Typ.
−
Max.
−
Program/erase endurance(2)
−
−
times
Byte program time
50
400
µs
(program/erase endurance ≤ 1,000 times)
−
−
−
Byte program time
(program/erase endurance > 1,000 times)
−
−
65
0.2
0.3
−
−
9
−
µs
s
Block erase time
(program/erase endurance ≤ 1,000 times)
Block erase time
(program/erase endurance > 1,000 times)
−
s
td(SR-SUS)
Time delay from suspend request until
suspend
−
97 + CPU clock
× 6 cycles
µs
µs
ns
µs
−
−
−
Interval from erase start/restart until
following suspend request
650
0
−
−
Interval from program start/restart until
following suspend request
−
−
Time from suspend until program/erase
restart
−
−
3 + CPU clock
× 4 cycles
−
−
−
−
Program, erase voltage
Read voltage
2.7
2.7
-40
20
−
−
−
−
5.5
5.5
85(8)
−
V
V
Program, erase temperature
°C
Data hold time(9)
Ambient temperature = 55°C
year
NOTES:
1. VCC = 2.7 to 5.5 V at Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
2. Definition of programming/erasure endurance
The programming and erasure endurance is defined on a per-block basis.
If the programming and erasure endurance is n (n = 10,000), each block can be erased n times. For example, if 1,024 1-byte
writes are performed to different addresses in block A, a 1 Kbyte block, and then the block is erased, the
programming/erasure endurance still stands at one.
However, the same address must not be programmed more than once per erase operation (overwriting prohibited).
3. Endurance to guarantee all electrical characteristics after program and erase. (1 to Min. value can be guaranteed).
4. Standard of block A and block B when program and erase endurance exceeds 1,000 times. Byte program time to 1,000 times
is the same as that in program ROM.
5. In a system that executes multiple programming operations, the actual erasure count can be reduced by writing to sequential
addresses in turn so that as much of the block as possible is used up before performing an erase operation. For example,
when programming groups of 16 bytes, the effective number of rewrites can be minimized by programming up to 128 groups
before erasing them all in one operation. In addition, averaging the erasure endurance between blocks A and B can further
reduce the actual erasure endurance. It is also advisable to retain data on the erasure endurance of each block and limit the
number of erase operations to a certain number.
6. If an error occurs during block erase, attempt to execute the clear status register command, then execute the block erase
command at least three times until the erase error does not occur.
7. Customers desiring program/erase failure rate information should contact their Renesas technical support representative.
8. 125°C for K version.
9. The data hold time includes time that the power supply is off or the clock is not supplied.
Rev.2.10 Sep 26, 2008 Page 410 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Suspend request
(maskable interrupt request)
FMR46
Clock-dependent
time
Fixed time
Access restart
td(SR-SUS)
Figure 20.21 Time delay until Suspend
Table 20.39 Voltage Detection 1 Circuit Electrical Characteristics
Standard
Symbol
Parameter
Voltage detection level(2, 4)
Voltage monitor 1 reset generation time(5)
Voltage detection circuit self power consumption
Waiting time until voltage detection circuit operation
starts(3)
Condition
Unit
Min.
Typ.
2.85
40
Max.
3.0
200
−
Vdet1
td(Vdet1-A)
−
2.70
V
−
−
−
µs
µA
µs
VCA26 = 1, VCC = 5.0 V
0.6
−
td(E-A)
100
Vccmin
MCU operating voltage minimum value
2.70
−
−
V
NOTES:
1. The measurement condition is VCC = 2.7 to 5.5 V and Topr = -40 to 85°C (J version) / -40 to 125°C (K version).
2. Hold Vdet2 > Vdet1.
3. Necessary time until the voltage detection circuit operates when setting to 1 again after setting the VCA26 bit in the VCA2
register to 0.
4. This parameter shows the voltage detection level when the power supply drops.
The voltage detection level when the power supply rises is higher than the voltage detection level when the power supply
drops by approximately 0.1 V.
5. Time until the voltage monitor 1 reset is generated after the voltage passes Vdet1 when VCC falls. When using the digital filter,
its sampling time is added to td(Vdet1-A). When using the voltage monitor 1 reset, maintain this time until VCC = 2.0 V after the
voltage passes Vdet1 when the power supply falls.
Table 20.40 Voltage Detection 2 Circuit Electrical Characteristics
Standard
Symbol
Vdet2
Parameter
Voltage detection level(2)
Condition
Unit
Min.
3.3
−
Typ.
3.6
40
Max.
3.9
V
td(Vdet2-A)
Voltage monitor 2 reset/interrupt request generation
time(3, 5)
200
µs
−
Voltage detection circuit self power consumption
Waiting time until voltage detection circuit operation
starts(4)
VCA27 = 1, VCC = 5.0 V
−
−
0.6
−
µA
µs
td(E-A)
−
100
NOTES:
1. The measurement condition is VCC = 2.7 to 5.5 V and Topr = -40 to 85°C (J version) / -40 to 125°C (K version).
2. Hold Vdet2 > Vdet1.
3. Time until the voltage monitor 2 reset/interrupt request is generated after the voltage passes Vdet2.
4. Necessary time until the voltage detection circuit operates after setting to 1 again after setting the VCA27 bit in the VCA2
register to 0.
5. When using the digital filter, its sampling time is added to td(Vdet2-A). When using the voltage monitor 2 reset, maintain this time
until VCC = 2.0 V after the voltage passes Vdet2 when the power supply falls.
Rev.2.10 Sep 26, 2008 Page 411 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
(3)
Table 20.41 Power-on Reset Circuit, Voltage Monitor 1 Reset Electrical Characteristics
Standard
Symbol
Parameter
Condition
Unit
Min.
−
Typ.
−
Max.
0.1
Power-on reset valid voltage(4)
Vpor1
Vpor2
V
V
Power-on reset or voltage monitor 1 reset valid
voltage
0
−
Vdet1
20(2)
20(2)
trth
External power VCC rise gradient
VCC ≤ 3.6 V
VCC > 3.6 V
−
−
−
mV/msec
2,000 mV/msec
NOTES:
1. The measurement condition is Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
2. This condition (the minimum value of external power VCC rise gradient) does not apply if Vpor2 ≥ 1.0 V.
3. To use the power-on reset function, enable voltage monitor 1 reset by setting the LVD1ON bit in the OFS register to 0, the
VW1C0 and VW1C6 bits in the VW1C register to 1 respectively, and the VCA26 bit in the VCA2 register to 1.
4. tw(por1) indicates the duration the external power VCC must be held below the effective voltage (Vpor1) to enable a power on
reset. When turning on the power for the first time, maintain tw(por1) for 30 s or more if -20°C ≤ Topr ≤ 125°C, maintain tw(por1) for
3,000 s or more if -40°C ≤ Topr < -20°C.
(3)
(3)
Vdet1
Vdet1
trth
trth
2.0 V
External
power VCC
td(Vdet1-A)
Vpor2
Vpor1
tw(por1)
Sampling time(1, 2)
Internal reset
signal
(“L” valid)
1
1
× 32
× 32
fOCO-S
fOCO-S
NOTES:
1. When using the voltage monitor 1 digital filter, ensure VCC is 2.0 V or higher during the sampling time.
2. The sampling clock can be selected. Refer to 6. Voltage Detection Circuit for details.
3. Vdet1 indicates the voltage detection level of the voltage detection 1 circuit. Refer to 6. Voltage Detection
Circuit for details.
Figure 20.22 Reset Circuit Electrical Characteristics
Rev.2.10 Sep 26, 2008 Page 412 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.42 High-speed On-Chip Oscillator Circuit Electrical Characteristics
Standard
Typ.
Symbol
Parameter
Condition
Unit
Min.
39.2
Max.
40.8
fOCO40M
High-speed on-chip oscillator frequency
temperature · supply voltage dependence
VCC = 4.75 to 5.25 V
0°C ≤ Topr ≤ 60°C(2)
VCC = 3.0 to 5.5 V
40
MHz
38.8
38.4
38
40
40
40
40
41.2
41.6
42
MHz
MHz
MHz
MHz
-20°C ≤ Topr ≤ 85°C(2)
VCC = 3.0 to 5.5 V
-40°C ≤ Topr ≤ 85°C(2)
VCC = 3.0 to 5.5 V
-40°C ≤ Topr ≤ 125°C(2)
VCC = 2.7 to 5.5 V
37.6
42.4
-40°C ≤ Topr ≤ 125°C(2)
−
−
Value in FRA1 register after reset
08h
−
F7h
−
Oscillation frequency adjustment unit of high-
speed on-chip oscillator
Adjust FRA1 register
(value after reset) to -1
−
+0.3
−
MHz
−
−
Oscillation stability time
−
−
10
100
µs
Self power consumption at oscillation
VCC = 5.0 V, Topr = 25°C
400
−
µA
NOTES:
1. VCC = 2.7 to 5.5 V, Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
2. These standard values show when the FRA1 register value after reset is assumed.
Table 20.43 Low-speed On-Chip Oscillator Circuit Electrical Characteristics
Standard
Typ.
125
Symbol
fOCO-S
Parameter
Condition
Unit
Min.
40
−
Max.
250
100
−
Low-speed on-chip oscillator frequency
Oscillation stability time
kHz
µs
−
−
10
Self power consumption at oscillation
VCC = 5.0 V, Topr = 25°C
−
15
µA
NOTE:
1. VCC = 2.7 to 5.5 V, Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
Table 20.44 Power Supply Circuit Timing Characteristics
Standard
Symbol
td(P-R)
Parameter
Condition
Unit
Min.
1
Typ.
Max.
2000
Time for internal power supply stabilization during
power-on(2)
−
µs
STOP exit time(3)
td(R-S)
−
−
150
µs
NOTES:
1. The measurement condition is VCC = 2.7 to 5.5 V and Topr = 25°C.
2. Waiting time until the internal power supply generation circuit stabilizes during power-on.
3. Time until system clock supply starts after the interrupt is acknowledged to exit stop mode.
Rev.2.10 Sep 26, 2008 Page 413 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
(1)
Table 20.45 Timing Requirements of Clock Synchronous Serial I/O with Chip Select
Standard
Unit
Symbol
tSUCYC
Parameter
Conditions
Min.
Typ.
−
Max.
−
(2)
tCYC
SSCK clock cycle time
SSCK clock “H” width
SSCK clock “L” width
4
tHI
0.4
−
0.6
0.6
1
tSUCYC
tSUCYC
tLO
0.4
−
(2)
tRISE
SSCK clock rising
time
Master
Slave
−
−
tCYC
−
−
1
µs
(2)
tFALL
SSCK clock falling
time
Master
Slave
−
−
1
tCYC
−
100
−
1
µs
tSU
SSO, SSI data input setup time
SSO, SSI data input hold time
−
−
ns
(2)
tH
1
−
−
tCYC
tLEAD
Slave
Slave
1tCYC + 50
−
−
ns
ns
SCS setup time
SCS hold time
tLAG
1tCYC + 50
−
−
(2)
tOD
tSA
tOR
SSO, SSI data output delay time
SSI slave access time
−
−
−
−
−
−
1
tCYC
1.5tCYC + 100
1.5tCYC + 100
ns
ns
SSI slave out open time
NOTES:
1. VCC = 2.7 to 5.5 V, VSS = 0 V at Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
2. 1tCYC = 1/f1(s)
Rev.2.10 Sep 26, 2008 Page 414 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
4-Wire Bus Communication Mode, Master, CPHS = 1
VIH or VOH
SCS (output)
VIH or VOH
tHI
tFALL
tRISE
SSCK (output)
(CPOS = 1)
tLO
tHI
SSCK (output)
(CPOS = 0)
tLO
tSUCYC
SSO (output)
SSI (input)
tOD
tSU
tH
4-Wire Bus Communication Mode, Master, CPHS = 0
VIH or VOH
SCS (output)
VIH or VOH
tHI
tFALL
tRISE
SSCK (output)
(CPOS = 1)
tLO
tHI
SSCK (output)
(CPOS = 0)
tLO
tSUCYC
SSO (output)
SSI (input)
tOD
tSU
tH
CPHS, CPOS: Bits in SSMR register
Figure 20.23 I/O Timing of Clock Synchronous Serial I/O with Chip Select (Master)
Rev.2.10 Sep 26, 2008 Page 415 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
4-Wire Bus Communication Mode, Slave, CPHS = 1
VIH or VOH
SCS (input)
VIH or VOH
tLEAD
tHI
tFALL
tRISE
tLAG
SSCK (input)
(CPOS = 1)
tLO
tHI
SSCK (input)
(CPOS = 0)
tLO
tSUCYC
SSO (input)
tSU
tH
SSI (output)
tSA
tOD
tOR
4-Wire Bus Communication Mode, Slave, CPHS = 0
VIH or VOH
SCS (input)
VIH or VOH
tHI
tFALL
tRISE
tLEAD
tLAG
SSCK (input)
(CPOS = 1)
tLO
tHI
SSCK (input)
(CPOS = 0)
tLO
tSUCYC
SSO (input)
tSU
tH
SSI (output)
tSA
tOD
tOR
CPHS, CPOS: Bits in SSMR register
Figure 20.24 I/O Timing of Clock Synchronous Serial I/O with Chip Select (Slave)
Rev.2.10 Sep 26, 2008 Page 416 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
tHI
VIH or VOH
VIH or VOH
SSCK
SSO (output)
SSI (input)
tLO
tSUCYC
tOD
tSU
tH
Figure 20.25 I/O Timing of Clock Synchronous Serial I/O with Chip Select (Clock Synchronous
Communication Mode)
Rev.2.10 Sep 26, 2008 Page 417 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
2
(1)
Table 20.46 Timing Requirements of I C bus Interface
Standard
Typ.
Unit
Symbol
tSCL
Parameter
SCL input cycle time
Condition
Min.
12tCYC + 600(2)
3tCYC + 300(2)
5tCYC + 500(2)
−
Max.
−
−
−
−
−
−
−
−
−
−
−
−
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
tSCLH
tSCLL
tsf
SCL input “H” width
−
SCL input “L” width
−
SCL, SDA input fall time
300
(2)
tSP
SCL, SDA input spike pulse rejection time
SDA input bus-free time
−
1tCYC
(2)
tBUF
−
−
−
−
−
−
5tCYC
(2)
tSTAH
tSTAS
tSTOP
tSDAS
tSDAH
Start condition input hold time
Retransmit start condition input setup time
Stop condition input setup time
Data input setup time
3tCYC
(2)
3tCYC
(2)
3tCYC
1tCYC + 20(2)
0
Data input hold time
NOTES:
1. VCC = 2.7 to 5.5 V, VSS = 0 V at Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.
2. 1tCYC = 1/f1(s)
VIH
SDA
VIL
tBUF
tSTAH
tSP
tSTOP
tSCLH
tSTAS
SCL
P(2)
S(1)
tsf
Sr(3)
P(2)
tSCLL
tsr
tSDAS
tSCL
tSDAH
NOTES:
1. Start condition
2. Stop condition
3. Retransmit start condition
2
Figure 20.26 I/O Timing of I C bus Interface
Rev.2.10 Sep 26, 2008 Page 418 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.47 Electrical Characteristics (1) [VCC = 5 V]
Standard
Unit
Symbol
VOH
Parameter
Condition
Min.
Typ.
−
Max.
VCC
VCC
VCC
VCC
2.0
Output “H” voltage Except XOUT
IOH = -5 mA
VCC - 2.0
VCC - 0.3
VCC - 2.0
V
V
V
V
V
V
V
V
V
IOH = -200 µA
−
XOUT
Output “L” voltage Except XOUT
XOUT
Drive capacity HIGH IOH = -1 mA
−
Drive capacity LOW IOH = -500 µA VCC - 2.0
−
VOL
IOL = 5 mA
−
−
−
IOL = 200 µA
−
0.45
2.0
Drive capacity HIGH IOL = 1 mA
Drive capacity LOW IOL = 500 µA
−
−
−
−
2.0
VT+-VT-
Hysteresis
0.1
0.5
−
INT0, INT1, INT3,
KI0, KI1, KI2, KI3,
TRAIO, RXD0, RXD1,
CLK0, CLK1,
SSI, SCL, SDA, SSO
0.1
1.0
−
V
RESET
IIH
IIL
Input “H” current
Input “L” current
VI = 5 V, VCC = 5V
VI = 0 V, VCC = 5V
VI = 0 V, VCC = 5V
−
−
−
−
5.0
-5.0
167
−
µA
µA
RPULLUP Pull-up resistance
30
−
50
1.0
kΩ
MΩ
RfXIN
Feedback
resistance
XIN
VRAM
RAM hold voltage
During stop mode
2.0
−
−
V
NOTE:
1. VCC = 4.2 to 5.5 V at Topr = -40 to 85°C (J version) / -40 to 125°C (K version), f(XIN) = 20 MHz, unless otherwise specified.
Rev.2.10 Sep 26, 2008 Page 419 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
20. Electrical Characteristics
Table 20.48 Electrical Characteristics (2) [Vcc = 5 V]
(Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.)
Standard
Symbol
ICC
Parameter
Condition
Unit
mA
Min.
Typ.
10
Max.
17
XIN = 20 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
Power supply current High-speed
−
(VCC = 3.3 to 5.5 V)
Single-chip mode,
output pins are open,
other pins are VSS
clock mode
XIN = 16 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
−
−
−
−
−
−
−
−
−
−
9
6
15
−
mA
mA
mA
mA
mA
mA
mA
mA
mA
µA
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
XIN = 20 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
5
−
XIN = 16 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
4
−
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
2.5
10
4
−
XIN clock off
High-speed
on-chip
oscillator
mode
15
−
High-speed on-chip oscillator on fOCO = 20 MHz (J version)
Low-speed on-chip oscillator on = 125 kHz
No division
XIN clock off
High-speed on-chip oscillator on fOCO = 20 MHz (J version)
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
XIN clock off
5.5
2.5
130
10
−
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
No division
XIN clock off
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
XIN clock off
Low-speed
on-chip
oscillator
mode
300
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8, FMR47 = 1
XIN clock off
Wait mode
−
−
25
23
75
60
µA
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock operation
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off, Topr = 25°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Stop mode
−
−
−
0.8
1.2
4.0
3.0
−
µA
µA
µA
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
XIN clock off, Topr = 85°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
XIN clock off, Topr = 125°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
−
Rev.2.10 Sep 26, 2008 Page 420 of 453
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20. Electrical Characteristics
Timing Requirements
(Unless Otherwise Specified: VCC = 5 V, VSS = 0 V at Topr = 25°C) [VCC = 5 V]
Table 20.49 XIN Input
Standard
Unit
Symbol
Parameter
Min.
50
Max.
tc(XIN)
tWH(XIN)
tWL(XIN)
XIN input cycle time
XIN input “H” width
XIN input “L” width
−
−
−
ns
ns
ns
25
25
VCC = 5 V
tC(XIN)
tWH(XIN)
XIN input
tWL(XIN)
Figure 20.27 XIN Input Timing Diagram when VCC = 5 V
Table 20.50 TRAIO Input
Standard
Max.
Symbol
Parameter
Unit
Min.
100
40
tc(TRAIO)
tWH(TRAIO)
tWL(TRAIO)
TRAIO input cycle time
TRAIO input “H” width
TRAIO input “L” width
−
−
−
ns
ns
ns
40
tC(TRAIO)
VCC = 5 V
tWH(TRAIO)
TRAIO input
tWL(TRAIO)
Figure 20.28 TRAIO Input Timing Diagram when VCC = 5 V
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20. Electrical Characteristics
Table 20.51 Serial Interface
Standard
Unit
Symbol
Parameter
Min.
200
100
100
−
Max.
tc(CK)
CLKi input cycle time
CLKi input “H” width
CLKi input “L” width
TXDi output delay time
TXDi hold time
−
−
ns
ns
ns
ns
ns
ns
ns
tW(CKH)
tW(CKL)
td(C-Q)
th(C-Q)
tsu(D-C)
th(C-D)
−
50
−
0
RXDi input setup time
RXDi input hold time
50
−
90
−
i = 0 or 1
VCC = 5 V
tC(CK)
tW(CKH)
CLKi
tW(CKL)
th(C-Q)
TXDi
RXDi
td(C-Q)
tsu(D-C)
th(C-D)
i = 0 or 1
Figure 20.29 Serial Interface Timing Diagram when VCC = 5 V
Table 20.52 External Interrupt INTi (i = 0, 1, 3) Input
Standard
Symbol
tW(INH)
Parameter
Unit
Min.
Max.
250(1)
250(2)
−
ns
ns
INTi input “H” width
INTi input “L” width
tW(INL)
−
NOTES:
1. When selecting the digital filter by the INTi input filter select bit, use an INTi input HIGH width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
2. When selecting the digital filter by the INTi input filter select bit, use an INTi input LOW width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
VCC = 5 V
tW(INL)
INTi input
tW(INH)
i = 0, 1, 3
Figure 20.30 External Interrupt INTi Input Timing Diagram when VCC = 5 V
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20. Electrical Characteristics
Table 20.53 Electrical Characteristics (3) [VCC = 3 V]
Standard
Unit
Symbol
VOH
Parameter
Output “H” voltage Except XOUT
Condition
Min.
Typ.
−
Max.
VCC
VCC
IOH = -1 mA
VCC - 0.5
V
V
XOUT
Drive capacity
HIGH
IOH = -0.1 mA VCC - 0.5
−
Drive capacity
LOW
IOH = -50 µA
VCC - 0.5
−
VCC
V
VOL
Output “L” voltage
Hysteresis
Except XOUT
XOUT
IOL = 1 mA
−
−
−
−
0.5
0.5
V
V
Drive capacity
HIGH
IOL = 0.1 mA
Drive capacity
LOW
IOL = 50 µA
−
−
0.5
V
V
VT+-VT-
0.1
0.3
−
INT0, INT1, INT3,
KI0, KI1, KI2, KI3,
TRAIO, RXD0, RXD1,
CLK0,CLK1,
SSI, SCL, SDA, SSO
0.1
0.4
−
V
RESET
IIH
IIL
Input “H” current
Input “L” current
VI = 3 V, VCC = 3V
VI = 0 V, VCC = 3V
VI = 0 V, VCC = 3V
−
−
−
−
4.0
-4.0
500
−
µA
µA
kΩ
MΩ
V
RPULLUP Pull-up resistance
66
−
160
3.0
−
RfXIN
VRAM
Feedback resistance XIN
RAM hold voltage
During stop mode
2.0
−
NOTE:
1. VCC = 2.7 to 3.3 V at Topr = -40 to 85°C (J version) / -40 to 125°C (K version), f(XIN) = 10 MHz, unless otherwise specified.
Rev.2.10 Sep 26, 2008 Page 423 of 453
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20. Electrical Characteristics
Table 20.54 Electrical Characteristics (4) [Vcc = 3 V]
(Topr = -40 to 85°C (J version) / -40 to 125°C (K version), unless otherwise specified.)
Standard
Symbol
ICC
Parameter
Condition
Unit
mA
Min.
Typ.
6
Max.
Power supply current High-speed
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
No division
−
−
(VCC = 2.7 to 3.3 V)
Single-chip mode,
output pins are open,
other pins are VSS
clock mode
XIN = 10 MHz (square wave)
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
−
−
−
−
−
2
5
−
9
mA
mA
mA
µA
High-speed
on-chip
oscillator
mode
XIN clock off
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
No division
XIN clock off
2
−
High-speed on-chip oscillator on fOCO = 10 MHz
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8
Low-speed
on-chip
oscillator
mode
XIN clock off
130
25
300
70
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
Divide-by-8, FMR47 = 1
Wait mode
XIN clock off
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock operation
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
XIN clock off
−
23
55
µA
High-speed on-chip oscillator off
Low-speed on-chip oscillator on = 125 kHz
While a WAIT instruction is executed
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
VCA20 = 1
Stop mode
XIN clock off, Topr = 25°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
−
−
−
0.7
1.1
3.8
3.0
µA
µA
µA
XIN clock off, Topr = 85°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
−
XIN clock off, Topr = 125°C
High-speed on-chip oscillator off
Low-speed on-chip oscillator off
CM10 = 1
−
Peripheral clock off
VCA27 = VCA26 = VCA25 = 0
Rev.2.10 Sep 26, 2008 Page 424 of 453
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20. Electrical Characteristics
Timing requirements
(Unless Otherwise Specified: VCC = 3 V, VSS = 0 V at Topr = 25°C) [VCC = 3 V]
Table 20.55 XIN Input
Standard
Unit
Symbol
Parameter
Min.
100
40
Max.
tc(XIN)
tWH(XIN)
tWL(XIN)
XIN input cycle time
XIN input “H” width
XIN input “L” width
−
−
−
ns
ns
ns
40
tC(XIN)
VCC = 3 V
tWH(XIN)
XIN input
tWL(XIN)
Figure 20.31 XIN Input Timing Diagram when VCC = 3 V
Table 20.56 TRAIO Input
Standard
Symbol
Parameter
Unit
Min.
300
120
120
Max.
tc(TRAIO)
tWH(TRAIO)
tWL(TRAIO)
TRAIO input cycle time
TRAIO input “H” width
TRAIO input “L” width
−
−
−
ns
ns
ns
VCC = 3 V
tC(TRAIO)
tWH(TRAIO)
TRAIO input
tWL(TRAIO)
Figure 20.32 TRAIO Input Timing Diagram when VCC = 3 V
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20. Electrical Characteristics
Table 20.57 Serial Interface
Standard
Unit
Symbol
Parameter
Min.
300
150
150
−
Max.
tc(CK)
CLKi input cycle time
CLKi input “H” width
CLKi Input “L” width
TXDi output delay time
TXDi hold time
−
−
ns
ns
ns
ns
ns
ns
ns
tW(CKH)
tW(CKL)
td(C-Q)
th(C-Q)
tsu(D-C)
th(C-D)
−
80
−
0
RXDi input setup time
RXDi input hold time
70
−
90
−
i = 0 or 1
tC(CK)
VCC = 3 V
tW(CKH)
CLKi
tW(CKL)
th(C-Q)
TXDi
RXDi
td(C-Q)
tsu(D-C)
th(C-D)
i = 0 or 1
Figure 20.33 Serial Interface Timing Diagram when VCC = 3 V
Table 20.58 External Interrupt INTi (i = 0, 1, 3) Input
Standard
Min. Max.
Symbol
tW(INH)
Parameter
Unit
380(1)
380(2)
−
−
ns
ns
INTi input “H” width
INTi input “L” width
tW(INL)
NOTES:
1. When selecting the digital filter by the INTi input filter select bit, use an INTi input HIGH width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
2. When selecting the digital filter by the INTi input filter select bit, use an INTi input LOW width of either (1/digital filter clock
frequency × 3) or the minimum value of standard, whichever is greater.
VCC = 3 V
tW(INL)
INTi input
tW(INH)
i = 0, 1, 3
Figure 20.34 External Interrupt INTi Input Timing Diagram when VCC = 3 V
Rev.2.10 Sep 26, 2008 Page 426 of 453
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21. Usage Notes
21. Usage Notes
21.1 Notes on Clock Generation Circuit
21.1.1 Stop Mode
When entering stop mode, set the FMR01 bit in the FMR0 register to 0 (CPU rewrite mode disabled) and the
CM10 bit in the CM1 register to 1 (stop mode). An instruction queue pre-reads 4 bytes from the instruction
which sets the CM10 bit to 1 (stop mode) and the program stops.
Insert at least 4 NOP instructions following the JMP.B instruction after the instruction which sets the CM10 bit
to 1.
• Program example to enter stop mode
BCLR
BSET
FSET
BSET
JMP.B
1,FMR0
0,PRCR
I
0,CM1
LABEL_001
; CPU rewrite mode disabled
; Protect disabled
; Enable interrupt
; Stop mode
LABEL_001 :
NOP
NOP
NOP
NOP
21.1.2 Wait Mode
When entering wait mode, set the FMR01 bit in the FMR0 register to 0 (CPU rewrite mode disabled) and
execute the WAIT instruction. An instruction queue pre-reads 4 bytes from the WAIT instruction and the
program stops. Insert at least 4 NOP instructions after the WAIT instruction.
• Program example to execute the WAIT instruction
BCLR
FSET
WAIT
NOP
1,FMR0
I
; CPU rewrite mode disabled
; Enable interrupt
; Wait mode
NOP
NOP
NOP
21.1.3 Oscillation Stop Detection Function
Since the oscillation stop detection function cannot be used if the XIN clock frequency is 2 MHz or below, set
bits OCD1 to OCD0 to 00b.
21.1.4 Oscillation Circuit Constants
Ask the manufacturer of the oscillator to specify the best oscillation circuit constants for your system.
To use this MCU with supply voltage below VCC = 2.7 V, it is recommended to set the CM11 bit in the CM1
register to 1 (on-chip feedback resistor disabled), the CM15 bit to 1 (high drive capacity), and connect the
feedback resistor to the chip externally.
Rev.2.10 Sep 26, 2008 Page 427 of 453
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21. Usage Notes
21.2 Notes on Interrupts
21.2.1 Reading Address 00000h
Do not read address 00000h by a program. When a maskable interrupt request is acknowledged, the CPU reads
interrupt information (interrupt number and interrupt request level) from 00000h in the interrupt sequence. At
this time, the acknowledged interrupt IR bit is set to 0.
If address 00000h is read by a program, the IR bit for the interrupt which has the highest priority among the
enabled interrupts is set to 0. This may cause the interrupt to be canceled, or an unexpected interrupt to be
generated.
21.2.2 SP Setting
Set any value in the SP before an interrupt is acknowledged. The SP is set to 0000h after reset. Therefore, if an
interrupt is acknowledged before setting a value in the SP, the program may run out of control.
21.2.3 External Interrupt and Key Input Interrupt
Either “L” level or an “H” level of width shown in the Electrical Characteristics is necessary for the signal input
to pins INT0, INT1, INT3 and pins KI0 to KI3, regardless of the CPU clock.
For details, refer to Table 20.21 (VCC = 5V), Table 20.27 (VCC = 3V), Table 20.33 (VCC = 2.2V), Table
20.52 (VCC = 5V), Table 20.58 (VCC = 3V) External Interrupt INTi (i = 0, 1, 3) Input.
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21. Usage Notes
21.2.4 Changing Interrupt Sources
The IR bit in the interrupt control register may be set to 1 (interrupt requested) when the interrupt source
changes. When using an interrupt, set the IR bit to 0 (no interrupt requested) after changing the interrupt source.
In addition, changes of interrupt sources include all factors that change the interrupt sources assigned to
individual software interrupt numbers, polarities, and timing. Therefore, if a mode change of a peripheral
function involves interrupt sources, edge polarities, and timing, set the IR bit to 0 (no interrupt requested) after
the change. Refer to the individual peripheral function for its related interrupts.
Figure 21.1 shows an Example of Procedure for Changing Interrupt Sources.
Interrupt source change
Disable interrupts(2, 3)
Change interrupt source (including mode
of peripheral function)
Set the IR bit to 0 (interrupt not requested)
using the MOV instruction(3)
Enable interrupts(2, 3)
Change completed
IR bit:
The interrupt control register bit of an
interrupt whose source is changed.
NOTES:
1. Execute the above settings individually. Do not execute two
or more settings at once (by one instruction).
2. To prevent interrupt requests from being generated, disable
the peripheral function before changing the interrupt
source. In this case, use the I flag if all maskable interrupts
can be disabled. If all maskable interrupts cannot be
disabled, use bits ILVL0 to ILVL2 of the interrupt whose
source is changed.
3. Refer to 12.6.5 Changing Interrupt Control Register
Contents for the instructions to be used and usage notes.
Figure 21.1
Example of Procedure for Changing Interrupt Sources
Rev.2.10 Sep 26, 2008 Page 429 of 453
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21. Usage Notes
21.2.5 Changing Interrupt Control Register Contents
(a) The contents of an interrupt control register can only be changed while no interrupt requests
corresponding to that register are generated. If interrupt requests may be generated, disable interrupts
before changing the interrupt control register contents.
(b) When changing the contents of an interrupt control register after disabling interrupts, be careful to
choose appropriate instructions.
Changing any bit other than IR bit
If an interrupt request corresponding to a register is generated while executing the instruction, the IR bit
may not be set to 1 (interrupt requested), and the interrupt request may be ignored. If this causes a
problem, use the following instructions to change the register: AND, OR, BCLR, BSET
Changing IR bit
If the IR bit is set to 0 (interrupt not requested), it may not be set to 0 depending on the instruction used.
Therefore, use the MOV instruction to set the IR bit to 0.
(c) When disabling interrupts using the I flag, set the I flag as shown in the sample programs below. Refer
to (b) regarding changing the contents of interrupt control registers by the sample programs.
Sample programs 1 to 3 are for preventing the I flag from being set to 1 (interrupts enabled) before the interrupt
control register is changed for reasons of the internal bus or the instruction queue buffer.
Example 1: Use NOP instructions to prevent I flag from being set to 1 before interrupt control register
is changed
INT_SWITCH1:
FCLR
I
; Disable interrupts
AND.B #00H,0056H
NOP
NOP
; Set TRAIC register to 00h
;
FSET
I
; Enable interrupts
Example 2: Use dummy read to delay FSET instruction
INT_SWITCH2:
FCLR
AND.B #00H,0056H
MOV.W MEM,R0
I
; Disable interrupts
; Set TRAIC register to 00h
; Dummy read
FSET
I
; Enable interrupts
Example 3: Use POPC instruction to change I flag
INT_SWITCH3:
PUSHC FLG
FCLR
AND.B #00H,0056H
POPC FLG
I
; Disable interrupts
; Set TRAIC register to 00h
; Enable interrupts
Rev.2.10 Sep 26, 2008 Page 430 of 453
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21. Usage Notes
21.3 Notes on Timers
21.3.1 Notes on Timer RA
• Timer RA stops counting after a reset. Set the values in the timer RA and timer RA prescalers before the
count starts.
• Even if the prescaler and timer RA are read out in 16-bit units, these registers are read 1 byte at a time by
the MCU. Consequently, the timer value may be updated during the period when these two registers are
being read.
• In pulse period measurement mode, bits TEDGF and TUNDF in the TRACR register can be set to 0 by
writing 0 to these bits by a program. However, these bits remain unchanged if 1 is written. When using the
READ-MODIFY-WRITE instruction for the TRACR register, the TEDGF or TUNDF bit may be set to 0
although these bits are set to 1 while the instruction is being executed. In this case, write 1 to the TEDGF or
TUNDF bit which is not supposed to be set to 0 with the MOV instruction.
• When changing to pulse period measurement mode from another mode, the contents of bits TEDGF and
TUNDF are undefined. Write 0 to bits TEDGF and TUNDF before the count starts.
• The TEDGF bit may be set to 1 by the first timer RA prescaler underflow generated after the count starts.
• When using the pulse period measurement mode, leave two or more periods of the timer RA prescaler
immediately after the count starts, then set the TEDGF bit to 0.
• The TCSTF bit retains 0 (count stops) for 0 to 1 cycle of the count source after setting the TSTART bit to 1
(count starts) while the count is stopped.
During this time, do not access registers associated with timer RA other than the TCSTF bit. Timer RA
(1)
starts counting at the first valid edge of the count source after The TCSTF bit is set to 1 (during count).
The TCSTF bit remains 1 for 0 to 1 cycle of the count source after setting the TSTART bit to 0 (count
stops) while the count is in progress. Timer RA counting is stopped when the TCSTF bit is set to 0.
(1)
During this time, do not access registers associated with timer RA other than the TCSTF bit.
NOTE:
1. Registers associated with timer RA: TRACR, TRAIOC, TRAMR, TRAPRE, and TRA.
• When the TRAPRE register is continuously written during count operation (TCSTF bit is set to 1), allow
three or more cycles of the count source clock for each write interval.
• When the TRA register is continuously written during count operation (TCSTF bit is set to 1), allow three
or more cycles of the prescaler underflow for each write interval.
Rev.2.10 Sep 26, 2008 Page 431 of 453
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21. Usage Notes
21.3.2 Notes on Timer RB
• Timer RB stops counting after a reset. Set the values in the timer RB and timer RB prescalers before the
count starts.
• Even if the prescaler and timer RB is read out in 16-bit units, these registers are read 1 byte at a time by the
MCU. Consequently, the timer value may be updated during the period when these two registers are being
read.
• In programmable one-shot generation mode and programmable wait one-shot generation mode, when
setting the TSTART bit in the TRBCR register to 0, 0 (stops counting) or setting the TOSSP bit in the
TRBOCR register to 1 (stops one-shot), the timer reloads the value of reload register and stops. Therefore,
in programmable one-shot generation mode and programmable wait one-shot generation mode, read the
timer count value before the timer stops.
• The TCSTF bit remains 0 (count stops) for 1 to 2 cycles of the count source after setting the TSTART bit to
1 (count starts) while the count is stopped.
During this time, do not access registers associated with timer RB other than the TCSTF bit. Timer RB
(1)
starts counting at the first valid edge of the count source after the TCSTF bit is set to 1 (during count).
The TCSTF bit remains 1 for 1 to 2 cycles of the count source after setting the TSTART bit to 0 (count
stops) while the count is in progress. Timer RB counting is stopped when the TCSTF bit is set to 0.
(1)
During this time, do not access registers associated with timer RB other than the TCSTF bit.
NOTE:
1. Registers associated with timer RB: TRBCR, TRBOCR, TRBIOC, TRBMR, TRBPRE, TRBSC, and
TRBPR.
• If the TSTOP bit in the TRBCR register is set to 1 during timer operation, timer RB stops immediately.
• If 1 is written to the TOSST or TOSSP bit in the TRBOCR register, the value of the TOSSTF bit changes
after one or two cycles of the count source have elapsed. If the TOSSP bit is written to 1 during the period
between when the TOSST bit is written to 1 and when the TOSSTF bit is set to 1, the TOSSTF bit may be
set to either 0 or 1 depending on the content state. Likewise, if the TOSST bit is written to 1 during the
period between when the TOSSP bit is written to 1 and when the TOSSTF bit is set to 0, the TOSSTF bit
may be set to either 0 or 1.
21.3.2.1 Timer mode
The following workaround should be performed in timer mode.
To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the following
points:
• When the TRBPRE register is written continuously, allow three or more cycles of the count source for each
write interval.
• When the TRBPR register is written continuously, allow three or more cycles of the prescaler underflow
for each write interval.
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21. Usage Notes
21.3.2.2 Programmable waveform generation mode
The following three workarounds should be performed in programmable waveform generation mode.
(1) To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the
following points:
• When the TRBPRE register is written continuously, allow three or more cycles of the count source for each
write interval.
• When the TRBPR register is written continuously, allow three or more cycles of the prescaler underflow
for each write interval.
(2) To change registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), synchronize
the TRBO output cycle using a timer RB interrupt, etc. This operation should be preformed only once in
the same output cycle. Also, make sure that writing to the TRBPR register does not occur during period
A shown in Figures 21.2 and 21.3.
The following shows the detailed workaround examples.
• Workaround example (a):
As shown in Figure 21.2, write to registers TRBSC and TRBPR in the timer RB interrupt routine. These
write operations must be completed by the beginning of period A.
Period A
Count source/
prescaler
underflow signal
Primary period
Secondary period
TRBO pin output
IR bit in
TRBIC register
Interrupt request is
acknowledged
(a)
Ensure sufficient time
(b)
Interrupt
Instruction in
Set the secondary and then
the primary register immediately
Interrupt request
is generated
sequence interrupt routine
(a) Period between interrupt request generation and the completion of execution of an instruction. The length of time
varies depending on the instruction being executed.
The DIVX instruction requires the longest time, 30 cycles (assuming no wait states and that a register is set as
the divisor).
(b) 20 cycles. 21 cycles for address match and single-step interrupts.
Figure 21.2
Workaround Example (a) When Timer RB interrupt is Used
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21. Usage Notes
• Workaround example (b):
As shown in Figure 21.3 detect the start of the primary period by the TRBO pin output level and write to
registers TRBSC and TRBPR. These write operations must be completed by the beginning of period A.
If the port register’s bit value is read after the port direction register’s bit corresponding to the TRBO pin is
set to 0 (input mode), the read value indicates the TRBO pin output value.
Period A
Count source/
prescaler
underflow signal
Primary period
Secondary period
TRBO pin output
Read value of the port register’s
bit corresponding to the TRBO pin
(when the bit in the port direction
register is set to 0)
(i) (ii) (iii)
Ensure sufficient time
The TRBO output inversion
is detected at the end of the
secondary period.
Upon detecting (i), set the secondary and
then the primary register immediately.
Figure 21.3
Workaround Example (b) When TRBO Pin Output Value is Read
(3) To stop the timer counting in the primary period, use the TSTOP bit in the TRBCR register. In this case,
registers TRBPRE and TRBPR are initialized and their values are set to the values after reset.
21.3.2.3 Programmable one-shot generation mode
The following two workarounds should be performed in programmable one-shot generation mode.
(1) To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the
following points:
• When the TRBPRE register is written continuously during count operation (TCSTF bit is set to 1), allow
three or more cycles of the count source for each write interval.
• When the TRBPR register is written continuously during count operation (TCSTF bit is set to 1), allow
three or more cycles of the prescaler underflow for each write interval.
(2) Do not set both the TRBPRE and TRBPR registers to 00h.
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21. Usage Notes
21.3.2.4 Programmable wait one-shot generation mode
The following three workarounds should be performed in programmable wait one-shot generation mode.
(1) To write to registers TRBPRE and TRBPR during count operation (TCSTF bit is set to 1), note the
following points:
• When the TRBPRE register is written continuously, allow three or more cycles of the count source for each
write interval.
• When the TRBPR register is written continuously, allow three or more cycles of the prescaler underflow
for each write interval.
(2) Do not set both the TRBPRE and TRBPR registers to 00h.
(3) Set registers TRBSC and TRBPR using the following procedure.
(a) To use “INT0 pin one-shot trigger enabled” as the count start condition
Set the TRBSC register and then the TRBPR register. At this time, after writing to the TRBPR
register, allow an interval of 0.5 or more cycles of the count source before trigger input from the
INT0 pin.
(b) To use “writing 1 to TOSST bit” as the start condition
Set the TRBSC register, the TRBPR register, and then TOSST bit. At this time, after writing to the
TRBPR register, allow an interval of 0.5 or more cycles of the count source before writing to the
TOSST bit.
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21. Usage Notes
21.3.3 Notes on Timer RC
21.3.3.1 TRC Register
• The following note applies when the CCLR bit in the TRCCR1 register is set to 1 (clear TRC register at
compare match with TRCGRA register).
When using a program to write a value to the TRC register while the TSTART bit in the TRCMR register is
set to 1 (count starts), ensure that the write does not overlap with the timing with which the TRC register is
set to 0000h.
If the timing of the write to the TRC register and the setting of the TRC register to 0000h coincide, the
write value will not be written to the TRC register and the TRC register will be set to 0000h.
• Reading from the TRC register immediately after writing to it can result in the value previous to the write
being read out. To prevent this, execute the JMP.B instruction between the read and the write instructions.
Program Example
MOV.W
JMP.B
MOV.W
#XXXXh, TRC
L1
TRC,DATA
;Write
;JMP.B instruction
;Read
L1:
21.3.3.2 TRCSR Register
Reading from the TRCSR register immediately after writing to it can result in the value previous to the write
being read out. To prevent this, execute the JMP.B instruction between the read and the write instructions.
Program Example
MOV.B
JMP.B
MOV.B
#XXh, TRCSR
L1
TRCSR,DATA
;Write
;JMP.B instruction
;Read
L1:
21.3.3.3 Count Source Switching
• Stop the count before switching the count source.
Switching procedure
(1) Set the TSTART bit in the TRCMR register to 0 (count stops).
(2) Change the settings of bits TCK2 to TCK0 in the TRCCR1 register.
• After switching the count source from fOCO40M to another clock, allow a minimum of two cycles of f1 to
elapse after changing the clock setting before stopping fOCO40M.
Switching procedure
(1) Set the TSTART bit in the TRCMR register to 0 (count stops).
(2) Change the settings of bits TCK2 to TCK0 in the TRCCR1 register.
(3) Wait for a minimum of two cycles of f1.
(4) Set the FRA00 bit in the FRA0 register to 0 (high-speed on-chip oscillator off).
21.3.3.4 Input Capture Function
• The pulse width of the input capture signal should be three cycles or more of the timer RC operation clock
(refer to Table 14.11 Timer RC Operation Clock).
• The value of the TRC register is transferred to the TRCGRj register one or two cycles of the timer RC
operation clock after the input capture signal is input to the TRCIOj (j = A, B, C, or D) pin (when the
digital filter function is not used).
21.3.3.5 TRCMR Register in PWM2 Mode
When the CSEL bit in the TRCCR2 register is set to 1 (count stops at compare match with the TRCGRA
register), do not set the TRCMR register at compare match timing of registers TRC and TRCGRA.
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21. Usage Notes
21.3.4 Notes on Timer RE
21.3.4.1 Starting and Stopping Count
Timer RE has the TSTART bit for instructing the count to start or stop, and the TCSTF bit, which indicates
count start or stop. Bits TSTART and TCSTF are in the TRECR1 register.
Timer RE starts counting and the TCSTF bit is set to 1 (count starts) when the TSTART bit is set to 1 (count
starts). It takes up to 2 cycles of the count source until the TCSTF bit is set to 1 after setting the TSTART bit to
(1)
1. During this time, do not access registers associated with timer RE other than the TCSTF bit.
Also, timer RE stops counting when setting the TSTART bit to 0 (count stops) and the TCSTF bit is set to 0
(count stops). It takes the time for up to 2 cycles of the count source until the TCSTF bit is set to 0 after setting
the TSTART bit to 0. During this time, do not access registers associated with timer RE other than the TCSTF
bit.
NOTE:
1. Registers associated with timer RE: TRESEC, TREMIN, TREHR, TREWK, TRECR1, TRECR2, and
TRECSR.
21.3.4.2 Register Setting
Write to the following registers or bits when timer RE is stopped.
• Registers TRESEC, TREMIN, TREHR, TREWK, and TRECR2
• Bits H12_H24, PM, and INT in TRECR1 register
• Bits RCS0 to RCS3 in TRECSR register
Timer RE is stopped when bits TSTART and TCSTF in the TRECR1 register are set to 0 (timer RE stopped).
Also, set all above-mentioned registers and bits (immediately before timer RE count starts) before setting the
TRECR2 register.
Figure 21.4 shows a Setting Example in Real-Time Clock Mode.
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21. Usage Notes
TSTART in TRECR1 = 0
Stop timer RE operation
TCSTF in TRECR1 = 0?
TREIC ← 00h
(disable timer RE interrupt)
TRERST in TRECR1 = 1
TRERST in TRECR1 = 0
Timer RE register
and control circuit reset
Setting of registers TRECSR,
TRESEC, TREMIN, TREHR,
TREWK, and bits H12_H24, PM,
and INT in TRECR1 register
Select clock output
Select clock source
Seconds, minutes, hours, days of week, operating mode
Set a.m./p.m., interrupt timing
Setting of TRECR2
Select interrupt source
Setting of TREIC (IR bit ← 0,
select interrupt priority level)
TSTART in TRECR1 = 1
TCSTF in TRECR1 = 1?
Start timer RE operation
Figure 21.4
Setting Example in Real-Time Clock Mode
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21. Usage Notes
21.3.4.3 Time Reading Procedure of Real-Time Clock Mode
In real-time clock mode, read registers TRESEC, TREMIN, TREHR, and TREWK when time data is updated
and read the PM bit in the TRECR1 register when the BSY bit is set to 0 (not while data is updated).
Also, when reading several registers, an incorrect time will be read if data is updated before another register is
read after reading any register.
In order to prevent this, use the reading procedure shown below.
• Using an interrupt
Read necessary contents of registers TRESEC, TREMIN, TREHR, and TREWK and the PM bit in the
TRECR1 register in the timer RE interrupt routine.
• Monitoring with a program 1
Monitor the IR bit in the TREIC register with a program and read necessary contents of registers TRESEC,
TREMIN, TREHR, and TREWK and the PM bit in the TRECR1 register after the IR bit in the TREIC
register is set to 1 (timer RE interrupt request generated).
• Monitoring with a program 2
(1) Monitor the BSY bit.
(2) Monitor until the BSY bit is set to 0 after the BSY bit is set to 1 (approximately 62.5 ms while the BSY
bit is set to 1).
(3) Read necessary contents of registers TRESEC, TREMIN, TREHR, and TREWK and the PM bit in the
TRECR1 register after the BSY bit is set to 0.
• Using read results if they are the same value twice
(1) Read necessary contents of registers TRESEC, TREMIN, TREHR, and TREWK and the PM bit in the
TRECR1 register.
(2) Read the same register as (1) and compare the contents.
(3) Recognize as the correct value if the contents match. If the contents do not match, repeat until the read
contents match with the previous contents.
Also, when reading several registers, read them as continuously as possible.
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21. Usage Notes
21.4 Notes on Serial Interface
• When reading data from the UiRB (i = 0 or 1) register either in the clock synchronous serial I/O mode or in the
clock asynchronous serial I/O mode. Ensure the data is read in 16-bit units. When the high-order byte of the
UiRB register is read, bits PER and FER in the UiRB register and the RI bit in the UiC1 register are set to 0.
To check receive errors, read the UiRB register and then use the read data.
Example (when reading receive buffer register):
MOV.W
00A6H,R0
; Read the U0RB register
• When writing data to the UiTB register in the clock asynchronous serial I/O mode with 9-bit transfer data
length, write data to the high-order byte first then the low-order byte, in 8-bit units.
Example (when reading transmit buffer register):
MOV.B
MOV.B
#XXH,00A3H ; Write the high-order byte of U0TB register
#XXH,00A2H ; Write the low-order byte of U0TB register
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21. Usage Notes
21.5 Notes on Clock Synchronous Serial Interface
21.5.1 Notes on Clock Synchronous Serial I/O with Chip Select
Set the IICSEL bit in the PMR register to 0 (select clock synchronous serial I/O with chip select function) to use
the clock synchronous serial I/O with chip select function.
2
21.5.2 Notes on I C bus Interface
2
2
Set the IICSEL bit in the PMR register to 1 (select I C bus interface function) to use the I C bus interface.
21.5.2.1 Multimaster Operation
2
The following actions must be performed to use the I C bus interface in multimaster operation.
• Transfer rate
Set the transfer rate by 1/1.8 or faster than the fastest rate of the other masters. For example, if the fastest
2
transfer rate of the other masters is set to 400 kbps, the I C-bus transfer rate in this MCU should be set to
223 kbps (= 400/1.18) or more.
• Bits MST and TRS in the ICCR1 register setting
(a) Use the MOV instruction to set bits MST and TRS.
(b) When arbitration is lost, confirm the contents of bits MST and TRS. If the contents are other than the
MST bit set to 0 and the TRS bit set to 0 (slave receive mode), set the MST bit to 0 and the TRS bit to 0
again.
21.5.2.2 Master Receive Mode
2
Either of the following actions must be performed to use the I C bus interface in master receive mode.
(a) In master receive mode while the RDRF bit in the ICSR register is set to 1, read the ICDRR register
before the rising edge of the 8th clock.
(b) In master receive mode, set the RCVD bit in the ICCR1 register to 1 (disables the next receive
operation) to perform 1-byte communications.
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21. Usage Notes
21.6 Notes on Hardware LIN
For the time-out processing of the header and response fields, use another timer to measure the duration of time
with a Synch Break detection interrupt as the starting point.
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21. Usage Notes
21.7 Notes on A/D Converter
• Write to each bit (other than bit 6) in the ADCON0 register, each bit in the ADCON1 register, or the SMP bit
in the ADCON2 register when A/D conversion is stopped (before a trigger occurs).
When the VCUT bit in the ADCON1 register is changed from 0 (VREF not connected) to 1 (VREF
connected), wait for at least 1 µs before starting the A/D conversion.
• After changing the A/D operating mode, select an analog input pin again.
• When using the one-shot mode, ensure that A/D conversion is completed before reading the AD register. The
IR bit in the ADIC register or the ADST bit in the ADCON0 register can be used to determine whether A/D
conversion is completed.
• When using the repeat mode, select the frequency of the A/D converter operating clock φAD or more for the
CPU clock during A/D conversion.
• If the ADST bit in the ADCON0 register is set to 0 (A/D conversion stops) by a program and A/D conversion
is forcibly terminated during an A/D conversion operation, the conversion result of the A/D converter will be
undefined. If the ADST bit is set to 0 by a program, do not use the value of the AD register.
• Connect 0.1 µF capacitor between the P4_2/VREF pin and AVSS pin.
• Do not enter stop mode during A/D conversion.
• Do not enter wait mode when the CM02 bit in the CM0 register is set to 1 (peripheral function clock stops in
wait mode) during A/D conversion.
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21. Usage Notes
21.8 Notes on Flash Memory
21.8.1 CPU Rewrite Mode
21.8.1.1 Operating Speed
Before entering CPU rewrite mode (EW0 mode), select 5 MHz or below for the CPU clock using the CM06 bit
in the CM0 register and bits CM16 to CM17 in the CM1 register.
This does not apply to EW1 mode.
21.8.1.2 Prohibited Instructions
The following instructions cannot be used in EW0 mode because they reference internal data in flash memory:
UND, INTO, and BRK.
21.8.1.3 Interrupts
Table 21.1 lists the EW0 Mode Interrupts and Table 21.2 lists the EW1 Mode Interrupt.
Table 21.1
Mode
EW0 Mode Interrupts
When Watchdog Timer, Oscillation Stop
Detection, Voltage Monitor 1, or Voltage
Monitor 2 Interrupt Request is
When Maskable Interrupt
Request is Acknowledged
Status
Acknowledged
EW0 During auto-erasure Any interrupt can be used by
allocating a vector in RAM
Once an interrupt request is
acknowledged, the auto-programming
or auto-erasure is forcibly stopped
immediately and the flash memory is
reset. Interrupt handling starts after the
fixed period and the flash memory
restarts. Since the block during auto-
erasure or the address during auto-
programming is forcibly stopped, the
normal value may not be read. Execute
auto-erasure again and ensure it
completes normally.
Auto-programming
Since the watchdog timer does not stop
during the command operation,
interrupt requests may be generated.
Reset the watchdog timer regularly.
NOTES:
1. Do not use the address match interrupt while a command is being executed because the vector of
the address match interrupt is allocated in ROM.
2. Do not use a non-maskable interrupt while block 0 is being automatically erased because the fixed
vector is allocated in block 0.
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21. Usage Notes
Table 21.2
Mode
EW1 Mode Interrupt
When Watchdog Timer, Oscillation Stop
Detection, Voltage Monitor 1, or Voltage
Monitor 2 Interrupt Request is
Acknowledged
When Maskable Interrupt
Request is Acknowledged
Status
EW1 During auto-erasure Auto-erasure is suspended after Once an interrupt request is
(erase-suspend
function enabled)
td(SR-SUS) and interrupt
handling is executed. Auto-
erasure can be restarted by
setting the FMR41 bit in the
acknowledged, auto-programming or
auto-erasure is forcibly stopped
immediately and the flash memory is
reset. Interrupt handling starts after the
FMR4 register to 0 (erase restart) fixed period and the flash memory
after interrupt handling
completes.
restarts. Since the block during auto-
erasure or the address during auto-
programming is forcibly stopped, the
normal value may not be read. Execute
auto-erasure again and ensure it
completes normally.
Since the watchdog timer does not stop
during the command operation,
interrupt requests may be generated.
Reset the watchdog timer regularly
using the erase-suspend function.
During auto-erasure Auto-erasure has priority and the
(erase-suspend
function disabled)
interrupt request
acknowledgement is put on
standby. Interrupt handling is
executed after auto-erasure
completes.
During auto-
programming
(program suspend
function enabled)
Auto-programming is suspended
after td(SR-SUS) and interrupt
handling is executed.
Auto-programming can be
restarted by setting the FMR42 bit
in the FMR4 register to 0
(program restart) after interrupt
handling completes.
During auto-
programming
(program suspend
function disabled)
Auto-programming has priority
and the interrupt request
acknowledgement is put on
standby. Interrupt handling is
executed after auto-programming
completes.
NOTES:
1. Do not use the address match interrupt while a command is executing because the vector of the
address match interrupt is allocated in ROM.
2. Do not use a non-maskable interrupt while block 0 is being automatically erased because the fixed
vector is allocated in block 0.
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21. Usage Notes
21.8.1.4 How to Access
Write 0 before writing 1 when setting the FMR01, FMR02, or FMR11 bit to 1. Do not generate an interrupt
between writing 0 and 1.
21.8.1.5 Rewriting User ROM Area
In EW0 Mode, if the supply voltage drops while rewriting any block in which a rewrite control program is
stored, it may not be possible to rewrite the flash memory because the rewrite control program cannot be
rewritten correctly. In this case, use standard serial I/O mode.
21.8.1.6 Program
Do not write additions to the already programmed address.
21.8.1.7 Entering Stop Mode or Wait Mode
Do not enter stop mode or wait mode during erase-suspend.
21.8.1.8 Program and Erase Voltage for Flash Memory
To perform programming and erasure, use VCC = 2.7 to 5.5 V as the supply voltage. Do not perform
programming and erasure at less than 2.7 V.
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21. Usage Notes
21.9 Notes on Noise
21.9.1 Inserting a Bypass Capacitor between VCC and VSS Pins as a Countermeasure
against Noise and Latch-up
Connect a bypass capacitor (at least 0.1 µF) using the shortest and thickest write possible.
21.9.2 Countermeasures against Noise Error of Port Control Registers
During rigorous noise testing or the like, external noise (mainly power supply system noise) can exceed the
capacity of the MCU's internal noise control circuitry. In such cases the contents of the port related registers
may be changed.
As a firmware countermeasure, it is recommended that the port registers, port direction registers, and pull-up
control registers be reset periodically. However, examine the control processing fully before introducing the
reset routine as conflicts may be created between the reset routine and interrupt routines.
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22. Notes for On-Chip Debugger
22. Notes for On-Chip Debugger
When using the on-chip debugger to develop and debug programs for the R8C/26 Group and R8C/27 Group take note
of the following.
(1) Do not access the registers associated with UART1.
(2) Some of the user flash memory and RAM areas are used by the on-ship debugger. These areas cannot be
accessed by the user.
Refer to the on-chip debugger manual for which areas are used.
(3) Do not set the address match interrupt (registers AIER, RMAD0, and RMAD1 and fixed vector tables) in a
user system.
(4) Do not use the BRK instruction in a user system.
(5) Debugging is available under the condition of supply voltage VCC = 2.7 to 5.5 V. Debugging with the on-chip
debugger under less than 2.7 V is not allowed.
Connecting and using the on-chip debugger has some special restrictions. Refer to the on-chip debugger manual for
details.
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Appendix 1. Package Dimensions
Appendix 1. Package Dimensions
Diagrams showing the latest package dimensions and mounting information are available in the “Packages” section of
the Renesas Technology website.
JEITA Package Code
P-LQFP32-7x7-0.80
RENESAS Code
PLQP0032GB-A
Previous Code
32P6U-A
MASS[Typ.]
0.2g
HD
*1
D
24
17
NOTE)
1. DIMENSIONS "*1" AND "*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION "*3" DOES NOT
INCLUDE TRIM OFFSET.
16
25
bp
b1
Dimension in Millimeters
Reference
Symbol
Min Nom Max
D
E
6.9 7.0 7.1
6.9 7.0 7.1
1.4
Terminal cross section
32
9
A2
HD
HE
A
8.8 9.0 9.2
8.8 9.0 9.2
1.7
1
8
ZD
Index mark
A1
bp
b1
c
0.1 0.2
0
0.32 0.37 0.42
0.35
F
c
0.09
0.20
0.145
0.125
c1
L
L1
0°
8°
e
0.8
Detail F
y
x
0.20
0.10
*3
bp
x
e
y
ZD
ZE
L
0.7
0.7
0.3 0.5 0.7
1.0
L1
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R8C/26 Group, R8C/27 Group Appendix 2. Connection Examples between Serial Writer and On-Chip Debugging Emulator
Appendix 2. Connection Examples between Serial Writer and On-Chip
Debugging Emulator
Appendix Figure 2.1 shows a Connection Example with M16C Flash Starter (M3A-0806) and Appendix Figure 2.2
shows a Connection Example with E8 Emulator (R0E000080KCE00).
VCC
1
2
3
4
5
6
7
8
24
23
22
21
20
19
18
17
TXD
RESET
Connect oscillation circuit(1)
VSS
MODE
10
TXD
7
1
VSS
VCC
RXD
4
M16C Flash Starter
(M3A-0806)
RXD
NOTE:
1. An oscillation circuit must be connected, even when operating with the on-chip oscillator clock.
Appendix Figure 2.1
Connection Example with M16C Flash Starter (M3A-0806)
VCC
Open collector buffer
User logic
4.7kΩ or more
1
24
23
22
21
20
19
18
17
2
3
Connect oscillation circuit(1)
4
VSS
5
6
7
8
4.7kΩ ±10%
RESET
13
14
12
10
8
MODE
MODE
7
VCC
6
4
2
VSS
NOTE:
1. It is not necessary to connect an oscillation circuit when
operating with the on-chip oscillator clock.
E8 emulator
(R0E000080KCE00)
Appendix Figure 2.2
Connection Example with E8 Emulator (R0E000080KCE00)
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Appendix 3. Example of Oscillation Evaluation Circuit
Appendix 3. Example of Oscillation Evaluation Circuit
Appendix Figure 3.1 shows an Example of Oscillation Evaluation Circuit.
VCC
1
2
24
23
22
21
20
19
18
17
RESET
VSS
3
4
5
6
7
8
Connect
oscillation
circuit
NOTE:
1. After reset, the XIN and XCIN clocks stop.
Write a program to oscillate the XIN and XCIN clocks.
Appendix Figure 3.1
Example of Oscillation Evaluation Circuit
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Index
Index
PM1 ....................................................................................... 77
[ A ]
PMR ............................................................... 63, 247, 269, 299
PRCR .................................................................................. 109
PUR0 ..................................................................................... 64
PUR1 ..................................................................................... 64
AD ....................................................................................... 341
ADCON0 ............................................................................. 340
ADCON1 ............................................................................. 341
ADCON2 ............................................................................. 341
ADIC .................................................................................... 115
AIER .................................................................................... 130
[ R ]
RMAD0 ................................................................................ 130
RMAD1 ................................................................................ 130
[ C ]
CM0 ....................................................................................... 81
CM1 ....................................................................................... 82
CPSRF .................................................................................. 86
CSPR .................................................................................. 138
[ S ]
S0RIC .................................................................................. 115
S0TIC .................................................................................. 115
S1RIC .................................................................................. 115
S1TIC ................................................................................... 115
SAR ..................................................................................... 298
SSCRH ................................................................................ 262
SSCRL ................................................................................. 263
SSER ................................................................................... 265
SSMR .................................................................................. 264
SSMR2 ................................................................................ 267
SSRDR ................................................................................ 268
SSSR ................................................................................... 266
SSTDR ................................................................................ 268
SSUIC .................................................................................. 116
[ F ]
FMR0 .................................................................................. 361
FMR1 .................................................................................. 362
FMR4 .................................................................................. 363
FRA0 ..................................................................................... 84
FRA1 ..................................................................................... 84
FRA2 ..................................................................................... 85
FRA4 ..................................................................................... 85
FRA6 ..................................................................................... 85
FRA7 ..................................................................................... 85
[ I ]
[ T ]
ICCR1 ................................................................................. 293
ICCR2 ................................................................................. 294
ICDRR ................................................................................. 298
ICDRS ................................................................................. 298
ICDRT ................................................................................. 298
ICIER ................................................................................... 296
ICMR ................................................................................... 295
ICSR .................................................................................... 297
IICIC .................................................................................... 116
INT0IC ................................................................................. 117
INT1IC ................................................................................. 117
INT3IC ................................................................................. 117
INTEN ................................................................................. 124
INTF .................................................................................... 125
TRA ..................................................................................... 145
TRACR ................................................................................ 144
TRAIC .................................................................................. 115
TRAIOC ....................................... 144, 146, 149, 151, 153, 156
TRAMR ................................................................................ 145
TRAPRE .............................................................................. 145
TRBCR ................................................................................ 160
TRBIC .................................................................................. 115
TRBIOC ............................................... 161, 163, 167, 170, 175
TRBMR ................................................................................ 161
TRBOCR ............................................................................. 160
TRBPR ................................................................................ 162
TRBPRE .............................................................................. 162
TRBSC ................................................................................ 162
TRC ..................................................................................... 188
TRCCR1 ...................................................... 185, 208, 212, 217
TRCCR2 .............................................................................. 189
TRCDF ................................................................................ 190
TRCGRA ............................................................................. 188
TRCGRB ............................................................................. 188
TRCGRC ............................................................................. 188
TRCGRD ............................................................................. 188
TRCIC .................................................................................. 116
TRCIER ............................................................................... 186
TRCIOR0 ............................................................. 192, 201, 206
TRCIOR1 ............................................................. 192, 202, 207
TRCMR ................................................................................ 184
TRCOER ............................................................................. 191
TRCSR ................................................................................ 187
TRECR1 ...................................................................... 228, 235
TRECR2 ...................................................................... 229, 235
TRECSR ...................................................................... 230, 236
TREHR ................................................................................ 227
TREIC .................................................................................. 115
TREMIN ....................................................................... 226, 234
TRESEC ...................................................................... 226, 234
TREWK ................................................................................ 227
[ K ]
KIEN .................................................................................... 128
KUPIC ................................................................................. 115
[ L ]
LINCR ................................................................................. 325
LINST .................................................................................. 326
[ O ]
OCD ...................................................................................... 83
OFS ....................................................................... 27, 137, 356
[ P ]
P1DRR .................................................................................. 64
PDi (i = 0, 1, and 3 to 5) ........................................................ 60
Pi (i = 0, 1, and 3 to 5) ........................................................... 61
PINSR1 ......................................................................... 62, 247
PINSR2 ................................................................................. 62
PINSR3 ................................................................................. 62
PM0 ....................................................................................... 77
Rev.2.10 Sep 26, 2008 Page 452 of 453
REJ09B0278-0210
R8C/26 Group, R8C/27 Group
Index
[ U ]
U0BRG ................................................................................ 244
U0C0 ................................................................................... 245
U0C1 ................................................................................... 246
U0MR .................................................................................. 244
U0RB ................................................................................... 243
U0TB ................................................................................... 243
U1BRG ................................................................................ 244
U1C0 ................................................................................... 245
U1C1 ................................................................................... 246
U1MR .................................................................................. 244
U1RB ................................................................................... 243
U1TB ................................................................................... 243
[ V ]
VCA1 ..................................................................................... 39
VCA2 ................................................................... 39, 40, 86, 87
VW0C .................................................................................... 41
VW1C .............................................................................. 42, 43
VW2C .................................................................................... 44
[ W ]
WDC .................................................................................... 137
WDTR ................................................................................. 138
WDTS .................................................................................. 138
Rev.2.10 Sep 26, 2008 Page 453 of 453
REJ09B0278-0210
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
0.10
Date
Page
Jan 30, 2006
−
First Edition issued
1.00 Nov 08, 2006 All pages “Preliminary” deleted
2
3
Table 1.1 revised
Table 1.2 revised
Figure 1.1 revised
Table 1.3 revised
Table 1.4 revised
Figure 1.4 revised
Table 1.6 revised
4
5
6
7
9
15
Table 4.1;
• 001Ch: “00h” → “00h, 10000000b” revised
• 000Fh: “000XXXXXb” → “00X11111b” revised
• 0029h: “High-Speed On-Chip Oscillator Control Register 4, FRA4,
When shipping” added
• 002Bh: “High-Speed On-Chip Oscillator Control Register 6, FRA6,
When shipping” added
• 0032h: “00h, 01000000b” → “00h, 00100000b” revised
• 0038h: “00001000b, 01001001b” → “0000X000b, 0100X001b” revised
• NOTE3 and 4 revised; NOTE6 added
18
Table 4.4;
• 00E0h, 00E1h, 00E5h, 00E8h, 00E9h: “XXh” → “00h” revised
• 00FDh: “XX00000000b” → “00h” revised
23
24
25
26
27
28
33
35
46
52
53
58
60
64
65
69
70
71
Table 5.2 revised
Figure 5.4 NOTE2 revised
5.1.1 (2), 5.1.2 (4) revised
Figure 5.5, Figure 5.6 revised
Figure 5.7 revised
5.3 revised
Figure 6.5; VCA2 register NOTE6 revised
Figure 6.7 revised
Figure 7.2 revised
Figure 7.9 PINSR2 register revised
Figure 7.10 revised
Table 7.17 revised
Table 7.25 revised
Table 7.35, Table 7.36 revised
Table 7.37, Table 7.39 revised
Table 10.1 NOTE5 revised
Figure 10.1 revised
Figure 10.2 revised
C - 1
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
73
1.00 Nov 08, 2006
Figure 10.4 revised
74
Figure 10.5; FRA0 register NOTE2 and FRA1 register NOTE1 revised
Figure 10.6; FRA2 register revised, registers FRA4 and FRA6 added
Figure 10.8 NOTE6 revised
Figure 10.9 NOTE1 revised
10.2.2 revised
75
76
77
78
80
10.4.3 revised, 10.4.8 added
Table 10.2 revised
81
83
10.5.2.2, 10.5.2.3 revised
10.5.2.4, Table 10.3 revised
Figure 10.11 added
84
85
86
10.5.2.5 added, Figure 10.12 revised
10.5.3.3 revised, Figure 10.13 added
10.6.1 revised
88
91
92
Figure 10.16 revised
93
Figure 10.17 revised
94
10.7.1 revised, 10.7.2 added, 10.7.4 fOCO40M deleted
Figure 11.1 revised
95
96
Figure 12.1 revised
103
106
108
111
117
121
122
123
126
127
129
130
131
132
133
134
135
136
137
138
Figure 12.5 NOTE3 revised
Table 12.5 revised
Figure 12.10 revised
Figure 12.13 revised
Table 12.8 revised
12.6.7 deleted
Figure 13.1 revised
Figure 13.2 revised
Table 13.3 NOTE2 revised
14 revised
14.1, Figure 14.1 revised
Figure 14.2 revised
Figure 14.3 revised
Table 14.2, Figure 14.4 revised
14.1.1.1, Figure 14.5 added
Table 14.3 revised
Figure 14.6 revised
Table 14.4 revised
Figure 14.7 revised
Table 14.5 revised
C - 2
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
139
140
141
142
143
145
146
147
148
149
150
151
152
153
154
155
156
158
159
160
161
162
178
182
190
194
198
199
203
205
206
214
226
228
229
230
232
235
236
1.00 Nov 08, 2006
Figure 14.8 revised
Figure 14.9 revised
Table 14.6 revised
Figure 14.10 revised
Figure 14.11 revised
14.2, Figure 14.12 revised
Figure 14.13 revised
Figure 14.14 revised
Figure 14.15 revised
Table 14.7, Figure 14.16 revised
14.2.1.1 added
Figure 14.17 added
Table 14.8 revised
Figure 14.18 revised
Figure 14.19 revised
Table 14.9 revised
Figure 14.20 revised
14.2.3.1 added
Table 14.10 revised
Figure 14.22 revised
Figure 14.23 revised
14.2.5 revised
Figure 14.38 revised
Figure 14.40 revised
Figure 14.47 revised
Figure 14.50 revised
Table 14.22 revised
Figure 14.54 revised
Table 14.24 revised
14.4 revised
Figure 14.59 revised
Figure 14.69 revised
Figure 15.4; U0MR to U1MR register revised
Figure 15.6 revised
Figure 15.7; PMR register revised
Table 15.1 NOTE2 revised
Figure 15.8 revised
Table 15.4 NOTE1 revised
“TXD0” → “TXDi” revised
C - 3
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
237
238
242
245
246
249
250
251
258
259
262
263
265
266
267
271
274
275
277
282
285
287
289
290
1.00 Nov 08, 2006
Figure 15.11 revised
Figure 15.12 revised
Table 16.2 NOTE2 deleted
Figure 16.3 revised
Figure 16.4 revised
Figure 16.7 revised
Figure 16.8 SSTDR register NOTE1 deleted
Figure 16.9 revised
16.2.5.2 revised
Figure 16.14 NOTE2 deleted
16.2.5.4 revised
Figure 16.17 NOTE2 deleted
Figure 16.18 revised
16.2.6.2 revised
Figure 16.19 revised
16.2.8.1 revised
Figure 16.23 revised
Figure 16.24 NOTE1 revised
Figure 16.26 NOTE3 revised
Figure 16.31 revised
Figure 16.32 revised
Figure 16.33, Figure 16.34 revised
Figure 16.35 revised
Figure 16.36 revised
301 to 304 Figure 16.46 to Figure 16.49 figure title revised and Figure 16.47 revised
306 to 320 17 “Sync” → “Synch” revised
308
310
311
312
313
314
315
316
317
318
319
321
322
Figure 17.2 revised
Figure 17.4 revised
Figure 17.5 revised
Figure 17.6 revised
17.4.2 (5), Figure 17.7 revised
Figure 17.8 revised
Figure 17.9 revised
Figure 17.10 revised
Figure 17.11 revised
17.4.4, Figure 17.12 added
17.5, Table 17.2 revised
Table 18.1 revised
Figure 18.1 revised
C - 4
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
324
325
329
331
332
333
334
335
339
340
342
346
347
350
351
352
353
354
357
364
365
366
367
368
369
370
371
377
378
379
382
383
387
390
393
395
401
402
403
1.00 Nov 08, 2006
Figure 18.3 revised
Table 18.2 revised
Figure 18.6 revised
18.3 revised
Figure 18.10 revised
18.6 revised
18.7 revised
Table 19.1 revised
Figure 19.4 NOTE2 revised
Table 19.3 revised
19.4.2.1 revised
Figure 19.7 revised
Figure 19.8 revised
19.4.3.1, 19.4.3.2 revised
19.4.3.4 revised, Figure 19.12 title revised
Figure 19.13 added
Figure 19.14 title revised
Figure 19.15 revised
Figure 19.16 revised
19.7.1.7 deleted
Table 20.2 revised
Figure 20.1 title revised
Table 20.4 revised
Table 20.5 revised
Figure 20.2 title revised and Table 20.7 NOTE4 added
Table 20.9, Figure 20.3 revised and Table 20.10 deleted
Table 20.10, Table 20.11 revised
Table 20.15 revised
Table 20.16 revised
Table 20.17 revised
Table 20.22 revised
Table 20.23 revised
Table 20.29 revised
21.1.1 revised, 21.1.2 added, 21.1.4 fOCO40M deleted
21.2.7 deleted
21.3.2 revised
21.5.1.1 revised
21.6 revised
21.7 revised
C - 5
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
406
408
409
−
1.00 Nov 08, 2006
21.8.1.7 deleted
22 (2) revised, (5) deleted
Appendix 1; “Diagrams showing the latest...website.” added
“J, K version” added
1.10
Jan 17, 2007
1
1 “J and K versions are under development...notice.” added
1.1 revised
2
3
Table 1.1 revised
Table 1.2 revised
4
Figure 1.1 NOTE3 added
Table 1.3 and Figure 1.2 revised
Table 1.4 and Figure 1.3 revised
Figure 1.4 NOTE3 added
Table 1.5 revised
5
6
7
8
9
Table 1.6 NOTE2 added
Figure 3.1 revised
13
14
15
Figure 3.2 revised
Table 4.1; “0000h to 003Fh” → “0000h to 002Fh” revised
• NOTE3 added
16
Table 4.2; “0040h to 007Fh” → “0030h to 007Fh” revised
• 0032h, 0036h: value after reset is revised
• 0038h: NOTE revised
• NOTES 2, 5, 6 revised and NOTES 7, 8 added
18
19
22
Table 4.4 NOTE2 added
Table 4.5 NOTE2 added
5 “(for N, D version only)” added
Table 5.1 NOTE1 added
Figure 5.1 figure title “(N, D Version)” added
23
25
27
28
Figure 5.2 added
Figure 5.5 revised
Figures 5.6 and 5.7 revised
5.2 revised
Figure 5.8 revised
29
30
Figure 5.9 added
5.3, 5.4 titles “(N, D Version)” added
5.5 added
32
33
6 “...voltage monitor 0 reset (for N, D version only), voltage monitor 1
interrupt (for N, D version only)...” revised
Table 6.1 table title “(N, D Version)” added
Table 6.2 added
Figure 6.1 figure title “(N, D Version)” added
C - 6
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
1.10
Date
Page
34
Jan 17, 2007
Figure 6.2 added
Figure 6.3 figure title “(For N, D Version Only)” added
35
Figure 6.4 figure title “(N, D Version)” added
Figure 6.5 added
37
38
39
40
41
42
44
45
46
47
50
56
62
63
73
78
79
80
81
83
84
Figure 6.7; VCA2 register figure title and NOTE6 revised
Figure 6.8 added
Figure 6.9 figure title “(For N, D Version Only)” added
Figure 6.10 figure title “(N, D Version)” added
Figure 6.11 added
Figure 6.12 NOTE8 revised
6.2 Title “(For N, D Version Only)” added
6.3 Title “(N, D Version)” added
Figure 6.14 figure title “(N, D Version)” added
6.4 added
7 NOTE1 added and Table 7.1 NOTE3 revised
Figure 7.5 revised
Figure 7.13 “(For N, D Version Only)” added
Table 7.4 NOTE1 revised
Table 7.35 NOTE1 added and Table 7.36 NOTE2 added
10 revised and Table 10.1 “(For N, D Version Only)” added
Figure 10.1 NOTE1 added
Figure 10.2 NOTE12 added
Figure 10.3 NOTE10 added
Figure 10.5; FRA0 register NOTE2 revised
Figure 10.6; FRA2 register NOTE2 added, registers FRA4 and FRA6
“For N, D Version Only” added
85
Figure 10.7 “(For N, D Version Only)” added, figure 10.8 figure title and
NOTE6 revised
86
87
88
89
90
91
92
93
95
96
97
Figure 10.9 added
Figure 10.10 added
Figure 10.11 NOTE1 revised
10.2.2 revised
10.3 Title “(For N, D Version Only)” added
10.4.1, 10.4.2, and 10.4.8 revised
Table 10.2 NOTE1 added
10.5.1.2 and 10.5.1.4 revised
Table 10.3 revised
Figure 10.13 revised
10.5.2.5 and Figure 10.14 revised
C - 7
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
1.10
Date
Page
98
Jan 17, 2007
Table 10.4 NOTE1 added
Figure 10.15 revised
99
101
103
104
105
106
110
Figure 10.17 “(For N, D Version Only)” added
Table 10.6 NOTE1 added
Figure 10.19 “(N, D Version)” added
Figure 10.20 added
10.7.1, 10.7.2 revised
12.1.3.1 revised
12.1.3.3 “(For N, D Version Only)” added
111
118
120
121
127
131
135
140
141
143
146
150
153
167
171
213
217
218
226
227
230
252
287
317
333
335
338
341
346
351
Table 12.1 NOTE2 added
Table 12.5 NOTE1 added
Figure 12.10 NOTE1 added
Figure 12.11 NOTE2 added
Table 12.6 revised
12.6.4 deleted
Figure 13.2; OFS register revised
Table 14.1 NOTES 1, 2 added
Figure 14.1 NOTE1 added
Figure 14.3 NOTE2 added
Table 14.3 NOTE2 added
Table 14.5 NOTE1 added
Table 14.6 NOTE2 added
Table 14.9 NOTE2 added
Table 14.10 NOTE2 added
Figure 14.56 revised
14.4 “(For J, K version...)” added
14.4.1 Title “(For N, D Version Only)” added
Figure 14.69 NOTE1 added
Table 14.27 NOTE1 added
Figure 14.74 NOTE2 added
15.3 revised
Figure 16.24 NOTE7 added
16.3.8.2, 16.3.8.3 added
Table 18.1 revised
Figure 18.2 NOTE4 revised
Figure 18.4 NOTE4 revised
Figure 18.6 NOTE4 revised
18.7 revised
Figure 19.4 revised
C - 8
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
1.10
Date
Page
353
361
364
368
383
Jan 17, 2007
19.4.1, 19.4.2 revised
Figure 19.11 revised
Figure 19.13 revised
Table 19.6 revised
Table 20.10 revised
402 to 421 20.2 J, K Version added
422
423
432
434
436
443
−
21.1.1, 21.1.2 revised
21.2.4 deleted
21.4 revised
21.5.2.2, 21.5.2.3 added
21.7 revised
Appendix Figure 2.1 NOTE2 deleted
1.20 May 18, 2007
“RENESAS TECHNICAL UPDATE” reflected:
TN-16C-A164A/E, TN-16C-A167A/E
2
3
Table 1.1 revised
Table 1.2 revised
5
Table 1.3 revised
6
Figure 1.2 revised
7
Table 1.4 revised
8
Figure 1.3 revised
9
Figure 1.4 NOTE4 added
Figure 3.1 part number revised
Figure 3.2 part number revised
Figure 5.4 revised
15
16
26
54
55
68
70
82
85
98
104
124
134
141
147
158
159
165
Figure 7.1 revised
Figure 7.2 revised
Table 7.18 revised
Table 7.24 revised
Figure 10.2 NOTE3 revised
Figure 10.5 FRA1 register revised
10.5.2.4 revised
10.6.1 revised
12.2.1 revised
Figure 12.20 NOTE2 revised
14 “two 16-bit timers” → “a 16-bit timer” revised
Figure 14.5 revised
14.1.6 revised
Figure 14.12 revised
Figure 14.17 revised
C - 9
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
173
1.20 May 18, 2007
Table 14.10 revised
176 to 179 14.2.5.1 to 14.2.5.4 added
203
229
243
253
261
262
263
264
265
266
267
288
292
293
294
295
296
297
321
350
351
356
358
359
360
362
364
365
367
368
370
387
410
412
428
430
Table 14.18 revised
Figure 14.69 revised
Figure 15.4 UiMR register NOTE2 deleted
Table 15.5 NOTE2 added
Figure 16.2 NOTE4 deleted
Figure 16.3 NOTE4 deleted
Figure 16.4 NOTE2 deleted
Figure 16.5 NOTE1 deleted
Figure 16.6 NOTE2 revised and NOTE7 deleted
Figure 16.7 NOTE5 revised
Figure 16.8 Registers SSTDR and SSRDR; NOTE1 deleted
16.2.8.1 deleted
Figure 16.24 NOTE6 deleted
Figure 16.25 NOTE5 deleted
Figure 16.26 NOTE7 deleted
Figure 16.27 NOTE3 deleted
Figure 16.28 NOTE7 deleted
Figure 16.29 Registers SAR, ICDRT, and ICDRR; NOTE1 deleted
16.3.8.1 deleted
18.7 revised
Table 19.2 revised
Table 19.3 revised
19.4.2.4 revised
19.4.2.15 revised
Figure 19.5 NOTES 3 and 5 revised
Figure 19.7 NOTE5 revised
Figure 19.9 revised
Figure 19.11 revised
19.4.3.4 revised
Figure 19.13 revised
Figure 19.15 revised
Table 20.10 revised
Table 20.39 NOTE4 added
Table 20.42 revised
Figure 21.1 NOTE2 revised
21.3.1 revised
431 to 434 21.3.2.1 to 21.3.2.4 added
C - 10
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
440
442
450
162
176
328
329
331
433
1.20 May 18, 2007
21.5.1.2 and 21.5.2.1 deleted
21.7 revised
Appendix Figure 3.1 NOTE1 revised
Figure 14.15 TRBPR register NOTE2 revised
14.2.5 NOTE revised
1.30
Jun 01, 2007
Figure 17.6 revised
Figure 17.7 “B0CLR bit” revised
Figure 17.9 revised
Figure 21.3 revised
2.00 Mar 01, 2008
1, 407 1.1, 20.2 “J and K versions are ...” deleted
5, 7
11
Table 1.3, Table 1.4 revised
Table 1.6 NOTE3 added
15, 16 Figure 3.1, Figure 3.2; “Expanded area” deleted
17
18
Table 4.1 “002Ch” added
Table 4.2 “0036h”; J, K version “0100X000b” → “0100X001b”
27, 137, Figure 5.5, Figure 13.2, Figure 19.4; “OFS Register” revised
356
67
70
Table 7.14 revised
Table 7.26 revised
71
Table 7.28 revised
80
Figure 10.1 revised
81
Figure 10.2 “Set to 0.” → “Do not set to 1.”
Figure 10.6 “FRA7 Register” added
10.2.2 revised
85
90
93
10.4.9 added
95
10.5.1.4 “... clock ...” → “... on-chip oscillator ...”
Table 12.2 “Reference” revised
114
124
12.2.1 “The INT0 pin is shared ...” deleted
Table 12.6 added
142
143
159
Table 14.1 “• fC32” deleted
Figure 14.1 “TSTART” → “TCSTF”
14.2 “The reload register and ...” deleted
Figure 14.2 “TSTRAT” → “TSTART”
162
166
Figure 14.15 revised
Table 14.8 “(P1_3)” “• TRBO pin select function ...” added
169, 174 Table 14.9, Table 14.10 “• TRBO pin select function ...” added
170
189
192
Figure 14.20 “... When write, ...” → “... If necessary, ...”
Figure 14.33 revised
Figure 14.36 TRCIOR0: b3 revised, NOTE4 added
C - 11
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
199
2.00 Mar 01, 2008
14.3.4 “The TRCGRA register can also select fOCO128 signal ...” added
Table 14.16 revised
200
201
206
209
210
216
239
246
257
263
266
283
297
323
328
329
332
335
349
373
Figure 14.42 revised
Figure 14.43 b3 revised, NOTE3 added
Figure 14.47 b3 revised
Figure 14.50 “• The CCLR bit ... 0 ...” → “• The CCLR bit ... 1 ...”
Table 14.20 revised
Table 14.22 revised
Figure 14.78 revised
Figure 15.6 “(b7-b4)” → “(b7-b6)”
Table 15.7 revised
Figure 16.3 “Cannot write to this.” → “The SOLP bit ...”
Figure 16.6 NOTE7 added
Figure 16.18 revised
Figure 16.28 NOTE7 added
Figure 17.1 revised
Figure 17.5 revised
Figure 17.6 revised
Figure 17.9 revised
Figure 17.12 revised
Figure 18.10 revised
Table 19.6 “FRM0 Register ...” → “FMR0 Register ...”
382, 407 Table 20.2, Table 20.35; NOTE2 revised
388
438
450
−
Table 20.10 revised, NOTE4 added
Figure 21.4 revised
Appendix Figure 2.2 revised
2.10 Sep 26, 2008
“RENESAS TECHNICAL UP DATE” reflected: TN-16C-A172A/E
Figure 5.9 revised
31
60
Figure 7.8 NOTE3 revised
61
Figure 7.9 NOTE2 revised
143
151
280
352
Figure 14.1 revised
Figure 14.7 TOENA bit revised
16.2.5.4 “When exiting transmit/receive .... set the RE bit to 1.” added
Table 19.1 NOTE1 revised
384, 409 Table 20.4, Table 20.37 NOTE2, NOTE4 revised
385, 410 Table 20.5, Table 20.38 NOTE2, NOTE5 revised
411
Table 20.39 Parameter: Voltage monitor 1 reset generation time added
NOTE5 added
Table 20.40 revised
C - 12
REVISION HISTORY
R8C/26 Group, R8C/27 Group Hardware Manual
Description
Summary
Rev.
Date
Page
412
2.10 Sep 26, 2008
Table 20.41 revised
Figure 20.22 revised
C - 13
R8C/26 Group, R8C/27 Group Hardware Manual
Publication Date: Rev.0.10 Jan 30, 2006
Rev.2.10 Sep 26, 2008
Published by: Sales Strategic Planning Div.
Renesas Technology Corp.
© 2008. Renesas Technology Corp., All rights reserved. Printed in Japan
R8C/26 Group, R8C/27 Group
Hardware Manual
2-6-2, Ote-machi, Chiyoda-ku, Tokyo,100-0004, Japan
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