DSPIC30F2013AT-20IML-ES [MICROCHIP]
High-Performance Digital Signal Controllers; 高性能数字信号控制器型号: | DSPIC30F2013AT-20IML-ES |
厂家: | MICROCHIP |
描述: | High-Performance Digital Signal Controllers |
文件: | 总220页 (文件大小:5084K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
dsPIC30F3014, dsPIC30F4013
Data Sheet
High-Performance
Digital Signal Controllers
2004 Microchip Technology Inc.
Advance Information
DS70138C
Note the following details of the code protection feature on Microchip devices:
•
•
Microchip products meet the specification contained in their particular Microchip Data Sheet.
Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the
intended manner and under normal conditions.
•
There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our
knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data
Sheets. Most likely, the person doing so is engaged in theft of intellectual property.
•
•
Microchip is willing to work with the customer who is concerned about the integrity of their code.
Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not
mean that we are guaranteeing the product as “unbreakable.”
Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our
products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts
allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.
Information contained in this publication regarding device
applications and the like is provided only for your convenience
and may be superseded by updates. It is your responsibility to
ensure that your application meets with your specifications.
MICROCHIP MAKES NO REPRESENTATIONS OR WAR-
RANTIES OF ANY KIND WHETHER EXPRESS OR IMPLIED,
WRITTEN OR ORAL, STATUTORY OR OTHERWISE,
RELATED TO THE INFORMATION, INCLUDING BUT NOT
LIMITED TO ITS CONDITION, QUALITY, PERFORMANCE,
MERCHANTABILITY OR FITNESS FOR PURPOSE.
Microchip disclaims all liability arising from this information and
its use. Use of Microchip’s products as critical components in
life support systems is not authorized except with express
written approval by Microchip. No licenses are conveyed,
implicitly or otherwise, under any Microchip intellectual property
rights.
Trademarks
The Microchip name and logo, the Microchip logo, Accuron,
dsPIC, KEELOQ, microID, MPLAB, PIC, PICmicro, PICSTART,
PRO MATE, PowerSmart, rfPIC, and SmartShunt are
registered trademarks of Microchip Technology Incorporated
in the U.S.A. and other countries.
AmpLab, FilterLab, MXDEV, MXLAB, PICMASTER, SEEVAL,
SmartSensor and The Embedded Control Solutions Company
are registered trademarks of Microchip Technology
Incorporated in the U.S.A.
Analog-for-the-Digital Age, Application Maestro, dsPICDEM,
dsPICDEM.net, dsPICworks, ECAN, ECONOMONITOR,
FanSense, FlexROM, fuzzyLAB, In-Circuit Serial
Programming, ICSP, ICEPIC, Migratable Memory, MPASM,
MPLIB, MPLINK, MPSIM, PICkit, PICDEM, PICDEM.net,
PICLAB, PICtail, PowerCal, PowerInfo, PowerMate,
PowerTool, rfLAB, rfPICDEM, Select Mode, Smart Serial,
SmartTel and Total Endurance are trademarks of Microchip
Technology Incorporated in the U.S.A. and other countries.
SQTP is a service mark of Microchip Technology Incorporated
in the U.S.A.
All other trademarks mentioned herein are property of their
respective companies.
© 2004, Microchip Technology Incorporated, Printed in the
U.S.A., All Rights Reserved.
Printed on recycled paper.
Microchip received ISO/TS-16949:2002 quality system certification for
its worldwide headquarters, design and wafer fabrication facilities in
Chandler and Tempe, Arizona and Mountain View, California in
October 2003. The Company’s quality system processes and
procedures are for its PICmicro® 8-bit MCUs, KEELOQ® code hopping
devices, Serial EEPROMs, microperipherals, nonvolatile memory and
analog products. In addition, Microchip’s quality system for the design
and manufacture of development systems is ISO 9001:2000 certified.
DS70138C-page ii
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
dsPIC30F3014/4013 High-Performance
Digital Signal Controllers
Peripheral Features:
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
• High current sink/source I/O pins: 25 mA/25 mA
• Up to five 16-bit timers/counters; optionally pair up
16-bit timers into 32-bit timer modules
• Up to four 16-bit Capture input functions
• Up to four 16-bit Compare/PWM output functions
• Data Converter Interface (DCI) supports common
2
audio Codec protocols, including I S and AC’97
High-Performance Modified RISC CPU:
• 3-wire SPI™ module (supports 4 Frame modes)
• Modified Harvard architecture
2
• I C™ module supports Multi-Master/Slave mode
• C compiler optimized instruction set architecture
• Flexible addressing modes
and 7-bit/10-bit addressing
• Up to two addressable UART modules with FIFO
buffers
• 84 base instructions
• 24-bit wide instructions, 16-bit wide data path
• Up to 48 Kbytes on-chip Flash program space
• 2 Kbytes of on-chip data RAM
• CAN bus module compliant with CAN 2.0B
standard
• 1 Kbyte of non-volatile data EEPROM
• 16 x 16-bit working register array
• Up to 30 MIPs operation:
Analog Features:
• 12-bit Analog-to-Digital Converter (A/D) with:
- 100 Ksps conversion rate
- DC to 40 MHz external clock input
- Up to 13 input channels
- 4 MHz-10 MHz oscillator input with
PLL active (4x, 8x, 16x)
- Conversion available during Sleep and Idle
• Programmable Low Voltage Detection (PLVD)
• Up to 33 interrupt sources:
- 8 user selectable priority levels
- 3 external interrupt sources
- 4 processor traps
• Programmable Brown-out Detection and Reset
generation
Special Microcontroller Features:
• Enhanced Flash program memory:
DSP Features:
- 10,000 erase/write cycle (min.) for
• Dual data fetch
industrial temperature range, 100K (typical)
• Modulo and Bit-reversed modes
• Data EEPROM memory:
• Two 40-bit wide accumulators with optional
saturation logic
- 100,000 erase/write cycle (min.) for
industrial temperature range, 1M (typical)
• 17-bit x 17-bit single cycle hardware fractional/
integer multiplier
• Self-reprogrammable under software control
• Power-on Reset (POR), Power-up Timer (PWRT)
and Oscillator Start-up Timer (OST)
• All DSP instructins are single cycle
- Multiply-Accumulate (MAC) operation
• Single cycle 16 shift
• Flexible Watchdog Timer (WDT) with on-chip low
power RC oscillator for reliable operation
• Fail-Safe Clock Monitor operation:
- Detects clock failure and switches to on-chip
low power RC oscillator
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 1
dsPIC30F3014/4013
Special Microcontroller Features (Cont.):
CMOS Technology:
• Programmable code protection
• Low power, high speed Flash technology
• Wide operating voltage range (2.5V to 5.5V)
• Industrial and Extended temperature ranges
• Low power consumption
• In-Circuit Serial Programming™ (ICSP™)
• Selectable Power Management modes:
- Sleep, Idle and Alternate Clock modes
dsPIC30F3014/4013 Controller Family
Program Memory
Output
SRAM EEPROM Timer Input
Codec A/D12-bit
Interface 100 Ksps
Device
Pins
Comp/Std
PWM
Bytes
Bytes
16-bit Cap
Bytes Instructions
dsPIC30F3014 40/44 24K
dsPIC30F4013 40/44 48K
8K
2048
2048
1024
1024
3
5
2
4
2
4
-
13 ch
2
2
1
1
1
1
0
1
2
AC’97, I S 13 ch
16K
Pin Diagrams
40-Pin PDIP
AVDD
MCLR
1
40
AN0/VREF+/CN2/RB0
AN1/VREF-/CN3/RB1
AVss
AN9/RB9
2
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
3
AN2/SS1/LVDIN/CN4/RB2
AN3/CN5/RB3
AN4/CN6/RB4
AN5/CN7/RB5
PGC/EMUC/AN6/OCFA/RB6
PGD/EMUD/AN7/RB7
AN8/RB8
AN10/RB10
AN11/RB11
4
5
AN12/RB12
EMUC2/OC1/RD0
EMUD2/OC2/RD1
VDD
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Vss
VDD
RF0
Vss
RF1
OSC1/CLKIN
U2RX/CN17/RF4
U2TX/CN18/RF5
U1RX/SDI1/SDA/RF2
EMUD3/U1TX/SDO1/SCL/RF3
EMUC3/SCK1/RF6
IC1/INT1/RD8
RD2
OSC2/CLKO/RC15
EMUD1/SOSCI/T2CK/U1ATX/CN1/RC13
EMUC1/SOSCO/T1CK/U1ARX/CN0/RC14
INT0/RA11
IC2/INT2/RD9
RD3
Vss
VDD
DS70138C-page 2
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
Pin Diagrams (Continued)
44-Pin TQFP
NC
U1RX/SDI1/SDA/RF2
U2TX/CN18/RF5
U2RX/CN17/RF4
RF1
33
32
31
30
29
28
27
26
1
EMUD1/SOSCI/T2CK/U1ATX/CN1/RC13
OSC2/CLKO/RC15
OSC1/CLKIN
2
3
4
VSS
RF0
5
VDD
VSS
dsPIC30F3014
6
AN8/RB8
VDD
7
PGD/EMUD/AN7/RB7
PGC/EMUC/AN6/OCFA/RB6
AN5/CN7/RB5
EMUD2/OC2/RD1
EMUC2/OC1/RD0
AN12/RB12
AN11/RB11
8
9
25
24
23
10
11
AN4/CN6/RB4
Note:
For descriptions of individual pins, see Section 1.0.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 3
dsPIC30F3014/4013
Pin Diagrams (Continued)
44-Pin QFN
U1RX/SDI1/SDA/RF2
1
OSC2/CLKO/RC15
OSC1/CLKIN
VSS
33
32
31
30
29
28
27
26
25
24
23
U2TX/CN18/RF5
2
U2RX/CN17/RF4
3
RF1
4
VSS
RF0
5
VDD
VSS
VDD
6
dsPIC30F3014
VDD
VDD
AN8/RB8
7
8
PGD/EMUD/AN7/RB7
PGC/EMUC/AN6/OCFA/RB6
AN5/CN7/RB5
AN4/CN6/RB4
EMUD2/OC2/RD1
EMUC2/OC1/RD0
AN12/RB12
9
10
11
Note:
For descriptions of individual pins, see Section 1.0.
DS70138C-page 4
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
Pin Diagrams (Continued)
40-Pin PDIP
MCLR
AN0/VREF+/CN2/RB0
AN1/VREF-/CN3/RB1
1
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
AVDD
2
AVSS
3
AN9/CSCK/RB9
AN10/CSDI/RB10
AN11/CSDO/RB11
AN12/COFS/RB12
EMUC2/OC1/RD0
EMUD2/OC2/RD1
VDD
AN2/SS1/LVDIN/CN4/RB2
4
AN3/CN5/RB3
5
AN4/IC7/CN6/RB4
6
AN5/IC8/CN7/RB5
7
PGC/EMUC/AN6/OCFA/RB6
8
PGD/EMUD/AN7/RB7
9
10
11
12
13
14
15
16
17
18
19
20
AN8/RB8
VSS
VDD
C1RX/RF0
C1TX/RF1
VSS
U2RX/CN17/RF4
U2TX/CN18/RF5
U1RX/SDI1/SDA/RF2
EMUD3/U1TX/SDO1/SCL/RF3
EMUC3/SCK1/RF6
IC1/INT1/RD8
OC3/RD2
OSC1/CLKIN
OSC2/CLKO/RC15
EMUD1/SOSCI/T2CK/U1ATX/CN1/RC13
EMUC1/SOSCO/T1CK/U1ARX/CN0/RC14
INT0/RA11
IC2/INT2/RD9
OC4/RD3
VSS
VDD
44-Pin TQFP
NC
U1RX/SDI1/SDA/RF2
U2TX/CN18/RF5
U2RX/CN17/RF4
CTX1/RF1
33
32
31
30
29
28
27
26
1
EMUD1/SOSCI/T2CK/U1ATX/CN1/RC13
OSC2/CLKO/RC15
OSC1/CLKIN
2
3
4
VSS
CRX1/RF0
5
VDD
VSS
dsPIC30F4013
6
AN8/RB8
VDD
7
PGD/EMUD/AN7/RB7
PGC/EMUC/AN6/OCFA/RB6
AN5/IC8/CN7/RB5
AN4/IC7/CN6/RB4
EMUD2/OC2/RD1
EMUC2/OC1/RD0
AN12/COFS/RB12
AN11/CSDO/RB11
8
9
25
24
23
10
11
Note:
For descriptions of individual pins, see Section 1.0.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 5
dsPIC30F3014/4013
Pin Diagrams (Continued)
44-Pin QFN
U1RX/SDI1/SDA/RF2
U2TX/CN18/RF5
U2RX/CN17/RF4
CTX1/RF1
1
2
33
32
31
30
29
28
27
26
25
24
23
OSC2/CLKO/RC15
OSC1/CLKIN
VSS
3
4
VSS
5
VDD
CRX1/RF0
6
VDD
VSS
dsPIC30F4013
AN8/RB8
7
VDD
PGD/EMUD/AN7/RB7
PGC/EMUC/AN6/OCFA/RB6
AN5/IC8/CN7/RB5
AN4/IC7/CN6/RB4
8
VDD
9
EMUD2/OC2/RD1
EMUC2/OC1/RD0
AN12/COFS/RB12
10
11
For descriptions of individual pins, see Section 1.0.
DS70138C-page 6
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
Table of Contents
1.0 Device Overview .......................................................................................................................................................................... 9
2.0 CPU Architecture Overview........................................................................................................................................................ 13
3.0 Memory Organization................................................................................................................................................................. 23
4.0 Address Generator Units............................................................................................................................................................ 35
5.0 Flash Program Memory.............................................................................................................................................................. 41
6.0 Data EEPROM Memory ............................................................................................................................................................. 47
7.0 I/O Ports ..................................................................................................................................................................................... 51
8.0 Interrupts .................................................................................................................................................................................... 55
9.0 Timer1 Module ........................................................................................................................................................................... 63
10.0 Timer2/3 Module ........................................................................................................................................................................ 67
11.0 Timer4/5 Module ....................................................................................................................................................................... 73
12.0 Input Capture Module................................................................................................................................................................. 77
13.0 Output Compare Module............................................................................................................................................................ 81
14.0 SPI Module................................................................................................................................................................................. 85
15.0 I2C Module................................................................................................................................................................................. 89
16.0 Universal Asynchronous Receiver Transmitter (UART) Module ................................................................................................ 97
17.0 CAN Module............................................................................................................................................................................. 105
18.0 Data Converter Interface (DCI) Module.................................................................................................................................... 115
19.0 12-bit Analog-to-Digital Converter (A/D) Module...................................................................................................................... 125
20.0 System Integration ................................................................................................................................................................... 131
21.0 Instruction Set Summary.......................................................................................................................................................... 149
22.0 Development Support............................................................................................................................................................... 157
23.0 Electrical Characteristics.......................................................................................................................................................... 163
24.0 Packaging Information.............................................................................................................................................................. 205
Index .................................................................................................................................................................................................. 209
On-Line Support................................................................................................................................................................................. 215
Systems Information and Upgrade Hot Line...................................................................................................................................... 215
Reader Response.............................................................................................................................................................................. 216
Product Identification System ............................................................................................................................................................ 217
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It is our intention to provide our valued customers with the best documentation possible to ensure successful use of your Microchip
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enhanced as new volumes and updates are introduced.
If you have any questions or comments regarding this publication, please contact the Marketing Communications Department via
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welcome your feedback.
Most Current Data Sheet
To obtain the most up-to-date version of this data sheet, please register at our Worldwide Web site at:
http://www.microchip.com
You can determine the version of a data sheet by examining its literature number found on the bottom outside corner of any page.
The last character of the literature number is the version number, (e.g., DS30000A is version A of document DS30000).
Errata
An errata sheet, describing minor operational differences from the data sheet and recommended workarounds, may exist for current
devices. As device/documentation issues become known to us, we will publish an errata sheet. The errata will specify the revision
of silicon and revision of document to which it applies.
To determine if an errata sheet exists for a particular device, please check with one of the following:
•
Microchip’s Worldwide Web site; http://www.microchip.com
Your local Microchip sales office (see last page)
•
When contacting a sales office, please specify which device, revision of silicon and data sheet (include literature number) you are
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2004 Microchip Technology Inc.
Advance Information
DS70138C-page 7
dsPIC30F3014/4013
NOTES:
DS70138C-page 8
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
This document contains specific information for the
dsPIC30F3014/4013 Digital Signal Controller (DSC)
devices. The dsPIC30F3014/4013 devices contain
extensive Digital Signal Processor (DSP) functionality
within a high-performance 16-bit microcontroller (MCU)
architecture. Figure 1-1 and Figure 1-2 show device
block diagrams for dsPIC30F3014 and dsPIC30F4013
respectively.
1.0
DEVICE OVERVIEW
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
FIGURE 1-1:
dsPIC30F3014 BLOCK DIAGRAM
Y Data Bus
X Data Bus
16
16 16
16
Data Latch
Data Latch
INT0/RA11
Interrupt
PSV & Table
Controller
X Data
RAM
Y Data
Data Access
8
16
RAM
24
Control Block
(1 Kbyte)
(1 Kbyte)
Address
Latch
Address
Latch
PORTA
24
16
16
16
X RAGU
X WAGU
24
AN0/CN2/RB0
Y AGU
PCH PCL
PCU
AN1/CN3/RB1
Program Counter
AN2/SS1/LVDIN/CN4/RB2
AN3/CN5/RB3
16
Stack
Control
Logic
Loop
Control
Logic
Address Latch
AN4/CN6/RB4
AN5/CN7/RB5
PGC/EMUC/AN6/OCFA/RB6
PGD/EMUD/AN7/RB7
AN8/RB8
Program Memory
(24 Kbytes)
Data EEPROM
(1 Kbyte)
Effective Address
16
Data Latch
AN9/RB9
AN10/RB10
AN11/RB11
ROM Latch
AN12/RB12
16
24
PORTB
IR
16
16
EMUD1/SOSCI/T2CK/U1ATX/
CN1/RC13
16 x 16
W Reg Array
EMUC1/SOSCO/T1CK/U1ARX/
CN0/RC14
Decode
Instruction
Decode and
Control
OSC2/CLKO/RC15
16 16
PORTC
Control Signals
to Various Blocks
DSP
Engine
Divide
Unit
Power-up
Timer
Timing
Generation
Oscillator
OSC1/CLKI
EMUC2/OC1/RD0
EMUD2/OC2/RD1
RD2
Start-up Timer
ALU<16>
POR/BOR
Reset
RD3
IC1/INT1/RD8
IC2/INT2/RD9
16
16
Watchdog
Timer
MCLR
Low Voltage
Detect
VDD, VSS
PORTD
AVDD, AVSS
RF0
Input
Output
2
I C™
RF1
Capture
Module
Compare
Module
12-bit ADC
U1RX/SDI1/SDA/RF2
EMUD3/U1TX/SDO1/SCL/RF3
U2RX/CN17/RF4
U2TX/CN18/RF5
EMUC3/SCK1/RF6
UART1,
UART2
PORTF
Timers
DCI
SPI1
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 9
dsPIC30F3014/4013
FIGURE 1-2:
dsPIC30F4013 BLOCK DIAGRAM
Y Data Bus
X Data Bus
16
16 16
16
Data Latch
Data Latch
Interrupt
INT0/RA11
PSV & Table
Data Access
Control Block
Controller
X Data
RAM
Y Data
RAM
8
16
24
(1 Kbyte)
(1 Kbyte)
Address
Latch
Address
Latch
PORTA
24
16
16
16
X RAGU
X WAGU
24
AN0/CN2/RB0
Y AGU
PCH PCL
PCU
AN1/CN3/RB1
Program Counter
AN2/SS1/LVDIN/CN4/RB2
AN3/CN5/RB3
16
Loop
Control
Logic
Stack
Control
Logic
Address Latch
AN4/IC7/CN6/RB4
AN5/IC8/CN7/RB5
PGC/EMUC/AN6/OCFA/RB6
PGD/EMUD/AN7/RB7
AN8/RB8
Program Memory
(48 Kbytes)
Data EEPROM
(1 Kbyte)
Effective Address
16
Data Latch
AN9/CSCK/RB9
AN10/CSDI/RB10
AN11/CSDO/RB11
AN12/COFS/RB12
ROM Latch
16
24
PORTB
IR
16
16
EMUD1/SOSCI/T2CK/U1ATX/
CN1/RC13
16 x 16
W Reg Array
EMUC1/SOSCO/T1CK/U1ARX/
CN0/RC14
Decode
Instruction
Decode &
Control
OSC2/CLKO/RC15
16 16
PORTC
Control Signals
to Various Blocks
DSP
Divide
Unit
Power-up
Engine
Timer
EMUC2/OC1/RD0
EMUD2/OC2/RD1
OC3/RD2
Timing
Generation
Oscillator
OSC1/CLKI
Start-up Timer
OC4/RD3
ALU<16>
POR/BOR
Reset
IC1/INT1/RD8
IC2/INT2/RD9
16
16
Watchdog
Timer
MCLR
Low Voltage
Detect
PORTD
VDD, VSS
AVDD, AVSS
Input
Output
C1RX/RF0
2
I C™
Capture
Module
Compare
Module
CAN1
12-bit ADC
C1TX/RF1
U1RX/SDI1/SDA/RF2
EMUD3/U1TX/SDO1/SCL/RF3
U2RX/CN17/RF4
U2TX/CN18/RF5
EMUC3/SCK1/RF6
UART1,
UART2
Timers
DCI
SPI1
PORTF
DS70138C-page 10
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
Table 1-1 provides a brief description of device I/O
pinouts and the functions that may be multiplexed to a
port pin. Multiple functions may exist on one port pin.
When multiplexing occurs, the peripheral module’s
functional requirements may force an override of the
data direction of the port pin.
TABLE 1-1:
PINOUT I/O DESCRIPTIONS
Pin
Buffer
Type
Pin Name
Description
Type
AN0-AN12
I
Analog
Analog input channels.
AN6 and AN7 are also used for device programming data and
clock inputs, respectively.
AVDD
AVSS
CLKI
P
P
I
P
P
Positive supply for analog module.
Ground reference for analog module.
ST/CMOS
External clock source input. Always associated with OSC1 pin
function.
CLKO
O
—
Oscillator crystal output. Connects to crystal or resonator in
Crystal Oscillator mode. Optionally functions as CLKO in RC
and EC modes. Always associated with OSC2 pin function.
CN0-CN7, CN17-CN18
I
ST
Input change notification inputs.
Can be software programmed for internal weak pull-ups on all
inputs.
COFS
CSCK
CSDI
I/O
I/O
I
ST
ST
ST
—
Data Converter Interface Frame Synchronization pin.
Data Converter Interface Serial Clock input/output pin.
Data Converter Interface Serial data input pin.
Data Converter Interface Serial data output pin.
CSDO
O
C1RX
C1TX
I
ST
—
CAN1 Bus Receive pin.
CAN1 Bus Transmit pin.
O
EMUD
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
ST
ST
ST
ST
ST
ST
ST
ST
ICD Primary Communication Channel data input/output pin.
ICD Primary Communication Channel clock input/output pin.
ICD Secondary Communication Channel data input/output pin.
ICD Secondary Communication Channel clock input/output pin.
ICD Tertiary Communication Channel data input/output pin.
ICD Tertiary Communication Channel clock input/output pin.
ICD Quaternary Communication Channel data input/output pin.
ICD Quaternary Communication Channel clock input/output pin.
EMUC
EMUD1
EMUC1
EMUD2
EMUC2
EMUD3
EMUC3
IC1, IC2, IC7, IC8
I
ST
Capture inputs 1,2, 7 and 8.
INT0
INT1
INT2
I
I
I
ST
ST
ST
External interrupt 0.
External interrupt 1.
External interrupt 2.
LVDIN
MCLR
I
Analog
ST
Low Voltage Detect Reference Voltage input pin.
I/P
Master Clear (Reset) input or programming voltage input. This
pin is an active low Reset to the device.
OCFA
I
ST
—
Compare Fault A input (for Compare channels 1, 2, 3 and 4).
Compare outputs 1 through 4.
OC1-OC4
O
OSC1
OSC2
I
ST/CMOS
Oscillator crystal input. ST buffer when configured in RC mode;
CMOS otherwise.
I/O
—
Oscillator crystal output. Connects to crystal or resonator in
Crystal Oscillator mode. Optionally functions as CLKO in RC
and EC modes.
PGD
PGC
I/O
I
ST
ST
In-Circuit Serial Programming data input/output pin.
In-Circuit Serial Programming clock input pin.
Legend: CMOS = CMOS compatible input or output
ST = Schmitt Trigger input with CMOS levels
= Input
Analog = Analog input
O
P
= Output
= Power
I
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dsPIC30F3014/4013
TABLE 1-1:
PINOUT I/O DESCRIPTIONS (CONTINUED)
Pin
Buffer
Type
Pin Name
Description
PORTA is a bidirectional I/O port.
Type
RA11
I/O
I/O
I/O
I/O
I/O
ST
ST
ST
ST
ST
RB0-RB12
RC13-RC15
RD0-RD3, RD8, RD9
RF0-RF5
PORTB is a bidirectional I/O port.
PORTC is a bidirectional I/O port.
PORTD is a bidirectional I/O port.
PORTF is a bidirectional I/O port.
SCK1
SDI1
SDO1
SS1
I/O
ST
ST
—
Synchronous serial clock input/output for SPI1.
SPI1 Data In.
I
O
I
SPI1 Data Out.
ST
SPI1 Slave Synchronization.
2
Synchronous serial clock input/output for I C.
SCL
SDA
I/O
I/O
ST
ST
2
Synchronous serial data input/output for I C.
SOSCO
SOSCI
O
I
—
32 kHz low power oscillator crystal output.
ST/CMOS
32 kHz low power oscillator crystal input. ST buffer when
configured in RC mode; CMOS otherwise.
T1CK
T2CK
I
I
ST
ST
Timer1 external clock input.
Timer2 external clock input.
U1RX
U1TX
I
ST
—
UART1 Receive.
O
I
UART1 Transmit.
U1ARX
U1ATX
ST
—
UART1 Alternate Receive.
UART1 Alternate Transmit.
O
VDD
P
P
I
—
Positive supply for logic and I/O pins.
Ground reference for logic and I/O pins.
Analog Voltage Reference (High) input.
Analog Voltage Reference (Low) input.
Analog = Analog input
VSS
—
VREF+
VREF-
Analog
Analog
I
Legend: CMOS = CMOS compatible input or output
ST
I
= Schmitt Trigger input with CMOS levels
= Input
O
= Output
= Power
P
DS70138C-page 12
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dsPIC30F3014/4013
There are two methods of accessing data stored in
program memory:
2.0
CPU ARCHITECTURE
OVERVIEW
• The upper 32 Kbytes of data space memory can
be mapped into the lower half (user space) of pro-
gram space at any 16K program word boundary,
defined by the 8-bit Program Space Visibility Page
(PSVPAG) register. This lets any instruction
access program space as if it were data space,
with a limitation that the access requires an addi-
tional cycle. Moreover, only the lower 16 bits of
each instruction word can be accessed using this
method.
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
2.1
Core Overview
• Linear indirect access of 32K word pages within
program space is also possible using any working
register, via table read and write instructions.
Table read and write instructions can be used to
access all 24 bits of an instruction word.
This section contains a brief overview of the CPU
architecture of the dsPIC30F.
The core has a 24-bit instruction word. The Program
Counter (PC) is 23-bits wide with the Least Significant
(LS) bit always clear (refer to Section 3.1), and the
Most Significant (MS) bit is ignored during normal pro-
gram execution, except for certain specialized instruc-
tions. Thus, the PC can address up to 4M instruction
words of user program space. An instruction pre-fetch
mechanism is used to help maintain throughput. Pro-
gram loop constructs, free from loop count manage-
ment overhead, are supported using the DO and
REPEATinstructions, both of which are interruptible at
any point.
Overhead-free circular buffers (modulo addressing) are
supported in both X and Y address spaces. This is
primarily intended to remove the loop overhead for
DSP algorithms.
The X AGU also supports bit-reversed addressing on
destination effective addresses to greatly simplify input
or output data reordering for radix-2 FFT algorithms.
Refer to Section 4.0 for details on modulo and
bit-reversed addressing.
The working register array consists of 16 x 16-bit regis-
ters, each of which can act as data, address or offset
registers. One working register (W15) operates as a
software stack pointer for interrupts and calls.
The core supports Inherent (no operand), Relative,
Literal, Memory Direct, Register Direct, Register
Indirect, Register Offset and Literal Offset Addressing
modes. Instructions are associated with predefined
Addressing modes, depending upon their functional
requirements.
The data space is 64 Kbytes (32K words) and is split
into two blocks, referred to as X and Y data memory.
Each block has its own independent Address Genera-
tion Unit (AGU). Most instructions operate solely
through the X memory, AGU, which provides the
appearance of a single unified data space. The
Multiply-Accumulate (MAC) class of dual source DSP
instructions operate through both the X and Y AGUs,
splitting the data address space into two parts (see
Section 3.2). The X and Y data space boundary is
device specific and cannot be altered by the user. Each
data word consists of 2 bytes, and most instructions
can address data either as words or bytes.
For most instructions, the core is capable of executing
a data (or program data) memory read, a working reg-
ister (data) read, a data memory write and a program
(instruction) memory read per instruction cycle. As a
result, 3-operand instructions are supported, allowing
C = A+B operations to be executed in a single cycle.
A DSP engine has been included to significantly
enhance the core arithmetic capability and throughput.
It features a high speed 17-bit by 17-bit multiplier, a
40-bit ALU, two 40-bit saturating accumulators and a
40-bit bidirectional barrel shifter. Data in the accumula-
tor or any working register can be shifted up to 15 bits
right, or 16 bits left in a single cycle. The DSP instruc-
tions operate seamlessly with all other instructions and
have been designed for optimal real-time performance.
The MAC class of instructions can concurrently fetch
two data operands from memory while multiplying two
W registers. To enable this concurrent fetching of data
operands, the data space has been split for these
instructions and linear for all others. This has been
achieved in a transparent and flexible manner, by
dedicating certain working registers to each address
space for the MACclass of instructions.
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dsPIC30F3014/4013
The core does not support a multi-stage instruction
pipeline. However, a single stage instruction pre-fetch
mechanism is used, which accesses and partially
decodes instructions a cycle ahead of execution, in
order to maximize available execution time. Most
instructions execute in a single cycle with certain
exceptions.
2.2.1
SOFTWARE STACK POINTER/
FRAME POINTER
®
The dsPIC devices contain a software stack. W15 is
the dedicated software Stack Pointer (SP), and will be
automatically modified by exception processing and
subroutine calls and returns. However, W15 can be ref-
erenced by any instruction in the same manner as all
other W registers. This simplifies the reading, writing
and manipulation of the stack pointer (e.g., creating
stack frames).
The core features a vectored exception processing
structure for traps and interrupts, with 62 independent
vectors. The exceptions consist of up to 8 traps (of
which 4 are reserved) and 54 interrupts. Each interrupt
is prioritized based on a user assigned priority between
1 and 7 (1 being the lowest priority and 7 being the
highest), in conjunction with a predetermined ‘natural
order’. Traps have fixed priorities ranging from 8 to 15.
Note:
In order to protect against misaligned
stack accesses, W15<0> is always clear.
W15 is initialized to 0x0800 during a Reset. The user
may reprogram the SP during initialization to any
location within data space.
2.2
Programmer’s Model
W14 has been dedicated as a stack frame pointer as
defined by the LNK and ULNK instructions. However,
W14 can be referenced by any instruction in the same
manner as all other W registers.
The programmer’s model is shown in Figure 2-1 and
consists of 16 x 16-bit working registers (W0 through
W15), 2 x 40-bit accumulators (AccA and AccB),
STATUS register (SR), Data Table Page register
(TBLPAG), Program Space Visibility Page register
(PSVPAG), DO and REPEAT registers (DOSTART,
DOEND, DCOUNT and RCOUNT) and Program
Counter (PC). The working registers can act as data,
address or offset registers. All registers are memory
mapped. W0 acts as the W register for file register
addressing.
2.2.2
STATUS REGISTER
The dsPIC core has a 16-bit STATUS register (SR), the
LS Byte of which is referred to as the SR Low byte
(SRL) and the MS Byte as the SR High byte (SRH).
See Figure 2-1 for SR layout.
SRL contains all the MCU ALU operation status flags
(including the Z bit), as well as the CPU Interrupt Prior-
ity Level status bits, IPL<2:0> and the Repeat Active
status bit, RA. During exception processing, SRL is
concatenated with the MS Byte of the PC to form a
complete word value which is then stacked.
Some of these registers have a shadow register asso-
ciated with each of them, as shown in Figure 2-1. The
shadow register is used as a temporary holding register
and can transfer its contents to or from its host register
upon the occurrence of an event. None of the shadow
registers are accessible directly. The following rules
apply for transfer of registers into and out of shadows.
The upper byte of the STATUS register contains the
DSP Adder/Subtracter status bits, the DO Loop Active
bit (DA) and the Digit Carry (DC) status bit.
• PUSH.Sand POP.S
W0, W1, W2, W3, SR (DC, N, OV, Z and C bits
2.2.3
PROGRAM COUNTER
only) are transferred.
The program counter is 23-bits wide; bit 0 is always
clear. Therefore, the PC can address up to 4M
instruction words.
• DOinstruction
DOSTART, DOEND, DCOUNT shadows are
pushed on loop start, and popped on loop end.
When a byte operation is performed on a working
register, only the Least Significant Byte of the target
register is affected. However, a benefit of memory
mapped working registers is that both the Least and
Most Significant Bytes can be manipulated through
byte wide data memory space accesses.
DS70138C-page 14
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dsPIC30F3014/4013
FIGURE 2-1:
PROGRAMMER’S MODEL
D15
D0
W0/WREG
W1
PUSH.S Shadow
DO Shadow
W2
W3
Legend
W4
DSP Operand
Registers
W5
W6
W7
Working Registers
W8
W9
DSP Address
Registers
W10
W11
W12/DSP Offset
W13/DSP Write Back
W14/Frame Pointer
W15/Stack Pointer
SPLIM
Stack Pointer Limit Register
AD15
AD39
AD31
AD0
DSP
AccA
AccB
Accumulators
PC22
PC0
Program Counter
0
0
7
TBLPAG
Data Table Page Address
7
0
PSVPAG
Program Space Visibility Page Address
15
0
0
RCOUNT
REPEAT Loop Counter
15
DCOUNT
DO Loop Counter
22
0
DOSTART
DO Loop Start Address
22
DO Loop End Address
DOEND
15
0
Core Configuration Register
CORCON
OA OB
SA SB OAB SAB DA DC
RA
N
Z
C
IPL2 IPL1 IPL0
OV
Status Register
SRH
SRL
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dsPIC30F3014/4013
The divide instructions must be executed within a
REPEAT loop. Any other form of execution (e.g., a
series of discrete divide instructions) will not function
correctly because the instruction flow depends on
RCOUNT. The divide instruction does not automatically
set up the RCOUNT value and it must, therefore, be
explicitly and correctly specified in the REPEATinstruc-
tion as shown in Table 2-1 (REPEATwill execute the tar-
get instruction {operand value+1} times). The REPEAT
loop count must be setup for 18 iterations of the DIV/
DIVF instruction. Thus, a complete divide operation
requires 19 cycles.
2.3
Divide Support
The dsPIC devices feature a 16/16-bit signed fractional
divide operation, as well as 32/16-bit and 16/16-bit
signed and unsigned integer divide operations, in the
form of single instruction iterative divides. The following
instructions and data sizes are supported:
1. DIVF- 16/16 signed fractional divide
2. DIV.sd- 32/16 signed divide
3. DIV.ud- 32/16 unsigned divide
4. DIV.sw- 16/16 signed divide
5. DIV.uw- 16/16 unsigned divide
Note:
The divide flow is interruptible. However,
the user needs to save the context as
appropriate.
The 16/16 divides are similar to the 32/16 (same number
of iterations), but the dividend is either zero-extended or
sign-extended during the first iteration.
TABLE 2-1:
Instruction
DIVIDE INSTRUCTIONS
Function
DIVF
Signed fractional divide: Wm/Wn → W0; Rem → W1
Signed divide: (Wm+1:Wm)/Wn → W0; Rem → W1
Signed divide: Wm/Wn → W0; Rem → W1
DIV.sd
DIV.sw or
DIV.s
DIV.ud
Unsigned divide: (Wm+1:Wm)/Wn → W0; Rem → W1
Unsigned divide: Wm/Wn → W0; Rem → W1
DIV.uw or
DIV.u
DS70138C-page 16
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The DSP engine has various options selected through
various bits in the CPU Core Configuration register
(CORCON), as listed below:
2.4
DSP Engine
The DSP engine consists of a high speed 17-bit x
17-bit multiplier, a barrel shifter and a 40-bit adder/
subtracter (with two target accumulators, round and
saturation logic).
1. Fractional or integer DSP multiply (IF).
2. Signed or unsigned DSP multiply (US).
3. Conventional or convergent rounding (RND).
4. Automatic saturation on/off for AccA (SATA).
5. Automatic saturation on/off for AccB (SATB).
The DSP engine also has the capability to perform
inherent
accumulator-to-accumulator
operations,
which require no additional data. These instructions are
ADD, SUBand NEG.
6. Automatic saturation on/off for writes to data
memory (SATDW).
The dsPIC30F is a single-cycle instruction flow archi-
tecture, threfore, concurrent operation of the DSP
engine with MCU instruction flow is not possible.
However, some MCU ALU and DSP engine resources
may be used concurrently by the same instruction (e.g.,
ED, EDAC).
7. Accumulator Saturation mode selection
(ACCSAT).
Note:
For CORCON layout, see Table 4-2.
A block diagram of the DSP engine is shown in
Figure 2-2.
TABLE 2-2:
DSP INSTRUCTION SUMMARY
Algebraic Operation
Instruction
ACC WB?
CLR
ED
A = 0
Yes
No
2
A = (x – y)
2
EDAC
MAC
A = A + (x – y)
No
A = A + (x * y)
Yes
No
2
MAC
A = A + x
MOVSAC
MPY
No change in A
A = x * y
Yes
No
MPY.N
MSC
A = – x * y
No
A = A – x * y
Yes
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dsPIC30F3014/4013
FIGURE 2-2:
DSP ENGINE BLOCK DIAGRAM
S
a
40
16
40-bit Accumulator A
40-bit Accumulator B
40
Round
t
u
r
Logic
a
t
Carry/Borrow Out
Saturate
e
Adder
Carry/Borrow In
Negate
40
40
40
Barrel
Shifter
16
40
Sign-Extend
32
16
Zero Backfill
32
33
17-bit
Multiplier/Scaler
16
16
To/From W Array
DS70138C-page 18
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dsPIC30F3014/4013
2.4.1
MULTIPLIER
2.4.2.1
Adder/Subtracter, Overflow and
Saturation
The 17 x 17-bit multiplier is capable of signed or
unsigned operation and can multiplex its output using a
scaler to support either 1.31 fractional (Q31) or 32-bit
integer results. Unsigned operands are zero-extended
into the 17th bit of the multiplier input value. Signed
operands are sign-extended into the 17th bit of the mul-
tiplier input value. The output of the 17 x 17-bit multi-
plier/scaler is a 33-bit value which is sign-extended to
40 bits. Integer data is inherently represented as a
signed two’s complement value, where the MSB is
defined as a sign bit. Generally speaking, the range of
The adder/subtracter is a 40-bit adder with an optional
zero input into one side and either true, or complement
data into the other input. In the case of addition, the
carry/borrow input is active high and the other input is
true data (not complemented), whereas in the case of
subtraction, the carry/borrow input is active low and the
other input is complemented. The adder/subtracter
generates overflow status bits SA/SB and OA/OB,
which are latched and reflected in the STATUS register:
• Overflow from bit 39: this is a catastrophic
overflow in which the sign of the accumulator is
destroyed.
N-1
N-1
to 2
an N-bit two’s complement integer is -2
– 1.
For a 16-bit integer, the data range is -32768 (0x8000)
to 32767 (0x7FFF) including ‘0’. For a 32-bit integer,
the data range is -2,147,483,648 (0x8000 0000) to
2,147,483,645 (0x7FFF FFFF).
• Overflow into guard bits 32 through 39: this is a
recoverable overflow. This bit is set whenever all
the guard bits bits are not identical to each other.
When the multiplier is configured for fractional multipli-
cation, the data is represented as a two’s complement
fraction, where the MSB is defined as a sign bit and the
radix point is implied to lie just after the sign bit (QX for-
mat). The range of an N-bit two’s complement fraction
The adder has an additional saturation block which
controls accumulator data saturation, if selected. It
uses the result of the adder, the overflow status bits
described above, and the SATA/B (CORCON<7:6>)
and ACCSAT (CORCON<4>) mode control bits to
determine when and to what value to saturate.
1-N
with this implied radix point is -1.0 to (1 – 2 ). For a
16-bit fraction, the Q15 data range is -1.0 (0x8000) to
0.999969482 (0x7FFF) including ‘0’ and has a preci-
-5
sion of 3.01518x10 . In Fractional mode, the 16x16
Six Status register bits have been provided to support
saturation and overflow; they are:
multiply operation generates a 1.31 product which has
1. OA:
-10
a precision of 4.65661 x 10
.
AccA overflowed into guard bits
The same multiplier is used to support the MCU multi-
ply instructions which include integer 16-bit signed,
unsigned and mixed sign multiplies.
2. OB:
AccB overflowed into guard bits
3. SA:
The MUL instruction may be directed to use byte or
word sized operands. Byte operands will direct a 16-bit
result, and word operands will direct a 32-bit result to
the specified register(s) in the W array.
AccA saturated (bit 31 overflow and saturation)
or
AccA overflowed into guard bits and saturated
(bit 39 overflow and saturation)
4. SB:
2.4.2
DATA ACCUMULATORS AND
ADDER/SUBTRACTER
AccB saturated (bit 31 overflow and saturation)
or
AccB overflowed into guard bits and saturated
(bit 39 overflow and saturation)
The data accumulator consists of a 40-bit adder/
subtracter with automatic sign extension logic. It can
select one of two accumulators (A or B) as its pre-
accumulation source and post-accumulation destina-
tion. For the ADDand LACinstructions, the data to be
accumulated or loaded can be optionally scaled via the
barrel shifter, prior to accumulation.
5. OAB:
Logical OR of OA and OB
6. SAB:
Logical OR of SA and SB
The OA and OB bits are modified each time data
passes through the adder/subtracter. When set, they
indicate that the most recent operation has overflowed
into the accumulator guard bits (bits 32 through 39).
The OA and OB bits can also optionally generate an
arithmetic warning trap when set and the correspond-
ing overflow trap flag enable bit (OVATEN, OVBTEN) in
the INTCON1 register (refer to Section 8.0) is set. This
allows the user to take immediate action, for example,
to correct system gain.
2004 Microchip Technology Inc.
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dsPIC30F3014/4013
The SA and SB bits are modified each time data
passes through the adder/subtracter but can only be
cleared by the user. When set, they indicate that the
accumulator has overflowed its maximum range (bit 31
for 32-bit saturation, or bit 39 for 40-bit saturation) and
will be saturated (if saturation is enabled). When satu-
ration is not enabled, SA and SB default to bit 39 over-
flow and thus indicate that a catastrophic overflow has
occurred. If the COVTE bit in the INTCON1 register is
set, SA and SB bits will generate an arithmetic warning
trap when saturation is disabled.
2.4.2.2
Accumulator ‘Write Back’
The MAC class of instructions (with the exception of
MPY, MPY.N, ED and EDAC) can optionally write a
rounded version of the high word (bits 31 through 16)
of the accumulator that is not targeted by the instruction
into data space memory. The write is performed across
the X bus into combined X and Y address space. The
following Addressing modes are supported:
1. W13, Register Direct:
The rounded contents of the non-target
accumulator are written into W13 as a 1.15
fraction.
The overflow and saturation status bits can optionally
be viewed in the STATUS register (SR) as the logical
OR of OA and OB (in bit OAB) and the logical OR of SA
and SB (in bit SAB). This allows programmers to check
one bit in the STATUS register to determine if either
accumulator has overflowed, or one bit to determine if
either accumulator has saturated. This would be useful
for complex number arithmetic which typically uses
both the accumulators.
2. [W13]+=2, Register Indirect with Post-Increment:
The rounded contents of the non-target accumu-
lator are written into the address pointed to by
W13 as
a
1.15 fraction. W13 is then
incremented by 2 (for a word write).
2.4.2.3
Round Logic
The round logic is a combinational block which per-
forms a conventional (biased) or convergent (unbi-
ased) round function during an accumulator write
(store). The Round mode is determined by the state of
the RND bit in the CORCON register. It generates a 16-
bit, 1.15 data value which is passed to the data space
write saturation logic. If rounding is not indicated by the
instruction, a truncated 1.15 data value is stored and
the LS Word is simply discarded.
The device supports three saturation and overflow
modes:
1. Bit 39 Overflow and Saturation:
When bit 39 overflow and saturation occurs, the
saturation logic loads the maximally positive 9.31
(0x7FFFFFFFFF), or maximally negative 9.31
value (0x8000000000) into the target accumula-
tor. The SA or SB bit is set and remains set until
cleared by the user. This is referred to as ‘super
saturation’ and provides protection against erro-
neous data, or unexpected algorithm problems
(e.g., gain calculations).
Conventional rounding takes bit 15 of the accumulator,
zero-extends it and adds it to the ACCxH word (bits 16
through 31 of the accumulator). If the ACCxL word
(bits 0 through 15 of the accumulator) is between
0x8000 and 0xFFFF (0x8000 included), ACCxH is
incremented. If ACCxL is between 0x0000 and 0x7FFF,
ACCxH is left unchanged. A consequence of this algo-
rithm is that over a succession of random rounding
operations, the value will tend to be biased slightly
positive.
2. Bit 31 Overflow and Saturation:
When bit 31 overflow and saturation occurs, the
saturation logic then loads the maximally posi-
tive 1.31 value (0x007FFFFFFF), or maximally
negative 1.31 value (0x0080000000) into the
target accumulator. The SA or SB bit is set and
remains set until cleared by the user. When this
Saturation mode is in effect, the guard bits are
not used (so the OA, OB or OAB bits are never
set).
Convergent (or unbiased) rounding operates in the
same manner as conventional rounding, except when
ACCxL equals 0x8000. If this is the case, the LS bit
(bit 16 of the accumulator) of ACCxH is examined. If it
is ‘1’, ACCxH is incremented. If it is ‘0’, ACCxH is not
modified. Assuming that bit 16 is effectively random in
nature, this scheme will remove any rounding bias that
may accumulate.
3. Bit 39 Catastrophic Overflow:
The bit 39 overflow status bit from the adder is
used to set the SA or SB bit which remain set
until cleared by the user. No saturation operation
is performed and the accumulator is allowed to
overflow (destroying its sign). If the COVTE bit in
the INTCON1 register is set, a catastrophic
overflow can initiate a trap exception.
The SAC and SAC.R instructions store either a trun-
cated (SAC) or rounded (SAC.R) version of the contents
of the target accumulator to data memory via the X bus
(subject to data saturation, see Section 2.4.2.4). Note
that for the MACclass of instructions, the accumulator
write back operation will function in the same manner,
addressing combined MCU (X and Y) data space
though the X bus. For this class of instructions, the data
is always subject to rounding.
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2.4.2.4
Data Space Write Saturation
2.4.3
BARREL SHIFTER
In addition to adder/subtracter saturation, writes to data
space may also be saturated but without affecting the
contents of the source accumulator. The data space
write saturation logic block accepts a 16-bit, 1.15 frac-
tional value from the round logic block as its input,
together with overflow status from the original source
(accumulator) and the 16-bit round adder. These are
combined and used to select the appropriate 1.15
fractional value as output to write to data space
memory.
The barrel shifter is capable of performing up to 16-bit
arithmetic or logic right shifts, or up to 16-bit left shifts
in a single cycle. The source can be either of the two
DSP accumulators, or the X bus (to support multi-bit
shifts of register or memory data).
The shifter requires a signed binary value to determine
both the magnitude (number of bits) and direction of the
shift operation. A positive value will shift the operand
right. A negative value will shift the operand left. A
value of ‘0’ will not modify the operand.
If the SATDW bit in the CORCON register is set, data
(after rounding or truncation) is tested for overflow and
adjusted accordingly, For input data greater than
0x007FFF, data written to memory is forced to the max-
imum positive 1.15 value, 0x7FFF. For input data less
than 0xFF8000, data written to memory is forced to the
maximum negative 1.15 value, 0x8000. The MS bit of
the source (bit 39) is used to determine the sign of the
operand being tested.
The barrel shifter is 40-bits wide, thereby obtaining a
40-bit result for DSP shift operations and a 16-bit result
for MCU shift operations. Data from the X bus is pre-
sented to the barrel shifter between bit positions 16 to
31 for right shifts, and bit positions 0 to 16 for left shifts.
If the SATDW bit in the CORCON register is not set, the
input data is always passed through unmodified under
all conditions.
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NOTES:
DS70138C-page 22
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User program space access is restricted to the lower
4M instruction word address range (0x000000 to
0x7FFFFE) for all accesses other than TBLRD/TBLWT,
which use TBLPAG<7> to determine user or configura-
tion space access. In Table 3-1, Program Space
Address Construction, bit 23 allows access to the
Device ID, the User ID and the configuration bits.
Otherwise, bit 23 is always clear.
3.0
MEMORY ORGANIZATION
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
FIGURE 3-2:
dsPIC30F4013 PROGRAM
SPACE MEMORY MAP
3.1
Program Address Space
The program address space is 4M instruction words. It
is addressable by a 24-bit value from either the 23-bit
PC, table instruction Effective Address (EA), or data
space EA, when program space is mapped into data
space as defined by Table 3-1. Note that the program
space address is incremented by two between succes-
sive program words in order to provide compatibility
with data space addressing.
Reset - GOTOInstruction
Reset - Target Address
000000
000002
000004
Interrupt Vector Table
00007E
000080
Reserved
000084
Alternate Vector Table
0000FE
000100
FIGURE 3-1:
dsPIC30F3014 PROGRAM
SPACE MEMORY MAP
Reset - GOTOInstruction
Reset - Target Address
000000
000002
000004
User Flash
Program Memory
(16K instructions)
Interrupt Vector Table
00007E
000080
Reserved
007FFE
004000
000084
Reserved
Alternate Vector Table
(Read ‘0’s)
0000FE
000100
7FFBFE
7FFC00
Data EEPROM
(1 Kbyte)
User Flash
Program Memory
(8K instructions)
7FFFFE
800000
003FFE
004000
Reserved
UNITID (32 instr.)
Reserved
Reserved
8005BE
8005C0
(Read ‘0’s)
7FFBFE
7FFC00
Data EEPROM
(1 Kbyte)
8005FE
800600
7FFFFE
800000
Reserved
UNITID (32 instr.)
Reserved
8005BE
8005C0
F7FFFE
Device Configuration
Registers
F80000
F8000E
F80010
8005FE
800600
Reserved
FEFFFE
FF0000
FF0002
DEVID (2)
F7FFFE
Device Configuration
Registers
F80000
F8000E
F80010
Reserved
FEFFFE
FF0000
FF0002
DEVID (2)
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TABLE 3-1:
PROGRAM SPACE ADDRESS CONSTRUCTION
Program Space Address
Access
Space
Access Type
<23>
<22:16>
<15>
<14:1>
<0>
Instruction Access
User
User
0
PC<22:1>
0
TBLRD/TBLWT
TBLPAG<7:0>
Data EA<15:0>
Data EA<15:0>
(TBLPAG<7> = 0)
TBLRD/TBLWT
Configuration
TBLPAG<7:0>
(TBLPAG<7> = 1)
Program Space Visibility User
0
PSVPAG<7:0>
Data EA<14:0>
FIGURE 3-3:
DATA ACCESS FROM PROGRAM SPACE ADDRESS GENERATION
23 bits
Using
Program
Counter
Program Counter
0
0
Select
1
EA
Using
Program
Space
0
PSVPAG Reg
8 bits
Visibility
15 bits
EA
Using
1/0
TBLPAG Reg
8 bits
Table
Instruction
16 bits
User/
Configuration
Space
Byte
24-bit EA
Select
Select
Note:
Program space visibility cannot be used to access bits <23:16> of a word in program memory.
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A set of table instructions are provided to move byte or
word sized data to and from program space.
3.1.1
DATA ACCESS FROM PROGRAM
MEMORY USING TABLE
INSTRUCTIONS
1. TBLRDL:Table Read Low
Word: Read the LS Word of the program address;
P<15:0> maps to D<15:0>.
This architecture fetches 24-bit wide program memory.
Consequently, instructions are always aligned.
However, as the architecture is modified Harvard, data
can also be present in program space.
Byte: Read one of the LS Bytes of the program
address;
P<7:0> maps to the destination byte when byte
select = 0;
P<15:8> maps to the destination byte when byte
There are two methods by which program space can
be accessed: via special table instructions, or through
the remapping of a 16K word program space page into
the upper half of data space (see Section 3.1.2). The
TBLRDLand TBLWTLinstructions offer a direct method
of reading or writing the LS Word of any address within
program space, without going through data space. The
TBLRDHand TBLWTHinstructions are the only method
whereby the upper 8 bits of a program space word can
be accessed as data.
select = 1.
2. TBLWTL:Table Write Low (refer to Section 5.0
for details on Flash Programming)
3. TBLRDH:Table Read High
Word: Read the MS Word of the program address;
P<23:16> maps to D<7:0>; D<15:8> will always
be = 0.
Byte: Read one of the MS Bytes of the program
The PC is incremented by two for each successive
24-bit program word. This allows program memory
addresses to directly map to data space addresses.
Program memory can thus be regarded as two 16-bit
word wide address spaces, residing side by side, each
with the same address range. TBLRDL and TBLWTL
access the space which contains the LS Data Word,
and TBLRDH and TBLWTH access the space which
contains the MS Data Byte.
address;
P<23:16> maps to the destination byte when
byte select = 0;
The destination byte will always be = 0 when
byte select = 1.
4. TBLWTH:Table Write High (refer to Section 5.0
for details on Flash Programming)
Figure 3-3 shows how the EA is created for table oper-
ations and data space accesses (PSV = 1). Here,
P<23:0> refers to a program space word, whereas
D<15:0> refers to a data space word.
FIGURE 3-4:
PROGRAM DATA TABLE ACCESS (LS WORD)
PC Address
23
8
0
16
0x000000
0x000002
0x000004
0x000006
00000000
00000000
00000000
00000000
TBLRDL.B (Wn<0> = 0)
TBLRDL.W
Program Memory
‘Phantom’ Byte
(read as ‘0’)
TBLRDL.B (Wn<0> = 1)
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FIGURE 3-5:
PROGRAM DATA TABLE ACCESS (MS BYTE)
TBLRDH.W
PC Address
23
8
0
16
0x000000
0x000002
0x000004
0x000006
00000000
00000000
00000000
00000000
TBLRDH.B (Wn<0> = 0)
Program Memory
‘Phantom’ Byte
(read as ‘0’)
TBLRDH.B (Wn<0> = 1)
Note that by incrementing the PC by 2 for each
program memory word, the LS 15 bits of data space
addresses directly map to the LS 15 bits in the corre-
sponding program space addresses. The remaining
bits are provided by the Program Space Visibility Page
register, PSVPAG<7:0>, as shown in Figure 3-6.
3.1.2
DATA ACCESS FROM PROGRAM
MEMORY USING PROGRAM SPACE
VISIBILITY
The upper 32 Kbytes of data space may optionally be
mapped into any 16K word program space page. This
provides transparent access of stored constant data
from X data space without the need to use special
instructions (i.e., TBLRDL/H, TBLWTL/Hinstructions).
Note:
PSV access is temporarily disabled during
table reads/writes.
Program space access through the data space occurs
if the MS bit of the data space EA is set and program
space visibility is enabled by setting the PSV bit in the
Core Control register (CORCON). The functions of
CORCON are discussed in Section 2.4, DSP Engine.
For instructions that use PSV which are executed
outside a REPEAT loop:
• The following instructions will require one
instruction cycle in addition to the specified
execution time:
Data accesses to this area add an additional cycle to
the instruction being executed, since two program
memory fetches are required.
- MACclass of instructions with data operand
pre-fetch
- MOVinstructions
Note that the upper half of addressable data space is
always part of the X data space. Therefore, when a
DSP operation uses program space mapping to access
this memory region, Y data space should typically con-
tain state (variable) data for DSP operations, whereas
X data space should typically contain coefficient
(constant) data.
- MOV.Dinstructions
• All other instructions will require two instruction
cycles in addition to the specified execution time
of the instruction.
For instructions that use PSV which are executed
inside a REPEAT loop:
• The following instances will require two instruction
cycles in addition to the specified execution time
of the instruction:
Although each data space address, 0x8000 and higher,
maps directly into a corresponding program memory
address (see Figure 3-6), only the lower 16 bits of the
24-bit program word are used to contain the data. The
upper 8 bits should be programmed to force an illegal
instruction to maintain machine robustness. Refer to
the Programmer’s Reference Manual (DS70030) for
details on instruction encoding.
- Execution in the first iteration
- Execution in the last iteration
- Execution prior to exiting the loop due to an
interrupt
- Execution upon re-entering the loop after an
interrupt is serviced
• Any other iteration of the REPEAT loop will allow
the instruction accessing data, using PSV, to
execute in a single cycle.
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FIGURE 3-6:
DATA SPACE WINDOW INTO PROGRAM SPACE OPERATION
Data Space
Program Space
0x0000
0x000100
(1)
15
PSVPAG
0x00
8
EA<15> =
0
16
Data
Space
EA
0x8000
15
23
15
0
Address
EA<15> = 1
0x000200
Concatenation
15
23
Upper Half of Data
Space is Mapped
into Program Space
0x007FFF
0xFFFF
BSET CORCON,#2
; PSV bit set
MOV
MOV
MOV
#0x00, W0
W0, PSVPAG
0x8200, W0
; Set PSVPAG register
; Access program memory location
; using a data space access
Data Read
Note:
PSVPAG is an 8-bit register, containing bits <22:15> of the program space address (i.e., it defines
the page in program space to which the upper half of data space is being mapped).
The memory map shown here is for a dsPIC30F4013 device.
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When executing any instruction other than one of the
MACclass of instructions, the X block consists of the 64-
Kbyte data address space (including all Y addresses).
When executing one of the MAC class of instructions,
the X block consists of the 64-Kbyte data address
space excluding the Y address block (for data reads
only). In other words, all other instructions regard the
entire data memory as one composite address space.
The MACclass instructions extract the Y address space
from data space and address it using EAs sourced from
W10 and W11. The remaining X data space is
addressed using W8 and W9. Both address spaces are
concurrently accessed only with the MAC class
instructions.
3.2
Data Address Space
The core has two data spaces. The data spaces can be
considered either separate (for some DSP instruc-
tions), or as one unified linear address range (for MCU
instructions). The data spaces are accessed using two
Address Generation Units (AGUs) and separate data
paths.
3.2.1
DATA SPACE MEMORY MAP
The data space memory is split into two blocks, X and
Y data space. A key element of this architecture is that
Y space is a subset of X space, and is fully contained
within X space. In order to provide an apparent linear
addressing space, X and Y spaces have contiguous
addresses.
The data space memory map is shown in Figure 3-7.
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FIGURE 3-7:
dsPIC30F3014/dsPIC30F4013 DATA SPACE MEMORY MAP
LS Byte
Address
MS Byte
Address
16 bits
MSB
LSB
0x0000
0x0001
2 Kbyte
SFR Space
SFR Space
0x07FE
0x0800
0x07FF
0x0801
8 Kbyte
Near
X Data RAM (X)
0x0BFF
0x0C01
0x0BFE
0x0C00
2 Kbyte
Data
Space
SRAM Space
Y Data RAM (Y)
0x0FFF
0x1001
0x0FFE
0x1000
0x1FFF
0x1FFE
0x8001
0x8000
X Data
Optionally
Unimplemented (X)
Mapped
into Program
Memory
0xFFFF
0xFFFE
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FIGURE 3-8:
DATA SPACE FOR MCU AND DSP (MACCLASS) INSTRUCTIONS EXAMPLE
SFR SPACE
SFR SPACE
UNUSED
Y SPACE
UNUSED
(Y SPACE)
UNUSED
Non-MACClass Ops (Read/Write)
MACClass Ops (Write)
MACClass Ops (Read)
Indirect EA using any W
Indirect EA using W8, W9 Indirect EA using W10, W11
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3.2.2
DATA SPACES
3.2.3
DATA SPACE WIDTH
The X data space is used by all instructions and sup-
ports all Addressing modes. There are separate read
and write data buses. The X read data bus is the return
data path for all instructions that view data space as
combined X and Y address space. It is also the X
address space data path for the dual operand read
instructions (MAC class). The X write data bus is the
only write path to data space for all instructions.
The core data width is 16 bits. All internal registers are
organized as 16-bit wide words. Data space memory is
organized in byte addressable, 16-bit wide blocks.
3.2.4
DATA ALIGNMENT
To help maintain backward compatibility with
PICmicro® devices and improve data space memory
usage efficiency, the dsPIC30F instruction set supports
both word and byte operations. Data is aligned in data
memory and registers as words, but all data space EAs
resolve to bytes. Data byte reads will read the complete
word which contains the byte, using the LS bit of any
EA to determine which byte to select. The selected byte
is placed onto the LS Byte of the X data path (no byte
accesses are possible from the Y data path as the MAC
class of instruction can only fetch words). That is, data
memory and registers are organized as two parallel
byte wide entities with shared (word) address decode
but separate write lines. Data byte writes only write to
the corresponding side of the array or register which
matches the byte address.
The X data space also supports modulo addressing for
all instructions, subject to Addressing mode restric-
tions. Bit-reversed addressing is only supported for
writes to X data space.
The Y data space is used in concert with the X data
space by the MAC class of instructions (CLR, ED,
EDAC, MAC, MOVSAC, MPY, MPY.N and MSC) to
provide two concurrent data read paths. No writes
occur across the Y bus. This class of instructions dedi-
cates two W register pointers, W10 and W11, to always
address Y data space, independent of X data space,
whereas W8 and W9 always address X data space.
Note that during accumulator write back, the data
address space is considered a combination of X and Y
data spaces, so the write occurs across the X bus.
Consequently, the write can be to any address in the
entire data space.
As a consequence of this byte accessibility, all effective
address calculations (including those generated by the
DSP operations which are restricted to word sized
data) are internally scaled to step through word aligned
memory. For example, the core would recognize that
Post-Modified Register Indirect Addressing mode
[Ws++] will result in a value of Ws+1 for byte operations
and Ws+2 for word operations.
The Y data space can only be used for the data pre-
fetch operation associated with the MAC class of
instructions. It also supports modulo addressing for
automated circular buffers. Of course, all other instruc-
tions can access the Y data address space through the
X data path as part of the composite linear space.
All word accesses must be aligned to an even address.
Misaligned word data fetches are not supported so
care must be taken when mixing byte and word opera-
tions, or translating from 8-bit MCU code. Should a mis-
aligned read or write be attempted, an address error
trap will be generated. If the error occurred on a read,
the instruction underway is completed, whereas if it
occurred on a write, the instruction will be executed but
the write will not occur. In either case, a trap will then
be executed, allowing the system and/or user to exam-
ine the machine state prior to execution of the address
fault.
The boundary between the X and Y data spaces is
defined as shown in Figure 3-7 and is not user pro-
grammable. Should an EA point to data outside its own
assigned address space, or to a location outside phys-
ical memory, an all zero word/byte will be returned. For
example, although Y address space is visible by all
non-MAC instructions using any Addressing mode, an
attempt by a MAC instruction to fetch data from that
space using W8 or W9 (X space pointers) will return
0x0000.
FIGURE 3-9:
DATA ALIGNMENT
TABLE 3-2:
EFFECT OF INVALID
MEMORY ACCESSES
MS Byte
LS Byte
15
8 7
0
Attempted Operation
Data Returned
0000
0002
0004
0001
Byte1
Byte3
Byte5
Byte 0
Byte 2
Byte 4
EA = an unimplemented address
0x0000
0x0000
0003
0005
W8 or W9 used to access Y data
space in a MACinstruction
W10 or W11 used to access X
0x0000
data space in a MACinstruction
All effective addresses are 16 bits wide and point to
bytes within the data space. Therefore, the data space
address range is 64 Kbytes or 32K words.
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dsPIC30F3014/4013
All byte loads into any W register are loaded into the
LS Byte. The MSB is not modified.
There is a Stack Pointer Limit register (SPLIM) associ-
ated with the stack pointer. SPLIM is uninitialized at
Reset. As is the case for the stack pointer, SPLIM<0>
is forced to ‘0’ because all stack operations must be
word aligned. Whenever an effective address (EA) is
generated using W15 as a source or destination
pointer, the address thus generated is compared with
the value in SPLIM. If the contents of the Stack Pointer
(W15) and the SPLIM register are equal and a push
operation is performed, a Stack Error Trap will not
occur. The Stack Error Trap will occur on a subsequent
push operation. Thus, for example, if it is desirable to
cause a Stack Error Trap when the stack grows beyond
address 0x2000 in RAM, initialize the SPLIM with the
value, 0x1FFE.
A sign-extend (SE) instruction is provided to allow
users to translate 8-bit signed data to 16-bit signed
values. Alternatively, for 16-bit unsigned data, users
can clear the MSB of any W register by executing a
zero-extend (ZE) instruction on the appropriate
address.
Although most instructions are capable of operating on
word or byte data sizes, it should be noted that some
instructions, including the DSP instructions, operate
only on words.
3.2.5
NEAR DATA SPACE
An 8-Kbyte ‘near’ data space is reserved in X address
memory space between 0x0000 and 0x1FFF, which is
directly addressable via a 13-bit absolute address field
within all memory direct instructions. The remaining X
address space and all of the Y address space is
addressable indirectly. Additionally, the whole of X data
space is addressable using MOV instructions, which
support memory direct addressing with a 16-bit
address field.
Similarly, a stack pointer underflow (stack error) trap is
generated when the stack pointer address is found to
be less than 0x0800, thus preventing the stack from
interfering with the Special Function Register (SFR)
space.
A write to the SPLIM register should not be immediately
followed by an indirect read operation using W15.
FIGURE 3-10:
CALLSTACK FRAME
3.2.6
SOFTWARE STACK
0x0000
15
0
The dsPIC devices contain a software stack. W15 is
used as the stack pointer.
The stack pointer always points to the first available
free word and grows from lower addresses towards
higher addresses. It pre-decrements for stack pops
and post-increments for stack pushes as shown in
Figure 3-10. Note that for a PC push during any CALL
instruction, the MSB of the PC is zero-extended before
the push, ensuring that the MSB is always clear.
PC<15:0>
000000000
W15 (before CALL)
PC<22:16>
<Free Word>
W15 (after CALL)
POP : [--W15]
PUSH: [W15++]
Note:
A PC push during exception processing
will concatenate the SRL register to the
MSB of the PC prior to the push.
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4.1.1
FILE REGISTER INSTRUCTIONS
4.0
ADDRESS GENERATOR UNITS
Most file register instructions use a 13-bit address field
(f) to directly address data present in the first 8192
bytes of data memory (near data space). Most file
register instructions employ a working register W0,
which is denoted as WREG in these instructions. The
destination is typically either the same file register, or
WREG (with the exception of the MUL instruction),
which writes the result to a register or register pair. The
MOV instruction allows additional flexibility and can
access the entire data space during file register
operation.
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
The dsPIC core contains two independent address
generator units: the X AGU and Y AGU. The Y AGU
supports word sized data reads for the DSP MACclass
of instructions only. The dsPIC AGUs support three
types of data addressing:
4.1.2
MCU INSTRUCTIONS
• Linear Addressing
The three-operand MCU instructions are of the form:
Operand 3 = Operand 1 <function> Operand 2
• Modulo (Circular) Addressing
• Bit-Reversed Addressing
where Operand 1 is always a working register (i.e., the
addressing mode can only be register direct), which is
referred to as Wb. Operand 2 can be a W register,
fetched from data memory, or a 5-bit literal. The result
location can be either a W register or an address
location. The following addressing modes are
supported by MCU instructions:
Linear and Modulo Data Addressing modes can be
applied to data space or program space. Bit-reversed
addressing is only applicable to data space addresses.
4.1
Instruction Addressing Modes
The addressing modes in Table 4-1 form the basis of
the addressing modes optimized to support the specific
features of individual instructions. The addressing
modes provided in the MAC class of instructions are
somewhat different from those in the other instruction
types.
• Register Direct
• Register Indirect
• Register Indirect Post-modified
• Register Indirect Pre-modified
• 5-bit or 10-bit Literal
Note:
Not all instructions support all the address-
ing modes given above. Individual
instructions may support different subsets
of these addressing modes.
TABLE 4-1:
FUNDAMENTAL ADDRESSING MODES SUPPORTED
Description
The address of the File register is specified explicitly.
Addressing Mode
File Register Direct
Register Direct
The contents of a register are accessed directly.
The contents of Wn forms the EA.
Register Indirect
Register Indirect Post-modified
The contents of Wn forms the EA. Wn is post-modified (incremented or
decremented) by a constant value.
Register Indirect Pre-modified
Wn is pre-modified (incremented or decremented) by a signed constant value
to form the EA.
Register Indirect with Register Offset The sum of Wn and Wb forms the EA.
Register Indirect with Literal Offset
The sum of Wn and a literal forms the EA.
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In summary, the following addressing modes are
4.1.3
MOVE AND ACCUMULATOR
INSTRUCTIONS
supported by the MACclass of instructions:
• Register Indirect
Move instructions and the DSP accumulator class of
instructions provide a greater degree of addressing
flexibility than other instructions. In addition to the
addressing modes supported by most MCU instruc-
tions, move and accumulator instructions also support
Register Indirect with Register Offset Addressing
mode, also referred to as Register Indexed mode.
• Register Indirect Post-modified by 2
• Register Indirect Post-modified by 4
• Register Indirect Post-modified by 6
• Register Indirect with Register Offset (Indexed)
4.1.5
OTHER INSTRUCTIONS
Note:
For the MOV instructions, the addressing
mode specified in the instruction can differ
for the source and destination EA.
However, the 4-bit Wb (register offset)
field is shared between both source and
destination (but typically only used by
one).
Besides the various addressing modes outlined above,
some instructions use literal constants of various sizes.
For example, BRA (branch) instructions use 16-bit
signed literals to specify the branch destination directly,
whereas the DISI instruction uses a 14-bit unsigned
literal field. In some instructions, such as ADD Acc, the
source of an operand or result is implied by the opcode
itself. Certain operations, such as NOP, do not have any
operands.
In summary, the following addressing modes are
supported by move and accumulator instructions:
• Register Direct
4.2
Modulo Addressing
• Register Indirect
• Register Indirect Post-modified
• Register Indirect Pre-modified
• Register Indirect with Register Offset (Indexed)
• Register Indirect with Literal Offset
• 8-bit Literal
Modulo addressing is a method of providing an auto-
mated means to support circular data buffers using
hardware. The objective is to remove the need for soft-
ware to perform data address boundary checks when
executing tightly looped code, as is typical in many
DSP algorithms.
• 16-bit Literal
Modulo addressing can operate in either data or pro-
gram space (since the data pointer mechanism is
essentially the same for both). One circular buffer can
be supported in each of the X (which also provides the
pointers into program space) and Y data spaces. Mod-
ulo addressing can operate on any W register pointer.
However, it is not advisable to use W14 or W15 for mod-
ulo addressing since these two registers are used as
the stack frame pointer and stack pointer, respectively.
Note:
Not all instructions support all the address-
ing modes given above. Individual
instructions may support different subsets
of these addressing modes.
4.1.4
MACINSTRUCTIONS
The dual source operand DSP instructions (CLR, ED,
EDAC, MAC, MPY, MPY.N, MOVSACand MSC), also
referred to as MACinstructions, utilize a simplified set of
addressing modes to allow the user to effectively
manipulate the data pointers through register indirect
tables.
In general, any particular circular buffer can only be
configured to operate in one direction, as there are cer-
tain restrictions on the buffer start address (for incre-
menting buffers), or end address (for decrementing
buffers) based upon the direction of the buffer.
The 2 source operand pre-fetch registers must be a
member of the set {W8, W9, W10, W11}. For data
reads, W8 and W9 will always be directed to the X
RAGU and W10 and W11 will always be directed to the
Y AGU. The effective addresses generated (before and
after modification) must, therefore, be valid addresses
within X data space for W8 and W9 and Y data space
for W10 and W11.
The only exception to the usage restrictions is for buff-
ers which have a power-of-2 length. As these buffers
satisfy the start and end address criteria, they may
operate in a Bidirectional mode (i.e., address boundary
checks will be performed on both the lower and upper
address boundaries).
Note:
Register indirect with register offset
addressing is only available for W9 (in X
space) and W11 (in Y space).
DS70138C-page 36
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4.2.1
START AND END ADDRESS
4.2.2
W ADDRESS REGISTER
SELECTION
The modulo addressing scheme requires that a starting
and an ending address be specified and loaded
into the 16-bit Modulo Buffer Address registers:
XMODSRT, XMODEND, YMODSRT and YMODEND
(see Table 3-3).
The Modulo and Bit-Reversed Addressing Control reg-
ister MODCON<15:0> contains enable flags as well as
a W register field to specify the W address registers.
The XWM and YWM fields select which registers will
operate with modulo addressing. If XWM = 15, X
RAGU and X WAGU modulo addressing is disabled.
Similarly, if YWM = 15, Y AGU modulo addressing is
disabled.
Note:
Y space modulo addressing EA calcula-
tions assume word sized data (LS bit of
every EA is always clear).
The length of a circular buffer is not directly specified. It
is determined by the difference between the corre-
sponding start and end addresses. The maximum pos-
sible length of the circular buffer is 32K words
(64 Kbytes).
The X Address Space Pointer W register (XWM), to
which modulo addressing is to be applied, is stored in
MODCON<3:0> (see Table 3-3). Modulo addressing is
enabled for X data space when XWM is set to any value
other than ‘15’ and the XMODEN bit is set at
MODCON<15>.
The Y Address Space Pointer W register (YWM), to
which modulo addressing is to be applied, is stored in
MODCON<7:4>. Modulo addressing is enabled for Y
data space when YWM is set to any value other than
‘15’ and the YMODEN bit is set at MODCON<14>.
FIGURE 4-1:
MODULO ADDRESSING OPERATION EXAMPLE
Byte
MOV
MOV
MOV
MOV
MOV
MOV
#0x800,W0
Address
W0,XMODSRT
#0x863,W0
W0,MODEND
#0x8001,W0
W0,MODCON
;set modulo start address
;set modulo end address
0x0800
;enable W1, X AGU for modulo
MOV
MOV
#0x0000,W0
#0x800,W1
;W0 holds buffer fill value
;point W1 to buffer
DO
AGAIN,#0x31 ;fill the 50 buffer locations
MOV
W0,[W1++]
;fill the next location
;increment the fill value
AGAIN: INC W0,W0
0x0863
Start Addr = 0x0800
End Addr = 0x0863
Length = 0x0032words
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dsPIC30F3014/4013
N
If the length of a bit-reversed buffer is M = 2 bytes,
4.2.3
MODULO ADDRESSING
APPLICABILITY
then the last ‘N’ bits of the data buffer start address
must be zeros.
Modulo addressing can be applied to the effective
address (EA) calculation associated with any W regis-
ter. It is important to realize that the address bound-
aries check for addresses less than, or greater than the
upper (for incrementing buffers), and lower (for decre-
menting buffers) boundary addresses (not just equal
to). Address changes may, therefore, jump beyond
boundaries and still be adjusted correctly.
XB<14:0> is the bit-reversed address modifier or ‘pivot
point’ which is typically a constant. In the case of an
FFT computation, its value is equal to half of the FFT
data buffer size.
Note:
All bit-reversed EA calculations assume
word sized data (LS bit of every EA is
always clear). The XB value is scaled
accordingly to generate compatible (byte)
addresses.
Note:
The modulo corrected effective address is
written back to the register only when Pre-
Modify or Post-Modify Addressing mode is
used to compute the effective address.
When an address offset (e.g., [W7+W2]) is
used, modulo address correction is per-
formed but the contents of the register
remain unchanged.
When enabled, bit-reversed addressing will only be
executed for register indirect with pre-increment or
post-increment addressing and word sized data writes.
It will not function for any other addressing mode or for
byte sized data, and normal addresses will be gener-
ated instead. When bit-reversed addressing is active,
the W address pointer will always be added to the
address modifier (XB) and the offset associated with
the Register Indirect Addressing mode will be ignored.
In addition, as word sized data is a requirement, the LS
bit of the EA is ignored (and always clear).
4.3
Bit-Reversed Addressing
Bit-reversed addressing is intended to simplify data re-
ordering for radix-2 FFT algorithms. It is supported by
the X AGU for data writes only.
Note:
Modulo addressing and bit-reversed
addressing should not be enabled together.
In the event that the user attempts to do
this, bit-reversed addressing will assume
priority when active for the X WAGU, and X
WAGU modulo addressing will be disabled.
However, modulo addressing will continue
to function in the X RAGU.
The modifier, which may be a constant value or register
contents, is regarded as having its bit order reversed. The
address source and destination are kept in normal order.
Thus, the only operand requiring reversal is the modifier.
4.3.1
BIT-REVERSED ADDRESSING
IMPLEMENTATION
Bit-reversed addressing is enabled when:
If bit-reversed addressing has already been enabled by
setting the BREN (XBREV<15>) bit, then a write to the
XBREV register should not be immediately followed by
an indirect read operation using the W register that has
been designated as the bit-reversed pointer.
1. BWM (W register selection) in the MODCON
register is any value other than ‘15’ (the stack
cannot be accessed using bit-reversed
addressing) and
2. the BREN bit is set in the XBREV register and
3. the addressing mode used is Register Indirect
with Pre-Increment or Post-Increment.
FIGURE 4-2:
BIT-REVERSED ADDRESS EXAMPLE
Sequential Address
b15 b14 b13 b12 b11 b10 b9 b8 b7 b6 b5 b4 b3 b2 b1
0
Bit Locations Swapped Left-to-Right
Around Center of Binary Value
b2 b3 b4
0
b15 b14 b13 b12 b11 b10 b9 b8 b7 b6 b5 b1
Bit-Reversed Address
Pivot Point
XB = 0x0008 for a 16-word Bit-Reversed Buffer
DS70138C-page 38
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TABLE 4-2:
BIT-REVERSED ADDRESS SEQUENCE (16-ENTRY)
Normal Address
Bit-Reversed Address
A3
A2
A1
A0
Decimal
A3
A2
A1
A0
Decimal
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
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
0
1
0
1
0
1
0
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
8
2
4
3
12
2
4
5
10
6
6
7
14
1
8
9
9
10
11
12
13
14
15
5
13
3
11
7
15
TABLE 4-3:
BIT-REVERSED ADDRESS MODIFIER VALUES FOR XBREV REGISTER
Buffer Size (Words)
XB<14:0> Bit-Reversed Address Modifier Value
1024
512
256
128
64
0x0200
0x0100
0x0080
0x0040
0x0020
0x0010
0x0008
0x0004
0x0002
0x0001
32
16
8
4
2
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dsPIC30F3014/4013
NOTES:
DS70138C-page 40
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5.2
Run-Time Self-Programming
(RTSP)
5.0
FLASH PROGRAM MEMORY
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
RTSP is accomplished using TBLRD (table read) and
TBLWT(table write) instructions.
With RTSP, the user may erase program memory, 32
instructions (96 bytes) at a time and can write program
memory data, 32 instructions (96 bytes) at a time.
The dsPIC30F family of devices contains internal pro-
gram Flash memory for executing user code. There are
two methods by which the user can program this
memory:
5.3
Table Instruction Operation
Summary
The TBLRDLand the TBLWTLinstructions are used to
read or write to bits<15:0> of program memory.
TBLRDLand TBLWTLcan access program memory in
Word or Byte mode.
1. Run-Time Self-Programming (RTSP)
2. In-Circuit Serial Programming™ (ICSP™)
The TBLRDHand TBLWTHinstructions are used to read
or write to bits<23:16> of program memory. TBLRDH
and TBLWTHcan access program memory in Word or
Byte mode.
5.1
In-Circuit Serial Programming
(ICSP)
dsPIC30F devices can be serially programmed while in
the end application circuit. This is simply done with two
lines for Programming Clock and Programming Data
(which are named PGC and PGD respectively), and
three other lines for Power (VDD), Ground (VSS) and
Master Clear (MCLR). this allows customers to manu-
facture boards with unprogrammed devices, and then
program the microcontroller just before shipping the
product. This also allows the most recent firmware or a
custom firmware to be programmed.
A 24-bit program memory address is formed using
bits<7:0> of the TBLPAG register and the effective
address (EA) from a W register specified in the table
instruction, as shown in Figure 5-1.
FIGURE 5-1:
ADDRESSING FOR TABLE AND NVM REGISTERS
24 bits
Using
Program
Counter
Program Counter
0
0
NVMADR Reg EA
Using
NVMADR
Addressing
1/0 NVMADRU Reg
8 bits
16 bits
Working Reg EA
Using
1/0
TBLPAG Reg
8 bits
Table
Instruction
16 bits
Byte
User/Configuration
Space Select
Select
24-bit EA
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5.4
RTSP Operation
5.5
Control Registers
The dsPIC30F Flash program memory is organized
into rows and panels. Each row consists of 32 instruc-
tions, or 96 bytes. Each panel consists of 128 rows, or
4K x 24 instructions. RTSP allows the user to erase one
row (32 instructions) at a time and to program four
instructions at one time. RTSP may be used to program
multiple program memory panels, but the table pointer
must be changed at each panel boundary.
The four SFRs used to read and write the program
Flash memory are:
• NVMCON
• NVMADR
• NVMADRU
• NVMKEY
5.5.1
NVMCON REGISTER
Each panel of program memory contains write latches
that hold 32 instructions of programming data. Prior to
the actual programming operation, the write data must
be loaded into the panel write latches. The data to be
programmed into the panel is loaded in sequential
order into the write latches; instruction 0, instruction 1,
etc. The instruction words loaded must always be from
a group of 32 boundary.
The NVMCON register controls which blocks are to be
erased, which memory type is to be programmed, and
start of the programming cycle.
5.5.2
NVMADR REGISTER
The NVMADR register is used to hold the lower two
bytes of the effective address. The NVMADR register
captures the EA<15:0> of the last table instruction that
has been executed and selects the row to write.
The basic sequence for RTSP programming is to set up
a table pointer, then do a series of TBLWTinstructions
to load the write latches. Programming is performed by
setting the special bits in the NVMCON register. 32
TBLWTL and four TBLWTH instructions are required to
load the 32 instructions. If multiple panel programming
is required, the table pointer needs to be changed and
the next set of multiple write latches written.
5.5.3
NVMADRU REGISTER
The NVMADRU register is used to hold the upper byte
of the effective address. The NVMADRU register cap-
tures the EA<23:16> of the last table instruction that
has been executed.
All of the table write operations are single word writes
(2 instruction cycles), because only the table latches
are written. A programming cycle is required for
programming each row.
5.5.4
NVMKEY REGISTER
NVMKEY is a write-only register that is used for write
protection. To start a programming or an erase
sequence, the user must consecutively write 0x55 and
0xAA to the NVMKEY register. Refer to Section 5.6 for
further details.
The Flash Program Memory is readable, writable and
erasable during normal operation over the entire VDD
range.
Note:
The user can also directly write to the
NVMADR and NVMADRU registers to
specify a program memory address for
erasing or programming.
DS70138C-page 42
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4. Write 32 instruction words of data from data
RAM “image” into the program Flash write
latches.
5.6
Programming Operations
A complete programming sequence is necessary for
programming or erasing the internal Flash in RTSP
mode. A programming operation is nominally 2 msec in
duration and the processor stalls (waits) until the oper-
ation is finished. Setting the WR bit (NVMCON<15>)
starts the operation, and the WR bit is automatically
cleared when the operation is finished.
5. Program 32 instruction words into program
Flash.
a) Setup NVMCON register for multi-word,
program Flash, program, and set WREN
bit.
b) Write ‘55’ to NVMKEY.
c) Write ‘AA’ to NVMKEY.
5.6.1
PROGRAMMING ALGORITHM FOR
PROGRAM FLASH
d) Set the WR bit. This will begin program
cycle.
The user can erase or program one row of program
Flash memory at a time. The general process is:
e) CPU will stall for duration of the program
cycle.
1. Read one row of program Flash (32 instruction
words) and store into data RAM as a data
“image”.
f) The WR bit is cleared by the hardware
when program cycle ends.
6. Repeat steps 1 through 5 as needed to program
desired amount of program Flash memory.
2. Update the data image with the desired new
data.
3. Erase program Flash row.
5.6.2
ERASING A ROW OF PROGRAM
MEMORY
a) Setup NVMCON register for multi-word,
program Flash, erase, and set WREN bit.
Example 5-1 shows a code sequence that can be used
to erase a row (32 instructions) of program memory.
b) Write address of row to be erased into
NVMADRU/NVMDR.
c) Write ‘55’ to NVMKEY.
d) Write ‘AA’ to NVMKEY.
e) Set the WR bit. This will begin erase cycle.
f) CPU will stall for the duration of the erase
cycle.
g) The WR bit is cleared when erase cycle
ends.
EXAMPLE 5-1:
ERASING A ROW OF PROGRAM MEMORY
; Setup NVMCON for erase operation, multi word write
; program memory selected, and writes enabled
MOV
MOV
#0x4041,W0
W0,NVMCON
;
; Init NVMCON SFR
; Init pointer to row to be ERASED
MOV
MOV
MOV
MOV
DISI
#tblpage(PROG_ADDR),W0
W0,NVMADRU
#tbloffset(PROG_ADDR),W0
W0, NVMADR
;
; Initialize PM Page Boundary SFR
; Intialize in-page EA[15:0] pointer
; Initialize NVMADR SFR
; Block all interrupts with priority <7 for
; next 5 instructions
#5
MOV
MOV
MOV
MOV
BSET
NOP
NOP
#0x55,W0
W0,NVMKEY
#0xAA,W1
W1,NVMKEY
NVMCON,#WR
; Write the 0x55 key
;
; Write the 0xAA key
; Start the erase sequence
; Insert two NOPs after the erase
; command is asserted
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5.6.3
LOADING WRITE LATCHES
5.6.4
INITIATING THE PROGRAMMING
SEQUENCE
Example 5-2 shows a sequence of instructions that
can be used to load the 96 bytes of write latches. 32
TBLWTL and 32 TBLWTH instructions are needed to
load the write latches selected by the table pointer.
For protection, the write initiate sequence for NVMKEY
must be used to allow any erase or program operation
to proceed. After the programming command has been
executed, the user must wait for the programming time
until programming is complete. The two instructions
following the start of the programming sequence
should be NOPs as shown in Example 5-3.
EXAMPLE 5-2:
LOADING WRITE LATCHES
; Set up a pointer to the first program memory location to be written
; program memory selected, and writes enabled
MOV
MOV
MOV
#0x0000,W0
W0,TBLPAG
#0x6000,W0
;
; Initialize PM Page Boundary SFR
; An example program memory address
; Perform the TBLWT instructions to write the latches
; 0th_program_word
MOV
MOV
#LOW_WORD_0,W2
#HIGH_BYTE_0,W3
;
;
TBLWTL W2,[W0]
TBLWTH W3,[W0++]
; Write PM low word into program latch
; Write PM high byte into program latch
; 1st_program_word
MOV
MOV
#LOW_WORD_1,W2
#HIGH_BYTE_1,W3
;
;
TBLWTL W2,[W0]
TBLWTH W3,[W0++]
; Write PM low word into program latch
; Write PM high byte into program latch
;
2nd_program_word
MOV
MOV
#LOW_WORD_2,W2
#HIGH_BYTE_2,W3
;
;
TBLWTL W2, [W0]
TBLWTH W3, [W0++]
; Write PM low word into program latch
; Write PM high byte into program latch
•
•
•
; 31st_program_word
MOV
MOV
#LOW_WORD_31,W2
#HIGH_BYTE_31,W3
;
;
TBLWTL W2, [W0]
TBLWTH W3, [W0++]
; Write PM low word into program latch
; Write PM high byte into program latch
Note: In Example 5-2, the contents of the upper byte of W3 has no effect.
EXAMPLE 5-3:
INITIATING A PROGRAMMING SEQUENCE
DISI
#5
; Block all interrupts with priority <7 for
; next 5 instructions
;
; Write the 0x55 key
;
; Write the 0xAA key
; Start the erase sequence
; Insert two NOPs after the erase
; command is asserted
MOV
MOV
MOV
MOV
BSET
NOP
NOP
#0x55,W0
W0,NVMKEY
#0xAA,W1
W1,NVMKEY
NVMCON,#WR
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Control bit WR initiates write operations similar to pro-
gram Flash writes. This bit cannot be cleared, only set,
in software. They are cleared in hardware at the com-
pletion of the write operation. The inability to clear the
WR bit in software prevents the accidental or
premature termination of a write operation.
6.0
DATA EEPROM MEMORY
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
The WREN bit, when set, will allow a write operation.
On power-up, the WREN bit is clear. The WRERR bit is
set when a write operation is interrupted by a MCLR
Reset or a WDT Time-out Reset during normal opera-
tion. In these situations, following Reset, the user can
check the WRERR bit and rewrite the location. The
address register NVMADR remains unchanged.
The Data EEPROM Memory is readable and writable
during normal operation over the entire VDD range. The
data EEPROM memory is directly mapped in the
program memory address space.
The four SFRs used to read and write the program
Flash memory are used to access data EEPROM
memory, as well. As described in Section 5.5, these
registers are:
Note:
Interrupt flag bit NVMIF in the IFS0 regis-
ter is set when write is complete. It must be
cleared in software.
• NVMCON
• NVMADR
• NVMADRU
• NVMKEY
6.1
Reading the Data EEPROM
A TBLRD instruction reads a word at the current pro-
gram word address. This example uses W0 as a
pointer to data EEPROM. The result is placed in
register W4 as shown in Example 6-1.
The EEPROM data memory allows read and write of
single words and 16-word blocks. When interfacing to
data memory, NVMADR in conjunction with the
NVMADRU register are used to address the EEPROM
location being accessed. TBLRDL and TBLWTL
instructions are used to read and write data EEPROM.
The dsPIC30F devices have up to 8 Kbytes (4K
words) of data EEPROM with an address range from
0x7FF000 to 0x7FFFFE.
EXAMPLE 6-1:
DATA EEPROM READ
MOV
MOV
MOV
#LOW_ADDR_WORD,W0 ; Init Pointer
#HIGH_ADDR_WORD,W1
W1,TBLPAG
TBLRDL [ W0 ], W4
; read data EEPROM
A word write operation should be preceded by an erase
of the corresponding memory location(s). The write typ-
ically requires 2 ms to complete but the write time will
vary with voltage and temperature.
A program or erase operation on the data EEPROM
does not stop the instruction flow. The user is respon-
sible for waiting for the appropriate duration of time
before initiating another data EEPROM write/erase
operation. Attempting to read the data EEPROM while
a programming or erase operation is in progress results
in unspecified data.
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6.2.2
ERASING A WORD OF DATA
EEPROM
6.2
Erasing Data EEPROM
6.2.1
ERASING A BLOCK OF DATA
EEPROM
The NVMADRU and NVMADR registers must point to
the block. Select erase a block of data Flash, and set
the ERASE and WREN bits in the NVMCON register.
Setting the WR bit initiates the erase, as shown in
Example 6-3.
In order to erase a block of data EEPROM, the
NVMADRU and NVMADR registers must initially point
to the block of memory to be erased. Configure
NVMCON for erasing a block of data EEPROM, and
set the ERASE and WREN bits in the NVMCON
register. Setting the WR bit initiates the erase, as
shown in Example 6-2.
EXAMPLE 6-2:
DATA EEPROM BLOCK ERASE
; Select data EEPROM block, ERASE, WREN bits
MOV
MOV
#4045,W0
W0,NVMCON
; Initialize NVMCON SFR
; Start erase cycle by setting WR after writing key sequence
DISI
#5
; Block all interrupts with priority <7 for
; next 5 instructions
MOV
MOV
MOV
MOV
BSET
NOP
NOP
#0x55,W0
W0,NVMKEY
#0xAA,W1
W1,NVMKEY
NVMCON,#WR
;
; Write the 0x55 key
;
; Write the 0xAA key
; Initiate erase sequence
; Erase cycle will complete in 2mS. CPU is not stalled for the Data Erase Cycle
; User can poll WR bit, use NVMIF or Timer IRQ to determine erasure complete
EXAMPLE 6-3:
DATA EEPROM WORD ERASE
; Select data EEPROM word, ERASE, WREN bits
MOV
MOV
#4044,W0
W0,NVMCON
; Start erase cycle by setting WR after writing key sequence
DISI
#5
; Block all interrupts with priority <7 for
; next 5 instructions
MOV
MOV
MOV
MOV
BSET
NOP
NOP
#0x55,W0
W0,NVMKEY
#0xAA,W1
W1,NVMKEY
NVMCON,#WR
;
; Write the 0x55 key
;
; Write the 0xAA key
; Initiate erase sequence
; Erase cycle will complete in 2mS. CPU is not stalled for the Data Erase Cycle
; User can poll WR bit, use NVMIF or Timer IRQ to determine erasure complete
DS70138C-page 48
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dsPIC30F3014/4013
The write will not initiate if the above sequence is not
exactly followed (write 0x55 to NVMKEY, write 0xAA to
NVMCON, then set WR bit) for each word. It is strongly
recommended that interrupts be disabled during this
code segment.
6.3
Writing to the Data EEPROM
To write an EEPROM data location, the following
sequence must be followed:
1. Erase data EEPROM word.
a) Select word, data EEPROM erase, and set
WREN bit in NVMCON register.
Additionally, the WREN bit in NVMCON must be set to
enable writes. This mechanism prevents accidental
writes to data EEPROM due to unexpected code exe-
cution. The WREN bit should be kept clear at all times
except when updating the EEPROM. The WREN bit is
not cleared by hardware.
b) Write address of word to be erased into
NVMADR.
c) Enable NVM interrupt (optional).
d) Write ‘55’ to NVMKEY.
After a write sequence has been initiated, clearing the
WREN bit will not affect the current write cycle. The WR
bit will be inhibited from being set unless the WREN bit
is set. The WREN bit must be set on a previous instruc-
tion. Both WR and WREN cannot be set with the same
instruction.
e) Write ‘AA’ to NVMKEY.
f) Set the WR bit. This will begin erase cycle.
g) Either poll NVMIF bit or wait for NVMIF
interrupt.
h) The WR bit is cleared when the erase cycle
ends.
At the completion of the write cycle, the WR bit is
cleared in hardware and the Non-Volatile Memory
Write Complete Interrupt Flag bit (NVMIF) is set. The
user may either enable this interrupt or poll this bit.
NVMIF must be cleared by software.
2. Write data word into data EEPROM write
latches.
3. Program 1 data word into data EEPROM.
a) Select word, data EEPROM program, and
set WREN bit in NVMCON register.
6.3.1
WRITING A WORD OF DATA
EEPROM
b) Enable NVM write done interrupt (optional).
c) Write ‘55’ to NVMKEY.
Once the user has erased the word to be programmed,
then a table write instruction is used to write one write
latch, as shown in Example 6-4.
d) Write ‘AA’ to NVMKEY.
e) Set the WR bit. This will begin program
cycle.
f) Either poll NVMIF bit or wait for NVM
interrupt.
6.3.2
WRITING A BLOCK OF DATA
EEPROM
g) The WR bit is cleared when the write cycle
ends.
To write a block of data EEPROM, write to all sixteen
latches first, then set the NVMCON register and
program the block, as shown in Example 6-5.
EXAMPLE 6-4:
DATA EEPROM WORD WRITE
; Point to data memory
MOV
#LOW_ADDR_WORD,W0
; Init pointer
MOV
MOV
#HIGH_ADDR_WORD,W1
W1,TBLPAG
MOV
TBLWTL
#LOW(WORD),W2
W2,[ W0]
; Get data
; Write data
; The NVMADR captures last table access address
; Select data EEPROM for 1 word op
MOV
MOV
#0x4004,W0
W0,NVMCON
; Operate key to allow write operation
DISI
#5
; Block all interrupts with priority <7 for
; next 5 instructions
MOV
MOV
MOV
MOV
BSET
NOP
NOP
#0x55,W0
W0,NVMKEY
#0xAA,W1
W1,NVMKEY
NVMCON,#WR
; Write the 0x55 key
; Write the 0xAA key
; Initiate program sequence
; Write cycle will complete in 2mS. CPU is not stalled for the Data Write Cycle
; User can poll WR bit, use NVMIF or Timer IRQ to determine write complete
2004 Microchip Technology Inc.
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DS70138C-page 49
dsPIC30F3014/4013
EXAMPLE 6-5:
DATA EEPROM BLOCK WRITE
MOV
MOV
#LOW_ADDR_WORD,W0 ; Init pointer
#HIGH_ADDR_WORD,W1
MOV
W1,TBLPAG
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
TBLWTL
MOV
#data1,W2
W2,[ W0]++
#data2,W2
W2,[ W0]++
#data3,W2
W2,[ W0]++
#data4,W2
W2,[ W0]++
#data5,W2
W2,[ W0]++
#data6,W2
W2,[ W0]++
#data7,W2
W2,[ W0]++
#data8,W2
W2,[ W0]++
#data9,W2
W2,[ W0]++
#data10,W2
W2,[ W0]++
#data11,W2
W2,[ W0]++
#data12,W2
W2,[ W0]++
#data13,W2
W2,[ W0]++
#data14,W2
W2,[ W0]++
#data15,W2
W2,[ W0]++
#data16,W2
W2,[ W0]++
#0x400A,W0
W0,NVMCON
; Get 1st data
; write data
; Get 2nd data
; write data
; Get 3rd data
; write data
; Get 4th data
; write data
; Get 5th data
; write data
; Get 6th data
; write data
; Get 7th data
; write data
; Get 8th data
; write data
; Get 9th data
; write data
; Get 10th data
; write data
; Get 11th data
; write data
; Get 12th data
; write data
; Get 13th data
; write data
; Get 14th data
; write data
; Get 15th data
; write data
; Get 16th data
TBLWTL
MOV
MOV
; write data. The NVMADR captures last table access address.
; Select data EEPROM for multi word op
; Operate Key to allow program operation
; Block all interrupts with priority <7 for
; next 5 instructions
DISI
#5
MOV
MOV
MOV
MOV
BSET
NOP
NOP
#0x55,W0
W0,NVMKEY
#0xAA,W1
W1,NVMKEY
NVMCON,#WR
; Write the 0x55 key
; Write the 0xAA key
; Start write cycle
6.4
Write Verify
6.5
Protection Against Spurious Write
Depending on the application, good programming
practice may dictate that the value written to the mem-
ory should be verified against the original value. This
should be used in applications where excessive writes
can stress bits near the specification limit.
There are conditions when the device may not want to
write to the data EEPROM memory. To protect against
spurious EEPROM writes, various mechanisms have
been built-in. On power-up, the WREN bit is cleared;
also, the Power-up Timer prevents EEPROM write.
The write initiate sequence and the WREN bit together
help prevent an accidental write during brown-out,
power glitch, or software malfunction.
DS70138C-page 50
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2004 Microchip Technology Inc.
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Any bit and its associated data and control registers
that are not valid for a particular device will be dis-
abled. That means the corresponding LATx and TRISx
registers and the port pin will read as zeros.
7.0
I/O PORTS
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
When a pin is shared with another peripheral or func-
tion that is defined as an input only, it is nevertheless
regarded as a dedicated port because there is no
other competing source of outputs. An example is the
INT4 pin.
All of the device pins (except VDD, VSS, MCLR and
OSC1/CLKI) are shared between the peripherals and
the parallel I/O ports.
The format of the registers for PORTA are shown in
Table 7-1.
All I/O input ports feature Schmitt Trigger inputs for
improved noise immunity.
The TRISA (Data Direction Control) register controls
the direction of the RA<7:0> pins, as well as the INTx
pins and the VREF pins. The LATA register supplies
data to the outputs and is readable/writable. Reading
the PORTA register yields the state of the input pins,
while writing the PORTA register modifies the contents
of the LATA register.
7.1
Parallel I/O (PIO) Ports
When a peripheral is enabled and the peripheral is
actively driving an associated pin, the use of the pin as
a general purpose output pin is disabled. The I/O pin
may be read but the output driver for the parallel port bit
will be disabled. If a peripheral is enabled but the
peripheral is not actively driving a pin, that pin may be
driven by a port.
A parallel I/O (PIO) port that shares a pin with a periph-
eral is, in general, subservient to the peripheral. The
peripheral’s output buffer data and control signals are
provided to a pair of multiplexers. The multiplexers
select whether the peripheral or the associated port
has ownership of the output data and control signals of
the I/O pad cell. Figure 7-2 shows how ports are shared
with other peripherals and the associated I/O cell (pad)
to which they are connected. Table 7-1 shows the
formats of the registers for the shared ports, PORTB
through PORTG.
All port pins have three registers directly associated
with the operation of the port pin. The Data Direction
register (TRISx) determines whether the pin is an input
or an output. If the data direction bit is a ‘1’, then the pin
is an input. All port pins are defined as inputs after a
Reset. Reads from the latch (LATx), read the latch.
Writes to the latch, write the latch (LATx). Reads from
the port (PORTx), read the port pins and writes to the
port pins, write the latch (LATx).
Note:
The actual bits in use vary between
devices.
FIGURE 7-1:
BLOCK DIAGRAM OF A DEDICATED PORT STRUCTURE
Dedicated Port Module
Read TRIS
I/O Cell
TRIS Latch
D
Q
Data Bus
WR TRIS
CK
Data Latch
I/O Pad
D
Q
WR LAT +
WR Port
CK
Read LAT
Read Port
2004 Microchip Technology Inc.
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DS70138C-page 51
dsPIC30F3014/4013
FIGURE 7-2:
BLOCK DIAGRAM OF A SHARED PORT STRUCTURE
Output Multiplexers
Peripheral Module
Peripheral Input Data
Peripheral Module Enable
Peripheral Output Enable
Peripheral Output Data
I/O Cell
1
0
Output Enable
1
0
PIO Module
Output Data
Read TRIS
I/O Pad
Data Bus
WR TRIS
D
Q
CK
TRIS Latch
D
Q
WR LAT +
WR Port
CK
Data Latch
Read LAT
Input Data
Read Port
7.2.1
I/O PORT WRITE/READ TIMING
7.2
Configuring Analog Port Pins
One instruction cycle is required between a port
direction change or port write operation and a read
operation of the same port. Typically this instruction
would be a NOP.
The use of the ADPCFG and TRIS registers control the
operation of the A/D port pins. The port pins that are
desired as analog inputs must have their correspond-
ing TRIS bit set (input). If the TRIS bit is cleared
(output), the digital output level (VOH or VOL) will be
converted.
EXAMPLE 7-1:
PORT WRITE/READ
EXAMPLE
When reading the Port register, all pins configured as
analog input channels will read as cleared (a low level).
MOV
0xFF00, W0 ; Configure PORTB<15:8>
; as inputs
Pins configured as digital inputs will not convert an ana-
log input. Analog levels on any pin that is defined as a
digital input (including the ANx pins) may cause the
input buffer to consume current that exceeds the
device specifications.
MOV
NOP
W0, TRISB
; and PORTB<7:0> as outputs
; additional instruction
cylcle
btss PORTB, #11 ; bit test RB11 and skip if
set
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DS70138C-page 53
dsPIC30F3014/4013
7.3
Input Change Notification Module
The input change notification module provides the
dsPIC30F devices the ability to generate interrupt
requests to the processor, in response to a change of
state on selected input pins. This module is capable of
detecting input change of states even in Sleep mode,
when the clocks are disabled. There are up to 24 exter-
nal signals (CN0 through CN23) that may be selected
(enabled) for generating an interrupt request on a
change of state.
TABLE 7-2:
INPUT CHANGE NOTIFICATION REGISTER MAP FOR dsPIC30F3014 (BITS 15-8)
SFR Name Addr.
Bit 15
Bit 14
Bit 13
Bit 12
Bit 11
Bit 10
Bit 9
Bit 8
Reset State
CNEN1
CNEN2
CNPU1
CNPU2
Legend:
00C0
00C2
CN15IE
—
CN14IE
—
CN13IE
—
CN12IE
—
CN11IE
—
CN10IE
—
CN9IE
—
CN8IE
—
0000 0000 0000 0000
0000 0000 0000 0000
00C4 CN15PUE CN14PUE CN13PUE CN12PUE CN11PUE CN10PUE CN9PUE CN8PUE 0000 0000 0000 0000
00C6
0000 0000 0000 0000
—
—
—
—
—
—
—
—
u= uninitialized bit
TABLE 7-3:
INPUT CHANGE NOTIFICATION REGISTER MAP FOR dsPIC30F3014 (BITS 7-0)
SFR
Addr.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Reset State
Name
CNEN1
CNEN2
CNPU1
CNPU2
Legend:
00C0
00C2
00C4
00C6
CN7IE
—
CN6IE
—
CN5IE
—
CN4IE
—
CN3IE
—
CN2IE
CN1IE
CN0IE
0000 0000 0000 0000
0000 0000 0000 0000
CN18IE
CN17IE
CN16IE
CN7PUE CN6PUE CN5PUE CN4PUE CN3PUE CN2PUE CN1PUE
CN0PUE 0000 0000 0000 0000
—
—
—
—
—
CN18PUE CN17PUE CN16PUE 0000 0000 0000 0000
u= uninitialized bit
TABLE 7-4:
INPUT CHANGE NOTIFICATION REGISTER MAP FOR dsPIC30F4013 (BITS 15-8)
SFR
Addr.
Bit 15
Bit 14
Bit 13
Bit 12
Bit 11
Bit 10
Bit 9
Bit 8
Reset State
Name
CNEN1
CNEN2
CNPU1
CNPU2
Legend:
00C0
00C2
00C4
00C6
CN15IE
—
CN14IE
—
CN13IE
—
CN12IE
—
CN11IE
—
CN10IE
—
CN9IE
—
CN8IE
—
0000 0000 0000 0000
0000 0000 0000 0000
CN15PUE CN14PUE CN13PUE CN12PUE CN11PUE CN10PUE CN9PUE CN8PUE 0000 0000 0000 0000
0000 0000 0000 0000
—
—
—
—
—
—
—
—
u= uninitialized bit
TABLE 7-5:
INPUT CHANGE NOTIFICATION REGISTER MAP FOR dsPIC30F4013 (BITS 7-0)
SFR
Addr.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Reset State
Name
CNEN1
CNEN2
CNPU1
CNPU2
Legend:
00C0
00C2
00C4
00C6
CN7IE
CN6IE
CN5IE
CN4IE
CN3IE
CN2IE
CN1IE
CN0IE
0000 0000 0000 0000
0000 0000 0000 0000
CN23IE
CN22IE
CN21IE
CN20IE
CN19IE
CN18IE
CN17IE
CN16IE
CN7PUE CN6PUE CN5PUE CN4PUE CN3PUE CN2PUE CN1PUE
CN0PUE 0000 0000 0000 0000
CN23PUE CN22PUE CN21PUE CN20PUE CN19PUE CN18PUE CN17PUE CN16PUE 0000 0000 0000 0000
u= uninitialized bit
Note: Refer to dsPIC30F Family Reference Manual (DS70046) for descriptions of register bit fields.
DS70138C-page 54
Advance Information
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• INTCON1<15:0>, INTCON2<15:0>
8.0
INTERRUPTS
Global interrupt control functions are derived from
these two registers. INTCON1 contains the con-
trol and status flags for the processor exceptions.
The INTCON2 register controls the external
interrupt request signal behavior and the use of
the alternate vector table.
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
Note:
Interrupt flag bits get set when an interrupt
condition occurs, regardless of the state of
its corresponding enable bit. User soft-
ware should ensure the appropriate inter-
rupt flag bits are clear prior to enabling an
interrupt.
The dsPIC30F Sensor and General Purpose Families
have up to 41 interrupt sources and 4 processor excep-
tions (traps) which must be arbitrated based on a
priority scheme.
The CPU is responsible for reading the Interrupt Vector
Table (IVT) and transferring the address contained in
the interrupt vector to the program counter. The inter-
rupt vector is transferred from the program data bus
into the program counter via a 24-bit wide multiplexer
on the input of the program counter.
All interrupt sources can be user assigned to one of 7
priority levels, 1 through 7, via the IPCx registers. Each
interrupt source is associated with an interrupt vector,
as shown in Table 8-1. Levels 7 and 1 represent the
highest and lowest maskable priorities, respectively.
Note:
Assigning a priority level of ‘0’ to an inter-
rupt source is equivalent to disabling that
interrupt.
The Interrupt Vector Table (IVT) and Alternate Interrupt
Vector Table (AIVT) are placed near the beginning of
program memory (0x000004). The IVT and AIVT are
shown in Figure 8-1.
If the NSTDIS bit (INTCON1<15>) is set, nesting of
interrupts is prevented. Thus, if an interrupt is currently
being serviced, processing of a new interrupt is pre-
vented even if the new interrupt is of higher priority than
the one currently being serviced.
The interrupt controller is responsible for pre-
processing the interrupts and processor exceptions
prior to them being presented to the processor core.
The peripheral interrupts and traps are enabled, priori-
tized and controlled using centralized Special Function
Registers:
Note:
The IPL bits become read only whenever
the NSTDIS bit has been set to ‘1’.
Certain interrupts have specialized control bits for
features like edge or level triggered interrupts, inter-
rupt-on-change, etc. Control of these features remains
within the peripheral module which generates the
interrupt.
• IFS0<15:0>, IFS1<15:0>, IFS2<15:0>
All interrupt request flags are maintained in these
three registers. The flags are set by their respec-
tive peripherals or external signals, and they are
cleared via software.
• IEC0<15:0>, IEC1<15:0>, IEC2<15:0>
All interrupt enable control bits are maintained in
these three registers. These control bits are used
to individually enable interrupts from the
peripherals or external signals.
The DISI instruction can be used to disable the
processing of interrupts of priorities 6 and lower for a
certain number of instructions, during which the DISI bit
(INTCON2<14>) remains set.
When an interrupt is serviced, the PC is loaded with the
address stored in the vector location in program mem-
ory that corresponds to the interrupt. There are 63 dif-
ferent vectors within the IVT (refer to Table 8-1). These
vectors are contained in locations 0x000004 through
0x0000FE of program memory (refer to Table 8-1).
These locations contain 24-bit addresses and in order
to preserve robustness, an address error trap will take
place should the PC attempt to fetch any of these
words during normal execution. This prevents execu-
tion of random data as a result of accidentally
decrementing a PC into vector space, accidentally
mapping a data space address into vector space, or the
PC rolling over to 0x000000 after reaching the end of
implemented program memory space. Execution of a
GOTOinstruction to this vector space will also generate
an address error trap.
• IPC0<15:0>... IPC10<7:0>
The user assignable priority level associated with
each of these 41 interrupts is held centrally in
these twelve registers.
• IPL<3:0>
The current CPU priority level is explicitly stored
in the IPL bits. IPL<3> is present in the CORCON
register, whereas IPL<2:0> are present in the
STATUS register (SR) in the processor core.
2004 Microchip Technology Inc.
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DS70138C-page 55
dsPIC30F3014/4013
TABLE 8-1:
dsPIC30F3014 INTERRUPT
VECTOR TABLE
8.1
Interrupt Priority
The user assignable interrupt priority (IP<2:0>) bits for
each individual interrupt source are located in the LS
3 bits of each nibble within the IPCx register(s). Bit 3 of
each nibble is not used and is read as a ‘0’. These bits
define the priority level assigned to a particular interrupt
by the user.
INT
Vector
Interrupt Source
Number Number
Highest Natural Order Priority
0
1
8
INT0 - External Interrupt 0
IC1 - Input Capture 1
OC1 - Output Compare 1
T1 - Timer 1
9
2
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
Note:
The user selectable priority levels start at
0 as the lowest priority and level 7 as the
highest priority.
3
4
IC2 - Input Capture 2
OC2 - Output Compare 2
T2 - Timer 2
Natural Order Priority is determined by the position of
an interrupt in the vector table, and only affects
interrupt operation when multiple interrupts with the
same user-assigned priority become pending at the
same time.
5
6
7
T3 - Timer 3
8
SPI1
9
U1RX - UART1 Receiver
U1TX - UART1 Transmitter
ADC - ADC Convert Done
NVM - NVM Write Complete
Table 8-1 and Table 8-2 list the interrupt numbers, cor-
responding interrupt sources and associated vector
numbers for the dsPIC30F3014 and dsPIC30F4013
devices respectively.
10
11
12
13
14
15
16
17-22
23
24
25
26
27
28-41
42
43-53
2
SI2C - I C Slave Interrupt
Note 1: The natural order priority scheme has 0
as the highest priority and 53 as the
lowest priority.
2
MI2C - I C Master Interrupt
Input Change Interrupt
INT1 - External Interrupt 1
2: The natural order priority number is the
25-30 Reserved
same as the INT number.
31
32
33
34
35
INT2 - External Interrupt 2
The ability for the user to assign every interrupt to one
of seven priority levels implies that the user can assign
a very high overall priority level to an interrupt with a
low natural order priority. For example, the PLVD (Low
Voltage Detect) can be given a priority of 7. The INT0
(External Interrupt 0) may be assigned to priority level
1, thus giving it a very low effective priority.
U2RX - UART2 Receiver
U2TX - UART2 Transmitter
Reserved
C1 - Combined IRQ for CAN1
36-49 Reserved
50 LVD - Low Voltage Detect
51-61 Reserved
Lowest Natural Order Priority
DS70138C-page 56
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dsPIC30F3014/4013
TABLE 8-2:
dsPIC30F4013 INTERRUPT
VECTOR TABLE
8.2
Reset Sequence
A Reset is not a true exception, because the interrupt
controller is not involved in the Reset process. The pro-
cessor initializes its registers in response to a Reset
which forces the PC to zero. The processor then begins
program execution at location 0x000000. A GOTO
instruction is stored in the first program memory loca-
tion immediately followed by the address target for the
GOTOinstruction. The processor executes the GOTOto
the specified address and then begins operation at the
specified target (start) address.
INT
Vector
Interrupt Source
Number Number
Highest Natural Order Priority
0
1
8
INT0 - External Interrupt 0
IC1 - Input Capture 1
OC1 - Output Compare 1
T1 - Timer 1
9
2
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
3
4
IC2 - Input Capture 2
OC2 - Output Compare 2
T2 - Timer 2
5
8.2.1
RESET SOURCES
6
7
T3 - Timer 3
In addition to external Reset and Power-on Reset
(POR), there are 6 sources of error conditions which
‘trap’ to the Reset vector.
8
SPI1
9
U1RX - UART1 Receiver
U1TX - UART1 Transmitter
ADC - ADC Convert Done
NVM - NVM Write Complete
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28-40
41
42
43-53
• Watchdog Time-out:
The watchdog has timed out, indicating that the
processor is no longer executing the correct flow
of code.
2
SI2C - I C Slave Interrupt
• Uninitialized W Register Trap:
2
MI2C - I C Master Interrupt
An attempt to use an uninitialized W register as
an address pointer will cause a Reset.
Input Change Interrupt
INT1 - External Interrupt 1
IC7 - Input Capture 7
IC8 - Input Capture 8
OC3 - Output Compare 3
OC4 - Output Compare 4
T4 - Timer 4
• Illegal Instruction Trap:
Attempted execution of any unused opcodes will
result in an illegal instruction trap. Note that a
fetch of an illegal instruction does not result in an
illegal instruction trap if that instruction is flushed
prior to execution due to a flow change.
• Brown-out Reset (BOR):
T5 - Timer 5
A momentary dip in the power supply to the
device has been detected which may result in
malfunction.
INT2 - External Interrupt 2
U2RX - UART2 Receiver
U2TX - UART2 Transmitter
Reserved
• Trap Lockout:
Occurrence of multiple trap conditions
simultaneously will cause a Reset.
C1 - Combined IRQ for CAN1
36-48 Reserved
49 DCI - CODEC Transfer Done
50 LVD - Low Voltage Detect
51-61 Reserved
Lowest Natural Order Priority
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Address Error Trap:
8.3
Traps
This trap is initiated when any of the following
circumstances occurs:
Traps can be considered as non-maskable interrupts
indicating a software or hardware error, which adhere
to a predefined priority as shown in Figure 8-1. They
are intended to provide the user a means to correct
erroneous operation during debug and when operating
within the application.
1. A misaligned data word access is attempted.
2. A data fetch from our unimplemented data
memory location is attempted.
3. A data access of an unimplemented program
memory location is attempted.
Note:
If the user does not intend to take correc-
tive action in the event of a trap error
condition, these vectors must be loaded
with the address of a default handler that
simply contains the RESET instruction. If,
on the other hand, one of the vectors
containing an invalid address is called, an
address error trap is generated.
4. An instruction fetch from vector space is
attempted.
Note:
In the MAC class of instructions, wherein
the data space is split into X and Y data
space, unimplemented X space includes
all of Y space, and unimplemented Y
space includes all of X space.
Note that many of these trap conditions can only be
detected when they occur. Consequently, the question-
able instruction is allowed to complete prior to trap
exception processing. If the user chooses to recover
from the error, the result of the erroneous action that
caused the trap may have to be corrected.
5. Execution of a “BRA #literal” instruction or a
“GOTO #literal” instruction, where literal
is an unimplemented program memory address.
6. Executing instructions after modifying the PC to
point to unimplemented program memory
addresses. The PC may be modified by loading
a value into the stack and executing a RETURN
instruction.
There are 8 fixed priority levels for traps: Level 8
through Level 15, which implies that the IPL3 is always
set during processing of a trap.
Stack Error Trap:
If the user is not currently executing a trap, and he sets
the IPL<3:0> bits to a value of ‘0111’ (Level 7), then all
interrupts are disabled, but traps can still be processed.
This trap is initiated under the following conditions:
1. The stack pointer is loaded with a value which is
greater than the (user programmable) limit value
written into the SPLIM register (stack overflow).
8.3.1
TRAP SOURCES
The following traps are provided with increasing prior-
ity. However, since all traps can be nested, priority has
little effect.
2. The stack pointer is loaded with a value which is
less than 0x0800 (simple stack underflow).
Oscillator Fail Trap:
Math Error Trap:
This trap is initiated if the external oscillator fails and
operation becomes reliant on an internal RC backup.
The Math Error trap executes under the following three
circumstances:
8.3.2
HARD AND SOFT TRAPS
1. Should an attempt be made to divide by zero,
the divide operation will be aborted on a cycle
boundary and the trap taken.
It is possible that multiple traps can become active
within the same cycle (e.g., a misaligned word stack
write to an overflowed address). In such a case, the
fixed priority shown in Figure 8-2 is implemented,
which may require the user to check if other traps are
pending, in order to completely correct the fault.
2. If enabled, a Math Error trap will be taken when
an arithmetic operation on either accumulator A
or B causes an overflow from bit 31 and the
accumulator guard bits are not utilized.
3. If enabled, a Math Error trap will be taken when
an arithmetic operation on either accumulator A
or B causes a catastrophic overflow from bit 39
and all saturation is disabled.
‘Soft’ traps include exceptions of priority level 8 through
level 11, inclusive. The arithmetic error trap (level 11)
falls into this category of traps.
‘Hard’ traps include exceptions of priority level 12
through level 15, inclusive. The address error (level
12), stack error (level 13) and oscillator error (level 14)
traps fall into this category.
4. If the shift amount specified in a shift instruction
is greater than the maximum allowed shift
amount, a trap will occur.
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Each hard trap that occurs must be acknowledged
before code execution of any type may continue. If a
lower priority hard trap occurs while a higher priority
trap is pending, acknowledged, or is being processed,
a hard trap conflict will occur.
rupt into the STATUS register. This action will disable
all lower priority interrupts until the completion of the
Interrupt Service Routine.
FIGURE 8-2:
INTERRUPTSTACKFRAME
The device is automatically Reset in a hard trap conflict
condition. The TRAPR status bit (RCON<15>) is set
when the Reset occurs, so that the condition may be
detected in software.
0x0000 15
0
FIGURE 8-1:
TRAP VECTORS
W15 (before CALL)
PC<15:0>
SRL IPL3 PC<22:16>
<Free Word>
Reset - GOTOInstruction
Reset - GOTOAddress
Reserved
0x000000
0x000002
W15 (after CALL)
0x000004
Oscillator Fail Trap Vector
Address Error Trap Vector
Stack Error Trap Vector
Math Error Trap Vector
Reserved Vector
POP :[--W15]
PUSH:[W15++]
IVT
Reserved Vector
Reserved Vector
Interrupt 0 Vector
Interrupt 1 Vector
—
0x000014
Note 1: The user can always lower the priority
level by writing a new value into SR. The
Interrupt Service Routine must clear the
interrupt flag bits in the IFSx register
before lowering the processor interrupt
priority, in order to avoid recursive
interrupts.
—
—
Interrupt 52 Vector
Interrupt 53 Vector
Reserved
0x00007E
0x000080
0x000082
Reserved
0x000084
Reserved
Oscillator Fail Trap Vector
Stack Error Trap Vector
Address Error Trap Vector
Math Error Trap Vector
Reserved Vector
2: The IPL3 bit (CORCON<3>) is always
clear when interrupts are being pro-
cessed. It is set only during execution of
traps.
AIVT
Reserved Vector
Reserved Vector
0x000094
Interrupt 0 Vector
Interrupt 1 Vector
—
—
—
The RETFIE (return from interrupt) instruction will
unstack the program counter and STATUS registers to
return the processor to its state prior to the interrupt
sequence.
Interrupt 52 Vector
Interrupt 53 Vector
0x0000FE
8.4
Interrupt Sequence
8.5
Alternate Vector Table
All interrupt event flags are sampled in the beginning of
each instruction cycle by the IFSx registers. A pending
interrupt request (IRQ) is indicated by the flag bit being
equal to a ‘1’ in an IFSx register. The IRQ will cause an
interrupt to occur if the corresponding bit in the Interrupt
Enable (IECx) register is set. For the remainder of the
instruction cycle, the priorities of all pending interrupt
requests are evaluated.
In program memory, the Interrupt Vector Table (IVT) is
followed by the Alternate Interrupt Vector Table (AIVT),
as shown in Figure 8-1. Access to the alternate vector
table is provided by the ALTIVT bit in the INTCON2 reg-
ister. If the ALTIVT bit is set, all interrupt and exception
processes will use the alternate vectors instead of the
default vectors. The alternate vectors are organized in
the same manner as the default vectors. The AIVT sup-
ports emulation and debugging efforts by providing a
means to switch between an application and a support
environment without requiring the interrupt vectors to
be reprogrammed. This feature also enables switching
between applications for evaluation of different
software algorithms at run time.
If there is a pending IRQ with a priority level greater
than the current processor priority level in the IPL bits,
the processor will be interrupted.
The processor then stacks the current program counter
and the low byte of the processor STATUS register
(SRL), as shown in Figure 8-2. The low byte of the
STATUS register contains the processor priority level at
the time prior to the beginning of the interrupt cycle.
The processor then loads the priority level for this inter-
If the AIVT is not required, the program memory allo-
cated to the AIVT may be used for other purposes.
AIVT is not a protected section and may be freely
programmed by the user.
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8.6
Fast Context Saving
8.7
External Interrupt Requests
A context saving option is available using shadow reg-
isters. Shadow registers are provided for the DC, N,
OV, Z and C bits in SR, and the registers W0 through
W3. The shadows are only one level deep. The shadow
registers are accessible using the PUSH.Sand POP.S
instructions only.
The interrupt controller supports up to five external
interrupt request signals, INT0-INT4. These inputs are
edge sensitive; they require a low-to-high or a high-to-
low transition to generate an interrupt request. The
INTCON2 register has five bits, INT0EP-INT4EP, that
select the polarity of the edge detection circuitry.
When the processor vectors to an interrupt, the
PUSH.S instruction can be used to store the current
value of the aforementioned registers into their
respective shadow registers.
8.8
Wake-up from Sleep and Idle
The interrupt controller may be used to wake-up the
processor from either Sleep or Idle modes, if Sleep or
Idle mode is active when the interrupt is generated.
If an ISR of a certain priority uses the PUSH.S and
POP.S instructions for fast context saving, then a
higher priority ISR should not include the same instruc-
tions. Users must save the key registers in software
during a lower priority interrupt if the higher priority ISR
uses fast context saving.
If an enabled interrupt request of sufficient priority is
received by the interrupt controller, then the standard
interrupt request is presented to the processor. At the
same time, the processor will wake-up from Sleep or
Idle and begin execution of the Interrupt Service
Routine (ISR) needed to process the interrupt request.
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These Operating modes are determined by setting the
appropriate bit(s) in the 16-bit SFR, T1CON. Figure 9-1
presents a block diagram of the 16-bit timer module.
9.0
TIMER1 MODULE
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
16-bit Timer Mode: In the 16-bit Timer mode, the timer
increments on every instruction cycle up to a match
value preloaded into the Period register PR1, then
resets to ‘0’ and continues to count.
This section describes the 16-bit General Purpose
(GP) Timer1 module and associated Operational
modes. Figure 9-1 depicts the simplified block diagram
of the 16-bit Timer1 module.
When the CPU goes into the Idle mode, the timer will
stop incrementing unless the TSIDL (T1CON<13>)
bit = 0. If TSIDL = 1, the timer module logic will resume
the incrementing sequence upon termination of the
CPU Idle mode.
The following sections provide a detailed description
including setup and control registers, along with asso-
ciated block diagrams for the Operational modes of the
timers.
16-bit Synchronous Counter Mode: In the 16-bit
Synchronous Counter mode, the timer increments on
the rising edge of the applied external clock signal
which is synchronized with the internal phase clocks.
The timer counts up to a match value preloaded in PR1,
then resets to ‘0’ and continues.
The Timer1 module is a 16-bit timer which can serve as
the time counter for the real-time clock, or operate as a
free-running interval timer/counter. The 16-bit timer has
the following modes:
When the CPU goes into the Idle mode, the timer will
stop incrementing unless the respective TSIDL bit = 0.
If TSIDL = 1, the timer module logic will resume the
incrementing sequence upon termination of the CPU
Idle mode.
• 16-bit Timer
• 16-bit Synchronous Counter
• 16-bit Asynchronous Counter
Further, the following operational characteristics are
supported:
16-bit Asynchronous Counter Mode: In the 16-bit
Asynchronous Counter mode, the timer increments on
every rising edge of the applied external clock signal.
The timer counts up to a match value preloaded in PR1,
then resets to ‘0’ and continues.
• Timer gate operation
• Selectable prescaler settings
• Timer operation during CPU Idle and Sleep
modes
When the timer is configured for the Asynchronous
mode of operation and the CPU goes into the Idle
mode, the timer will stop incrementing if TSIDL = 1.
• Interrupt on 16-bit Period register match or falling
edge of external gate signal
FIGURE 9-1:
16-BIT TIMER1 MODULE BLOCK DIAGRAM
PR1
Comparator x 16
TMR1
Equal
TSYNC
1
0
Sync
Reset
0
1
T1IF
Event Flag
Q
Q
D
TGATE
CK
TGATE
TCKPS<1:0>
2
TON
SOSCO/
T1CK
1x
01
00
Prescaler
Gate
Sync
LPOSCEN
1, 8, 64, 256
SOSCI
TCY
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9.1
Timer Gate Operation
9.4
Timer Interrupt
The 16-bit timer can be placed in the Gated Time Accu-
mulation mode. This mode allows the internal TCY to
increment the respective timer when the gate input sig-
nal (T1CK pin) is asserted high. Control bit TGATE
(T1CON<6>) must be set to enable this mode. The
timer must be enabled (TON = 1) and the timer clock
source set to internal (TCS = 0).
The 16-bit timer has the ability to generate an interrupt on
period match. When the timer count matches the Period
register, the T1IF bit is asserted and an interrupt will be
generated if enabled. The T1IF bit must be cleared in
software. The timer interrupt flag, T1IF, is located in the
IFS0 Control register in the interrupt controller.
When the Gated Time Accumulation mode is enabled,
an interrupt will also be generated on the falling edge of
the gate signal (at the end of the accumulation cycle).
When the CPU goes into the Idle mode, the timer will
stop incrementing unless TSIDL = 0. If TSIDL = 1, the
timer will resume the incrementing sequence upon
termination of the CPU Idle mode.
Enabling an interrupt is accomplished via the respec-
tive timer interrupt enable bit, T1IE. The timer interrupt
enable bit is located in the IEC0 Control register in the
interrupt controller.
9.2
Timer Prescaler
The input clock (FOSC/4 or external clock) to the 16-bit
Timer has a prescale option of 1:1, 1:8, 1:64 and 1:256,
selected by control bits TCKPS<1:0> (T1CON<5:4>).
The prescaler counter is cleared when any of the
following occurs:
9.5
Real-Time Clock
Timer1, when operating in Real-Time Clock (RTC)
mode, provides time of day and event time-stamping
capabilities. Key operational features of the RTC are:
• a write to the TMR1 register
• Operation from 32 kHz LP oscillator
• 8-bit prescaler
• a write to the T1CON register
• device Reset, such as POR and BOR
• Low power
However, if the timer is disabled (TON = 0), then the
timer prescaler cannot be reset since the prescaler
clock is halted.
• Real-Time Clock interrupts
These operating modes are determined by setting the
appropriate bit(s) in the T1CON Control register.
TMR1 is not cleared when T1CON is written. It is
cleared by writing to the TMR1 register.
FIGURE 9-2:
RECOMMENDED
COMPONENTS FOR
TIMER1 LP OSCILLATOR
RTC
9.3
Timer Operation During Sleep
Mode
During CPU Sleep mode, the timer will operate if:
C1
• The timer module is enabled (TON = 1) and
SOSCI
• The timer clock source is selected as external
(TCS = 1) and
32.768 kHz
XTAL
dsPIC30FXXXX
• The TSYNC bit (T1CON<2>) is asserted to a logic
‘0’ which defines the external clock source as
asynchronous.
SOSCO
C2
R
When all three conditions are true, the timer will con-
tinue to count up to the Period register and be reset to
0x0000.
C1 = C2 = 18 pF; R = 100K
When a match between the timer and the Period regis-
ter occurs, an interrupt can be generated if the
respective timer interrupt enable bit is asserted.
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9.5.1
RTC OSCILLATOR OPERATION
9.5.2
RTC INTERRUPTS
When the TON = 1, TCS = 1and TGATE = 0, the timer
increments on the rising edge of the 32 kHz LP oscilla-
tor output signal, up to the value specified in the Period
register and is then reset to ‘0’.
When an interrupt event occurs, the respective interrupt
flag, T1IF, is asserted and an interrupt will be generated
if enabled. The T1IF bit must be cleared in software. The
respective Timer interrupt flag, T1IF, is located in the
IFS0 Status register in the interrupt controller.
The TSYNC bit must be asserted to a logic ‘0’
(Asynchronous mode) for correct operation.
Enabling an interrupt is accomplished via the respec-
tive timer interrupt enable bit, T1IE. The timer interrupt
enable bit is located in the IEC0 Control register in the
interrupt controller.
Enabling LPOSCEN (OSCCON<1>) will disable the
normal Timer and Counter modes and enable a timer
carry-out wake-up event.
When the CPU enters Sleep mode, the RTC will con-
tinue to operate provided the 32 kHz external crystal
oscillator is active and the control bits have not been
changed. The TSIDL bit should be cleared to ‘0’ in
order for RTC to continue operation in Idle mode.
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16-bit Timer Mode: In the 16-bit mode, Timer2 and
Timer3 can be configured as two independent 16-bit
timers. Each timer can be set up in either 16-bit Timer
mode or 16-bit Synchronous Counter mode. See
Section 9.0, Timer1 Module for details on these two
Operating modes.
10.0 TIMER2/3 MODULE
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
The only functional difference between Timer2 and
Timer3 is that Timer2 provides synchronization of the
clock prescaler output. This is useful for high frequency
external clock inputs.
This section describes the 32-bit General Purpose
(GP) Timer module (Timer2/3) and associated Opera-
tional modes. Figure 10-1 depicts the simplified block
diagram of the 32-bit Timer2/3 module. Figure 10-2
and Figure 10-3 show Timer2/3 configured as two
independent 16-bit timers, Timer2 and Timer3,
respectively.
32-bit Timer Mode: In the 32-bit Timer mode, the timer
increments on every instruction cycle, up to a match
value preloaded into the combined 32-bit Period
register PR3/PR2, then resets to ‘0’ and continues to
count.
The Timer2/3 module is a 32-bit timer (which can be
configured as two 16-bit timers) with selectable
Operating modes. These timers are utilized by other
peripheral modules, such as:
For synchronous 32-bit reads of the Timer2/Timer3
pair, reading the LS Word (TMR2 register) will cause
the MS word to be read and latched into a 16-bit
holding register, termed TMR3HLD.
• Input Capture
• Output Compare/Simple PWM
For synchronous 32-bit writes, the holding register
(TMR3HLD) must first be written to. When followed by
a write to the TMR2 register, the contents of TMR3HLD
will be transferred and latched into the MSB of the
32-bit timer (TMR3).
The following sections provide a detailed description,
including setup and control registers, along with asso-
ciated block diagrams for the Operational modes of the
timers.
32-bit Synchronous Counter Mode: In the 32-bit
Synchronous Counter mode, the timer increments on
the rising edge of the applied external clock signal
which is synchronized with the internal phase clocks.
The timer counts up to a match value preloaded in the
combined 32-bit period register PR3/PR2, then resets
to ‘0’ and continues.
The 32-bit timer has the following modes:
• Two independent 16-bit timers (Timer2 and
Timer3) with all 16-bit Operating modes (except
Asynchronous Counter mode)
• Single 32-bit timer operation
• Single 32-bit synchronous counter
When the timer is configured for the Synchronous
Counter mode of operation and the CPU goes into the
Idle mode, the timer will stop incrementing unless the
TSIDL (T2CON<13>) bit = 0. If TSIDL = 1, the timer
module logic will resume the incrementing sequence
upon termination of the CPU Idle mode.
Further, the following operational characteristics are
supported:
• ADC event trigger
• Timer gate operation
• Selectable prescaler settings
• Timer operation during Idle and Sleep modes
• Interrupt on a 32-bit period register match
These Operating modes are determined by setting the
appropriate bit(s) in the 16-bit T2CON and T3CON
SFRs.
For 32-bit timer/counter operation, Timer2 is the LS
Word and Timer3 is the MS Word of the 32-bit timer.
Note:
For 32-bit timer operation, T3CON control
bits are ignored. Only T2CON control bits
are used for setup and control. Timer2
clock and gate inputs are utilized for the
32-bit timer module but an interrupt is gen-
erated with the Timer3 interrupt flag (T3IF)
and the interrupt is enabled with the
Timer3 interrupt enable bit (T3IE).
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FIGURE 10-1:
32-BIT TIMER2/3 BLOCK DIAGRAM
Data Bus<15:0>
TMR3HLD
16
16
Write TMR2
Read TMR2
16
Reset
Sync
TMR3
MSB
TMR2
LSB
ADC Event Trigger
Comparator x 32
Equal
PR3
PR2
0
1
T3IF
Event Flag
Q
Q
D
TGATE (T2CON<6>)
CK
TGATE
(T2CON<6>)
TCKPS<1:0>
2
TON
T2CK
1x
Prescaler
Gate
Sync
1, 8, 64, 256
01
00
TCY
Note:
Timer configuration bit T32 (T2CON<3>) must be set to ‘1’ for a 32-bit timer/counter operation. All control
bits are respective to the T2CON register.
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FIGURE 10-2:
16-BIT TIMER2 BLOCK DIAGRAM
PR2
Equal
Comparator x 16
TMR2
Sync
Reset
0
1
T2IF
Event Flag
TGATE
Q
Q
D
CK
TGATE
TCKPS<1:0>
2
TON
T2CK
1x
01
00
Prescaler
Gate
Sync
1, 8, 64, 256
TCY
FIGURE 10-3:
16-BIT TIMER3 BLOCK DIAGRAM
PR3
ADC Event Trigger
Equal
Comparator x 16
TMR3
Reset
0
1
T3IF
TGATE
Event Flag
Q
Q
D
CK
TGATE
TCKPS<1:0>
2
TON
T3CK
Sync
1x
Prescaler
1, 8, 64, 256
01
00
TCY
Note:
T3CK pin does not exist on dsPIC30F3014/4013 devices. The block diagram shown here illustrates
the schematic of Timer3 as implemented on the 30F6014 device.
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10.1 Timer Gate Operation
10.4 Timer Operation During Sleep
Mode
The 32-bit timer can be placed in the Gated Time Accu-
mulation mode. This mode allows the internal TCY to
increment the respective timer when the gate input sig-
nal (T2CK pin) is asserted high. Control bit TGATE
(T2CON<6>) must be set to enable this mode. When in
this mode, Timer2 is the originating clock source. The
TGATE setting is ignored for Timer3. The timer must be
enabled (TON = 1) and the timer clock source set to
internal (TCS = 0).
During CPU Sleep mode, the timer will not operate
because the internal clocks are disabled.
10.5 Timer Interrupt
The 32-bit timer module can generate an interrupt on
period match or on the falling edge of the external gate
signal. When the 32-bit timer count matches the
respective 32-bit period register, or the falling edge of
the external “gate” signal is detected, the T3IF bit
(IFS0<7>) is asserted and an interrupt will be gener-
ated if enabled. In this mode, the T3IF interrupt flag is
used as the source of the interrupt. The T3IF bit must
be cleared in software.
The falling edge of the external signal terminates the
count operation but does not reset the timer. The user
must reset the timer in order to start counting from zero.
10.2 ADC Event Trigger
When a match occurs between the 32-bit timer (TMR3/
TMR2) and the 32-bit combined period register (PR3/
PR2), a special ADC trigger event signal is generated
by Timer3.
Enabling an interrupt is accomplished via the
respective timer interrupt enable bit, T3IE (IEC0<7>).
10.3 Timer Prescaler
The input clock (FOSC/4 or external clock) to the timer
has a prescale option of 1:1, 1:8, 1:64, and 1:256,
selected by control bits TCKPS<1:0> (T2CON<5:4>
and T3CON<5:4>). For the 32-bit timer operation, the
originating clock source is Timer2. The prescaler oper-
ation for Timer3 is not applicable in this mode. The
prescaler counter is cleared when any of the following
occurs:
• a write to the TMR2/TMR3 register
• a write to the T2CON/T3CON register
• device Reset, such as POR and BOR
However, if the timer is disabled (TON = 0), then the
Timer 2 prescaler cannot be reset since the prescaler
clock is halted.
TMR2/TMR3 is not cleared when T2CON/T3CON is
written.
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The Operating modes of the Timer4/5 module are
determined by setting the appropriate bit(s) in the
16-bit T4CON and T5CON SFRs.
11.0 TIMER4/5 MODULE
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
For 32-bit timer/counter operation, Timer4 is the LS
Word and Timer5 is the MS Word of the 32-bit timer.
Note:
For 32-bit timer operation, T5CON control
bits are ignored. Only T4CON control bits
are used for setup and control. Timer4
clock and gate inputs are utilized for the
32-bit timer module but an interrupt is gen-
erated with the Timer5 interrupt flag (T5IF)
and the interrupt is enabled with the
Timer5 interrupt enable bit (T5IE).
This section describes the second 32-bit General Pur-
pose (GP) Timer module (Timer4/5) and associated
Operational modes. Figure 11-1 depicts the simplified
block diagram of the 32-bit Timer4/5 module.
Figure 11-2 and Figure 11-3 show Timer4/5 configured
as two independent 16-bit timers, Timer4 and Timer5,
respectively.
The Timer4/5 module is similar in operation to the
Timer2/3 module. However, there are some differences
which are listed:
• The Timer4/5 module does not support the ADC
event trigger feature
• Timer4/5 can not be utilized by other peripheral
modules, such as input capture and output compare
FIGURE 11-1:
32-BIT TIMER4/5 BLOCK DIAGRAM
Data Bus<15:0>
TMR5HLD
16
16
Write TMR4
Read TMR4
16
Reset
Sync
TMR5
MSB
TMR4
LSB
Comparator x 32
Equal
PR5
PR4
0
1
T5IF
Event Flag
Q
Q
D
TGATE (T4CON<6>)
CK
TGATE
(T4CON<6>)
TCKPS<1:0>
2
TON
T4CK
1x
Prescaler
Gate
Sync
1, 8, 64, 256
01
00
TCY
Note:
Timer configuration bit T32 (T4CON<3>) must be set to ‘1’ for a 32-bit timer/counter operation. All control
bits are respective to the T4CON register.
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FIGURE 11-2:
16-BIT TIMER4 BLOCK DIAGRAM
PR4
Comparator x 16
TMR4
Equal
Sync
Reset
0
1
T4IF
Event Flag
Q
D
TGATE
Q
CK
TGATE
TCKPS<1:0>
2
TON
T4CK
1x
01
00
Prescaler
Gate
Sync
1, 8, 64, 256
TCY
FIGURE 11-3:
16-BIT TIMER5 BLOCK DIAGRAM
PR5
ADC Event Trigger
Equal
Comparator x 16
TMR5
Reset
0
1
T5IF
Event Flag
Q
D
TGATE
Q
CK
TGATE
TCKPS<1:0>
2
TON
T5CK
1x
Sync
Prescaler
1, 8, 64, 256
01
00
TCY
Note:
In the dsPIC30F3014 device, there is no T5CK pin. Therefore, in this device the following modes should
not be used for Timer5:
1: TCS = 1 (16-bit counter)
2: TCS = 0, TGATE = 1 (gated time accumulation)
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NOTES:
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These Operating modes are determined by setting the
appropriate bits in the ICxCON register (where
x = 1,2,...,N). The dsPIC devices contain up to 8
capture channels (i.e., the maximum value of N is 8).
12.0 INPUT CAPTURE MODULE
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
The dsPIC30F3014 device contains
2
capture
channels while the dsPIC30F4013 device contains 4
capture channels.
This section describes the input capture module and
associated Operational modes. The features provided
by this module are useful in applications requiring fre-
quency (period) and pulse measurement. Figure 12-1
depicts a block diagram of the input capture module.
Input capture is useful for such modes as:
12.1 Simple Capture Event Mode
The simple capture events in the dsPIC30F product
family are:
• Capture every falling edge
• Capture every rising edge
• Frequency/Period/Pulse Measurements
• Additional Sources of External Interrupts
• Capture every 4th rising edge
• Capture every 16th rising edge
• Capture every rising and falling edge
The key operational features of the input capture
module are:
These simple Input Capture modes are configured by
setting the appropriate bits ICM<2:0> (ICxCON<2:0>).
• Simple Capture Event mode
• Timer2 and Timer3 mode selection
• Interrupt on input capture event
12.1.1
CAPTURE PRESCALER
There are four input capture prescaler settings speci-
fied by bits ICM<2:0> (ICxCON<2:0>). Whenever the
capture channel is turned off, the prescaler counter will
be cleared. In addition, any Reset will clear the
prescaler counter.
FIGURE 12-1:
INPUT CAPTURE MODE BLOCK DIAGRAM
T3_CNT
From GP Timer Module
T2_CNT
16
16
ICTMR
1
0
ICx pin
Edge
Detection
Logic
FIFO
R/W
Prescaler
1, 4, 16
Clock
Synchronizer
Logic
ICM<2:0>
Mode Select
3
ICxBUF
ICBNE, ICOV
ICI<1:0>
Interrupt
Logic
ICxCON
Data Bus
Set Flag
ICxIF
Note:
Where ‘x’ is shown, reference is made to the registers or bits associated to the respective input capture
channels 1 through N.
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12.1.2
CAPTURE BUFFER OPERATION
12.2 Input Capture Operation During
Sleep and Idle Modes
Each capture channel has an associated FIFO buffer
which is four 16-bit words deep. There are two status
flags which provide status on the FIFO buffer:
An input capture event will generate a device wake-up
or interrupt, if enabled, if the device is in CPU Idle or
Sleep mode.
• ICBFNE - Input Capture Buffer Not Empty
• ICOV - Input Capture Overflow
Independent of the timer being enabled, the input cap-
ture module will wake-up from the CPU Sleep or Idle
mode when a capture event occurs if ICM<2:0> = 111
and the interrupt enable bit is asserted. The same wake-
up can generate an interrupt if the conditions for pro-
cessing the interrupt have been satisfied. The wake-up
feature is useful as a method of adding extra external pin
interrupts.
The ICBFNE will be set on the first input capture event
and remain set until all capture events have been read
from the FIFO. As each word is read from the FIFO, the
remaining words are advanced by one position within
the buffer.
In the event that the FIFO is full with four capture
events and a fifth capture event occurs prior to a read
of the FIFO, an overflow condition will occur and the
ICOV bit will be set to a logic ‘1’. The fifth capture event
is lost and is not stored in the FIFO. No additional
events will be captured until all four events have been
read from the buffer.
12.2.1
INPUT CAPTURE IN CPU SLEEP
MODE
CPU Sleep mode allows input capture module opera-
tion with reduced functionality. In the CPU Sleep mode,
the ICI<1:0> bits are not applicable and the input cap-
ture module can only function as an external interrupt
source.
If a FIFO read is performed after the last read and no
new capture event has been received, the read will
yield indeterminate results.
The capture module must be configured for interrupt
only on rising edge (ICM<2:0> = 111) in order for the
input capture module to be used while the device is in
Sleep mode. The prescale settings of 4:1 or 16:1 are
not applicable in this mode.
12.1.3
TIMER2 AND TIMER3 SELECTION
MODE
The input capture module consists of up to 8 input cap-
ture channels. Each channel can select between one of
two timers for the time base, Timer2 or Timer3.
12.2.2
INPUT CAPTURE IN CPU IDLE
MODE
Selection of the timer resource is accomplished
through SFR bit, ICTMR (ICxCON<7>). Timer3 is the
default timer resource available for the input capture
module.
CPU Idle mode allows input capture module operation
with full functionality. In the CPU Idle mode, the Inter-
rupt mode selected by the ICI<1:0> bits is applicable,
as well as the 4:1 and 16:1 capture prescale settings
which are defined by control bits ICM<2:0>. This mode
requires the selected timer to be enabled. Moreover,
the ICSIDL bit must be asserted to a logic ‘0’.
12.1.4
HALL SENSOR MODE
When the input capture module is set for capture on
every edge, rising and falling, ICM<2:0> = 001, the
following operations are performed by the input capture
logic:
If the input capture module is defined as
ICM<2:0> = 111 in CPU Idle mode, the input capture
pin will serve only as an external interrupt pin.
• The input capture interrupt flag is set on every
edge, rising and falling.
• The interrupt on Capture mode setting bits,
ICI<1:0>, is ignored since every capture
generates an interrupt.
12.3 Input Capture Interrupts
The input capture channels have the ability to generate
an interrupt based upon the selected number of cap-
ture events. The selection number is set by control bits
ICI<1:0> (ICxCON<6:5>).
• A capture overflow condition is not generated in
this mode.
Each channel provides an interrupt flag (ICxIF) bit. The
respective capture channel interrupt flag is located in
the corresponding IFSx Status register.
Enabling an interrupt is accomplished via the respec-
tive capture channel interrupt enable (ICxIE) bit. The
capture interrupt enable bit is located in the
corresponding IEC Control register.
DS70138C-page 78
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• Simple PWM mode
13.0 OUTPUT COMPARE MODULE
• Output Compare During Sleep and Idle modes
• Interrupt on Output Compare/PWM Event
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
These Operating modes are determined by setting the
appropriate bits in the 16-bit OCxCON SFR (where
x = 1,2,3,...,N). The dsPIC devices contain up to 8
compare channels (i.e., the maximum value of N is 8).
The dsPIC30F3014 device contains 2 compare chan-
nels while the dsPIC30F4013 device contains 4 com-
pare channels.
This section describes the output compare module and
associated Operational modes. The features provided
by this module are useful in applications requiring
Operational modes, such as:
OCxRS and OCxR in Figure 13-1 represent the Dual
Compare registers. In the Dual Compare mode, the
OCxR register is used for the first compare and OCxRS
is used for the second compare.
• Generation of Variable Width Output Pulses
• Power Factor Correction
Figure 13-1 depicts a block diagram of the output
compare module.
13.1 Timer2 and Timer3 Selection Mode
The key operational features of the output compare
module include:
Each output compare channel can select between one
of two 16-bit timers, Timer2 or Timer3.
• Timer2 and Timer3 Selection mode
• Simple Output Compare Match mode
• Dual Output Compare Match mode
The selection of the timers is controlled by the OCTSEL
bit (OCxCON<3>). Timer2 is the default timer resource
for the output compare module.
FIGURE 13-1:
OUTPUT COMPARE MODE BLOCK DIAGRAM
Set Flag bit
OCxIF
OCxRS
Output
S
Q
OCxR
Logic
R
OCx
Output
Enable
3
OCM<2:0>
Mode Select
Comparator
OCFA
OCTSEL
0
1
0
1
(for x = 1, 2, 3 or 4)
or OCFB
(for x = 5, 6, 7 or 8)
From GP
Timer Module
TMR2<15:0
TMR3<15:0> T2P2_MATCH
T3P3_MATCH
Note:
Where ‘x’ is shown, reference is made to the registers associated with the respective output compare
channels 1 through N.
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13.3.2
CONTINUOUS PULSE MODE
13.2 Simple Output Compare Match
Mode
For the user to configure the module for the generation
of a continuous stream of output pulses, the following
steps are required:
When control bits OCM<2:0> (OCxCON<2:0>) = 001,
010 or 011, the selected output compare channel is
configured for one of three simple Output Compare
Match modes:
• Determine instruction cycle time TCY.
• Calculate desired pulse value based on TCY.
• Calculate timer to start pulse width from timer start
value of 0x0000.
• Compare forces I/O pin low
• Compare forces I/O pin high
• Compare toggles I/O pin
• Write pulse width start and stop times into OCxR
and OCxRS (x denotes channel 1, 2, ...,N)
Compare registers, respectively.
The OCxR register is used in these modes. The OCxR
register is loaded with a value and is compared to the
selected incrementing timer count. When a compare
occurs, one of these Compare Match modes occurs. If
the counter resets to zero before reaching the value in
OCxR, the state of the OCx pin remains unchanged.
• Set Timer Period register to value equal to, or
greater than value in OCxRS Compare register.
• Set OCM<2:0> = 101.
• Enable timer, TON (TxCON<15>) = 1.
13.4 Simple PWM Mode
13.3 Dual Output Compare Match Mode
When control bits OCM<2:0> (OCxCON<2:0>) = 110
or 111, the selected output compare channel is config-
ured for the PWM mode of operation. When configured
for the PWM mode of operation, OCxR is the main latch
(read only) and OCxRS is the secondary latch. This
enables glitchless PWM transitions.
When control bits OCM<2:0> (OCxCON<2:0>) = 100
or 101, the selected output compare channel is config-
ured for one of two Dual Output Compare modes,
which are:
• Single Output Pulse mode
• Continuous Output Pulse mode
The user must perform the following steps in order to
configure the output compare module for PWM
operation:
13.3.1
SINGLE PULSE MODE
For the user to configure the module for the generation
of a single output pulse, the following steps are
required (assuming timer is off):
1. Set the PWM period by writing to the appropriate
period register.
2. Set the PWM duty cycle by writing to the OCxRS
register.
• Determine instruction cycle time TCY.
• Calculate desired pulse width value based on TCY.
3. Configure the output compare module for PWM
operation.
• Calculate time to start pulse from timer start value
of 0x0000.
4. Set the TMRx prescale value and enable the
• Write pulse width start and stop times into OCxR
and OCxRS Compare registers (x denotes
channel 1, 2, ...,N).
Timer, TON (TxCON<15>) = 1.
13.4.1
INPUT PIN FAULT PROTECTION
FOR PWM
• Set Timer Period register to value equal to, or
greater than value in OCxRS Compare register.
When control bits OCM<2:0> (OCxCON<2:0>) = 111,
the selected output compare channel is again config-
ured for the PWM mode of operation with the additional
feature of input FAULT protection. While in this mode,
if a logic ‘0’ is detected on the OCFA/B pin, the respec-
tive PWM output pin is placed in the high impedance
input state. The OCFLT bit (OCxCON<4>) indicates
whether a FAULT condition has occurred. This state will
be maintained until both of the following events have
occurred:
• Set OCM<2:0> = 100.
• Enable timer, TON (TxCON<15>) = 1.
To initiate another single pulse, issue another write to
set OCM<2:0> = 100.
• The external FAULT condition has been removed.
• The PWM mode has been re-enabled by writing
to the appropriate control bits.
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When the selected TMRx is equal to its respective
period register, PRx, the following four events occur on
the next increment cycle:
13.4.2
PWM PERIOD
The PWM period is specified by writing to the PRx
register. The PWM period can be calculated using
Equation 13-1.
• TMRx is cleared.
• The OCx pin is set.
EQUATION 13-1:
- Exception 1: If PWM duty cycle is 0x0000,
the OCx pin will remain low.
PWM period = [(PRx) + 1] • 4 • TOSC •
(TMRx prescale value)
- Exception 2: If duty cycle is greater than PRx,
the pin will remain high.
• The PWM duty cycle is latched from OCxRS into
OCxR.
PWM frequency is defined as 1 / [PWM period].
• The corresponding timer interrupt flag is set.
See Figure 13-2 for key PWM period comparisons.
Timer3 is referred to in Figure 13-2 for clarity.
FIGURE 13-2:
PWM OUTPUT TIMING
Period
Duty Cycle
TMR3 = PR3
TMR3 = PR3
T3IF = 1
(Interrupt Flag)
T3IF = 1
(Interrupt Flag)
OCxR = OCxRS
OCxR = OCxRS
TMR3 = Duty Cycle
(OCxR)
TMR3 = Duty Cycle
(OCxR)
13.5 Output Compare Operation During
CPU Sleep Mode
13.7 Output Compare Interrupts
The output compare channels have the ability to gener-
ate an interrupt on a compare match, for whichever
Match mode has been selected.
When the CPU enters Sleep mode, all internal clocks
are stopped. Therefore, when the CPU enters the
Sleep state, the output compare channel will drive the
pin to the active state that was observed prior to
entering the CPU Sleep state.
For all modes except the PWM mode, when a compare
event occurs, the respective interrupt flag (OCxIF) is
asserted and an interrupt will be generated if enabled.
The OCxIF bit is located in the corresponding IFS
Status register and must be cleared in software. The
interrupt is enabled via the respective compare inter-
rupt enable (OCxIE) bit located in the corresponding
IEC Control register.
For example, if the pin was high when the CPU entered
the Sleep state, the pin will remain high. Likewise, if the
pin was low when the CPU entered the Sleep state, the
pin will remain low. In either case, the output compare
module will resume operation when the device wakes
up.
For the PWM mode, when an event occurs, the respec-
tive timer interrupt flag (T2IF or T3IF) is asserted and
an interrupt will be generated if enabled. The IF bit is
located in the IFS0 Status register and must be cleared
in software. The interrupt is enabled via the respective
timer interrupt enable bit (T2IE or T3IE) located in the
IEC0 Control register. The output compare interrupt
flag is never set during the PWM mode of operation.
13.6 Output Compare Operation During
CPU Idle Mode
When the CPU enters the Idle mode, the output
compare module can operate with full functionality.
The output compare channel will operate during the
CPU Idle mode if the OCSIDL bit (OCxCON<13>) is at
logic ‘0’ and the selected time base (Timer2 or Timer3)
is enabled and the TSIDL bit of the selected timer is set
to logic ‘0’.
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In Master mode, the clock is generated by prescaling
the system clock. Data is transmitted as soon as a
value is written to SPIxBUF. The interrupt is generated
at the middle of the transfer of the last bit.
14.0 SPI MODULE
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
In Slave mode, data is transmitted and received as
external clock pulses appear on SCK. Again, the inter-
rupt is generated when the last bit is latched. If SSx
control is enabled, then transmission and reception are
enabled only when SSx = low. The SDOx output will be
disabled in SSx mode with SSx high.
The Serial Peripheral Interface (SPI) module is a syn-
chronous serial interface. It is useful for communicating
with other peripheral devices, such as EEPROMs, shift
registers, display drivers and A/D converters, or other
microcontrollers. It is compatible with Motorola's SPI
and SIOP interfaces. The dsPIC30F3014 and
dsPIC30F4013 devices feature one SPI module, SPI1.
The clock provided to the module is (FOSC/4). This
clock is then prescaled by the primary (PPRE<1:0>)
and the secondary (SPRE<2:0>) prescale factors. The
CKE bit determines whether transmit occurs on transi-
tion from active clock state to Idle clock state, or vice
versa. The CKP bit selects the Idle state (high or low)
for the clock.
14.1 Operating Function Description
Each SPI module consists of a 16-bit shift register,
SPIxSR (where x = 1 or 2) , used for shifting data in and
out, and a buffer register, SPIxBUF. A control register,
SPIxCON, configures the module. Additionally, a status
register, SPIxSTAT, indicates various status conditions.
14.1.1
WORD AND BYTE
COMMUNICATION
A control bit, MODE16 (SPIxCON<10>), allows the
module to communicate in either 16-bit or 8-bit mode.
16-bit operation is identical to 8-bit operation except
that the number of bits transmitted is 16 instead of 8.
The serial interface consists of 4 pins: SDIx (serial data
input), SDOx (serial data output), SCKx (shift clock
input or output), and SSx (active low slave select).
The user software must disable the module prior to
changing the MODE16 bit. The SPI module is reset
when the MODE16 bit is changed by the user.
In Master mode operation, SCK is a clock output but in
Slave mode, it is a clock input.
A series of eight (8) or sixteen (16) clock pulses shift
out bits from the SPIxSR to SDOx pin and simulta-
neously shift in data from SDIx pin. An interrupt is gen-
erated when the transfer is complete and the
corresponding interrupt flag bit (SPI1IF or SPI2IF) is
set. This interrupt can be disabled through an interrupt
enable bit (SPI1IE or SPI2IE).
A basic difference between 8-bit and 16-bit operation is
that the data is transmitted out of bit 7 of the SPIxSR for
8-bit operation, and data is transmitted out of bit15 of
the SPIxSR for 16-bit operation. In both modes, data is
shifted into bit 0 of the SPIxSR.
14.1.2
SDOx DISABLE
The receive operation is double-buffered. When a com-
plete byte is received, it is transferred from SPIxSR to
SPIxBUF.
A control bit, DISSDO, is provided to the SPIxCON reg-
ister to allow the SDOx output to be disabled. This will
allow the SPI module to be connected in an input only
configuration. SDO can also be used for general
purpose I/O.
If the receive buffer is full when new data is being trans-
ferred from SPIxSR to SPIxBUF, the module will set the
SPIROV bit indicating an overflow condition. The trans-
fer of the data from SPIxSR to SPIxBUF will not be
completed and the new data will be lost. The module
will not respond to SCL transitions while SPIROV is ‘1’,
effectively disabling the module until SPIxBUF is read
by user software.
14.2 Framed SPI Support
The module supports a basic framed SPI protocol in
Master or Slave mode. The control bit FRMEN enables
framed SPI support and causes the SSx pin to perform
the frame synchronization pulse (FSYNC) function.
The control bit SPIFSD determines whether the SSx
pin is an input or an output (i.e., whether the module
receives or generates the frame synchronization
pulse). The frame pulse is an active high pulse for a
single SPI clock cycle. When frame synchronization is
enabled, the data transmission starts only on the
subsequent transmit edge of the SPI clock.
Transmit writes are also double-buffered. The user
writes to SPIxBUF. When the master or slave transfer
is completed, the contents of the shift register (SPIxSR)
are moved to the receive buffer. If any transmit data has
been written to the buffer register, the contents of the
transmit buffer are moved to SPIxSR. The received
data is thus placed in SPIxBUF and the transmit data in
SPIxSR is ready for the next transfer.
Note:
Both the transmit buffer (SPIxTXB) and
the receive buffer (SPIxRXB) are mapped
to the same register address, SPIxBUF.
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FIGURE 14-1:
SPI BLOCK DIAGRAM
Internal
Data Bus
Read
Write
SPIxBUF
Transmit
SPIxBUF
Receive
SPIxSR
SDIx
bit 0
SDOx
Shift
Clock
SS and
FSYNC
Control
Clock
Control
Edge
Select
SSx
Primary
Prescaler
1:1, 1:4,
Secondary
Prescaler
1:1-1:8
FCY
1:16, 1:64
SCKx
Enable Master Clock
Note: x = 1 or 2.
FIGURE 14-2:
SPI MASTER/SLAVE CONNECTION
SPI™ Master
SPI™ Slave
SDOx
SDIy
Serial Input Buffer
(SPIxBUF)
Serial Input Buffer
(SPIyBUF)
SDIx
SDOy
Shift Register
Shift Register
(SPIySR)
(SPIxSR)
LSb
MSb
MSb
LSb
Serial Clock
SCKx
SCKy
PROCESSOR 1
PROCESSOR 2
Note: x = 1 or 2, y = 1 or 2.
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14.3 Slave Select Synchronization
14.5 SPI Operation During CPU Idle
Mode
The SSx pin allows a Synchronous Slave mode. The
SPI must be configured in SPI Slave mode with SSx pin
control enabled (SSEN = 1). When the SSx pin is low,
transmission and reception are enabled and the SDOx
pin is driven. When SSx pin goes high, the SDOx pin is
no longer driven. Also, the SPI module is re-
synchronized, and all counters/control circuitry are
reset. Therefore, when the SSx pin is asserted low
again, transmission/reception will begin at the MS bit
even if SSx had been de-asserted in the middle of a
transmit/receive.
When the device enters Idle mode, all clock sources
remain functional. The SPISIDL bit (SPIxSTAT<13>)
selects if the SPI module will stop or continue on Idle. If
SPISIDL = 0, the module will continue to operate when
the CPU enters Idle mode. If SPISIDL = 1, the module
will stop when the CPU enters Idle mode.
14.4 SPI Operation During CPU Sleep
Mode
During Sleep mode, the SPI module is shutdown. If the
CPU enters Sleep mode while an SPI transaction is in
progress, then the transmission and reception is
aborted.
The transmitter and receiver will stop in Sleep mode.
However, register contents are not affected by entering
or exiting Sleep mode.
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2
VARIOUS I C MODES
2
15.0 I C MODULE
15.1.1
2
The following types of I C operation are supported:
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
2
• I C slave operation with 7-bit address
2
• I C slave operation with 10-bit address
2
• I C master operation with 7 or 10-bit address
2
See the I C programmer’s model in Figure 15-1.
2
The Inter-Integrated Circuit (I CTM) module provides
2
PIN CONFIGURATION IN I C MODE
15.1.2
complete hardware support for both Slave and Multi-
2
Master modes of the I C serial communication
2
I C has a 2-pin interface: the SCL pin is clock and the
standard, with a 16-bit interface.
SDA pin is data.
This module offers the following key features:
2
I C REGISTERS
15.1.3
2
• I C interface supporting both master and slave
I2CCON and I2CSTAT are control and status registers,
respectively. The I2CCON register is readable and writ-
able. The lower 6 bits of I2CSTAT are read only. The
remaining bits of the I2CSTAT are read/write.
operation.
2
• I C Slave mode supports 7 and 10-bit address.
2
• I C Master mode supports 7 and 10-bit address.
2
• I C port allows bidirectional transfers between
I2CRSR is the shift register used for shifting data,
whereas I2CRCV is the buffer register to which data
bytes are written, or from which data bytes are read.
I2CRCV is the receive buffer as shown in Figure 15-1.
I2CTRN is the transmit register to which bytes are
written during a transmit operation, as shown in
Figure 15-2.
master and slaves.
2
• Serial clock synchronization for I C port can be
used as a handshake mechanism to suspend and
resume serial transfer (SCLREL control).
2
• I C supports multi-master operation; detects bus
collision and will arbitrate accordingly.
The I2CADD register holds the slave address. A status
bit, ADD10, indicates 10-bit Address mode. The
I2CBRG acts as the baud rate generator reload value.
15.1 Operating Function Description
The hardware fully implements all the master and slave
2
functions of the I C Standard and Fast mode
In receive operations, I2CRSR and I2CRCV together
specifications, as well as 7 and 10-bit addressing.
form
a double-buffered receiver. When I2CRSR
2
Thus, the I C module can operate either as a slave or
receives a complete byte, it is transferred to I2CRCV
and an interrupt pulse is generated. During
transmission, the I2CTRN is not double-buffered.
2
a master on an I C bus.
Note:
Following a RESTART condition in 10-bit
mode, the user only needs to match the
first 7-bit address.
FIGURE 15-1:
PROGRAMMER’S MODEL
I2CRCV (8 bits)
Bit 0
Bit 7
I2CTRN (8 bits)
Bit 0
Bit 7
I2CBRG (9 bits)
Bit 0
Bit 8
I2CCON (16 bits)
Bit 0
Bit 15
Bit 15
I2CSTAT (16 bits)
Bit 0
I2CADD (10 bits)
Bit 0
Bit 9
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2
I C BLOCK DIAGRAM
FIGURE 15-2:
Internal
Data Bus
I2CRCV
Read
Shift
SCL
Clock
I2CRSR
LSB
SDA
Addr_Match
Match Detect
Write
I2CADD
Read
Start and
Stop bit Detect
Write
Start, RESTART,
Stop bit Generate
Read
Collision
Detect
Write
Acknowledge
Generation
Read
Clock
Stretching
Write
I2CTRN
LSB
Shift
Clock
Read
Reload
Control
Write
I2CBRG
BRG Down
Counter
Read
FCY
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2
15.2 I C Module Addresses
15.3.2
SLAVE RECEPTION
If the R_W bit received is a ‘0’ during an address
match, then Receive mode is initiated. Incoming bits
are sampled on the rising edge of SCL. After 8 bits are
received, if I2CRCV is not full or I2COV is not set,
I2CRSR is transferred to I2CRCV. ACK is sent on the
ninth clock.
The I2CADD register contains the Slave mode
addresses. The register is a 10-bit register.
If the A10M bit (I2CCON<10>) is ‘0’, the address is
interpreted by the module as a 7-bit address. When an
address is received, it is compared to the 7 LS bits of
the I2CADD register.
If the RBF flag is set, indicating that I2CRCV is still
holding data from a previous operation (RBF = 1), then
ACK is not sent; however, the interrupt pulse is gener-
ated. In the case of an overflow, the contents of the
I2CRSR are not loaded into the I2CRCV.
If the A10M bit is ‘1’, the address is assumed to be a
10-bit address. When an address is received, it will be
compared with the binary value ‘11110 A9 A8’ (where
A9and A8are two Most Significant bits of I2CADD). If
that value matches, the next address will be compared
with the Least Significant 8 bits of I2CADD, as specified
in the 10-bit addressing protocol.
Note:
The I2CRCV will be loaded if the I2COV
bit = 1and the RBF flag = 0. In this case,
a read of the I2CRCV was performed but
the user did not clear the state of the
I2COV bit before the next receive
occurred. The Acknowledgement is not
sent (ACK = 1) and the I2CRCV is
updated.
2
TABLE 15-1: 7-BIT I C SLAVE ADDRESSES
SUPPORTED BY dsPIC30F
0x00
General call address or start byte
0x01-0x03 Reserved
0x04-0x77 Valid 7-bit addresses
0x78-0x7b Valid 10-bit addresses (lower 7 bits)
2
15.4 I C 10-bit Slave Mode Operation
0x7c-0x7f
Reserved
In 10-bit mode, the basic receive and transmit opera-
tions are the same as in the 7-bit mode. However, the
criteria for address match is more complex.
2
15.3 I C 7-bit Slave Mode Operation
Once enabled (I2CEN = 1), the slave module will wait
2
for a Start bit to occur (i.e., the I C module is ‘Idle’). Fol-
2
The I C specification dictates that a slave must be
lowing the detection of a Start bit, 8 bits are shifted into
I2CRSR and the address is compared against
I2CADD. In 7-bit mode (A10M = 0), bits I2CADD<6:0>
are compared against I2CRSR<7:1> and I2CRSR<0>
is the R_W bit. All incoming bits are sampled on the
rising edge of SCL.
addressed for a write operation with two address bytes
following a Start bit.
The A10M bit is a control bit that signifies that the
address in I2CADD is a 10-bit address rather than a 7-bit
address. The address detection protocol for the first byte
of a message address is identical for 7-bit and 10-bit
messages, but the bits being compared are different.
If an address match occurs, an Acknowledgement will
be sent, and the slave event interrupt flag (SI2CIF) is
set on the falling edge of the ninth (ACK) bit. The
address match does not affect the contents of the
I2CRCV buffer or the RBF bit.
I2CADD holds the entire 10-bit address. Upon receiv-
ing an address following a Start bit, I2CRSR <7:3> is
compared against a literal ‘11110’ (the default 10-bit
address) and I2CRSR<2:1> are compared against
I2CADD<9:8>. If a match occurs and if R_W = 0, the
interrupt pulse is sent. The ADD10 bit will be cleared to
indicate a partial address match. If a match fails or
R_W = 1, the ADD10 bit is cleared and the module
returns to the Idle state.
15.3.1
SLAVE TRANSMISSION
If the R_W bit received is a ‘1’, then the serial port will
go into Transmit mode. It will send ACK on the ninth bit
and then hold SCL to ‘0’ until the CPU responds by writ-
ing to I2CTRN. SCL is released by setting the SCLREL
bit, and 8 bits of data are shifted out. Data bits are
shifted out on the falling edge of SCL, such that SDA is
valid during SCL high. The interrupt pulse is sent on the
falling edge of the ninth clock pulse, regardless of the
status of the ACK received from the master.
The low byte of the address is then received and com-
pared with I2CADD<7:0>. If an address match occurs,
the interrupt pulse is generated and the ADD10 bit is
set, indicating a complete 10-bit address match. If an
address match did not occur, the ADD10 bit is cleared
and the module returns to the Idle state.
15.4.1
10-BIT MODE SLAVE TRANSMISSION
Once a slave is addressed in this fashion with the full
10-bit address (we will refer to this state as
“PRIOR_ADDR_MATCH”), the master can begin
sending data bytes for a slave reception operation.
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Clock stretching takes place following the ninth clock of
the receive sequence. On the falling edge of the ninth
clock at the end of the ACK sequence, if the RBF bit is
set, the SCLREL bit is automatically cleared, forcing
the SCL output to be held low. The user’s ISR must set
the SCLREL bit before reception is allowed to continue.
By holding the SCL line low, the user has time to ser-
15.4.2
10-BIT MODE SLAVE RECEPTION
Once addressed, the master can generate a Repeated
Start, reset the high byte of the address and set the
R_W bit without generating a Stop bit, thus initiating a
slave transmit operation.
15.5 Automatic Clock Stretch
2
vice the ISR and read the contents of the I CRCV
before the master device can initiate another receive
sequence. This will prevent buffer overruns from
occurring.
In the Slave modes, the module can synchronize buffer
reads and write to the master device by clock stretching.
15.5.1
TRANSMIT CLOCK STRETCHING
Note 1: If the user reads the contents of the
I2CRCV, clearing the RBF bit before the
falling edge of the ninth clock, the
SCLREL bit will not be cleared and clock
stretching will not occur.
Both 10-bit and 7-bit Transmit modes implement clock
stretching by asserting the SCLREL bit after the falling
edge of the ninth clock, if the TBF bit is cleared,
indicating the buffer is empty.
In Slave Transmit modes, clock stretching is always
performed irrespective of the STREN bit.
2: The SCLREL bit can be set in software
regardless of the state of the RBF bit. The
user should be careful to clear the RBF bit
in the ISR before the next receive
sequence in order to prevent an overflow
condition.
Clock synchronization takes place following the ninth
clock of the transmit sequence. If the device samples
an ACK on the falling edge of the ninth clock and if the
TBF bit is still clear, then the SCLREL bit is automati-
cally cleared. The SCLREL being cleared to ‘0’ will
assert the SCL line low. The user’s ISR must set the
SCLREL bit before transmission is allowed to continue.
By holding the SCL line low, the user has time to ser-
vice the ISR and load the contents of the I2CTRN
before the master device can initiate another transmit
sequence.
15.5.4
CLOCK STRETCHING DURING
10-BIT ADDRESSING (STREN = 1)
Clock stretching takes place automatically during the
addressing sequence. Because this module has a
register for the entire address, it is not necessary for
the protocol to wait for the address to be updated.
Note 1: If the user loads the contents of I2CTRN,
setting the TBF bit before the falling edge
of the ninth clock, the SCLREL bit will not
be cleared and clock stretching will not
occur.
After the address phase is complete, clock stretching
will occur on each data receive or transmit sequence as
was described earlier.
15.6 Software Controlled Clock
2: The SCLREL bit can be set in software,
Stretching (STREN = 1)
regardless of the state of the TBF bit.
When the STREN bit is ‘1’, the SCLREL bit may be
cleared by software to allow software to control the
clock stretching. The logic will synchronize writes to the
SCLREL bit with the SCL clock. Clearing the SCLREL
bit will not assert the SCL output until the module
detects a falling edge on the SCL output and SCL is
sampled low. If the SCLREL bit is cleared by the user
while the SCL line has been sampled low, the SCL out-
put will be asserted (held low). The SCL output will
remain low until the SCLREL bit is set, and all other
15.5.2
RECEIVE CLOCK STRETCHING
The STREN bit in the I2CCON register can be used to
enable clock stretching in Slave Receive mode. When
the STREN bit is set, the SCL pin will be held low at the
end of each data receive sequence.
15.5.3
CLOCK STRETCHING DURING
7-BIT ADDRESSING (STREN = 1)
When the STREN bit is set in Slave Receive mode, the
SCL line is held low when the buffer register is full. The
method for stretching the SCL output is the same for
both 7 and 10-bit Addressing modes.
2
devices on the I C bus have de-asserted SCL. This
ensures that a write to the SCLREL bit will not violate
the minimum high time requirement for SCL.
If the STREN bit is ‘0’, a software write to the SCLREL
bit will be disregarded and have no effect on the
SCLREL bit.
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2
15.11 I C Master Support
15.7 Interrupts
2
The I C module generates two interrupt flags, MI2CIF
As a master device, six operations are supported:
2
2
(I C Master Interrupt Flag) and SI2CIF (I C Slave Inter-
rupt Flag). The MI2CIF interrupt flag is activated on
completion of a master message event. The SI2CIF
interrupt flag is activated on detection of a message
directed to the slave.
• Assert a Start condition on SDA and SCL.
• Assert a RESTART condition on SDA and SCL.
• Write to the I2CTRN register initiating
transmission of data/address.
• Generate a Stop condition on SDA and SCL.
2
• Configure the I C port to receive data.
15.8 Slope Control
• Generate an ACK condition at the end of a
received byte of data.
2
The I C standard requires slope control on the SDA
and SCL signals for Fast mode (400 kHz). The control
bit, DISSLW, enables the user to disable slew rate
control if desired. It is necessary to disable the slew
rate control for 1 MHz mode.
2
15.12 I C Master Operation
The master device generates all of the serial clock
pulses and the Start and Stop conditions. A transfer is
ended with a Stop condition or with a Repeated Start
condition. Since the Repeated Start condition is also
15.9 IPMI Support
The control bit, IPMIEN, enables the module to support
Intelligent Peripheral Management Interface (IPMI).
When this bit is set, the module accepts and acts upon
all addresses.
2
the beginning of the next serial transfer, the I C bus will
not be released.
In Master Transmitter mode, serial data is output
through SDA, while SCL outputs the serial clock. The
first byte transmitted contains the slave address of the
receiving device (7 bits) and the data direction bit. In
this case, the data direction bit (R_W) is logic ‘0’. Serial
data is transmitted 8 bits at a time. After each byte is
transmitted, an ACK bit is received. Start and Stop con-
ditions are output to indicate the beginning and the end
of a serial transfer.
15.10 General Call Address Support
The general call address can address all devices.
When this address is used, all devices should, in
theory, respond with an Acknowledgement.
The general call address is one of eight addresses
reserved for specific purposes by the I2C protocol. It
consists of all ‘0’s with R_W = 0.
In Master Receive mode, the first byte transmitted con-
tains the slave address of the transmitting device
(7 bits) and the data direction bit. In this case, the data
direction bit (R_W) is logic ‘1’. Thus, the first byte trans-
mitted is a 7-bit slave address, followed by a ‘1’ to indi-
cate receive bit. Serial data is received via SDA while
SCL outputs the serial clock. Serial data is received
8 bits at a time. After each byte is received, an ACK bit
is transmitted. Start and Stop conditions indicate the
beginning and end of transmission.
The general call address is recognized when the Gen-
eral Call Enable (GCEN) bit is set (I2CCON<15> = 1).
Following a Start bit detection, 8 bits are shifted into
I2CRSR and the address is compared with I2CADD,
and is also compared with the general call address
which is fixed in hardware.
If a general call address match occurs, the I2CRSR is
transferred to the I2CRCV after the eighth clock, the
RBF flag is set and on the falling edge of the ninth bit
(ACK bit), the master event interrupt flag (MI2CIF) is
set.
2
15.12.1 I C MASTER TRANSMISSION
Transmission of a data byte, a 7-bit address, or the sec-
ond half of a 10-bit address is accomplished by simply
writing a value to I2CTRN register. The user should
only write to I2CTRN when the module is in a WAIT
state. This action will set the Buffer Full Flag (TBF) and
allow the baud rate generator to begin counting and
start the next transmission. Each bit of address/data
will be shifted out onto the SDA pin after the falling
edge of SCL is asserted. The Transmit Status Flag,
TRSTAT (I2CSTAT<14>), indicates that a master
transmit is in progress.
When the interrupt is serviced, the source for the inter-
rupt can be checked by reading the contents of the
I2CRCV to determine if the address was device
specific or a general call address.
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2
15.12.2 I C MASTER RECEPTION
If a transmit was in progress when the bus collision
occurred, the transmission is halted, the TBF flag is
cleared, the SDA and SCL lines are de-asserted and a
value can now be written to I2CTRN. When the user
Master mode reception is enabled by programming the
2
Receive Enable bit, RCEN (I2CCON<11>). The I C
module must be Idle before the RCEN bit is set, other-
wise the RCEN bit will be disregarded. The baud rate
generator begins counting and on each rollover, the
state of the SCL pin ACK and data are shifted into the
I2CRSR on the rising edge of each clock.
2
services the I C master event Interrupt Service Rou-
2
tine, if the I C bus is free (i.e., the P bit is set), the user
can resume communication by asserting a Start
condition.
If a Start, RESTART, Stop or Acknowledge condition
was in progress when the bus collision occurred, the
condition is aborted, the SDA and SCL lines are
de-asserted, and the respective control bits in the
I2CCON register are cleared to ‘0’. When the user ser-
vices the bus collision Interrupt Service Routine, and if
the I2C bus is free, the user can resume communication
by asserting a Start condition.
15.12.3 BAUD RATE GENERATOR
2
In I C Master mode, the reload value for the BRG is
located in the I2CBRG register. When the BRG is
loaded with this value, the BRG counts down to ‘0’ and
stops until another reload has taken place. If clock arbi-
tration is taking place, for instance, the BRG is reloaded
when the SCL pin is sampled high.
The master will continue to monitor the SDA and SCL
pins, and if a Stop condition occurs, the MI2CIF bit will
be set.
2
As per the I C standard, FSCK may be 100 kHz or
400 kHz. However, the user can specify any baud rate
up to 1 MHz. I2CBRG values of ‘0’ or ‘1’ are illegal.
A write to the I2CTRN will start the transmission of data
at the first data bit regardless of where the transmitter
left off when bus collision occurred.
EQUATION 15-1: SERIAL CLOCK RATE
In a multi-master environment, the interrupt generation
on the detection of Start and Stop conditions allows the
FCY
FCY
)
1,111,111
I2CBRG =
– 1
–
(
FSCK
2
determination of when the bus is free. Control of the I C
bus can be taken when the P bit is set in the I2CSTAT
register, or the bus is Idle and the S and P bits are
cleared.
15.12.4 CLOCK ARBITRATION
Clock arbitration occurs when the master de-asserts
the SCL pin (SCL allowed to float high) during any
receive, transmit, or RESTART/Stop condition. When
the SCL pin is allowed to float high, the baud rate gen-
erator (BRG) is suspended from counting until the SCL
pin is actually sampled high. When the SCL pin is sam-
pled high, the baud rate generator is reloaded with the
contents of I2CBRG and begins counting. This ensures
that the SCL high time will always be at least one BRG
rollover count in the event that the clock is held low by
an external device.
2
15.13 I C Module Operation During CPU
Sleep and Idle Modes
2
15.13.1 I C OPERATION DURING CPU
SLEEP MODE
When the device enters Sleep mode, all clock sources
to the module are shutdown and stay at logic ‘0’. If
Sleep occurs in the middle of a transmission and the
state machine is partially into a transmission as the
clocks stop, then the transmission is aborted. Similarly,
if Sleep occurs in the middle of a reception, then the
reception is aborted.
15.12.5 MULTI-MASTER COMMUNICATION,
BUS COLLISION AND BUS
ARBITRATION
2
15.13.2 I C OPERATION DURING CPU IDLE
Multi-master operation support is achieved by bus arbi-
tration. When the master outputs address/data bits
onto the SDA pin, arbitration takes place when the
master outputs a ‘1’ on SDA by letting SDA float high
while another master asserts a ‘0’. When the SCL pin
floats high, data should be stable. If the expected data
on SDA is a ‘1’ and the data sampled on the SDA
pin = 0, then a bus collision has taken place. The
master will set the MI2CIF pulse and reset the master
MODE
2
For the I C, the I2CSIDL bit selects if the module will
stop on Idle or continue on Idle. If I2CSIDL = 0, the
module will continue operation on assertion of the Idle
mode. If I2CSIDL = 1, the module will stop on Idle.
2
portion of the I C port to its Idle state.
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• One or two Stop bits
16.0 UNIVERSAL ASYNCHRONOUS
RECEIVER TRANSMITTER
(UART) MODULE
• Fully integrated baud rate generator with 16-bit
prescaler
• Baud rates range from 38 bps to 1.875 Mbps at a
30 MHz instruction rate
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
• 4-word deep transmit data buffer
• 4-word deep receive data buffer
• Parity, framing and buffer overrun error detection
• Support for interrupt only on address detect
This section describes the Universal Asynchronous
Receiver/Transmitter Communications module.
(9th bit = 1)
• Separate transmit and receive interrupts
• Loopback mode for diagnostic support
• Two choices of TX/RX pins on UART1 module
16.1 UART Module Overview
The key features of the UART module are:
• Full-duplex, 8 or 9-bit data communication
• Even, odd or no parity options (for 8-bit data)
FIGURE 16-1:
UART TRANSMITTER BLOCK DIAGRAM
Internal Data Bus
Control and Status bits
Write
Write
UTX8 UxTXREG Low Byte
Transmit Control
– Control TSR
– Control Buffer
– Generate Flags
– Generate Interrupt
Load TSR
UxTXIF
UTXBRK
Data
Transmit Shift Register (UxTSR)
‘0’ (Start)
‘1’ (Stop)
UxTX
or UxATX
if ALTIO=1
16x Baud Clock
from Baud Rate
Generator
Parity
Generator
16 Divider
Parity
Control
Signals
Note:
x = 1 or 2.
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FIGURE 16-2:
UART RECEIVER BLOCK DIAGRAM
Internal Data Bus
16
Write
Read
Read Read
Write
UxMODE
UxSTA
UxRXREG Low Byte
URX8
Receive Buffer Control
– Generate Flags
– Generate Interrupt
– Shift Data Characters
8-9
LPBACK
From UxTX
Load RSR
to Buffer
Receive Shift Register
(UxRSR)
1
Control
Signals
0
UxRX
· Start bit Detect
· Parity Check
or UxARX
if ALTIO=1
· Stop bit Detect
· Shift Clock Generation
· Wake Logic
16 Divider
16x Baud Clock from
Baud Rate Generator
UxRXIF
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16.2 Enabling and Setting Up UART
16.3 Transmitting Data
16.2.1
ENABLING THE UART
16.3.1
TRANSMITTING IN 8-BIT DATA
MODE
The UART module is enabled by setting the UARTEN
bit in the UxMODE register (where x = 1 or 2). Once
enabled, the UxTX and UxRX pins are configured as an
output and an input respectively, overriding the TRIS
and LATCH register bit settings for the corresponding
I/O port pins. The UxTX pin is at logic ‘1’ when no
transmission is taking place.
The following steps must be performed in order to
transmit 8-bit data:
1. Set up the UART:
First, the data length, parity and number of Stop
bits must be selected. Then, the transmit and
receive interrupt enable and priority bits are
setup in the UxMODE and UxSTA registers.
Also, the appropriate baud rate value must be
written to the UxBRG register.
16.2.2
DISABLING THE UART
The UART module is disabled by clearing the UARTEN
bit in the UxMODE register. This is the default state
after any Reset. If the UART is disabled, all I/O pins
operate as port pins under the control of the latch and
TRIS bits of the corresponding port pins.
2. Enable the UART by setting the UARTEN bit
(UxMODE<15>).
3. Set the UTXEN bit (UxSTA<10>), thereby
enabling a transmission.
Disabling the UART module resets the buffers to empty
states. Any data characters in the buffers are lost and
the baud rate counter is reset.
4. Write the byte to be transmitted to the lower byte
of UxTXREG. The value will be transferred to the
Transmit Shift register (UxTSR) immediately
and the serial bit stream will start shifting out
during the next rising edge of the baud clock.
Alternatively, the data byte may be written while
UTXEN = 0, following which, the user may set
UTXEN. This will cause the serial bit stream to
begin immediately because the baud clock will
start from a cleared state.
All error and status flags associated with the UART
module are reset when the module is disabled. The
URXDA, OERR, FERR, PERR, UTXEN, UTXBRK and
UTXBF bits are cleared, whereas RIDLE and TRMT
are set. Other control bits, including ADDEN,
URXISEL<1:0>, UTXISEL, as well as the UxMODE
and UxBRG registers, are not affected.
5. A transmit interrupt will be generated, depend-
ing on the value of the interrupt control bit
UTXISEL (UxSTA<15>).
Clearing the UARTEN bit while the UART is active will
abort all pending transmissions and receptions and
reset the module as defined above. Re-enabling the
UART will restart the UART in the same configuration.
16.3.2
TRANSMITTING IN 9-BIT DATA
MODE
16.2.3
ALTERNATE I/O
The sequence of steps involved in the transmission of
9-bit data is similar to 8-bit transmission, except that a
16-bit data word (of which the upper 7 bits are always
clear) must be written to the UxTXREG register.
The alternate I/O function is enabled by setting the
ALTIO bit (UxMODE<10>). If ALTIO = 1, the UxATX
and UxARX pins (alternate transmit and alternate
receive pins, respectively) are used by the UART mod-
ule instead of the UxTX and UxRX pins. If ALTIO = 0,
the UxTX and UxRX pins are used by the UART
module.
16.3.3
TRANSMIT BUFFER (UXTXB)
The transmit buffer is 9 bits wide and 4 characters
deep. Including the Transmit Shift register (UxTSR),
the user effectively has a 5-deep FIFO (First-In, First-
Out) buffer. The UTXBF status bit (UxSTA<9>)
indicates whether the transmit buffer is full.
16.2.4
SETTING UP DATA, PARITY AND
STOP BIT SELECTIONS
Control bits PDSEL<1:0> in the UxMODE register are
used to select the data length and parity used in the
transmission. The data length may either be 8 bits with
even, odd or no parity, or 9 bits with no parity.
If a user attempts to write to a full buffer, the new data
will not be accepted into the FIFO, and no data shift will
occur within the buffer. This enables recovery from a
buffer overrun condition.
The STSEL bit determines whether one or two Stop bits
will be used during data transmission.
The FIFO is reset during any device Reset but is not
affected when the device enters or wakes up from a
Power Saving mode.
The default (power-on) setting of the UART is 8 bits, no
parity and 1 Stop bit (typically represented as 8, N, 1).
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16.3.4
TRANSMIT INTERRUPT
16.4.2
RECEIVE BUFFER (UXRXB)
The transmit interrupt flag (U1TXIF or U2TXIF) is
located in the corresponding interrupt flag register.
The receive buffer is 4 words deep. Including the
Receive Shift register (UxRSR), the user effectively
has a 5-word deep FIFO buffer.
The transmitter generates an edge to set the UxTXIF
bit. The condition for generating the interrupt depends
on the UTXISEL control bit:
URXDA (UxSTA<0>) = 1 indicates that the receive
buffer has data available. URXDA = 0implies that the
buffer is empty. If a user attempts to read an empty
buffer, the old values in the buffer will be read and no
data shift will occur within the FIFO.
a) If UTXISEL = 0, an interrupt is generated when
a word is transferred from the transmit buffer to
the Transmit Shift register (UxTSR). This implies
that the transmit buffer has at least one empty
word.
The FIFO is reset during any device Reset. It is not
affected when the device enters or wakes up from a
Power Saving mode.
b) If UTXISEL = 1, an interrupt is generated when
a word is transferred from the transmit buffer to
the Transmit Shift register (UxTSR) and the
transmit buffer is empty.
16.4.3
RECEIVE INTERRUPT
The receive interrupt flag (U1RXIF or U2RXIF) can be
read from the corresponding interrupt flag register. The
interrupt flag is set by an edge generated by the
receiver. The condition for setting the receive interrupt
flag depends on the settings specified by the
URXISEL<1:0> (UxSTA<7:6>) control bits.
Switching between the two Interrupt modes during
operation is possible and sometimes offers more
flexibility.
16.3.5
TRANSMIT BREAK
a) If URXISEL<1:0> = 00or 01, an interrupt is gen-
erated every time a data word is transferred
from the Receive Shift register (UxRSR) to the
receive buffer. There may be one or more
characters in the receive buffer.
Setting the UTXBRK bit (UxSTA<11>) will cause the
UxTX line to be driven to logic ‘0’. The UTXBRK bit
overrides all transmission activity. Therefore, the user
should generally wait for the transmitter to be Idle
before setting UTXBRK.
b) If URXISEL<1:0> = 10, an interrupt is generated
when a word is transferred from the Receive Shift
register (UxRSR) to the receive buffer, which as a
result of the transfer, contains 3 characters.
To send a break character, the UTXBRK bit must be set
by software and must remain set for a minimum of 13
baud clock cycles. The UTXBRK bit is then cleared by
software to generate Stop bits. The user must wait for
a duration of at least one or two baud clock cycles in
order to ensure a valid Stop bit(s) before reloading the
UxTXB, or starting other transmitter activity. Transmis-
sion of a break character does not generate a transmit
interrupt.
c) If URXISEL<1:0> = 11, an interrupt is set when
a word is transferred from the Receive Shift
register (UxRSR) to the receive buffer, which as
a result of the transfer, contains 4 characters
(i.e., becomes full).
Switching between the Interrupt modes during opera-
tion is possible, though generally not advisable during
normal operation.
16.4 Receiving Data
16.4.1
RECEIVING IN 8-BIT OR 9-BIT
DATA MODE
16.5 Reception Error Handling
The following steps must be performed while receiving
8-bit or 9-bit data:
16.5.1
RECEIVE BUFFER OVERRUN
ERROR (OERR BIT)
1. Set up the UART (see Section 16.3.1).
2. Enable the UART (see Section 16.3.1).
The OERR bit (UxSTA<1>) is set if all of the following
conditions occur:
3. A receive interrupt will be generated when one
or more data words have been received,
depending on the receive interrupt settings
specified by the URXISEL bits (UxSTA<7:6>).
a) The receive buffer is full.
b) The Receive Shift register is full, but unable to
transfer the character to the receive buffer.
4. Read the OERR bit to determine if an overrun
error has occurred. The OERR bit must be reset
in software.
c) The Stop bit of the character in the UxRSR is
detected, indicating that the UxRSR needs to
transfer the character to the buffer.
5. Read the received data from UxRXREG. The act
of reading UxRXREG will move the next word to
the top of the receive FIFO, and the PERR and
FERR values will be updated.
Once OERR is set, no further data is shifted in UxRSR
(until the OERR bit is cleared in software or a Reset
occurs). The data held in UxRSR and UxRXREG
remains valid.
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16.5.2
FRAMING ERROR (FERR)
16.6 Address Detect Mode
The FERR bit (UxSTA<2>) is set if a ‘0’ is detected
instead of a Stop bit. If two Stop bits are selected, both
Stop bits must be ‘1’, otherwise FERR will be set. The
read only FERR bit is buffered along with the received
data. It is cleared on any Reset.
Setting the ADDEN bit (UxSTA<5>) enables this spe-
cial mode in which a 9th bit (URX8) value of ‘1’ identi-
fies the received word as an address, rather than data.
This mode is only applicable for 9-bit data communica-
tion. The URXISEL control bit does not have any
impact on interrupt generation in this mode since an
interrupt (if enabled) will be generated every time the
received word has the 9th bit set.
16.5.3
PARITY ERROR (PERR)
The PERR bit (UxSTA<3>) is set if the parity of the
received word is incorrect. This error bit is applicable
only if a Parity mode (odd or even) is selected. The
read only PERR bit is buffered along with the received
data bytes. It is cleared on any Reset.
16.7 Loopback Mode
Setting the LPBACK bit enables this special mode in
which the UxTX pin is internally connected to the UxRX
pin. When configured for the Loopback mode, the
UxRX pin is disconnected from the internal UART
receive logic. However, the UxTX pin still functions as
in a normal operation.
16.5.4
IDLE STATUS
When the receiver is active (i.e., between the initial
detection of the Start bit and the completion of the Stop
bit), the RIDLE bit (UxSTA<4>) is ‘0’. Between the com-
pletion of the Stop bit and detection of the next Start bit,
the RIDLE bit is ‘1’, indicating that the UART is Idle.
To select this mode:
a) Configure UART for desired mode of operation.
b) Set LPBACK = 1to enable Loopback mode.
c) Enable transmission as defined in Section 16.3.
16.5.5
RECEIVE BREAK
The receiver will count and expect a certain number of
bit times based on the values programmed in the
PDSEL (UxMODE<2:1>) and STSEL (UxMODE<0>)
bits.
16.8 Baud Rate Generator
The UART has a 16-bit baud rate generator to allow
maximum flexibility in baud rate generation. The baud
rate generator register (UxBRG) is readable and
writable. The baud rate is computed as follows:
If the break is longer than 13 bit times, the reception is
considered complete after the number of bit times
specified by PDSEL and STSEL. The URXDA bit is set,
FERR is set, zeros are loaded into the receive FIFO,
interrupts are generated if appropriate and the RIDLE
bit is set.
BRG = 16-bit value held in UxBRG register
(0 through 65535)
FCY = Instruction Clock Rate (1/TCY)
When the module receives a long break signal and the
receiver has detected the Start bit, the data bits and the
invalid Stop bit (which sets the FERR), the receiver
must wait for a valid Stop bit before looking for the next
Start bit. It cannot assume that the break condition on
the line is the next Start bit.
The Baud Rate is given by Equation 16-1.
EQUATION 16-1: BAUD RATE
Baud Rate = FCY / (16*(BRG+1))
Break is regarded as a character containing all ‘0’s with
the FERR bit set. The break character is loaded into the
buffer. No further reception can occur until a Stop bit is
received. Note that RIDLE goes high when the Stop bit
has not yet been received.
Therefore, the maximum baud rate possible is
FCY /16 (if BRG = 0),
and the minimum baud rate possible is
FCY / (16* 65536).
With a full 16-bit baud rate generator at 30 MIPs
operation, the minimum baud rate achievable is
28.5 bps.
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16.10.2 UART OPERATION DURING CPU
IDLE MODE
16.9 Auto Baud Support
To allow the system to determine baud rates of
received characters, the input can be optionally linked
to a capture input (IC1 for UART1, IC2 for UART2). To
enable this mode, the user must program the input
capture module to detect the falling and rising edges of
the Start bit.
For the UART, the USIDL bit selects if the module will
stop operation when the device enters Idle mode or
whether the module will continue on Idle. If USIDL = 0,
the module will continue operation during Idle mode. If
USIDL = 1, the module will stop on Idle.
16.10 UART Operation During CPU
Sleep and Idle Modes
16.10.1 UART OPERATION DURING CPU
SLEEP MODE
When the device enters Sleep mode, all clock sources
to the module are shutdown and stay at logic ‘0’. If entry
into Sleep mode occurs while a transmission is in
progress, then the transmission is aborted. The UxTX
pin is driven to logic ‘1’. Similarly, if entry into Sleep
mode occurs while a reception is in progress, then the
reception is aborted. The UxSTA, UxMODE, transmit
and receive registers and buffers, and the UxBRG
register are not affected by Sleep mode.
If the WAKE bit (UxMODE<7>) is set before the device
enters Sleep mode, then a falling edge on the UxRX pin
will generate a receive interrupt. The Receive Interrupt
Select mode bit (URXISEL) has no effect for this func-
tion. If the receive interrupt is enabled, then this will
wake-up the device from Sleep. The UARTEN bit must
be set in order to generate a wake-up interrupt.
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NOTES:
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The CAN bus module consists of a protocol engine and
message buffering/control. The CAN protocol engine
handles all functions for receiving and transmitting
messages on the CAN bus. Messages are transmitted
by first loading the appropriate data registers. Status
and errors can be checked by reading the appropriate
registers. Any message detected on the CAN bus is
checked for errors and then matched against filters to
see if it should be received and stored in one of the
receive registers.
17.0 CAN MODULE
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
17.1 Overview
The Controller Area Network (CAN) module is a serial
interface, useful for communicating with other CAN
modules or microcontroller devices. This interface/
protocol was designed to allow communications within
noisy environments.
17.2 Frame Types
The CAN module transmits various types of frames
which include data messages or remote transmission
requests initiated by the user, as other frames that are
automatically generated for control purposes. The
following frame types are supported:
The CAN module is a communication controller imple-
menting the CAN 2.0 A/B protocol, as defined in the
BOSCH specification. The module will support
CAN 1.2, CAN 2.0A, CAN 2.0B Passive, and CAN 2.0B
Active versions of the protocol. The module implemen-
tation is a full CAN system. The CAN specification is
not covered within this data sheet. The reader may
refer to the BOSCH CAN specification for further
details.
• Standard Data Frame:
A standard data frame is generated by a node
when the node wishes to transmit data. It includes
an 11-bit standard identifier (SID) but not an 18-bit
extended identifier (EID).
• Extended Data Frame:
The module features are as follows:
An extended data frame is similar to a standard
data frame but includes an extended identifier as
well.
• Implementation of the CAN protocol CAN 1.2,
CAN 2.0A and CAN 2.0B
• Standard and extended data frames
• 0-8 bytes data length
• Remote Frame:
It is possible for a destination node to request the
data from the source. For this purpose, the desti-
nation node sends a remote frame with an identi-
fier that matches the identifier of the required data
frame. The appropriate data source node will then
send a data frame as a response to this remote
request.
• Programmable bit rate up to 1 Mbit/sec
• Support for remote frames
• Double-buffered receiver with two prioritized
received message storage buffers (each buffer
may contain up to 8 bytes of data)
• 6 full (standard/extended identifier) acceptance
filters, 2 associated with the high priority receive
buffer and 4 associated with the low priority
receive buffer
• Error Frame:
An error frame is generated by any node that
detects a bus error. An error frame consists of 2
fields: an error flag field and an error delimiter
field.
• 2 full acceptance filter masks, one each
associated with the high and low priority receive
buffers
• Overload Frame:
• Three transmit buffers with application specified
prioritization and abort capability (each buffer may
contain up to 8 bytes of data)
An overload frame can be generated by a node as
a result of 2 conditions. First, the node detects a
dominant bit during interframe space which is an
illegal condition. Second, due to internal condi-
tions, the node is not yet able to start reception of
the next message. A node may generate a maxi-
mum of 2 sequential overload frames to delay the
start of the next message.
• Programmable wake-up functionality with
integrated low-pass filter
• Programmable Loopback mode supports self-test
operation
• Signaling via interrupt capabilities for all CAN
receiver and transmitter error states
• Interframe Space:
• Programmable clock source
Interframe space separates a proceeding frame
(of whatever type) from a following data or remote
frame.
• Programmable link to Input Capture module (IC2,
for both CAN1 and CAN2) for time-stamping and
network synchronization
• Low power Sleep and Idle mode
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FIGURE 17-1:
CAN BUFFERS AND PROTOCOL ENGINE BLOCK DIAGRAM
Acceptance Mask
RXM1
BUFFERS
Acceptance Filter
RXF2
A
c
c
e
p
t
Acceptance Mask
RXM0
Acceptance Filter
RXF3
TXB0
TXB1
TXB2
A
c
c
e
p
t
Acceptance Filter
RXF0
Acceptance Filter
RXF4
Acceptance Filter
RXF1
Acceptance Filter
RXF5
R
X
B
0
R
X
B
1
M
A
B
Identifier
Identifier
Message
Queue
Control
Transmit Byte Sequencer
Data Field
Data Field
Receive
RERRCNT
TERRCNT
Error
Counter
PROTOCOL
ENGINE
Transmit
Error
Err Pas
Bus Off
Counter
Transmit Shift
Receive Shift
Protocol
Finite
CRC Check
CRC Generator
State
Machine
Bit
Timing
Logic
Transmit
Logic
Bit Timing
Generator
(1)
(1)
CiTX
CiRX
Note 1: i = 1 or 2 refers to a particular CAN module (CAN1 or CAN2).
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The module can be programmed to apply a low-pass
filter function to the CiRX input line while the module or
the CPU is in Sleep mode. The WAKFIL bit
(CiCFG2<14>) enables or disables the filter.
17.3 Modes of Operation
The CAN module can operate in one of several Operation
modes selected by the user. These modes include:
• Initialization Mode
• Disable Mode
Note:
Typically, if the CAN module is allowed to
transmit in a particular mode of operation
and a transmission is requested immedi-
ately after the CAN module has been
placed in that mode of operation, the mod-
ule waits for 11 consecutive recessive bits
on the bus before starting transmission. If
the user switches to Disable Mode within
this 11-bit period, then this transmission is
aborted and the corresponding TXABT bit
is set and TXREQ bit is cleared.
• Normal Operation Mode
• Listen Only Mode
• Loopback Mode
• Error Recognition Mode
Modes are requested by setting the REQOP<2:0> bits
(CiCTRL<10:8>), except the Error Recognition mode
which is requested through the RXM<1:0> bits
(CiRXnCON<6:5>, where n = 0 or 1 represents a par-
ticular receive buffer). Entry into a mode is Acknowl-
edged by monitoring the OPMODE<2:0> bits
(CiCTRL<7:5>). The module will not change the mode
and the OPMODE bits until a change in mode is
acceptable, generally during bus Idle time which is
defined as at least 11 consecutive recessive bits.
17.3.3
NORMAL OPERATION MODE
Normal Operating mode is selected when
REQOP<2:0> = 000. In this mode, the module is acti-
vated and the I/O pins will assume the CAN bus func-
tions. The module will transmit and receive CAN bus
messages via the CxTX and CxRX pins.
17.3.1
INITIALIZATION MODE
In the Initialization mode, the module will not transmit or
receive. The error counters are cleared and the inter-
rupt flags remain unchanged. The programmer will
have access to configuration registers that are access
restricted in other modes. The module will protect the
user from accidentally violating the CAN protocol
through programming errors. All registers which control
the configuration of the module can not be modified
while the module is on-line. The CAN module will not
be allowed to enter the Configuration mode while a
transmission is taking place. The Configuration mode
serves as a lock to protect the following registers.
17.3.4
LISTEN ONLY MODE
If the Listen Only mode is activated, the module on the
CAN bus is passive. The transmitter buffers revert to
the port I/O function. The receive pins remain inputs.
For the receiver, no error flags or Acknowledge signals
are sent. The error counters are deactivated in this
state. The Listen Only mode can be used for detecting
the baud rate on the CAN bus. To use this, it is neces-
sary that there are at least two further nodes that
communicate with each other.
17.3.5
LISTEN ALL MESSAGES MODE
• All Module Control Registers
• Baud Rate and Interrupt Configuration Registers
• Bus Timing Registers
The module can be set to ignore all errors and receive
any message. The Listen All Messages mode is acti-
vated by setting the REQOP<2:0> bits to ‘111’. In this
mode, the data which is in the message assembly
buffer until the time an error occurred, is copied in the
receive buffer and can be read via the CPU interface.
• Identifier Acceptance Filter Registers
• Identifier Acceptance Mask Registers
17.3.2
DISABLE MODE
In Disable mode, the module will not transmit or
receive. The module has the ability to set the WAKIF bit
due to bus activity, however, any pending interrupts will
remain and the error counters will retain their value.
17.3.6
LOOPBACK MODE
If the Loopback mode is activated, the module will con-
nect the internal transmit signal to the internal receive
signal at the module boundary. The transmit and
receive pins revert to their port I/O function.
If the REQOP<2:0> bits (CiCTRL<10:8>) = 001, the
module will enter the Module Disable mode. If the module
is active, the module will wait for 11 recessive bits on the
CAN bus, detect that condition as an Idle bus, then
accept the module disable command. When the
OPMODE<2:0> bits (CiCTRL<7:5>) = 001, that indi-
cates whether the module successfully went into Module
Disable mode. The I/O pins will revert to normal I/O
function when the module is in the Module Disable mode.
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17.4.4
RECEIVE OVERRUN
17.4 Message Reception
An overrun condition occurs when the Message
Assembly Buffer (MAB) has assembled valid
17.4.1
RECEIVE BUFFERS
a
The CAN bus module has 3 receive buffers. However,
one of the receive buffers is always committed to mon-
itoring the bus for incoming messages. This buffer is
called the Message Assembly Buffer (MAB). So there
are 2 receive buffers visible, RXB0 and RXB1, that can
received message, the message is accepted through
the acceptance filters, and when the receive buffer
associated with the filter has not been designated as
clear of the previous message.
The overrun error flag, RXnOVR (CiINTF<15> or
CiINTF<14>), and the ERRIF bit (CiINTF<5>) will be
set and the message in the MAB will be discarded.
essentially instantaneously receive
message from the protocol engine.
a
complete
All messages are assembled by the MAB and are trans-
ferred to the RXBn buffers only if the acceptance filter
criterion are met. When a message is received, the
RXnIF flag (CiINTF<0> or CiINRF<1>) will be set. This
bit can only be set by the module when a message is
received. The bit is cleared by the CPU when it has com-
pleted processing the message in the buffer. If the
RXnIE bit (CiINTE<0> or CiINTE<1>) is set, an interrupt
will be generated when a message is received.
If the DBEN bit is clear, RXB1 and RXB0 operate inde-
pendently. When this is the case, a message intended
for RXB0 will not be diverted into RXB1 if RXB0 con-
tains an unread message and the RX0OVR bit will be
set.
If the DBEN bit is set, the overrun for RXB0 is handled
differently. If a valid message is received for RXB0 and
RXFUL = 1indicates that RXB0 is full and RXFUL = 0
indicates that RXB1 is empty, the message for RXB0
will be loaded into RXB1. An overrun error will not be
generated for RXB0. If a valid message is received for
RXB0 and RXFUL = 1, indicating that both RXB0 and
RXB1 are full, the message will be lost and an overrun
will be indicated for RXB1.
RXF0 and RXF1 filters with RXM0 mask are associated
with RXB0. The filters RXF2, RXF3, RXF4, and RXF5
and the mask RXM1 are associated with RXB1.
17.4.2
MESSAGE ACCEPTANCE FILTERS
The message acceptance filters and masks are used to
determine if a message in the message assembly
buffer should be loaded into either of the receive buff-
ers. Once a valid message has been received into the
Message Assembly Buffer (MAB), the identifier fields of
the message are compared to the filter values. If there
is a match, that message will be loaded into the
appropriate receive buffer.
17.4.5
RECEIVE ERRORS
The CAN module will detect the following receive
errors:
• Cyclic Redundancy Check (CRC) Error
• Bit Stuffing Error
• Invalid Message Receive Error
The acceptance filter looks at incoming messages for
the RXIDE bit (CiRXnSID<0>) to determine how to
compare the identifiers. If the RXIDE bit is clear, the
message is a standard frame and only filters with the
EXIDE bit (CiRXFnSID<0>) clear are compared. If the
RXIDE bit is set, the message is an extended frame,
and only filters with the EXIDE bit set are compared.
Configuring the RXM<1:0> bits to ‘01’ or ‘10’ can
override the EXIDE bit.
These receive errors do not generate an interrupt.
However, the receive error counter is incremented by
one in case one of these errors occur. The RXWAR bit
(CiINTF<9>) indicates that the receive error counter
has reached the CPU warning limit of 96 and an
interrupt is generated.
17.4.6
RECEIVE INTERRUPTS
Receive interrupts can be divided into 3 major groups,
each including various conditions that generate
interrupts:
17.4.3
MESSAGE ACCEPTANCE FILTER
MASKS
• Receive Interrupt:
The mask bits essentially determine which bits to apply
the filter to. If any mask bit is set to a zero, then that bit
will automatically be accepted regardless of the filter
bit. There are 2 programmable acceptance filter masks
associated with the receive buffers, one for each buffer.
A message has been successfully received and
loaded into one of the receive buffers. This inter-
rupt is activated immediately after receiving the
End of Frame (EOF) field. Reading the RXnIF flag
will indicate which receive buffer caused the
interrupt.
• Wake-up Interrupt:
The CAN module has woken up from Disable
mode or the device has woken up from Sleep
mode.
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• Receive Error Interrupts:
Setting TXREQ bit simply flags a message buffer as
enqueued for transmission. When the module detects
an available bus, it begins transmitting the message
which has been determined to have the highest priority.
A receive error interrupt will be indicated by the
ERRIF bit. This bit shows that an error condition
occurred. The source of the error can be deter-
mined by checking the bits in the CAN Interrupt
Status register, CiINTF.
If the transmission completes successfully on the first
attempt, the TXREQ bit is cleared automatically, and an
interrupt is generated if TXIE was set.
- Invalid Message Received:
If the message transmission fails, one of the error con-
dition flags will be set, and the TXREQ bit will remain
set indicating that the message is still pending for trans-
mission. If the message encountered an error condition
during the transmission attempt, the TXERR bit will be
set, and the error condition may cause an interrupt. If
the message loses arbitration during the transmission
attempt, the TXLARB bit is set. No interrupt is
generated to signal the loss of arbitration.
If any type of error occurred during reception of
the last message, an error will be indicated by
the IVRIF bit.
- Receiver Overrun:
The RXnOVR bit indicates that an overrun
condition occurred.
- Receiver Warning:
The RXWAR bit indicates that the receive error
counter (RERRCNT<7:0>) has reached the
warning limit of 96.
17.5.4
ABORTING MESSAGE
TRANSMISSION
- Receiver Error Passive:
The system can also abort a message by clearing the
TXREQ bit associated with each message buffer. Set-
ting the ABAT bit (CiCTRL<12>) will request an abort of
all pending messages. If the message has not yet
started transmission, or if the message started but is
interrupted by loss of arbitration or an error, the abort
will be processed. The abort is indicated when the
module sets the TXABT bit and the TXnIF flag is not
automatically set.
The RXEP bit indicates that the receive error
counter has exceeded the error passive limit of
127 and the module has gone into error passive
state.
17.5 Message Transmission
17.5.1
TRANSMIT BUFFERS
The CAN module has three transmit buffers. Each of
the three buffers occupies 14 bytes of data. Eight of the
bytes are the maximum 8 bytes of the transmitted mes-
sage. Five bytes hold the standard and extended
identifiers and other message arbitration information.
17.5.5
TRANSMISSION ERRORS
The CAN module will detect the following transmission
errors:
• Acknowledge Error
• Form Error
17.5.2
TRANSMIT MESSAGE PRIORITY
• Bit Error
Transmit priority is a prioritization within each node of
the pending transmittable messages. There are
4 levels of transmit priority. If TXPRI<1:0>
(CiTXnCON<1:0>, where n = 0, 1 or 2 represents a par-
ticular transmit buffer) for a particular message buffer is
set to ‘11’, that buffer has the highest priority. If
TXPRI<1:0> for a particular message buffer is set to
‘10’ or ‘01’, that buffer has an intermediate priority. If
TXPRI<1:0> for a particular message buffer is ‘00’, that
buffer has the lowest priority.
These transmission errors will not necessarily generate
an interrupt but are indicated by the transmission error
counter. However, each of these errors will cause the
transmission error counter to be incremented by one.
Once the value of the error counter exceeds the value
of 96, the ERRIF (CiINTF<5>) and the TXWAR bit
(CiINTF<10>) are set. Once the value of the error
counter exceeds the value of 96, an interrupt is
generated and the TXWAR bit in the Error Flag register
is set.
17.5.3
TRANSMISSION SEQUENCE
To initiate transmission of the message, the TXREQ bit
(CiTXnCON<3>) must be set. The CAN bus module
resolves any timing conflicts between setting of the
TXREQ bit and the Start of Frame (SOF), ensuring that if
the priority was changed, it is resolved correctly before the
SOF occurs. When TXREQ is set, the TXABT
(CiTXnCON<6>), TXLARB (CiTXnCON<5>) and TXERR
(CiTXnCON<4>) flag bits are automatically cleared.
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17.5.6
TRANSMIT INTERRUPTS
17.6 Baud Rate Setting
Transmit interrupts can be divided into 2 major groups,
each including various conditions that generate
interrupts:
All nodes on any particular CAN bus must have the
same nominal bit rate. In order to set the baud rate, the
following parameters have to be initialized:
• Transmit Interrupt:
• Synchronization Jump Width
• Baud Rate Prescaler
At least one of the three transmit buffers is empty
(not scheduled) and can be loaded to schedule a
message for transmission. Reading the TXnIF
flags will indicate which transmit buffer is available
and caused the interrupt.
• Phase Segments
• Length determination of Phase Segment 2
• Sample Point
• Propagation Segment bits
• Transmit Error Interrupts:
A transmission error interrupt will be indicated by
the ERRIF flag. This flag shows that an error con-
dition occurred. The source of the error can be
determined by checking the error flags in the CAN
Interrupt Status register, CiINTF. The flags in this
register are related to receive and transmit errors.
17.6.1
BIT TIMING
All controllers on the CAN bus must have the same
baud rate and bit length. However, different controllers
are not required to have the same master oscillator
clock. At different clock frequencies of the individual
controllers, the baud rate has to be adjusted by
adjusting the number of time quanta in each segment.
- Transmitter Warning Interrupt:
The TXWAR bit indicates that the transmit error
counter has reached the CPU warning limit of
96.
The nominal bit time can be thought of as being divided
into separate non-overlapping time segments. These
segments are shown in Figure 17-2.
- Transmitter Error Passive:
•
•
•
•
Synchronization Segment (Sync Seg)
Propagation Time Segment (Prop Seg)
Phase Segment 1 (Phase1 Seg)
Phase Segment 2 (Phase2 Seg)
The TXEP bit (CiINTF<12>) indicates that the
transmit error counter has exceeded the error
passive limit of 127 and the module has gone to
error passive state.
The time segments and also the nominal bit time are
made up of integer units of time called time quanta or
TQ. By definition, the nominal bit time has a minimum
of 8 TQ and a maximum of 25 TQ. Also, by definition,
the minimum nominal bit time is 1 µsec corresponding
to a maximum bit rate of 1 MHz.
- Bus Off:
The TXBO bit (CiINTF<13>) indicates that the
transmit error counter has exceeded 255 and
the module has gone to the bus off state.
FIGURE 17-2:
CAN BIT TIMING
Input Signal
Prop
Phase
Segment 1
Phase
Sync
Sync
Segment
Segment 2
Sample Point
TQ
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17.6.2
PRESCALER SETTING
17.6.5
SAMPLE POINT
There is a programmable prescaler with integral values
ranging from 1 to 64, in addition to a fixed divide-by-2
for clock generation. The time quantum (TQ) is a fixed
unit of time derived from the oscillator period, and is
given by Equation 17-1, where FCAN is FCY (if the
CANCKS bit is set) or 4FCY (if CANCKS is clear).
The sample point is the point of time at which the bus
level is read and interpreted as the value of that respec-
tive bit. The location is at the end of Phase1 Seg. If the
bit timing is slow and contains many TQ, it is possible to
specify multiple sampling of the bus line at the sample
point. The level determined by the CAN bus then corre-
sponds to the result from the majority decision of three
values. The majority samples are taken at the sample
point and twice before with a distance of TQ/2. The
CAN module allows the user to choose between sam-
pling three times at the same point or once at the same
point, by setting or clearing the SAM bit (CiCFG2<6>).
Note:
FCAN must not exceed 30 MHz. If
CANCKS = 0, then FCY must not exceed
7.5 MHz.
EQUATION 17-1: TIME QUANTUM FOR
CLOCK GENERATION
Typically, the sampling of the bit should take place at
about 60 - 70% through the bit time, depending on the
system parameters.
TQ = 2 (BRP<5:0> + 1) / FCAN
17.6.6
SYNCHRONIZATION
17.6.3
PROPAGATION SEGMENT
To compensate for phase shifts between the oscillator
frequencies of the different bus stations, each CAN
controller must be able to synchronize to the relevant
signal edge of the incoming signal. When an edge in
the transmitted data is detected, the logic will compare
the location of the edge to the expected time (Synchro-
nous Segment). The circuit will then adjust the values
of Phase1 Seg and Phase2 Seg. There are 2
mechanisms used to synchronize.
This part of the bit time is used to compensate physical
delay times within the network. These delay times con-
sist of the signal propagation time on the bus line and
the internal delay time of the nodes. The Prop Seg can
be programmed from 1 TQ to 8 TQ by setting the
PRSEG<2:0> bits (CiCFG2<2:0>).
17.6.4
PHASE SEGMENTS
The phase segments are used to optimally locate the
sampling of the received bit within the transmitted bit
time. The sampling point is between Phase1 Seg and
Phase2 Seg. These segments are lengthened or short-
ened by resynchronization. The end of the Phase1 Seg
determines the sampling point within a bit period. The
segment is programmable from 1 TQ to 8 TQ. Phase2
Seg provides delay to the next transmitted data transi-
tion. The segment is programmable from 1 TQ to 8 TQ,
or it may be defined to be equal to the greater of
Phase1 Seg or the information processing time (2 TQ).
The Phase1 Seg is initialized by setting bits
SEG1PH<2:0> (CiCFG2<5:3>), and Phase2 Seg is
initialized by setting SEG2PH<2:0> (CiCFG2<10:8>).
17.6.6.1
Hard Synchronization
Hard synchronization is only done whenever there is a
‘recessive’ to ‘dominant’ edge during bus Idle indicating
the start of a message. After hard synchronization, the
bit time counters are restarted with the Sync Seg. Hard
synchronization forces the edge which has caused the
hard synchronization to lie within the synchronization
segment of the restarted bit time. If a hard synchroniza-
tion is done, there will not be a resynchronization within
that bit time.
17.6.6.2
Resynchronization
As a result of resynchronization, Phase1 Seg may be
lengthened or Phase2 Seg may be shortened. The
amount of lengthening or shortening of the phase
buffer segment has an upper bound known as the syn-
chronization jump width, and is specified by the
SJW<1:0> bits (CiCFG1<7:6>). The value of the syn-
chronization jump width will be added to Phase1 Seg or
subtracted from Phase2 Seg. The resynchronization
jump width is programmable between 1 TQ and 4 TQ.
The following requirement must be fulfilled while setting
the lengths of the phase segments:
Prop Seg + Phase1 Seg > = Phase2 Seg
The following requirement must be fulfilled while setting
the SJW<1:0> bits:
Phase2 Seg > Synchronization Jump Width
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18.2.3
CSDI PIN
18.0 DATA CONVERTER
INTERFACE (DCI) MODULE
The serial data input (CSDI) pin is configured as an
input only pin when the module is enabled.
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
18.2.3.1
COFS PIN
The Codec frame synchronization (COFS) pin is used
to synchronize data transfers that occur on the CSDO
and CSDI pins. The COFS pin may be configured as an
input or an output. The data direction for the COFS pin
is determined by the COFSD control bit in the
DCICON1 register.
18.1 Module Introduction
The dsPIC30F Data Converter Interface (DCI) module
allows simple interfacing of devices, such as audio
coder/decoders (Codecs), A/D converters and D/A
converters. The following interfaces are supported:
The DCI module accesses the shadow registers while
the CPU is in the process of accessing the memory
mapped buffer registers.
• Framed Synchronous Serial Transfer (Single or
Multi-Channel)
18.2.4
BUFFER DATA ALIGNMENT
2
• Inter-IC Sound (I S) Interface
Data values are always stored left justified in the buff-
ers since most Codec data is represented as a signed
2’s complement fractional number. If the received word
length is less than 16 bits, the unused LS bits in the
receive buffer registers are set to ‘0’ by the module. If
the transmitted word length is less than 16 bits, the
unused LS bits in the transmit buffer register are
ignored by the module. The word length setup is
described in subsequent sections of this document.
• AC-Link Compliant mode
The DCI module provides the following general
features:
• Programmable word size up to 16 bits
• Support for up to 16 time slots, for a maximum
frame size of 256 bits
• Data buffering for up to 4 samples without CPU
overhead
18.2.5
TRANSMIT/RECEIVE SHIFT
REGISTER
18.2 Module I/O Pins
The DCI module has a 16-bit shift register for shifting
serial data in and out of the module. Data is shifted in/
out of the shift register MS bit first, since audio PCM
data is transmitted in signed 2’s complement format.
There are four I/O pins associated with the module.
When enabled, the module controls the data direction
of each of the four pins.
18.2.1
CSCK PIN
18.2.6
DCI BUFFER CONTROL
The CSCK pin provides the serial clock for the DCI
module. The CSCK pin may be configured as an input
or output using the CSCKD control bit in the DCICON2
SFR. When configured as an output, the serial clock is
provided by the dsPIC30F. When configured as an
input, the serial clock must be provided by an external
device.
The DCI module contains a buffer control unit for trans-
ferring data between the shadow buffer memory and
the serial shift register. The buffer control unit is a sim-
ple 2-bit address counter that points to word locations
in the shadow buffer memory. For the receive memory
space (high address portion of DCI buffer memory), the
address counter is concatenated with a ‘0’ in the MSb
location to form a 3-bit address. For the transmit mem-
ory space (high portion of DCI buffer memory), the
address counter is concatenated with a ‘1’ in the MSb
location.
18.2.2
CSDO PIN
The serial data output (CSDO) pin is configured as an
output only pin when the module is enabled. The
CSDO pin drives the serial bus whenever data is to be
transmitted. The CSDO pin is tri-stated or driven to ‘0’
during CSCK periods when data is not transmitted,
depending on the state of the CSDOM control bit. This
allows other devices to place data on the serial bus
during transmission periods not used by the DCI
module.
Note:
The DCI buffer control unit always
accesses the same relative location in the
transmit and receive buffers, so only one
address counter is provided.
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FIGURE 18-1:
DCI MODULE BLOCK DIAGRAM
BCG Control bits
SCKD
Sample Rate
Generator
FOSC/4
CSCK
FSD
Word Size Selection bits
Frame Length Selection bits
DCI Mode Selection bits
Frame
Synchronization
Generator
COFS
Receive Buffer
Registers w/Shadow
DCI Buffer
Control Unit
15
0
Transmit Buffer
DCI Shift Register
CSDI
Registers w/Shadow
CSDO
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18.3.4
FRAME SYNC MODE
CONTROL BITS
18.3 DCI Module Operation
18.3.1
MODULE ENABLE
The type of frame sync signal is selected using the
The DCI module is enabled or disabled by setting/
clearing the DCIEN control bit in the DCICON1 SFR.
Clearing the DCIEN control bit has the effect of reset-
ting the module. In particular, all counters associated
with CSCK generation, frame sync, and the DCI buffer
control unit are reset.
Frame
Synchronization
mode
control
bits
(COFSM<1:0>) in the DCICON1 SFR. The following
operating modes can be selected:
• Multi-Channel mode
2
• I S mode
• AC-Link mode (16-bit)
• AC-Link mode (20-bit)
The DCI clocks are shutdown when the DCIEN bit is
cleared.
The operation of the COFSM control bits depends on
whether the DCI module generates the frame sync
signal as a master device, or receives the frame sync
signal as a slave device.
When enabled, the DCI controls the data direction for
the four I/O pins associated with the module. The Port,
LAT and TRIS register values for these I/O pins are
overridden by the DCI module when the DCIEN bit is set.
The master device in a DSP/Codec pair is the device
that generates the frame sync signal. The frame sync
signal initiates data transfers on the CSDI and CSDO
pins and usually has the same frequency as the data
sample rate (COFS).
It is also possible to override the CSCK pin separately
when the bit clock generator is enabled. This permits
the bit clock generator to operate without enabling the
rest of the DCI module.
18.3.2
WORD SIZE SELECTION BITS
The DCI module is a frame sync master if the COFSD
control bit is cleared and is a frame sync slave if the
COFSD control bit is set.
The WS<3:0> word size selection bits in the DCICON2
SFR determine the number of bits in each DCI data
word. Essentially, the WS<3:0> bits determine the
counting period for a 4-bit counter clocked from the
CSCK signal.
18.3.5
MASTER FRAME SYNC
OPERATION
When the DCI module is operating as a frame sync
master device (COFSD = 0), the COFSM mode bits
determine the type of frame sync pulse that is
generated by the frame sync generator logic.
Any data length, up to 16-bits, may be selected. The
value loaded into the WS<3:0> bits is one less the
desired word length. For example, a 16-bit data word
size is selected when WS<3:0> = 1111.
A new COFS signal is generated when the frame sync
Note:
These WS<3:0> control bits are used only
generator resets to ‘0’.
2
in the Multi-Channel and I S modes. These
In the Multi-Channel mode, the frame sync pulse is
driven high for the CSCK period to initiate a data trans-
fer. The number of CSCK cycles between successive
frame sync pulses will depend on the word size and
frame sync generator control bits. A timing diagram for
the frame sync signal in Multi-Channel mode is shown
in Figure 18-2.
bits have no effect in AC-Link mode since
the data slot sizes are fixed by the protocol.
18.3.3
FRAME SYNC GENERATOR
The frame sync generator (COFSG) is a 4-bit counter
that sets the frame length in data words. The frame
sync generator is incremented each time the word size
counter is reset (refer to Section 18.3.2). The period for
the frame synchronization generator is set by writing
the COFSG<3:0> control bits in the DCICON2 SFR.
The COFSG period in clock cycles is determined by the
following formula:
In the AC-Link mode of operation, the frame sync sig-
nal has a fixed period and duty cycle. The AC-Link
frame sync signal is high for 16 CSCK cycles and is low
for 240 CSCK cycles. A timing diagram with the timing
details at the start of an AC-Link frame is shown in
Figure 18-3.
2
In the I S mode, a frame sync signal having a 50% duty
EQUATION 18-1: COFSG PERIOD
2
cycle is generated. The period of the I S frame sync
Frame Length = Word Length • (FSG Value + 1)
signal in CSCK cycles is determined by the word size
2
and frame sync generator control bits. A new I S data
Frame lengths, up to 16 data words, may be selected.
The frame length in CSCK periods can vary up to a
maximum of 256 depending on the word size that is
selected.
transfer boundary is marked by a high-to-low or a
low-to-high transition edge on the COFS pin.
Note:
The COFSG control bits will have no effect
in AC-Link mode since the frame length is
set to 256 CSCK periods by the protocol.
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2
In the I S mode, a new data word will be transferred
18.3.6
SLAVE FRAME SYNC OPERATION
one CSCK cycle after a low-to-high or a high-to-low
transition is sampled on the COFS pin. A rising or fall-
ing edge on the COFS pin resets the frame sync
generator logic.
When the DCI module is operating as a frame sync
slave (COFSD = 1), data transfers are controlled by the
Codec device attached to the DCI module. The
COFSM control bits control how the DCI module
responds to incoming COFS signals.
In the AC-Link mode, the tag slot and subsequent data
slots for the next frame will be transferred one CSCK
cycle after the COFS pin is sampled high.
In the Multi-Channel mode, a new data frame transfer
will begin one CSCK cycle after the COFS pin is sam-
pled high (see Figure 18-2). The pulse on the COFS
pin resets the frame sync generator logic.
The COFSG and WS bits must be configured to pro-
vide the proper frame length when the module is oper-
ating in the Slave mode. Once a valid frame sync pulse
has been sampled by the module on the COFS pin, an
entire data frame transfer will take place. The module
will not respond to further frame sync pulses until the
data frame transfer has completed.
FIGURE 18-2:
FRAME SYNC TIMING, MULTI-CHANNEL MODE
CSCK
COFS
CSDI/CSDO
MSB
LSB
FIGURE 18-3:
FRAME SYNC TIMING, AC-LINK START OF FRAME
BIT_CLK
S12 S12 S12 Tag Tag Tag
bit 2 bit 1 LSb
CSDO or CSDI
MSb bit 14 bit 13
SYNC
2
I S INTERFACE FRAME SYNC TIMING
FIGURE 18-4:
CSCK
CSDI or CSDO
LSB
MSB
LSB MSB
WS
2
A 5-bit transfer is shown here for illustration purposes. The I S protocol does not specify word length - this will
Note:
be system dependent.
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18.3.7
BIT CLOCK GENERATOR
EQUATION 18-2: BIT CLOCK FREQUENCY
The DCI module has a dedicated 12-bit time base that
produces the bit clock. The bit clock rate (period) is set
by writing a non-zero 12-bit value to the BCG<11:0>
control bits in the DCICON1 SFR.
FCY
FBCK =
2
(BCG + 1)
•
When the BCG<11:0> bits are set to zero, the bit clock
will be disabled. If the BCG<11:0> bits are set to a non-
zero value, the bit clock generator is enabled. These
bits should be set to ‘0’ and the CSCKD bit set to ‘1’ if
the serial clock for the DCI is received from an external
device.
The required bit clock frequency will be determined by
the system sampling rate and frame size. Typical bit
clock frequencies range from 16x to 512x the converter
sample rate depending on the data converter and the
communication protocol that is used.
To achieve bit clock frequencies associated with com-
mon audio sampling rates, the user will need to select
a crystal frequency that has an ‘even’ binary value.
Examples of such crystal frequencies are listed in
Table 18-1.
The formula for the bit clock frequency is given in
Equation 18-2.
TABLE 18-1: DEVICE FREQUENCIES FOR COMMON CODEC CSCK FREQUENCIES
(1)
(2)
FS (KHz)
FCSCK/FS
FCSCK (MHz)
FOSC (MHZ)
PLL
FCY (MIPS)
BCG
8
12
256
256
32
2.048
3.072
1.024
1.4112
3.072
8.192
6.144
8.192
5.6448
6.144
4
8
8.192
12.288
16.384
11.2896
24.576
1
1
7
3
3
32
8
44.1
48
32
8
64
16
Note 1: When the CSCK signal is applied externally (CSCKD = 1), the BCG<11:0> bits have no effect on the
operation of the DCI module.
2: When the CSCK signal is applied externally (CSCKD = 1), the external clock high and low times must
meet the device timing requirements.
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18.3.8
SAMPLE CLOCK EDGE
CONTROL BIT
18.3.11 RECEIVE SLOT ENABLE BITS
The RSCON SFR contains control bits that are used to
enable up to 16 time slots for reception. These control
bits are the RSE<15:0> bits. The size of each receive
time slot is determined by the WS<3:0> word size
selection bits and can vary from 1 to 16 bits.
The sample clock edge (CSCKE) control bit determines
the sampling edge for the CSCK signal. If the CSCK bit
is cleared (default), data will be sampled on the falling
edge of the CSCK signal. The AC-Link protocols and
most Multi-Channel formats require that data be sam-
pled on the falling edge of the CSCK signal. If the
CSCK bit is set, data will be sampled on the rising edge
If a receive time slot is enabled via one of the RSE bits
(RSEx = 1), the shift register contents will be written to
the current DCI receive shadow buffer location and the
buffer control unit will be incremented to point to the
next buffer location.
2
of CSCK. The I S protocol requires that data be
sampled on the rising edge of the CSCK signal.
Data is not packed in the receive memory buffer loca-
tions if the selected word size is less than 16 bits. Each
received slot data word is stored in a separate 16-bit
buffer location. Data is always stored in a left justified
format in the receive memory buffer.
18.3.9
DATA JUSTIFICATION
CONTROL BIT
In most applications, the data transfer begins one
CSCK cycle after the COFS signal is sampled active.
This is the default configuration of the DCI module. An
alternate data alignment can be selected by setting the
DJST control bit in the DCICON2 SFR. When DJST = 1,
data transfers will begin during the same CSCK cycle
when the COFS signal is sampled active.
18.3.12 SLOT ENABLE BITS OPERATION
WITH FRAME SYNC
The TSE and RSE control bits operate in concert with
the DCI frame sync generator. In the Master mode, a
COFS signal is generated whenever the frame sync
generator is reset. In the Slave mode, the frame sync
generator is reset whenever a COFS pulse is received.
18.3.10 TRANSMIT SLOT ENABLE BITS
The TSCON SFR has control bits that are used to
enable up to 16 time slots for transmission. These con-
trol bits are the TSE<15:0> bits. The size of each time
slot is determined by the WS<3:0> word size selection
bits and can vary up to 16 bits.
The TSE and RSE control bits allow up to 16 consecu-
tive time slots to be enabled for transmit or receive.
After the last enabled time slot has been transmitted/
received, the DCI will stop buffering data until the next
occurring COFS pulse.
If a transmit time slot is enabled via one of the TSE bits
(TSEx = 1), the contents of the current transmit shadow
buffer location will be loaded into the CSDO Shift regis-
ter and the DCI buffer control unit is incremented to
point to the next location.
18.3.13 SYNCHRONOUS DATA
TRANSFERS
The DCI buffer control unit will be incremented by one
word location whenever a given time slot has been
enabled for transmission or reception. In most cases,
data input and output transfers will be synchronized,
which means that a data sample is received for a given
channel at the same time a data sample is transmitted.
Therefore, the transmit and receive buffers will be filled
with equal amounts of data when a DCI interrupt is
generated.
During an unused transmit time slot, the CSDO pin will
drive ‘0’s or will be tri-stated during all disabled time
slots depending on the state of the CSDOM bit in the
DCICON1 SFR.
The data frame size in bits is determined by the chosen
data word size and the number of data word elements
in the frame. If the chosen frame size has less than 16
elements, the additional slot enable bits will have no
effect.
In some cases, the amount of data transmitted and
received during a data frame may not be equal. As an
example, assume a two-word data frame is used. Fur-
thermore, assume that data is only received during
slot #0 but is transmitted during slot #0 and slot #1. In
this case, the buffer control unit counter would be incre-
mented twice during a data frame but only one receive
register location would be filled with data.
Each transmit data word is written to the 16-bit transmit
buffer as left justified data. If the selected word size is
less than 16 bits, then the LS bits of the transmit buffer
memory will have no effect on the transmitted data. The
user should write ‘0’s to the unused LS bits of each
transmit buffer location.
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18.3.14
BUFFER LENGTH CONTROL
18.3.16 TRANSMIT STATUS BITS
The amount of data that is buffered between interrupts
is determined by the buffer length (BLEN<1:0>) control
bits in the DCISTAT SFR. The size of the transmit and
receive buffers may be varied from 1 to 4 data words
using the BLEN control bits. The BLEN control bits are
compared to the current value of the DCI buffer control
unit address counter. When the 2 LS bits of the DCI
address counter match the BLEN<1:0> value, the
buffer control unit will be reset to ‘0’. In addition, the
contents of the receive shadow registers are trans-
ferred to the receive buffer registers and the contents
of the transmit buffer registers are transferred to the
transmit shadow registers.
There are two transmit status bits in the DCISTAT SFR.
The TMPTY bit is set when the contents of the transmit
buffer registers are transferred to the transmit shadow
registers. The TMPTY bit may be polled in software to
determine when the transmit buffer registers may be
written. The TMPTY bit is cleared automatically by the
hardware when a write to one of the four transmit
buffers occurs.
The TUNF bit is read only and indicates that a transmit
underflow has occurred for at least one of the transmit
buffer registers that is in use. The TUNF bit is set at the
time the transmit buffer registers are transferred to the
transmit shadow registers. The TUNF status bit is
cleared automatically when the buffer register that
underflowed is written by the CPU.
18.3.15 BUFFER ALIGNMENT WITH DATA
FRAMES
Note:
The transmit status bits only indicate sta-
tus for buffer locations that are used by the
module. If the buffer length is set to less
than four words, for example, the unused
buffer locations will not affect the transmit
status bits.
There is no direct coupling between the position of the
AGU address pointer and the data frame boundaries.
This means that there will be an implied assignment of
each transmit and receive buffer that is a function of the
BLEN control bits and the number of enabled data slots
via the TSE and RSE control bits.
As an example, assume that a 4-word data frame is
chosen and that we want to transmit on all four time
slots in the frame. This configuration would be estab-
lished by setting the TSE0, TSE1, TSE2, and TSE3
control bits in the TSCON SFR. With this module setup,
the TXBUF0 register would be naturally assigned to
slot #0, the TXBUF1 register would be naturally
assigned to slot #1, and so on.
18.3.17 RECEIVE STATUS BITS
There are two receive status bits in the DCISTAT SFR.
The RFUL status bit is read only and indicates that new
data is available in the receive buffers. The RFUL bit is
cleared automatically when all receive buffers in use
have been read by the CPU.
The ROV status bit is read only and indicates that a
receive overflow has occurred for at least one of the
receive buffer locations. A receive overflow occurs
when the buffer location is not read by the CPU before
new data is transferred from the shadow registers. The
ROV status bit is cleared automatically when the buffer
register that caused the overflow is read by the CPU.
Note:
When more than four time slots are active
within a data frame, the user code must
keep track of which time slots are to be
read/written at each interrupt. In some
cases, the alignment between transmit/
receive buffers and their respective slot
assignments could be lost. Examples of
such cases include an emulation break-
point or a hardware trap. In these situa-
tions, the user should poll the SLOT status
bits to determine what data should be
loaded into the buffer registers to
resynchronize the software with the DCI
module.
When a receive overflow occurs for a specific buffer
location, the old contents of the buffer are overwritten.
Note:
The receive status bits only indicate status
for buffer locations that are used by the
module. If the buffer length is set to less
than four words, for example, the unused
buffer locations will not affect the transmit
status bits.
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18.3.18 SLOT STATUS BITS
18.4 DCI Module Interrupts
The SLOT<3:0> status bits in the DCISTAT SFR indi-
cate the current active time slot. These bits will corre-
spond to the value of the frame sync generator counter.
The user may poll these status bits in software when a
DCI interrupt occurs to determine what time slot data
was last received and which time slot data should be
loaded into the TXBUF registers.
The frequency of DCI module interrupts is dependent
on the BLEN<1:0> control bits in the DCICON2 SFR.
An interrupt to the CPU is generated each time the set
buffer length has been reached and a shadow register
transfer takes place. A shadow register transfer is
defined as the time when the previously written TXBUF
values are transferred to the transmit shadow registers
and new received values in the receive shadow
registers are transferred into the RXBUF registers.
18.3.19 CSDO MODE BIT
The CSDOM control bit controls the behavior of the
CSDO pin during unused transmit slots. A given trans-
mit time slot is unused if it’s corresponding TSEx bit in
the TSCON SFR is cleared.
18.5 DCI Module Operation During CPU
Sleep and Idle Modes
18.5.1
DCI MODULE OPERATION DURING
CPU SLEEP MODE
If the CSDOM bit is cleared (default), the CSDO pin will
be low during unused time slot periods. This mode will
be used when there are only two devices attached to
the serial bus.
The DCI module has the ability to operate while in
Sleep mode and wake the CPU when the CSCK signal
is supplied by an external device (CSCKD = 1). The
DCI module will generate an asynchronous interrupt
when a DCI buffer transfer has completed and the CPU
is in Sleep mode.
If the CSDOM bit is set, the CSDO pin will be tri-stated
during unused time slot periods. This mode allows mul-
tiple devices to share the same CSDO line in a multi-
channel application. Each device on the CSDO line is
configured so that it will only transmit data during
specific time slots. No two devices will transmit data
during the same time slot.
18.5.2
DCI MODULE OPERATION DURING
CPU IDLE MODE
If the DCISIDL control bit is cleared (default), the mod-
ule will continue to operate normally even in Idle mode.
If the DCISIDL bit is set, the module will halt when Idle
mode is asserted.
18.3.20 DIGITAL LOOPBACK MODE
Digital Loopback mode is enabled by setting the
DLOOP control bit in the DCISTAT SFR. When the
DLOOP bit is set, the module internally connects the
CSDO signal to CSDI. The actual data input on the
CSDI I/O pin will be ignored in Digital Loopback mode.
18.6 AC-Link Mode Operation
The AC-Link protocol is a 256-bit frame with one 16-bit
data slot, followed by twelve 20-bit data slots. The DCI
module has two Operating modes for the AC-Link pro-
tocol. These Operating modes are selected by the
COFSM<1:0> control bits in the DCICON1 SFR. The
first AC-Link mode is called ‘16-bit AC-Link mode’ and
is selected by setting COFSM<1:0> = 10. The second
AC-Link mode is called ‘20-bit AC-Link mode’ and is
selected by setting COFSM<1:0> = 11.
18.3.21 UNDERFLOW MODE CONTROL BIT
When an underflow occurs, one of two actions may
occur depending on the state of the Underflow mode
(UNFM) control bit in the DCICON2 SFR. If the UNFM
bit is cleared (default), the module will transmit ‘0’s on
the CSDO pin during the active time slot for the buffer
location. In this Operating mode, the Codec device
attached to the DCI module will simply be fed digital
‘silence’. If the UNFM control bit is set, the module will
transmit the last data written to the buffer location. This
Operating mode permits the user to send continuous
data to the Codec device without consuming CPU
overhead.
18.6.1
16-BIT AC-LINK MODE
In the 16-bit AC-Link mode, data word lengths are
restricted to 16 bits. Note that this restriction only
affects the 20-bit data time slots of the AC-Link proto-
col. For received time slots, the incoming data is simply
truncated to 16 bits. For outgoing time slots, the 4 LS
bits of the data word are set to ‘0’ by the module. This
truncation of the time slots limits the A/D and DAC data
to 16 bits but permits proper data alignment in the
TXBUF and RXBUF registers. Each RXBUF and
TXBUF register will contain one data time slot value.
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2
I S FRAME AND DATA WORD
18.6.2
20-BIT AC-LINK MODE
18.7.1
LENGTH SELECTION
The 20-bit AC-Link mode allows all bits in the data time
slots to be transmitted and received but does not main-
tain data alignment in the TXBUF and RXBUF
registers.
The WS and COFSG control bits are set to produce the
2
period for one half of an I S data frame. That is, the
frame length is the total number of CSCK cycles
required for a left or a right data word transfer.
The 20-bit AC-Link mode functions similar to the Multi-
Channel mode of the DCI module, except for the duty
cycle of the frame synchronization signal. The AC-Link
frame synchronization signal should remain high for 16
CSCK cycles and should be low for the following
240 cycles.
The BLEN bits must be set for the desired buffer length.
Setting BLEN<1:0> = 01will produce a CPU interrupt,
2
once per I S frame.
2
I S DATA JUSTIFICATION
18.7.2
2
The 20-bit mode treats each 256-bit AC-Link frame as
sixteen, 16-bit time slots. In the 20-bit AC-Link mode,
the module operates as if COFSG<3:0> = 1111 and
WS<3:0> = 1111. The data alignment for 20-bit data
slots is ignored. For example, an entire AC-Link data
frame can be transmitted and received in a packed
fashion by setting all bits in the TSCON and RSCON
SFRs. Since the total available buffer length is 64 bits,
it would take 4 consecutive interrupts to transfer the
AC-Link frame. The application software must keep
track of the current AC-Link frame segment.
As per the I S specification, a data word transfer will, by
default, begin one CSCK cycle after a transition of the
WS signal. A ‘MS bit left justified’ option can be
selected using the DJST control bit in the DCICON2
SFR.
2
If DJST = 1, the I S data transfers will be MS bit left jus-
tified. The MS bit of the data word will be presented on
the CSDO pin during the same CSCK cycle as the ris-
ing or falling edge of the COFS signal. The CSDO pin
is tri-stated after the data word has been sent.
2
18.7 I S Mode Operation
2
The DCI module is configured for I S mode by writing
a value of ‘01’ to the COFSM<1:0> control bits in the
2
DCICON1 SFR. When operating in the I S mode, the
DCI module will generate frame synchronization sig-
nals with a 50% duty cycle. Each edge of the frame
synchronization signal marks the boundary of a new
data word transfer.
The user must also select the frame length and data
word size using the COFSG and WS control bits in the
DCICON2 SFR.
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The A/D module has six 16-bit registers:
19.0 12-BIT ANALOG-TO-DIGITAL
CONVERTER (A/D) MODULE
• A/D Control Register 1 (ADCON1)
• A/D Control Register 2 (ADCON2)
• A/D Control Register 3 (ADCON3)
• A/D Input Select Register (ADCHS)
• A/D Port Configuration Register (ADPCFG)
• A/D Input Scan Selection Register (ADCSSL)
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046).
The ADCON1, ADCON2 and ADCON3 registers con-
trol the operation of the A/D module. The ADCHS reg-
ister selects the input channels to be converted. The
ADPCFG register configures the port pins as analog
inputs or as digital I/O. The ADCSSL register selects
inputs for scanning.
The 12-bit Analog-to-Digital converter (A/D) allows
conversion of an analog input signal to a 12-bit digital
number. This module is based on a Successive
Approximation Register (SAR) architecture and pro-
vides a maximum sampling rate of 100 ksps. The A/D
module has up to 16 analog inputs which are multi-
plexed into a sample and hold amplifier. The output of
the sample and hold is the input into the converter
which generates the result. The analog reference volt-
age is software selectable to either the device supply
voltage (AVDD/AVSS) or the voltage level on the
(VREF+/VREF-) pin. The A/D converter has a unique
feature of being able to operate while the device is in
Sleep mode with RC oscillator selection.
Note:
The SSRC<2:0>, ASAM, SMPI<3:0>,
BUFM and ALTS bits, as well as the
ADCON3 and ADCSSL registers, must
not be written to while ADON = 1. This
would lead to indeterminate results.
The block diagram of the 12-bit A/D module is shown in
Figure 19-1.
FIGURE 19-1:
12-BIT A/D FUNCTIONAL BLOCK DIAGRAM
AVDD
AVSS
VREF+
VREF-
Comparator
0000
AN0
DAC
0001
0010
0011
AN1
AN2
AN3
12-bit SAR
Conversion Logic
0100
0101
0110
0111
1000
1001
1010
1011
1100
AN4
AN5
AN6
AN7
16-word, 12-bit
Dual Port
RAM
Sample/Sequence
Control
Sample
AN8
AN9
Input
AN10
AN11
AN12
Input MUX
Control
Switches
CH0
VREF-
S/H
AN1
Note: The ADCHS, ADPCFG and ADCSSL registers allow the application to configure AN13-AN15 as analog input pins.
Since these pins are not physically present on the device, conversion results from these pins will read ‘0’.
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19.1 A/D Result Buffer
19.3 Selecting the Conversion Sequence
The module contains a 16-word dual port read only
buffer, called ADCBUF0...ADCBUFF, to buffer the A/D
results. The RAM is 12 bits wide but the data obtained
is represented in one of four different 16-bit data for-
mats. The contents of the sixteen A/D Conversion
Result Buffer registers, ADCBUF0 through ADCBUFF,
cannot be written by user software.
Several groups of control bits select the sequence in
which the A/D connects inputs to the sample/hold
channel, converts a channel, writes the buffer memory
and generates interrupts.
The sequence is controlled by the sampling clocks.
The SMPI bits select the number of acquisition/
conversion sequences that would be performed before
an interrupt occurs. This can vary from 1 sample per
interrupt to 16 samples per interrupt.
19.2 Conversion Operation
After the A/D module has been configured, the sample
acquisition is started by setting the SAMP bit. Various
sources, such as a programmable bit, timer time-outs
and external events, will terminate acquisition and start
a conversion. When the A/D conversion is complete,
the result is loaded into ADCBUF0...ADCBUFF, and
the DONE bit and the A/D interrupt flag ADIF are set after
the number of samples specified by the SMPI bit. The
ADC module can be configured for different interrupt
rates as described in Section 19.3.
The BUFM bit will split the 16-word results buffer into
two 8-word groups. Writing to the 8-word buffers will be
alternated on each interrupt event.
Use of the BUFM bit will depend on how much time is
available for the moving of the buffers after the
interrupt.
If the processor can quickly unload a full buffer within
the time it takes to acquire and convert one channel,
the BUFM bit can be ‘0’ and up to 16 conversions (cor-
responding to the 16 input channels) may be done per
interrupt. The processor will have one acquisition and
conversion time to move the sixteen conversions.
The following steps should be followed for doing an
A/D conversion:
1. Configure the A/D module:
If the processor cannot unload the buffer within the
acquisition and conversion time, the BUFM bit should be
‘1’. For example, if SMPI<3:0> (ADCON2<5:2>) = 0111,
then eight conversions will be loaded into 1/2 of the
buffer, following which an interrupt occurs. The next
eight conversions will be loaded into the other 1/2 of the
buffer. The processor will have the entire time between
interrupts to move the eight conversions.
• Configure analog pins, voltage reference and
digital I/O
• Select A/D input channels
• Select A/D conversion clock
• Select A/D conversion trigger
• Turn on A/D module
2. Configure A/D interrupt (if required):
• Clear ADIF bit
The ALTS bit can be used to alternate the inputs
selected during the sampling sequence. The input
multiplexer has two sets of sample inputs: MUX A and
MUX B. If the ALTS bit is ‘0’, only the MUX A inputs are
selected for sampling. If the ALTS bit is ‘1’ and
• Select A/D interrupt priority
• Set ADIE bit (for ISR processing)
3. Start sampling.
4. Wait the required acquisition time.
5. Trigger acquisition end, start conversion:
6. Wait for A/D conversion to complete, by either:
• Waiting for the A/D interrupt, or
• Waiting for the DONE bit to get set.
7. Read A/D result buffer, clear ADIF if required.
SMPI<3:0>
=
0000 on the first sample/convert
sequence, the MUX A inputs are selected and on the
next acquire/convert sequence, the MUX B inputs are
selected.
The CSCNA bit (ADCON2<10>) will allow the S/H input
to be sequentially scanned across a selected number
of analog inputs for the MUX A group. The inputs are
selected by the ADCSSL register. If a particular bit in
the ADCSSL register is ‘1’, the corresponding input is
selected. The inputs are always scanned from lower to
higher numbered inputs, starting after each interrupt. If
the number of inputs selected is greater than the
number of samples taken per interrupt, the higher
numbered inputs are unused.
Note:
The ADCHS, ADPCFG and ADCSSL reg-
isters allow the application to configure
AN13-AN15 as analog input pins. Since
these pins are not physically present on
the device, conversion results from these
pins will read ‘0’.
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EXAMPLE 19-1:
A/D CONVERSION CLOCK
AND SAMPLING RATE
CALCULATION
19.4 Programming the Start of
Conversion Trigger
The conversion trigger will terminate acquisition and
start the requested conversions.
Minimum TAD = 667 nsec
TCY = 33 .33 nsec (30 MIPS)
The SSRC<2:0> bits select the source of the conver-
sion trigger. The SSRC bits provide for up to 4 alternate
sources of conversion trigger.
TAD
ADCS<5:0> = 2
– 1
TCY
667 nsec
33.33 nsec
When SSRC<2:0> = 000, the conversion trigger is
under software control. Clearing the SAMP bit will
cause the conversion trigger.
= 2 •
= 39
– 1
Therefore,
When SSRC<2:0> = 111 (Auto-Convert mode), the
conversion trigger is under A/D clock control. The
SAMC bits select the number of A/D clocks between
the start of acquisition and the start of conversion. This
provides the fastest conversion rates on multiple
channels. SAMC must always be at least 1 clock cycle.
Set ADCS<5:0> = 39
TCY
Actual TAD =
(ADCS<5:0> + 1)
33.33 nsec
(39 + 1)
2
=
2
Other trigger sources can come from timer modules or
external interrupts.
= 667 nsec
If SSRC<2:0> = ‘111’ and SAMC<4:0> = ‘00001’
19.5 Aborting a Conversion
Since,
Clearing the ADON bit during a conversion will abort
the current conversion and stop the sampling sequenc-
ing until the next sampling trigger. The ADCBUF will not
be updated with the partially completed A/D conversion
sample. That is, the ADCBUF will continue to contain
the value of the last completed conversion (or the last
value written to the ADCBUF register).
Sampling Time = Acquisition Time + Conversion Time
= 1 TAD + 14 TAD
= 15 x 667 nsec
Therefore,
1
Sampling Rate =
(15 x 667 nsec)
= ~100 kHz
If the clearing of the ADON bit coincides with an auto-
start, the clearing has a higher priority and a new
conversion will not start.
19.7 A/D Acquisition Requirements
The analog input model of the 12-bit A/D converter is
shown in Figure 19-2. The total sampling time for the A/
D is a function of the internal amplifier settling time and
the holding capacitor charge time.
19.6 Selecting the A/D Conversion
Clock
The A/D conversion requires 14 TAD. The source of the
A/D conversion clock is software selected, using a
six-bit counter. There are 64 possible options for TAD.
For the A/D converter to meet its specified accuracy,
the charge holding capacitor (CHOLD) must be allowed
to fully charge to the voltage level on the analog input
pin. The source impedance (RS), the interconnect
impedance (RIC), and the internal sampling switch
(RSS) impedance combine to directly affect the time
required to charge the capacitor CHOLD. The combined
impedance of the analog sources must therefore be
small enough to fully charge the holding capacitor
within the chosen sample time. To minimize the effects
of pin leakage currents on the accuracy of the A/D con-
verter, the maximum recommended source imped-
ance, RS, is 2.5 kΩ. After the analog input channel is
selected (changed), this sampling function must be
completed prior to starting the conversion. The internal
holding capacitor will be in a discharged state prior to
each sample operation.
EQUATION 19-1: A/D CONVERSION CLOCK
TAD = TCY * (0.5*(ADCS<5:0> + 1))
The internal RC oscillator is selected by setting the
ADRC bit.
For correct A/D conversions, the A/D conversion clock
(TAD) must be selected to ensure a minimum TAD time
of 667 nsec (for VDD = 5V). Refer to the Electrical
Specifications section for minimum TAD under other
operating conditions.
Example 19-1 shows a sample calculation for the
ADCS<5:0> bits, assuming a device operating speed
of 30 MIPS.
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FIGURE 19-2:
12-BIT A/D CONVERTER ANALOG INPUT MODEL
VDD
RIC ≤ 250Ω
RSS ≤ 3 kΩ
Sampling
Switch
VT = 0.6V
ANx
RSS
Rs
CHOLD
CPIN
= DAC capacitance
= 18 pF
VA
I leakage
500 nA
VT = 0.6V
VSS
Legend: CPIN
= input capacitance
= threshold voltage
I leakage = leakage current at the pin due to
various junctions
VT
RIC
= interconnect resistance
RSS
= sampling switch resistance
= sample/hold capacitance (from DAC)
CHOLD
Note: CPIN value depends on device package and is not tested. Effect of CPIN negligible if Rs ≤ 2.5 kΩ.
If the A/D interrupt is enabled, the device will wake-up
19.8 Module Power-down Modes
from Sleep. If the A/D interrupt is not enabled, the A/
D module will then be turned off, although the ADON bit
will remain set.
The module has 2 internal Power modes.
When the ADON bit is ‘1’, the module is in Active mode;
it is fully powered and functional.
19.9.2
A/D OPERATION DURING CPU IDLE
MODE
When ADON is ‘0’, the module is in Off mode. The dig-
ital and analog portions of the circuit are disabled for
maximum current savings.
The ADSIDL bit selects if the module will stop on Idle or
continue on Idle. If ADSIDL = 0, the module will con-
tinue operation on assertion of Idle mode. If ADSIDL =
1, the module will stop on Idle.
In order to return to the Active mode from Off mode, the
user must wait for the ADC circuitry to stabilize. The
time required to stabilize is specified in the “Electrical
Characteristics”.
19.10 Effects of a Reset
19.9 A/D Operation During CPU Sleep
and Idle Modes
A device Reset forces all registers to their Reset state.
This forces the A/D module to be turned off, and any
conversion and sampling sequence is aborted. The val-
ues that are in the ADCBUF registers are not modified.
The A/D Result register will contain unknown data after
a Power-on Reset.
19.9.1
A/D OPERATION DURING CPU
SLEEP MODE
When the device enters Sleep mode, all clock sources
to the module are shutdown and stay at logic ‘0’.
19.11 Output Formats
If Sleep occurs in the middle of a conversion, the con-
version is aborted. The converter will not continue with
a partially completed conversion on exit from Sleep
mode.
The A/D result is 12 bits wide. The data buffer RAM is
also 12 bits wide. The 12-bit data can be read in one of
four different formats. The FORM<1:0> bits select the
format. Each of the output formats translates to a 16-bit
result on the data bus. Write data will always be in right
justified (integer) format.
Register contents are not affected by the device
entering or leaving Sleep mode.
The A/D module can operate during Sleep mode if the
A/D clock source is set to RC (ADRC = 1). When the RC
clock source is selected, the A/D module waits one
instruction cycle before starting the conversion. This
allows the SLEEPinstruction to be executed which elim-
inates all digital switching noise from the conversion.
(When the conversion sequence is complete, the
DONE bit will be set.)
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FIGURE 19-3:
RAM Contents:
Read to Bus:
A/D OUTPUT DATA FORMATS
d11 d10 d09 d08 d07 d06 d05 d04 d03 d02 d01 d00
Signed Fractional
d11 d10 d09 d08 d07 d06 d05 d04 d03 d02 d01 d00
0
0
0
0
Fractional
Signed Integer
Integer
d11 d10 d09 d08 d07 d06 d05 d04 d03 d02 d01 d00
0
0
0
0
d11 d11 d11 d11 d11 d10 d09 d08 d07 d06 d05 d04 d03 d02 d01 d00
0
0
0
0
d11 d10 d09 d08 d07 d06 d05 d04 d03 d02 d01 d00
19.12 Configuring Analog Port Pins
19.13 Connection Considerations
The use of the ADPCFG and TRIS registers control the
operation of the A/D port pins. The port pins that are
desired as analog inputs must have their correspond-
ing TRIS bit set (input). If the TRIS bit is cleared (out-
put), the digital output level (VOH or VOL) will be
converted.
The analog inputs have diodes to VDD and VSS as ESD
protection. This requires that the analog input be
between VDD and VSS. If the input voltage exceeds this
range by greater than 0.3V (either direction), one of the
diodes becomes forward biased and it may damage the
device if the input current specification is exceeded.
The A/D operation is independent of the state of the
CH0SA<3:0>/CH0SB<3:0> bits and the TRIS bits.
An external RC filter is sometimes added for anti-
aliasing of the input signal. The R component should be
selected to ensure that the sampling time requirements
are satisfied. Any external components connected (via
high impedance) to an analog input pin (capacitor,
zener diode, etc.) should have very little leakage
current at the pin.
When reading the Port register, all pins configured as
analog input channels will read as cleared.
Pins configured as digital inputs will not convert an ana-
log input. Analog levels on any pin that is defined as a
digital input (including the ANx pins) may cause the
input buffer to consume current that exceeds the
device specifications.
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20.1 Oscillator System Overview
20.0 SYSTEM INTEGRATION
The dsPIC30F oscillator system has the following
modules and features:
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
• Various external and internal oscillator options as
clock sources
• An on-chip PLL to boost internal operating
frequency
• A clock switching mechanism between various
clock sources
There are several features intended to maximize sys-
tem reliability, minimize cost through elimination of
external components, provide Power Saving Operating
modes and offer code protection:
• Programmable clock postscaler for system power
savings
• A Fail-Safe Clock Monitor (FSCM) that detects
clock failure and takes fail-safe measures
• Oscillator Selection
• Reset
• Clock Control register (OSCCON)
- Power-on Reset (POR)
- Power-up Timer (PWRT)
- Oscillator Start-up Timer (OST)
- Programmable Brown-out Reset (BOR)
• Watchdog Timer (WDT)
• Power Saving Modes (Sleep and Idle)
• Code Protection
• Configuration bits for main oscillator selection
Configuration bits determine the clock source upon
Power-on Reset (POR) and Brown-out Reset (BOR).
Thereafter, the clock source can be changed between
permissible clock sources. The OSCCON register
controls the clock switching and reflects system clock
related status bits.
Table 20-1 provides a summary of the dsPIC30F Oscil-
lator Operating modes. A simplified diagram of the
oscillator system is shown in Figure 20-1.
• Unit ID Locations
• In-Circuit Serial Programming (ICSP)
dsPIC30F devices have a Watchdog Timer which is
permanently enabled via the configuration bits or can
be software controlled. It runs off its own RC oscillator
for added reliability. There are two timers that offer
necessary delays on power-up. One is the Oscillator
Start-up Timer (OST), intended to keep the chip in
Reset until the crystal oscillator is stable. The other is
the Power-up Timer (PWRT) which provides a delay on
power-up only, designed to keep the part in Reset while
the power supply stabilizes. With these two timers on-
chip, most applications need no external Reset
circuitry.
Sleep mode is designed to offer a very low current
Power-down mode. The user can wake-up from Sleep
through external Reset, Watchdog Timer Wake-up, or
through an interrupt. Several oscillator options are also
made available to allow the part to fit a wide variety of
applications. In the Idle mode, the clock sources are
still active but the CPU is shut-off. The RC oscillator
option saves system cost while the LP crystal option
saves power.
2004 Microchip Technology Inc.
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dsPIC30F3014/4013
TABLE 20-1: OSCILLATOR OPERATING MODES
Oscillator Mode
Description
XTL
200 kHz-4 MHz crystal on OSC1:OSC2
4 MHz-10 MHz crystal on OSC1:OSC2
XT
XT w/ PLL 4x
XT w/ PLL 8x
XT w/ PLL 16x
LP
4 MHz-10 MHz crystal on OSC1:OSC2, 4x PLL enabled
4 MHz-10 MHz crystal on OSC1:OSC2, 8x PLL enabled
4 MHz-10 MHz crystal on OSC1:OSC2, 16x PLL enabled
(1)
(2)
32 kHz crystal on SOSCO:SOSCI
HS
10 MHz-25 MHz crystal
HS/2 w/ PLL 4x
HS/2 w/ PLL 8x
HS/2 w/ PLL 16x
HS/3 w/ PLL 4x
HS/3 w/ PLL 8x
HS/3 w/ PLL 16x
EC
10 MHz-25 MHz crystal, divide by 2, 4x PLL enabled
10 MHz-25 MHz crystal, divide by 2, 8x PLL enabled
10 MHz-25 MHz crystal, divide by 2, 16x PLL enabled
10 MHz-25 MHz crystal, divide by 3, 4x PLL enabled
10 MHz-25 MHz crystal, divide by 3, 8x PLL enabled
10 MHz-25 MHz crystal, divide by 3, 16x PLL enabled
External clock input (0-40 MHz)
ECIO
External clock input (0-40 MHz), OSC2 pin is I/O
(1)
(1)
EC w/ PLL 4x
EC w/ PLL 8x
EC w/ PLL 16x
ERC
External clock input (0-40 MHz), OSC2 pin is I/O, 4x PLL enabled
External clock input (0-40 MHz), OSC2 pin is I/O, 8x PLL enabled
(1)
External clock input (0-40 MHz), OSC2 pin is I/O, 16x PLL enabled
(3)
External RC oscillator, OSC2 pin is FOSC/4 output
(3)
ERCIO
External RC oscillator, OSC2 pin is I/O
FRC
8 MHz internal RC oscillator
FRC w/ PLL 4x
FRC w/ PLL 8x
FRC w/ PLL 16x
LPRC
8 MHz Internal RC oscillator, 4x PLL enabled
8 MHz Internal RC oscillator, 8x PLL enabled
7.5 MHz Internal RC oscillator, 16x PLL enabled
512 kHz internal RC oscillator
Note 1: dsPIC30F maximum operating frequency of 120 MHz must be met.
2: LP oscillator can be conveniently shared as system clock, as well as real-time clock for Timer1.
3: Requires external R and C. Frequency operation up to 4 MHz.
DS70138C-page 132
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FIGURE 20-1:
OSCILLATOR SYSTEM BLOCK DIAGRAM
Oscillator Configuration bits
PWRSAVInstruction
Wake-up Request
FPLL
OSC1
OSC2
Primary
PLL
x4, x8, x16
Oscillator
PLL
Lock
COSC<2:0>
NOSC<2:0>
OSWEN
Primary Osc
Primary
Oscillator
Stability Detector
Oscillator
Start-up
Timer
POR Done
Clock
Programmable
Switching
and Control
Block
Secondary Osc
Clock Divider
System
Clock
SOSCO
SOSCI
Secondary
32 kHz LP
Oscillator
Oscillator
2
Stability Detector
POST<1:0>
4
TUN<3:0>
Internal Fast RC
Oscillator (FRC)
LPRC
Internal Low
Power RC
Oscillator (LPRC)
CF
Fail-Safe Clock
Monitor (FSCM)
FCKSM<1:0>
2
Oscillator Trap
To Timer1
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dsPIC30F3014/4013
20.2.2
OSCILLATOR START-UP TIMER
(OST)
20.2 Oscillator Configurations
20.2.1
INITIAL CLOCK SOURCE
SELECTION
In order to ensure that a crystal oscillator (or ceramic
resonator) has started and stabilized, an Oscillator
Start-up Timer is included. It is a simple 10-bit counter
that counts 1024 TOSC cycles before releasing the
oscillator clock to the rest of the system. The time-out
period is designated as TOST. The TOST time is involved
every time the oscillator has to restart (i.e., on POR,
BOR and wake-up from Sleep). The Oscillator Start-up
Timer is applied to the LP oscillator, XT, XTL, and HS
modes (upon wake-up from Sleep, POR and BOR) for
the primary oscillator.
While coming out of Power-on Reset or Brown-out
Reset, the device selects its clock source based on:
a) FOS<2:0> configuration bits that select one of
four oscillator groups,
b) and FPR<4:0> configuration bits that select one
of 13 oscillator choices within the primary group.
The selection is as shown in Table 20-2.
TABLE 20-2: CONFIGURATION BIT VALUES FOR CLOCK SELECTION
Oscillator
OSC2
Oscillator Mode
FOS<2:0>
FPR<4:0>
Source
PLL
PLL
Function
ECIO w/ PLL 4x
ECIO w/ PLL 8x
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
1
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
0
0
0
0
0
0
0
X
X
X
1
1
1
0
1
0
0
0
0
0
0
0
0
0
0
1
0
0
1
1
1
0
X
X
X
1
1
1
0
0
0
1
1
1
0
0
0
1
1
1
1
1
0
0
0
0
0
X
X
X
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
0
1
1
0
0
0
X
X
X
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
0
0
0
1
1
0
0
X
X
X
I/O
I/O
ECIO w/ PLL 16x PLL
I/O
FRC w/ PLL 4x
FRC w/ PLL 8x
FRC w/ PLL 16x
XT w/ PLL 4x
XT w/ PLL 8x
XT w/ PLL 16x
HS2 w/ PLL 4x
HS2 w/ PLL 8x
HS2 w/ PLL 16x
HS3 w/ PLL 4x
HS3 w/ PLL 8x
HS3 w/ PLL 16x
ECIO
PLL
I/O
PLL
I/O
PLL
I/O
PLL
OSC2
OSC2
OSC2
OSC2
OSC2
OSC2
OSC2
OSC2
OSC2
I/O
PLL
PLL
PLL
PLL
PLL
PLL
PLL
PLL
External
External
External
External
External
External
External
Secondary
Internal FRC
Internal LPRC
XT
OSC2
OSC2
CLKOUT
CLKOUT
I/O
HS
EXT
ERC
ERCIO
XTL
OSC2
(Notes 1, 2)
(Notes 1, 2)
(Notes 1, 2)
LP
FRC
LPRC
Note 1: OSC2 pin function is determined by (FPR<4:0>).
2: Note that OSC1 pin cannot be used as an I/O pin even if the secondary oscillator or an internal clock
source is selected at all times.
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20.2.3
LP OSCILLATOR CONTROL
Note:
When a 16x PLL is used, the FRC
frequency must not be tuned to
frequency greater than 7.5 MHz.
a
Enabling the LP oscillator is controlled with two
elements:
1. The current oscillator group bits COSC<2:0>.
2. The LPOSCEN bit (OSCON register).
TABLE 20-4: FRC TUNING
TUN<3:0>
The LP oscillator is on (even during Sleep mode) if
LPOSCEN = 1. The LP oscillator is the device clock if:
FRC Frequency
Bits
0111
0110
0101
0100
0011
0010
0001
0000
+ 10.5%
+ 9.0%
+ 7.5%
+ 6.0%
+ 4.5%
+ 3.0%
+ 1.5%
• COSC<2:0> = 00(LP selected as main oscillator)
and
• LPOSCEN = 1
Keeping the LP oscillator on at all times allows for a fast
switch to the 32 kHz system clock for lower power oper-
ation. Returning to the faster main oscillator will still
require a start-up time
Center Frequency (oscillator is
running at calibrated frequency)
20.2.4
PHASE LOCKED LOOP (PLL)
The PLL multiplies the clock which is generated by the
primary oscillator. The PLL is selectable to have either
gains of x4, x8, and x16. Input and output frequency
ranges are summarized in Table 20-3.
1111
1110
1101
1100
1011
1010
1001
1000
- 1.5%
- 3.0%
- 4.5%
- 6.0%
- 7.5%
- 9.0%
- 10.5%
- 12.0%
TABLE 20-3: PLL FREQUENCY RANGE
PLL
FIN
FOUT
Multiplier
4 MHz-10 MHz
4 MHz-10 MHz
4 MHz-7.5 MHz
x4
x8
16 MHz-40 MHz
32 MHz-80 MHz
64 MHz-120 MHz
20.2.6
LOW POWER RC OSCILLATOR
(LPRC)
x16
The PLL features a lock output which is asserted when
the PLL enters a phase locked state. Should the loop
fall out of lock (e.g., due to noise), the lock signal will be
rescinded. The state of this signal is reflected in the
read only LOCK bit in the OSCCON register.
The LPRC oscillator is a component of the Watchdog
Timer (WDT) and oscillates at a nominal frequency of
512 kHz. The LPRC oscillator is the clock source for
the Power-up Timer (PWRT) circuit, WDT, and clock
monitor circuits. It may also be used to provide a low
frequency clock source option for applications where
power consumption is critical and timing accuracy is
not required
20.2.5
FAST RC OSCILLATOR (FRC)
The FRC oscillator is a fast (8 MHz nominal) internal
RC oscillator. This oscillator is intended to provide
reasonable device operating speeds without the use of
an external crystal, ceramic resonator, or RC network.
The FRC oscillator can be used with the PLL to obtain
higher clock frequencies.
The LPRC oscillator is always enabled at a Power-on
Reset because it is the clock source for the PWRT.
After the PWRT expires, the LPRC oscillator will remain
on if one of the following is TRUE:
• The Fail-Safe Clock Monitor is enabled
• The WDT is enabled
The dsPIC30F operates from the FRC oscillator when-
ever the current oscillator selection control bits in the
OSCCON register (OSCCON<14:12>) are set to ‘001’.
• The LPRC oscillator is selected as the system
clock via the COSC<2:0> control bits in the
OSCCON register
The four bit field specified by TUN<3:0>
(OSCTUN<3:0>) allows the user to tune the internal
fast RC oscillator (nominal 8.0 MHz). The user can tune
the FRC oscillator within a range of +10.5% (840 kHz)
and -12% (960 kHz) in steps of 1.50% around the
factory-calibrated setting, see Table 20-4.
If one of the above conditions is not true, the LPRC will
shut-off after the PWRT expires.
Note 1: OSC2 pin function is determined by the
Primary Oscillator mode selection
(FPR<4:0>).
If OSCCON<14:12> are set to ‘111’ and FPR<4:0> are
set to ‘00101’, ‘00110’ or ‘00111’, then a PLL multiplier
of 4, 8 or 16 (respectively) is applied.
2: OSC1 pin cannot be used as an I/O pin
even if the secondary oscillator or an
internal clock source is selected at all
times.
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The OSCCON register holds the control and status bits
related to clock switching.
20.2.7
FAIL-SAFE CLOCK MONITOR
The Fail-Safe Clock Monitor (FSCM) allows the device
to continue to operate even in the event of an oscillator
failure. The FSCM function is enabled by appropriately
programming the FCKSM configuration bits (clock
switch and monitor selection bits) in the FOSC Device
Configuration register. If the FSCM function is enabled,
the LPRC internal oscillator will run at all times (except
during Sleep mode) and will not be subject to control by
the SWDTEN bit.
• COSC<1:0>: Read only status bits always reflect
the current oscillator group in effect.
• NOSC<2:0>: Control bits which are written to
indicate the new oscillator group of choice.
- On POR and BOR, COSC<2:0> and
NOSC<1:0> are both loaded with the
configuration bit values FOS<2:0>.
• LOCK: The LOCK status bit indicates a PLL lock.
In the event of an oscillator failure, the FSCM will gen-
erate a clock failure trap event and will switch the sys-
tem clock over to the FRC oscillator. The user will then
have the option to either attempt to restart the oscillator
or execute a controlled shutdown. The user may decide
to treat the trap as a warm Reset by simply loading the
Reset address into the oscillator fail trap vector. In this
event, the CF (Clock Fail) status bit (OSCCON<3>) is
also set whenever a clock failure is recognized.
• CF: Read only status bit indicating if a clock fail
detect has occurred.
• OSWEN: Control bit changes from a ‘0’ to a ‘1’
when a clock transition sequence is initiated.
Clearing the OSWEN control bit will abort a clock
transition in progress (used for hang-up
situations).
If configuration bits FCKSM<2:0> = 1x, then the clock
switching and Fail-Safe Clock monitoring functions are
disabled. This is the default configuration bit setting.
In the event of a clock failure, the WDT is unaffected
and continues to run on the LPRC clock.
If clock switching is disabled, then the FOS<2:0> and
FPR<4:0> bits directly control the oscillator selection
and the COSC<2:0> bits do not control the clock selec-
tion. However, these bits will reflect the clock source
selection.
If the oscillator has a very slow start-up time coming out
of POR, BOR or Sleep, it is possible that the PWRT
timer will expire before the oscillator has started. In
such cases, the FSCM will be activated and the FSCM
will initiate a clock failure trap, and the COSC<2:0> bits
are loaded with FRC oscillator selection. This will effec-
tively shut-off the original oscillator that was trying to
start.
Note:
The application should not attempt to
switch to a clock of frequency lower than
100 KHz when the fail-safe clock monitor is
enabled. If such clock switching is
performed, the device may generate an
oscillator fail trap and switch to the Fast RC
oscillator.
The user may detect this situation and restart the
oscillator in the clock fail trap ISR.
Upon a clock failure detection, the FSCM module will
initiate a clock switch to the FRC oscillator as follows:
1. The COSC bits (OSCCON<14:12>) are loaded
with the FRC oscillator selection value.
20.2.8
PROTECTION AGAINST
ACCIDENTAL WRITES TO OSCCON
2. CF bit is set (OSCCON<3>).
A write to the OSCCON register is intentionally made
difficult because it controls clock switching and clock
scaling.
3. OSWEN control bit (OSCCON<0>) is cleared.
For the purpose of clock switching, the clock sources
are sectioned into four groups:
To write to the OSCCON low byte, the following code
sequence must be executed without any other
instructions in between:
1. Primary
2. Secondary
3. Internal FRC
4. Internal LPRC
Byte Write “0x46” to OSCCON low
Byte Write “0x57” to OSCCON low
The user can switch between these functional groups
but cannot switch between options within a group. If the
primary group is selected, then the choice within the
group is always determined by the FPR<4:0>
configuration bits.
Byte write is allowed for one instruction cycle. Write the
desired value or use bit manipulation instruction.
To write to the OSCCON high byte, the following
instructions must be executed without any other
instructions in between:
Byte Write“0x78” to OSCCON high
Byte Write“0x9A” to OSCCON high
Byte write is allowed for one instruction cycle. Write the
desired value or use bit manipulation instruction.
DS70138C-page 136
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20.3 Oscillator Control Registers
Note:
The description of the OSCCON and
OSCTUN SFRs, as well as the FOSC
configuration register provided in this
section are applicable only to the
The oscillators are controlled with two SFRs,
OSCCON and OSCTUN and one configuration
register, FOSC.
dsPIC30F3014
and
dsPIC30F4013
devices in the dsPIC30F product family.
REGISTER 20-1: OSCCON: OSCILLATOR CONTROL REGISTER
Upper Byte:
U-0
—
R-y
R-y
R-y
U-0
—
R/W-y
R/W-y
R/W-y
COSC<2:0>
NOSC<2:0>
bit 15
bit 8
Lower Byte:
R/W-0
POST<1:0>
R/W-0
R-0
LOCK
U-0
R/W-0
CF
U-0
R/W-0
LPOSCEN OSWEN
bit 0
R/W-0
—
—
bit 7
bit 15
Unimplemented: Read as ‘0’
bit 14-12 COSC<2:0>: Current Oscillator Group Selection (Read Only)
111= PLL Oscillator; PLL source selected by FPR<4:0> bits
011= External Oscillator; OSC1/OSC2 pins; External Oscillator configuration selected by FPR<4:0> bits
010= LPRC internal low power RC
001= FRC internal fast RC
000= LP crystal oscillator; SOSCI/SOSCO pins
Set to FOS<2:0> values on POR or BOR.
Loaded with NOSC<2:0> at the completion of a successful clock switch.
Set to FRC value when FSCM detects a failure and switches clock to FRC.
bit 11
Unimplemented: Read as ‘0’
bit 10-8 NOSC<2:0>: New Oscillator Group Selection
111= PLL Oscillator; PLL source selected by FPR<4:0> bits
011= External Oscillator; OSC1/OSC2 pins; External Oscillator configuration selected by FPR<4:0> bits
010= LPRC internal low power RC
001= FRC internal fast RC
000= LP crystal oscillator; SOSCI/SOSCO pins
Set to FOS<2:0> values on POR or BOR.
bit 7-6
POST<1:0>: Oscillator Postscaler Selection bits
11= Oscillator postscaler divides clock by 64
10= Oscillator postscaler divides clock by 16
01= Oscillator postscaler divides clock by 4
00= Oscillator postscaler does not alter clock
bit 5
LOCK: PLL Lock Status bit (Read Only)
1= Indicates that PLL is in lock
0= Indicates that PLL is out of lock (or disabled)
Reset on POR or BOR.
Reset when a valid clock switching sequence is initiated.
Set when PLL lock is achieved after a PLL start.
Reset when lock is lost.
Read zero when PLL is not selected as a system clock.
bit 4
Unimplemented: Read as ‘0’
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REGISTER 20-1: OSCCON: OSCILLATOR CONTROL REGISTER (CONTINUED)
bit 3
CF: Clock Fail Detect (Read/Clearable by application)
1= FSCM has detected clock failure
0= FSCM has NOT detected clock failure
Reset on POR or BOR.
Reset when a valid clock switching sequence is initiated.
Set when clock fail detected.
bit 2
bit 1
Unimplemented: Read as ‘0’
LPOSCEN: 32 KHz Secondary (LP) oScillator Enable
1= Secondary Oscillator is enabled
0= Secondary Oscillator is disabled
Reset on POR or BOR.
bit 0
OSWEN: Oscillator Switch Enable bit
1= Request Oscillator switch to selection specified by NOSCG<2:0> bits
0= Oscillator switch is complete
Reset on POR or BOR.
Reset after a successful clock switch.
Reset after a redundant clock switch.
Reset after FSCM switches the oscillator to (Group 1) FRC.
Legend:
R = Readable bit
-n = Value at POR
W = Writable bit
‘1’ = Bit is set
U = Unimplemented bit, read as ‘0’
‘0’ = Bit is cleared x = Bit is unknown
y = Value set from configuration bits on POR
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REGISTER 20-2: OSCTUN: FRC OSCILLATOR TUNING REGISTER
Upper Byte:
U-0
—
U-0
—
U-0
U-0
U-0
U-0
U-0
U-0
—
—
—
—
—
—
bit 15
bit 8
Lower Byte:
U-0
—
U-0
U-0
U-0
R/W-0
R/W-0
R/W-0
R/W-0
—
—
—
TUN<3:0>
bit 7
bit 0
bit 15-4 Unimplemented: Read as ‘0’
bit 3-0
TUN<3:0>: Lower two bits of TUN field. The four bit field specified by TUN<3:0> specifies the user tuning
capability for the internal fast RC oscillator (nominal 7.37 MHz).
0111= Maximum Frequency
0110=
0101=
0100=
0011=
0010=
0001=
0000= Center Frequency, Oscillator is running at calibrated frequency
1111=
1110=
1101=
1100=
1011=
1010=
1001=
1000=Minimum Frequency
Legend:
R = Readable bit
-n = Value at POR
W = Writable bit
‘1’ = Bit is set
U = Unimplemented bit, read as ‘0’
‘0’ = Bit is cleared x = Bit is unknown
y = Value set from configuration bits on POR
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REGISTER 20-3: FOSC: OSCILLATOR CONFIGURATION REGISTER
Upper Byte:
U
U
U
U
U
U
U
U
—
—
—
—
—
—
—
—
bit 23
bit 16
Middle Byte:
R/P
R/P
U
U
U
R/P
R/P
FOS<2:0>
R/P
FCKSM<1:0>
bit 15
—
—
—
bit 8
Lower Byte:
U
—
U
U
R/P
R/P
R/P
FPR<4:0>
R/P
R/P
—
—
bit 7
bit 0
bit 23-16 Unimplemented: Read as ‘0’
bit 15-14 FCKSM<1:0>: Clock Switching and Monitor Selection Configuration bits
1x= Clock switching is disabled, fail safe clock monitor is disabled
01= Clock switching is enabled, fail safe clock monitor is disabled
00= Clock switching is enabled, fail safe clock monitor is enabled
bit 13-10 Unimplemented: Read as ‘0’
bit 9-8
FOS<2:0>: Oscillator Group Selection on POR
111= PLL Oscillator; PLL source selected by FPR<4:0> bits. See Table 20-2.
011= EXT: External Oscillator; OSC1/OSC2 pins; External Oscillator configuration selected by
FPR<4:0> bits
010= LPRC: Internal Low Power RC
001= FRC: Internal Fast RC
000= LPOSC: Low Power Crystal Oscillator; SOSCI/SOSCO pins
bit 7-4
bit 3-0
Unimplemented: Read as ‘0’
FPR<4:0>: Oscillator Selection within Primary Group, See Table 20-2.
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
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Different registers are affected in different ways by var-
ious Reset conditions. Most registers are not affected
by a WDT wake-up since this is viewed as the resump-
tion of normal operation. Status bits from the RCON
register are set or cleared differently in different Reset
situations, as indicated in Table 20-4. These bits are
used in software to determine the nature of the Reset.
20.4 Reset
The
PIC18F2220/2320/4220/4320
differentiates
between various kinds of Reset:
a) Power-on Reset (POR)
b) MCLR Reset during normal operation
c) MCLR Reset during Sleep
A block diagram of the On-Chip Reset Circuit is shown
in Figure 20-2.
d) Watchdog Timer (WDT) Reset (during normal
operation)
A MCLR noise filter is provided in the MCLR Reset
path. The filter detects and ignores small pulses.
e) Programmable Brown-out Reset (BOR)
f) RESETInstruction
Internally generated Resets do not drive MCLR pin low.
g) Reset caused by trap lockup (TRAPR)
h) Reset caused by illegal opcode or by using an
uninitialized W register as an address pointer
(IOPUWR)
FIGURE 20-2:
RESET SYSTEM BLOCK DIAGRAM
RESET
Instruction
Digital
Glitch Filter
MCLR
Sleep or Idle
WDT
Module
POR
VDD Rise
S
Detect
VDD
Brown-out
Reset
BOR
BOREN
Q
R
SYSRST
Trap Conflict
Illegal Opcode/
Uninitialized W Register
The POR circuit inserts a small delay, TPOR, which is
nominally 10 µs and ensures that the device bias cir-
cuits are stable. Furthermore, a user selected power-
up time-out (TPWRT) is applied. The TPWRT parameter
is based on device configuration bits and can be 0 ms
(no delay), 4 ms, 16 ms, or 64 ms. The total delay is at
device power-up, TPOR + TPWRT. When these delays
have expired, SYSRST will be negated on the next
leading edge of the Q1 clock and the PC will jump to the
Reset vector.
20.4.1
POR: POWER-ON RESET
A power-on event will generate an internal POR pulse
when a VDD rise is detected. The Reset pulse will occur
at the POR circuit threshold voltage (VPOR) which is
nominally 1.85V. The device supply voltage character-
istics must meet specified starting voltage and rise rate
requirements. The POR pulse will reset a POR timer
and place the device in the Reset state. The POR also
selects the device clock source identified by the oscil-
lator configuration fuses.
The timing for the SYSRST signal is shown in
Figure 20-3 through Figure 20-5.
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FIGURE 20-3:
TIME-OUT SEQUENCE ON POWER-UP (MCLR TIED TO VDD)
VDD
MCLR
INTERNAL POR
TOST
OST TIME-OUT
TPWRT
PWRT TIME-OUT
INTERNAL Reset
FIGURE 20-4:
TIME-OUT SEQUENCE ON POWER-UP (MCLR NOT TIED TO VDD): CASE 1
VDD
MCLR
INTERNAL POR
TOST
OST TIME-OUT
TPWRT
PWRT TIME-OUT
INTERNAL Reset
FIGURE 20-5:
TIME-OUT SEQUENCE ON POWER-UP (MCLR NOT TIED TO VDD): CASE 2
VDD
MCLR
INTERNAL POR
TOST
OST TIME-OUT
TPWRT
PWRT TIME-OUT
INTERNAL Reset
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A BOR will generate a Reset pulse which will reset the
device. The BOR will select the clock source based on
the device configuration bit values (FOS<1:0> and
FPR<3:0>). Furthermore, if an Oscillator mode is
selected, the BOR will activate the Oscillator Start-up
Timer (OST). The system clock is held until OST
expires. If the PLL is used, then the clock will be held
until the LOCK bit (OSCCON<5>) is ‘1’.
20.4.1.1
POR with Long Crystal Start-up Time
(with FSCM Enabled)
The oscillator start-up circuitry is not linked to the POR
circuitry. Some crystal circuits (especially low fre-
quency crystals) will have a relatively long start-up
time. Therefore, one or more of the following conditions
is possible after the POR timer and the PWRT have
expired:
Concurrently, the POR time-out (TPOR) and the PWRT
time-out (TPWRT) will be applied before the internal Reset
is released. If TPWRT = 0and a crystal oscillator is being
used, then a nominal delay of TFSCM = 100 µs is applied.
The total delay in this case is (TPOR + TFSCM).
• The oscillator circuit has not begun to oscillate.
• The Oscillator Start-up Timer has not expired (if a
crystal oscillator is used).
• The PLL has not achieved a LOCK (if PLL is
used).
The BOR status bit (RCON<1>) will be set to indicate
that a BOR has occurred. The BOR circuit, if enabled,
will continue to operate while in Sleep or Idle modes
and will reset the device should VDD fall below the BOR
threshold voltage.
If the FSCM is enabled and one of the above conditions
is true, then a clock failure trap will occur. The device
will automatically switch to the FRC oscillator and the
user can switch to the desired crystal oscillator in the
trap ISR.
FIGURE 20-6:
EXTERNAL POWER-ON
RESET CIRCUIT (FOR
SLOW VDD POWER-UP)
20.4.1.2
Operating without FSCM and PWRT
If the FSCM is disabled and the Power-up Timer
(PWRT) is also disabled, then the device will exit rap-
idly from Reset on power-up. If the clock source is
FRC, LPRC, EXTRC or EC, it will be active
immediately.
VDD
D
R
R1
If the FSCM is disabled and the system clock has not
started, the device will be in a frozen state at the Reset
vector until the system clock starts. From the user’s
perspective, the device will appear to be in Reset until
a system clock is available.
MCLR
dsPIC30F
C
Note 1: External Power-on Reset circuit is required
only if the VDD power-up slope is too slow.
The diode D helps discharge the capacitor
quickly when VDD powers down.
20.4.2
BOR: PROGRAMMABLE
BROWN-OUT RESET
The BOR (Brown-out Reset) module is based on an
internal voltage reference circuit. The main purpose of
the BOR module is to generate a device Reset when a
brown-out condition occurs. Brown-out conditions are
generally caused by glitches on the AC mains (i.e.,
missing portions of the AC cycle waveform due to bad
power transmission lines, or voltage sags due to exces-
sive current draw when a large inductive load is turned
on).
2: R should be suitably chosen so as to make
sure that the voltage drop across R does not
violate the device’s electrical specifications.
3: R1 should be suitably chosen so as to limit
any current flowing into MCLR from external
capacitor C, in the event of MCLR/VPP pin
breakdown due to Electrostatic Discharge
(ESD), or Electrical Overstress (EOS).
The BOR module allows selection of one of the
following voltage trip points:
Note:
Dedicated supervisory devices, such as
the MCP1XX and MCP8XX, may also be
used as an external Power-on Reset
circuit.
• 2.0V
• 2.7V
• 4.2V
• 4.5V
Note:
The BOR voltage trip points indicated here
are nominal values provided for design
guidance only. Refer to the Electrical
Specifications in the specific device data
sheet for BOR voltage limit specifications.
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Table 20-4 shows the Reset conditions for the RCON
register. Since the control bits within the RCON register
are R/W, the information in the table implies that all the
bits are negated prior to the action specified in the
condition column.
TABLE 20-4: INITIALIZATION CONDITION FOR RCON REGISTER: CASE 1
Program
Condition
Power-on Reset
TRAPR IOPUWR EXTR SWR WDTO Idle Sleep POR BOR
Counter
0x000000
0x000000
0x000000
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
1
1
0
Brown-out Reset
MCLR Reset during normal
operation
Software Reset during
normal operation
0x000000
0
0
0
1
0
0
0
0
0
MCLR Reset during Sleep
MCLR Reset during Idle
WDT Time-out Reset
WDT Wake-up
0x000000
0x000000
0x000000
PC + 2
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
(1)
Interrupt Wake-up from Sleep
Clock Failure Trap
PC + 2
0x000004
0x000000
0x000000
Trap Reset
Illegal Operation Trap
Legend: u= unchanged, x= unknown, - = unimplemented bit, read as ‘0’
Note 1: When the wake-up is due to an enabled interrupt, the PC is loaded with the corresponding interrupt vector.
Table 20-5 shows a second example of the bit
conditions for the RCON register. In this case, it is not
assumed the user has set/cleared specific bits prior to
action specified in the condition column.
TABLE 20-5: INITIALIZATION CONDITION FOR RCON REGISTER: CASE 2
Program
Condition
Power-on Reset
TRAPR IOPUWR EXTR SWR WDTO Idle Sleep POR BOR
Counter
0x000000
0x000000
0x000000
0
u
u
0
u
u
0
u
1
0
u
0
0
u
0
0
u
0
0
u
0
1
0
u
1
1
u
Brown-out Reset
MCLR Reset during normal
operation
Software Reset during
normal operation
0x000000
u
u
0
1
0
0
0
u
u
MCLR Reset during Sleep
MCLR Reset during Idle
WDT Time-out Reset
WDT Wake-up
0x000000
0x000000
0x000000
PC + 2
u
u
u
u
u
u
1
u
u
u
u
u
u
u
u
1
1
1
0
u
u
u
u
u
u
u
0
u
u
u
u
u
0
0
1
1
u
u
u
u
0
1
0
u
u
u
u
u
1
0
0
1
1
u
u
u
u
u
u
u
u
u
u
u
u
u
u
u
u
u
u
u
(1)
Interrupt Wake-up from Sleep
Clock Failure Trap
PC + 2
0x000004
0x000000
0x000000
Trap Reset
Illegal Operation Reset
Legend: u= unchanged, x= unknown, - = unimplemented bit, read as ‘0’
Note 1: When the wake-up is due to an enabled interrupt, the PC is loaded with the corresponding interrupt vector.
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20.5 Watchdog Timer (WDT)
20.7 Power Saving Modes
There are two power saving states that can be entered
through the execution of a special instruction, PWRSAV;
these are Sleep and Idle.
20.5.1
WATCHDOG TIMER OPERATION
The primary function of the Watchdog Timer (WDT) is
to reset the processor in the event of a software mal-
function. The WDT is a free-running timer which runs
off an on-chip RC oscillator, requiring no external com-
ponent. Therefore, the WDT timer will continue to oper-
ate even if the main processor clock (e.g., the crystal
oscillator) fails.
The format of the PWRSAVinstruction is as follows:
PWRSAV <parameter>, where ‘parameter’ defines
Idle or Sleep mode.
20.7.1
SLEEP MODE
In Sleep mode, the clock to the CPU and peripherals is
shutdown. If an on-chip oscillator is being used, it is
shutdown.
20.5.2
ENABLING AND DISABLING
THE WDT
The Watchdog Timer can be “Enabled” or “Disabled”
only through a configuration bit (FWDTEN) in the
Configuration register, FWDT.
The Fail-Safe Clock Monitor is not functional during
Sleep since there is no clock to monitor. However,
LPRC clock remains active if WDT is operational during
Sleep.
Setting FWDTEN = 1enables the Watchdog Timer. The
enabling is done when programming the device. By
default, after chip erase, FWDTEN bit = 1. Any device
programmer capable of programming dsPIC30F
devices allows programming of this and other
configuration bits.
The brown-out protection circuit and the Low Voltage
Detect circuit, if enabled, will remain functional during
Sleep.
The processor wakes up from Sleep if at least one of
the following conditions has occurred:
If enabled, the WDT will increment until it overflows or
“times out”. A WDT time-out will force a device Reset
(except during Sleep). To prevent a WDT time-out, the
user must clear the Watchdog Timer using a CLRWDT
instruction.
• any interrupt that is individually enabled and
meets the required priority level
• any Reset (POR, BOR and MCLR)
• WDT time-out
If a WDT times out during Sleep, the device will wake-
up. The WDTO bit in the RCON register will be cleared
to indicate a wake-up resulting from a WDT time-out.
On waking up from Sleep mode, the processor will
restart the same clock that was active prior to entry into
Sleep mode. When clock switching is enabled, bits
COSC<1:0> will determine the oscillator source that
will be used on wake-up. If clock switch is disabled,
then there is only one system clock.
Setting FWDTEN = 0 allows user software to enable/
disable the Watchdog Timer via the SWDTEN
(RCON<5>) control bit.
Note:
If a POR or BOR occurred, the selection of
the oscillator is based on the FOS<1:0>
and FPR<3:0> configuration bits.
20.6 Low Voltage Detect
The Low Voltage Detect (LVD) module is used to detect
when the VDD of the device drops below a threshold
value, VLVD, which is determined by the LVDL<3:0>
bits (RCON<11:8>) and is thus user programmable.
The internal voltage reference circuitry requires a nom-
inal amount of time to stabilize, and the BGST bit
(RCON<13>) indicates when the voltage reference has
stabilized.
If the clock source is an oscillator, the clock to the
device will be held off until OST times out (indicating a
stable oscillator). If PLL is used, the system clock is
held off until LOCK = 1 (indicating that the PLL is
stable). In either case, TPOR, TLOCK and TPWRT delays
are applied.
If EC, FRC, LPRC or EXTRC oscillators are used, then
a delay of TPOR (~ 10 µs) is applied. This is the smallest
delay possible on wake-up from Sleep.
In some devices, the LVD threshold voltage may be
applied externally on the LVDIN pin.
Moreover, if LP oscillator was active during Sleep and
LP is the oscillator used on wake-up, then the start-up
delay will be equal to TPOR. PWRT delay and OST
timer delay are not applied. In order to have -the small-
est possible start-up delay when waking up from Sleep,
one of these faster wake-up options should be selected
before entering Sleep.
The LVD module is enabled by setting the LVDEN bit
(RCON<12>).
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Any interrupt that is individually enabled (using the cor-
responding IE bit) and meets the prevailing priority level
will be able to wake-up the processor. The processor will
process the interrupt and branch to the ISR. The Sleep
status bit in the RCON register is set upon wake-up.
Any interrupt that is individually enabled (using IE bit)
and meets the prevailing priority level will be able to
wake-up the processor. The processor will process the
interrupt and branch to the ISR. The Idle status bit in
the RCON register is set upon wake-up.
Any Reset other than POR will set the Idle status bit.
On a POR, the Idle bit is cleared.
Note:
In spite of various delays applied (TPOR,
TLOCK and TPWRT), the crystal oscillator
(and PLL) may not be active at the end of
the time-out (e.g., for low frequency crys-
tals). In such cases, if FSCM is enabled,
then the device will detect this as a clock
failure and process the clock failure trap, the
FRC oscillator will be enabled and the user
will have to re-enable the crystal oscillator. If
FSCM is not enabled, then the device will
simply suspend execution of code until the
clock is stable and will remain in Sleep until
the oscillator clock has started.
If Watchdog Timer is enabled, then the processor will
wake-up from Idle mode upon WDT time-out. The Idle
and WDTO status bits are both set.
Unlike wake-up from Sleep, there are no time delays
involved in wake-up from Idle.
20.8 Device Configuration Registers
The configuration bits in each device configuration reg-
ister specify some of the Device modes and are
programmed by a device programmer, or by using the
In-Circuit Serial Programming™ (ICSP™) feature of
the device. Each device configuration register is a
24-bit register, but only the lower 16 bits of each regis-
ter are used to hold configuration data. There are four
device configuration registers available to the user:
All Resets will wake-up the processor from Sleep
mode. Any Reset, other than POR, will set the Sleep
status bit. In a POR, the Sleep bit is cleared.
If the Watchdog Timer is enabled, then the processor
will wake-up from Sleep mode upon WDT time-out. The
Sleep and WDTO status bits are both set.
1. FOSC (0xF80000): Oscillator Configuration
Register
20.7.2
IDLE MODE
2. FWDT (0xF80002): Watchdog Timer
Configuration Register
In Idle mode, the clock to the CPU is shutdown while
peripherals keep running. Unlike Sleep mode, the clock
source remains active.
3. FBORPOR (0xF80004): BOR and POR
Configuration Register
4. FGS (0xF8000A): General Code Segment
Configuration Register
Several peripherals have a control bit in each module
that allows them to operate during Idle.
The placement of the configuration bits is automatically
handled when you select the device in your device pro-
grammer. The desired state of the configuration bits
may be specified in the source code (dependent on the
language tool used), or through the programming inter-
face. After the device has been programmed, the appli-
cation software may read the configuration bit values
through the table read instructions. For additional infor-
mation, please refer to the Programming Specifications
of the device.
LPRC Fail-Safe Clock remains active if clock failure
detect is enabled.
The processor wakes up from Idle if at least one of the
following conditions has occurred:
• any interrupt that is individually enabled (IE bit is
‘1’) and meets the required priority level
• any Reset (POR, BOR, MCLR)
• WDT time-out
Upon wake-up from Idle mode, the clock is re-applied
to the CPU and instruction execution begins immedi-
ately, starting with the instruction following the PWRSAV
instruction.
Note:
If the code protection configuration fuse
bits (FGS<GCP> and FGS<GWRP>)
have been programmed, an erase of the
entire code-protected device is only
possible at voltages VDD ≥ 4.5V.
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20.9 Peripheral Module Disable (PMD)
Registers
20.10 In-Circuit Debugger
When MPLAB ICD2 is selected as a Debugger, the In-
Circuit Debugging functionality is enabled. This func-
tion allows simple debugging functions when used with
MPLAB IDE. When the device has this feature enabled,
some of the resources are not available for general
use. These resources include the first 80 bytes of Data
RAM and two I/O pins.
The Peripheral Module Disable (PMD) registers pro-
vide a method to disable a peripheral module by stop-
ping all clock sources supplied to that module. When a
peripheral is disabled via the appropriate PMD control
bit, the peripheral is in a minimum power consumption
state. The control and status registers associated with
the peripheral will also be disabled so writes to those
registers will have no effect and read values will be
invalid.
One of four pairs of Debug I/O pins may be selected by
the user using configuration options in MPLAB IDE.
These pin pairs are named EMUD/EMUC, EMUD1/
EMUC1, EMUD2/EMUC2 and MUD3/EMUC3.
A peripheral module will only be enabled if both the
associated bit in the the PMD register is cleared and
the peripheral is supported by the specific dsPIC vari-
ant. If the peripheral is present in the device, it is
enabled in the PMD register by default.
In each case, the selected EMUD pin is the Emulation/
Debug Data line, and the EMUC pin is the Emulation/
Debug Clock line. These pins will interface to the
MPLAB ICD 2 module available from Microchip. The
selected pair of Debug I/O pins is used by MPLAB
ICD 2 to send commands and receive responses, as
well as to send and receive data. To use the In-Circuit
Debugger function of the device, the design must
implement ICSP connections to MCLR, VDD, VSS,
PGC, PGD, and the selected EMUDx/EMUCx pin pair.
Note:
If a PMD bit is set, the corresponding mod-
ule is disabled after a delay of 1 instruction
cycle. Similarly, if a PMD bit is cleared, the
corresponding module is enabled after a
delay of 1 instruction cycle (assuming the
module control registers are already
configured to enable module operation).
This gives rise to two possibilities:
1. If EMUD/EMUC is selected as the Debug I/O pin
pair, then only a 5-pin interface is required, as
the EMUD and EMUC pin functions are multi-
plexed with the PGD and PGC pin functions in
all dsPIC30F devices.
Note:
In the dsPIC30F3014 device, the T4MD,
T5MD, IC7MD, IC8MD, OC3MD, OC4MD
and DCIMD are readable and writeable,
and will be read as “1” when set.
2. If EMUD1/EMUC1, EMUD2/EMUC2 or EMUD3/
EMUC3 is selected as the Debug I/O pin pair,
then a 7-pin interface is required, as the
EMUDx/EMUCx pin functions (x = 1, 2 or 3) are
not multiplexed with the PGD and PGC pin
functions.
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Most bit-oriented instructions (including simple rotate/
shift instructions) have two operands:
21.0 INSTRUCTION SET SUMMARY
Note: This data sheet summarizes features of this group
of dsPIC30F devices and is not intended to be a complete
reference source. For more information on the CPU,
peripherals, register descriptions and general device
functionality, refer to the dsPIC30F Family Reference
Manual (DS70046). For more information on the device
instruction set and programming, refer to the dsPIC30F
Programmer’s Reference Manual (DS70030).
• The W register (with or without an address
modifier) or file register (specified by the value of
‘Ws’ or ‘f’)
• The bit in the W register or file register
(specified by a literal value or indirectly by the
contents of register ‘Wb’)
The literal instructions that involve data movement may
use some of the following operands:
The dsPIC30F instruction set adds many
enhancements to the previous PICmicro® instruction
sets, while maintaining an easy migration from
PICmicro instruction sets.
• A literal value to be loaded into a W register or file
register (specified by the value of ‘k’)
• The W register or file register where the literal
value is to be loaded (specified by ‘Wb’ or ‘f’)
Most instructions are a single program memory word
(24 bits). Only three instructions require two program
memory locations.
However, literal instructions that involve arithmetic or
logical operations use some of the following operands:
Each single word instruction is a 24-bit word divided
into an 8-bit opcode which specifies the instruction
type, and one or more operands which further specify
the operation of the instruction.
• The first source operand which is a register ‘Wb’
without any address modifier
• The second source operand which is a literal
value
The instruction set is highly orthogonal and is grouped
into five basic categories:
• The destination of the result (only if not the same
as the first source operand) which is typically a
register ‘Wd’ with or without an address modifier
• Word or byte-oriented operations
• Bit-oriented operations
• Literal operations
The MACclass of DSP instructions may use some of the
following operands:
• DSP operations
• The accumulator (A or B) to be used (required
operand)
• Control operations
Table 21-1 shows the general symbols used in
describing the instructions.
• The W registers to be used as the two operands
• The X and Y address space pre-fetch operations
• The X and Y address space pre-fetch destinations
• The accumulator write back destination
The dsPIC30F instruction set summary in Table 21-2
lists all the instructions, along with the status flags
affected by each instruction.
The other DSP instructions do not involve any
multiplication, and may include:
Most word or byte-oriented W register instructions
(including barrel shift instructions) have three
operands:
• The accumulator to be used (required)
• The first source operand which is typically a
register ‘Wb’ without any address modifier
• The source or destination operand (designated as
Wso or Wdo, respectively) with or without an
address modifier
• The second source operand which is typically a
register ‘Ws’ with or without an address modifier
• The amount of shift specified by a W register ‘Wn’
or a literal value
• The destination of the result which is typically a
register ‘Wd’ with or without an address modifier
The control instructions may use some of the following
operands:
However, word or byte-oriented file register instructions
have two operands:
• A program memory address
• The file register specified by the value ‘f’
• The mode of the table read and table write
instructions
• The destination, which could either be the file
register ‘f’ or the W0 register, which is denoted as
‘WREG’
All instructions are a single word, except for certain
double-word instructions, which were made double-
word instructions so that all the required information is
available in these 48 bits. In the second word, the
8 MSbs are ‘0’s. If this second word is executed as an
instruction (by itself), it will execute as a NOP.
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Most single word instructions are executed in a single
instruction cycle, unless a conditional test is true or
the program counter is changed as a result of the
instruction. In these cases, the execution takes two
instruction cycles with the additional instruction
cycle(s) executed as a NOP. Notable exceptions are the
BRA (unconditional/computed branch), indirect CALL/
GOTO, all table reads and writes, and RETURN/RETFIE
instructions, which are single word instructions but take
two or three cycles. Certain instructions that involve
skipping over the subsequent instruction require either
two or three cycles if the skip is performed, depending
on whether the instruction being skipped is a single
word or two-word instruction. Moreover, double-word
moves require two cycles. The double-word
instructions execute in two instruction cycles.
Note:
For more details on the instruction set,
refer to the Programmer’s Reference
Manual.
TABLE 21-1: SYMBOLS USED IN OPCODE DESCRIPTIONS
Field Description
#text
(text)
[text]
{ }
Means literal defined by “text”
Means “content of text”
Means “the location addressed by text”
Optional field or operation
Register bit field
<n:m>
.b
Byte mode selection
.d
Double-Word mode selection
Shadow register select
.S
.w
Word mode selection (default)
One of two accumulators {A, B}
Acc
AWB
bit4
Accumulator write back destination address register ∈ {W13, [W13]+=2}
4-bit bit selection field (used in word addressed instructions) ∈ {0...15}
MCU status bits: Carry, Digit Carry, Negative, Overflow, Sticky Zero
Absolute address, label or expression (resolved by the linker)
File register address ∈ {0x0000...0x1FFF}
1-bit unsigned literal ∈ {0,1}
C, DC, N, OV, Z
Expr
f
lit1
lit4
4-bit unsigned literal ∈ {0...15}
lit5
5-bit unsigned literal ∈ {0...31}
lit8
8-bit unsigned literal ∈ {0...255}
lit10
10-bit unsigned literal ∈ {0...255} for Byte mode, {0:1023} for Word mode
14-bit unsigned literal ∈ {0...16384}
lit14
lit16
16-bit unsigned literal ∈ {0...65535}
lit23
23-bit unsigned literal ∈ {0...8388608}; LSB must be 0
Field does not require an entry, may be blank
DSP status bits: AccA Overflow, AccB Overflow, AccA Saturate, AccB Saturate
Program Counter
None
OA, OB, SA, SB
PC
Slit10
Slit16
Slit6
10-bit signed literal ∈ {-512...511}
16-bit signed literal ∈ {-32768...32767}
6-bit signed literal ∈ {-16...16}
DS70138C-page 150
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 21-1: SYMBOLS USED IN OPCODE DESCRIPTIONS (CONTINUED)
Field Description
Wb
Base W register ∈ {W0..W15}
Wd
Destination W register ∈ { Wd, [Wd], [Wd++], [Wd--], [++Wd], [--Wd] }
Wdo
Destination W register ∈
{ Wnd, [Wnd], [Wnd++], [Wnd--], [++Wnd], [--Wnd], [Wnd+Wb] }
Wm,Wn
Dividend, Divisor working register pair (direct addressing)
Wm*Wm
Multiplicand and Multiplier working register pair for Square instructions ∈
{W4*W4,W5*W5,W6*W6,W7*W7}
Wm*Wn
Multiplicand and Multiplier working register pair for DSP instructions ∈
{W4*W5,W4*W6,W4*W7,W5*W6,W5*W7,W6*W7}
Wn
One of 16 working registers ∈ {W0..W15}
Wnd
Wns
WREG
Ws
One of 16 destination working registers ∈ {W0..W15}
One of 16 source working registers ∈ {W0..W15}
W0 (working register used in file register instructions)
Source W register ∈ { Ws, [Ws], [Ws++], [Ws--], [++Ws], [--Ws] }
Wso
Source W register ∈
{ Wns, [Wns], [Wns++], [Wns--], [++Wns], [--Wns], [Wns+Wb] }
Wx
X data space pre-fetch address register for DSP instructions
∈ {[W8]+=6, [W8]+=4, [W8]+=2, [W8], [W8]-=6, [W8]-=4, [W8]-=2,
[W9]+=6, [W9]+=4, [W9]+=2, [W9], [W9]-=6, [W9]-=4, [W9]-=2,
[W9+W12],none}
Wxd
Wy
X data space pre-fetch destination register for DSP instructions ∈ {W4..W7}
Y data space pre-fetch address register for DSP instructions
∈ {[W10]+=6, [W10]+=4, [W10]+=2, [W10], [W10]-=6, [W10]-=4, [W10]-=2,
[W11]+=6, [W11]+=4, [W11]+=2, [W11], [W11]-=6, [W11]-=4, [W11]-=2,
[W11+W12], none}
Wyd
Y data space pre-fetch destination register for DSP instructions ∈ {W4..W7}
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 151
dsPIC30F3014/4013
TABLE 21-2: INSTRUCTION SET OVERVIEW
Base
Assembly
# of
# of
Status Flags
Affected
Instr
Assembly Syntax
Description
Mnemonic
Words Cycles
#
1
ADD
ADD
ADD
ADD
ADD
ADD
ADD
ADD
ADDC
ADDC
ADDC
ADDC
ADDC
AND
AND
AND
AND
AND
ASR
ASR
ASR
ASR
ASR
BCLR
BCLR
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BRA
BSET
BSET
BSW.C
BSW.Z
Acc
Add Accumulators
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
OA,OB,SA,SB
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
OA,OB,SA,SB
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
N,Z
f
f = f + WREG
f,WREG
#lit10,Wn
Wb,Ws,Wd
Wb,#lit5,Wd
Wso,#Slit4,Acc
f
WREG = f + WREG
1
Wd = lit10 + Wd
1
Wd = Wb + Ws
1
Wd = Wb + lit5
1
16-bit Signed Add to Accumulator
f = f + WREG + (C)
1
2
3
4
ADDC
1
f,WREG
#lit10,Wn
Wb,Ws,Wd
Wb,#lit5,Wd
f
WREG = f + WREG + (C)
Wd = lit10 + Wd + (C)
Wd = Wb + Ws + (C)
1
1
1
Wd = Wb + lit5 + (C)
1
AND
f = f .AND. WREG
1
f,WREG
#lit10,Wn
Wb,Ws,Wd
Wb,#lit5,Wd
f
WREG = f .AND. WREG
Wd = lit10 .AND. Wd
1
N,Z
1
N,Z
Wd = Wb .AND. Ws
1
N,Z
Wd = Wb .AND. lit5
1
N,Z
ASR
f = Arithmetic Right Shift f
WREG = Arithmetic Right Shift f
Wd = Arithmetic Right Shift Ws
Wnd = Arithmetic Right Shift Wb by Wns
Wnd = Arithmetic Right Shift Wb by lit5
Bit Clear f
1
C,N,OV,Z
C,N,OV,Z
C,N,OV,Z
N,Z
f,WREG
Ws,Wd
1
1
Wb,Wns,Wnd
Wb,#lit5,Wnd
f,#bit4
1
1
N,Z
5
6
BCLR
BRA
1
None
Ws,#bit4
C,Expr
Bit Clear Ws
1
None
Branch if Carry
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
1 (2)
2
None
GE,Expr
GEU,Expr
GT,Expr
GTU,Expr
LE,Expr
LEU,Expr
LT,Expr
LTU,Expr
N,Expr
Branch if greater than or equal
Branch if unsigned greater than or equal
Branch if greater than
Branch if unsigned greater than
Branch if less than or equal
Branch if unsigned less than or equal
Branch if less than
None
None
None
None
None
None
None
Branch if unsigned less than
Branch if Negative
None
None
NC,Expr
NN,Expr
NOV,Expr
NZ,Expr
OA,Expr
OB,Expr
OV,Expr
SA,Expr
SB,Expr
Expr
Branch if Not Carry
None
Branch if Not Negative
Branch if Not Overflow
Branch if Not Zero
None
None
None
Branch if Accumulator A overflow
Branch if Accumulator B overflow
Branch if Overflow
None
None
None
Branch if Accumulator A saturated
Branch if Accumulator B saturated
Branch Unconditionally
Branch if Zero
None
None
None
Z,Expr
1 (2)
2
None
Wn
Computed Branch
None
7
8
BSET
BSW
f,#bit4
Bit Set f
1
None
Ws,#bit4
Ws,Wb
Bit Set Ws
1
None
Write C bit to Ws<Wb>
Write Z bit to Ws<Wb>
1
None
Ws,Wb
1
None
DS70138C-page 152
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 21-2: INSTRUCTION SET OVERVIEW (CONTINUED)
Base
Instr
#
Assembly
Mnemonic
# of
# of
Status Flags
Affected
Assembly Syntax
Description
Words Cycles
9
BTG
BTG
BTG
BTSC
f,#bit4
Bit Toggle f
1
1
1
1
1
None
None
None
Ws,#bit4
f,#bit4
Bit Toggle Ws
10
11
12
BTSC
Bit Test f, Skip if Clear
Bit Test Ws, Skip if Clear
Bit Test f, Skip if Set
1
(2 or 3)
BTSC
BTSS
BTSS
Ws,#bit4
f,#bit4
1
1
1
1
None
None
None
(2 or 3)
BTSS
1
(2 or 3)
Ws,#bit4
Bit Test Ws, Skip if Set
1
(2 or 3)
BTST
BTST
f,#bit4
Bit Test f
1
1
1
1
1
1
1
1
2
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Z
BTST.C
BTST.Z
BTST.C
BTST.Z
BTSTS
Ws,#bit4
Ws,#bit4
Ws,Wb
Ws,Wb
f,#bit4
Bit Test Ws to C
C
Z
Bit Test Ws to Z
Bit Test Ws<Wb> to C
Bit Test Ws<Wb> to Z
Bit Test then Set f
C
Z
13
BTSTS
Z
BTSTS.C Ws,#bit4
BTSTS.Z Ws,#bit4
Bit Test Ws to C, then Set
Bit Test Ws to Z, then Set
Call subroutine
C
Z
14
15
CALL
CLR
CALL
CALL
CLR
CLR
CLR
CLR
CLRWDT
COM
COM
COM
CP
lit23
None
Wn
Call indirect subroutine
f = 0x0000
None
f
None
WREG
WREG = 0x0000
None
Ws
Ws = 0x0000
None
Acc,Wx,Wxd,Wy,Wyd,AWB
Clear Accumulator
Clear Watchdog Timer
f = f
OA,OB,SA,SB
WDTO,Sleep
N,Z
16
17
CLRWDT
COM
f
f,WREG
WREG = f
N,Z
Ws,Wd
Wd = Ws
N,Z
18
CP
f
Compare f with WREG
Compare Wb with lit5
Compare Wb with Ws (Wb - Ws)
Compare f with 0x0000
Compare Ws with 0x0000
Compare f with 0xFFFF
Compare Ws with 0xFFFF
Compare f with WREG, with Borrow
Compare Wb with lit5, with Borrow
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
CP
Wb,#lit5
CP
Wb,Ws
19
20
21
CP0
CP1
CPB
CP0
CP0
CP1
CP1
CPB
CPB
CPB
f
Ws
f
Ws
f
Wb,#lit5
Wb,Ws
Compare Wb with Ws, with Borrow
(Wb - Ws - C)
22
23
24
25
CPSEQ
CPSGT
CPSLT
CPSNE
CPSEQ
CPSGT
CPSLT
CPSNE
Wb, Wn
Wb, Wn
Wb, Wn
Wb, Wn
Compare Wb with Wn, skip if =
Compare Wb with Wn, skip if >
Compare Wb with Wn, skip if <
Compare Wb with Wn, skip if ≠
1
1
1
1
1
None
None
None
None
(2 or 3)
1
(2 or 3)
1
(2 or 3)
1
(2 or 3)
26
27
DAW
DEC
DAW
DEC
Wn
Wn = decimal adjust Wn
f = f -1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
C
f
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
DEC
f,WREG
Ws,Wd
f
WREG = f -1
Wd = Ws - 1
f = f -2
DEC
28
DEC2
DEC2
DEC2
DEC2
f,WREG
Ws,Wd
WREG = f -2
Wd = Ws - 2
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 153
dsPIC30F3014/4013
TABLE 21-2: INSTRUCTION SET OVERVIEW (CONTINUED)
Base
Assembly
# of
# of
Status Flags
Affected
Instr
Assembly Syntax
Description
Mnemonic
Words Cycles
#
29
DISI
DIV
DISI
#lit14
Disable Interrupts for k instruction cycles
Signed 16/16-bit Integer Divide
1
1
1
1
1
1
2
2
1
1
18
18
18
18
18
2
None
30
DIV.S
DIV.SD
DIV.U
DIV.UD
DIVF
DO
Wm,Wn
N,Z,C,OV
N,Z,C,OV
N,Z,C,OV
N,Z,C,OV
N,Z,C,OV
None
Wm,Wn
Signed 32/16-bit Integer Divide
Wm,Wn
Unsigned 16/16-bit Integer Divide
Unsigned 32/16-bit Integer Divide
Signed 16/16-bit Fractional Divide
Do code to PC+Expr, lit14+1 times
Do code to PC+Expr, (Wn)+1 times
Euclidean Distance (no accumulate)
Wm,Wn
31
32
DIVF
DO
Wm,Wn
#lit14,Expr
Wn,Expr
DO
2
None
33
34
ED
ED
Wm*Wm,Acc,Wx,Wy,Wxd
1
OA,OB,OAB,
SA,SB,SAB
EDAC
EDAC
Wm*Wm,Acc,Wx,Wy,Wxd
Euclidean Distance
1
1
OA,OB,OAB,
SA,SB,SAB
35
36
37
38
39
EXCH
FBCL
FF1L
EXCH
FBCL
FF1L
FF1R
GOTO
GOTO
INC
Wns,Wnd
Ws,Wnd
Ws,Wnd
Ws,Wnd
Expr
Swap Wns with Wnd
Find Bit Change from Left (MSb) Side
Find First One from Left (MSb) Side
Find First One from Right (LSb) Side
Go to address
1
1
1
1
2
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
1
1
1
1
1
1
1
1
1
1
1
1
None
C
C
FF1R
GOTO
C
None
Wn
Go to indirect
None
40
41
42
INC
f
f = f + 1
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
N,Z
INC
f,WREG
Ws,Wd
f
WREG = f + 1
INC
Wd = Ws + 1
INC2
INC2
INC2
INC2
IOR
f = f + 2
f,WREG
Ws,Wd
f
WREG = f + 2
Wd = Ws + 2
IOR
f = f .IOR. WREG
IOR
f,WREG
#lit10,Wn
Wb,Ws,Wd
Wb,#lit5,Wd
Wso,#Slit4,Acc
WREG = f .IOR. WREG
Wd = lit10 .IOR. Wd
Wd = Wb .IOR. Ws
Wd = Wb .IOR. lit5
Load Accumulator
N,Z
IOR
N,Z
IOR
N,Z
IOR
N,Z
43
LAC
LAC
OA,OB,OAB,
SA,SB,SAB
44
45
LNK
LSR
LNK
LSR
LSR
LSR
LSR
LSR
MAC
#lit14
Link frame pointer
1
1
1
1
1
1
1
1
1
1
1
1
1
1
None
C,N,OV,Z
C,N,OV,Z
C,N,OV,Z
N,Z
f
f = Logical Right Shift f
f,WREG
Ws,Wd
WREG = Logical Right Shift f
Wd = Logical Right Shift Ws
Wnd = Logical Right Shift Wb by Wns
Wnd = Logical Right Shift Wb by lit5
Wb,Wns,Wnd
Wb,#lit5,Wnd
N,Z
46
MAC
Wm*Wn,Acc,Wx,Wxd,Wy,Wyd, Multiply and Accumulate
AWB
OA,OB,OAB,
SA,SB,SAB
MAC
Wm*Wm,Acc,Wx,Wxd,Wy,Wyd Square and Accumulate
1
1
OA,OB,OAB,
SA,SB,SAB
47
MOV
MOV
f,Wn
Move f to Wn
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
1
None
N,Z
MOV
f
Move f to f
MOV
f,WREG
#lit16,Wn
#lit8,Wn
Wn,f
Move f to WREG
N,Z
MOV
Move 16-bit literal to Wn
Move 8-bit literal to Wn
Move Wn to f
None
None
None
None
N,Z
MOV.b
MOV
MOV
Wso,Wdo
WREG,f
Wns,Wd
Ws,Wnd
Move Ws to Wd
MOV
Move WREG to f
MOV.D
MOV.D
Move Double from W(ns):W(ns+1) to Wd
Move Double from Ws to W(nd+1):W(nd)
Pre-fetch and store accumulator
None
None
None
48
MOVSAC
MOVSAC Acc,Wx,Wxd,Wy,Wyd,AWB
DS70138C-page 154
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 21-2: INSTRUCTION SET OVERVIEW (CONTINUED)
Base
Instr
#
Assembly
Mnemonic
# of
# of
Status Flags
Affected
Assembly Syntax
Description
Words Cycles
49
MPY
MPY
MPY
Wm*Wn,Acc,Wx,Wxd,Wy,Wyd
Wm*Wm,Acc,Wx,Wxd,Wy,Wyd
Wm*Wn,Acc,Wx,Wxd,Wy,Wyd
Multiply Wm by Wn to Accumulator
Square Wm to Accumulator
1
1
1
1
OA,OB,OAB,
SA,SB,SAB
OA,OB,OAB,
SA,SB,SAB
50
51
MPY.N
MSC
MPY.N
MSC
-(Multiply Wm by Wn) to Accumulator
1
1
1
1
None
Wm*Wm,Acc,Wx,Wxd,Wy,Wyd, Multiply and Subtract from Accumulator
AWB
OA,OB,OAB,
SA,SB,SAB
52
MUL
MUL.SS
MUL.SU
MUL.US
Wb,Ws,Wnd
Wb,Ws,Wnd
Wb,Ws,Wnd
{Wnd+1, Wnd} = signed(Wb) * signed(Ws)
{Wnd+1, Wnd} = signed(Wb) * unsigned(Ws)
{Wnd+1, Wnd} = unsigned(Wb) * signed(Ws)
1
1
1
1
1
1
1
1
None
None
None
None
MUL.UU Wb,Ws,Wnd
{Wnd+1, Wnd} = unsigned(Wb) *
unsigned(Ws)
MUL.SU
Wb,#lit5,Wnd
{Wnd+1, Wnd} = signed(Wb) * unsigned(lit5)
1
1
1
1
None
None
MUL.UU Wb,#lit5,Wnd
{Wnd+1, Wnd} = unsigned(Wb) *
unsigned(lit5)
MUL
NEG
f
W3:W2 = f * WREG
Negate Accumulator
1
1
1
1
None
53
NEG
Acc
OA,OB,OAB,
SA,SB,SAB
NEG
NEG
NEG
NOP
NOPR
POP
f
f = f + 1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
None
f,WREG
Ws,Wd
WREG = f + 1
Wd = Ws + 1
54
55
NOP
POP
No Operation
No Operation
None
f
Pop f from top-of-stack (TOS)
Pop from top-of-stack (TOS) to Wdo
None
POP
Wdo
Wnd
None
POP.D
Pop from top-of-stack (TOS) to
W(nd):W(nd+1)
None
POP.S
Pop Shadow Registers
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
All
None
None
None
None
WDTO,Sleep
None
None
None
None
None
None
None
None
C,N,Z
C,N,Z
C,N,Z
N,Z
56
PUSH
PUSH
f
Push f to top-of-stack (TOS)
Push Wso to top-of-stack (TOS)
Push W(ns):W(ns+1) to top-of-stack (TOS)
Push Shadow Registers
PUSH
Wso
Wns
1
PUSH.D
PUSH.S
PWRSAV
RCALL
RCALL
2
1
57
58
PWRSAV
RCALL
#lit1
Expr
Wn
Go into Sleep or Idle mode
Relative Call
1
2
Computed Call
2
59
REPEAT
REPEAT #lit14
REPEAT Wn
RESET
Repeat Next Instruction lit14+1 times
Repeat Next Instruction (Wn)+1 times
Software device Reset
1
1
60
61
62
63
64
RESET
RETFIE
RETLW
RETURN
RLC
1
RETFIE
Return from interrupt
3 (2)
3 (2)
3 (2)
1
RETLW
RETURN
RLC
#lit10,Wn
Return with literal in Wn
Return from Subroutine
f
f = Rotate Left through Carry f
WREG = Rotate Left through Carry f
Wd = Rotate Left through Carry Ws
f = Rotate Left (No Carry) f
RLC
f,WREG
Ws,Wd
f
1
RLC
1
65
66
67
RLNC
RLNC
RLNC
RLNC
RRC
1
f,WREG
Ws,Wd
f
WREG = Rotate Left (No Carry) f
Wd = Rotate Left (No Carry) Ws
f = Rotate Right through Carry f
WREG = Rotate Right through Carry f
Wd = Rotate Right through Carry Ws
f = Rotate Right (No Carry) f
WREG = Rotate Right (No Carry) f
Wd = Rotate Right (No Carry) Ws
1
N,Z
1
N,Z
RRC
1
C,N,Z
C,N,Z
C,N,Z
N,Z
RRC
f,WREG
Ws,Wd
f
1
RRC
1
RRNC
RRNC
RRNC
RRNC
1
f,WREG
Ws,Wd
1
N,Z
1
N,Z
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 155
dsPIC30F3014/4013
TABLE 21-2: INSTRUCTION SET OVERVIEW (CONTINUED)
Base
Assembly
# of
# of
Status Flags
Affected
Instr
Assembly Syntax
Description
Mnemonic
Words Cycles
#
68
SAC
SAC
Acc,#Slit4,Wdo
Acc,#Slit4,Wdo
Ws,Wnd
f
Store Accumulator
1
1
1
1
1
1
1
1
1
1
1
1
1
1
None
None
C,N,Z
None
None
None
SAC.R
SE
Store Rounded Accumulator
Wnd = sign-extended Ws
f = 0xFFFF
69
70
SE
SETM
SETM
SETM
SETM
SFTAC
WREG
WREG = 0xFFFF
Ws
Ws = 0xFFFF
71
SFTAC
Acc,Wn
Arithmetic Shift Accumulator by (Wn)
OA,OB,OAB,
SA,SB,SAB
SFTAC
Acc,#Slit6
Arithmetic Shift Accumulator by Slit6
1
1
OA,OB,OAB,
SA,SB,SAB
72
SL
SL
f
f = Left Shift f
1
1
1
1
1
1
1
1
1
1
1
1
C,N,OV,Z
C,N,OV,Z
C,N,OV,Z
N,Z
SL
f,WREG
Ws,Wd
Wb,Wns,Wnd
Wb,#lit5,Wnd
Acc
WREG = Left Shift f
Wd = Left Shift Ws
SL
SL
Wnd = Left Shift Wb by Wns
Wnd = Left Shift Wb by lit5
Subtract Accumulators
SL
N,Z
73
SUB
SUB
OA,OB,OAB,
SA,SB,SAB
SUB
f
f = f - WREG
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
2
2
1
1
1
1
1
1
1
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
C,DC,N,OV,Z
None
SUB
f,WREG
#lit10,Wn
Wb,Ws,Wd
Wb,#lit5,Wd
f
WREG = f - WREG
Wn = Wn - lit10
SUB
SUB
Wd = Wb - Ws
SUB
Wd = Wb - lit5
74
SUBB
SUBB
SUBB
SUBB
SUBB
SUBB
SUBR
SUBR
SUBR
SUBR
SUBBR
SUBBR
SUBBR
SUBBR
SWAP.b
SWAP
f = f - WREG - (C)
f,WREG
#lit10,Wn
Wb,Ws,Wd
Wb,#lit5,Wd
f
WREG = f - WREG - (C)
Wn = Wn - lit10 - (C)
Wd = Wb - Ws - (C)
Wd = Wb - lit5 - (C)
f = WREG - f
75
76
77
SUBR
SUBBR
SWAP
f,WREG
Wb,Ws,Wd
Wb,#lit5,Wd
f
WREG = WREG - f
Wd = Ws - Wb
Wd = lit5 - Wb
f = WREG - f - (C)
f,WREG
Wb,Ws,Wd
Wb,#lit5,Wd
Wn
WREG = WREG -f - (C)
Wd = Ws - Wb - (C)
Wd = lit5 - Wb - (C)
Wn = nibble swap Wn
Wn = byte swap Wn
Read Prog<23:16> to Wd<7:0>
Read Prog<15:0> to Wd
Write Ws<7:0> to Prog<23:16>
Write Ws to Prog<15:0>
Unlink frame pointer
f = f .XOR. WREG
WREG = f .XOR. WREG
Wd = lit10 .XOR. Wd
Wd = Wb .XOR. Ws
Wd = Wb .XOR. lit5
Wnd = Zero-extend Ws
Wn
None
78
79
80
81
82
83
TBLRDH
TBLRDL
TBLWTH
TBLWTL
ULNK
TBLRDH Ws,Wd
TBLRDL Ws,Wd
TBLWTH Ws,Wd
TBLWTL Ws,Wd
ULNK
None
None
None
None
None
XOR
XOR
XOR
XOR
XOR
XOR
ZE
f
N,Z
f,WREG
#lit10,Wn
Wb,Ws,Wd
Wb,#lit5,Wd
Ws,Wnd
N,Z
N,Z
N,Z
N,Z
84
ZE
C,Z,N
DS70138C-page 156
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
22.1 MPLAB Integrated Development
Environment Software
22.0 DEVELOPMENT SUPPORT
The dsPIC® and PICmicro® microcontrollers are sup-
ported with a full range of hardware and software
development tools:
The MPLAB IDE software brings an ease of software
development previously unseen in the 8/16-bit micro-
controller market. The MPLAB IDE is a Windows®
based application that contains:
• Integrated Development Environment
- MPLAB® IDE Software
• An interface to debugging tools
- simulator
• Assemblers/Compilers/Linkers
- MPASMTM Assembler
- programmer (sold separately)
- emulator (sold separately)
- MPLAB C17 and MPLAB C18 C Compilers
- MPLINKTM Object Linker/
MPLIBTM Object Librarian
- in-circuit debugger (sold separately)
• A full-featured editor with color coded context
• A multiple project manager
- MPLAB C30 C Compiler
- MPLAB ASM30 Assembler/Linker/Library
• Simulators
• Customizable data windows with direct edit of
contents
- MPLAB SIM Software Simulator
- MPLAB dsPIC30 Software Simulator
• Emulators
• High-level source code debugging
• Mouse over variable inspection
• Extensive on-line help
- MPLAB ICE 2000 In-Circuit Emulator
- MPLAB ICE 4000 In-Circuit Emulator
• In-Circuit Debugger
The MPLAB IDE allows you to:
• Edit your source files (either assembly or C)
- MPLAB ICD 2
• One touch assemble (or compile) and download
to PICmicro emulator and simulator tools
• Device Programmers
- PRO MATE® II Universal Device Programmer
- PICSTART® Plus Development Programmer
• Low-Cost Demonstration Boards
- PICDEMTM 1 Demonstration Board
- PICDEM.netTM Demonstration Board
- PICDEM 2 Plus Demonstration Board
- PICDEM 3 Demonstration Board
- PICDEM 4 Demonstration Board
- PICDEM 17 Demonstration Board
- PICDEM 18R Demonstration Board
- PICDEM LIN Demonstration Board
- PICDEM USB Demonstration Board
• Evaluation Kits
(automatically updates all project information)
• Debug using:
- source files (assembly or C)
- absolute listing file (mixed assembly and C)
- machine code
MPLAB IDE supports multiple debugging tools in a
single development paradigm, from the cost effective
simulators, through low-cost in-circuit debuggers, to
full-featured emulators. This eliminates the learning
curve when upgrading to tools with increasing flexibility
and power.
22.2 MPASM Assembler
The MPASM assembler is a full-featured, universal
macro assembler for all PICmicro MCUs.
®
- KEELOQ
- PICDEM MSC
- microID®
- CAN
The MPASM assembler generates relocatable object
files for the MPLINK object linker, Intel® standard HEX
files, MAP files to detail memory usage and symbol ref-
erence, absolute LST files that contain source lines and
generated machine code and COFF files for
debugging.
- PowerSmart®
- Analog
The MPASM assembler features include:
• Integration into MPLAB IDE projects
• User defined macros to streamline assembly code
• Conditional assembly for multi-purpose source
files
• Directives that allow complete control over the
assembly process
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 157
dsPIC30F3014/4013
22.3 MPLAB C17 and MPLAB C18
C Compilers
22.6 MPLAB ASM30 Assembler, Linker
and Librarian
The MPLAB C17 and MPLAB C18 Code Development
MPLAB ASM30 assembler produces relocatable
machine code from symbolic assembly language for
dsPIC30F devices. MPLAB C30 compiler uses the
assembler to produce it’s object file. The assembler
generates relocatable object files that can then be
archived or linked with other relocatable object files and
archives to create an executable file. Notable features
of the assembler include:
Systems are complete ANSI
C
compilers for
Microchip’s PIC17CXXX and PIC18CXXX family of
microcontrollers. These compilers provide powerful
integration capabilities, superior code optimization and
ease of use not found with other compilers.
For easy source level debugging, the compilers provide
symbol information that is optimized to the MPLAB IDE
debugger.
• Support for the entire dsPIC30F instruction set
• Support for fixed-point and floating-point data
• Command line interface
22.4 MPLINK Object Linker/
MPLIB Object Librarian
• Rich directive set
The MPLINK object linker combines relocatable
objects created by the MPASM assembler and the
MPLAB C17 and MPLAB C18 C compilers. It can link
relocatable objects from precompiled libraries, using
directives from a linker script.
• Flexible macro language
• MPLAB IDE compatibility
22.7 MPLAB SIM Software Simulator
The MPLAB SIM software simulator allows code devel-
opment in a PC hosted environment by simulating the
PICmicro series microcontrollers on an instruction
level. On any given instruction, the data areas can be
examined or modified and stimuli can be applied from
a file, or user defined key press, to any pin. The execu-
tion can be performed in Single-Step, Execute Until
Break or Trace mode.
The MPLIB object librarian manages the creation and
modification of library files of precompiled code. When
a routine from a library is called from a source file, only
the modules that contain that routine will be linked in
with the application. This allows large libraries to be
used efficiently in many different applications.
The object linker/library features include:
• Efficient linking of single libraries instead of many
smaller files
The MPLAB SIM simulator fully supports symbolic
debugging using the MPLAB C17 and MPLAB C18
C Compilers, as well as the MPASM assembler. The
software simulator offers the flexibility to develop and
debug code outside of the laboratory environment,
making it an excellent, economical software
development tool.
• Enhanced code maintainability by grouping
related modules together
• Flexible creation of libraries with easy module
listing, replacement, deletion and extraction
22.5 MPLAB C30 C Compiler
22.8 MPLAB SIM30 Software Simulator
The MPLAB C30 C compiler is a full-featured, ANSI
compliant, optimizing compiler that translates standard
ANSI C programs into dsPIC30F assembly language
source. The compiler also supports many command
line options and language extensions to take full
advantage of the dsPIC30F device hardware capabili-
ties and afford fine control of the compiler code
generator.
The MPLAB SIM30 software simulator allows code
development in a PC hosted environment by simulating
the dsPIC30F series microcontrollers on an instruction
level. On any given instruction, the data areas can be
examined or modified and stimuli can be applied from
a file, or user defined key press, to any of the pins.
The MPLAB SIM30 simulator fully supports symbolic
debugging using the MPLAB C30 C Compiler and
MPLAB ASM30 assembler. The simulator runs in either
a Command Line mode for automated tasks, or from
MPLAB IDE. This high-speed simulator is designed to
debug, analyze and optimize time intensive DSP
routines.
MPLAB C30 is distributed with a complete ANSI C
standard library. All library functions have been vali-
dated and conform to the ANSI C library standard. The
library includes functions for string manipulation,
dynamic memory allocation, data conversion, time-
keeping and math functions (trigonometric, exponential
and hyperbolic). The compiler provides symbolic
information for high-level source debugging with the
MPLAB IDE.
DS70138C-page 158
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
22.9 MPLAB ICE 2000
High-Performance Universal
22.11 MPLAB ICD 2 In-Circuit Debugger
Microchip’s In-Circuit Debugger, MPLAB ICD 2, is a
powerful, low-cost, run-time development tool,
connecting to the host PC via an RS-232 or high-speed
USB interface. This tool is based on the Flash
PICmicro MCUs and can be used to develop for these
and other PICmicro microcontrollers. The MPLAB
ICD 2 utilizes the in-circuit debugging capability built
into the Flash devices. This feature, along with
In-Circuit Emulator
The MPLAB ICE 2000 universal in-circuit emulator is
intended to provide the product development engineer
with a complete microcontroller design tool set for
PICmicro microcontrollers. Software control of the
MPLAB ICE 2000 in-circuit emulator is advanced by
the MPLAB Integrated Development Environment,
which allows editing, building, downloading and source
debugging from a single environment.
Microchip’s In-Circuit Serial ProgrammingTM (ICSPTM
)
protocol, offers cost effective in-circuit Flash debugging
from the graphical user interface of the MPLAB
Integrated Development Environment. This enables a
designer to develop and debug source code by setting
breakpoints, single-stepping and watching variables,
CPU status and peripheral registers. Running at full
speed enables testing hardware and applications in
real-time. MPLAB ICD 2 also serves as a development
programmer for selected PICmicro devices.
The MPLAB ICE 2000 is a full-featured emulator sys-
tem with enhanced trace, trigger and data monitoring
features. Interchangeable processor modules allow the
system to be easily reconfigured for emulation of differ-
ent processors. The universal architecture of the
MPLAB ICE in-circuit emulator allows expansion to
support new PICmicro microcontrollers.
The MPLAB ICE 2000 in-circuit emulator system has
been designed as a real-time emulation system with
advanced features that are typically found on more
expensive development tools. The PC platform and
Microsoft® Windows 32-bit operating system were
chosen to best make these features available in a
simple, unified application.
22.12 PRO MATE II Universal Device
Programmer
The PRO MATE II is a universal, CE compliant device
programmer with programmable voltage verification at
VDDMIN and VDDMAX for maximum reliability. It features
an LCD display for instructions and error messages
and a modular detachable socket assembly to support
various package types. In Stand-Alone mode, the
PRO MATE II device programmer can read, verify and
program PICmicro devices without a PC connection. It
can also set code protection in this mode.
22.10 MPLAB ICE 4000
High-Performance Universal
In-Circuit Emulator
The MPLAB ICE 4000 universal in-circuit emulator is
intended to provide the product development engineer
with a complete microcontroller design tool set for high-
end PICmicro microcontrollers. Software control of the
MPLAB ICE in-circuit emulator is provided by the
MPLAB Integrated Development Environment, which
allows editing, building, downloading and source
debugging from a single environment.
22.13 PICSTART Plus Development
Programmer
The PICSTART Plus development programmer is an
easy-to-use, low-cost, prototype programmer. It con-
nects to the PC via a COM (RS-232) port. MPLAB
Integrated Development Environment software makes
using the programmer simple and efficient. The
PICSTART Plus development programmer supports
most PICmicro devices up to 40 pins. Larger pin count
devices, such as the PIC16C92X and PIC17C76X,
may be supported with an adapter socket. The
PICSTART Plus development programmer is CE
compliant.
The MPLAB ICD 4000 is a premium emulator system,
providing the features of MPLAB ICE 2000, but with
increased emulation memory and high-speed perfor-
mance for dsPIC30F and PIC18XXXX devices. Its
advanced emulator features include complex triggering
and timing, up to 2 Mb of emulation memory and the
ability to view variables in real-time.
The MPLAB ICE 4000 in-circuit emulator system has
been designed as a real-time emulation system with
advanced features that are typically found on more
expensive development tools. The PC platform and
Microsoft Windows 32-bit operating system were
chosen to best make these features available in a
simple, unified application.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 159
dsPIC30F3014/4013
22.14 PICDEM 1 PICmicro
Demonstration Board
22.17 PICDEM 3 PIC16C92X
Demonstration Board
The PICDEM 1 demonstration board demonstrates the
capabilities of the PIC16C5X (PIC16C54 to
PIC16C58A), PIC16C61, PIC16C62X, PIC16C71,
PIC16C8X, PIC17C42, PIC17C43 and PIC17C44. All
necessary hardware and software is included to run
basic demo programs. The sample microcontrollers
provided with the PICDEM 1 demonstration board can
be programmed with a PRO MATE II device program-
mer or a PICSTART Plus development programmer.
The PICDEM 1 demonstration board can be connected
to the MPLAB ICE in-circuit emulator for testing. A
prototype area extends the circuitry for additional appli-
cation components. Features include an RS-232
interface, a potentiometer for simulated analog input,
push button switches and eight LEDs.
The PICDEM 3 demonstration board supports the
PIC16C923 and PIC16C924 in the PLCC package. All
the necessary hardware and software is included to run
the demonstration programs.
22.18 PICDEM 4 8/14/18-Pin
Demonstration Board
The PICDEM 4 can be used to demonstrate the capa-
bilities of the 8, 14 and 18-pin PIC16XXXX and
PIC18XXXX MCUs, including the PIC16F818/819,
PIC16F87/88, PIC16F62XA and the PIC18F1320
family of microcontrollers. PICDEM 4 is intended to
showcase the many features of these low pin count
parts, including LIN and Motor Control using ECCP.
Special provisions are made for low-power operation
with the supercapacitor circuit and jumpers allow on-
board hardware to be disabled to eliminate current
draw in this mode. Included on the demo board are pro-
visions for Crystal, RC or Canned Oscillator modes, a
five volt regulator for use with a nine volt wall adapter
or battery, DB-9 RS-232 interface, ICD connector for
programming via ICSP and development with MPLAB
ICD 2, 2 x 16 liquid crystal display, PCB footprints for
H-Bridge motor driver, LIN transceiver and EEPROM.
Also included are: header for expansion, eight LEDs,
four potentiometers, three push buttons and a proto-
typing area. Included with the kit is a PIC16F627A and
a PIC18F1320. Tutorial firmware is included along with
the User’s Guide.
22.15 PICDEM.net Internet/Ethernet
Demonstration Board
The PICDEM.net demonstration board is an Internet/
Ethernet demonstration board using the PIC18F452
microcontroller and TCP/IP firmware. The board
supports any 40-pin DIP device that conforms to the
standard pinout used by the PIC16F877 or
PIC18C452. This kit features a user friendly TCP/IP
stack, web server with HTML, a 24L256 Serial
EEPROM for Xmodem download to web pages into
Serial EEPROM, ICSP/MPLAB ICD 2 interface con-
nector, an Ethernet interface, RS-232 interface and a
16 x 2 LCD display. Also included is the book and
CD-ROM “TCP/IP Lean, Web Servers for Embedded
Systems,” by Jeremy Bentham
22.19 PICDEM 17 Demonstration Board
The PICDEM 17 demonstration board is an evaluation
board that demonstrates the capabilities of several
Microchip microcontrollers, including PIC17C752,
PIC17C756A, PIC17C762 and PIC17C766. A pro-
grammed sample is included. The PRO MATE II device
programmer, or the PICSTART Plus development pro-
grammer, can be used to reprogram the device for user
tailored application development. The PICDEM 17
demonstration board supports program download and
execution from external on-board Flash memory. A
generous prototype area is available for user hardware
expansion.
22.16 PICDEM 2 Plus
Demonstration Board
The PICDEM 2 Plus demonstration board supports
many 18, 28 and 40-pin microcontrollers, including
PIC16F87X and PIC18FXX2 devices. All the neces-
sary hardware and software is included to run the dem-
onstration programs. The sample microcontrollers
provided with the PICDEM 2 demonstration board can
be programmed with a PRO MATE II device program-
mer, PICSTART Plus development programmer, or
MPLAB ICD 2 with a Universal Programmer Adapter.
The MPLAB ICD 2 and MPLAB ICE in-circuit emulators
may also be used with the PICDEM 2 demonstration
board to test firmware. A prototype area extends the
circuitry for additional application components. Some
of the features include an RS-232 interface, a 2 x 16
LCD display, a piezo speaker, an on-board temperature
sensor, four LEDs and sample PIC18F452 and
PIC16F877 Flash microcontrollers.
DS70138C-page 160
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
22.20 PICDEM 18R PIC18C601/801
Demonstration Board
22.23 PICDEM USB PIC16C7X5
Demonstration Board
The PICDEM 18R demonstration board serves to assist
development of the PIC18C601/801 family of Microchip
microcontrollers. It provides hardware implementation
of both 8-bit Multiplexed/Demultiplexed and 16-bit
Memory modes. The board includes 2 Mb external
Flash memory and 128 Kb SRAM memory, as well as
serial EEPROM, allowing access to the wide range of
memory types supported by the PIC18C601/801.
The PICDEM USB Demonstration Board shows off the
capabilities of the PIC16C745 and PIC16C765 USB
microcontrollers. This board provides the basis for
future USB products.
22.24 Evaluation and
Programming Tools
In addition to the PICDEM series of circuits, Microchip
has a line of evaluation kits and demonstration software
for these products.
22.21 PICDEM LIN PIC16C43X
Demonstration Board
• KEELOQ evaluation and programming tools for
The powerful LIN hardware and software kit includes a
series of boards and three PICmicro microcontrollers.
The small footprint PIC16C432 and PIC16C433 are
used as slaves in the LIN communication and feature
Microchip’s HCS Secure Data Products
• CAN developers kit for automotive network
applications
• Analog design boards and filter design software
on-board LIN transceivers.
A PIC16F874 Flash
• PowerSmart battery charging evaluation/
calibration kits
microcontroller serves as the master. All three micro-
controllers are programmed with firmware to provide
LIN bus communication.
• IrDA® development kit
• microID development and rfLabTM development
software
22.22 PICkitTM 1 Flash Starter Kit
• SEEVAL® designer kit for memory evaluation and
endurance calculations
A complete “development system in a box”, the PICkit
Flash Starter Kit includes a convenient multi-section
board for programming, evaluation and development of
8/14-pin Flash PIC® microcontrollers. Powered via
USB, the board operates under a simple Windows GUI.
The PICkit 1 Starter Kit includes the User’s Guide (on
CD ROM), PICkit 1 tutorial software and code for
various applications. Also included are MPLAB® IDE
(Integrated Development Environment) software,
software and hardware “Tips 'n Tricks for 8-pin Flash
PIC® Microcontrollers” Handbook and a USB interface
cable. Supports all current 8/14-pin Flash PIC
microcontrollers, as well as many future planned
devices.
• PICDEM MSC demo boards for Switching mode
power supply, high-power IR driver, delta sigma
ADC and flow rate sensor
Check the Microchip web page and the latest Product
Selector Guide for the complete list of demonstration
and evaluation kits.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 161
dsPIC30F3014/4013
NOTES:
DS70138C-page 162
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
23.0 ELECTRICAL CHARACTERISTICS
This section provides an overview of dsPIC30F electrical characteristics. Additional information will be provided in future
revisions of this document as it becomes available.
For detailed information about the dsPIC30F architecture and core, refer to dsPIC30F Family Reference Manual
(DS70046).
Absolute maximum ratings for the dsPIC30F family are listed below. Exposure to these maximum rating conditions for
extended periods may affect device reliability. Functional operation of the device at these or any other conditions above
the parameters indicated in the operation listings of this specification is not implied.
(†)
Absolute Maximum Ratings
Ambient temperature under bias.............................................................................................................-40°C to +125°C
Storage temperature .............................................................................................................................. -65°C to +150°C
Voltage on any pin with respect to VSS (except VDD and MCLR) (Note 1)..................................... -0.3V to (VDD + 0.3V)
Voltage on VDD with respect to VSS ......................................................................................................... -0.3V to +5.5V
Voltage on MCLR with respect to VSS ....................................................................................................... 0V to +13.25V
Maximum current out of VSS pin ...........................................................................................................................300 mA
Maximum current into VDD pin (Note 2)................................................................................................................250 mA
Input clamp current, IIK (VI < 0 or VI > VDD).......................................................................................................... 20 mA
Output clamp current, IOK (VO < 0 or VO > VDD)................................................................................................... 20 mA
Maximum output current sunk by any I/O pin..........................................................................................................25 mA
Maximum output current sourced by any I/O pin ....................................................................................................25 mA
Maximum current sunk by all ports .......................................................................................................................200 mA
Maximum current sourced by all ports (Note 2)....................................................................................................200 mA
Note 1: Voltage spikes below Vss at the MCLR/Vpp pin, inducing currents greater than 80 mA, may cause latchup.
Thus, a series resistor of 50-100W should be used when applying a “low” level to the MCLR/Vpp pin, rather
than pulling this pin directly to Vss.
2: Maximum allowable current is a function of device maximum power dissipation. See Table 23-4
†
NOTICE: Stresses above those listed under “Absolute Maximum Ratings” may cause permanent damage to the
device. This is a stress rating only and functional operation of the device at those or any other conditions above those
indicated in the operation listings of this specification is not implied. Exposure to maximum rating conditions for
extended periods may affect device reliability.
Note: All peripheral electrical characteristics are specified. For exact peripherals available on specific
devices, please refer the the Family Cross Reference Table.
23.1 DC Characteristics
TABLE 23-1: OPERATING MIPS VS. VOLTAGE
Max MIPS
VDD Range
Temp Range
dsPIC30FXXX-30I
dsPIC30FXXX-20I
dsPIC30FXXX-20E
4.5-5.5V
4.5-5.5V
3.0-3.6V
3.0-3.6V
2.5-3.0V
-40°C to 85°C
-40°C to 125°C
-40°C to 85°C
-40°C to 125°C
-40°C to 85°C
30
—
15
—
10
20
—
—
20
—
10
—
10
—
7.5
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 163
dsPIC30F3014/4013
TABLE 23-2: THERMAL OPERATING CONDITIONS
Rating
Symbol
Min
Typ
Max
Unit
dsPIC30F3014-30I
dsPIC30F4013-30I
Operating Junction Temperature Range
Operating Ambient Temperature Range
T
-40
-40
+125
+85
°C
°C
J
T
A
dsPIC30F3014-20I
dsPIC30F4013-20I
Operating Junction Temperature Range
Operating Ambient Temperature Range
T
-40
-40
+150
+85
°C
°C
J
T
A
dsPIC30F3014-20E
dsPIC30F4013-20E
Operating Junction Temperature Range
Operating Ambient Temperature Range
T
-40
-40
+150
+125
°C
°C
J
T
A
Power Dissipation:
Internal chip power dissipation:
PINT = VDD × (IDD –
)
IOH
∑
PD
PINT + PI/O
W
I/O Pin power dissipation:
=
({
OH} × OH ) +
I
(
)
OL
PI/O
V
DD
– V
∑
∑
OL
V
× I
Maximum Allowed Power Dissipation
PDMAX
(TJ - TA) / θJA
W
TABLE 23-3: THERMAL PACKAGING CHARACTERISTICS
Characteristic
Symbol
Typ
Max
Unit
Notes
Package Thermal Resistance, 40-pin DIP (P)
Package Thermal Resistance, 44-pin TQFP (10x10x1mm)
Package Thermal Resistance, 44-pin QFN
θJA
θJA
θJA
47
°C/W
°C/W
°C/W
1
1
1
39.3
27.8
Note 1: Junction to ambient thermal resistance, Theta-ja (θJA) numbers are achieved by package simulations.
TABLE 23-4: DC TEMPERATURE AND VOLTAGE SPECIFICATIONS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
Symbol
Characteristic
Min
Typ
Max Units
Conditions
No.
(2)
Operating Voltage
DC10
DC11
DC12
DC16
VDD
VDD
VDR
VPOR
Supply Voltage
2.5
3.0
—
—
—
5.5
5.5
—
V
V
V
V
Industrial temperature
Extended temperature
Supply Voltage
(3)
RAM Data Retention Voltage
1.5
VSS
VDD Start Voltage
to ensure internal
—
—
Power-on Reset signal
DC17
SVDD
VDD Rise Rate
0.05
V/ms 0-5V in 0.1 sec
0-3V in 60 ms
to ensure internal
Power-on Reset signal
Note 1: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2: These parameters are characterized but not tested in manufacturing.
3: This is the limit to which VDD can be lowered without losing RAM data.
DS70138C-page 164
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 23-5: DC CHARACTERISTICS: OPERATING CURRENT (IDD)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Parameter
No.
(1)
Typical
Max
Units
Conditions
(2)
Operating Current (IDD)
DC20
—
TBD
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
-40°C
25°C
DC20a
DC20b
DC20c
DC20d
DC20e
DC20f
DC20g
DC23
3.3V
85°C
—
125°C
-40°C
25°C
1 MIPS EC mode
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC23a
DC23b
DC23c
DC23d
DC23e
DC23f
DC23g
DC24
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
4 MIPS EC mode, 4X PLL
10 MIPS EC mode, 4X PLL
8 MIPS EC mode, 8X PLL
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC24a
DC24b
DC24c
DC24d
DC24e
DC24f
DC24g
DC25
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC25a
DC25b
DC25c
DC25d
DC25e
DC25f
DC25g
TBD
—
3V
85°C
—
125°C
-40°C
25°C
—
TBD
—
5V
85°C
—
125°C
Note 1: Data in “Typical” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only
and are not tested.
2: The supply current is mainly a function of the operating voltage and frequency. Other factors such as I/O
pin loading and switching rate, oscillator type, internal code execution pattern and temperature also have
an impact on the current consumption. The test conditions for all IDD measurements are as follows: OSC1
driven with external square wave from rail to rail. All I/O pins are configured as Inputs and pulled to VDD.
MCLR = VDD, WDT, FSCM, LVD and BOR are disabled. CPU, SRAM, Program Memory and Data
Memory are operational. No peripheral modules are operating.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 165
dsPIC30F3014/4013
TABLE 23-5: DC CHARACTERISTICS: OPERATING CURRENT (IDD) (CONTINUED)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Parameter
(1)
Typical
Max
Units
Conditions
No.
(2)
Operating Current (IDD)
DC27
—
TBD
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
-40°C
25°C
85°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
DC27a
DC27b
DC27c
DC27d
DC27e
DC27f
DC28
3.3V
—
20 MIPS EC mode, 8X PLL
TBD
—
5V
—
—
DC28a
DC28b
DC28c
DC28d
DC28e
DC28f
DC29
TBD
—
3.3V
—
16 MIPS EC mode, 16X PLL
TBD
—
5V
—
—
DC29a
DC29b
DC29c
DC30
TBD
—
5V
3.3V
5V
30 MIPS EC mode, 16X PLL
—
—
DC30a
DC30b
DC30c
DC30d
DC30e
DC30f
DC30g
DC31
TBD
—
—
FRC (~ 2 MIPS)
—
TBD
—
—
—
DC31a
DC31b
DC31c
DC31d
DC31e
DC31f
DC31g
TBD
—
3.3V
—
LPRC (~ 512 kHz)
—
TBD
—
5V
—
Note 1: Data in “Typical” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only
and are not tested.
2: The supply current is mainly a function of the operating voltage and frequency. Other factors such as I/O
pin loading and switching rate, oscillator type, internal code execution pattern and temperature also have
an impact on the current consumption. The test conditions for all IDD measurements are as follows: OSC1
driven with external square wave from rail to rail. All I/O pins are configured as Inputs and pulled to VDD.
MCLR = VDD, WDT, FSCM, LVD and BOR are disabled. CPU, SRAM, Program Memory and Data
Memory are operational. No peripheral modules are operating.
DS70138C-page 166
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 23-6: DC CHARACTERISTICS: IDLE CURRENT (IIDLE)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Parameter
No.
(1)
Typical
Max
Units
Conditions
(2)
Idle Current (IIDLE): Core OFF Clock ON Base Current
DC40
—
TBD
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
-40°C
25°C
DC40a
DC40b
DC40c
DC40d
DC40e
DC40f
DC40g
DC43
3.3V
85°C
—
125°C
-40°C
25°C
1 MIPS EC mode
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC43a
DC43b
DC43c
DC43d
DC43e
DC43f
DC43g
DC44
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
4 MIPS EC mode, 4X PLL
10 MIPS EC mode, 4X PLL
8 MIPS EC mode, 8X PLL
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC44a
DC44b
DC44c
DC44d
DC44e
DC44f
DC44g
DC45
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC45a
DC45b
DC45c
DC45d
DC45e
DC45f
DC45g
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
—
TBD
—
5V
85°C
—
125°C
Note 1: Data in “Typical” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only
and are not tested.
2: Base IIDLE current is measured with Core off, Clock on and all modules turned off.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 167
dsPIC30F3014/4013
TABLE 23-6: DC CHARACTERISTICS: IDLE CURRENT (IIDLE) (CONTINUED)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Parameter
(1)
Typical
Max
Units
Conditions
No.
(2)
Idle Current (IIDLE): Core OFF Clock ON Base Current
DC47
—
TBD
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
-40°C
25°C
85°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
-40°C
25°C
85°C
125°C
DC47a
DC47b
DC47c
DC47d
DC47e
DC47f
DC48
3.3V
—
20 MIPS EC mode, 8X PLL
TBD
—
5V
—
—
DC48a
DC48b
DC48c
DC48d
DC48e
DC48f
DC49
TBD
—
3.3V
—
16 MIPS EC mode, 16X PLL
TBD
—
5V
—
—
DC49a
DC49b
DC49c
DC50
TBD
—
5V
3.3V
5V
30 MIPS EC mode, 16X PLL
—
—
DC50a
DC50b
DC50c
DC50d
DC50e
DC50f
DC50g
DC51
TBD
—
—
FRC (~ 2 MIPS)
—
TBD
—
—
—
DC51a
DC51b
DC51c
DC51d
DC51e
DC51f
DC51g
TBD
—
3.3V
—
LPRC (~ 512 kHz)
—
TBD
—
5V
—
Note 1: Data in “Typical” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only
and are not tested.
2: Base IIDLE current is measured with Core off, Clock on and all modules turned off.
DS70138C-page 168
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 23-7: DC CHARACTERISTICS: POWER-DOWN CURRENT (IPD)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Parameter
No.
(1)
Typical
Max
Units
Conditions
(2)
Power Down Current (IPD)
DC60
—
TBD
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
µA
-40°C
25°C
DC60a
DC60b
DC60c
DC60d
DC60e
DC60f
DC60g
DC61
3.3V
85°C
—
125°C
-40°C
25°C
(3)
Base Power Down Current
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC61a
DC61b
DC61c
DC61d
DC61e
DC61f
DC61g
DC62
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
(3)
Watchdog Timer Current: ∆IWDT
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC62a
DC62b
DC62c
DC62d
DC62e
DC62f
DC62g
DC63
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
(3)
Timer 1 w/32 kHz Crystal: ∆ITI32
—
TBD
—
5V
85°C
—
125°C
-40°C
25°C
—
DC63a
DC63b
DC63c
DC63d
DC63e
DC63f
DC63g
TBD
—
3.3V
85°C
—
125°C
-40°C
25°C
(3)
BOR On: ∆IBOR
—
TBD
—
5V
85°C
—
125°C
Note 1: Data in the Typical column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance
only and are not tested.
2: Base IPD is measured with all peripherals and clocks shut down. All I/Os are configured as inputs and
pulled high. LVD, BOR, WDT, etc. are all switched off.
3: The ∆ current is the additional current consumed when the module is enabled. This current should be
added to the base IPD current.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 169
dsPIC30F3014/4013
TABLE 23-7: DC CHARACTERISTICS: POWER-DOWN CURRENT (IPD) (CONTINUED)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Parameter
(1)
Typical
Max
Units
Conditions
No.
(2)
Power Down Current (IPD)
DC66
—
TBD
—
—
—
—
—
—
—
—
—
µA
µA
µA
µA
µA
µA
µA
µA
-40°C
25°C
DC66a
DC66b
DC66c
DC66d
DC66e
DC66f
DC66g
3.3V
85°C
—
125°C
-40°C
25°C
(3)
Low Voltage Detect: ∆ILVD
—
TBD
—
5V
85°C
—
125°C
Note 1: Data in the Typical column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance
only and are not tested.
2: Base IPD is measured with all peripherals and clocks shut down. All I/Os are configured as inputs and
pulled high. LVD, BOR, WDT, etc. are all switched off.
3: The ∆ current is the additional current consumed when the module is enabled. This current should be
added to the base IPD current.
DS70138C-page 170
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 23-8: DC CHARACTERISTICS: I/O PIN INPUT SPECIFICATIONS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
Characteristic
Min
Typ
Max
Units
Conditions
(2)
VIL
Input Low Voltage
DI10
I/O pins:
with Schmitt Trigger buffer
VSS
VSS
VSS
VSS
TBD
TBD
—
—
—
—
—
—
0.2 VDD
0.2 VDD
0.2 VDD
0.3 VDD
TBD
V
V
V
V
V
V
DI15
DI16
DI17
DI18
DI19
MCLR
OSC1 (in XT, HS and LP modes)
(3)
OSC1 (in RC mode)
SDA, SCL
SDA, SCL
SM bus disabled
SM bus enabled
TBD
(2)
VIH
Input High Voltage
DI20
I/O pins:
with Schmitt Trigger buffer
0.8 VDD
0.8 VDD
—
—
—
—
—
—
VDD
VDD
VDD
VDD
TBD
TBD
V
V
V
V
V
V
DI25
DI26
DI27
DI28
DI29
MCLR
OSC1 (in XT, HS and LP modes) 0.7 VDD
(3)
OSC1 (in RC mode)
0.9 VDD
TBD
SDA, SCL
SM bus disabled
SM bus enabled
SDA, SCL
TBD
(2)
ICNPU
CNXX Pull-up Current
DI30
DI31
50
250
400
µA VDD = 5V, VPIN = VSS
µA VDD = 3V, VPIN = VSS
TBD
TBD
TBD
(2)(4)(5)
IIL
Input Leakage Current
DI50
DI51
I/O ports
—
—
0.01
0.50
1
µA
µA
µA
VSS ≤ VPIN ≤ VDD,
Pin at hi-impedance
Analog input pins
—
VSS ≤ VPIN ≤ VDD,
Pin at hi-impedance
DI55
DI56
MCLR
OSC1
—
—
0.05
0.05
5
5
VSS ≤ VPIN ≤ VDD
µA VSS ≤ VPIN ≤ VDD, XT, HS
and LP Osc mode
Note 1: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2: These parameters are characterized but not tested in manufacturing.
3: In RC oscillator configuration, the OSC1/CLKl pin is a Schmitt Trigger input. It is not recommended that
the dsPIC30F device be driven with an external clock while in RC mode.
4: The leakage current on the MCLR pin is strongly dependent on the applied voltage level. The specified
levels represent normal operating conditions. Higher leakage current may be measured at different input
voltages.
5: Negative current is defined as current sourced by the pin.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 171
dsPIC30F3014/4013
TABLE 23-9: DC CHARACTERISTICS: I/O PIN OUTPUT SPECIFICATIONS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
Symbol
Characteristic
Min
Typ
Max Units
Conditions
No.
(2)
VOL
Output Low Voltage
DO10
DO16
I/O ports
—
—
—
—
—
—
—
—
0.6
TBD
0.6
V
V
V
V
IOL = 8.5 mA, VDD = 5V
IOL = 2.0 mA, VDD = 3V
IOL = 1.6 mA, VDD = 5V
IOL = 2.0 mA, VDD = 3V
OSC2/CLKOUT
(RC or EC Osc mode)
TBD
(2)
VOH
Output High Voltage
DO20
DO26
I/O ports
VDD – 0.7
TBD
—
—
—
—
—
—
—
—
V
V
V
V
IOH = -3.0 mA, VDD = 5V
IOH = -2.0 mA, VDD = 3V
IOH = -1.3 mA, VDD = 5V
IOH = -2.0 mA, VDD = 3V
OSC2/CLKOUT
VDD – 0.7
TBD
(RC or EC Osc mode)
Capacitive Loading Specs
(2)
on Output Pins
DO50 COSC2
OSC2/SOSC2 pin
—
—
15
pF In XTL, XT, HS and LP modes
when external clock is used to
drive OSC1.
DO56 CIO
DO58 CB
All I/O pins and OSC2
SCL, SDA
—
—
—
—
50
pF RC or EC Osc mode
2
pF In I C mode
400
Note 1: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2: These parameters are characterized but not tested in manufacturing.
FIGURE 23-1:
LOW-VOLTAGE DETECT CHARACTERISTICS
VDD
LV10
LVDIF
(LVDIF set by hardware)
DS70138C-page 172
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dsPIC30F3014/4013
TABLE 23-10: ELECTRICAL CHARACTERISTICS: LVDL
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
Characteristic
Min
Typ
Max Units Conditions
(2)
LV10
VPLVD
LVDL Voltage on VDD transition LVDL = 0000
high to low
—
—
—
V
(2)
(2)
(2)
LVDL = 0001
LVDL = 0010
LVDL = 0011
LVDL = 0100
LVDL = 0101
LVDL = 0110
LVDL = 0111
LVDL = 1000
LVDL = 1001
LVDL = 1010
LVDL = 1011
LVDL = 1100
LVDL = 1101
LVDL = 1110
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
—
—
—
—
2.50
2.70
2.80
3.00
3.30
3.50
3.60
3.80
4.00
4.20
4.50
—
2.65
2.86
2.97
3.18
3.50
3.71
3.82
4.03
4.24
4.45
4.77
—
LV15
VLVDIN
External LVD input pin
threshold voltage
LVDL = 1111
Note 1: These parameters are characterized but not tested in manufacturing.
2: These values not in usable operating range.
FIGURE 23-2:
BROWN-OUT RESET CHARACTERISTICS
VDD
(Device not in Brown-out Reset)
BO15
BO10
(Device in Brown-out Reset)
RESET (due to BOR)
Power Up Time-out
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TABLE 23-11: ELECTRICAL CHARACTERISTICS: BOR
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
Characteristic
Min Typ
Max Units
Conditions
(2)
(3)
BO10
VBOR
BOR Voltage on
VDD transition high to
low
BORV = 00
—
—
—
V
Not in operating
range
BORV = 01
BORV = 10
BORV = 11
2.7
4.2
4.5
—
—
—
—
5
2.86
4.46
4.78
—
V
V
V
BO15
VBHYS
mV
Note 1: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2: These parameters are characterized but not tested in manufacturing.
3: 00values not in usable operating range.
TABLE 23-12: DC CHARACTERISTICS: PROGRAM AND EEPROM
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
DC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
Symbol
Characteristic
Min Typ
Max
Units
Conditions
No.
(2)
Data EEPROM Memory
Byte Endurance
D120
D121
ED
100K
1M
—
—
E/W -40°C ≤ TA ≤ +85°C
VDRW
VDD for Read/Write
VMIN
5.5
V
Using EECON to read/write
VMIN = Minimum operating
voltage
D122
D123
TDEW
Erase/Write Cycle Time
Characteristic Retention
—
2
—
—
ms
TRETD
40
100
Year Provided no other specifications
are violated
D124
IDEW
IDD During Programming
Program Flash Memory
Cell Endurance
—
10
30
mA Row Erase
(2)
D130
D131
EP
10K
100K
—
—
E/W -40°C ≤ TA ≤ +85°C
VPR
VDD for Read
VMIN
5.5
V
VMIN = Minimum operating
voltage
D132
D133
D134
D135
VEB
VDD for Bulk Erase
4.5
3.0
—
—
—
5.5
5.5
—
V
V
VPEW
TPEW
TRETD
VDD for Erase/Write
Erase/Write Cycle Time
Characteristic Retention
2
ms
40
100
—
Year Provided no other specifications
are violated
D136
D137
D138
TEB
IPEW
IEB
ICSP Block Erase Time
IDD During Programming
IDD During Programming
—
—
—
4
—
30
30
ms
10
10
mA Row Erase
mA Bulk Erase
Note 1: Data in “Typ” column is at 5V, 25°C unless otherwise stated.
2: These parameters are characterized but not tested in manufacturing.
DS70138C-page 174
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dsPIC30F3014/4013
23.2 AC Characteristics and Timing Parameters
The information contained in this section defines dsPIC30F AC characteristics and timing parameters.
TABLE 23-13: TEMPERATURE AND VOLTAGE SPECIFICATIONS – AC
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Operating voltage VDD range as described in DC Spec Section 23.0.
FIGURE 23-3:
LOAD CONDITIONS FOR DEVICE TIMING SPECIFICATIONS
Load Condition 1 - for all pins except OSC2
Load Condition 2 - for OSC2
VDD/2
CL
RL
Pin
VSS
CL
Pin
RL = 464 Ω
CL = 50 pF for all pins except OSC2
5 pF for OSC2 output
VSS
FIGURE 23-4:
EXTERNAL CLOCK TIMING
Q4
Q1
Q2
Q3
Q4
Q1
OSC1
OS20
OS30 OS30
OS31 OS31
OS25
CLKOUT
OS40
OS41
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TABLE 23-14: EXTERNAL CLOCK TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
Characteristic
Min
Typ
Max
Units
Conditions
(2)
OS10 FOSC
External CLKIN Frequency
DC
4
—
—
—
—
40
10
10
7.5
MHz EC
(External clocks allowed only
in EC mode)
MHz EC with 4x PLL
MHz EC with 8x PLL
MHz EC with 16x PLL
4
4
(2)
Oscillator Frequency
DC
0.4
4
—
—
4
4
MHz RC
MHz XTL
—
10
10
10
7.5
25
33
—
—
MHz XT
4
—
MHz XT with 4x PLL
MHz XT with 8x PLL
MHz XT with 16x PLL
MHz HS
4
—
4
—
10
31
—
—
—
—
kHz
LP
7.37
512
MHz FRC internal
kHz
—
LPRC internal
OS20 TOSC
TOSC = 1/FOSC
—
—
—
See parameter OS10
for FOSC value
(2)(3)
OS25 TCY
Instruction Cycle Time
33
—
—
DC
—
ns
ns
See Table 23-16
EC
(2)
External Clock in (OSC1)
OS30 TosL,
TosH
.45 x TOSC
High or Low Time
(2)
External Clock in (OSC1)
OS31 TosR,
TosF
—
—
20
ns
EC
Rise or Fall Time
(2)(4)
OS40 TckR
OS41 TckF
CLKOUT Rise Time
—
—
6
6
10
10
ns
ns
(2)(4)
CLKOUT Fall Time
Note 1: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2: These parameters are characterized but not tested in manufacturing.
3: Instruction cycle period (TCY) equals four times the input oscillator time-base period. All specified values
are based on characterization data for that particular oscillator type under standard operating conditions
with the device executing code. Exceeding these specified limits may result in an unstable oscillator
operation and/or higher than expected current consumption. All devices are tested to operate at “min.”
values with an external clock applied to the OSC1/CLKI pin. When an external clock input is used, the
“Max.” cycle time limit is “DC” (no clock) for all devices.
4: Measurements are taken in EC or ERC modes. The CLKOUT signal is measured on the OSC2 pin.
CLKOUT is low for the Q1-Q2 period (1/2 TCY) and high for the Q3-Q4 period (1/2 TCY).
DS70138C-page 176
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TABLE 23-15: PLL CLOCK TIMING SPECIFICATIONS (VDD = 2.5 TO 5.5 V)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
(2)
Characteristic
Min
Typ
Max
Units
Conditions
(2)
OS50
OS51
OS52
OS53
FPLLI
FSYS
TLOC
DCLK
PLL Input Frequency Range
4
16
—
—
20
1
10
120
50
MHz EC, XT modes with PLL
MHz EC, XT modes with PLL
µs
(2)
On-chip PLL Output
PLL Start-up Time (Lock Time)
CLKOUT Stability (Jitter)
—
TBD
TBD
%
Measured over 100 ms
period
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
TABLE 23-16: INTERNAL CLOCK TIMING EXAMPLES
Clock
(3)
(3)
(3)
(3)
FOSC
(1)
(MHz)
MIPS
MIPS
MIPS
MIPS
(2)
Oscillator
Mode
TCY (µsec)
w/o PLL
w PLL x4
w PLL x8
w PLL x16
EC
0.200
4
20.0
1.0
0.05
1.0
—
4.0
10.0
—
—
8.0
20.0
—
—
16.0
—
10
25
4
0.4
2.5
0.16
1.0
25.0
1.0
—
XT
4.0
10.0
8.0
20.0
16.0
—
10
0.4
2.5
Note 1: Assumption: Oscillator Postscaler is divide by 1.
2: Instruction Execution Cycle Time: TCY = 1 / MIPS.
3: Instruction Execution Frequency: MIPS = (FOSC * PLLx) / 4 [since there are 4 Q clocks per instruction
cycle].
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TABLE 23-17: AC CHARACTERISTICS: INTERNAL RC ACCURACY
Standard Operating Conditions: 2.5 V to 5.5 V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature
-40°C ≤ TA ≤ +85°C for industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
No.
Characteristic
Min
Typ
Max
Units
Conditions
(1)
Internal FRC Accuracy @ FRC Freq = 7.37 MHz
FRC
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
+25°C
VDD = 3.0-3.6 V
+25°C
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
+25°C
FRC with x4 PLL
FRC with x8 PLL
FRC with x16 PLL
+25°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
+25°C
+25°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
+25°C
+25°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
Note 1: Frequency calibrated at 25°C and 5V. TUN bits can be used to compensate for temperature drift.
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TABLE 23-18: AC CHARACTERISTICS: INTERNAL RC JITTER
Standard Operating Conditions: 2.5 V to 5.5 V
(unless otherwise stated)
Operating temperature
AC CHARACTERISTICS
-40°C ≤ TA ≤ +85°C for industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
No.
Characteristic
Min
Typ
Max
Units
Conditions
(1)
Internal FRC Jitter @ FRC Freq = 7.37 MHz
FRC
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
%
+25°C
+25°C
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 3.0-3.6 V
VDD = 4.5-5.5 V
VDD = 4.5-5.5 V
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
+25°C
FRC with x4 PLL
FRC with x8 PLL
FRC with x16 PLL
+25°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
+25°C
+25°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
+25°C
+25°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +85°C
-40°C ≤ TA ≤ +125°C
Note 1: Frequency calibrated at 25°C and 5V. TUN bits can be used to compensate for temperature drift.
TABLE 23-19: INTERNAL RC ACCURACY
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Characteristic
Min
Typ
Max
Units
Conditions
No.
(1)
LPRC @ Freq = 512 kHz
F20
F21
TBD
TBD
—
—
TBD
TBD
%
%
-40°C to +85°C
-40°C to +85°C
VDD = 3V
VDD = 5V
Note 1: Frequency at 25°C and 5V. Change of LPRC frequency as VDD changes.
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FIGURE 23-5:
CLKOUT AND I/O TIMING CHARACTERISTICS
I/O Pin
(Input)
DI35
DI40
I/O Pin
New Value
Old Value
(Output)
DO31
DO32
Note: Refer to Figure 23-3 for load conditions.
TABLE 23-20: CLKOUT AND I/O TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)(2)(3)
(4)
Typ
Characteristic
Min
Max
Units
Conditions
DO31
DO32
DI35
TIOR
TIOF
TINP
TRBP
Port output rise time
Port output fall time
—
—
10
10
—
—
25
25
—
—
ns
ns
ns
ns
—
—
—
—
INTx pin high or low time (output)
CNx high or low time (input)
20
DI40
2 TCY
Note 1: These parameters are asynchronous events not related to any internal clock edges
2: Measurements are taken in RC mode and EC mode where CLKOUT output is 4 x TOSC.
3: These parameters are characterized but not tested in manufacturing.
4: Data in “Typ” column is at 5V, 25°C unless otherwise stated.
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FIGURE 23-6:
RESET, WATCHDOG TIMER, OSCILLATOR START-UP TIMER AND POWER-UP
TIMER TIMING CHARACTERISTICS
VDD
SY12
MCLR
SY10
Internal
POR
SY11
PWRT
Time-out
SY30
OSC
Time-out
Internal
Reset
Watchdog
Timer
Reset
SY20
SY13
SY13
I/O Pins
SY35
FSCM
Delay
Note: Refer to Figure 23-3 for load conditions.
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TABLE 23-21: RESET, WATCHDOG TIMER, OSCILLATOR START-UP TIMER, POWER-UP TIMER
AND BROWN-OUT RESET TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
(2)
Symbol
Characteristic
Min
Typ
Max Units
Conditions
No.
SY10
SY11
TmcL
MCLR Pulse Width (low)
Power-up Timer Period
2
—
—
µs
-40°C to +85°C
TPWRT
TBD
TBD
TBD
TBD
0
4
TBD
TBD
TBD
TBD
ms
-40°C to +85°C
User programmable
16
64
SY12
SY13
TPOR
TIOZ
Power On Reset Delay
3
10
—
30
µs
-40°C to +85°C
I/O Hi-impedance from MCLR
Low or Watchdog Timer Reset
—
100
ns
SY20
TWDT1
Watchdog Timer Time-out Period
(No Prescaler)
1.8
2.0
2.2
ms VDD = 5V, -40°C to +85°C
TWDT2
TBOR
TOST
1.9
100
—
2.1
—
2.3
—
—
—
ms VDD = 3V, -40°C to +85°C
(3)
SY25
SY30
SY35
Brown-out Reset Pulse Width
µs
—
µs
VDD ≤ VBOR (D034)
TOSC = OSC1 period
-40°C to +85°C
Oscillation Start-up Timer Period
Fail-Safe Clock Monitor Delay
1024 TOSC
100
TFSCM
—
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated.
3: Refer to Figure 23-2 and Table 23-11 for BOR.
FIGURE 23-7:
BAND GAP START-UP TIME CHARACTERISTICS
VBGAP
0V
Enable Band Gap
(see Note)
Band Gap
Stable
SY40
Note: Set LVDEN bit (RCON<12>) or FBORPOR<7>set.
TABLE 23-22: BAND GAP START-UP TIME REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
(2)
Characteristic
Min Typ
Max Units
Conditions
SY40
TBGAP
Band Gap Start-up Time
—
20
50
µs Defined as the time between the
instant that the band gap is enabled
and the moment that the band gap
reference voltage is stable.
RCON<13>Status bit
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated.
DS70138C-page 182
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FIGURE 23-8:
TYPE A, B AND C TIMER EXTERNAL CLOCK TIMING CHARACTERISTICS
TxCK
Tx11
Tx10
Tx15
OS60
Tx20
TMRX
Note: Refer to Figure 23-3 for load conditions.
TABLE 23-23: TYPE A TIMER (TIMER1) EXTERNAL CLOCK TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
Characteristic
Min
Typ
Max Units
Conditions
No.
TA10
TTXH
TxCK High Time
Synchronous,
0.5 TCY + 20
—
—
—
ns Must also meet
parameter TA15
no prescaler
Synchronous,
with prescaler
10
—
ns
Asynchronous
10
—
—
—
—
ns
TA11
TTXL
TxCK Low Time
Synchronous,
no prescaler
0.5 TCY + 20
ns Must also meet
parameter TA15
Synchronous,
with prescaler
10
—
—
ns
Asynchronous
10
—
—
—
—
ns
ns
TA15
TTXP
TxCK Input Period Synchronous,
no prescaler
TCY + 10
Synchronous,
with prescaler
Greater of:
20 ns or
—
—
—
N = prescale
value
(TCY + 40)/N
(1, 8, 64, 256)
Asynchronous
20
—
—
—
ns
OS60
Ft1
SOSC1/T1CK oscillator input
DC
50
kHz
frequency range (oscillator enabled
by setting bit TCS (T1CON, bit 1))
TA20
TCKEXTMRL Delay from External TxCK Clock
2 TOSC
6 TOSC
—
Edge to Timer Increment
Note:
Timer1 is a Type A.
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TABLE 23-24: TYPE B TIMER (TIMER2 AND TIMER4) EXTERNAL CLOCK TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
TtxH
Characteristic
Min
Typ
Max
Units
Conditions
No.
TB10
TxCK High Time Synchronous, 0.5 TCY + 20
no prescaler
—
—
ns
Must also meet
parameter TB15
Synchronous,
with prescaler
10
—
—
—
—
—
—
—
—
ns
ns
ns
ns
TB11
TtxL
TxCK Low Time
Synchronous, 0.5 TCY + 20
no prescaler
Must also meet
parameter TB15
Synchronous,
with prescaler
10
TB15
TtxP
TxCK Input Period Synchronous,
no prescaler
TCY + 10
N = prescale
value
(1, 8, 64, 256)
Synchronous,
with prescaler
Greater of:
20 ns or
(TCY + 40)/N
TB20
TCKEXTMRL Delay from External TxCK Clock
2 TOSC
—
6 TOSC
—
Edge to Timer Increment
Note:
Timer2 and Timer4 are Type B.
TABLE 23-25: TYPECTIMER(TIMER3ANDTIMER5)EXTERNALCLOCKTIMINGREQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
TtxH
Characteristic
Min
Typ
Max Units
Conditions
No.
TC10
TxCK High Time
Synchronous
Synchronous
0.5 TCY + 20
—
—
—
—
ns Must also meet
parameter TC15
TC11
TC15
TtxL
TtxP
TxCK Low Time
0.5 TCY + 20
—
—
ns Must also meet
parameter TC15
TxCK Input Period Synchronous,
no prescaler
TCY + 10
ns N = prescale
value
(1, 8, 64, 256)
Synchronous,
with prescaler
Greater of:
20 ns or
(TCY + 40)/N
TC20
TCKEXTMRL Delay from External TxCK Clock
2 TOSC
—
6 TOSC
—
Edge to Timer Increment
Note:
Timer3 and Timer5 are Type C.
DS70138C-page 184
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
FIGURE 23-9:
INPUT CAPTURE (CAPx) TIMING CHARACTERISTICS
ICX
IC10
IC11
IC15
Note: Refer to Figure 23-3 for load conditions.
TABLE 23-26: INPUT CAPTURE TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
Characteristic
Min
Max
Units
Conditions
IC10
IC11
IC15
TccL
TccH
TccP
ICx Input Low Time No Prescaler
With Prescaler
0.5 TCY + 20
10
—
—
—
—
—
ns
ns
ns
ns
ns
ICx Input High Time No Prescaler
With Prescaler
0.5 TCY + 20
10
ICx Input Period
(2 TCY + 40)/N
N = prescale
value (1, 4, 16)
Note 1: These parameters are characterized but not tested in manufacturing.
FIGURE 23-10:
OUTPUT COMPARE MODULE (OCx) TIMING CHARACTERISTICS
OCx
(Output Compare
or PWM Mode)
OC10
OC11
Note: Refer to Figure 23-3 for load conditions.
TABLE 23-27: OUTPUT COMPARE MODULE TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
(2)
Characteristic
Min
Typ
Max
Units
Conditions
OC10 TccF
OC11 TccR
OCx Output Fall Time
OCx Output Rise Time
—
—
10
10
25
25
ns
ns
—
—
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 185
dsPIC30F3014/4013
FIGURE 23-11:
OCFA/OCFB
OCx
OC/PWM MODULE TIMING CHARACTERISTICS
OC20
OC15
TABLE 23-28: SIMPLE OC/PWM MODE TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
(2)
Symbol
Characteristic
Min
Typ
Max
Units
Conditions
No.
OC15
TFD
Fault Input to PWM I/O
Change
—
—
25
TBD
50
ns
ns
ns
ns
VDD = 3V
VDD = 5V
VDD = 3V
VDD = 5V
-40°C to +85°C
OC20
TFLT
Fault Input Pulse Width
—
—
-40°C to +85°C
TBD
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
DS70138C-page 186
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
2
DCI MODULE (MULTICHANNEL, I S MODES) TIMING CHARACTERISTICS
FIGURE 23-12:
CSCK
(SCKE =
0)
CS11
CS10
CS21
CS20
CSCK
(SCKE =
1)
CS21
CS20
COFS
CS55 CS56
CS35
70
CS51
CS50
LSb
HIGH-Z
HIGH-Z
MSb
CSDO
CS30
CS31
LSb IN
MSb IN
CSDI
CS40 CS41
Note: Refer to Figure 23-3 for load conditions.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 187
dsPIC30F3014/4013
2
TABLE 23-29: DCI MODULE (MULTICHANNEL, I S MODES) TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
(2)
Symbol
Characteristic
Min
Typ
Max
Units
Conditions
No.
CS10
TcSCKL
CSCK Input Low Time
(CSCK pin is an input)
TCY / 2 + 20
—
—
—
—
10
10
—
ns
—
(3)
CSCK Output Low Time
30
—
—
—
25
25
ns
ns
ns
ns
ns
—
—
—
—
—
(CSCK pin is an output)
CS11
TcSCKH
CSCK Input High Time
(CSCK pin is an input)
TCY / 2 + 20
(3)
CSCK Output High Time
30
—
—
(CSCK pin is an output)
(4)
CS20
CS21
TcSCKF
TcSCKR
CSCK Output Fall Time
(CSCK pin is an output)
(4)
CSCK Output Rise Time
(CSCK pin is an output)
(4)
CS30
CS31
CS35
CS36
CS40
TcSDOF
TcSDOR
TDV
CSDO Data Output Fall Time
—
—
—
10
20
10
10
—
—
—
25
25
10
20
—
ns
ns
ns
ns
ns
—
—
—
—
—
(4)
CSDO Data Output Rise Time
Clock edge to CSDO data valid
Clock edge to CSDO tri-stated
TDIV
TCSDI
Setup time of CSDI data input to
CSCK edge (CSCK pin is input
or output)
CS41
THCSDI
Hold time of CSDI data input to
CSCK edge (CSCK pin is input
or output)
20
—
—
ns
—
CS50
CS51
CS55
CS56
TcoFSF
TcoFSR
TscoFS
THCOFS
COFS Fall Time
—
—
20
20
10
10
—
—
25
25
—
—
ns
ns
ns
ns
Note 1
(COFS pin is output)
COFS Rise Time
Note 1
(COFS pin is output)
Setup time of COFS data input to
CSCK edge (COFS pin is input)
—
—
Hold time of COFS data input to
CSCK edge (COFS pin is input)
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
3: The minimum clock period for CSCK is 100 ns. Therefore, the clock generated in Master mode must not
violate this specification.
4: Assumes 50 pF load on all DCI pins.
DS70138C-page 188
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
FIGURE 23-13:
DCI MODULE (AC-LINK MODE) TIMING CHARACTERISTICS
BIT_CLK
(CSCK)
CS62
CS61
CS60
CS21
CS20
CS71
CS70
CS72
SYNC
(COFS)
CS76
CS75
CS80
MSb
LSb
LSb
SDO
(CSDO)
CS76
CS75
MSb IN
SDI
(CSDI)
CS65 CS66
TABLE 23-30: DCI MODULE (AC-LINK MODE) TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)(2)
(3)
Typ
Characteristic
Min
Max
Units
Conditions
CS60
CS61
CS62
CS65
TBCLKL
TBCLKH
TBCLK
TSACL
BIT_CLK Low Time
BIT_CLK High Time
BIT_CLK Period
36
36
—
—
40.7
40.7
81.4
—
45
45
—
10
ns
ns
ns
ns
—
—
Bit clock is input
—
Input Setup Time to
Falling Edge of BIT_CLK
CS66
THACL
Input Hold Time from
—
—
10
ns
—
Falling Edge of BIT_CLK
CS70
CS71
CS72
CS75
CS76
CS77
CS78
CS80
TSYNCLO SYNC Data Output Low Time
—
—
—
—
—
—
—
—
19.5
1.3
—
—
µs
µs
µs
ns
ns
ns
ns
ns
Note 1
TSYNCHI
TSYNC
TRACL
TFACL
TRACL
TFACL
SYNC Data Output High Time
SYNC Data Output Period
Note 1
20.8
10
—
Note 1
Rise Time, SYNC, SDATA_OUT
Fall Time, SYNC, SDATA_OUT
Rise Time, SYNC, SDATA_OUT
Fall Time, SYNC, SDATA_OUT
25
CLOAD = 50 pF, VDD = 5V
CLOAD = 50 pF, VDD = 5V
CLOAD = 50 pF, VDD = 3V
CLOAD = 50 pF, VDD = 3V
—
10
25
TBD
TBD
—
TBD
TBD
15
TOVDACL Output valid delay from rising
edge of BIT_CLK
Note 1: These parameters are characterized but not tested in manufacturing.
2: These values assume BIT_CLK frequency is 12.288 MHz.
3: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 189
dsPIC30F3014/4013
FIGURE 23-14:
SPI MODULE MASTER MODE (CKE = 0) TIMING CHARACTERISTICS
SCKx
(CKP = 0)
SP11
SP10
SP21
SP20
SCKx
(CKP = 1)
SP35
SP21
SP20
BIT14 - - - - - -1
MSb
LSb
SDOx
SP31
SP30
SDIx
MSb IN
SP40
LSb IN
BIT14 - - - -1
SP41
Note: Refer to Figure 23-3 for load conditions.
TABLE 23-31: SPI MASTER MODE (CKE = 0) TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
(2)
Characteristic
Min
Typ
Max
Units
Conditions
(3)
(3)
SP10
SP11
SP20
SP21
SP30
SP31
SP35
TscL
TscH
TscF
TscR
TdoF
TdoR
SCKX Output Low Time
TCY / 2
TCY / 2
—
—
—
10
10
10
10
—
—
—
25
25
25
25
30
ns
ns
ns
ns
ns
ns
ns
—
—
—
—
—
—
—
SCKX Output High Time
(4
SCKX Output Fall Time
SCKX Output Rise Time
(4)
—
(4)
SDOX Data Output Fall Time
—
(4)
SDOX Data Output Rise Time
—
TscH2doV, SDOX Data Output Valid after
TscL2doV SCKX Edge
—
SP40
SP41
TdiV2scH, Setup Time of SDIX Data Input
TdiV2scL to SCKX Edge
20
20
—
—
—
—
ns
ns
—
—
TscH2diL, Hold Time of SDIX Data Input
TscL2diL to SCKX Edge
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
3: The minimum clock period for SCK is 100 ns. Therefore, the clock generated in Master mode must not
violate this specification.
4: Assumes 50 pF load on all SPI pins.
DS70138C-page 190
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
FIGURE 23-15:
SPI MODULE MASTER MODE (CKE =1) TIMING CHARACTERISTICS
SP36
SCKX
(CKP = 0)
SP11
SP10
SP21
SP20
SCKX
(CKP = 1)
SP35
SP21
SP20
LSb
MSb
BIT14 - - - - - -1
SDOX
SP40
SP30,SP31
SDIX
MSb IN
BIT14 - - - -1
LSb IN
SP41
Note: Refer to Figure 23-3 for load conditions.
TABLE 23-32: SPI MODULE MASTER MODE (CKE = 1) TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
(3)
(2)
Symbol
Characteristic
Min
Typ
Max
Units
Conditions
No.
SP10
SP11
SP20
SP21
SP30
SP31
SP35
TscL
SCKX output low time
TCY / 2
TCY / 2
—
—
—
10
10
10
10
—
—
—
25
25
25
25
30
ns
ns
ns
ns
ns
ns
ns
—
—
—
—
—
—
—
(3)
(4)
TscH
TscF
TscR
TdoF
TdoR
SCKX output high time
SCKX output fall time
(4)
SCKX output rise time
—
(4)
SDOX data output fall time
—
(4)
SDOX data output rise time
—
TscH2doV, SDOX data output valid after
TscL2doV SCKX edge
—
SP36
SP40
SP41
TdoV2sc, SDOX data output setup to
TdoV2scL first SCKX edge
30
20
20
—
—
—
—
—
—
ns
ns
ns
—
—
—
TdiV2scH, Setup time of SDIX data input
TdiV2scL to SCKX edge
TscH2diL, Hold time of SDIX data input
TscL2diL
to SCKX edge
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
3: The minimum clock period for SCK is 100 ns. Therefore, the clock generated in master mode must not
violate this specification.
4: Assumes 50 pF load on all SPI pins.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 191
dsPIC30F3014/4013
FIGURE 23-16:
SPI MODULE SLAVE MODE (CKE = 0) TIMING CHARACTERISTICS
SSX
SP52
SP50
SCKX
(CKP =
0)
SP71
SP70
SP72
SP73
SCKX
(CKP =
1)
SP73
SP72
SP35
MSb
LSb
BIT14 - - - - - -1
SDO
X
SP51
SP30,SP31
BIT14 - - - -1
SDIX
MSb IN
SP41
LSb IN
SP40
Note: Refer to Figure 23-3 for load conditions.
TABLE 23-33: SPI MODULE SLAVE MODE (CKE = 0) TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
(2)
Symbol
TscL
Characteristic
Min
Typ
Max
Units
Conditions
No.
SP70
SCKX Input Low Time
SCKX Input High Time
30
30
—
—
—
—
—
—
—
—
—
10
10
—
—
—
25
25
25
25
30
ns
ns
ns
ns
ns
ns
ns
—
—
—
—
—
—
—
SP71
SP72
SP73
SP30
SP31
SP35
TscH
TscF
TscR
TdoF
TdoR
(3)
SCKX Input Fall Time
(3)
SCKX Input Rise Time
(3)
(3)
SDOX Data Output Fall Time
SDOX Data Output Rise Time
TscH2doV, SDOX Data Output Valid after
TscL2doV SCKX Edge
SP40
SP41
SP50
SP51
SP52
TdiV2scH, Setup Time of SDIX Data Input
TdiV2scL to SCKX Edge
20
20
—
—
—
—
—
—
—
—
50
—
ns
ns
ns
ns
ns
—
—
—
—
—
TscH2diL, Hold Time of SDIX Data Input
TscL2diL
to SCKX Edge
TssL2scH, SSX↓ to SCKX↑ or SCKX↓ Input
120
TssL2scL
TssH2doZ SSX↑ to SDOX Output
10
(3)
Hi-Impedance
TscH2ssH SSX after SCK Edge
1.5 TCY +40
TscL2ssH
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
3: Assumes 50 pF load on all SPI pins.
DS70138C-page 192
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
FIGURE 23-17:
SPI MODULE SLAVE MODE (CKE = 1) TIMING CHARACTERISTICS
SP60
SSX
SP52
SP50
SCKX
(CKP = 0)
SP71
SP70
SP72
SP73
SCKX
(CKP = 1)
SP35
SP73
SP72
LSb
SP52
MSb
BIT14 - - - - - -1
SDOX
SP30,SP31
SP51
SDIX
MSb IN
SP41
BIT14 - - - -1
LSb IN
SP40
Note: Refer to Figure 23-3 for load conditions.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 193
dsPIC30F3014/4013
TABLE 23-34: SPI MODULE SLAVE MODE (CKE = 1) TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
(1)
(2)
Symbol
TscL
Characteristic
Min
Typ
Max
Units
Conditions
No.
SP70
SP71
SP72
SP73
SP30
SP31
SP35
SCKX Input Low Time
SCKX Input High Time
30
30
—
—
—
—
—
—
—
—
—
10
10
—
—
—
25
25
25
25
30
ns
ns
ns
ns
ns
ns
ns
—
—
—
—
—
—
—
TscH
TscF
TscR
TdoF
TdoR
(3)
SCKX Input Fall Time
(3)
SCKX Input Rise Time
(3)
SDOX Data Output Fall Time
(3)
SDOX Data Output Rise Time
TscH2doV, SDOX Data Output Valid after
TscL2doV SCKX Edge
SP40
SP41
SP50
SP51
SP52
SP60
TdiV2scH, Setup Time of SDIX Data Input
TdiV2scL to SCKX Edge
20
—
—
—
—
—
—
—
—
—
50
—
50
ns
ns
ns
ns
ns
ns
—
—
—
—
—
—
TscH2diL, Hold Time of SDIX Data Input
TscL2diL to SCKX Edge
20
TssL2scH, SSX↓ to SCKX↓ or SCKX↑ input
120
TssL2scL
TssH2doZ SS↑ to SDOX Output
10
1.5 TCY + 40
—
(4)
Hi-Impedance
TscH2ssH SSX↑ after SCKX Edge
TscL2ssH
TssL2doV SDOX Data Output Valid after
SCKX Edge
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
3: The minimum clock period for SCK is 100 ns. Therefore, the clock generated in master mode must not
violate this specification.
4: Assumes 50 pF load on all SPI pins.
DS70138C-page 194
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
2
I C BUS START/STOP BITS TIMING CHARACTERISTICS (MASTER MODE)
FIGURE 23-18:
SCL
IM31
IM34
IM30
IM33
SDA
Stop
Condition
Start
Condition
Note: Refer to Figure 23-3 for load conditions.
2
I C BUS DATA TIMING CHARACTERISTICS (MASTER MODE)
FIGURE 23-19:
IM20
IM21
IM11
IM10
SCL
IM11
IM26
IM10
IM33
IM25
SDA
In
IM45
IM40
IM40
SDA
Out
Note: Refer to Figure 23-3 for load conditions.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 195
dsPIC30F3014/4013
2
TABLE 23-35: I C BUS DATA TIMING REQUIREMENTS (MASTER MODE)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
(1)
Min
Characteristic
Max
Units
Conditions
IM10
IM11
IM20
IM21
IM25
IM26
IM30
IM31
IM33
IM34
IM40
IM45
IM50
TLO:SCL Clock Low Time 100 kHz mode TCY / 2 (BRG + 1)
—
—
µs
µs
µs
µs
µs
µs
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
µs
ns
µs
µs
µs
µs
µs
µs
µs
µs
µs
ns
ns
ns
ns
ns
ns
µs
µs
µs
pF
—
—
—
—
—
—
400 kHz mode TCY / 2 (BRG + 1)
(2)
1 MHz mode
TCY / 2 (BRG + 1)
—
THI:SCL Clock High Time 100 kHz mode TCY / 2 (BRG + 1)
—
400 kHz mode TCY / 2 (BRG + 1)
—
(2)
1 MHz mode
100 kHz mode
400 kHz mode
TCY / 2 (BRG + 1)
—
TF:SCL
SDA and SCL
Fall Time
—
300
300
100
1000
300
300
—
CB is specified to be
from 10 to 400 pF
20 + 0.1 CB
(2)
1 MHz mode
—
TR:SCL
SDA and SCL
Rise Time
100 kHz mode
400 kHz mode
—
CB is specified to be
from 10 to 400 pF
20 + 0.1 CB
(2)
1 MHz mode
—
250
100
TBD
0
TSU:DAT Data Input
100 kHz mode
400 kHz mode
—
Setup Time
—
(2)
1 MHz mode
—
THD:DAT Data Input
100 kHz mode
400 kHz mode
—
—
Hold Time
0
0.9
—
(2)
1 MHz mode
TBD
TSU:STA Start Condition 100 kHz mode TCY / 2 (BRG + 1)
—
Only relevant for
repeated Start
condition
Setup Time
400 kHz mode TCY / 2 (BRG + 1)
—
(2)
1 MHz mode
TCY / 2 (BRG + 1)
—
THD:STA Start Condition 100 kHz mode TCY / 2 (BRG + 1)
—
After this period the
first clock pulse is
generated
Hold Time
400 kHz mode TCY / 2 (BRG + 1)
—
(2)
1 MHz mode
TCY / 2 (BRG + 1)
—
TSU:STO Stop Condition 100 kHz mode TCY / 2 (BRG + 1)
—
—
Setup Time
400 kHz mode TCY / 2 (BRG + 1)
—
(2)
1 MHz mode
TCY / 2 (BRG + 1)
—
THD:STO Stop Condition 100 kHz mode TCY / 2 (BRG + 1)
—
—
Hold Time
400 kHz mode TCY / 2 (BRG + 1)
—
(2)
1 MHz mode
100 kHz mode
400 kHz mode
TCY / 2 (BRG + 1)
—
TAA:SCL Output Valid
—
—
3500
1000
—
—
—
—
From Clock
(2)
1 MHz mode
—
TBF:SDA Bus Free Time 100 kHz mode
4.7
1.3
TBD
—
—
Time the bus must be
free before a new
400 kHz mode
—
transmission can start
(2)
1 MHz mode
—
CB
Bus Capacitive Loading
400
2 2
Note 1: BRG is the value of the I C Baud Rate Generator. Refer to Section 21 “Inter-Integrated Circuit™ (I C)”
in the dsPIC30F Family Reference Manual.
2
2: Maximum pin capacitance = 10 pF for all I C pins (for 1 MHz mode only).
DS70138C-page 196
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
2
I C BUS START/STOP BITS TIMING CHARACTERISTICS (SLAVE MODE)
FIGURE 23-20:
SCL
IS34
IS31
IS30
IS33
SDA
Stop
Condition
Start
Condition
2
I C BUS DATA TIMING CHARACTERISTICS (SLAVE MODE)
FIGURE 23-21:
IS20
IS21
IS11
IS10
SCL
IS30
IS26
IS31
IS33
IS25
SDA
In
IS45
IS40
IS40
SDA
Out
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 197
dsPIC30F3014/4013
2
TABLE 23-36: I C BUS DATA TIMING REQUIREMENTS (SLAVE MODE)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
Characteristic
Min
Max Units
Conditions
No.
IS10
TLO:SCL Clock Low Time 100 kHz mode
4.7
—
—
µs
µs
Device must operate at a
minimum of 1.5 MHz
400 kHz mode
1.3
Device must operate at a
minimum of 10 MHz.
(1)
1 MHz mode
0.5
4.0
—
—
µs
µs
—
IS11
THI:SCL
Clock High Time 100 kHz mode
Device must operate at a
minimum of 1.5 MHz
400 kHz mode
0.6
—
µs
Device must operate at a
minimum of 10 MHz
(1)
1 MHz mode
0.5
—
300
300
100
1000
300
300
—
µs
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
ns
ns
ns
ns
ns
ns
µs
µs
µs
pF
—
IS20
IS21
IS25
IS26
IS30
IS31
IS33
IS34
IS40
IS45
IS50
TF:SCL
SDA and SCL
Fall Time
100 kHz mode
400 kHz mode
—
CB is specified to be from
10 to 400 pF
20 + 0.1 CB
(1)
1 MHz mode
—
—
TR:SCL
SDA and SCL
Rise Time
100 kHz mode
400 kHz mode
CB is specified to be from
10 to 400 pF
20 + 0.1 CB
—
(1)
1 MHz mode
TSU:DAT Data Input
100 kHz mode
400 kHz mode
250
100
100
0
—
Setup Time
—
(1)
1 MHz mode
—
THD:DAT Data Input
100 kHz mode
400 kHz mode
—
—
Hold Time
0
0.9
0.3
—
(1)
1 MHz mode
0
TSU:STA Start Condition
100 kHz mode
400 kHz mode
4.7
0.6
0.25
4.0
0.6
0.25
4.7
0.6
0.6
4000
600
250
0
Only relevant for repeated
Start condition
Setup Time
—
(1)
1 MHz mode
—
THD:STA Start Condition
100 kHz mode
400 kHz mode
—
After this period the first
clock pulse is generated
Hold Time
—
(1)
1 MHz mode
—
TSU:STO Stop Condition
100 kHz mode
400 kHz mode
—
—
—
—
Setup Time
—
(1)
1 MHz mode
—
THD:STO Stop Condition
100 kHz mode
400 kHz mode
—
Hold Time
—
(1)
1 MHz mode
TAA:SCL
Output Valid
From Clock
100 kHz mode
400 kHz mode
3500
1000
350
—
0
(1)
1 MHz mode
0
TBF:SDA Bus Free Time
100 kHz mode
400 kHz mode
4.7
1.3
0.5
—
Time the bus must be free
before a new transmission
can start
—
(1)
1 MHz mode
—
CB
Bus Capacitive
Loading
400
—
2
Note 1: Maximum pin capacitance = 10 pF for all I C pins (for 1 MHz mode only).
DS70138C-page 198
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
FIGURE 23-22:
CAN MODULE I/O TIMING CHARACTERISTICS
CXTX Pin
New Value
Old Value
(output)
CA10 CA11
CXRX Pin
(input)
CA20
TABLE 23-37: CAN MODULE I/O TIMING REQUIREMENTS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
AC CHARACTERISTICS
Param
Symbol
No.
(1)
(2)
Characteristic
Min
Typ
Max
Units
Conditions
TioF
TioR
Tcwf
CA10
CA11
CA20
Port Output Fall Time
Port Output Rise Time
—
—
10
10
25
25
ns
ns
ns
—
—
—
Pulse Width to Trigger
CAN Wakeup Filter
500
Note 1: These parameters are characterized but not tested in manufacturing.
2: Data in “Typ” column is at 5V, 25°C unless otherwise stated. Parameters are for design guidance only and
are not tested.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 199
dsPIC30F3014/4013
TABLE 23-38: 12-BIT A/D MODULE SPECIFICATIONS
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
Characteristic
Min.
Typ
Max.
Units
Conditions
Device Supply
AD01 AVDD
Module VDD Supply
Greater of
VDD - 0.3
or 2.7
—
Lesser of
VDD + 0.3
or 5.5
V
V
—
—
AD02 AVSS
Module VSS Supply
VSS - 0.3
—
VSS + 0.3
Reference Inputs
AD05
AD06
AD07
VREFH
VREFL
VREF
Reference Voltage High
Reference Voltage Low
AVSS + 2.7
AVSS
—
—
—
AVDD
V
V
V
—
—
—
AVDD - 2.7
AVDD + 0.3
Absolute Reference
Voltage
AVSS - 0.3
AD08
IREF
Current Drain
—
200
300
3
µA
µA
A/D operating
.001
A/D off
Analog Input
VREFL
AD10 VINH-VINL Full-Scale Input Span
VREFH
AVDD + 0.3
0.610
V
V
See Note
AD11
AD12
VIN
Absolute Input Voltage
Leakage Current
AVSS - 0.3
—
—
—
0.001
µA
VINL = AVSS = VREFL =
0V, AVDD = VREFH = 5V
Source Impedance =
2.5 kΩ
AD13
—
Leakage Current
—
0.001
0.610
µA
VINL = AVSS = VREFL =
0V, AVDD = VREFH = 3V
Source Impedance =
2.5 kΩ
AD15
RSS
Switch Resistance
—
—
—
3.2K
18
—
Ω
pF
Ω
—
—
—
AD16 CSAMPLE Sample Capacitor
AD17
RIN
Recommended Impedance
of Analog Voltage Source
—
2.5K
DC Accuracy
12 data bits
0.75
AD20 Nr
Resolution
bits
AD21 INL
Integral Nonlinearity
—
—
—
—
—
—
TBD
TBD
< 1
< 1
TBD
TBD
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 5V
AD21A INL
AD22 DNL
AD22A DNL
Integral Nonlinearity
Differential Nonlinearity
Differential Nonlinearity
Gain Error
0.75
0.5
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 3V
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 5V
0.5
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 3V
AD23
GERR
1.25
1.25
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 5V
AD23A GERR
Gain Error
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 3V
Note 1: The A/D conversion result never decreases with an increase in the input voltage, and has no missing
codes.
DS70138C-page 200
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 23-38: 12-BIT A/D MODULE SPECIFICATIONS (CONTINUED)
Standard Operating Conditions: 2.5V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
Characteristic
Offset Error
Min.
Typ
Max.
Units
Conditions
AD24
EOFF
—
1.25
TBD
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 5V
AD24A EOFF
Offset Error
Monotonicity
—
1.25
TBD
LSb VINL = AVSS = VREFL =
0V, AVDD = VREFH = 3V
(1)
AD25
—
—
—
—
—
—
—
—
—
dB
dB
Guaranteed
AD26 CMRR
AD27 PSRR
Common-Mode Rejection
TBD
TBD
—
Power Supply Rejection
Ratio
—
AD28 CTLK
Channel to Channel
Crosstalk
—
TBD
—
dB
—
Dynamic Performance
AD30 THD
Total Harmonic Distortion
—
—
—
—
—
dB
dB
—
—
AD31 SINAD
Signal to Noise and
Distortion
TBD
AD32 SFDR
Spurious Free Dynamic
Range
—
TBD
—
dB
—
AD33
FNYQ
Input Signal Bandwidth
Effective Number of Bits
—
—
—
50
kHz
bits
—
—
AD34 ENOB
TBD
TBD
Note 1: The A/D conversion result never decreases with an increase in the input voltage, and has no missing
codes.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 201
dsPIC30F3014/4013
FIGURE 23-23:
12-BIT A/D CONVERSION TIMING CHARACTERISTICS
(ASAM = 0, SSRC = 000)
AD50
ADCLK
Instruction
Set SAMP
Clear SAMP
Execution
SAMP
ch0_dischrg
ch0_samp
eoc
AD61
AD60
TSAMP
AD55
DONE
ADIF
ADRES(0)
1
2
3
4
5
6
7
8
9
- Software sets ADCON. SAMP to start sampling.
- Sampling starts after discharge period.
1
2
TSAMP is described in the dsPIC30F Family Reference Manual, Section 18.
- Software clears ADCON. SAMP to start conversion.
- Sampling ends, conversion sequence starts.
- Convert bit 11.
3
4
5
6
7
8
9
- Convert bit 10.
- Convert bit 1.
- Convert bit 0.
- One TAD for end of conversion.
DS70138C-page 202
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
TABLE 23-39: 12-BIT A/D CONVERSION TIMING REQUIREMENTS
Standard Operating Conditions: 2.7V to 5.5V
(unless otherwise stated)
AC CHARACTERISTICS
Operating temperature -40°C ≤ TA ≤ +85°C for Industrial
-40°C ≤ TA ≤ +125°C for Extended
Param
Symbol
No.
Characteristic
Min.
Typ
Max.
Units
Conditions
Clock Parameters
AD50
AD51
TAD
tRC
A/D Clock Period
A/D Internal RC Oscillator Period
—
667
1.5
—
ns
VDD = 3-5.5V (Note 1)
1.2
1.8
µs
—
Conversion Rate
AD55
AD56
AD57
tCONV
FCNV
Conversion Time
Throughput Rate
Sampling Time
—
—
—
14 TAD
—
—
100
—
ns
ksps
ns
—
VDD = VREF = 5V
TSAMP
1 TAD
VDD = 3-5.5V source
resistance
RS = 0-2.5 kΩ
Timing Parameters
AD60
AD61
AD62
AD63
tPCS
tPSS
tCSS
tDPU
Conversion Start from Sample
Trigger
—
0.5 TAD
—
—
—
—
—
TAD
1.5 TAD
TBD
ns
ns
ns
µs
—
—
—
—
Sample Start from Setting
Sample (SAMP) Bit
Conversion Completion to
Sample Start (ASAM = 1)
Time to Stabilize Analog Stage
from A/D Off to A/D On
—
TBD
Note 1: Because the sample caps will eventually lose charge, clock rates below 10 kHz can affect linearity
performance, especially at elevated temperatures.
2: These parameters are characterized but not tested in manufacturing.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 203
dsPIC30F3014/4013
NOTES:
DS70138C-page 204
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
24.0 PACKAGING INFORMATION
24.1 Package Marking Information
40-Lead PDIP
Example
dsPIC30F4013
-30I/P
XXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXX
YYWWNNN
0510017
Example
44-Lead TQFP
dsPIC
XXXXXXXXXX
XXXXXXXXXX
XXXXXXXXXX
YYWWNNN
30F4013
-301/PT
0510017
44-Lead QFN
Example
XXXXXXXXXX
XXXXXXXXXX
XXXXXXXXXX
YYWWNNN
dsPIC
30F4013
-30I/ML
0510017
Legend: XX...X Customer specific information*
Y
Year code (last digit of calendar year)
YY
Year code (last 2 digits of calendar year)
Week code (week of January 1 is week ‘01’)
Alphanumeric traceability code
WW
NNN
Note: In the event the full Microchip part number cannot be marked on one line, it will
be carried over to the next line thus limiting the number of available characters
for customer specific information.
* Standard PICmicro device marking consists of Microchip part number, year code, week code, and
traceability code. For PICmicro device marking beyond this, certain price adders apply. Please check with
your Microchip Sales Office. For QTP devices, any special marking adders are included in QTP price.
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 205
dsPIC30F3014/4013
40-Lead Plastic Dual In-line – 600 mil Body (PDIP)
E1
D
2
α
n
1
E
A2
A
L
c
B1
B
β
A1
p
eB
Units
INCHES*
NOM
40
MILLIMETERS
Dimension Limits
MIN
MAX
MIN
NOM
40
MAX
n
p
Number of Pins
Pitch
.100
2.54
Top to Seating Plane
A
.160
.175
.190
.160
4.06
3.56
4.45
3.81
4.83
4.06
Molded Package Thickness
Base to Seating Plane
Shoulder to Shoulder Width
Molded Package Width
Overall Length
A2
A1
E
.140
.015
.595
.530
2.045
.120
.008
.030
.014
.620
5
.150
0.38
15.11
13.46
51.94
3.05
0.20
0.76
0.36
15.75
5
.600
.545
2.058
.130
.012
.050
.018
.650
10
.625
.560
2.065
.135
.015
.070
.022
.680
15
15.24
13.84
52.26
3.30
0.29
1.27
0.46
16.51
10
15.88
14.22
52.45
3.43
0.38
1.78
0.56
17.27
15
E1
D
Tip to Seating Plane
Lead Thickness
L
c
Upper Lead Width
B1
B
Lower Lead Width
Overall Row Spacing
Mold Draft Angle Top
§
eB
α
β
Mold Draft Angle Bottom
* Controlling Parameter
§ Significant Characteristic
5
10
15
5
10
15
Notes:
Dimensions D and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not exceed
.010” (0.254mm) per side.
JEDEC Equivalent: MO-011
Drawing No. C04-016
DS70138C-page 206
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
44-Lead Plastic Thin Quad Flatpack 10x10x1 mm Body, 1.0/0.10 mm Lead Form (TQFP)
E
E1
#leads=n1
p
D1
D
2
1
B
n
°
CH x 45
α
A
c
φ
β
A1
A2
L
(F)
Units
INCHES
NOM
44
MILLIMETERS*
Dimension Limits
MIN
MAX
MIN
NOM
44
MAX
n
p
Number of Pins
Pitch
.031
0.80
11
Pins per Side
Overall Height
n1
A
11
.043
.039
.004
.024
.039
3.5
.039
.037
.002
.018
.047
1.00
0.95
1.10
1.00
0.10
0.60
1.20
Molded Package Thickness
Standoff
A2
A1
L
.041
.006
.030
1.05
0.15
0.75
§
0.05
0.45
1.00
0
Foot Length
(F)
φ
Footprint (Reference)
Foot Angle
0
.463
.463
.390
.390
.004
.012
.025
5
7
.482
.482
.398
.398
.008
.017
.045
15
3.5
12.00
12.00
10.00
10.00
0.15
0.38
0.89
10
7
12.25
12.25
10.10
10.10
0.20
0.44
1.14
15
Overall Width
E
D
.472
.472
.394
.394
.006
.015
.035
10
11.75
11.75
9.90
9.90
0.09
0.30
0.64
5
Overall Length
Molded Package Width
Molded Package Length
Lead Thickness
E1
D1
c
Lead Width
B
CH
α
Pin 1 Corner Chamfer
Mold Draft Angle Top
Mold Draft Angle Bottom
β
5
10
15
5
10
15
* Controlling Parameter
§ Significant Characteristic
Notes:
Dimensions D1 and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not exceed
.010” (0.254mm) per side.
JEDEC Equivalent: MS-026
Drawing No. C04-076
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 207
dsPIC30F3014/4013
44-Lead Plastic Quad Flat No Lead Package 8x8 mm Body (QFN)
DS70138C-page 208
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
DCI Module............................................................... 116
Dedicated Port Structure ............................................ 51
DSP Engine................................................................ 18
dsPIC30F3014.............................................................. 9
dsPIC30F4013............................................................ 10
External Power-on Reset Circuit .............................. 143
INDEX
Numerics
12-bit Analog-to-Digital Converter (A/D) Module .............. 125
A
2
I C .............................................................................. 90
A/D.................................................................................... 125
Aborting a Conversion .............................................. 127
ADCHS Register....................................................... 125
ADCON1 Register..................................................... 125
ADCON2 Register..................................................... 125
ADCON3 Register..................................................... 125
ADCSSL Register ..................................................... 125
ADPCFG Register..................................................... 125
Configuring Analog Port Pins.............................. 52, 129
Connection Considerations....................................... 129
Conversion Operation............................................... 126
Effects of a Reset...................................................... 128
Operation During CPU Idle Mode ............................. 128
Operation During CPU Sleep Mode.......................... 128
Output Formats......................................................... 128
Power-down Modes .................................................. 128
Programming the Sample Trigger............................. 127
Register Map............................................................. 130
Result Buffer ............................................................. 126
Sampling Requirements............................................ 127
Selecting the Conversion Clock................................ 127
Selecting the Conversion Sequence......................... 126
AC Characteristics ............................................................ 175
Load Conditions........................................................ 175
AC Temperature and Voltage Specifications.................... 175
AC-Link Mode Operation .................................................. 122
16-bit Mode............................................................... 122
20-bit Mode............................................................... 123
Address Generator Units .................................................... 35
Alternate Vector Table ........................................................ 59
Analog-to-Digital Converter. See A/D.
Input Capture Mode.................................................... 77
Oscillator System...................................................... 133
Output Compare Mode............................................... 81
Reset System ........................................................... 141
Shared Port Structure................................................. 52
SPI.............................................................................. 86
SPI Master/Slave Connection..................................... 86
UART Receiver........................................................... 98
UART Transmitter....................................................... 97
BOR Characteristics ......................................................... 174
BOR. See Brown-out Reset.
Brown-out Reset
Characteristics.......................................................... 173
Timing Requirements ............................................... 182
C
C Compilers
MPLAB C17.............................................................. 158
MPLAB C18.............................................................. 158
MPLAB C30.............................................................. 158
CAN Module ..................................................................... 105
Baud Rate Setting .................................................... 110
CAN1 Register Map.................................................. 112
Frame Types ............................................................ 105
I/O Timing Characteristics ........................................ 199
I/O Timing Requirements.......................................... 199
Message Reception.................................................. 108
Message Transmission............................................. 109
Modes of Operation.................................................. 107
Overview................................................................... 105
CLKOUT and I/O Timing
Assembler
Characteristics.......................................................... 180
Requirements ........................................................... 180
Code Examples
MPASM Assembler................................................... 157
Automatic Clock Stretch...................................................... 92
During 10-bit Addressing (STREN = 1)....................... 92
During 7-bit Addressing (STREN = 1)......................... 92
Receive Mode............................................................. 92
Transmit Mode............................................................ 92
Data EEPROM Block Erase ....................................... 48
Data EEPROM Block Write ........................................ 50
Data EEPROM Read.................................................. 47
Data EEPROM Word Erase ....................................... 48
Data EEPROM Word Write ........................................ 49
Erasing a Row of Program Memory ........................... 43
Initiating a Programming Sequence ........................... 44
Loading Write Latches................................................ 44
Code Protection................................................................ 131
Control Registers................................................................ 42
NVMADR.................................................................... 42
NVMADRU ................................................................. 42
NVMCON.................................................................... 42
NVMKEY .................................................................... 42
Core Architecture
B
Bandgap Start-up Time
Requirements............................................................ 182
Timing Characteristics .............................................. 182
Barrel Shifter....................................................................... 21
Bit-Reversed Addressing .................................................... 38
Example...................................................................... 38
Implementation ........................................................... 38
Modifier Values Table ................................................. 39
Sequence Table (16-Entry)......................................... 39
Block Diagrams
Overview..................................................................... 13
CPU Architecture Overview................................................ 13
12-bit A/D Functional ................................................ 125
16-bit Timer1 Module.................................................. 63
16-bit Timer2............................................................... 69
16-bit Timer3............................................................... 69
16-bit Timer4............................................................... 74
16-bit Timer5............................................................... 74
32-bit Timer2/3............................................................ 68
32-bit Timer4/5............................................................ 73
CAN Buffers and Protocol Engine............................. 106
D
Data Accumulators and Adder/Subtractor .......................... 19
Data Space Write Saturation...................................... 21
Overflow and Saturation............................................. 19
Round Logic ............................................................... 20
Write Back .................................................................. 20
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 209
dsPIC30F3014/4013
Data Address Space ...........................................................28
Alignment....................................................................31
Alignment (Figure) ......................................................31
Effect of Invalid Memory Accesses (Table).................31
MCU and DSP (MAC Class) Instructions Example.....30
Memory Map.........................................................28, 29
Near Data Space ........................................................32
Software Stack............................................................32
Spaces........................................................................31
Width...........................................................................31
Data Converter Interface (DCI) Module ............................115
Data EEPROM Memory......................................................47
Erasing........................................................................48
Erasing, Block.............................................................48
Erasing, Word .............................................................48
Protection Against Spurious Write ..............................50
Reading.......................................................................47
Write Verify .................................................................50
Writing.........................................................................49
Writing, Block..............................................................49
Writing, Word ..............................................................49
DC Characteristics ............................................................163
BOR ..........................................................................174
Brown-out Reset .......................................................173
I/O Pin Input Specifications.......................................171
I/O Pin Output Specifications....................................172
Idle Current (IIDLE) ....................................................167
Low-Voltage Detect...................................................172
LVDL.........................................................................173
Operating Current (IDD).............................................165
Power-Down Current (IPD)........................................169
Program and EEPROM.............................................174
Temperature and Voltage Specifications..................163
DCI Module
Synchronous Data Transfers.................................... 120
Timing Characteristics
AC-Link Mode................................................... 189
2
Multichannel, I S Modes................................... 187
Timing Requirements
AC-Link Mode................................................... 189
2
Multichannel, I S Modes................................... 188
Transmit Slot Enable Bits ......................................... 120
Transmit Status Bits.................................................. 121
Transmit/Receive Shift Register............................... 115
Underflow Mode Control Bit...................................... 122
Word Size Selection Bits .......................................... 117
Demonstration Boards
PICDEM 1................................................................. 160
PICDEM 17............................................................... 160
PICDEM 18R ............................................................ 161
PICDEM 2 Plus......................................................... 160
PICDEM 3................................................................. 160
PICDEM 4................................................................. 160
PICDEM LIN ............................................................. 161
PICDEM USB ........................................................... 161
PICDEM.net Internet/Ethernet.................................. 160
Development Support....................................................... 157
Device Configuration
Register Map ............................................................ 148
Device Configuration Registers
FBORPOR................................................................ 146
FGS .......................................................................... 146
FOSC........................................................................ 146
FWDT ....................................................................... 146
Device Overview................................................................... 9
Disabling the UART ............................................................ 99
Divide Support .................................................................... 16
Instructions (Table)..................................................... 16
DSP Engine ........................................................................ 17
Multiplier ..................................................................... 19
Dual Output Compare Match Mode.................................... 82
Continuous Pulse Mode.............................................. 82
Single Pulse Mode...................................................... 82
Bit Clock Generator...................................................119
Buffer Alignment with Data Frames ..........................121
Buffer Control............................................................115
Buffer Data Alignment...............................................115
Buffer Length Control................................................121
COFS Pin..................................................................115
CSCK Pin..................................................................115
CSDI Pin ...................................................................115
CSDO Mode Bit ........................................................122
CSDO Pin .................................................................115
Data Justification Control Bit.....................................120
Device Frequencies for Common Codec CSCK Frequen-
cies (Table) .......................................................119
Digital Loopback Mode .............................................122
Enable.......................................................................117
Frame Sync Generator .............................................117
Frame Sync Mode Control Bits.................................117
I/O Pins .....................................................................115
Interrupts...................................................................122
Introduction ...............................................................115
Master Frame Sync Operation..................................117
Operation ..................................................................117
Operation During CPU Idle Mode .............................122
Operation During CPU Sleep Mode..........................122
Receive Slot Enable Bits...........................................120
Receive Status Bits...................................................121
Register Map.............................................................124
Sample Clock Edge Control Bit.................................120
Slave Frame Sync Operation....................................118
Slot Enable Bits Operation with Frame Sync............120
Slot Status Bits..........................................................122
E
Electrical Characteristics .................................................. 163
AC............................................................................. 175
DC ............................................................................ 163
Enabling and Setting Up UART
Alternate I/O ............................................................... 99
Setting Up Data, Parity and Stop Bit Selections......... 99
Enabling the UART............................................................. 99
Equations
A/D Conversion Clock............................................... 127
Baud Rate................................................................. 101
Bit Clock Frequency.................................................. 119
COFSG Period.......................................................... 117
Serial Clock Rate........................................................ 94
Time Quantum for Clock Generation........................ 111
Errata.................................................................................... 7
Evaluation and Programming Tools.................................. 161
Exception Sequence
Trap Sources .............................................................. 58
External Clock Timing Characteristics
Type A, B and C Timer............................................. 183
External Clock Timing Requirements ............................... 176
Type A Timer............................................................ 183
Type B Timer............................................................ 184
Type C Timer............................................................ 184
External Interrupt Requests................................................ 60
DS70138C-page 210
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
Instruction Addressing Modes ............................................ 35
File Register Instructions............................................ 35
Fundamental Modes Supported ................................. 35
MAC Instructions ........................................................ 36
MCU Instructions........................................................ 35
Move and Accumulator Instructions ........................... 36
Other Instructions ....................................................... 36
Instruction Set
F
Fast Context Saving............................................................ 60
Flash Program Memory ...................................................... 41
I
I/O Pin Specifications
Input.......................................................................... 171
Output ....................................................................... 172
I/O Ports.............................................................................. 51
Parallel (PIO) .............................................................. 51
Overview................................................................... 152
Summary .................................................................. 149
Internal Clock Timing Examples ....................................... 177
Interrupt Controller
2
I C 10-bit Slave Mode Operation........................................ 91
Reception.................................................................... 92
Transmission............................................................... 91
Register Map .............................................................. 62
Interrupt Priority.................................................................. 56
Traps .......................................................................... 58
Interrupt Sequence............................................................. 59
Interrupt Stack Frame................................................. 59
Interrupts ............................................................................ 55
2
I C 7-bit Slave Mode Operation.......................................... 91
Reception.................................................................... 91
Transmission............................................................... 91
2
I C Master Mode Operation................................................ 93
Baud Rate Generator.................................................. 94
Clock Arbitration.......................................................... 94
Multi-Master Communication, Bus Collision
L
Load Conditions................................................................ 175
Low Voltage Detect (LVD) ................................................ 145
Low-Voltage Detect Characteristics.................................. 172
LVDL Characteristics........................................................ 173
and Bus Arbitration ............................................. 94
Reception.................................................................... 94
Transmission............................................................... 93
2
I C Master Mode Support ................................................... 93
2
I C Module.......................................................................... 89
M
Addresses................................................................... 91
Bus Data Timing Characteristics
Memory Organization ......................................................... 23
Core Register Map ..................................................... 32
Modes of Operation
Master Mode..................................................... 195
Slave Mode....................................................... 197
Bus Data Timing Requirements
Disable...................................................................... 107
Initialization............................................................... 107
Listen All Messages.................................................. 107
Listen Only................................................................ 107
Loopback.................................................................. 107
Normal Operation ..................................................... 107
Modulo Addressing............................................................. 36
Applicability................................................................. 38
Incrementing Buffer Operation Example .................... 37
Start and End Address ............................................... 37
W Address Register Selection.................................... 37
MPLAB ASM30 Assembler, Linker, Librarian................... 158
MPLAB ICD 2 In-Circuit Debugger ................................... 159
MPLAB ICE 2000 High-Performance Universal
Master Mode..................................................... 196
Slave Mode....................................................... 198
Bus Start/Stop Bits Timing Characteristics
Master Mode..................................................... 195
Slave Mode....................................................... 197
General Call Address Support .................................... 93
Interrupts..................................................................... 93
IPMI Support............................................................... 93
Operating Function Description .................................. 89
Operation During CPU Sleep and Idle Modes ............ 94
Pin Configuration ........................................................ 89
Programmer’s Model................................................... 89
Register Map............................................................... 95
Registers..................................................................... 89
Slope Control .............................................................. 93
Software Controlled Clock Stretching (STREN = 1).... 92
Various Modes............................................................ 89
In-Circuit Emulator.................................................... 159
MPLAB ICE 4000 High-Performance Universal
In-Circuit Emulator.................................................... 159
MPLAB Integrated Development Environment
Software ................................................................... 157
MPLINK Object Linker/MPLIB Object Librarian................ 158
2
I S Mode Operation .......................................................... 123
Data Justification....................................................... 123
Frame and Data Word Length Selection................... 123
Idle Current (IIDLE) ............................................................ 167
In-Circuit Serial Programming (ICSP)......................... 41, 131
Input Capture (CAPX) Timing Characteristics .................. 185
Input Capture Module ......................................................... 77
Interrupts..................................................................... 78
Register Map............................................................... 79
Input Capture Operation During Sleep and Idle Modes...... 78
CPU Idle Mode............................................................ 78
CPU Sleep Mode ........................................................ 78
Input Capture Timing Requirements................................. 185
Input Change Notification Module....................................... 54
dsPIC30F3014 Register Map (Bits 15-8).................... 54
dsPIC30F3014 Register Map (Bits 7-0)...................... 54
dsPIC30F4013 Register Map (Bits 15-8).................... 54
dsPIC30F4013 Register Map (Bits 7-0)...................... 54
N
NVM
Register Map .............................................................. 45
O
OC/PWM Module Timing Characteristics ......................... 186
Operating Current (IDD) .................................................... 165
Operating Frequency vs Voltage
dsPIC30FXXXX-20 (Extended) ................................ 163
Oscillator
Configurations .......................................................... 134
Fail-Safe Clock Monitor .................................... 136
Fast RC (FRC).................................................. 135
Initial Clock Source Selection........................... 134
Low Power RC (LPRC)..................................... 135
LP Oscillator Control......................................... 135
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 211
dsPIC30F3014/4013
Phase Locked Loop (PLL) ................................135
Start-up Timer (OST) ........................................134
Control Registers ......................................................137
Operating Modes (Table)..........................................132
System Overview......................................................131
Oscillator Selection ...........................................................131
Oscillator Start-up Timer
R
Reset ........................................................................ 131, 141
BOR, Programmable ................................................ 143
Brown-out Reset (BOR)............................................ 131
Oscillator Start-up Timer (OST)................................ 131
POR
Operating without FSCM and PWRT................ 143
With Long Crystal Start-up Time ...................... 143
POR (Power-on Reset)............................................. 141
Power-on Reset (POR)............................................. 131
Power-up Timer (PWRT) .......................................... 131
Reset Sequence ................................................................. 57
Reset Sources ............................................................ 57
Reset Sources
Timing Characteristics ..............................................181
Timing Requirements................................................182
Output Compare Interrupts .................................................83
Output Compare Module.....................................................81
Register Map dsPIC30F3014......................................84
Register Map dsPIC30F4013......................................84
Timing Characteristics ..............................................185
Timing Requirements................................................185
Output Compare Operation During CPU Idle Mode............83
Output Compare Sleep Mode Operation.............................83
Brown-out Reset (BOR).............................................. 57
Illegal Instruction Trap ................................................ 57
Trap Lockout............................................................... 57
Uninitialized W Register Trap ..................................... 57
Watchdog Time-out .................................................... 57
Reset Timing Characteristics............................................ 181
Reset Timing Requirements ............................................. 182
Run-Time Self-Programming (RTSP)................................. 41
P
Packaging Information ......................................................205
Marking .....................................................................205
Peripheral Module Disable (PMD) Registers ....................147
PICkit 1 Flash Starter Kit...................................................161
PICSTART Plus Development Programmer .....................159
Pinout Descriptions .............................................................11
PLL Clock Timing Specifications.......................................177
POR. See Power-on Reset.
S
Simple Capture Event Mode............................................... 77
Buffer Operation ......................................................... 78
Hall Sensor Mode ....................................................... 78
Prescaler .................................................................... 77
Timer2 and Timer3 Selection Mode............................ 78
Simple OC/PWM Mode Timing Requirements ................. 186
Simple Output Compare Match Mode ................................ 82
Simple PWM Mode............................................................. 82
Input Pin Fault Protection ........................................... 82
Period ......................................................................... 83
Software Simulator (MPLAB SIM) .................................... 158
Software Simulator (MPLAB SIM30) ................................ 158
Software Stack Pointer, Frame Pointer .............................. 14
CALL Stack Frame ..................................................... 32
SPI Module ......................................................................... 85
Framed SPI Support................................................... 85
Operating Function Description .................................. 85
Operation During CPU Idle Mode............................... 87
Operation During CPU Sleep Mode............................ 87
SDOx Disable ............................................................. 85
Slave Select Synchronization ..................................... 87
SPI1 Register Map...................................................... 88
Timing Characteristics
Port Register Map for dsPIC30F3014/4013........................53
Port Write/Read Example....................................................52
Power Saving Modes ........................................................145
Idle ............................................................................146
Sleep.........................................................................145
Sleep and Idle...........................................................131
Power-Down Current (IPD) ................................................169
Power-up Timer
Timing Characteristics ..............................................181
Timing Requirements................................................182
PRO MATE II Universal Device Programmer ...................159
Program Address Space.....................................................23
Construction................................................................24
Data Access from Program Memory Using
Program Space Visibility.....................................26
Data Access From Program Memory Using
Table Instructions................................................25
Data Access from, Address Generation......................24
Data Space Window into Operation............................27
Data Table Access (LS Word) ....................................25
Data Table Access (MS Byte).....................................26
Memory Map...............................................................23
Table Instructions
Master Mode (CKE = 0).................................... 190
Master Mode (CKE = 1).................................... 191
Slave Mode (CKE = 1).............................. 192, 193
Timing Requirements
TBLRDH..............................................................25
TBLRDL ..............................................................25
TBLWTH .............................................................25
TBLWTL..............................................................25
Program and EEPROM Characteristics............................174
Program Counter.................................................................14
Programmable...................................................................131
Programmer’s Model...........................................................14
Diagram ......................................................................15
Programming Operations....................................................43
Algorithm for Program Flash.......................................43
Erasing a Row of Program Memory............................43
Initiating the Programming Sequence.........................44
Loading Write Latches ................................................44
Protection Against Accidental Writes to OSCCON ...........136
Master Mode (CKE = 0).................................... 190
Master Mode (CKE = 1).................................... 191
Slave Mode (CKE = 0)...................................... 192
Slave Mode (CKE = 1)...................................... 194
Word and Byte Communication.................................. 85
Status Bits, Their Significance and the Initialization
Condition for RCON Register, Case 1...................... 144
Status Bits, Their Significance and the Initialization
Condition for RCON Register, Case 2...................... 144
Status Register ................................................................... 14
Symbols Used in Opcode Descriptions ............................ 150
System Integration............................................................ 131
Register Map ............................................................ 148
DS70138C-page 212
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
Time-out Sequence on Power-up
T
(MCLR Not Tied to VDD), Case 1 ..................... 142
Time-out Sequence on Power-up
Table Instruction Operation Summary ................................ 41
Temperature and Voltage Specifications
(MCLR Not Tied to VDD), Case 2 ..................... 142
Time-out Sequence on Power-up
AC............................................................................. 175
DC............................................................................. 163
Timer1 Module.................................................................... 63
16-bit Asynchronous Counter Mode ........................... 63
16-bit Synchronous Counter Mode ............................. 63
16-bit Timer Mode....................................................... 63
Gate Operation ........................................................... 64
Interrupt....................................................................... 64
Operation During Sleep Mode .................................... 64
Prescaler..................................................................... 64
Real-Time Clock ......................................................... 64
Interrupts............................................................. 65
Oscillator Operation............................................ 65
Register Map............................................................... 66
Timer2 and Timer3 Selection Mode.................................... 81
Timer2/3 Module................................................................. 67
16-bit Timer Mode....................................................... 67
32-bit Synchronous Counter Mode ............................. 67
32-bit Timer Mode....................................................... 67
ADC Event Trigger...................................................... 70
Gate Operation ........................................................... 70
Interrupt....................................................................... 70
Operation During Sleep Mode .................................... 70
Register Map............................................................... 71
Timer Prescaler........................................................... 70
Timer4/5 Module................................................................. 73
Register Map............................................................... 75
Timing Characteristics
(MCLR Tied to VDD) ......................................... 142
Timing Diagrams and Specifications
DC Characteristics - Internal RC Accuracy .............. 177
Timing Diagrams.See Timing Characteristics
Timing Requirements
A/D Conversion
Low-speed........................................................ 203
Bandgap Start-up Time ............................................ 182
Brown-out Reset....................................................... 182
CAN Module I/O ....................................................... 199
CLKOUT and I/O ...................................................... 180
DCI Module
AC-Link Mode................................................... 189
2
Multichannel, I S Modes................................... 188
External Clock .......................................................... 176
2
I C Bus Data (Master Mode) .................................... 196
2
I C Bus Data (Slave Mode) ...................................... 198
Input Capture............................................................ 185
Oscillator Start-up Timer........................................... 182
Output Compare Module .......................................... 185
Power-up Timer........................................................ 182
Reset ........................................................................ 182
Simple OC/PWM Mode ............................................ 186
SPI Module
Master Mode (CKE = 0).................................... 190
Master Mode (CKE = 1).................................... 191
Slave Mode (CKE = 0)...................................... 192
Slave Mode (CKE = 1)...................................... 194
Type A Timer External Clock.................................... 183
Type B Timer External Clock.................................... 184
Type C Timer External Clock.................................... 184
Watchdog Timer ....................................................... 182
Timing Specifications
A/D Conversion
Low-speed (ASAM = 0, SSRC = 000) .............. 202
Bandgap Start-up Time............................................. 182
CAN Module I/O........................................................ 199
CLKOUT and I/O....................................................... 180
DCI Module
AC-Link Mode................................................... 189
PLL Clock ................................................................. 177
Trap Vectors ....................................................................... 59
2
Multichannel, I S Modes................................... 187
External Clock........................................................... 175
2
I C Bus Data
U
Master Mode..................................................... 195
Slave Mode....................................................... 197
UART Module
Address Detect Mode............................................... 101
Auto Baud Support ................................................... 102
Baud Rate Generator ............................................... 101
Enabling and Setting Up............................................. 99
Framing Error (FERR) .............................................. 101
Idle Status................................................................. 101
Loopback Mode........................................................ 101
Operation During CPU Sleep and Idle Modes.......... 102
Overview..................................................................... 97
Parity Error (PERR).................................................. 101
Receive Break .......................................................... 101
Receive Buffer (UxRXB)........................................... 100
Receive Buffer Overrun Error (OERR Bit)................ 100
Receive Interrupt ...................................................... 100
Receiving Data ......................................................... 100
Receiving in 8-bit or 9-bit Data Mode ....................... 100
Reception Error Handling ......................................... 100
Transmit Break ......................................................... 100
Transmit Buffer (UxTXB) ............................................ 99
Transmit Interrupt ..................................................... 100
Transmitting Data ....................................................... 99
Transmitting in 8-bit Data Mode ................................. 99
Transmitting in 9-bit Data Mode ................................. 99
2
I C Bus Start/Stop Bits
Master Mode..................................................... 195
Slave Mode....................................................... 197
Input Capture (CAPX)............................................... 185
OC/PWM Module...................................................... 186
Oscillator Start-up Timer........................................... 181
Output Compare Module........................................... 185
Power-up Timer ........................................................ 181
Reset......................................................................... 181
SPI Module
Master Mode (CKE = 0).................................... 190
Master Mode (CKE = 1).................................... 191
Slave Mode (CKE = 0)...................................... 192
Slave Mode (CKE = 1)...................................... 193
Type A, B and C Timer External Clock ..................... 183
Watchdog Timer........................................................ 181
Timing Diagrams
CAN Bit ..................................................................... 110
Frame Sync, AC-Link Start of Frame........................ 118
Frame Sync, Multi-Channel Mode ............................ 118
2
I S Interface Frame Sync.......................................... 118
PWM Output ............................................................... 83
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 213
dsPIC30F3014/4013
UART1 Register Map................................................103
UART2 Register Map................................................103
UART Operation
W
Wake-up from Sleep......................................................... 131
Wake-up from Sleep and Idle ............................................. 60
Watchdog Timer
Idle Mode ..................................................................102
Sleep Mode...............................................................102
Unit ID Locations...............................................................131
Universal Asynchronous Receiver Transmitter (UART)
Module ........................................................................97
Timing Characteristics .............................................. 181
Timing Requirements................................................ 182
Watchdog Timer (WDT)............................................ 131, 145
Enabling and Disabling............................................. 145
Operation.................................................................. 145
WWW, On-Line Support ....................................................... 7
DS70138C-page 214
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
ON-LINE SUPPORT
SYSTEMS INFORMATION AND
UPGRADE HOT LINE
Microchip provides on-line support on the Microchip
World Wide Web site.
The Systems Information and Upgrade Line provides
system users a listing of the latest versions of all of
Microchip's development systems software products.
Plus, this line provides information on how customers
can receive the most current upgrade kits.The Hot Line
Numbers are:
The web site is used by Microchip as a means to make
files and information easily available to customers. To
view the site, the user must have access to the Internet
®
and a web browser, such as Netscape or Microsoft
®
Internet Explorer. Files are also available for FTP
download from our FTP site.
1-800-755-2345 for U.S. and most of Canada, and
1-480-792-7302 for the rest of the world.
Connecting to the Microchip Internet
Web Site
The Microchip web site is available at the following
URL:
www.microchip.com
The file transfer site is available by using an FTP
service to connect to:
ftp://ftp.microchip.com
The web site and file transfer site provide a variety of
services. Users may download files for the latest
Development Tools, Data Sheets, Application Notes,
User's Guides, Articles and Sample Programs. A vari-
ety of Microchip specific business information is also
available, including listings of Microchip sales offices,
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available for consideration is:
• Latest Microchip Press Releases
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Questions
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• Links to other useful web sites related to
Microchip Products
• Conferences for products, Development Systems,
technical information and more
• Listing of seminars and events
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Advance Information
DS70138C-page 215
dsPIC30F3014/4013
READER RESPONSE
It is our intention to provide you with the best documentation possible to ensure successful use of your Microchip prod-
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dsPIC30F3014/4013
DS70138C
Literature Number:
Device:
Questions:
1. What are the best features of this document?
2. How does this document meet your hardware and software development needs?
3. Do you find the organization of this document easy to follow? If not, why?
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7. How would you improve this document?
DS70138C-page 216
Advance Information
2004 Microchip Technology Inc.
dsPIC30F3014/4013
PRODUCT IDENTIFICATION SYSTEM
To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.
dsPIC30F4013AT-30I/PT-ES
Custom ID (3 digits) or
Engineering Sample (ES)
Trademark
Architecture
Package
= 40-pin PDIP
PT = 44-pin TQFP (10x10)
ML = 44-pin QFN (8x8)
= Die (Waffle Pack)
= Die (Wafers)
P
Flash
S
Memory Size in Bytes
W
0 = ROMless
1 = 1K to 6K
2 = 7K to 12K
3 = 13K to 24K
4 = 25K to 48K
5 = 49K to 96K
6 = 97K to 192K
7 = 193K to 384K
8 = 385K to 768K
9 = 769K and Up
Temperature
I = Industrial -40°C to +85°C
E = Extended High Temp -40°C to +125°C
Speed
20 = 20 MIPS
30 = 30 MIPS
Device ID
T = Tape and Reel
A,B,C… = Revision Level
Example:
dsPIC30F4013AT-30I/PT = 30 MIPS, Industrial temp., TQFP package, Rev. A
2004 Microchip Technology Inc.
Advance Information
DS70138C-page 217
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Boston
Tel: 39-0331-742611
Fax: 39-0331-466781
Singapore
Westford, MA
Tel: 978-692-3848
Fax: 978-692-3821
Fax: 852-2401-3431
Tel: 65-6334-8870
Fax: 65-6334-8850
Netherlands - Drunen
Tel: 31-416-690399
Fax: 31-416-690340
China - Shanghai
Tel: 86-21-5407-5533
Fax: 86-21-5407-5066
China - Shenyang
Tel: 86-24-2334-2829
Fax: 86-24-2334-2393
Taiwan - Kaohsiung
Tel: 886-7-536-4818
Fax: 886-7-536-4803
Chicago
Itasca, IL
England - Berkshire
Tel: 44-118-921-5869
Fax: 44-118-921-5820
Tel: 630-285-0071
Fax: 630-285-0075
Taiwan - Taipei
Tel: 886-2-2500-6610
Fax: 886-2-2508-0102
Dallas
China - Shenzhen
Addison, TX
Tel: 86-755-8203-2660
Fax: 86-755-8203-1760
Tel: 972-818-7423
Fax: 972-818-2924
Taiwan - Hsinchu
Tel: 886-3-572-9526
Fax: 886-3-572-6459
China - Shunde
Detroit
Tel: 86-757-2839-5507
Fax: 86-757-2839-5571
Farmington Hills, MI
Tel: 248-538-2250
Fax: 248-538-2260
China - Qingdao
Tel: 86-532-502-7355
Fax: 86-532-502-7205
Kokomo
Kokomo, IN
Tel: 765-864-8360
Fax: 765-864-8387
Los Angeles
Mission Viejo, CA
Tel: 949-462-9523
Fax: 949-462-9608
San Jose
Mountain View, CA
Tel: 650-215-1444
Fax: 650-961-0286
Toronto
Mississauga, Ontario,
Canada
Tel: 905-673-0699
Fax: 905-673-6509
10/20/04
DS70138C-page 218
Advance Information
2004 Microchip Technology Inc.
相关型号:
DSPIC30F2013AT-30E/PF-ES
General Purpose and Sensor Families High-Performance Digital Signal Controllers
MICROCHIP
DSPIC30F2013AT-30E/PT-ES
General Purpose and Sensor Families High-Performance Digital Signal Controllers
MICROCHIP
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