M37544G2HP [RENESAS]
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER; 单片8位CMOS微机型号: | M37544G2HP |
厂家: | RENESAS TECHNOLOGY CORP |
描述: | SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER |
文件: | 总68页 (文件大小:660K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
7544 Group
REJ03B0012-0104Z
Rev.1.04
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
2004.06.08
DESCRIPTION
• Clock generating circuit............................................. Built-in type
(low-power dissipation by an on-chip oscillator enabled)
(connect to external ceramic resonator or quartz-crystal oscilla-
tor permitting RC oscillation)
The 7544 Group is the 8-bit microcomputer based on the 740 fam-
ily core technology.
The 7544 Group has a serial I/O, 8-bit timers, a 16-bit timer, and
an A/D converter, and is useful for control of home electric appli-
ances and office automation equipment.
• Watchdog timer ............................................................ 16-bit ✕ 1
• Power source voltage
X
IN oscillation frequency at ceramic/quartz-crystal oscillation, in
FEATURES
double-speed mode
• Basic machine-language instructions ...................................... 71
• The minimum instruction execution time ......................... 0.25 µs
(at 8 MHz oscillation frequency, double-speed mode for the
shortest instruction)
At 8 MHz .................................................................... 4.5 to 5.5 V
XIN oscillation frequency at ceramic/quartz-crystal oscillation, in
high-speed mode
At 8 MHz .................................................................... 4.0 to 5.5 V
XIN oscillation frequency at RC oscillation
• Memory size ROM......................................................... 8 K bytes
RAM ........................................................ 256 bytes
At 4 MHz .................................................................... 4.0 to 5.5 V
• Power dissipation ........................................... 22.5mW(standard)
• Operating temperature range................................... –20 to 85 °C
• Programmable I/O ports ........................................................... 25
• Interrupts ................................................. 12 sources, 12 vectors
• Timers ............................................................................. 8-bit ✕ 2
...................................................................................... 16-bit ✕ 1
• Serial I/O...................... 8-bit ✕ 1 (UART or Clock-synchronized)
• A/D converter ................................................. 8-bit ✕ 6 channels
APPLICATION
Office automation equipment, factory automation equipment,
home electric appliances, consumer electronics, etc.
PIN CONFIGURATION (TOP VIEW)
1
32
P1
P1
P1 /CNTR
2
/SCLK
P1
P1
P0
P0
P0
P0
P0
P0
P0
P0
1
0
7
6
5
/T
/R
X
D
D
2
3
4
5
31
30
29
28
3/SRDY
X
4
0
0
1
(LED
(LED
(LED
(LED
(LED
(LED
(LED
(LED
7
6
5
)
)
)
)
P2
0
/AN
/AN
/AN
/AN
/AN
/AN
P2
P2
P2
P2
P2
1
6
7
8
27
26
25
2
3
4
5
2
3
4
5
4
3
4
3
)/TXOUT
)
)
2
1
0
2
1
0
9
10
11
12
24
23
22
21
V
REF
)/CNTR
1
P3
P3
P3
P3
P3
P3
7
(LED13)/INT
4
0
RESET
CNVSS
(LED12)/INT
1
13
14
15
16
20
19
18
17
V
CC
IN
OUT
SS
3
2
1
0
(LED11
(LED10
(LED
(LED
)
)
X
X
9
8
)
)
V
Package type : 32P4B
Fig. 1 Pin configuration (32P4B type)
Rev.1.04 2004.06.08 page 1 of 66
REJ03B0012-0104Z
7544 Group
25
26
27
28
29
30
31
32
16
15
14
13
12
11
10
9
P0
P1
P1
P1
P1
P1
7
(LED
7
)
P3
P3
P3
4
(LED12)/INT
(LED11
(LED10
1
0
/RX
D
D
3
)
)
1
/T
X
2
M37544M2-XXXGP
M37544G2GP
2/SCLK
P3
1
(LED
(LED
9
)
)
3/SRDY
P30
8
4
/CNTR
P2 AN
P2 AN
0
VSS
0/
0
X
X
OUT
IN
1/
1
Package type : 32P6U-A
Fig. 2 Pin configuration (32P6U-A type)
1
2
42
41
P14/CNTR0
P1
3
/SRDY
/SCLK
/T
/R
P1
P1
P1
2
1
0
NC
NC
3
4
40
39
38
X
D
P20/AN
0
X
D
5
6
7
P21/AN
1
P0
P0
P0
P0
P0
7(LED
6(LED
5(LED
(LED
(LED
7
6
5
)
)
)
)
37
36
35
NC
/AN
P2
2
2
8
9
P2
P2
P2
3
/AN
3
4
3
4
3
34
33
32
4
/AN
/AN
4
5
)/TXOUT
)
10
5
P0
P0
P0
2
1
0
(LED
(LED
(LED
2
1
0
11
12
13
NC
NC
NC
NC
REF
)
31
30
29
)/CNTR
1
NC
14
15
16
P37(LED13)/INT0
28
27
26
V
NC
NC
RESET
17
18
19
P3
P3
P3
P3
P3
4(LED12)/INT1
CNVSS
Vcc
25
24
23
22
3
(LED11
)
)
X
IN
OUT
SS
2
1
0
(LED10
20
21
X
V
(LED
(LED
9
8
)
)
Package type: 42S1M
Fig. 3 Pin configuration (42S1M type)
Rev.1.04 2004.06.08 page 2 of 66
REJ03B0012-0104Z
7544 Group
27 26 25 24 23 22 21 20 19
[N.C.]
18
17
16
28
29
30
31
32
33
34
35
36
P0
P0
P1
P1
P1
P1
P1 /CNTR
6
(LED
6
)
P3
P3
P3
P3
3
2
1
0
(LED11
)
)
7(LED
7
)
(LED10
0/RxD
(LED
(LED
9
)
)
M37544M2-XXXHP15
1
/TxD
8
14
2
/SCLK
Vss
M37544G2HP(Note)
13
3
/SRDY
X
X
OUT
IN
4
0
0
1
12
11
10
P2
0
/AN
/AN
[N.C.]
P21
1
2
3
4
5
6
7
8
9
N.C.: Non Connection
Note: Only ES version
(MP: no plan)
Package type: 36PJW-A
Fig. 4 Pin configuration (36PJW-A type)
Rev.1.04 2004.06.08 page 3 of 66
REJ03B0012-0104Z
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FUNCTIONAL BLOCK
K e y - o n w a k e u p
Fig. 5 Functional block diagram (32P4B package)
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REJ03B0012-0104Z
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K e y - o n w a k e u p
Fig. 6 Functional block diagram (32P6U package)
Rev.1.04 2004.06.08 page 5 of 66
REJ03B0012-0104Z
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K e y - o n w a k e u p
Fig. 7 Functional block diagram (36PJW package)
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PIN DESCRIPTION
Table 1 Pin description
Pin
Vcc, Vss
VREF
Name
Function
Function expect a port function
Power source •Apply voltage of 4.0 to 5.5 V to Vcc, and 0 V to Vss.
Analog reference •Reference voltage input pin for A/D converter
voltage
CNVss
______
CNVss
•Chip operating mode control pin, which is always connected to Vss.
•Reset input pin for active “L”
RESET
Reset input
Clock input
XIN
•Input and output pins for main clock generating circuit
•Connect a ceramic resonator or quartz-crystal oscillator between the XIN and XOUT pins.
•For using RC oscillator, short between the XIN and XOUT pins, and connect the capacitor and resistor.
•If an external clock is used, connect the clock source to the XIN pin and leave the XOUT pin open.
• When the on-chip oscillator is selected as the main clock, connect XIN pin to VCC and leave XOUT open.
XOUT
Clock output
I/O port P0
P00/CNTR1
P01
P02
P03/TXOUT
P04–P07
•8-bit I/O port.
• Key-input (key-on wake up
interrupt input) pins
•I/O direction register allows each pin to be individually pro-
grammed as either input or output.
• Timer X and timer A function
pin
•CMOS compatible input level
•CMOS 3-state output structure
•P0 can output a large current for driving LED.
•Whether a built-in pull-up resistor is to be used or not can be de-
termined by program.
P10/RxD
P11/TxD
I/O port P1
•5-bit I/O port
• Serial I/O function pin
•I/O direction register allows each pin to be individually pro-
grammed as either input or output.
P12/SCLK
____
P1
3/SRDY
•CMOS compatible input level
P14/CNTR0
• Timer X function pin
•CMOS 3-state output structure
•CMOS/TTL level can be switched for P10 and P12
•6-bit I/O port having almost the same function as P0
•CMOS compatible input level
P2
0/AN0–P2
5/AN
5
I/O port P2
I/O port P3
• Input pins for A/D converter
•CMOS 3-state output structure
•6-bit I/O port
P30–P33
•I/O direction register allows each pin to be individually programmed as either input or output.
•CMOS compatible input level (CMOS/TTL level can be switched for P34 and P37).
•CMOS 3-state output structure
•P3 can output a large current for driving LED.
P34/INT1
P37/INT0
• Interrupt input pins
•Whether a built-in pull-up resistor is to be used or not can be de-
termined by program.
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REJ03B0012-0104Z
7544 Group
GROUP EXPANSION
We are planning to expand the 7544 group as follow:
Memory size
ROM/PROM size .............................................................. 8 K bytes
RAM size ......................................................................... 256 bytes
Memory type
Support for Mask ROM version, One Time PROM version, and
Emulator MCU .
Package
32P4B .................................................. 32-pin plastic molded SDIP
32P6U-A ...................... 0.8 mm-pitch 32-pin plastic molded LQFP
36PJW-A ...................... 0.5 mm-pitch 36-pin plastic molded SSOP
42S1M....................................42-pin shrink ceramic PIGGY BACK
ROM size
(bytes)
M37544M2
M37544G2
8K
RAM size
256
0
Fig. 8 Memory expansion plan
Currently supported products are listed below.
Table 2 List of supported products
(P) ROM size (bytes) RAM size
Part number
Package
32P4B
Remarks
ROM size for User ()
(bytes)
256
M37544M2-XXXSP
M37544M2-XXXGP
M37544M2-XXXHP
M37544G2SP
M37544G2GP
M37544G2HP
(Note)
Mask ROM version
8192
32P6U-A Mask ROM version
36PJW-A Mask ROM version
(8062)
32P4B
One Time PROM version (blank)
32P6U-A One Time PROM version (blank)
36PJW-A One Time PROM version (blank)
M37544RSS
42S1M
Emulator MCU
256
Note: Only ES version (MP: no plan)
Rev.1.04 2004.06.08 page 8 of 66
REJ03B0012-0104Z
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FUNCTIONAL DESCRIPTION
Stack pointer (S)
The stack pointer is an 8-bit register used during subroutine calls
and interrupts. The stack is used to store the current address data
and processor status when branching to subroutines or interrupt
routines.
Central Processing Unit (CPU)
The MCU uses the standard 740 family instruction set. Refer to
the table of 740 family addressing modes and machine-language
instructions or the SERIES 740 <SOFTWARE> USER’S MANUAL
for details on each instruction set.
The lower eight bits of the stack address are determined by the
contents of the stack pointer. The upper eight bits of the stack ad-
dress are determined by the Stack Page Selection Bit. If the Stack
Page Selection Bit is “0”, then the RAM in the zero page is used
as the stack area. If the Stack Page Selection Bit is “1”, then RAM
in page 1 is used as the stack area.
Machine-resident 740 family instructions are as follows:
1. The FST and SLW instructions cannot be used.
2. The MUL and DIV instructions can be used.
3. The WIT instruction can be used.
4. The STP instruction can be used.
The Stack Page Selection Bit is located in the SFR area in the
zero page. Note that the initial value of the Stack Page Selection
Bit varies with each microcomputer type. Also some microcom-
puter types have no Stack Page Selection Bit and the upper eight
bits of the stack address are fixed. The operations of pushing reg-
ister contents onto the stack and popping them from the stack are
shown in Fig. 10.
This instruction cannot be used while CPU operates by an on-chip
oscillator.
Accumulator (A)
The accumulator is an 8-bit register. Data operations such as data
transfer, etc., are executed mainly through the accumulator.
Program counter (PC)
Index register X (X), Index register Y (Y)
Both index register X and index register Y are 8-bit registers. In
the index addressing modes, the value of the OPERAND is added
to the contents of register X or register Y and specifies the real
address.
The program counter is a 16-bit counter consisting of two 8-bit
registers PCH and PCL. It is used to indicate the address of the
next instruction to be executed.
When the T flag in the processor status register is set to “1”, the
value contained in index register X becomes the address for the
second OPERAND.
b7
b7
b7
b7
b7
b7
b0
b0
b0
b0
b0
b0
A
X
Accumulator
Index Register X
Index Register Y
Stack Pointer
Y
S
b15
PCH
PC
L
Program Counter
Processor Status Register (PS)
N V T B D I Z C
Carry Flag
Zero Flag
Interrupt Disable Flag
Decimal Mode Flag
Break Flag
Index X Mode Flag
Overflow Flag
Negative Flag
Fig. 9 740 Family CPU register structure
Rev.1.04 2004.06.08 page 9 of 66
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On-going Routine
Execute JSR
Interrupt request
(Note)
M (S) (PC
(S) (S – 1)
M (S) (PC
H
)
Store Return Address
on Stack
M (S) (PC
(S) (S – 1)
M (S) (PC
H)
L
)
Store Return Address
on Stack
(S) (S – 1)
M (S) (PS)
(S) (S – 1)
Store Contents of Processor
Status Register on Stack
L)
(S) (S – 1)
Subroutine
Interrupt
Service Routine
I Flag “0” to “1”
Execute RTS
(S) (S + 1)
Fetch the Jump Vector
Execute RTI
(S) (S + 1)
Restore Return
Address
Restore Contents of
Processor Status Register
(PC
(S) (S + 1)
(PC M (S)
L)
M (S)
(PS)
(S) (S + 1)
(PC M (S)
(S) (S + 1)
(PC M (S)
M (S)
H)
L)
Restore Return
Address
H)
Note : The condition to enable the interrupt
Interrupt enable bit is “1”
Interrupt disable flag is “0”
Fig. 10 Register push and pop at interrupt generation and subroutine call
Table 3 Push and pop instructions of accumulator or processor status register
Push instruction to stack
Pop instruction from stack
Accumulator
PHA
PHP
PLA
PLP
Processor status register
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Processor status register (PS)
(5) Break flag (B)
The processor status register is an 8-bit register consisting of
flags which indicate the status of the processor after an arithmetic
operation. Branch operations can be performed by testing the
Carry (C) flag, Zero (Z) flag, Overflow (V) flag, or the Negative (N)
flag. In decimal mode, the Z, V, N flags are not valid.
The B flag is used to indicate that the current interrupt was gener-
ated by the BRK instruction. The BRK flag in the processor status
register is always “0”. When the BRK instruction is used to gener-
ate an interrupt, the processor status register is pushed onto the
stack with the break flag set to “1”. The saved processor status is
the only place where the break flag is ever set.
After reset, the Interrupt disable (I) flag is set to “1”, but all other
flags are undefined. Since the Index X mode (T) and Decimal
mode (D) flags directly affect arithmetic operations, they should
be initialized in the beginning of a program.
(6) Index X mode flag (T)
When the T flag is “0”, arithmetic operations are performed be-
tween accumulator and memory, e.g. the results of an operation
between two memory locations is stored in the accumulator. When
the T flag is “1”, direct arithmetic operations and direct data trans-
fers are enabled between memory locations, i.e. between memory
and memory, memory and I/O, and I/O and I/O. In this case, the
result of an arithmetic operation performed on data in memory lo-
cation 1 and memory location 2 is stored in memory location 1.
The address of memory location 1 is specified by index register X,
and the address of memory location 2 is specified by normal ad-
dressing modes.
(1) Carry flag (C)
The C flag contains a carry or borrow generated by the arithmetic
logic unit (ALU) immediately after an arithmetic operation. It can
also be changed by a shift or rotate instruction.
(2) Zero flag (Z)
The Z flag is set if the result of an immediate arithmetic operation
or a data transfer is “0”, and cleared if the result is anything other
than “0”.
(7) Overflow flag (V)
(3) Interrupt disable flag (I)
The V flag is used during the addition or subtraction of one byte of
signed data. It is set if the result exceeds +127 to -128. When the
BIT instruction is executed, bit 6 of the memory location operated
on by the BIT instruction is stored in the overflow flag.
The I flag disables all interrupts except for the interrupt generated
by the BRK instruction. Interrupts are disabled when the I flag is
“1”.
When an interrupt occurs, this flag is automatically set to “1” to
prevent other interrupts from interfering until the current interrupt
is serviced.
(8) Negative flag (N)
The N flag is set if the result of an arithmetic operation or data
transfer is negative. When the BIT instruction is executed, bit 7 of
the memory location operated on by the BIT instruction is stored in
the negative flag.
(4) Decimal mode flag (D)
The D flag determines whether additions and subtractions are ex-
ecuted in binary or decimal. Binary arithmetic is executed when
this flag is “0”; decimal arithmetic is executed when it is “1”.
Decimal correction is automatic in decimal mode. Only the ADC
and SBC instructions can be used for decimal arithmetic.
Table 4 Set and clear instructions of each bit of processor status register
C flag
SEC
CLC
Z flag
I flag
SEI
D flag
SED
CLD
B flag
T flag
SET
CLT
V flag
–
N flag
Set instruction
–
–
–
–
–
–
Clear instruction
CLI
CLV
Rev.1.04 2004.06.08 page 11 of 66
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[CPU mode register] CPUM
The CPU mode register contains the stack page selection bit.
This register is allocated at address 003B16.
b7
b0
CPU mode register
(CPUM: address 003B16, initial value: 8016
)
Processor mode bits (Note 1)
b1 b0
Switching method of CPU mode register
0
0
1
1
0
1
0
1
Single-chip mode
Switch the CPU mode register (CPUM) at the head of program af-
ter releasing Reset in the following method.
Not available
Stack page selection bit
0
1
: 0 page
: 1 page
On-chip oscillator oscillation control bit
0
1
: On-chip oscillator oscillation enabled
: On-chip oscillator oscillation stop
XIN oscillation control bit
0
1
: Ceramic/quartz-crystal or RC oscillation enabled
: Ceramic/quartz-crystal or RC oscillation stop
Oscillation mode selection bit (Note 1)
0
1
: Ceramic/quartz-crystal oscillation
: RC oscillation
Clock division ratio selection bits
b7 b6
0
0
1
1
0
1
0
1
:
:
:
:
f(φ) = f(XIN)/2 (High-speed mode)
f(φ) = f(XIN)/8 (Middle-speed mode)
applied from on-chip oscillator
f(φ) = f(XIN) (Double-speed mode)(Note 2)
Note 1: The bit can be rewritten only once after releasing reset. After rewriting
it is disable to write any data to the bit. However, by reset the bit is
initialized and can be rewritten, again.
(It is not disable to write any data to the bit for emulator MCU
“M37544RSS”.)
2: These bits are used only when a ceramic/quartz-crystal oscillation is selected.
Do not use these when an RC oscillation is selected.
Fig. 11 Structure of CPU mode register
After releasing reset
Start with an on-chip oscillator
An initial value is set as a ceramic/quartz-crystal
oscillation mode. When it is switched to an RC
oscillation, its oscillation starts.
Switch the oscillation mode
selection bit (bit 5 of CPUM)
When using a ceramic/quartz-crystal oscillation, wait
until establlishment of oscillation from oscillation starts.
When using an RC oscillation, wait time is not required
basically (time to execute the instruction to switch from
an on-chip oscillator meets the requirement).
Wait by on-chip oscillator operation
until establishment of oscillator clock
Select 1/1, 1/2, 1/8 or on-chip oscillator.
Switch the clock division ratio
selection bits (bits 6 and 7 of CPUM)
Main routine
Fig. 12 Switching method of CPU mode register
Rev.1.04 2004.06.08 page 12 of 66
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Memory
Zero page
Special function register (SFR) area
The SFR area in the zero page contains control registers such as
I/O ports and timers.
The 256 bytes from addresses 000016 to 00FF16 are called the
zero page area. The internal RAM and the special function regis-
ters (SFR) are allocated to this area.
The zero page addressing mode can be used to specify memory
and register addresses in the zero page area. Access to this area
with only 2 bytes is possible in the zero page addressing mode.
RAM
RAM is used for data storage and for a stack area of subroutine
calls and interrupts.
Special page
ROM
The 256 bytes from addresses FF0016 to FFFF16 are called the
special page area. The special page addressing mode can be
used to specify memory addresses in the special page area. Ac-
cess to this area with only 2 bytes is possible in the special page
addressing mode.
The first 128 bytes and the last 2 bytes of ROM are reserved for
device testing and the rest is a user area for storing programs.
Interrupt vector area
The interrupt vector area contains reset and interrupt vectors.
✕ Note on use
The content of RAM is undefined when the microcomputer is re-
set. The initial values must be surely set before you use it.
000016
SFR area
Zero page
004016
010016
RAM
RAM area
RAM capacity
(bytes)
address
XXXX16
XXXX16
Reserved area
256
013F16
044016
Disable
YYYY16
Reserved ROM area
(128 bytes)
ZZZZ16
FF0016
ROM
ROM area
ROM capacity
(bytes)
address
YYYY16
address
ZZZZ16
Special page
FFDC16
Interrupt vector area
8192
E00016
E08016
FFFE16
Reserved ROM area
FFFF16
Fig. 13 Memory map diagram
Rev.1.04 2004.06.08 page 13 of 66
REJ03B0012-0104Z
7544 Group
Reserved
Reserved
Port P0 (P0)
000016
000116
000216
002016
002116
Port P0 direction register (P0D)
Port P1 (P1)
002216 Reserved
Port P1 direction register (P1D)
Reserved
Reserved
Reserved
000316
002316
002416
002516
000416 Port P2 (P2)
Port P2 direction register (P2D)
000516
Port P3 (P3)
Reserved
000616
000716
000816
002616
002716
002816
002916
Port P3 direction register (P3D)
Reserved
Reserved
Prescaler 1 (PRE1)
Timer 1 (T1)
000916 Reserved
Reserved
Reserved
Reserved
000A16
000B16
000C16
000D16
002A16
002B16
002C16
002D16
Timer X mode register (TXM)
Prescaler X (PREX)
Timer X (TX)
Reserved
Reserved
Reserved
Reserved
Timer count source set register1 (TCSS1)
Timer count source set register2 (TCSS2)
Reserved
000E16
000F16
001016
001116
002E16
002F16
003016
003116
Reserved
Reserved
Reserved
Reserved
Reserved
001216
003216
003316
003416
003516
Reserved
001316 Reserved
001416 Reserved
001516 Reserved
A/D control register (ADCON)
A/D register (AD)
Reserved
001616 Pull-up control register (PULL)
003616
003716
003816
003916
Reserved
Port P1P3 control register (P1P3C)
001716
MISRG
001816 Transmit/Receive buffer register (TB/RB)
Watchdog timer control register (WDTCON)
Interrupt edge selection register (INTEDGE)
001916
Serial I/O status register (SIOSTS)
Serial I/O control register (SIOCON)
UART control register (UARTCON)
001A16
001B16
001C16
003A16
003B16
003C16
CPU mode register (CPUM)
Interrupt request register 1 (IREQ1)
Interrupt request register 2 (IREQ2)
Interrupt control register 1 (ICON1)
Baud rate generator (BRG)
Timer A mode register (TAM)
Timer A (low-order) (TAL)
001D16
001E16
001F16
003D16
003E16
003F16
Interrupt control register 2 (ICON2)
Timer A (high-order) (TAH)
Note : Do not access to the SFR area including nothing.
Fig. 14 Memory map of special function register (SFR)
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7544 Group
I/O Ports
[Pull-up control register] PULL
[Direction registers] PiD
By setting the pull-up control register (address 001616), ports P0
and P3 can exert pull-up control by program. However, pins set to
output are disconnected from this control and cannot exert pull-up
control.
The I/O ports have direction registers which determine the input/
output direction of each pin. Each bit in a direction register corre-
sponds to one pin, and each pin can be set to be input or output.
When “1” is set to the bit corresponding to a pin, this pin becomes
an output port. When “0” is set to the bit, the pin becomes an in-
put port.
[Port P1P3 control register] P1P3C
By setting the port P1P3 control register (address 001716), a
CMOS input level or a TTL input level can be selected for ports
P10, P12, P34, and P37 by program.
When data is read from a pin set to output, not the value of the pin
itself but the value of port latch is read. Pins set to input are float-
ing, and permit reading pin values.
If a pin set to input is written to, only the port latch is written to and
the pin remains floating.
b7
b0
Pull-up control register
(PULL: address 001616, initial value: 0016
)
P0
P0
P0
P0
P3
P3
0
1
2
4
0
4
pull-up control bit
pull-up control bit
, P03 pull-up control bit
– P0
7
pull-up control bit
pull-up control bit
– P3
3
pull-up control bit
0 : Pull-up Off
1 : Pull-up On
Disable
P3 pull-up control bit
7
Note : Pins set to output ports are disconnected from pull-up control.
Fig. 15 Structure of pull-up control register
b7
b0
Port P1P3 control register
(P1P3C: address 001716, initial value: 0016)
P37/INT0 input level selection bit
0 : CMOS level
1 : TTL level
P34/INT1 input level selection bit
0 : CMOS level
1 : TTL level
P10,P12 input level selection bit
0 : CMOS level
1 : TTL level
Disable
Fig. 16 Structure of port P1P3 control register
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7544 Group
Table 5 I/O port function table
Pin
Name
Input/output
I/O format
Non-port function
Key input interrupt
Timer X function output
Timer A function input
Related SFRs
Diagram No.
P00/CNTR1
P01
I/O port P0 I/O individual •CMOS compatible
Pull-up control register
Timer X mode register
Timer A mode register
Interrupt edge selection
register
(1)
(2)
(3)
bits
input level
P02
•CMOS 3-state output
(Note)
P03/TXOUT
P04–P07
P10/RxD
P11/TxD
I/O port P1
Serial I/O function
input/output
Serial I/O control register
Port P1,P3 control register
(4)
(5)
(6)
(7)
P12/SCLK
____
P13/SRDY
(8)
(9)
P14/CNTR0
Timer X function input/output Timer X mode register
P20/AN0–
P25/AN5
I/O port P2
I/O port P3
A/D conversion input
A/D control register
(10)
(11)
P30–P33
Pull-up control register
P34/INT1
P37/INT0
External interrupt input
Interrupt edge selection
register
Pull-up control register
Port P1,P3 control register
Note : Ports P10, P12, P34, and P37 are CMOS/TTL level.
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7544 Group
(1)Port P0
0
(2)Ports P0
1
,P0
2
,P04–P0
Pull-up control
Direction
7
Pull-up control
Direction
register
register
Port latch
Data bus
Port latch
Data bus
CNTR1 interrupt input
To key input interrupt
generating circuit
To key input interrupt
generating circuit
P0
0 key-on wakeup
selection bit
(4)Port P1
0
(3)Port P0
3
Serial I/O enable bit
Receive enable bit
Pull-up control
Direction
register
Direction
register
Data bus
Port latch
Data bus
Port latch
P10, P12
input level
selection bit
Timer output
P03/TXOUT
output valid
Serial I/O input
*
To key input interrupt
generating circuit
(5)Port P1
1
(6)Port P12
Serial I/O synchronous
clock selection bit
Serial I/O enable bit
P1
1
/T
xD P-channel output disable bit
Serial I/O enable bit
Transmit enable bit
Serial I/O mode selection bit
Serial I/O enable bit
Direction
register
Direction
register
Data bus
Port latch
Data bus
Port latch
P10, P12
input level
selection bit
Serial I/O clock output
Serial I/O output
Serial I/O clock input
*
P1
0
, P1
2, P34, and P37 input level are switched to the CMOS/TTL level by the port P1P3 control register.
*
When the TTL level is selected, there is no hysteresis characteristics.
Fig. 17 Block diagram of ports (1)
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7544 Group
(7) Port P1
3
(8) Port P1
4
Direction
register
Serial I/O mode selection bit
Serial I/O enable bit
S
RDY output enable bit
Direction
register
Port latch
Data bus
Data bus
Port latch
Pulse output mode
Timer output
CNTR0 interrupt input
Serial I/O ready output
(10) Ports P30–P33
(9) Ports P2
0
–P2
5
Direction
register
Pull-up control
Direction
register
Data bus
Port latch
Data bus
Port latch
A/D converter input
Analog input pin
selection bit
(11) Ports P3
4, P37
Pull-up control
Direction
register
Data bus
Port latch
P3 input level
selection bit
INT interrupt input
*
P10
, P12, P34, and P37 input level are switched to the CMOS/TTL level by the port P1P3 control register.
*
When the TTL level is selected, there is no hysteresis characteristics.
Fig. 18 Block diagram of ports (2)
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7544 Group
Interrupts
[Interrupt edge selection register] INTEDGE
Interrupts occur by 12 different sources : 5 external sources, 6 in-
The valid edge of external interrupt INT0 and INT1 can be selected
by the interrupt edge selection bit, respectively.
ternal sources and 1 software source.
By the key-on wakeup selection bit, enable/disable of a key-on
wakeup of P00 pin can be selected.
Interrupt control
All interrupts except the BRK instruction interrupt have an interrupt
request bit and an interrupt enable bit, and they are controlled by
the interrupt disable flag. When the interrupt enable bit and the in-
terrupt request bit are set to “1” and the interrupt disable flag is set
to “0”, an interrupt is accepted.
✕ Notes on use
When setting the followings, the interrupt request bit may be set to
“1”.
•When setting external interrupt active edge
Related register: Interrupt edge selection register (address
003A16)
The interrupt request bit can be cleared by program but not be set.
The interrupt enable bit can be set and cleared by program.
The reset and BRK instruction interrupt can never be disabled with
any flag or bit. All interrupts except these are disabled when the
interrupt disable flag is set.
Timer X mode register (address 2B16)
Timer A mode register (address 1D16)
When several interrupts occur at the same time, the interrupts are
received according to priority.
When not requiring the interrupt occurrence synchronized with
these setting, take the following sequence.
Interrupt operation
✕ Set the corresponding interrupt enable bit to “0” (disabled).
✕ Set the interrupt edge select bit (active edge switch bit) to “1”.
✕ Set the corresponding interrupt request bit to “0” after 1 or more
instructions have been executed.
Upon acceptance of an interrupt the following operations are auto-
matically performed:
1. The processing being executed is stopped.
2. The contents of the program counter and processor status reg-
ister are automatically pushed onto the stack.
✕ Set the corresponding interrupt enable bit to “1” (enabled).
3. The interrupt disable flag is set and the corresponding interrupt
request bit is cleared.
4. Concurrently with the push operation, the interrupt destination
address is read from the vector table into the program counter.
Table 6 Interrupt vector address and priority
Vector addresses (Note 1)
Interrupt source Priority
Interrupt request generating conditions
At reset input
Remarks
High-order Low-order
Reset (Note 2)
Serial I/O receive
Serial I/O transmit
1
2
3
Non-maskable
FFFD16
FFFB16
FFF916
FFFC16
FFFA16
FFF816
At completion of serial I/O data receive
At completion of serial I/O transmit shift or
when transmit buffer is empty
INT0
4
5
6
7
8
At detection of either rising or falling edge of External interrupt
FFF716
FFF516
FFF316
FFF116
FFEF16
FFF616
FFF416
FFF216
FFF016
FFEE16
INT0 input
(active edge selectable)
INT1
At detection of either rising or falling edge of External interrupt
INT1 input
(active edge selectable)
Key-on wake-up
CNTR0
At falling of conjunction of input logical level External interrupt (valid at falling)
for port P0 (at input)
At detection of either rising or falling edge of External interrupt
CNTR0 input
(active edge selectable)
CNTR1
At detection of either rising or falling edge of External interrupt
CNTR1 input
(active edge selectable)
Timer X
9
At timer X underflow
Not available
FFED16
FFEB16
FFE916
FFE716
FFE516
FFE316
FFE116
FFDF16
FFDD16
FFEC16
FFEA16
FFE816
FFE616
FFE416
FFE216
FFE016
FFDE16
FFDC16
Reserved area
Reserved area
Timer A
—
—
10
—
11
12
—
13
Not available
At timer A underflow
Not available
Reserved area
A/D conversion
Timer 1
At completion of A/D conversion
At timer 1 underflow
Not available
STP release timer underflow
Reserved area
BRK instruction
At BRK instruction execution
Non-maskable software interrupt
Note 1: Vector addressed contain internal jump destination addresses.
2: Reset function in the same way as an interrupt with the highest priority.
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7544 Group
Interrupt request bit
Interrupt enable bit
Interrupt disable flag I
BRK instruction
Reset
Interrupt request
Fig. 19 Interrupt control
b7
b0
Interrupt edge selection register
(INTEDGE : address 003A16, initial value : 0016
)
INT
INT
0 interrupt edge selection bit
0 : Falling edge active
1 : Rising edge active
1
interrupt edge selection bit
0 : Falling edge active
1 : Rising edge active
Disable (returns “0” when read)
P00
key-on wakeup enable bit
0 : Key-on wakeup enabled
1 : Key-on wakeup disabled
b7
b0
Interrupt request register 1
(IREQ1 : address 003C16, initial value : 0016
)
Serial I/O receive interrupt request bit
Serial I/O transmit interrupt request bit
INT
INT
0
1
interrupt request bit
interrupt request bit
Key-on wake up interrupt request bit
CNTR
CNTR
0
1
interrupt request bit
interrupt request bit
0 : No interrupt request issued
1 : Interrupt request issued
Timer X interrupt request bit
b7
b0
Interrupt request register 2
(IREQ2 : address 003D16, initial value : 0016
)
Disable (returns “0” when read)
Disable (returns “0” when read)
Timer A interrupt request bit
Disable (returns “0” when read)
A/D conversion interrupt request bit
Timer 1 interrupt request bit
Disable (returns “0” when read)
0 : No interrupt request issued
1 : Interrupt request issued
b7
b0
Interrupt control register 1
(ICON1 : address 003E16, initial value : 0016
)
Serial I/O receive interrupt enable bit
Serial I/O transmit interrupt enable bit
INT
INT
0
1
interrupt enable bit
interrupt enable bit
Key-on wake up interrupt enable bit
CNTR
0
interrupt enable bit
interrupt enable bit
CNTR
1
0 : Interrupts disabled
1 : Interrupts enabled
Timer X interrupt enable bit
b7
b0
Interrupt control register 2
(ICON2 : address 003F16, initial value : 0016
)
Disable (returns “0” when read)
Disable (returns “0” when read)
Timer A interrupt enable bit
Disable (returns “0” when read)
A/D conversion interrupt enable bit
Timer 1 interrupt enable bit
Disable (returns “0” when read)
(Do not write “1” to this bit)
0 : Interrupts disabled
1 : Interrupts enabled
Fig. 20 Structure of Interrupt-related registers
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7544 Group
Key Input Interrupt (Key-On Wake-Up)
A key-on wake-up interrupt request is generated by applying “L”
level to any pin of port P0 that has been set to input mode.
In other words, it is generated when the AND of input level goes
from “1” to “0”. An example of using a key input interrupt is shown
in Figure 21, where an interrupt request is generated by pressing
one of the keys provided as an active-low key matrix which uses
ports P00 to P03 as input ports.
Port PXx
“L” level output
PULL register
bit 3 = “0”
Port P0
Direction register = “1”
7
Key input interrupt request
*
*
*
**
Port P0
latch
7
6
5
4
3
2
1
0
P0
7
output
output
Falling edge
detection
PULL register
bit 3 = “0”
Port P0
6
Direction register = “1”
**
Port P0
latch
P0
6
Falling edge
detection
PULL register
bit 3 = “0”
Port P0
5
Direction register = “1”
**
Port P0
latch
P0
5
output
output
Falling edge
detection
PULL register
bit 3 = “0”
Port P0
4
Direction register = “1”
*
*
*
*
**
Port P0
latch
P0
4
Falling edge
detection
PULL register
bit 2 = “1”
Port P0
3
Port P0
Input read circuit
Direction register = “0”
**
Port P0
latch
P0
3
input
input
input
input
Falling edge
detection
PULL register
bit 2 = “1”
Port P0
2
Direction register = “0”
**
Port P0
latch
P0
2
Falling edge
detection
PULL register
bit 1 = “1”
Port P0
1
Direction register = “0”
**
Port P0
latch
P0
P0
1
Falling edge
detection
PULL register
bit 0 = “1”
Port P0
0
Direction register = “0”
*
**
Port P0
latch
0
Falling edge
detection
Port P00 key-on wakeup
selection bit
* P-channel transistor for pull-up
** CMOS output buffer
Fig. 21 Connection example when using key input interrupt and port P0 block diagram
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7544 Group
✕Timer A
Timers
Timer A is a 16-bit timer and counts the signal selected by the
timer A count source selection bit. When Timer A underflows, the
timer A interrupt request bit is set to “1”.
The 7544 Group has 3 timers: timer 1, timer A and timer X.
The division ratio of every timer and prescaler is 1/(n+1) provided
that the value of the timer latch or prescaler is n.
Timer A consists of the low-order of Timer A (TAL) and the high-or-
der of Timer A (TAH).
All the timers are down count timers. When a timer reaches “0”, an
underflow occurs at the next count pulse, and the corresponding
timer latch is reloaded into the timer. When a timer underflows, the
interrupt request bit corresponding to each timer is set to “1”.
Timer A has the timer A latch to retain the reload value. The value
of timer A latch is set to Timer A at the timing shown below.
• When Timer A undeflows.
• When an active edge is input from CNTR1 pin (valid only when
period measurement mode and pulse width HL continuously mea-
surement mode).
✕Timer 1
Timer 1 is an 8-bit timer and counts the prescaler output.
When Timer 1 underflows, the timer 1 interrupt request bit is set to
“1”.
When writing to both the low-order of Timer A (TAL) and the high-
order of Timer A (TAH) is executed, the value is written to both the
timer A latch and Timer A.
Prescaler 1 is an 8-bit prescaler and counts the signal selected by
the timer 1 count source selection bit.
When reading from the low-order of Timer A (TAL) and the high-or-
der of Timer A (TAH) is executed, the following values are read out
according to the operating mode.
Prescaler 1 and Timer 1 have the prescaler 1 latch and the timer 1
latch to retain the reload value, respectively. The value of
prescaler 1 latch is set to Prescaler 1 when Prescaler 1
underflows. The value of timer 1 latch is set to Timer 1 when Timer
1 underflows.
• In timer mode, event counter mode:
The count value of Timer A is read out.
• In period measurement mode, pulse width HL continuously mea-
surement mode:
When writing to Prescaler 1 (PRE1) is executed, the value is writ-
ten to both the prescaler 1 latch and Prescaler 1.
The measured value is read out.
When writing to Timer 1 (T1) is executed, the value is written to
both the timer 1 latch and Timer 1.
Be sure to write to/read out the low-order of Timer A (TAL) and the
high-order of Timer A (TAH) in the following order;
Read
When reading from Prescaler 1 (PRE1) and Timer 1 (T1) is ex-
ecuted, each count value is read out.
Timer 1 always operates in the timer mode.
Read the high-order of Timer A (TAH) first, and the low-order of
Timer A (TAL) next and be sure to read out both TAH and TAL.
Write
Prescaler 1 counts the signal selected by the timer 1 count source
selection bit. Each time the count clock is input, the contents of
Prescaler 1 is decremented by 1. When the contents of Prescaler
1 reach “0016”, an underflow occurs at the next count clock, and
the prescaler 1 latch is reloaded into Prescaler 1 and count contin-
ues. The division ratio of Prescaler 1 is 1/(n+1) provided that the
value of Prescaler 1 is n.
Write to the low-order of Timer A (TAL) first, and the high-order of
Timer A (TAH) next and be sure to write to both TAL and TAH.
Timer A can be selected in one of 4 operating modes by setting
the timer A mode register.
The contents of Timer 1 is decremented by 1 each time the under-
flow signal of Prescaler 1 is input. When the contents of Timer 1
reach “0016”, an underflow occurs at the next count clock, and the
timer 1 latch is reloaded into Timer 1 and count continues. The di-
vision ratio of Timer 1 is 1/(m+1) provided that the value of Timer
1 is m. Accordingly, the division ratio of Prescaler 1 and Timer 1 is
1/((n+1)✕(m+1)) provided that the value of Prescaler 1 is n and
the value of Timer 1 is m.
(1) Timer mode
Timer A counts the selected by the timer A count source selection
bit. Each time the count clock is input, the contents of Timer A is
decremented by 1. When the contents of Timer A reach “000016”,
an underflow occurs at the next count clock, and the timer A latch
is reloaded into Timer A. The division ratio of Timer A is 1/(n+1)
provided that the value of Timer A is n.
Timer 1 cannot stop counting by software.
(2) Period measurement mode
In the period measurement mode, the pulse period input from the
P00/CNTR1 pin is measured.
CNTR1 interrupt request is generated at rising/falling edge of
CNTR1 pin input signal. Simultaneously, the value in the timer A
latch is reloaded in Timer A and count continues. The active edge
of CNTR1 pin input signal can be selected from rising or falling by
the CNTR1 active edge switch bit .The count value when trigger
input from CNTR1 pin is accepted is retained until Timer A is read
once.
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(3) Event counter mode
b7
b0
Timer A counts signals input from the P00/CNTR1 pin.
Except for this, the operation in event counter mode is the same
as in timer mode.
Timer A mode register
(TAM : address 001D16, initial value: 0016
)
Disable (return “0” when read)
The active edge of CNTR1 pin input signal can be selected from
rising or falling by the CNTR1 active edge switch bit .
Timer A operating mode bits
b5 b4
0
0
1
1
0 : Timer mode
(4) Pulse width HL continuously measurement mode
In the pulse width HL continuously measurement mode, the pulse
width (“H” and “L” levels) input to the P00/CNTR1 pin is measured.
CNTR1 interrupt request is generated at both rising and falling
edges of CNTR1 pin input signal. Except for this, the operation in
pulse width HL continuously measurement mode is the same as in
period measurement mode.
1 : Period measurement mode
0 : Event counter mode
1 : Pulse width HL continuously
measurement mode
CNTR1 active edge switch bit
0 : Count at rising edge in event counter mode
Measure the falling edge period in period
measurement mode
Falling edge active for CNTR1 interrupt
1 : Count at falling edge in event counter mode
Measure the rising edge period in period
measurement mode
The count value when trigger input from the CNTR1 pin is ac-
cepted is retained until Timer A is read once.
Rising edge active for CNTR1 interrupt
Timer A can stop counting by setting “1” to the timer A count stop
Timer A count stop bit
0 : Count start
bit in any mode.
1 : Count stop
Also, when Timer A underflows, the timer A interrupt request bit is
set to “1”.
Fig. 22 Structure of timer A mode register
Note on Timer A is described below;
✕ Note on Timer A
CNTR1 interrupt active edge selection
b7
b0
CNTR1 interrupt active edge depends on the CNTR1 active edge
switch bit.
Timer count source set register 2
(TCSS2 : address 002F16, initial value: 0016
)
Timer 1 count source selection bits
b1 b0
When this bit is “0”, the CNTR1 interrupt request bit is set to “1” at
the falling edge of the CNTR1 pin input signal. When this bit is “1”,
the CNTR1 interrupt request bit is set to “1” at the rising edge of
the CNTR1 pin input signal.
0
0
1
1
0 : f(XIN)/16
1 : f(XIN)/2
0 : On-chip oscillator output
1 : Disable
However, in the pulse width HL continuously measurement mode,
CNTR1 interrupt request is generated at both rising and falling
edges of CNTR1 pin input signal regardless of the setting of
CNTR1 active edge switch bit.
Timer A count source selection bits
b3 b2
0
0
1
1
0 : f(XIN)/16
1 : f(XIN)/2
0 : On-chip oscillator output
1 : Disable
Disable (return “0” when read)
Note : System operates using an on-chip oscillator as a count source
by setting the on-chip oscillator to oscillation enabled by bit 3
of CPUM.
Fig. 23 Timer count source set register 2
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7544 Group
(4) Pulse width measurement mode
✕Timer X
In the pulse width measurement mode, the pulse width of the sig-
nal input to P14/CNTR0 pin is measured.
Timer X is an 8-bit timer and counts the prescaler X output.
When Timer X underflows, the timer X interrupt request bit is set
to “1”.
The operation of Timer X can be controlled by the level of the sig-
nal input from the CNTR0 pin.
Prescaler X is an 8-bit prescaler and counts the signal selected by
the timer X count source selection bit.
When the CNTR0 active edge switch bit is “0”, the signal selected
by the timer X count source selection bit is counted while the input
signal level of CNTR0 pin is “H”. The count is stopped while the
pin is “L”. Also, when the CNTR0 active edge switch bit is “1”, the
signal selected by the timer X count source selection bit is
counted while the input signal level of CNTR0 pin is “L”. The count
is stopped while the pin is “H”.
Prescaler X and Timer X have the prescaler X latch and the timer
X latch to retain the reload value, respectively. The value of
prescaler X latch is set to Prescaler X when Prescaler X
underflows. The value of timer X latch is set to Timer X when
Timer X underflows.
When writing to Prescaler X (PREX) and Timer X (TX) is ex-
ecuted, writing to “latch only” or “latch and prescaler (timer)” can
be selected by the setting value of the timer X write control bit.
When reading from Prescaler X (PREX) and Timer X (TX) is ex-
ecuted, each count value is read out.
Timer X can stop counting by setting “1” to the timer X count stop
bit in any mode.
Also, when Timer X underflows, the timer X interrupt request bit is
set to “1”.
Timer X can be selected in one of 4 operating modes by setting
the timer X operating mode bits of the timer X mode register.
Note on Timer X is described below;
✕ Note on Timer X
(1) Timer mode
CNTR0 interrupt active edge selection
Prescaler X counts the count source selected by the timer X count
source selection bits. Each time the count clock is input, the con-
tents of Prescaler X is decremented by 1. When the contents of
Prescaler X reach “0016”, an underflow occurs at the next count
clock, and the prescaler X latch is reloaded into Prescaler X and
count continues. The division ratio of Prescaler X is 1/(n+1) pro-
vided that the value of Prescaler X is n.
CNTR0 interrupt active edge depends on the CNTR0 active edge
switch bit.
When this bit is “0”, the CNTR0 interrupt request bit is set to “1” at
the falling edge of CNTR0 pin input signal. When this bit is “1”, the
CNTR0 interrupt request bit is set to “1” at the rising edge of
CNTR0 pin input signal.
The contents of Timer X is decremented by 1 each time the under-
flow signal of Prescaler X is input. When the contents of Timer X
reach “0016”, an underflow occurs at the next count clock, and the
timer X latch is reloaded into Timer X and count continues. The di-
vision ratio of Timer X is 1/(m+1) provided that the value of Timer
X is m. Accordingly, the division ratio of Prescaler X and Timer X is
1/((n+1)✕(m+1)) provided that the value of Prescaler X is n and
the value of Timer X is m.
(2) Pulse output mode
In the pulse output mode, the waveform whose polarity is inverted
each time timer X underflows is output from the CNTR0 pin.
The output level of CNTR0 pin can be selected by the CNTR0 ac-
tive edge switch bit. When the CNTR0 active edge switch bit is “0”,
the output of CNTR0 pin is started at “H” level. When this bit is “1”,
the output is started at “L” level.
Also, the inverted waveform of pulse output from CNTR0 pin can
be output from TXOUT pin by setting “1” to the P03/TXOUT output
valid bit.
When using a timer in this mode, set the port P14 and P03 direc-
tion registers to output mode.
(3) Event counter mode
The timer A counts signals input from the P14/CNTR0 pin.
Except for this, the operation in event counter mode is the same
as in timer mode.
The active edge of CNTR0 pin input signal can be selected from
rising or falling by the CNTR0 active edge switch bit .
Rev.1.04 2004.06.08 page 24 of 66
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7544 Group
b7
b0
Timer X mode register
(TXM : address 002B16, initial value: 0016
)
Timer X operating mode bits
b1 b0
0
0
1
1
0 : Timer mode
1 : Pulse output mode
0 : Event counter mode
1 : Pulse width measurement mode
CNTR
0 active edge switch bit
0 : Interrupt at falling edge
Count at rising edge
(in event counter mode)
1 : Interrupt at rising edge
Count at falling edge
(in event counter mode)
Timer X count stop bit
0 : Count start
1 : Count stop
P03/TXOUT output valid bit
0 : Output invalid (I/O port)
1 : Output valid (Inverted CNTR0 output)
Disable (return “0” when read)
Fig. 24 Structure of timer X mode register
b7
b0
Timer count source set register 1
(TCSS1 : address 002E16, initial value: 0016
)
Timer X count source selection bits
b1 b0
0
0
1
1
0 : f(XIN)/16
1 : f(XIN)/2
0 : f(XIN) (Note)
1 : Not available
Disable (return “0” when read)
Note : f(XIN) can be used as timer X count source when using
a ceramic resonator or on-chip oscillator.
Do not use it at RC oscillation.
Fig. 25 Timer count source set register 1
Rev.1.04 2004.06.08 page 25 of 66
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7544 Group
Data bus
Prescaler 1 latch (8)
Prescaler 1 (8)
Timer 1 latch (8)
f(XIN)/16
f(XIN)/2
On-chip oscillator clock RING
Timer 1 interrupt
request bit
Timer 1 (8)
Pulse width HL
continuously
measurement mode
Rising edge detected
Falling edge detected
Period measurement mode
CNTR1 active
edge switch bit
Data bus
P00/CNTR1
Timer A (high-order) latch (8)
Timer A (low-order) latch (8)
Timer A interrupt
request bit
Timer A (low-order) (8)
Timer A (high-order) (8)
f(XIN)/16
f(XIN)/2
On-chip oscillator clock RING
Timer A count
stop bit
Timer A operation mode bit
Fig. 26 Block diagram of timer 1 and timer A
Data bus
f(XIN)/16
f(XIN)/2
Prescaler X latch (8)
Timer X latch (8)
Timer X (8)
Pulse width
measurement
mode
f(XIN
)
Timer mode
Pulse output
mode
Timer X count
source selection bits
Timer X
Prescaler X (8)
interrupt
request bit
CNTR0 active
edge switch bit
“0”
Event
counter
mode
Timer X count stop bit
P14/CNTR0
CNTR
0
interrupt
request bit
“1”
CNTR0 active
edge switch bit
“1”
“0”
Q
Q
Toggle flip-flop T
R
Timer X write control bit
Writing to timer X latch
Pulse output mode
Port P1
latch
4
Port P1
register
4 direction
Pulse output mode
P03/TXOUT
Port P03 latch
P03/TXOUT output valid
Port P0
3
direction
register
Fig. 27 Block diagram of timer X
Rev.1.04 2004.06.08 page 26 of 66
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Serial I/O
(1) Clock Synchronous Serial I/O Mode
●Serial I/O
Clock synchronous serial I/O mode can be selected by setting the
serial I/O mode selection bit of the serial I/O control register (bit 6)
to “1”.
Serial I/O can be used as either clock synchronous or asynchro-
nous (UART) serial I/O. A dedicated timer is also provided for
baud rate generation.
For clock synchronous serial I/O, the transmitter and the receiver
must use the same clock. If an internal clock is used, transfer is
started by a write signal to the TB/RB.
Data bus
Serial I/O control register
Address 001A16
Address 001816
Receive buffer register
Receive buffer full flag (RBF)
Receive shift register
Receive interrupt request (RI)
P10/RXD
Shift clock
Clock control circuit
P12/SCLK
Serial I/O synchronous
clock selection bit
Frequency division ratio 1/(n+1)
BRG count source selection bit
1/4
XIN
Baud rate generator
1/4
Address 001C16
P13/SRDY
Clock control circuit
Falling-edge detector
F/F
Shift clock
Transmit shift register
Transmit buffer register
Transmit shift completion flag (TSC)
Transmit interrupt source selection bit
P11/TXD
Transmit interrupt request (TI)
Transmit buffer empty flag (TBE)
Address 001916
Serial I/O status register
Address 001816
Data bus
Fig. 28 Block diagram of clock synchronous serial I/O
Transfer shift clock
(1/2 to 1/2048 of the internal
clock, or an external clock)
Serial output TxD
Serial input RxD
D
0
0
D
1
1
D
2
2
D
3
3
D
4
4
D
5
5
D
6
6
D
7
7
D
D
D
D
D
D
D
D
Receive enable signal SRDY
Write pulse to receive/transmit
buffer register (address 001816
)
RBF = 1
TSC = 1
TBE = 0
TBE = 1
TSC = 0
Overrun error (OE)
detection
Notes 1: As the transmit interrupt (TI), which can be selected, either when the transmit buffer has emptied (TBE=1) or after
the transmit shift operation has ended (TSC=1), by setting the transmit interrupt source selection bit (TIC) of the
serial I/O control register.
2: If data is written to the transmit buffer register when TSC=0, the transmit clock is generated continuously and serial
data is output continuously from the TxD pin.
3: The receive interrupt (RI) is set when the receive buffer full flag (RBF) becomes “1” .
Fig. 29 Operation of clock synchronous serial I/O function
Rev.1.04 2004.06.08 page 27 of 66
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The transmit and receive shift registers each have a buffer, but the
two buffers have the same address in memory. Since the shift reg-
ister cannot be written to or read from directly, transmit data is
written to the transmit buffer register, and receive data is read
from the receive buffer register.
(2) Asynchronous Serial I/O (UART) Mode
Clock asynchronous serial I/O mode (UART) can be selected by
clearing the serial I/O mode selection bit of the serial I/O control
register to “0”.
Eight serial data transfer formats can be selected, and the transfer
formats used by a transmitter and receiver must be identical.
The transmit buffer register can also hold the next data to be
transmitted, and the receive buffer register can hold a character
while the next character is being received.
Data bus
Address 001816
Serial I/O control register Address 001A16
Receive buffer register
Receive buffer full flag (RBF)
Receive interrupt request (RI)
OE
Character length selection bit
P10/RXD
ST detector
7 bits
8 bits
Receive shift register
1/16
UART control register
PE FE SP detector
Address 001B16
Clock control circuit
Serial I/O synchronous clock selection bit
P12/SCLK
Frequency division ratio 1/(n+1)
Baud rate generator
BRG count source selection bit
1/4
XIN
Address 001C16
ST/SP/PA generator
1/16
Transmit shift completion flag (TSC)
Transmit interrupt source selection bit
P11/TX
D
Transmit shift register
Transmit interrupt request (TI)
Character length selection bit
Transmit buffer empty flag (TBE)
Transmit buffer register
Address 001816
Address 001916
Serial I/O status register
Data bus
Fig. 30 Block diagram of UART serial I/O
Transmit or receive clock
Transmit buffer write
signal
TBE=0
TSC=0
TBE=1
TBE=0
TSC=1✽
SP
TBE=1
Serial output TXD
ST
D0
D1
ST
D0
D1
SP
✽ Generated at 2nd bit in 2-stop-bit mode
1 start bit
7 or 8 data bit
1 or 0 parity bit
1 or 2 stop bit (s)
Receive buffer read
signal
RBF=0
RBF=1
SP
RBF=1
SP
ST
Serial input R
X
D
D0
D1
ST
D0
D1
Notes 1: Error flag detection occurs at the same time that the RBF flag becomes “1” (at 1st stop bit, during reception).
2: As the transmit interrupt (TI), when either the TBE or TSC flag becomes “1,” can be selected to occur depending on the setting of the transmit
interrupt source selection bit (TIC) of the serial I/O control register.
3: The receive interrupt (RI) is set when the RBF flag becomes “1.”
4: After data is written to the transmit buffer when TSC=1, 0.5 to 1.5 cycles of the data shift cycle is necessary until changing to TSC=0.
Fig. 31 Operation of UART serial I/O function
Rev.1.04 2004.06.08 page 28 of 66
REJ03B0012-0104Z
7544 Group
[Transmit buffer register/receive buffer register (TB/RB)]
001816
✕ Notes on serial I/O
• Serial I/O interrupt
The transmit buffer register and the receive buffer register are lo-
cated at the same address. The transmit buffer is write-only and
the receive buffer is read-only. If a character bit length is 7 bits, the
MSB of data stored in the receive buffer is “0”.
When setting the transmit enable bit to “1”, the serial I/O transmit
interrupt request bit is automatically set to “1”. When not requiring
the interrupt occurrence synchronized with the transmission en-
abled, take the following sequence.
✕ Set the serial I/O transmit interrupt enable bit to “0” (disabled).
✕ Set the transmit enable bit to “1”.
[Serial I/O status register (SIOSTS)] 001916
The read-only serial I/O status register consists of seven flags
(bits 0 to 6) which indicate the operating status of the serial I/O
function and various errors.
✕ Set the serial I/O transmit interrupt request bit to “0” after 1 or
more instructions have been executed.
✕ Set the serial I/O transmit interrupt enable bit to “1” (enabled).
Three of the flags (bits 4 to 6) are valid only in UART mode.
The receive buffer full flag (bit 1) is cleared to “0” when the receive
buffer register is read.
• I/O pin function when serial I/O is enabled.
The functions of P12 and P13 are switched with the setting values
of a serial I/O mode selection bit and a serial I/O synchronous
clock selection bit as follows.
If there is an error, it is detected at the same time that data is
transferred from the receive shift register to the receive buffer reg-
ister, and the receive buffer full flag is set. A write to the serial I/O
status register clears all the error flags OE, PE, FE, and SE (bit 3
to bit 6, respectively). Writing “0” to the serial I/O enable bit SIOE
(bit 7 of the serial I/O control register) also clears all the status
flags, including the error flags.
(1) Serial I/O mode selection bit → “1” :
Clock synchronous type serial I/O is selected.
Setup of a serial I/O synchronous clock selection bit
“0” : P12 pin turns into an output pin of a synchronous clock.
“1” : P12 pin turns into an input pin of a synchronous clock.
Setup of a SRDY output enable bit (SRDY)
Bits 0 to 6 of the serial I/O status register are initialized to “0” at re-
set, but if the transmit enable bit of the serial I/O control register
has been set to “1”, the transmit shift completion flag (bit 2) and
the transmit buffer empty flag (bit 0) become “1”.
“0” : P13 pin can be used as a normal I/O pin.
“1” : P13 pin turns into a SRDY output pin.
[Serial I/O control register (SIOCON)] 001A16
The serial I/O control register consists of eight control bits for the
serial I/O function.
(2) Serial I/O mode selection bit → “0” :
Clock asynchronous (UART) type serial I/O is selected.
Setup of a serial I/O synchronous clock selection bit
“0”: P12 pin can be used as a normal I/O pin.
[UART control register (UARTCON)] 001B16
“1”: P12 pin turns into an input pin of an external clock.
When clock asynchronous (UART) type serial I/O is selected, it is
P13 pin. It can be used as a normal I/O pin.
The UART control register consists of four control bits (bits 0 to 3)
which are valid when asynchronous serial I/O is selected and set
the data format of an data transfer and one bit (bit 4) which is al-
ways valid and sets the output structure of the P11/TXD pin.
[Baud rate generator (BRG)] 001C16
The baud rate generator determines the baud rate for serial transfer.
The baud rate generator divides the frequency of the count source
by 1/(n + 1), where n is the value written to the baud rate generator.
Rev.1.04 2004.06.08 page 29 of 66
REJ03B0012-0104Z
7544 Group
b7
b0
b0
b7
Serial I/O status register
(SIOSTS : address 001916, initial value: 0016
Serial I/O control register
(SIOCON : address 001A16, initial value: 0016
)
)
BRG count source selection bit (CSS)
Transmit buffer empty flag (TBE)
0: Buffer full
1: Buffer empty
0: f(XIN
)
1: f(XIN)/4
Serial I/O synchronous clock selection bit (SCS)
0: BRG output divided by 4 when clock synchronous
serial I/O is selected, BRG output divided by 16
when UART is selected.
Receive buffer full flag (RBF)
0: Buffer empty
1: Buffer full
1: External clock input when clock synchronous serial
I/O is selected, external clock input divided by 16
when UART is selected.
Transmit shift completion flag (TSC)
0: Transmit shift in progress
1: Transmit shift completed
S
0: P1
1: P1
RDY output enable bit (SRDY)
Overrun error flag (OE)
0: No error
1: Overrun error
3
pin operates as ordinary I/O pin
pin operates as SRDY output pin
3
Transmit interrupt source selection bit (TIC)
0: Interrupt when transmit buffer has emptied
1: Interrupt when transmit shift operation is completed
Parity error flag (PE)
0: No error
1: Parity error
Transmit enable bit (TE)
0: Transmit disabled
1: Transmit enabled
Framing error flag (FE)
0: No error
1: Framing error
Receive enable bit (RE)
0: Receive disabled
1: Receive enabled
Summing error flag (SE)
0: (OE) U (PE) U (FE)=0
1: (OE) U (PE) U (FE)=1
Serial I/O mode selection bit (SIOM)
0: Clock asynchronous (UART) serial I/O
1: Clock synchronous serial I/O
Disable (returns “1” when read)
b7
b0
Serial I/O enable bit (SIOE)
0: Serial I/O disabled
UART control register
(UARTCON : address 001B16, initial value: E016
)
(pins P1
1: Serial I/O enabled
(pins P1 to P1 operate as serial I/O pins)
0 to P13 operate as ordinary I/O pins)
Character length selection bit (CHAS)
0: 8 bits
1: 7 bits
0
3
Parity enable bit (PARE)
0: Parity checking disabled
1: Parity checking enabled
Parity selection bit (PARS)
0: Even parity
1: Odd parity
Stop bit length selection bit (STPS)
0: 1 stop bit
1: 2 stop bits
P1
1/TXD1 P-channel output disable bit (POFF)
0: CMOS output (in output mode)
1: N-channel open drain output (in output mode)
Disable (return “1” when read)
Fig. 32 Structure of serial I/O-related registers
Rev.1.04 2004.06.08 page 30 of 66
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A/D Converter
The functional blocks of the A/D converter are described below.
b7
b0
A/D control register
(ADCON : address 003416, initial value: 1016
)
Analog input pin selection bits
[A/D conversion register] AD
000 : P2
001 : P2
010 : P2
011 : P2
100 : P2
101 : P2
0
/AN
/AN
/AN
/AN
/AN
/AN
0
1
2
3
1
2
3
The A/D conversion register is a read-only register that stores the
result of A/D conversion. Do not read out this register during an A/
D conversion.
4
5
4
5
110 : Disable
[A/D control register] ADCON
111 : Disable
Disable (returns “0” when read)
The A/D control register controls the A/D converter. Bit 2 to 0 are
analog input pin selection bits. Bit 4 is the AD conversion comple-
tion bit. The value of this bit remains at “0” during A/D conversion,
and changes to “1” at completion of A/D conversion.
A/D conversion is started by setting this bit to “0”.
AD conversion completion bit
0 : Conversion in progress
1 : Conversion completed
Disable (returns “0” when read)
Fig. 33 Structure of A/D control register
[Comparison voltage generator]
The comparison voltage generator divides the voltage between
AVSS and VREF by 256, and outputs the divided voltages.
■ Notes on A/D converter
The comparator uses internal capacitors whose charge will be lost
if the clock frequency is too low.
[Channel selector]
Make sure that f(XIN) is 500 kHz or more during A/D conversion.
As for AD translation accuracy, on the following operating condi-
tions, accuracy may become low.
The channel selector selects one of ports P25/AN5 to P20/AN0,
and inputs the voltage to the comparator.
(1) Since the analog circuit inside a microcomputer becomes sen-
sitive to noise when VREF voltage is set up lower than Vcc
voltage, accuracy may become low rather than the case
where VREF voltage and Vcc voltage are set up to the same
value..
[Comparator and control circuit]
The comparator and control circuit compares an analog input volt-
age with the comparison voltage and stores its result into the A/D
conversion register. When A/D conversion is completed, the con-
trol circuit sets the AD conversion completion bit and the AD
interrupt request bit to “1”. Because the comparator is constructed
linked to a capacitor, set f(XIN) to 500 kHz or more during A/D con-
version.
(2) When VREF voltage is lower than [ 3.0 V ], the accuracy at the
low temperature may become extremely low compared with
that at room temperature. When the system would be used at
low temperature, the use at VREF=3.0 V or more is recom-
mended.
Data bus
b7
b0
A/D control register
(Address 003416
)
3
A/D interrupt request
A/D control circuit
P20/AN0
P2
1
2
/AN
/AN
1
2
P2
Comparator
A/D conversion register (low-order)
(Address 003516
)
P2
P2
P2
3
4
5
/AN
/AN
/AN
3
4
5
10
Resistor ladder
V
REF
VSS
Fig. 34 Block diagram of A/D converter
Rev.1.04 2004.06.08 page 31 of 66
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7544 Group
Watchdog Timer
Operation of watchdog timer H count source selection bit
A watchdog timer H count source can be selected by bit 7 of the
watchdog timer control register (address 003916). When this bit is
“0”, the count source becomes a watchdog timer L underflow sig-
nal. The detection time is 131.072 ms at f(XIN)=8 MHz.
When this bit is “1”, the count source becomes f(XIN)/16. In this
case, the detection time is 512 µs at f(XIN)=8 MHz.
The watchdog timer gives a means for returning to a reset status
when the program fails to run on its normal loop due to a runaway.
The watchdog timer consists of an 8-bit watchdog timer H and an
8-bit watchdog timer L, being a 16-bit counter.
Standard operation of watchdog timer
The watchdog timer stops when the watchdog timer control regis-
ter (address 003916) is not set after reset. Writing an optional
value to the watchdog timer control register (address 003916)
causes the watchdog timer to start to count down. When the
watchdog timer H underflows, an internal reset occurs. Accord-
ingly, it is programmed that the watchdog timer control register
(address 003916) can be set before an underflow occurs.
When the watchdog timer control register (address 003916) is
read, the values of the high-order 6-bit of the watchdog timer H,
STP instruction disable bit and watchdog timer H count source se-
lection bit are read.
This bit is cleared to “0” after reset.
Operation of STP instruction disable bit
When the watchdog timer is in operation, the STP instruction can
be disabled by bit 6 of the watchdog timer control register (ad-
dress 003916).
When this bit is “0”, the STP instruction is enabled.
When this bit is “1”, the STP instruction is disabled, and an inter-
nal reset occurs if the STP instruction is executed.
Once this bit is set to “1”, it cannot be changed to “0” by program.
This bit is cleared to “0” after reset.
Initial value of watchdog timer
By a reset or writing to the watchdog timer control register (ad-
dress 003916), the watchdog timer H is set to “FF16” and the
watchdog timer L is set to “FF16”.
Data bus
Write “FF16” to the
watchdog timer
control register
Write "FF16" to the
watchdog timer
control register
“0”
“1”
Watchdog timer L (8)
Watchdog timer H (8)
1/16
XIN
Watchdog timer H count
source selection bit
STP Instruction disable bit
STP Instruction
Reset
circuit
Internal
reset
RESET
Fig. 35 Block diagram of watchdog timer
b7
b0
Watchdog timer control register
(WDTCON: address 003916, initial value: 3F16
)
Watchdog timer H (read only for high-order 6-bit)
STP instruction disable bit
0 : STP instruction enabled
1 : STP instruction disabled
Watchdog timer H count source selection bit
0 : Watchdog timer L underflow
Fig. 36 Structure of watchdog timer control register
Rev.1.04 2004.06.08 page 32 of 66
REJ03B0012-0104Z
7544 Group
Reset Circuit
Poweron
(Note)
The microcomputer is put into a reset status by holding the RE-
Power source
voltage
0 V
SET pin at the “L” level for 2 µs or more when the power source
RESET
VCC
voltage is 4.5 to 5.5 V and XIN is in stable oscillation.
______
After that, this reset status is released by returning the RESET pin
to the “H” level. The program starts from the address having the
contents of address FFFD16 as high-order address and the con-
tents of address FFFC16 as low-order address.
Reset input
voltage
0 V
0.2 VCC
In the case of f(φ) ≤ 8 MHz, the reset input voltage must be 0.9 V
or less when the power source voltage passes 4.5 V.
Note : Reset release voltage Vcc 4.5V
RESET
VCC
Power source
voltage
detection circuit
Fig. 37 Example of reset circuit
Clock from
on-chip oscillator
RING
φ
RESET
RESETOUT
SYNC
AD
H
H,ADL
?
?
?
?
?
FFFC
FFFD
Address
Reset address from the
vector table
?
?
?
?
?
ADL
AD
Data
Notes
1 : An on-chip oscillator applies about RING•2 MHz, φ•250 kHz frequency clock
at average of Vcc = 5 V.
8-13 clock cycles
2 : The mark “?” means that the address is changeable depending on the previous state.
3 : These are all internal signals except RESET.
Fig. 38 Timing diagram at reset
Rev.1.04 2004.06.08 page 33 of 66
REJ03B0012-0104Z
7544 Group
Address
Register contents
0016
(1) Port P0 direction register
(2) Port P1 direction register
(3) Port P2 direction register
(4) Port P3 direction register
(5) Pull-up control register
(6) Port P1P3 control register
(7) Serial I/O status register
(8) Serial I/O control register
(9) UART control registe
(10) Timer A mode register
(11) Timer A (low-order)
000116
X
X
0
X
X
X
X
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
000316
000516
000716
001616
001716
001916
001A16
001B16
001D16
001E16
001F16
002816
002916
002B16
002C16
002D16
002E16
002F16
003416
003816
003916
003A16
003B16
003C16
003D16
003E16
003F16
(PS)
X
0016
0016
1
1
0
1
0
1
0
0
0
0
0
0
0
0
0016
0
0
0016
FF16
FF16
FF16
(12) Timer A (high-order)
(13) Prescaler 1
(14) Timer 1
0
0
0
0
0
0
0
1
(15) Timer X mode register
(16) Prescaler X
0016
FF16
FF16
0016
0016
(17) Timer X
(18) Timer count source set register 1
(19) Timer count source set register 2
(20) A/D control register
0
0
1
0
0
0
0
1
0
1
0
0
1
0
0
1
0
0
1
0
(21) MISRG
0016
(22) Watchdog timer control register
(23) Interrupt edge selection register
(24) CPU mode register
1
1
0016
0
0
0016
0016
0016
0016
(25) Interrupt request register 1
(26) Interrupt request register 2
(27) Interrupt control register 1
(28) Interrupt control register 2
(29) Processor status register
(30) Program counter
X
X
X
X
X
1
X
X
(PC
H)
Contents of address FFFD16
Contents of address FFFC16
(PC
L)
X : Undefined
The content of other registers is undefined when the microcomputer is reset.
The initial values must be surely set bifore you use it.
Fig. 39 Internal status of microcomputer at reset
Rev.1.04 2004.06.08 page 34 of 66
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Clock Generating Circuit
An oscillation circuit can be formed by connecting a resonator be-
tween XIN and XOUT, and an RC oscillation circuit can be formed
by connecting a resistor and a capacitor.
Note:
The clock frequency of the
on-chip oscillator depends
on the supply voltage and
the operation temperature
range.
Be careful that variable fre-
quencies and obtain the
sufficient margin.
M37544
Use the circuit constants in accordance with the resonator
manufacturer's recommended values.
X
IN
XOUT
(1) On-chip oscillator operation
Open
When the MCU operates by the on-chip oscillator for the main
clock, connect XIN pin to VCC and leave XOUT pin open.
The clock frequency of the on-chip oscillator depends on the sup-
ply voltage and the operation temperature range.
Be careful that variable frequencies when designing application
products.
Fig. 40 Processing of XIN and XOUT pins at on-chip oscillator opera-
tion
Note:
Externally connect a
damping resistor Rd
depending on the oscil-
lation frequency.
(A feedback resistor is
built-in.)
(2) Ceramic resonator and quartz-crystal oscillator
When the ceramic resonator and quartz-crystal oscillator is used
for the main clock, connect the ceramic/quartz-crystal oscillator
and the external circuit to pins XIN and XOUT at the shortest dis-
tance. A feedback resistor is built in between pins XIN and XOUT.
M37544
X
IN
XOUT
Use the resonator
(3) RC oscillation
manufacturer’s recom-
mended value because
constants such as ca-
pacitance depend on
the resonator.
Rd
When the RC oscillation is used for the main clock, connect the
XIN pin and XOUT pin to the external circuit of resistor R and the
capacitor C at the shortest distance.
COUT
CIN
The frequency is affected by a capacitor, a resistor and a micro-
computer.
Fig. 41 External circuit of ceramic resonator and quartz-crystal
oscillator
So, set the constants within the range of the frequency limits.
(4) External clock
Note:
When the external signal clock is used for the main clock, connect
the XIN pin to the clock source and leave XOUT pin open.
Connect the external
circuit of resistor R
and the capacitor C at
M37544
the shortest distance.
The frequency is af-
fected by a capacitor,
a resistor and a micro-
computer.
So, set the constants
within the range of the
frequency limits.
X
IN
XOUT
R
C
Fig. 42 External circuit of RC oscillation
M37544
X
IN
XOUT
Open
External oscillation
circuit
V
CC
SS
Fig. 43 External clock input circuit
V
Rev.1.04 2004.06.08 page 35 of 66
REJ03B0012-0104Z
7544 Group
(1) Oscillation control
• Clock division ratio, XIN oscillation control, on-chip oscillator con-
trol
• Stop mode
When the STP instruction is executed, the internal clock φ stops at
an “H” level and the XIN oscillator stops. At this time, timer 1 is set
to “0116” and prescaler 1 is set to “FF16” when the oscillation sta-
bilization time set bit after release of the STP instruction is “0”. On
the other hand, timer 1 and prescaler 1 are not set when the
above bit is “1”. Accordingly, set the wait time fit for the oscillation
stabilization time of the oscillator to be used. Single selected by
the timer 1 count source selection bit is connected to the input of
prescaler 1. When an external interrupt is accepted, oscillation is
restarted but the internal clock φ remains at “H” until timer 1
underflows. As soon as timer 1 underflows, the internal clock φ is
supplied. This is because when a ceramic/quartz-crystal oscillator
is used, some time is required until a start of oscillation. In case
The state transition shown in Fig. 48 can be performed by setting
the clock division ratio selection bits (bits 7 and 6), XIN oscillation
control bit (bit 4), on-chip oscillator oscillation control bit (bit 3) of
CPU mode register. Be careful of notes on use in Fig. 48.
b7
b0
CPU mode register
(CPUM: address 003B16, initial value: 8016
)
Processor mode bits (Note 1)
b1 b0
0
0
1
1
0
1
0
1
Single-chip mode
Not available
Stack page selection bit
0
1
: 0 page
: 1 page
On-chip oscillator oscillation control bit
oscillation is restarted by reset, no wait time is generated. So ap-
0
1
: On-chip oscillator oscillation enabled
: On-chip oscillator oscillation stop
______
ply an “L” level to the RESET pin while oscillation becomes stable.
Also, the STP instruction cannot be used while CPU is operating
by an on-chip oscillator.
X
IN oscillation control bit
0
1
: Ceramic/quartz-crystal or RC oscillation enabled
: Ceramic/quartz-crystal or RC oscillation stop
Oscillation mode selection bit (Note 1)
0
1
: Ceramic/quartz-crystal oscillation
: RC oscillation
• Wait mode
Clock division ratio selection bits
b7 b6
If the WIT instruction is executed, the internal clock φ stops at an
“H” level, but the oscillator does not stop. The internal clock re-
starts if a reset occurs or when an interrupt is received. Since the
oscillator does not stop, normal operation can be started immedi-
ately after the clock is restarted. To ensure that interrupts will be
received to release the STP or WIT state, interrupt enable bits
must be set to “1” before the STP or WIT instruction is executed.
0
0
1
1
0
1
0
1
:
:
:
:
f(φ) = f(XIN)/2 (High-speed mode)
f(φ) = f(XIN)/8 (Middle-speed mode)
applied from on-chip oscillator
f(φ) = f(XIN) (Double-speed mode)(Note 2)
Note 1: The bit can be rewritten only once after releasing reset. After rewriting
it is disable to write any data to the bit. However, by reset the bit is
initialized and can be rewritten, again.
(It is not disable to write any data to the bit for emulator MCU
“M37544RSS”.)
2: These bits are used only when a ceramic/quartz-crystal oscillation is selected.
Do not use these when an RC oscillation is selected.
✕ Notes on clock generating circuit
For use with the oscillation stabilization set bit after release of the
STP instruction set to “1”, set values in timer 1 and prescaler 1 af-
ter fully appreciating the oscillation stabilization time of the
oscillator to be used.
Fig. 44 Structure of CPU mode register
• Switch of ceramic/quartz-crystal and RC oscillations
After releasing reset the operation starts by starting an on-chip os-
cillator. Then, a ceramic/quartz-crystal oscillation or an RC
oscillation is selected by setting bit 5 of the CPU mode register.
• Double-speed mode
When a ceramic/quartz-crystal oscillation is selected, a double-
speed mode can be used. Do not use it when an RC oscillation is
selected.
• CPU mode register
Bits 5, 1 and 0 of CPU mode register are used to select oscillation
mode and to control operation modes of the microcomputer. In or-
der to prevent the dead-lock by error-writing (ex. program
run-away), these bits can be rewritten only once after releasing re-
set. After rewriting it is disable to write any data to the bit. (The
emulator MCU “M37544RSS” is excluded.)
Also, when the read-modify-write instructions (SEB, CLB) are ex-
ecuted to bits 2 to 4, 6 and 7, bits 5, 1 and 0 are locked.
Rev.1.04 2004.06.08 page 36 of 66
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● Oscillation stop detection circuit
The oscillation stop detection circuit is used for reset occurrence
when a ceramic resonator or an oscillation circuit stops by discon-
nection. When internal reset occurs, reset because of oscillation
stop can be detected by setting “1” to the oscillation stop detection
status bit.
b7
b0
MISRG(address 003816, initial value: 0016
)
Oscillation stabilization time set bit after
release of the STP instruction
0: Set “0116” in timer1, and “FF16
in prescaler 1 automatically
1: Not set automatically
”
Also, when using the oscillation stop detection circuit, an on-chip
oscillator is required.
Ceramic/quartz-crystal or RC oscillation
stop detection function active bit
0: Detection function inactive
Figure 48 shows the state transition.
The oscillation stop detection status bit retains “1”, not initialized,
when the oscillation stop reset occurs. The oscillation stop detec-
tion status bit is initialized to “0” when the external reset occurs.
Accordingly, reset by oscillation stop can be confirmed by using
this bit.
1: Detection function active
Reserved bits (return “0” when read)
(Do not write “1” to these bits)
Disable (return “0” when read)
Oscillation stop detection status bit
0: Oscillation stop not detected
1: Oscillation stop detected
● Notes on Oscillation Stop Detection Circuit
• Oscillation stop detection status bit is initialized by the following
operation.
Fig. 45 Structure of MISRG
(1) External reset
(2) Write “0” data to the ceramic or RC oscillation stop detection
function active bit.
• The oscillation stop detection circuit is not included in the emu-
lator MCU “M37544RSS”.
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7544 Group
X
IN
XOUT
Rf
Clock division ratio selection bit
Middle-, high-, low-speed mode
1/2
1/4
1/2
On-chip oscillator mode
Timer 1
Prescaler 1
Clock division
ratio selection bit
Middle-speed mode
Timing φ
(Internal clock)
High-speed mode
Double-speed mode
On-chip oscillator mode
RING
1/8
On-chip oscillator
Q
S
R
S
R
Q
Q S
RESET
WIT
instruction
R
STP instruction
STP instruction
Reset
Interrupt disable flag l
Interrupt request
Fig. 46 Block diagram of internal clock generating circuit (for ceramic/quartz-crystal resonator)
X
OUT
XIN
Clock division ratio selection bit
Middle-, high-, low-speed mode
1/4
1/2
1/2
On-chip
oscillator
mode
Timer 1
Prescaler 1
Delay
Clock division
ratio selection bit
Middle-speed mode
Timing φ
(Internal clock)
High-speed mode
Double-speed mode
RING
1/8
On-chip oscillator
On-chip oscillator mode
Q
S
R
S
R
Q
Q S
R
RESET
WIT
instruction
STP instruction
STP instruction
Reset
Interrupt disable flag l
Interrupt request
Fig. 47 Block diagram of internal clock generating circuit (for RC oscillation)
Rev.1.04 2004.06.08 page 38 of 66
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Stop mode
Wait mode
Interrupt
WIT
instruction
Interrupt
STP
instruction
Interrupt
WIT
instruction
State 1
Operation clock source:
f(XIN) (Note 1)
f(XIN) oscillation enabled
On-chip oscillator stop
State 3
State 2
Operation clock source:
f(XIN) (Note 1)
f(XIN) oscillation enabled
On-chip oscillator enabled
State 4
CPUM76¨10
2
CPUM
3
←0
2
CPUM
4
←1
2
Operation clock source:
On-chip oscillator (Note 3)
f(XIN) oscillation enabled
On-chip oscillator enabled
2
Operation clock source:
On-chip oscillator (Note 3)
f(XIN) oscillation stop
CPUM
4
¨0
2
CPUM3¨12
On-chip oscillator enabled
CPUM76¨00
01
11
(Note 2)
2
2
Notes on switch of clock
(1) In operation clock source = f(XIN), the following can be
selected for the CPU clock division ratio.
✕ f(XIN)/2 (high-speed mode)
MISRG
1¨12
MISRG1←02
MISRG
1¨12
MISRG1¨02
✕ f(XIN)/8 (middle-speed mode)
✕ f(XIN) (double-speed mode, only at a ceramic/quartz-crystal
oscillation)
(2) Execute the state transition state 3 to state 2 or
state 3’ to state 2’ after stabilizing XIN oscillation.
(3) In operation clock source = on-chip oscillator, the middle-
speed mode is selected for the CPU clock division ratio.
State 2’
Operation clock source:
f(XIN) (Note 1)
f(XIN) oscillation enabled
On-chip oscillator enabled
State 3’
CPUM76¨10
2
Operation clock source:
On-chip oscillator (Note 3)
f(XIN) oscillation enabled
On-chip oscillator enabled
CPUM76←00
2
2
2
01
11
(Note 2)
(4) When the state transition state 2 → state 3 → state 4
is performed, execute the NOP instruction as shown below
according to the division ratio of CPU clock.
Oscillation stop detection circuit valid
Reset released
• CPUM76 → 10
• NOP instruction
• CPUM4 → 1 (State 3 → state 4)
2 (State 2 → state 3)
Reset state
2
Double-speed mode at on-chip oscillator: NOP ✕ 3
High-speed mode at on-chip oscillator: NOP ✕ 1
Fig. 48 State transition
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NOTES ON PROGRAMMING
State transition
Do not stop the clock selected as the operation clock because of
Processor Status Register
setting of CM3, 4.
The contents of the processor status register (PS) after reset are
undefined except for the interrupt disable flag I which is “1”. After
reset, initialize flags which affect program execution. In particular,
it is essential to initialize the T flag and the D flag because of their
effect on calculations.
NOTES ON HARDWARE
Handling of Power Source Pin
In order to avoid a latch-up occurrence, connect a capacitor suit-
able for high frequencies as bypass capacitor between power
source pin (Vcc pin) and GND pin (Vss pin). Besides, connect the
capacitor to as close as possible. For bypass capacitor which
should not be located too far from the pins to be connected, a ce-
ramic capacitor of 0.01 µF to 0.1 µF is recommended.
Interrupts
The contents of the interrupt request bit do not change even if the
BBC or BBS instruction is executed immediately after they are
changed by program because this instruction is executed for the
previous contents. For executing the instruction for the changed
contents, execute one instruction before executing the BBC or
BBS instruction.
One Time PROM Version
The CNVss pin is connected to the internal memory circuit block
by a low-ohmic resistance, since it has the multiplexed function to
be a programmable power source pin (VPP pin) as well.
To improve the noise reduction, connect a track between CNVss
pin and Vss pin with 1 to 10 kΩ resistance.
Decimal Calculations
• For calculations in decimal notation, set the decimal mode flag
D to “1”, then execute the ADC instruction or SBC instruction. In
this case, execute SEC instruction, CLC instruction or CLD in-
struction after executing one instruction before the ADC instruction
or SBC instruction.
The mask ROM version track of CNVss pin has no operational in-
terference even if it is connected via a resistor.
• In the decimal mode, the values of the N (negative), V (overflow)
and Z (zero) flags are invalid.
DATA REQUIRED FOR MASK ORDERS
The following are necessary when ordering a mask ROM produc-
tion:
Ports
1.Mask ROM Order Confirmation Form *
2.Mark Specification Form *
• The values of the port direction registers cannot be read.
That is, it is impossible to use the LDA instruction, memory opera-
tion instruction when the T flag is “1”, addressing mode using
direction register values as qualifiers, and bit test instructions such
as BBC and BBS.
For the mask ROM confirmation and the mark specifications,
refer to the "Renesas Technology Corp." Homepage
(http://www.renesas.com/en/rom).
It is also impossible to use bit operation instructions such as CLB
and SEB and read/modify/write instructions of direction registers
for calculations such as ROR.
For setting direction registers, use the LDM instruction, STA in-
struction, etc.
A/D Conversion
Do not execute the STP instruction during A/D conversion.
Instruction Execution Timing
The instruction execution time can be obtained by multiplying the
frequency of the internal clock φ by the number of cycles men-
tioned in the machine-language instruction table.
The frequency of the internal clock φ is the same as that of the XIN
in double-speed mode, twice the XIN cycle in high-speed mode
and 8 times the XIN cycle in middle-speed mode.
CPU Mode Register
The oscillation mode selection bit and processor mode bits can be
rewritten only once after releasing reset. However, after rewriting it
is disable to write any value to the bit. (Emulator MCU is ex-
cluded.)
When a ceramic / quartz-crystal oscillation is selected, a double-
speed mode of the clock division ratio selection bits can be used.
Do not use it when an RC oscillation is selected.
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(3) Wiring for clock input/output pins
NOTES ON USE
• Make the length of wiring which is connected to clock I/O pins as
short as possible.
Countermeasures against noise
1. Shortest wiring length
• Make the length of wiring (within 20 mm) across the grounding
lead of a capacitor which is connected to an oscillator and the
VSS pin of a microcomputer as short as possible.
• Separate the VSS pattern only for oscillation from other VSS pat-
terns.
(1) Package
Select the smallest possible package to make the total wiring
length short.
<Reason>
If noise enters clock I/O pins, clock waveforms may be deformed.
This may cause a program failure or program runaway. Also, if a
potential difference is caused by the noise between the VSS level
of a microcomputer and the VSS level of an oscillator, the correct
clock will not be input in the microcomputer.
<Reason>
The wiring length depends on a microcomputer package. Use of a
small package, for example QFP and not DIP, makes the total wir-
ing length short to reduce influence of noise.
DIP
Noise
SDIP
SOP
X
X
IN
X
X
IN
QFP
OUT
OUT
V
SS
V
SS
Fig. 49 Selection of packages
O.K.
N.G.
Fig. 51 Wiring for clock I/O pins
(2) Wiring for RESET pin
Make the length of wiring which is connected to the RESET pin as
short as possible. Especially, connect a capacitor across the
RESET pin and the VSS pin with the shortest possible wiring
(within 20mm).
(4) Wiring to CNVss pin
Connect the CNVss pin to the Vss pin with the shortest possible
wiring.
<Reason>
<Reason>
The processor mode of a microcomputer is influenced by a poten-
tial at the CNVss pin. If a potential difference is caused by the
noise between pins CNVss and Vss, the processor mode may be-
come unstable. This may cause a microcomputer malfunction or a
program runaway.
The width of a pulse input into the RESET pin is determined by the
timing necessary conditions. If noise having a shorter pulse width
than the standard is input to the RESET pin, the reset is released
before the internal state of the microcomputer is completely initial-
ized. This may cause a program runaway.
Noise
Noise
Reset
RESET
circuit
CNVSS
VSS
CNVSS
VSS
V
SS
V
SS
N.G.
N.G.
O.K.
Reset
circuit
RESET
Fig. 52 Wiring for CNVss pin
V
SS
V
SS
O.K.
Fig. 50 Wiring for the RESET pin
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3. Wiring to analog input pins
(5) Wiring to VPP pin of One Time PROM version
Connect an approximately 5 kΩ resistor to the VPP pin the shortest
possible in series and also to the Vss pin. When not connecting
the resistor, make the length of wiring between the VPP pin and
the Vss pin the shortest possible.
• Connect an approximately 100 Ω to 1 kΩ resistor to an analog
signal line which is connected to an analog input pin in series.
Besides, connect the resistor to the microcomputer as close as
possible.
• Connect an approximately 1000 pF capacitor across the Vss pin
and the analog input pin. Besides, connect the capacitor to the
Vss pin as close as possible. Also, connect the capacitor across
the analog input pin and the Vss pin at equal length.
<Reason>
Note: Even when a circuit which included an approximately 5 kΩ
resistor is used in the Mask ROM version, the microcom-
puter operates correctly.
<Reason>
The VPP pin of the One Time PROM is the power source input pin
for the built-in PROM. When programming in the built-in PROM,
the impedance of the VPP pin is low to allow the electric current for
writing flow into the PROM. Because of this, noise can enter eas-
ily. If noise enters the VPP pin, abnormal instruction codes or data
are read from the built-in PROM, which may cause a program run-
away.
Signals which is input in an analog input pin (such as an A/D con-
verter/comparator input pin) are usually output signals from
sensor. The sensor which detects a change of event is installed far
from the printed circuit board with a microcomputer, the wiring to
an analog input pin is longer necessarily. This long wiring func-
tions as an antenna which feeds noise into the microcomputer,
which causes noise to an analog input pin.
Noise
About 5kΩ
CNVSS/VPP
(Note)
Microcomputer
V
SS
shortest
distance
Analog
input pin
Thermistor
Fig. 53 Wiring for the VPP pin of the One Time PROM
N.G.
O.K.
V
SS
2. Connection of bypass capacitor across VSS line and VCC line
Connect an approximately 0.1 µF bypass capacitor across the VSS
line and the VCC line as follows:
Note : The resistor is used for dividing
resistance with a thermistor.
• Connect a bypass capacitor across the VSS pin and the VCC pin
at equal length.
Fig. 55 Analog signal line and a resistor and a capacitor
• Connect a bypass capacitor across the VSS pin and the VCC pin
with the shortest possible wiring.
• The analog input pin is connected to the capacitor of a voltage
comparator. Accordingly, sufficient accuracy may not be ob-
tained by the charge/discharge current at the time of A/D
conversion when the analog signal source of high-impedance is
connected to an analog input pin. In order to obtain the A/D con-
version result stabilized more, please lower the impedance of an
analog signal source, or add the smoothing capacitor to an ana-
log input pin.
• Use lines with a larger diameter than other signal lines for VSS
line and VCC line.
• Connect the power source wiring via a bypass capacitor to the
VSS pin and the VCC pin.
V
CC
V
CC
V
SS
V
SS
N.G.
O.K.
Fig. 54 Bypass capacitor across the VSS line and the VCC line
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(3) Oscillator protection using Vss pattern
4. Oscillator concerns
As for a two-sided printed circuit board, print a Vss pattern on the
underside (soldering side) of the position (on the component side)
where an oscillator is mounted.
So that the product obtains the stabilized operation clock on the
user system and its condition, contact the resonator manufacturer
and select the resonator and oscillation circuit constants.
Be careful especially when range of voltage and temperature is
wide.
Connect the Vss pattern to the microcomputer Vss pin with the
shortest possible wiring. Besides, separate this Vss pattern from
other Vss patterns.
Take care to prevent an oscillator that generates clocks for a mi-
crocomputer operation from being affected by other signals.
(1) Keeping oscillator away from large current signal lines
Install a microcomputer (and especially an oscillator) as far as
possible from signal lines where a current larger than the toler-
ance of current value flows.
An example of VSS patterns on the
underside of a printed circuit board
<Reason>
In the system using a microcomputer, there are signal lines for
controlling motors, LEDs, and thermal heads or others. When a
large current flows through those signal lines, strong noise occurs
because of mutual inductance.
Oscillator wiring
pattern example
X
X
IN
OUT
(2) Installing oscillator away from signal lines where potential lev-
els change frequently
V
SS
Install an oscillator and a connecting pattern of an oscillator away
from signal lines where potential levels change frequently. Also, do
not cross such signal lines over the clock lines or the signal lines
which are sensitive to noise.
Separate the VSS line for oscillation from other VSS lines
<Reason>
Signal lines where potential levels change frequently (such as the
CNTR pin signal line) may affect other lines at signal rising edge
or falling edge. If such lines cross over a clock line, clock wave-
forms may be deformed, which causes a microcomputer failure or
a program runaway.
Fig. 57 Vss pattern on the underside of an oscillator
✕ Keeping oscillator away from large current signal lines
Microcomputer
Mutual inductance
M
X
X
IN
Large
current
OUT
V
SS
GND
✕ Installing oscillator away from signal lines where potential lev-
els change frequently
N.G.
CNTR
Do not cross
X
X
V
IN
OUT
SS
Fig. 56 Wiring for a large current signal line/Writing of signal
lines where potential levels change frequently
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5. Setup for I/O ports
<The main routine>
Setup I/O ports using hardware and software as follows:
• Assigns a single byte of RAM to a software watchdog timer
(SWDT) and writes the initial value N in the SWDT once at each
execution of the main routine. The initial value N should satisfy
the following condition:
<Hardware>
• Connect a resistor of 100 Ω or more to an I/O port in series.
N+1 ≥ (Counts of interrupt processing executed in each main
routine)
<Software>
• As for an input port, read data several times by a program for
checking whether input levels are equal or not.
• As for an output port, since the output data may reverse because
of noise, rewrite data to its port latch at fixed periods.
• Rewrite data to direction registers and pull-up control registers at
fixed periods.
As the main routine execution cycle may change because of an
interrupt processing or others, the initial value N should have a
margin.
• Watches the operation of the interrupt processing routine by
comparing the SWDT contents with counts of interrupt process-
ing after the initial value N has been set.
• Detects that the interrupt processing routine has failed and de-
termines to branch to the program initialization routine for
recovery processing in the following case:
Note: When a direction register is set for input port again at fixed
periods, a several-nanosecond short pulse may be output
from this port. If this is undesirable, connect a capacitor to
this port to remove the noise pulse.
If the SWDT contents do not change after interrupt processing.
<The interrupt processing routine>
• Decrements the SWDT contents by 1 at each interrupt process-
ing.
Noise
O.K.
• Determines that the main routine operates normally when the
SWDT contents are reset to the initial value N at almost fixed
cycles (at the fixed interrupt processing count).
• Detects that the main routine has failed and determines to
branch to the program initialization routine for recovery process-
ing in the following case:
Data bus
Noise
Direction register
N.G.
Port latch
If the SWDT contents are not initialized to the initial value N but
continued to decrement and if they reach 0 or less.
I/O port
pins
Interrupt processing routine
Main routine
Fig. 58 Setup for I/O ports
(SWDT) ← (SWDT)—1
(SWDT)← N
CLI
6. Providing of watchdog timer function by software
If a microcomputer runs away because of noise or others, it can
be detected by a software watchdog timer and the microcomputer
can be reset to normal operation. This is equal to or more effective
than program runaway detection by a hardware watchdog timer.
The following shows an example of a watchdog timer provided by
software.
Interrupt processing
Main processing
>0
(SWDT)
≤0?
RTI
≠N
≤0
(SWDT)
=N?
Return
N
In the following example, to reset a microcomputer to normal op-
eration, the main routine detects errors of the interrupt processing
routine and the interrupt processing routine detects errors of the
main routine.
Interrupt processing
routine errors
Main routine
errors
This example assumes that interrupt processing is repeated mul-
tiple times in a single main routine processing.
Fig. 59 Watchdog timer by software
7. Electric Characteristic Differences Between Mask ROM and
One Time PROM Version MCUs
There are differences in electric characteristics, operation margin,
noise immunity, and noise radiation between the mask ROM and
One Time PROM version MCUs due to the difference in the manu-
facturing processes.
When manufacturing an application system with the One Time
PROM version and then switching to use of the Mask ROM ver-
sion, please perform sufficient evaluations for the commercial
samples of the Mask ROM version.
Rev.1.04 2004.06.08 page 44 of 66
REJ03B0012-0104Z
7544 Group
PROM Mode
There are three operation modes in PROM Mode : Read, Program
and Program-Verify. Three commands are defined to enable each
mode respectively.
M37544G2SP/GP (referred to as “the MCU”) has a PROM Mode
as well as the normal operation mode. PROM Mode enables an
external device (referred to as “Programmer”) to read and pro-
gram the built-in EPROM via a minimum number of serial I/O pins
by sending commands to control the MCU.
The format of the serial I/O is : clock synchronous and LSB-data-
first.
To enable PROM Mode, use the pin connection shown in Figure
60 to 61 and apply power (VCC). Then execute the new OTP en-
try operation, called “Mad Dog Entry”.
ESCLK
1
32
ESDA
ESPGMB
P12/SCLK
P13/SRDY
P14/CNTR0
P20/AN0
P11/TXD
P10/RXD
P07(LED7)
P06(LED6)
P05(LED5)
2
3
4
5
31
30
29
28
P21/AN1
6
7
8
9
27
26
25
24
P22/AN2
P23/AN3
P24/AN4
P25/AN5
VREF
RESET
CNVSS
VCC
P04(LED4)
P03(LED3)/TXOUT
P02(LED2)
P01(LED1)
10
11
12
23
22
21
P00(LED0)/CNTR1
RESETB
VPP
VCC
XIN
XOUT
VSS
P37(LED13)/INT0
P34(LED12)/INT1
P33(LED11)
P32(LED10)
P31(LED9)
13
14
15
16
20
19
18
17
XIN
XOUT
VSS
P30(LED8)
Fig. 60 “Mad Dog Entry” Pin Diagram (32P4B)
Rev.1.04 2004.06.08 page 45 of 66
REJ03B0012-0104Z
7544 Group
25
26
27
28
29
30
31
32
16
15
14
13
12
11
10
9
P0
P1
P1
P1
P1
P1
7
(LED
/R
/T
7
)
P3
P3
P3
4
(LED12)/INT
(LED11
(LED10
1
ESPGMB
ESDA
ESCLK
0
X
D
3
)
)
1
X
D
2
2/SCLK
P3
1
(LED
(LED
9
)
)
M37544G2GP
3
/SRDY
P30
8
VSS
XOUT
XIN
4
/CNTR
P2 AN
P2 AN
0
V
SS
0/
0
X
X
OUT
IN
1/
1
Fig. 61 “Mad Dog Entry” Pin Diagram (32P6U-A)
Rev.1.04 2004.06.08 page 46 of 66
REJ03B0012-0104Z
7544 Group
Precaution for Handling One-Time-Programmable
Devices
Our company ships one-time-programmable version MCUs (One-
Time PROM MCU) without being screened by the PROM writing
test.
To ensure the reliability of the MCU, We recommend that the user
performs the program and test procedure shown in Figure 62
before using the MCU.
Programming with
PROM programmer
Screening (Caution)
(150 °C for 40 hours)
Verification with PROM
programmer
Functional check in
target device
The screening temperature is far higher
than the storage temperature. Never
expose to 150 °C exceeding 100 hours.
Caution:
Fig. 62 Programming and testing of One Time PROM
Rev.1.04 2004.06.08 page 47 of 66
REJ03B0012-0104Z
7544 Group
ROM Code Access Protection
We would like to support a simple ROM code protection function
that prevents a party other than the ROM-code owner to read and
reprogram the builit-in PROM code of the MCU.
Address
FFD416
FFD516
FFD616
FFD716
FFD816
FFD916
FFDA16
ID1
ID2
ID3
ID4
ID5
ID6
ID7
The MCU has 7 bytes of dedicated ROM spaces in address
0xFFD4 to 0xFFDA, as an ID-code (referred to as “the ID-code”)
enabling a Programmer to verify with the input ID-code and
validate further operations.
Expected Programmer ID-Code Verification
Function
First, Programmer must check the ID-code of the MCU.
If the ID-code is still in blank, Programmer enables all operations,
Read, Program, and Program-Verify.
When Programmer programs the MCU, Programmer also
programs the given ID-code as well as the actual firmware.
If the ID-code is not blank, Programmer verifies it with the input
ID-code.
Fig. 63 ROM-Code Protection ID Location
When the ID-codes don't match, Programmer will reject all further
operations.
If they match, Programmer perform operations according to the
given command.
Rev.1.04 2004.06.08 page 48 of 66
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ELECTRICAL CHARACTERISTICS
1.7544Group
Applied to: M37544M2-XXXSP/GP/HP, M37544G2SP/GP/HP(Note)
Note: M37544G2HP: Only ES version (MP: no plan)
Absolute Maximum Ratings
Table 9 Absolute maximum ratings
Symbol
Parameter
Conditions
Ratings
–0.3 to 6.5
Unit
V
VCC
Power source voltage
Input voltage
VI
–0.3 to VCC + 0.3
V
P00–P07, P10–P14, P20–P25, P30–P34,P37, VREF
All voltages are
based on VSS.
Output transistors
are cut off.
______
VI
Input voltage RESET, XIN
Input voltage CNVSS (Note)
Output voltage
–0.3 to VCC + 0.3
–0.3 to 7.0
V
V
V
VI
VO
–0.3 to VCC + 0.3
P00–P07, P10–P14, P20–P25, P30–P34,P37, XOUT
Power dissipation
Pd
Ta = 25°C
200
mW
°C
Topr
Tstg
Operating temperature
–20 to 85
–40 to 125
Storage temperature
°C
Notes : It is a rating only for the One Time PROM version. Connect to VSS for the mask ROM version.
Rev.1.04 2004.06.08 page 49 of 66
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Recommended Operating Conditions
Table 10 Recommended operating conditions (1) (VCC = 4.0 to 5.5 V, Ta = –20 to 85 °C, unless otherwise noted)
Limits
Symbol
Parameter
Unit
Min.
4.0
4.5
4.0
Typ.
5.0
5.0
5.0
0
Max.
5.5
VCC
Power source voltage (ceramic)
f(XIN) = 8 MHz (High-, Middle-speed mode)
f(XIN) = 8 MHz (Double-speed mode)
f(XIN) = 4 MHz (High-, Middle-speed mode)
V
V
V
V
V
V
5.5
Power source voltage (RC)
Power source voltage
Analog reference voltage
“H” input voltage
5.5
VSS
VREF
VIH
2.0
VCC
VCC
0.8VCC
P00–P07, P10–P14, P20–P25, P30–P34, P37
“H” input voltage (TTL input level selected)
P10, P12, P34, P37
VIH
VIH
VIL
VIL
VIL
VIL
V
V
2.0
VCC
VCC
0.3VCC
0.8
“H” input voltage
0.8VCC
______
RESET, XIN
“L” input voltage
V
0
0
0
0
P00–P07, P10–P14, P20–P25, P30–P34, P37
“L” input voltage (TTL input level selected)
P10, P12, P34, P37
V
“L” input voltage
V
0.2VCC
0.16VCC
–80
______
RESET, CNVSS
“L” input voltage
XIN
V
∑IOH(peak) “H” total peak output current (Note)
mA
mA
mA
mA
mA
mA
P00–P07, P10–P14, P20–P25, P30–P34, P37
∑IOL(peak)
∑IOL(peak)
∑IOH(avg)
∑IOL(avg)
∑IOL(avg)
“L” total peak output current (Note)
P10–P14, P20–P25
80
“L” total peak output current (Note)
P00–P07, P30–P34, P37
60
“H” total average output current (Note)
–40
P00–P07, P10–P14, P20–P25, P30–P34, P37
“L” total average output current (Note)
P10–P14, P20–P25
40
“L” total average output current (Note)
P00–P07, P30–P34, P37
30
Note : The total output current is the sum of all the currents flowing through all the applicable ports. The total average current is an
average value measured over 100 ms. The total peak current is the peak value of all the currents.
Rev.1.04 2004.06.08 page 50 of 66
REJ03B0012-0104Z
7544 Group
Recommended Operating Conditions (continued)
Table 11 Recommended operating conditions (2) (VCC = 4.0 to 5.5 V, Ta = –20 to 85 °C, unless otherwise noted)
Limits
Symbol
Parameter
Unit
mA
Min.
Typ.
Max.
–10
IOH(peak)
“H” peak output current (Note 1)
P00–P07, P10–P14, P20–P25, P30–P34, P37
“L” peak output current (Note 1)
P10–P14, P20–P25
10
30
–5
5
mA
mA
IOL(peak)
IOL(peak)
IOH(avg)
IOL(avg)
IOL(avg)
f(XIN)
“L” peak output current (Note 1)
P00–P07, P30–P34, P37
“H” average output current (Note 2)
P00–P07, P10–P14, P20–P25, P30–P34, P37
“L” average output current (Note 2)
P10–P14, P20–P25
mA
mA
“L” average output current (Note 2)
P00–P07, P30–P34, P37
15
8
mA
Internal clock oscillation frequency (Note 3)
at ceramic oscillation or external clock input
Internal clock oscillation frequency (Note 3)
at ceramic oscillation or external clock input
Internal clock oscillation frequency (Note 3)
at RC oscillation
MHz
MHz
MHz
VCC = 4.5 to 5.5 V
Double-speed mode
VCC = 4.0 to 5.5 V
8
High-, Middle-speed mode
VCC = 4.0 to 5.5 V
4
High-, Middle-speed mode
Notes 1: The peak output current is the peak current flowing in each port.
2: The average output current IOL (avg), IOH (avg) in an average value measured over 100 ms.
3: When the oscillation frequency has a duty cycle of 50 %.
Rev.1.04 2004.06.08 page 51 of 66
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Electrical Characteristics
Table 12 Electrical characteristics (1) (VCC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Limits
Symbol
Parameter
Test conditions
IOH = –5 mA
Unit
V
Min.
Typ.
Max.
“H” output voltage
VCC–1.5
VOH
P00–P07, P10–P14, P20–P25, P30–P34, P37 (Note 1) VCC = 4.0 to 5.5 V
IOH = –1.0 mA
VCC = 4.0 to 5.5 V
VCC–1.0
V
V
V
V
V
V
V
V
“L” output voltage
P10–P14, P20–P25
IOL = 5 mA
VCC = 4.0 to 5.5 V
1.5
0.3
1.0
2.0
0.3
1.0
VOL
IOL = 1.5 mA
VCC = 4.0 to 5.5 V
IOL = 1.0 mA
VCC = 4.0 to 5.5 V
VOL
“L” output voltage
IOL = 15 mA
VCC = 4.0 to 5.5 V
P00–P07, P30–P34, P37
IOL = 1.5 mA
VCC = 4.0 to 5.5 V
IOL = 10 mA
VCC = 4.0 to 5.5 V
Hysteresis
0.4
VT+–VT–
CNTR0, CNTR1, INT0, INT1 (Note 2)
P00–P07 (Note 3)
Hysteresis
RXD, SCLK (Note 2)
0.5
0.9
V
V
VT+–VT–
VT+–VT–
IIH
Hysteresis
______
RESET
“H” input current
P00–P07, P10–P14, P20–P25, P30–P34, P37
VI = VCC
(Pin floating. Pull up
transistors “off”)
5.0
5.0
µA
“H” input current
______
RESET
VI = VCC
µA
µA
µA
IIH
IIH
IIL
“H” input current
XIN
VI = VCC
4.0
“L” input current
P00–P07, P10–P14, P20–P25, P30–P34, P37
VI = VSS
(Pin floating. Pull up
transistors “off”)
–5.0
–5.0
IIL
IIL
IIL
“L” input current
______
RESET, CNVSS
VI = VSS
µA
µA
“L” input current
XIN
VI = VSS
–4.0
–0.2
“L” input current
VI = VSS
–0.5
mA
P00–P07, P30–P34, P37
(Pull up transistors “on”)
VRAM
ROSC
DOSC
RAM hold voltage
When clock stopped
2.0
5.5
V
On-chip oscillator oscillation frequency
VCC = 5.0 V, Ta = 25 °C
2000
125
3000
187.5
kHz
kHz
1000
62.5
Oscillation stop detection circuit detection frequency VCC = 5.0 V, Ta = 25 °C
Notes 1: P11 is measured when the P11/TXD P-channel output disable bit of the UART control register (bit 4 of address 001B16) is “0”.
2: RXD, SCLK, INT0, and INT1 have hysteresises only when bits 0 to 2 of the port P1P3 control register are set to “0” (CMOS level).
3: It is available only when operating key-on wake up.
Rev.1.04 2004.06.08 page 52 of 66
REJ03B0012-0104Z
7544 Group
Electrical Characteristics (continued)
Table 13 Electrical characteristics (2) (VCC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Limits
Symbol
ICC
Parameter
Test conditions
High-speed mode, f(XIN) = 8 MHz
Unit
mA
Min.
Typ.
3.3
Max.
8.0
Power source
current
Output transistors “off”
4.8
1.8
250
1.3
10.0
5.0
mA
mA
µA
Double-speed mode, f(XIN) = 8 MHz
Output transistors “off”
Middle-speed mode, f(XIN) = 8 MHz
Output transistors “off”
On-chip oscillator operation mode, VCC = 5 V
Output transistors “off”
900
3.2
mA
f(XIN) = 8 MHz (in WIT state),
functions except timer 1 disabled,
Output transistors “off”
140
450
µA
On-chip oscillator operation mode(in WIT state), VCC = 5V
functions except timer 1 disabled,
Output transistors “off”
0.45
0.1
mA
Increment when A/D conversion is executed
f(XIN) = 8 MHz, VCC = 5 V
All oscillation stopped
(in STP state)
1.0
µA
µA
Ta = 25 °C
Ta = 85 °C
10.0
Output transistors “off”
Rev.1.04 2004.06.08 page 53 of 66
REJ03B0012-0104Z
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A/D Converter Characteristics
Table 14 A/D Converter characteristics (VCC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Limits
Symbol
Parameter
Test conditions
Unit
Min.
Typ.
Max.
8
—
Resolution
Bits
ABS
Absolute accuracy
Ta = –20 to 85 °C, Vcc = VREF
±3
LSB
(quantification error excluded)
tCONV
Conversion time
109
tc(XIN)
kΩ
RLADDER
IVREF
Ladder resistor
37
135
80
Reference power source
input current
VREF = 5.0 V
VREF = 3.0 V
50
30
200
120
5.0
µA
II(AD)
A/D port input current
µA
Note: As for AD translation accuracy, on the following operating conditions, accuracy may become low.
(1) Since the analog circuit inside a microcomputer becomes sensitive to noise when VREF voltage is set up lower than Vcc voltage,
accuracy may become low rather than the case where VREF voltage and Vcc voltage are set up to the same value..
(2) When VREF voltage is less than [ 3.0V ], the accuracy at the time of low temperature may become extremely low compared with
the time of room temperature. The use beyond VREF=3.0V is recommended in the system the use by the side of low temperature
is assumed to be.
Timing Requirements
Table 15 Timing requirements (VCC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Limits
Symbol
______
tW(RESET)
Parameter
Unit
Min.
2
Typ.
Max.
Reset input “L” pulse width
µs
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
tC(XIN)
External clock input cycle time
External clock input “H” pulse width
External clock input “L” pulse width
CNTR0 input cycle time
125
50
tWH(XIN)
tWL(XIN)
50
tC(CNTR0)
tWH(CNTR0)
tWL(CNTR0)
tC(CNTR1)
tWH(CNTR1)
tWL(CNTR1)
tC(SCLK)
200
80
CNTR0, INT0, INT1, input “H” pulse width
CNTR0, INT0, INT1, input “L” pulse width
CNTR1 input cycle time
80
2000
800
800
800
370
370
220
100
CNTR1 input “H” pulse width
CNTR1 input “L” pulse width
Serial I/O clock input cycle time (Note)
Serial I/O clock input “H” pulse width (Note)
Serial I/O clock input “L” pulse width (Note)
Serial I/O input set up time
tWH(SCLK)
tWL(SCLK)
tsu(RxD–SCLK)
th(SCLK–RxD)
Serial I/O input hold time
Note: In this time, bit 6 of the serial I/O control register (address 001A16) is set to “1” (clock synchronous serial I/O is selected).
When bit 6 of the serial I/O control register is “0” (clock asynchronous serial I/O is selected), the rating values are divided by 4.
Rev.1.04 2004.06.08 page 54 of 66
REJ03B0012-0104Z
7544 Group
Switching Characteristics
Table 16 Switching characteristics (VCC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Limits
Symbol
Parameter
Unit
Min.
Typ.
Max.
140
tWH(SCLK)
Serial I/O clock output “H” pulse width
Serial I/O clock output “L” pulse width
Serial I/O output delay time
tC(SCLK)/2–30
tC(SCLK)/2–30
ns
ns
ns
ns
ns
ns
ns
ns
tWL(SCLK)
td(SCLK–TxD)
tv(SCLK–TxD)
tr(SCLK)
Serial I/O output valid time
–30
Serial I/O clock output rising time
Serial I/O clock output falling time
CMOS output rising time (Note)
CMOS output falling time (Note)
30
30
30
30
tf(SCLK)
tr(CMOS)
tf(CMOS)
10
10
Note : Pin XOUT is excluded.
Measured
output pin
100 pF
/ / /
CMOS output
Fig. 64 Switching characteristics measurement circuit diagram
Rev.1.04 2004.06.08 page 55 of 66
REJ03B0012-0104Z
7544 Group
t
t
C
(CNTR
(CNTR
0
)
t
t
t
WL(CNTR
0
)
)
)
t
WH(CNTR
0
)
)
)
0.8VCC
CNTR
0
0.2VCC
C
1)
WL(CNTR
1
t
WH(CNTR1
0.8VCC
0.2VCC
CNTR
1
WL(CNTR
0
t
WH(CNTR0
0.8VCC
INT0, INT1
0.2VCC
tW(RESET)
0.8VCC
RESET
0.2VCC
t
C(XIN)
t
WL(XIN)
t
WH(XIN)
0.8VCC
XIN
0.2VCC
t
C
(SCLK
)
tr
tf
t
WL(SCLK
)
tWH(SCLK)
0.8VCC
SCLK
0.2VCC
t
su(RxD-SCLK
)
th(SCLK-RxD)
0.8VCC
0.2VCC
R
XD (at receive)
td(SCLK-TxD)
tv(SCLK-TxD)
T
X
D (at transmit)
Fig. 65 Timing chart
Rev.1.04 2004.06.08 page 56 of 66
REJ03B0012-0104Z
7544 Group
PACKAGE OUTLINE
Recommended
32P4B
Plastic 32pin 400mil SDIP
EIAJ Package Code
JEDEC Code
–
Weight(g)
2.2
Lead Material
Alloy 42/Cu Alloy
SDIP32-P-400-1.78
32
17
1
16
D
Dimension in Millimeters
Symbol
A
Min
–
0.51
–
Nom
–
–
Max
5.08
–
A1
A
2
3.8
–
b
0.35
0.9
0.63
0.22
27.8
8.75
–
–
3.0
0°
0.45
1.0
0.73
0.27
28.0
8.9
1.778
10.16
–
0.55
1.3
1.03
0.34
28.2
9.05
–
–
–
15°
b1
b2
c
D
E
e
e
b1
b
b2
SEATING PLANE
e1
L
–
Recommended
32P6U-A
Plastic 32pin 7✕7mm body LQFP
EIAJ Package Code
LQFP32-P-0707-0.80
JEDEC Code
–
Weight(g)
Lead Material
Cu Alloy
MD
HD
D
32
25
I
2
1
24
Recommended Mount Pad
Dimension in Millimeters
Symbol
Min
–
0
Nom
–
Max
1.7
0.2
–
0.45
0.175
7.1
7.1
–
9.2
9.2
0.7
–
0.75
–
A
A
A
1
2
0.1
1.4
0.37
0.125
7.0
7.0
0.8
9.0
9.0
0.5
1.0
0.6
0.25
–
–
–
0.5
–
7.4
7.4
–
b
0.32
0.105
6.9
6.9
–
8.8
8.8
0.3
–
0.45
–
–
–
0°
8
17
c
D
E
e
H
H
9
16
A
D
E
L
L
1
L1
e
F
Lp
A3
x
0.2
0.1
10°
–
–
–
y
L
b
Lp
Detail F
b2
–
1.0
–
x
M
I
2
y
M
M
D
E
–
–
Rev.1.04 2004.06.08 page 57 of 66
REJ03B0012-0104Z
7544 Group
36PJW-A
Plastic 36pin 6X6mm body WQFN
EIAJ Package Code
JEDEC Code
–
Weight(g)
0.83
Lead Material
Cu Alloy
WQFN36-P-0606-0.50
MD
I
2
(Typ.)
4.26
D
Recommended Mount Pad
c
27
19
19
27
28
18
18
28
Dimension in Millimeters
Symbol
Min
–
0.15
–
5.9
5.9
–
0.5
–
Nom
–
Max
0.8
0.25
–
6.1
6.1
–
0.7
0.05
0.05
–
36
10
10
36
A
b
c
D
E
e
Lp
x
0.2
0.2
6.0
6.0
0.5
0.6
–
–
0.3
–
1
9
9
1
A
Lp
b
M
x
y
–
–
b2
I
2
0.7
–
M
M
D
E
4.8
4.8
–
–
–
–
Rev.1.04 2004.06.08 page 58 of 66
REJ03B0012-0104Z
7544 Group
APPENDIX
2. Decimal calculations
(1) Execution of decimal calculations
NOTES ON PROGRAMMING
The ADC and SBC are the only instructions which will yield proper
decimal notation, set the decimal mode flag (D) to “1” with the
SED instruction. After executing the ADC or SBC instruction, ex-
ecute another instruction before executing the SEC, CLC, or CLD
instruction.
1. Processor Status Register
(1) Initializing of processor status register
Flags which affect program execution must be initialized after a re-
set.
In particular, it is essential to initialize the T and D flags because
they have an important effect on calculations.
<Reason>
(2) Notes on status flag in decimal mode
When decimal mode is selected, the values of three of the flags in
the status register (the N, V, and Z flags) are invalid after a ADC or
SBC instruction is executed.
After a reset, the contents of the processor status register (PS) are
undefined except for the I flag which is “1”.
The carry flag (C) is set to “1” if a carry is generated as a result of
the calculation, or is cleared to “0” if a borrow is generated. To de-
termine whether a calculation has generated a carry, the C flag
must be initialized to “0” before each calculation. To check for a
borrow, the C flag must be initialized to “1” before each calcula-
tion.
Reset
↓
Initializing of flags
↓
Main program
Set D flag to “1”
↓
ADC or SBC instruction
↓
Fig. 1 Initialization of processor status register
NOP instruction
↓
(2) How to reference the processor status register
To reference the contents of the processor status register (PS), ex-
ecute the PHP instruction once then read the contents of (S+1). If
necessary, execute the PLP instruction to return the PS to its origi-
nal status.
SEC, CLC, or CLD instruction
Fig. 4 Status flag at decimal calculations
3. JMP instruction
A NOP instruction should be executed after every PLP instruction.
When using the JMP instruction in indirect addressing mode, do
not specify the last address on a page as an indirect address.
4. BRK instruction
PLP instruction execution
(1) Interrupt priority level
↓
When the BRK instruction is executed with the following condi-
tions satisfied, the interrupt execution is started from the address
of interrupt vector which has the highest priority.
• Interrupt request bit and interrupt enable bit are set to “1”.
• Interrupt disable flag (I) is set to “1” to disable interrupt.
NOP
Fig. 2 Sequence of PLP instruction execution
5. Multiplication and Division Instructions
(1) The index X mode (T) and the decimal mode (D) flags do not
affect the MUL and DIV instruction.
(S)
(2) The execution of these instructions does not change the con-
tents of the processor status register.
(S)+1
Stored PS
Fig. 3 Stack memory contents after PHP instruction execution
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3. Modifying output data with bit managing instruction
6. Read-modify-write instruction
When the port latch of an I/O port is modified with the bit manag-
Do not execute a read-modify-write instruction to the read invalid
address (SFR).
2
ing instruction* , the value of the unspecified bit may be changed.
<Reason>
The read-modify-write instruction operates in the following se-
quence: read one-byte of data from memory, modify the data,
write the data back to original memory. The following instructions
are classified as the read-modify-write instructions in the 740
Family.
The bit managing instructions are read-modify-write form instruc-
tions for reading and writing data by a byte unit. Accordingly, when
these instructions are executed on a bit of the port latch of an I/O
port, the following is executed to all bits of the port latch.
• As for a bit which is set for an input port :
(1) Bit management instructions: CLB, SEB
The pin state is read in the CPU, and is written to this bit after bit
managing.
(2) Shift and rotate instructions: ASL, LSR, ROL, ROR, RRF
(3) Add and subtract instructions: DEC, INC
• As for a bit which is set for an output port :
The bit value of the port latch is read in the CPU, and is written to
this bit after bit managing.
(4) Logical operation instructions (1’s complement): COM
Add and subtract/logical operation instructions (ADC, SBC, AND,
EOR, and ORA) when T flag = “1” operate in the way as the read-
modify-write instruction. Do not execute the read invalid SFR.
<Reason>
Note the following :
• Even when a port which is set as an output port is changed for
an input port, its port latch holds the output data.
• As for a bit of the port latch which is set for an input port, its
value may be changed even when not specified with a bit man-
aging instruction in case where the pin state differs from its port
latch contents.
When the read-modify-write instruction is executed to read invalid
SFR, the instruction may cause the following consequence: the in-
struction reads unspecified data from the area due to the read
invalid condition. Then the instruction modifies this unspecified
data and writes the data to the area. The result will be random
data written to the area or some unexpected event.
2
* bit managing instructions : SEB, and CLB instructions
NOTES ON PERIPHERAL FUNCTIONS
Notes on I/O Ports
4. Direction register
The values of the port direction registers cannot be read.
That is, it is impossible to use the LDA instruction, memory opera-
tion instruction when the T flag is “1”, addressing mode using
direction register values as qualifiers, and bit test instructions
such as BBC and BBS.
1. Pull-up control register
When using each port which built in pull-up resistor as an output
port, the pull-up control bit of corresponding port becomes invalid,
and pull-up resistor is not connected.
<Reason>
It is also impossible to use bit operation instructions such as CLB
and SEB and read-modify-write instructions of direction registers
for calculations such as ROR.
Pull-up control is effective only when each direction register is set
to the input mode.
For setting direction registers, use the LDM instruction, STA in-
struction, etc.
2. Notes in stand-by state
1
In stand-by state* for low-power dissipation, do not make input
levels of an input port and an I/O port “undefined”.
Pull-up (connect the port to Vcc) or pull-down (connect the port to
Vss) these ports through a resistor.
When determining a resistance value, note the following points:
• External circuit
• Variation of output levels during the ordinary operation
When using a built-in pull-up resistor, note on varied current val-
ues:
• When setting as an input port : Fix its input level
•When setting as an output port : Prevent current from flowing out
to external.
<Reason>
The output transistor becomes the OFF state, which causes the
ports to be the high-impedance state. Note that the level becomes
“undefined” depending on external circuits.
Accordingly, the potential which is input to the input buffer in a mi-
crocomputer is unstable in the state that input levels of an input
port and an I/O port are “undefined”. This may cause power
source current.
1
* stand-by state : the stop mode by executing the STP instruction
the wait mode by executing the WIT instruction
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Termination of Unused Pins
1. Terminate unused pins
Notes on Interrupts
1. Change of relevant register settings
Perform the following wiring at the shortest possible distance (20
mm or less) from microcomputer pins.
When not requiring for the interrupt occurrence synchronous with
the following case, take the sequence shown in Figure 5.
• When switching external interrupt active edge
• When switching interrupt sources of an interrupt vector address
where two or more interrupt sources are allocated
(1) I/O ports
Set the I/O ports for the input mode and connect each pin to VCC
or VSS through each resistor of 1 kΩ to 10 kΩ. The port which can
select a built-in pull-up resistor can also use the built-in pull-up re-
sistor.
Set the corresponding interrupt enable bit to “0” (disabled) .
When using the I/O ports as the output mode, open them at “L” or
“H”.
↓
Set the interrupt edge selection bit, active edge switch bit, or
• When opening them in the output mode, the input mode of the
initial status remains until the mode of the ports is switched over
to the output mode by the program after reset. Thus, the poten-
tial at these pins is undefined and the power source current may
increase in the input mode. With regard to an effects on the sys-
tem, thoroughly perform system evaluation on the user side.
• Since the direction register setup may be changed because of a
program runaway or noise, set direction registers by program
periodically to increase the reliability of program.
the interrupt source selection bit.
↓
NOP (One or more instructions)
↓
Set the corresponding interrupt request bit to “0”
(no interrupt request issued).
↓
Set the corresponding interrupt enable bit to “1” (enabled).
Fig. 5 Sequence of changing relevant register
2. Termination remarks
(1) I/O ports setting as input mode
<Reason>
[1] Do not open in the input mode.
When setting the followings, the interrupt request bit of the corre-
sponding interrupt may be set to “1”.
• When switching external interrupt active edge
INT0 interrupt edge selection bit
<Reason>
• The power source current may increase depending on the first-
stage circuit.
• An effect due to noise may be easily produced as compared with
proper termination (1) shown on the above “1. Terminate unused
pins”.
(bit 0 of Interrupt edge selection register (address 3A16))
INT1 interrupt edge selection bit
(bit 1 of Interrupt edge selection register)
CNTR0 active edge switch bit
[2] Do not connect to VCC or VSS directly.
(bit 2 of timer X mode register (address 2B16))
CNTR1 active edge switch bit
<Reason>
If the direction register setup changes for the output mode be-
cause of a program runaway or noise, a short circuit may occur.
(bit 6 of timer A mode register (address 1D16))
2. Check of interrupt request bit
[3] Do not connect multiple ports in a lump to VCC or VSS through
When executing the BBC or BBS instruction to determine an in-
terrupt request bit immediately after this bit is set to “0”, take the
following sequence.
a resistor.
<Reason>
If the direction register setup changes for the output mode be-
cause of a program runaway or noise, a short circuit may occur
between ports.
<Reason>
If the BBC or BBS instruction is executed immediately after an in-
terrupt request bit is cleared to “0”, the value of the interrupt
request bit before being cleared to “0” is read.
Set the interrupt request bit to “0” (no interrupt issued)
↓
NOP (one or more instructions)
↓
Execute the BBC or BBS instruction
Fig. 6 Sequence of check of interrupt request bit
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Notes on Timers
1. When n (0 to 255) is written to a timer latch, the frequency divi-
Notes on Timer X
1. CNTR0 interrupt active edge selection
sion ratio is 1/(n+1).
CNTR0 interrupt active edge depends on the CNTR0 active edge
switch bit (bit 2 of timer X mode register (address 2B16)).
When this bit is “0”, the CNTR0 interrupt request bit goes to “1” at
the falling edge of CNTR0 pin input signal. When this bit is “1”, the
CNTR0 interrupt request bit goes to “1” at the rising edge of
CNTR0 pin input signal.
2. When a count source of timer X is switched, stop a count of the
timer.
Notes on Timer 1
1. Timer 1 count source
The “on-chip oscillator output” of timer 1 count source selection
bits (bits 1 and 0 of timer count source set register 2 (address
2F16)) can be selected while the on-chip oscillator oscillation con-
trol bit (bit 3 of CPU mode register (address 3B16)) is “0” (on-chip
oscillator oscillation enabled).
2. Timer X count source selection
The f(XIN) (frequency not divided) can be selected by the timer X
count source selection bits (bits 1 and 0 of timer count source set
register 1 (address 2E16)) only when the ceramic oscillation or the
on-chip oscillator is selected.
Do not select it for the timer X count source at the RC oscillation.
Notes on Timer A
1. CNTR1 interrupt active edge selection
3. Pulse output mode
CNTR1 interrupt active edge depends on the CNTR1 active edge
switch bit (bit 6 of timer A mode register (address 1D16)).
When this bit is “0”, the CNTR1 interrupt request bit goes to “1” at
the falling edge of the CNTR1 pin input signal. When this bit is “1”,
the CNTR1 interrupt request bit goes to “1” at the rising edge of
the CNTR1 pin input signal.
Set the direction register of port P14, which is also used as CNTR0
pin, to output.
When the TXOUT pin is used, set the direction register of port P03,
which is also used as TXOUT pin, to output.
4. Pulse width measurement mode
Set the direction register of port P14, which is also used as CNTR0
pin, to input.
However, in the pulse width HL continuously measurement mode,
CNTR1 interrupt request is generated at both rising and falling
edges of CNTR1 pin input signal regardless of the setting of
CNTR1 active edge switch bit.
2. Period measurement mode, event counter mode and pulse
width HL continuously measurement mode
Set the direction register of port P00, which is also used as CNTR1
pin, to input.
Set the key-on wakeup function of P00, which is also used as
CNTR1 pin, to be disabled by setting the P00 key-on wakeup se-
lection bit (bit 7 of interrupt edge selection register (address 3A16))
to “1”.
3. Timer A count source
The “on-chip oscillator output” of timer A count source selection
bits (bits 3 and 2 of timer count source set register 2 (address
2F16)) can be selected while the on-chip oscillator oscillation con-
trol bit (bit 3 of CPU mode register (address 3B16)) is “0” (on-chip
oscillator oscillation enabled).
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3. Notes common to clock synchronous serial I/O and UART
(1) Set the serial I/O control register again after the transmission
and the reception circuits are reset by clearing both the trans-
mit enable bit and the receive enable bit to “0.”
Notes on Serial I/O
1. Clock synchronous serial I/O
(1) When the transmit operation is stopped, clear the serial I/O en-
able bit (bit 7) and the transmit enable bit (bit 4 of serial I/O
control register (address 1A16)) to “0” (serial I/O and transmit
disabled).
Clear both the transmit enable bit (TE)
and the receive enable bit (RE) to “0”
<Reason>
Since transmission is not stopped and the transmission circuit is
not initialized even if only the serial I/O enable bit is cleared to “0”
(serial I/O disabled), the internal transmission is running (in this
case, since pins TxD, RxD, SCLK, and SRDY function as I/O ports,
the transmission data is not output). When data is written to the
transmit buffer register in this state, data starts to be shifted to the
transmit shift register. When the serial I/O enable bit is set to “1” at
this time, the data during internally shifting is output to the TxD pin
and an operation failure occurs.
Set the bits 0 to 3 and bit 6 of the
serial I/O control register
Can be set
with the LDM
instruction at
the same time
Set both the transmit enable bit (TE)
and the receive enable bit (RE), or
one of them to “1”
Fig. 7 Sequence of setting serial I/O control register again
(2) The transmit shift completion flag (bit 2 of serial I/O status reg-
ister (address 1916)) changes from “1” to “0” with a delay of
0.5 to 1.5 shift clocks. When data transmission is controlled
with referring to the flag after writing the data to the transmit
buffer register, note the delay.
(2) When the receive operation is stopped, clear the receive en-
able bit (bit 5) to “0” (receive disabled), or clear the serial I/O
enable bit (bit 7 of serial I/O control register (address 1A16)) to
“0” (serial I/O disabled).
(3) When the transmit/receive operation is stopped, clear both the
transmit enable bit and receive enable bit to “0” (transmit and
receive disabled) simultaneously. (any one of data transmis-
sion and reception cannot be stopped.)
(3) When data transmission is executed at the state that an exter-
nal clock input is selected as the synchronous clock, set “1” to
the transmit enable bit while the SCLK is “H” state. Also, write
to the transmit buffer register while the SCLK is “H” state.
<Reason>
In the clock synchronous serial I/O mode, the same clock is used
for transmission and reception.
(4) When the transmit interrupt is used, set as the following se-
quence.
If any one of transmission and reception is disabled, a bit error oc-
curs because transmission and reception cannot be synchronized.
In this mode, the clock circuit of the transmission circuit also oper-
ates for data reception. Accordingly, the transmission circuit does
not stop by clearing only the transmit enable bit to “0” (transmit
disabled). Also, the transmission circuit cannot be initialized even
if the serial I/O enable bit is cleared to “0” (serial I/O disabled)
(same as (1)).
✕ Serial I/O transmit interrupt enable bit is set to “0” (disabled).
✕ Serial I/O transmit enable bit is set to “1”.
✕ Serial I/O transmit interrupt request bit (bit 1 of interrupt request
register 1 (address 3C16)) is set to “0” after 1 or more instruc-
tions have been executed.
✕ Serial I/O transmit interrupt enable bit (bit 1 of interrupt control
register 1 (address 3E16)) is set to “1” (enabled).
<Reason>
When the transmit enable bit is set to “1”, the transmit buffer
empty flag (bit 0) and transmit shift completion flag (bit 2 of serial
I/O status register (address 1916)) are set to “1”.
Accordingly, even if the timing when any of the above flags is set
to “1” is selected for the transmit interrupt source, interrupt request
occurs and the transmit interrupt request bit is set.
(4) When signals are output from the SRDY pin on the reception
side by using an external clock, set all of the receive enable bit
(bit 5), the SRDY output enable bit (bit 2 of serial I/O control
register (address 1A16)), and the transmit enable bit to “1”.
(5) When the SRDY signal input is used, set the using pin to the in-
put mode before data is written to the transmit/receive buffer
register.
(5) Write to the baud rate generator (BRG) while the transmit/re-
ceive operation is stopped.
2. UART
When the transmit operation is stopped, clear the transmit enable
bit to “0” (transmit disabled).
<Reason>
Same as (1) shown on the above “1. Clock synchronous serial I/
O“.
When the receive operation is stopped, clear the receive enable
bit to “0” (receive disabled).
When the transmit/receive operation is stopped, clear the transmit
enable bit to “0” (transmit disabled) and receive enable bit to “0”
(receive disabled).
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4. I/O pin function when serial I/O is enabled.
3. A/D conversion accuracy
The pin functions of P12/SCLK and P13/SRDY are switched to as
follows according to the setting values of a serial I/O mode selec-
tion bit (bit 6 of serial I/O control register (address 1A16)) and a
serial I/O synchronous clock selection bit (bit 1 of serial I/O control
register).
As for AD translation accuracy, on the following operating condi-
tions, accuracy may become low.
(1) Since the analog circuit inside a microcomputer becomes sen-
sitive to noise when VREF voltage is set up lower than Vcc
voltage, accuracy may become low rather than the case
where VREF voltage and Vcc voltage are set up to the same
value.
(1) Serial I/O mode selection bit → “1” :
Clock synchronous type serial I/O is selected.
• Setup of a serial I/O synchronous clock selection bit
“0” : P12 pin turns into an output pin of a synchronous clock.
“1” : P12 pin turns into an input pin of a synchronous clock.
• Setup of a SRDY output enable bit (SRDY)
(2) When VREF voltage is lower than [ 3.0 V ], the accuracy at the
low temperature may become extremely low compared with
that at room temperature. When the system would be used at
low temperature, the use at VREF=3.0 V or more is recom-
mended.
“0” : P13 pin can be used as a normal I/O pin.
“1” : P13 pin turns into a SRDY output pin.
Notes on Watchdog Timer
(2) Serial I/O mode selection bit → “0” :
1. The watchdog timer is operating during the wait mode. Write
data to the watchdog timer control register to prevent timer un-
derflow.
Clock asynchronous (UART) type serial I/O is selected.
• Setup of a serial I/O synchronous clock selection bit
“0”: P12 pin can be used as a normal I/O pin.
“1”: P12 pin turns into an input pin of an external clock.
• When clock asynchronous (UART) type serial I/O is selected, it
functions P13 pin. It can be used as a normal I/O pin.
2. The watchdog timer stops during the stop mode. However, the
watchdog timer is running during the oscillation stabilizing time
after the STP instruction is released. In order to avoid the un-
derflow of the watchdog timer, the watchdog timer control
register must be written just before executing the STP instruc-
tion.
Notes on A/D conversion
1. Analog input pin
In order to execute the A/D conversion correctly, to complete the
charge to an internal capacitor within the specified time is re-
quired. The maximum output impedance of the analog input
source required to complete the charge to a capacitor within the
specified time is as follows;
3. The STP instruction disable bit (bit 6 of watchdog timer control
register (address 3916)) can be set to “1” but cannot be set to
“0” by program.
Notes on RESET pin
1. Connecting capacitor
About 35 kΩ (at f(XIN) = 8 MHz)
In case where the RESET signal rise time is long, connect a ce-
ramic capacitor or others across the RESET pin and the Vss pin.
And use a 1000 pF or more capacitor for high frequency use.
When connecting the capacitor, note the following :
• Make the length of the wiring which is connected to a capacitor
as short as possible.
When the maximum output impedance exceeds the above value,
equip an analog input pin with an external capacitor of 0.01µF to
1µF between an analog input pin and VSS.
Further, be sure to verify the operation of application products on
the user side.
<Reason>
• Be sure to verify the operation of application products on the
user side.
An analog input pin includes the capacitor for analog voltage com-
parison. Accordingly, when signals from signal source with high
impedance are input to an analog input pin, charge and discharge
noise generates. This may cause the A/D conversion/comparison
precision to be worse.
<Reason>
If the several nanosecond or several ten nanosecond impulse
noise enters the RESET pin, it may cause a microcomputer fail-
ure.
2. Clock frequency during A/D conversion
The comparator consists of a capacity coupling, and a charge of
the capacity will be lost if the clock frequency is too low. This may
cause the A/D conversion precision to be worse. Accordingly, set
f(XIN) in order that the A/D conversion clock is 500 kHz or over
during A/D conversion.
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Notes on Oscillation Control
1. Oscillation stop detection circuit
Notes on Clock Generating Circuit
1. Switch of ceramic/quartz-crystal oscillation and RC oscillation
After releasing reset, the oscillation mode selection bit (bit 5 of
CPU mode register (address 3B16)) is “0” (ceramic/quartz-crystal
oscillation selected). When the RC oscillation is used, after releas-
ing reset, set this bit to “1”.
(1) When the stop mode is used, set the oscillation stop detection
function to “invalid”.
(2) When the ceramic or RC oscillation is stopped (bit 4 of CPU
mode register (address 3B16)), set the oscillation stop detec-
tion function to “invalid”.
2. Double-speed mode
The double-speed mode can be used only when a ceramic oscilla-
tion is selected. Do not use it when an RC oscillation is selected.
(3) The oscillation stop detection circuit is not included in the emu-
lator MCU “M37542RSS”.
3. CPU mode register
2. Stop mode
Oscillation mode selection bit (bit 5), processor mode bits (bits 1
and 0) of CPU mode register (address 3B16) are used to select os-
cillation mode and to control operation modes of the
microcomputer. In order to prevent the dead-lock by erroneously
writing (ex. program run-away), these bits can be rewritten only
once after releasing reset. After rewriting, it is disabled to write any
data to the bit. (The emulator MCU “M37542RSS” is excluded.)
Also, when the read-modify-write instructions (SEB, CLB, etc.) are
executed to bits 2 to 4, 6 and 7, bits 5, 1 and 0 are locked.
(1) When the stop mode is used, set the oscillation stop detection
function to “invalid”.
(2) When the stop mode is used, set “0” (STP instruction enabled)
to the STP instruction disable bit of the watchdog timer control
register (bit 6 of watchdog timer control register (address
3916)).
(3) The oscillation stabilizing time after release of STP instruction
can be selected from “set automatically”/“not set automati-
cally” by the oscillation stabilizing time set bit after release of
the STP instruction (bit 0 of MISRG (address 3816)). When “0”
is set to this bit, “0116” is set to timer 1 and “FF16” is set to
prescaler 1 automatically at the execution of the STP instruc-
tion. When “1” is set to this bit, set the wait time to timer 1 and
prescaler 1 according to the oscillation stabilizing time of the
oscillation. Also, when timer 1 is used, set values again to
timer 1 and prescaler 1 after system is returned from the stop
mode.
4. Clock division ratio, XIN oscillation control, on-chip oscillator
control
The state transition shown in Fig. 81 can be performed by setting
the clock division ratio selection bits (bits 7 and 6), XIN oscillation
control bit (bit 4), on-chip oscillator oscillation control bit (bit 3) of
CPU mode register. Be careful of notes on use in Fig. 81.
5. On-chip oscillator operation
When the MCU operates by the on-chip oscillator for the main
clock, connect XIN pin to VCC through a 1 kΩ to 10 kΩ resistor and
leave XOUT pin open.
(4) The STP instruction cannot be used when the on-chip oscilla-
tor is selected by the clock division ratio selection bits (bits 7
and 6 of CPU mode register (address 3B16)).
The clock frequency of the on-chip oscillator depends on the sup-
ply voltage and the operation temperature range.
Be careful that this margin of frequencies when designing applica-
tion products.
(5) When the stop mode is used, set the on-chip oscillator oscilla-
tion control bit (bit 3 of CPU mode register (address 3B16)) to
“1” (on-chip oscillator oscillation stop).
6. Ceramic resonator
When the ceramic resonator/quartz-crystal oscillation is used for
the main clock, connect the ceramic resonator and the external
circuit to pins XIN and XOUT at the shortest distance. A feedback
resistor is built-in.
(6) Do not execute the STP instruction during the A/D conversion.
7. RC oscillation
When the RC oscillation is used for the main clock, connect the
XIN pin and XOUT pin to the external circuit of resistor R and the
capacitor C at the shortest distance.
The frequency is affected by a capacitor, a resistor and a micro-
computer.
So, set the constants within the range of the frequency limits.
8. External clock
When the external signal clock is used for the main clock, connect
the XIN pin to the clock source and leave XOUT pin open.
Select “0” (ceramic oscillation) to oscillation mode selection bit.
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Electric Characteristic Differences Among
Mask ROM and One Time PROM Version
MCUs
There are differences in electric characteristics, operation margin,
noise immunity, and noise radiation among mask ROM and One
Time PROM version MCUs due to the differences in the manufac-
turing processes.
When manufacturing an application system with One Time PROM
version and then switching to use of the mask ROM version, per-
form sufficient evaluations for the commercial samples of the
mask ROM version.
Note on Power Source Voltage
When the power source voltage value of a microcomputer is less
than the value which is indicated as the recommended operating
conditions, the microcomputer does not operate normally and may
perform unstable operation.
In a system where the power source voltage drops slowly when
the power source voltage drops or the power supply is turned off,
reset a microcomputer when the supply voltage is less than the
recommended operating conditions and design a system not to
cause errors to the system by this unstable operation.
NOTES ON HARDWARE
Handling of Power Source Pin
In order to avoid a latch-up occurrence, connect a capacitor suit-
able for high frequencies as bypass capacitor between power
source pin (Vcc pin) and GND pin (Vss pin). Besides, connect the
capacitor to as close as possible. For bypass capacitor which
should not be located too far from the pins to be connected, a ce-
ramic capacitor of 0.01 µF to 0.1 µF is recommended.
One Time PROM Version
The CNVss pin is connected to the internal memory circuit block
by a low-ohmic resistance, since it has the multiplexed function to
be a programmable power source pin (VPP pin) as well.
To improve the noise reduction, connect a track between CNVss
pin and Vss pin with 1 to 10 kΩ resistance.
The mask ROM version track of CNVss pin has no operational in-
terference even if it is connected via a resistor.
Rev.1.04 2004.06.08 page 66 of 66
REJ03B0012-0104Z
7544 Group Data Sheet
REVISION HISTORY
Rev.
Date
Description
Summary
Page
1.00 Nov. 8, 2002
–
First edition issued
1.01 May. 6, 2003 44 to 48 Added to Electrical Characteristics
1.02 Jun. 25, 2003
1.03 Feb. 12, 2004
48
49
Entered to Limits
Icc Power source current On-chip oscillator operation mode,
On-chip oscillator operation mode(in WIT state)
Entered to Limits
A/D Converter characteristics
6
Table 2 and Fig.6: Under development eliminated.
[Interrupt edge selection register] added.
Fig.23: “1” is added to Fig. title and register name.
Timer count source set register 1, TCSS1
■ Notes on A/D converter added.
17
23
29
33
38
39
47
Fig.38: Processing of XIN pin revised.
DATA REQUIRED FOR MASK ORDERS added.
■ Notes on A/D converter added.
Table 12: VOH/VOL Test conditions revised.
Hysteresis RESET revised.
49
Table 14: ABS Test conditions revised.
Note added.
1.04 Jun. 08, 2004
3
6
8
Fig.4 Pin configuration : 36PJW-A added.
Fig.7 Functional block diagram: 36PJW-A added.
Package: 36PJW-A added.
Table 2: M37544M2-XXXHP, M37544G2HP added.
“Under development” eliminated.
14
23
25
31
37
38
41
Fig.14: SIO1STS → SIOSTS, SIO1CON → SIOCON
Fig.23: Address revised.
Fig.25: Bit 6 revised.
Comparator and control circuit revised.
Oscillation stop detection circuit revised.
Fig. 46, Fig. 47 a bit name revised.
Countermeasure against noise added.
(NOTES ON PERIPHERAL FUNCTIONS described previously here are included
in APPENDIX at the end of this data sheet.)
Part number: M37544M2-XXXHP, M37544G2HP added.
PACKAGE OUTLINE: 36PJW-A added.
49
58
59 to 66 APPENDIX added.
All pages Words standardized: On-chip oscillator, A/D converter
(1/1)
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