MITSUBISHI M32C

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Description
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
About M32C/83 Group
The M32C/83 group of single-chip microcomputers are built using a high-performance silicon gate CMOS
process uses a M32C/80 Series CPU core and are packaged in a 144-pin and 100-pin plastic molded QFP.
These single-chip microcomputers operate using sophisticated instructions featuring a high level of instruction efficiency. With 16M bytes of address space, they are capable of executing instructions at high speed.
They also feature a built-in multiplier and DMAC, making them ideal for controlling office, communications,
industrial equipment, and other high-speed processing applications.
Applications
Audio, cameras, office equipment, communications equipment, portable equipment, etc.
Index
About M32C/83 Group .......................................... 1
Central Processing Unit (CPU) ........................... 20
Reset ................................................................... 24
SFR ..................................................................... 37
Software Reset ................................................... 48
Processor Mode .................................................. 48
Bus Settings ........................................................ 52
Bus Control ......................................................... 55
System Clock ...................................................... 65
Power Saving ...................................................... 76
Protection ............................................................ 81
Interrupt Outline .................................................. 83
______
INT Interrupts ...................................................... 98
______
NMI Interrupt ....................................................... 99
Key Input Interrupt .............................................. 99
Address Match Interrupt .................................... 100
Intelligent I/O and CAN Interrupt ....................... 101
Precautions for Interrupts .................................. 104
Watchdog Timer ................................................ 106
DMAC ............................................................... 109
DMAC II ............................................................ 121
Timer ................................................................. 129
Timer A .............................................................. 131
Timer B .............................................................. 147
Three-phase motor control timers’ functions ..... 155
Serial I/O ........................................................... 168
CAN Module ...................................................... 198
Intelligent I/O ..................................................... 235
Base timer (group 0 to 3) .................................. 240
Time measurement (group 0 and 1) .................. 247
WG function (group 0 to 3) ................................ 252
Serial I/O (group 0 to 2) .................................... 264
A-D Converter ................................................... 281
D-A Converter ................................................... 296
CRC Calculation Circuit .................................... 298
X-Y Converter ................................................... 300
DRAM Controller ............................................... 303
Programmable I/O Ports ................................... 310
VDC .................................................................. 334
Usage Precaution ............................................. 335
Electrical characteristics ................................... 344
Outline Performance ......................................... 381
Flash Memory ................................................... 383
CPU Rewrite Mode ........................................... 384
Outline Performance of CPU Rewrite Mode ..... 384
Inhibit Rewriting Flash Memory Version ............ 397
Parallel I/O Mode .............................................. 399
Standard serial I/O mode .................................. 400
Specifications written in this manual are believed to be accurate, but are
not guaranteed to be entirely free of error.
Specifications in this manual may be changed for functional or performance
improvements. Please make sure your manual is the latest edition.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Performance Outline
Table 1.1.1 and 1.1.2 are performance outline of M32C/83 group.
Table 1.1.1. Performance outline of M32C/83 group (144-pin version) (1/2)
Item
CPU
Performance
Number of basic instructions
108 instructions
Shortest instruction execution time 33 ns(f(XIN)=30MHz)
Operation mode
Single-chip, memory expansion and microprocessor modes
Memory space
16 M bytes
Memory capacity
See ROM/RAM expansion figure.
Peripheral function
I/O port
123 pins (P0 to P15 except P85)
Input port
1 pin (P85)
Multifunction timer
Output
16 bits x 5 (TA0, TA1, TA2, TA3, TA4)
Input
16 bits x 6 (TB0, TB1, TB2, TB3, TB4, TB5)
Intelligent I/O
4 groups
Time measurement
8 channels (group 0) + 4 channels (group 1)
Waveform generation
4 channels (group 0) + 8 channels X 3 (group 1, 2 and 3)
Bit-modulation PWM
8 channels X 2 (group 2 and 3)
Real time port
8 channels X 2 (group 2 and 3)
Communication function
• Clock synchronous serial I/O, UART (group 0 and 1)
• HDLC data process (group 0 and 1)
• Clock synchronous variable length serial I/O (group 2)
• IE bus (Note 1) (group 2)
Serial I/O
5 channels (UART0 to UART4)
IE Bus (Note 1, 3), I2C Bus (Note 2, 3)
CAN module
1 channel, 2.0B specification
A-D converter
10-bit A-D x 2 circuits, standard 18 inputs, max 34 inputs
D-A converter
8-bit D-A x 2 circuits
DMAC
4 channels
DMAC II
Start by all variable vector interrupt factor
Immediate transfer, operation transfer and chain transfer function
DRAM controller
CAS before RAS refresh, self-refresh, EDO, FP
CRC calculation circuit
CRC-CCITT
X-Y converter
16 bits X 16 bits
Watchdog timer
15 bits x 1 (with prescaler)
Interrupt
42 internal and 8 external sources, 5 software sources, interrupt
Clock generating circuit
3 built-in clock generation circuits
priority level 7 levels
• Main/sub-clock generating circuit :built-in feedback resistance, and
external ceramic or quartz oscillator
• Ring oscillator for detecting main clock oscillation stop
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.1. Performance outline of M32C/83 group (144-pin version) (2/2)
Electric characteristics
Supply voltage
4.2 to 5.5V (f(XIN)=30MHz without wait), 3.0 to 3.6V (f(X IN)=20MHz without wait)
Power consumption
26mA (f(XIN)=20MHz without software wait,Vcc=5V)
38mA (f(XIN)=30MHz without software wait,Vcc=5V)
I/O characteristics
I/O withstand voltage :5V
I/O current :5mA
Operating ambient temperature
–40 to 85oC
Device configuration
CMOS high performance silicon gate
Package
144-pin plastic mold QFP
Note 1 :IE Bus is a trademark of NEC corporation.
Note 2 :I2C Bus is a registered trademark of Philips.
Note 3 :This function is executed by using software and hardware.
Table 1.1.2. Performance outline of M32C/83 group (100-pin version) (1/2)
Item
CPU
Performance
Number of basic instructions
108 instructions
Shortest instruction execution time 33 ns (f(XIN)=30MHz)
Operation mode
Single-chip, memory expansion and microprocessor modes
Memory space
16 M bytes
Memory capacity
See ROM/RAM expansion figure.
Peripheral function
I/O port
87 pins (P0 to P10 except P85)
Input port
1 pin (P85)
Multifunction timer
Output
16 bits x 5 (TA0, TA1, TA2, TA3, TA4)
Input
16 bits x 6 (TB0, TB1, TB2, TB3, TB4, TB5)
Intelligent I/O
4 groups
Time measurement
3 channels (group 0) + 2 channels (group 1)
Waveform generation
2 channels X 2 (group 0 and 3) + 3 channels X 2 (group 1 and 2)
Bit-modulation PWM
3 channels (group 2) + 2 channels (group 3)
Real time port
3 channels (group 2) + 2 channels (group 3)
Communication function
• Clock synchronous serial I/O, UART (group 0 and 1)
• HDLC data process (group 0 and 1)
• Clock synchronous variable length serial I/O (group 2)
• IE bus (Note 1) (group 2)
Serial I/O
5 channels (UART0 to UART4)
IE Bus (Note 1, 3), I2C Bus (Note 2, 3)
CAN module
1 channel, 2.0B specification
A-D converter
10 bits A-Dx 2 circuits, standard 10 inputs, max 26 inputs
D-A converter
8 bits D-A x 2 circuits
DMAC
4 channels
DMAC II
Start by all variable vector interrupt factor
Immediate transfer, operation function and chain transfer function
DRAM controller
CAS before RAS refresh, self-refresh, EDO, FP
CRC calculation circuit
CRC-CCITT
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.2. Performance outline of M32C/83 group (100-pin version) (2/2)
X-Y converter
16 bits X 16 bits
Watchdog timer
15 bits x 1 (with prescaler)
Interrupt
42 internal and 8 external sources, 5 software sources, interrupt priority
level 7 levels
Clock generating circuit
3 built-in clock generation circuits
• Main/sub-clock generating circuit :built-in feedback resistance, and
external ceramic or quartz oscillator
• Ring oscillator for detecting main clock oscillation stop
Electric characteristics
Supply voltage
4.2 to 5.5V (f(XIN)=30MHz without wait), 3.0 to 3.6V (f(XIN)=20MHz without wait)
Power consumption
26mA (f(XIN)=20MHz without software wait,Vcc=5V)
38mA (f(XIN)=30MHz without software wait,Vcc=5V)
I/O characteristics
I/O withstand voltage :5V
I/O current :5mA
Operating ambient temperature
–40 to 85oC
Device configuration
CMOS high performance silicon gate
Package
100-pin plastic mold QFP
Note 1 :IE Bus is a trademark of NEC corporation.
Note 2 :I2C Bus is a registered trademark of Philips.
Note 3 :This function is executed by using software and hardware.
Mitsubishi plans to release the following products in the M32C/83 group:
(1) Support for mask ROM version and flash memory version
(2) ROM capacity
(3) Package
100P6S-A : Plastic molded QFP (mask ROM version and flash memory version)
100P6Q-A : Plastic molded QFP (mask ROM version and flash memory version)
144P6Q-A : Plastic molded QFP (mask ROM version and flash memory version)
RAM size
(byte)
M30835FJGP
M30835MJGP
M30833FJGP
M30833MJGP
M30833FJFP
M30833MJFP
31K
20K
10K
128K
Figure 1.1.1. ROM expansion
4
192K
256K
512K
ROM size
(byte)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
The M32C/83 group products currently supported are listed in Table 1.1.3.
Table 1.1.3. M32C/83 group
Type No
As of Nov. 2001
ROM capacity
RAM capacity
Package type
M30835MJGP
***
144P6Q-A
M30833MJGP
***
100P6Q-A
M30833MJFP
***
M30835FJGP
**
144P6Q-A
M30833FJGP
**
100P6Q-A
M30833FJFP
**
100P6S-A
**
:Under development
***
:Under planning
Type No.
512K
31K
Remarks
Mask ROM version
100P6S-A
Flash memory version
M 3 0 8 3 5 F J – (X X X ) G P
Package type:
FP : Package
GP : Package
ROM capacity:
J : 512K bytes
100P6S-A
100P6Q-A, 144P6Q-A
Memory type:
M : Mask ROM version
F : Flash memory version
Shows RAM capacity, pin count, etc
(The value itself has no specific meaning)
M32C/83 Group
M16C Family
Figure 1.1.2. Type No., memory size, and package
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Pin Configuration and Pin Description
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
109
72
110
71
111
70
112
69
113
68
114
67
115
66
116
65
117
64
118
63
119
62
120
61
121
60
122
59
123
58
124
57
125
56
M32C/83 (144P6Q-A)
126
127
55
54
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
SRxD4 / SDA4 / TxD4 / ANEX1 / P96
CLK4 / ANEX0 / P95
SS4 / RTS4 / CTS4 / TB4IN / DA1 / P94
SS3 / RTS3 / CTS3 / TB3IN / DA0 / P93
IEOUT / OUTC20 / SRxD3 / SDA3 / TxD3 / TB2IN / P92
IEIN / STxD3 / SCL3 / RxD3 / TB1IN / P91
CLK3 / TB0IN / P90
P146
P145
P144
OUTC17 / INPC17 / P143
OUTC16 / INPC16 / P142
OUTC15 / P141
OUTC14 / P140
BYTE
CNVss
VCONT / XCIN / P87
XCOUT / P86
RESET
XOUT
Vss
XIN
Vcc
NMI / P85
INT2 / P84
CANIN / INT1 / P83
CANOUT / OUTC32 / INT0 / P82
OUTC30 / U / TA4IN / P81
BE0IN / ISRxD0 / INPC02 / U / TA4OUT / P80
CANIN / ISCLK0 / OUTC01 / INPC01 / TA3IN / P77
CANOUT / BE0OUT / ISTxD0 / OUTC00 / INPC00 / TA3OUT / P76
BE1IN / ISRxD1 / OUTC12 / INPC12 / W / TA2IN / P75
ISCLK1 / OUTC11 / INPC11 / W / TA2OUT / P74
BE1OUT / ISTxD1 / OUTC10 / SS2 / RTS2 / CTS2 / V / TA1IN / P73
CLK2 / V / TA1OUT / P72
IEIN / ISRxD2 / OUTC22 / STxD2 / SCL2 / RxD2 / TA0IN / TB5IN / P71
19
37
18
38
144
17
39
143
16
40
142
15
41
141
14
42
140
13
43
139
12
44
138
11
45
137
10
46
136
9
47
135
8
48
134
7
49
133
6
50
132
5
51
131
4
52
130
3
53
129
2
128
1
D8 / P10
AN07 / D7 / P07
AN06 / D6 / P06
AN05 / D5 / P05
AN04 / D4 / P04
P114
OUTC13 / P113
BE1IN / ISRxD1 / OUTC12 / INPC12 / P112
ISCLK1 / OUTC11 / INPC11 / P111
BE1OUT / ISTxD1 / OUTC10 / P110
AN03 / D3 / P03
AN02 / D2 / P02
AN01 / D1 / P01
AN00 / D0 / P00
INPC07 / AN157 / P157
INPC06 / AN156 / P156
OUTC05 / INPC05 / AN155 / P155
OUTC04 / INPC04 / AN154 / P154
INPC03 / AN153 / P153
BE0IN / ISRxD0 / INPC02 / AN152 / P152
ISCLK0 / OUTC01 / INPC01 / AN151 / P151
Vss
BE0OUT / ISTxD0 / OUTC00 / INPC00 / AN150 / P150
Vcc
KI3 / AN7 / P107
KI2 / AN6 / P106
KI1 / AN5 / P105
KI0 / AN4 / P104
AN3 / P103
AN2 / P102
AN1 / P101
AVss
AN0 / P100
VREF
AVcc
STxD4 / SCL4 / RxD4 / ADTRG / P97
107
108
P11 / D9
P12 / D10
P13 / D11
P14 / D12
P15 / D13 / INT3
P16 / D14 / INT4
P17 / D15 / INT5
P20 / A0 ( / D0 ) / AN20
P21 / A1 ( / D1 ) / AN21
P22 / A2 ( / D2 ) / AN22
P23 / A3 ( / D3 ) / AN23
P24 / A4 ( / D4 ) / AN24
P25 / A5 ( / D5 ) / AN25
P26 / A6 ( / D6 ) / AN26
P27 / A7 ( / D7 ) / AN27
Vss
P30 / A8 ( MA0 ) ( / D8 )
Vcc
P120 / OUTC30
P121 / OUTC31
P122 / OUTC32
P123 / OUTC33
P124 / OUTC34
P31 / A9 ( MA1 ) ( / D9 )
P32 / A10 ( MA2 ) ( / D10 )
P33 / A11 ( MA3 ) ( / D11 )
P34 / A12 ( MA4 ) ( / D12 )
P35 / A13 ( MA5 ) ( / D13 )
P36 / A14 ( MA6 ) ( / D14 )
P37 / A15 ( MA7 ) ( / D15 )
P40 / A16 ( MA8 )
P41 / A17 ( MA9 )
Vss
P42 / A18 ( MA10 )
Vcc
P43 / A19 ( MA11 )
Figure 1.1.3 to 1.1.5 show the pin configurations (top view), Table 1.1.3 list pin names, and Table 1.1.4 list
pin description.
Note: P70 and P71 are N-channel open drain output.
Figure 1.1.3. 144-pin version pin configuration (top view)
6
P44 / CS3 / A20 (MA12)
P45 / CS2 / A21
P46 / CS1 / A22
P47 / CS0 / A23
P125 / OUTC35
P126 / OUTC36
P127 / OUTC37
P50 / WRL / WR / CASL
P51 / WRH / BHE / CASH
P52 / RD / DW
P53 / CLKOUT / BCLK / ALE
P130 / OUTC24
P131 / OUTC25
Vcc
P132 / OUTC26
Vss
P133 / OUTC23
P54 / HLDA / ALE
P55 / HOLD
P56 / ALE / RAS
P57 / RDY
P134 / OUTC20 / ISTxD2 / IEOUT
P135 / OUTC22 / ISRxD2 / IEIN
P136 / OUTC21 / ISCLK2
P137 / OUTC27
P60 / CTS0 / RTS0 / SS0
P61 / CLK0
P62 / RxD0 / SCL0 / STxD0
P63 / TxD0 / SDA0 / SRxD0
P64 / CTS1 / RTS1 / SS1 / OUTC21 / ISCLK2
P65 / CLK1
Vss
P66 / RxD1 / SCL1 / STxD1
Vcc
P67 / TxD1 / SDA1 / SRxD1
P70 / TA0OUT / TxD2 / SDA2 / SRxD2
/ OUTC20 / ISTxD2 / IEOUT
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.4. 144-pin version pin description (1/3)
Pin
No
Control
Port
1
P96
2
P95
P94
3
4
Interrupt Timer
P93
TB4IN
TB3IN
7
P92
P91
P90
TB2IN
TB1IN
TB0IN
8
P146
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
P145
5
6
UART/CAN
Intelligent I/O
Analog
TxD4/SDA4/SRxD4
CLK4
ANEX1
CTS4/RTS4/SS4
DA1
DA0
CTS3/RTS3/SS3
TxD3/SDA3/SRxD3
RxD3/SCL3/STxD3
Bus control
ANEX0
OUTC20/IEOUT
IEIN
CLK3
P144
P143
P142
P141
INPC17/OUTC17
INPC16/OUTC16
OUTC15
P140
OUTC14
BYTE
CNVSS
XCIN/VCONT P87
XCOUT
RESET
XOUT
VSS
XIN
VCC
P86
P85
P84
P83
P82
P81
P80
P77
P76
P75
NMI
INT2
INT1
INT0
CANIN
CANOUT
P74
P73
P72
TA4IN/U
TA4OUT/U
TA3IN
TA3OUT
TA2IN/W
TA2OUT/W
TA1IN/V
TA1OUT/V
P71
P70
TB5IN/TA0IN
TA0OUT
CANIN
CANOUT
P67
CTS2/RTS2/SS2
CLK2
RxD2/SCL2/STxD2
TxD2/SDA2/SRxD2
TxD1/SDA1/SRxD1
P66
RxD1/SCL1/STxD1
P65
P64
P63
P62
P61
P60
P137
CLK1
CTS1/RTS1/SS1
TxD0/SDA0/SRxD0
RxD0/SCL0/STxD0
CLK0
CTS0/RTS0/SS0
OUTC32
OUTC30
INPC02/ISRxD0/BE0IN
INPC01/OUTC01/ISCLK0
INPC00/OUTC00/ISTxD0/BE0OUT
INPC12/OUTC12/ISRxD1/BE1IN
INPC11/OUTC11/ISCLK1
OUTC10/ISTxD1/BE1OUT
OUTC22/ISRxD2/IEIN
OUTC20/ISTxD2/IEOUT
VCC
VSS
OUTC21/ISCLK2
OUTC27
7
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.5. 144-pin version pin description (2/3)
Pin
No
Control
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
8
Port
Interrupt
Timer
UART/CAN
Intelligent I/O
P136
P135
P134
P57
P56
P55
P54
OUTC21/ISCLK2
OUTC22/ISRxD2/IEIN
P133
OUTC23
P132
OUTC26
P131
P130
P53
P52
P51
P50
P127
P126
P125
P47
P46
P45
P44
P43
OUTC25
OUTC24
Analog
Bus control
OUTC20/ISTxD2/IEOUT
RDY
ALE/RAS
HOLD
HLDA/ALE
VSS
VCC
CLKOUT/BCLK/ALE
RD/DW
WRH/BHE/CASH
WRL/WR/CASL
OUTC37
OUTC36
OUTC35
CS0/A23
CS1/A22
CS2/A21
CS3/A20(MA12)
A19(MA11)
VCC
P42
A18(MA10)
P41
P40
P37
P36
P35
P34
P33
P32
P31
P124
P123
P122
P121
P120
A17(MA9)
A16(MA8)
A15(MA7)(/D15)
A14(MA6)(/D14)
A13(MA5)(/D13)
A12(MA4)(/D12)
A11(MA3)(/D11)
A10(MA2)(/D10)
A9(MA1)(/D9)
VSS
OUTC34
OUTC33
OUTC32
OUTC31
OUTC30
VCC
P30
A8(MA0)(/D8)
VSS
P27
P26
P25
AN37
AN36
AN35
A7(/D7)
A6(/D6)
A5(/D5)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.6. 144-pin version pin description (3/3)
Pin
No
Control
97
Port
Interrupt Timer
UART/CAN
Intelligent I/O
Analog
Bus control
P24
P23
AN24
A4(/D4)
AN23
A3(/D3)
99
100
P22
AN22
A2(/D2)
P21
AN21
A1(/D1)
101
AN20
A0(/D0)
102
P20
P17
INT5
D15
103
P16
INT4
D14
104
P15
P14
INT3
D13
D12
98
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
P13
P12
P11
P10
P07
AN07
D11
D10
D9
D8
D7
P06
P05
AN06
AN05
D6
D5
P04
P114
P113
P112
P111
P110
P03
P02
P01
P00
P157
P156
P155
P154
P153
AN04
D4
D3
D2
D1
D0
INPC07
INPC06
INPC05/OUTC05
INPC04/OUTC04
INPC03
AN03
AN02
AN01
AN00
AN157
AN156
AN155
AN154
AN153
P152
INPC02/ISRxD0/BE0IN
AN152
P151
INPC01/OUTC01/ISCLK0
AN151
P150
INPC00/OUTC00/ISTxD0/BE0OUT
AN150
OUTC13
INPC12/OUTC12/ISRxD1/BE1IN
INPC11/OUTC11/ISCLK1
OUTC10/ISTxD1/BE1OUT
VSS
VCC
P107
P106
P105
KI3
P104
P103
KI0
AN7
AN6
AN5
KI2
KI1
AN4
AN3
P102
P101
AN2
AN1
P100
AN0
AVSS
VREF
AVCC
P97
RxD4/SCL4/STxD4
ADTRG
9
10
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
SS4 / RTS4 / CTS4 / TB4IN / DA1 / P94
SS3 / RTS3 / CTS3 / TB3IN / DA0 / P93
IEOUT / OUTC20 / SRxD3 / SDA3 / TxD3 / TB2IN / P92
IEIN / STxD3 / SCL3 / RxD3 / TB1IN / P91
CLK3 / TB0IN / P90
BYTE
CNVss
VCONT / XCIN / P87
XCOUT / P86
RESET
XOUT
Vss
XIN
Vcc
NMI / P85
INT2 / P84
CANIN / INT1 / P83
CANOUT / OUTC32 / INT0 / P82
OUTC30 / U / TA4IN / P81
BE0IN / ISRxD0 /INPC02 / U / TA4OUT / P80
CANIN / ISCLK0 / OUTC01 / INPC01 / TA3IN / P77
CANOUT / BE0OUT / ISTxD0 / OUTC00 / INPC00 / TA3OUT / P76
BE1IN / ISRxD1 / OUTC12 / INPC12 / W / TA2IN / P75
ISCLK1 / OUTC11 / INPC11 / W / TA2OUT / P74
BE1OUT / ISTxD1 / OUTC10 / SS2 / RTS2 / CTS2 / V / TA1IN / P73
CLK2 / V / TA1OUT / P72
IEIN / ISRxD2 / OUTC22 / STxD2 / SCL2 / RxD2 / TA0IN / TB5IN / P71
IEOUT / ISTxD2 / OUTC20 / SRxD2 / SDA2 / TxD2 / TA0OUT / P70
Note: P70 and P71 are N-channel open drain output.
1
STxD4 / SCL4 /
CLK4 / ANEX0 / P95
P27 / A7 ( / D7 ) / AN27
Vss
65
64
Figure 1.1.4. 100-pin version pin configuration (top view)
P42 / A18 ( MA10 )
P43 / A19 ( MA11 )
52
51
55
P40 / A16 ( MA8 )
P37 / A15 ( MA7 ) ( / D15 )
56
P41 / A17 ( MA9 )
P36 / A14 ( MA6 ) ( / D14 )
57
53
P35 / A13 ( MA5 ) ( / D13 )
58
Description
54
P33 / A11 ( MA3 ) ( / D11 )
P34 / A12 ( MA4 ) ( / D12 )
59
P32 / A10 ( MA2 ) ( / D10 )
P26 / A6 ( / D6 ) / AN26
66
P31 / A9 ( MA1 ) ( / D9 )
P25 / A5 ( / D5 ) / AN25
67
60
P24 / A4 ( / D4 ) / AN24
68
61
P23 / A3 ( / D3 ) / AN23
69
P30 / A8 ( MA0 ) ( / D8 )
P22 / A2 ( / D2 ) / AN22
70
Vcc
P21 / A1 ( / D1 ) / AN21
71
62
P20 / A0 ( / D0 ) / AN20
72
63
P17 / D15 / INT5
73
P14 / D12
76
P15 / D13 / INT3
P13 / D11
77
P16 / D14 / INT4
P12 / D10
78
74
P11 / D9
79
75
P10 / D8
80
t
SRxD4 / SDA4 / TxD4 / ANEX1 / P96
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
M32C/83 group
D7 / AN07 / P07
81
50
D6 / AN06 / P06
82
49
P45 / CS2 / A21
D5 / AN05 / P05
83
48
P46 / CS1 / A22
D4 / AN04 / P04
84
47
P47 / CS0 / A23
D3 / AN03 / P03
85
46
P50 / WRL / WR / CASL
D2 / AN02 / P02
86
45
P51 / WRH / BHE / CASH
D1 / AN01 / P01
87
44
P52 / RD / DW
D0 / AN00 / P00
88
43
P53 / CLKOUT / BCLK / ALE
KI3 / AN7 / P107
89
42
P54 / HLDA / ALE
KI2 / AN6 / P106
90
41
P55 / HOLD
KI1 / AN5 / P105
91
40
P56 / ALE / RAS
KI0 / AN4 / P104
92
39
P57 / RDY
AN3 / P103
93
38
P60 / CTS0 / RTS0 / SS0
AN2 / P102
94
37
P61 / CLK0
AN1 / P101
95
36
P62 / RxD0 / SCL0 / STxD0
AVss
96
35
P63 / TxD0 / SDA0 / SRxD0
AN0 / P100
97
34
P64 / CTS1 / RTS1 / SS1 / OUTC21 / ISCLK2
VREF
98
33
P65 / CLK1
AVcc
99
32
P66 / RxD1 / SCL1 / STxD1
RxD4 / ADTRG / P97
100
31
P67 / TxD1 / SDA1 / SRxD1
M32C/83 (100P6S-A)
P44 / CS3 / A20 (MA12)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
P33 / A11 ( MA3 ) ( / D11 )
P34 / A12 ( MA4 ) ( / D12 )
P35 / A13 ( MA5 ) ( / D13 )
P36 / A14 ( MA6 ) ( / D14 )
P37 / A15 ( MA7 ) ( / D15 )
P40 / A16 ( MA8 )
P41 / A17 ( MA9 )
55
54
53
52
51
Vss
62
56
P27 / A7 ( / D7 ) / AN27
63
P32 / A10 ( MA2 ) ( / D10 )
P26 / A6 ( / D6 ) / AN26
64
57
P25 / A5 ( / D5 ) / AN25
65
P31 / A9 ( MA1 ) ( / D9 )
P24 / A4 ( / D4 ) / AN24
66
58
P23 / A3 ( / D3 ) / AN23
67
59
P22 / A2 ( / D2 ) / AN22
68
P30 / A8 ( MA0 ) ( / D8 )
P21 / A1 ( / D1 ) / AN21
69
Vcc
P20 / A0 ( / D0 ) / AN20
70
60
P17 / D15 / INT5
71
61
P15 / D13 / INT3
P16 / D14 / INT4
72
P14 / D12
74
73
P13 / D11
75
Description
D10 / P12
76
50
P42 / A18 ( MA10 )
D9 / P11
77
49
P43 / A19 ( MA11 )
D8 / P10
78
48
P44 / CS3 / A20 (MA12)
D7 / AN07 / P07
79
47
P45 / CS2 / A21
D6 / AN06 / P06
80
46
P46 / CS1 / A22
D5 / AN05 / P05
81
45
P47 / CS0 / A23
D4 / AN04 / P04
82
44
P50 / WRL / WR / CASL
D3 / AN03 / P03
83
43
P51 / WRH / BHE / CASH
D2 / AN02 / P02
84
42
P52 / RD / DW
D1 / AN01 / P01
85
41
P53 / CLKOUT / BCLK / ALE
D0 / AN00 / P00
86
40
P54 / HLDA / ALE
KI3 / AN37 / P107
87
39
P55 / HOLD
KI2 / AN36 / P106
88
38
P56 / ALE / RAS
KI1 / AN35 / P105
89
37
P57 / RDY
KI0 / AN34 / P104
90
36
P60 / CTS0 / RTS0 / SS0
AN33 / P103
91
35
P61 / CLK0
AN32 / P102
92
34
P62 / RxD0 / SCL0 / STxD0
AN31 / P101
93
33
P63 / TxD0 / SDA0 / SRxD0
AVss
94
32
P64 / CTS1 / RTS1 / SS1 / OUTC21 / ISCLK2
AN30 / P100
95
31
P65 / CLK1
VREF
96
30
P66 / RxD1 / SCL1 / STxD1
AVcc
97
29
P67 / TxD1 / SDA1 / SRxD1
STxD4 / SCL4 / RxD4 / ADTRG / P97
98
28
SRxD4 / SDA4 / TxD4 / ANEX1 / P96
99
27
CLK4 / ANEX0 / P95
100
26
11
12
13
14
15
16
17
18
19
20
XOUT
Vss
XIN
Vcc
NMI / P85
INT2 / P84
CANIN / INT1 / P83
CANOUT / OUTC32 / INT0 / P82
OUTC30 / U / TA4IN / P81
BE0IN / ISRxD0 /INPC02 / U / TA4OUT / P80
25
10
RESET
BE1OUT / ISTxD1 / OUTC10 / SS2 / RTS2 / CTS2 / V / TA1IN / P73
9
XCOUT / P86
24
8
VCONT / XCIN / P87
ISCLK1 / OUTC11 / INPC11 / W / TA2OUT / P74
7
CNVss
23
6
BYTE
BE1IN / ISRxD1 / OUTC12 / INPC12 / W / TA2IN / P75
5
CLK3 / TB0IN / P90
22
4
IEIN / STxD3 / SCL3 / RxD3 / TB1IN / P91
21
3
IEOUT / OUTC20 / SRxD3 / SDA3 / TxD3 / TB2IN / P92
CANIN / ISCLK0 / OUTC01 / INPC01 / TA3IN / P77
2
SS3 / RTS3 / CTS3 / TB3IN / DA0 / P93
Note: P70 and P71 are N-channel open drain output.
CANOUT / BE0OUT / ISTxD0 / OUTC00 / INPC00 / TA3OUT / P76
1
SS4 / RTS4 / CTS4 / TB4IN / DA1 / P94
M32C/83 (100P6Q-A)
/ ISTxD2 / IEOUT
P70 / TA0OUT / TxD2 / SDA2 / SRxD2 / OUTC20
P71 / TA0IN / TB5IN / RxD2 / SCL2 / STxD2 / OUTC22
/ ISRxD2 / IEIN
P72 / TA1OUT / V / CLK2
Figure 1.1.5. 100-pin version pin configuration (top view)
11
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.7. 100-pin version pin description (1/2)
Package
Pin No
Control
Port
Interrupt
Timer
UART/CAN
Intelligent I/O
Analog
Bus control
FP GP
1
99
P96
2
3
100
1
P95
P94
TB4IN
TB3IN
4
2
P93
TB2IN
CTS4/RTS4/SS4
CTS3/RTS3/SS3
5
3
P92
TB1IN
TxD3/SDA3/SRxD3
6
7
4
5
P91
TB0IN
RxD3/SCL3/STxD3
8
6 BYTE
7 CNVSS
9
10
11
12
ANEX1
CLK4
ANEX0
DA1
8 XCIN/VCONT P87
P86
9 XCOUT
10 RESET
16
17
18
19
15
16
17
P85
20
18
P82
21
22
23
19
20
21
P81
TA4IN/U
TA4OUT/U
P80
TA3IN
P77
TA3OUT
CANIN
24
25
22
23
P76
TA2IN/W
TA2OUT/W
CANOUT
26
27
24
25
P74
P73
TA1IN/V
TA1OUT/V
28
29
26
27
P72
TB5IN/TA0IN
P71
TA0OUT
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
28
29
P70
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
P66
14
15
DA0
OUTC20/IEOUT
IEIN
CLK3
11 XOUT
12 VSS
13 XIN
14 VCC
13
12
P90
TxD4/SDA4/SRxD4
P84
P83
P75
P67
P65
P64
P63
P62
P61
P60
P57
P56
P55
P54
NMI
INT2
INT1
INT0
CANIN
CANOUT
CTS2/RTS2/SS2
CLK2
RxD2/SCL2/STxD2
TxD2/SDA2/SRxD2
OUTC32
OUTC30
INPC02/ISRxD0/BE0IN
INPC01/OUTC01/ISCLK0
INPC00/OUTC00/ISTxD0/BE0OUT
INPC12/OUTC12/ISRxD1/BE1IN
INPC11/OUTC11/ISCLK1
OUTC10/ISTxD1/BE1OUT
OUTC22/ISRxD2/IEIN
OUTC20/ISTxD2/IEOUT
TxD1/SDA1/SRxD1
RxD1/SCL1/STxD1
CLK1
CTS1/RTS1/SS1
TxD0/SDA0/SRxD0
RxD0/SCL0/STxD0
CLK0
CTS0/RTS0/SS0
OUTC21/ISCLK2
RDY
ALE/RAS
HOLD
HLDA/ALE
P53
P52
CLKOUT/BCLK/ALE
P51
WRH/BHE/CASH
P50
P47
WRL/WR/CASL
CS0/A23
P46
CS1/A22
P45
CS2/A21
P44
CS3/A20(MA12)
RD/DW
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.8. 100-pin version pin description (2/2)
Package
pin No
Control
Port
Interrupt Timer
UART/CAN
Intelligent I/O
Analog
Bus control
FP GP
51
52
53
49
50
51
54
55
56
57
58
59
60
61
52
53
54
55
56
57
58
59
62
63
64
65
66
60
61
62
63
64
67
65
68
69
70
71
72
66
67
68
69
70
73
74
71
72
75
76
77
78
73
74
75
76
79
80
81
77
78
79
82
83
84
85
86
87
80
81
82
83
84
85
88
89
90
91
86
87
88
89
92
93
94
95
96
97
98
90
91
92
93
94
95
96
99
100
97
98
P43
A19(MA11)
P42
P41
P40
A18(MA10)
A17(MA9)
A16(MA8)
A15(MA7)(/D15)
P37
P36
P35
A14(MA6)(/D14)
A13(MA5)(/D13)
A12(MA4)(/D12)
P34
P33
P32
P31
A11(MA3)(/D11)
A10(MA2)(/D10)
A9(MA1)(/D9)
P30
A8(MA0)(/D8)
VCC
VSS
P27
P26
P25
P24
AN27
AN26
AN25
AN24
P23
P22
P21
AN23
AN22
AN21
P20
P17
P16
P15
P14
AN20
INT5
INT4
INT3
A7(/D7)
A6(/D6)
A5(/D5)
A4(/D4)
A3(/D3)
A2(/D2)
A1(/D1)
A0(/D0)
D15
D14
D13
D12
P13
P12
P11
D11
D10
D9
P10
P07
AN07
D8
D7
P06
AN06
D6
P05
P04
P03
P02
AN05
AN04
AN03
AN02
D5
D4
D3
D2
P01
P00
P107
AN01
AN00
AN7
D1
D0
P106
P105
P104
P103
KI3
KI2
KI1
KI0
AN6
AN5
AN4
AN3
P102
AN2
P101
AN1
P100
AN0
AVSS
VREF
AVCC
P97
RxD4/SCL4/STxD4
ADTRG
13
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.9. Pin description (1/4)
Port
P0
P1
P2
P3
P4
14
Function
Pin name
I/O type
Description
Power supply
input
VCC
VSS
I
I
4.2 to 5.5 V or 3.0V to 3.6V.
0 V.
CPU mode switch
CNVSS
I
Connect it to VSS : Single-chip or memory expansion mode
Connect it to VCC : Microprocessor mode
External data
bus width
select input
BYTE
I
Selects the width of the data bus for external memory.
Connect it to VSS : A 16-bit width
Connect it to VCC : An 8-bit width
Reset input
RESET
I
A “L” on this input resets the microcomputer.
Clock input
XIN
I
Clock output
XOUT
O
These pins are provided for the main clock generating circuit.
Connect a ceramic resonator or crystal between the XIN and
the XOUT pins. To use an externally derived clock, input it to
the XIN pin and leave the XOUT pin open.
Analog power
supply input
AVCC
AVSS
I
I
Connect this pin to VCC.
Connect this pin to VSS.
Reference
voltage input
VREF
I
This pin is a reference voltage input for the A-D converter.
I/O port
P00 to P07
I/O
An 8-bit CMOS I/O port.
It has an input/output port direction register that allows the
user to set each pin for input or output individually.
The user can specify in units of four bits via software whether
or not they are tied to a pull-up resistor.
Data bus
D0 to D7
I/O
When set as a separate bus, these pins input and output 8
low-order data bits.
Analog input port
AN00 to AN07
I
P00 to P07 are analog input ports for the A-D converter.
I/O port
P10 to P17
External interrupt input
port
INT3 to INT5
Data bus
D8 to D15
I/O
When set as a separate bus, these pins input and output 8
high-order data bits.
I/O port
P20 to P27
I/O
This is an 8-bit I/O port equivalent to P0.
Address bus
A0 to A7
O
These pins output 8 low-order address bits.
Address bus/data bus
A0/D0 to
A7/D7
I/O
If a multiplexed bus is set, these pins input and output data and
output 8 low-order address bits separated in time by
multiplexing.
Analog input port
AN20 to AN27
I/O port
P30 to P37
I/O
This is an 8-bit I/O port equivalent to P0.
Address bus
A8 to A15
O
These pins output 8 middle-order address bits.
Address bus/data bus
A8/D8 to
A15/D15
I/O
If the external bus is set as a 16-bit wide multiplexed bus,
these pins output 8 middle-order address bits, and input and
output 8 middle-order data separated in time by multiplexing.
Address bus
MA0 to MA7
O
If accessing to DRAM area, these pins output row address
and column address separated in time by multiplexing.
I/O port
P40 to P47
I/O
This is an 8-bit I/O port equivalent to P0.
Address bus
A16 to A22
A23
O
These pins output 8 high-order address bits.
Highest address bit (A23) outputs inversely.
Chip select
CS0 to CS3
O
P40 to P47 are chip select output pins to specify access area.
Address bus
MA8 to MA12
O
If accessing to DRAM area, these pins output row address and
column address separated in time by multiplexing.
I/O
I
I
This is an 8-bit I/O port equivalent to P0.
P15 to P17 function as external interrupt pins.
P20 to P27 are analog input ports for the A-D converter.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.10. Pin description (2/4)
Function
Port
P5
P6
P7
Pin name
I/O type
Description
I/O port
P50 to P57
I/O
This is an 8-bit I/O port equivalent to P0.
Clock output
CLKOUT
I/O
P53 in this port outputs a divide-by-8 or divide-by-32 clock of
XIN or a clock of the same frequency as XCIN.
Bus control
WRL / WR,
WRH / BHE,
RD
O
O
O
BCLK,
HOLD,
O
I
HLDA
ALE,
RDY
O
O
I
Output WRL, WRH and RD, or WR, BHE and RD bus control
signals.
WRL, WRH, and RD selected
In 16-bit data bus, data is written to even addresses when the
WRL signal is “L”.
Data is written to odd addresses when the WRH signal is “L”.
Data is read when RD is “L”.
WR, BHE, and RD selected
Data is written when WR is “L”.
Data is read when RD is “L”.
Odd addresses are accessed when BHE is “L”. Even
addresses are accessed when BHE is “H”.
Use WR, BHE, and RD when all external memory is an 8-bit
data bus.
Output operation clock for CPU.
While the input level at the HOLD pin is “L”, the microcomputer
is placed in the hold state.
While in the hold state, HLDA outputs a “L” level.
ALE is used to latch the address.
While the input level of the RDY pin is “L”, the microcomputer
is in the ready state.
Bus control for DRAM
DW,
CASL,
CASH,
RAS
O
O
O
O
When DW signal is “L”, write to DRAM.
Timing signal when latching to line address of even address.
Timing signal when latching to line address of odd address.
Timing signal when latching to row address.
I/O port
P60 to P67
I/O
This is an 8-bit I/O port equivalent to P0.
UART port
I/O
P60 to P63 are I/O ports for UART0.
P64 to P67 are I/O ports for UART1.
Intelligent I/O port
CTS/RTS/SS
CLK
RxD/SCL/STxD
TxD/SDA/SRxD
OUTC/ISCLK
I/O
ISCLK is a clock I/O port for intelligent I/O communication.
OUTC is an output port for waveform generation function.
I/O port
P70 to P77
I/O
This is an 8-bit I/O port equivalent to P0.
However, P70 and P71 are N-channel open drain outputs.
Timer A port
O
I
I
P70 to P77 are I/O ports for timers A0–A3.
Timer B port
TAOUT
TAIN
TBIN
Three phase motor
control output port
V, V
W, W
O
P72 and P73 are V phase outputs.
P74 and P75 are W phase outputs.
UART port
CTS/RTS/SS
CLK
RxD/SCL/STxD
TxD/SDA/SRxD
INPC/OUTC
ISCLK/ISTxD/
ISRxD
IEOUT/IEIN
BEOUT/BEIN
I/O
P70 to P73 are I/O ports for UART2.
I/O
CAN
O
I
INPC is an input port for time measurement function.
OUTC is an output port for waveform generation function.
ISCLK is a clock I/O port for intelligent I/O communication.
ISTxD/IEOUT/BEOUT is transmit data output port for intelligent
I/O communication.
ISRxD/IEIN/BEIN is receive data input port for intelligent I/O
communication.
P76 and P77 are I/O ports for CAN communication function.
Intelligent I/O port
CANOUT
CANIN
P71 is an input port for timer B5.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.11. Pin description (3/4)
Port
Function
Pin name
I/O type
Description
P8
I/O port
P80-P84, P86, P87
I/O
Sub clock input
XCIN
I
Sub clock output
XCOUT
O
This is a 7-bit I/O port equivalent to P0.
P86 and P87 function as I/O ports for the sub clock
generating circuit by software. Connect a crystal between
the XCIN and the XCOUT pins.
When using PLL frequency synthesizer, connect P87 to a
low-pass filter. To stabilize PLL frequency, connect P86 to
Vss.
Low-pass filter connect VCOUT
pin for PLL frequency
synthesizer
Timer A port
TA4OUT
TA4IN
P9
O
O
I
P80 to P81 are I/O ports for timer A4.
Three phase motor
control output port
U, U
O
P80 and P81 are U phase output ports.
External interrupt input
port
INT0 to INT2
I
P82 to P84 are external interrupt input ports.
Intelligent I/O port
INPC/ISRxD/BEIN
I
Input port
P85/NMI
I
INPC is an input port for time measurement function.
ISRxD/BEIN is receive data input port for intelligent I/O
communication.
Input port and input ports for NMI interrupt.
I/O port
P90 to P97
Timer B port
TB0IN to TB4IN
I
UART port
CTS/RTS/SS
CLK
RxD/SCL/STxD
TxD/SDA/SRxD
I/O
I/O
I/O
I/O
P90 to P93 are I/O ports for UART3.
P94 to P97 are I/O ports for UART4.
D-A output port
DA0, DA1
O
P93 and P94 are D-A output ports.
A-D related port
ANEX1, ANEX2
ADTRG
OUTC/IEOUT
I
I
P95 to P96 are expanded input port for A-D converter.
P97 is A-D trigger input port.
OUTC is an output port for waveform generation function.
IEOUT is transmit data output port for intelligent I/O
communication.
IEIN is receive data input port for intelligent I/O
communication.
Intelligent I/O port
IEIN
I/O
I/O
I
This is an 8-bit I/O port equivalent to P0.
P90 to P94 are input port for timer B4.
The protect register prevents a false write to P9 direction register and function select register A3.
P10 I/O port
16
P100 to P107
I/O
This is an 8-bit I/O port equivalent to P0.
Key input interrupt port KI0 to KI3
I
P104 to P107 are key input interrupt ports.
Analog input port
I
P100 to P107 are analog input ports for A-D convertor.
AN0 to AN7
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Table 1.1.12. Pin description (4/4)
Port
Function
P11 I/O port
Intelligent I/O port
(Note)
P12 I/O port
Intelligent I/O port
(Note)
P13 I/O port
Intelligent I/O port
(Note)
P14 I/O port
Intelligent I/O port
(Note)
P15 I/O port
Intelligent I/O port
(Note)
Analog input port
Pin name
I/O type
Description
I/O
This is an 5-bit I/O port equivalent to P0.
INPC/OUTC
ISCLK
ISTxD/ISRxD
BEOUT/BEIN
I/O
I/O
I/O
INPC is an input port for time measurement function.
OUTC is an output port for waveform generation function.
ISCLK is a clock I/O port for intelligent I/O communication.
ISTxD/BEOUT is transmit data output port for intelligent I/O
communication.
ISRxD/BEIN is receive data input port for intelligent I/O
communication.
P110 to P114
P120 to P127
I/O
This is an 8-bit I/O port equivalent to P0.
OUTC
O
OUTC is an output port for waveform generation function.
P130 to P137
I/O
This is an 8-bit I/O port equivalent to P0.
OUTC
ISCLK/ISTxD/
ISRxD
IEOUT/IEIN
I/O
I/O
I/O
I/O
OUTC is an output port for waveform generation function.
ISCLK is a clock I/O port for intelligent I/O communication.
ISTxD/IEOUT is transmit data output port for intelligent I/O
communication.
ISRxD/IEIN is receive data input port for intelligent I/O
communication.
P140 to P146
I/O
This is a 7-bit I/O port equivalent to P0.
INPC/OUTC
I/O
INPC is an input port for time measurement function.
OUTC is an output port for waveform generation function.
P150 to P157
I/O
This is an 8-bit I/O port equivalent to P0.
INPC/OUTC
ISCLK/ISTxD/
ISRxD
BEOUT/BEIN
I/O
I/O
INPC is an input port for time measurement function.
OUTC is an output port for waveform generation function.
ISCLK is a clock I/O port for intelligent I/O communication.
ISTxD/BEOUT is transmit data output port for intelligent I/O
communication.
ISRxD/BEIN is receive data input port for intelligent I/O
communication.
AN150 to AN157
I/O
I
P150 to P157 are analog input ports for A-D convertor.
Note :Port P11 to P15 exist in 144-pin version.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Block Diagram
The M32C/83 group includes the following devices in a single-chip. ROM and RAM for code instructions
and data, storage, CPU for executing operation and peripheral functions such as timer, serial I/O, D-A
converter, DMAC, CRC operation circuit, A-D converter, DRAM controller, intelligent I/O and I/O ports.
Figure 1.1.6 is a block diagram of the M32C/83 group (144-pin version).
8
8
Port P0
8
Port P1
8
Port P2
8
Port P3
8
Port P4
8
Port P5
8
Port P6
Port P7
I/O ports
Internal peripheral functions
A-D converter
(10-bit X 2 circuits)
Timer (16 bits)
Input (6)
Timer B0
Timer B1
Timer B2
Timer B3
Timer B4
Timer B5
Output (5)
Timer A0
Timer A1
Timer A2
Timer A3
Timer A4
System clock generator
XIN - XOUT
XCIN - XCOUT
Ring oscillator
UART/Clock synchronous
SI/O (8-bit X 5 channels)
Memory (Note)
X-Y converter
(16-bit X 16-bit)
Three-phase control
circuit
ROM
Watchdog timer (15 bits)
Intelligent I/O
CRC arithmetic circuit
(CCITT)
RAM
M32C/80 series CPU core
Group 0
Group 1
Group 2
Group 3
D-A converter
(8-bit X 2 circuit)
R0H
R0L
R1H
R1L
FLG
R2
ISP
R3
USP
A0
Port P15
8
Port P14
7
Port P13
8
Port P12
8
DMA II
controller
PC
A1
CAN communication
function
DRAM
controller
SVF
FB
SVP
SB
VCT
Port P11
5
Port P10
Multiplier
Port P9
8
Figure 1.1.6. Block diagram of the M32C/83 group (144-pin version)
18
DMA
controller
INTB
8
P85
Port P8
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description
Memory
Figure 1.2.1 is a memory map of the M32C/83 group. The address space extends 16 Mbytes from address
00000016 to FFFFFF16. From FFFFFF16 down is ROM. For example, in the M30835FJGP, there are 512K
bytes of internal ROM from F8000016 to FFFFFF16. The vector table for fixed interrupts such as the reset
_______
and NMI are mapped to FFFFDC16 to FFFFFF16. The starting address of the interrupt routine is stored
here. The address of the vector table for timer interrupts, etc., can be set as desired using the internal
register (INTB). See the section on interrupts for details.
From 00040016 up is RAM. For example, in the M30835FJGP, 31 Kbytes of internal RAM are mapped to
the space from 00040016 to 007FFF16. In addition to storing data, the RAM also stores the stack used when
calling subroutines and when interrupts are generated.
The SFR area is mapped from 00000016 to 0003FF16. This area accommodates the control registers for
peripheral devices such as I/O ports, A-D converter, serial I/O, and timers, etc. Any part of the SFR area
that is not occupied is reserved and cannot be used for any other purpose.
The special page vector table is mapped from FFFE0016 to FFFFDB16. If the starting addresses of subroutines or the destination addresses of jumps are stored here, subroutine call instructions and jump instructions can be used as 2-byte instructions, reducing the number of program steps.
In memory expansion mode and microprocessor mode, a part of the spaces are reserved and cannot be
used.
00000016
SFR area
00040016
Internal RAM
area
XXXXXX16
AAAAA
AAAAA
AAAAA
AAAAA
FFFE0016
Internal reserved
area (Note 1)
00800016
Special page
vector table
External area
F0000016
FFFFDC16
Overflow
BRK instruction
Address match
Internal reserved
area (Note 2)
Watchdog timer
YYYYYY16
Type No.
M30835F/MJ
M30833F/MJ
Address
XXXXX16
Address
YYYYY16
007FFF16
F8000016
Internal ROM
area
FFFFFF16
Undefined instruction
FFFFFF16
NMI
Reset
Note 1: During memory expansion and microprocessor modes, can not be used.
Note 2: In memory expansion mode, can not be used.
Figure 1.2.1. Memory map
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Software Reset
Central Processing Unit (CPU)
The CPU has a total of 28 registers shown in Figure 1.3.1. Eight of these registers (R0, R1, R2, R3, A0, A1,
SB and FB) come in two sets; therefore, these have two register banks.
General register
b15
b0
FLG
b31
Flag register
R2
R0H
R0L
R3
R1H
R1L
Data register (Note)
R2
R3
b23
A0
Address register (Note)
A1
SB
Static base register (Note)
FB
Frame base register (Note)
USP
User stack pointer
ISP
Interrupt stack pointer
INTB
Interrupt table register
Program counter
PC
High-speed interrupt register
b15
b0
SVF
b23
Flag save register
SVP
PC save register
VCT
Vector register
DMAC related register
b7
b0
DMD0
DMD1
b15
DMA mode register
DCT0
DMA transfer count register
DCT1
DRC0
b23
DRC1
DMA transfer count reload register
DMA0
DMA1
DMA memory address register
DSA0
DSA1
DMA SFR address register
DRA0
DRA1
Note: These registers have two register banks.
Figure 1.3.1. Central processing unit register
20
DMA memory address reload register
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Processor Mode
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
(1) Data registers (R0, R0H, R0L, R1, R1H, R1L, R2, R3, R2R0 and R3R1)
Data registers (R0, R1, R2, and R3) are configured with 16 bits, and are used primarily for transfer and
arithmetic/logic operations.
Registers R0 and R1 each can be used as separate 8-bit data registers, high-order bits as (R0H/R1H),
and low-order bits as (R0L/R1L). Registers R2 and R0, as well as R3 and R1 can function as 32-bit data
registers (R2R0/R3R1).
(2) Address registers (A0 and A1)
Address registers (A0 and A1) are configured with 24 bits, and have functions equivalent to those of data
registers. These registers can also function as address register, indirect addressing and address register
relative addressing.
(3) Static base register (SB)
Static base register (SB) is configured with 24 bits, and is used for SB relative addressing.
(4) Frame base register (FB)
Frame base register (FB) is configured with 24 bits, and is used for FB relative addressing.
(5) Program counter (PC)
Program counter (PC) is configured with 24 bits, indicating the address of an instruction to be executed.
(6) Interrupt table register (INTB)
Interrupt table register (INTB) is configured with 24 bits, indicating the start address of an interrupt vector
table.
(7) User stack pointer (USP), interrupt stack pointer (ISP)
Stack pointer comes in two types: user stack pointer (USP) and interrupt stack pointer (ISP), each configured with 24 bits.
The desired type of stack pointer (USP or ISP) can be selected by a stack pointer select flag (U flag). This
flag is located at bit 7 in the flag register (FLG).
To execute efficienly set USP and ISP to an even number.
(8) Save flag register (SVF)
This register consists of 16 bits and is used to save the flag register when a high-speed interrupt is
generated.
(9) Save PC register (SVP)
This register consists of 24 bits and is used to save the program counter when a high-speed interrupt is
generated.
This register consist of 24 bits and is used to indicate a jump address when a high-speed interrupt is
generated.
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Processor Mode
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
(10) Vector register (VCT)
This register consists of 24 bits and is used to indicate the jump address when a high-speed interrupt is
generated.
(11) DMA mode registers (DMD0/DMD1)
These registers consist of 8 bits and are used to set the transfer mode, etc. for DMA.
(12) DMA transfer count registers (DCT0/DCT1)
These registers consist of 16 bits and are used to set the number of DMA transfers performed.
(13) DMA transfer count reload registers (DRC0/DRC1)
These registers consist of 16 bits and are used to reload the DMA transfer count registers.
(14) DMA memory address registers (DMA0/DMA1)
These registers consist of 24 bits and are used to set a memory address at the source or destination of
DMA transfer.
(15) DMA SFR address registers (DSA0/DSA1)
These registers consist of 24 bits and are used to set a fixed address at the source or destination of DMA
transfer.
(16) DMA memory address reload registers (DRA0/DRA1)
These registers consist of 24 bits and are used to reload the DMA memory address registers.
(17) Flag register (FLG)
Flag register (FLG) is configured with 11 bits, each bit is used as a flag. Figure 1.3.2 shows the flag
register (FLG). The following explains the function of each flag:
• Bit 0: Carry flag (C)
This flag retains a carry, borrow, or shift-out bit that has occurred in the arithmetic/logic unit.
• Bit 1: Debug flag (D)
This flag enables a single-step interrupt.
When this flag is “1”, a single-step interrupt is generated after instruction execution. This flag is
cleared to “0” when the interrupt is acknowledged.
• Bit 2: Zero flag (Z)
This flag is set to “1” when an arithmetic operation resulted in 0; otherwise, cleared to “0”.
• Bit 3: Sign flag (S)
This flag is set to “1” when an arithmetic operation resulted in a negative value; otherwise, cleared to
“0”.
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Mitsubishi Microcomputers
M32C/83 group
Processor Mode
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
• Bit 4: Register bank select flag (B)
This flag chooses a register bank. Register bank 0 is selected when this flag is “0” ; register bank 1 is
selected when this flag is “1”.
• Bit 5: Overflow flag (O)
This flag is set to “1” when an arithmetic operation resulted in overflow; otherwise, cleared to “0”.
• Bit 6: Interrupt enable flag (I)
This flag enables a maskable interrupt.
An interrupt is disabled when this flag is “0”, and is enabled when this flag is “1”. This flag is cleared to
“0” when the interrupt is acknowledged.
• Bit 7: Stack pointer select flag (U)
Interrupt stack pointer (ISP) is selected when this flag is “0” ; user stack pointer (USP) is selected
when this flag is “1”.
This flag is cleared to “0” when a hardware interrupt is acknowledged or an INT instruction of software
interrupt Numbers. 0 to 31 is executed.
• Bits 8 to 11: Reserved area
• Bits 12 to 14: Processor interrupt priority level (IPL)
Processor interrupt priority level (IPL) is configured with three bits, for specification of up to eight
processor interrupt priority levels from level 0 to level 7.
If a requested interrupt has priority greater than the processor interrupt priority level (IPL), the interrupt
is enabled.
• Bit 15: Reserved area
AA
AAAAAAA
AA
A
AA
AA
AA
A
AA
AA
AAAAAAAAA
AA
A
AAAAAAAA
AAA
b15
b0
IPL
U
I
O B S Z D C
Flag register (FLG)
Carry flag
Debug flag
Zero flag
Sign flag
Register bank select flag
Overflow flag
Interrupt enable flag
Stack pointer select flag
Reserved area
Processor interrupt priority level
Reserved area
Figure 1.3.2. Flag register (FLG)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
Reset
There are two kinds of resets; hardware and software. In both cases, operation is the same after the reset.
(See “Software Reset” for details of software resets.) This section explains hardware resets.
When the supply voltage is in the range where operation is guaranteed, a reset is enabled by holding the
reset pin Low (0.2VCC max.) for at least 20 cycles. When the reset pin level is then returned to High while
main clock is stable, the reset status is cancelled and program execution resumes from the address in the
reset vector table.
Since the value of RAM is indeterminate when power is applied, the initial values must be set. Also, if a
reset signal is input during write to RAM, the access to the RAM will be interrupted. Consequently, the value
of the RAM being written may change to an unintended value due to the interruption.
Figure 1.4.1 shows the example reset circuit. Figure 1.4.2 shows the reset sequence.
____________
Table 1.4.1 shows the status of other pins while the RESET pin level is Low. Figures 1.4.3 and 1.4.4 show
the internal status of the microcomputer immediately after the reset is cancelled.
5V
4.2V
VCC
RESET
VCC
0V
5V
RESET
0.8V
0V
Example when VCC = 5V.
Figure 1.4.1. Example reset circuit
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
XIN
More than 20 cycles are needed
Microprocessor
mode BYTE = “H”
RESET
BCLK
24cycles
BCLK
Content of reset vector
Address
FFFFC16
FFFFD16
FFFFE16
RD
WR
CS0
Microprocessor
mode BYTE = “L”
Address
Content of reset vector
FFFFC16
FFFFE16
RD
WR
CS0
Single chip
mode
FFFFC16
Content of reset vector
Address
FFFFE16
Figure 1.4.2. Reset sequence
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
____________
Table 1.4.1. Pin status when RESET pin level is “L”
Status
Pin name
CNVSS = VCC
CNVSS = VSS
BYTE = VSS
P0
Input port (floating)
Data input (floating)
P1
Input port (floating)
Data input (floating)
P2, P3, P4
Input port (floating)
Address output (undefined)
P50
Input port (floating)
WR output (“H” level output)
P51
Input port (floating)
BHE output (undefined)
P52
Input port (floating)
RD output (“H” level output)
P53
Input port (floating)
BCLK output
P54
Input port (floating)
HLDA output (The output value depends on the input to the
HOLD pin)
P55
Input port (floating)
HOLD input (floating)
P56
Input port (floating)
RAS output
P57
Input port (floating)
RDY input (floating)
P6 to P15 (Note)
Input port (floating)
Input port (floating)
Note :Port P11 to P15 exists in 144-pin version.
26
BYTE = VCC
Input port (floating)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(000416)
(26) UART2 receive /ACK interrupt control register (006B16) X X X X ? 0 0 0
(1)
Processor mode register 0
(2)
Processor mode register 1
(000516) X 0 0 0 0 0 X X
(27) Timer A0 interrupt control register
(3)
System clock control register 0
(000616) 0 0 0 0 X 0 0 0
(28) UART3 receive/ACK interrupt control register (006D16) X X X X ? 0 0 0
(4)
System clock control register 1
(000716)
2016
(29) Timer A2 interrupt control register
(006E16) X X X X ? 0 0 0
(5)
Wait control register
(000816)
FF16
(30) UART4 receive/ACK interrupt control register
(006F16) X X X X ? 0 0 0
(6)
Address match interrupt control register
(000916) X X X X 0 0 0 0
(31) Timer A4 interrupt control register
(007016) X X X X ? 0 0 0
(7)
Protect register
(000A16) X X X X 0 0 0 0
(32) UART0/UART3 bus collision detection interrupt
control register
(007116) X X X X ? 0 0 0
(8)
External data bus width control register
(33) UART0 receive/ACK interrupt control register
(007216) X X X X ? 0 0 0
(9)
Main clock divided register
(000C16) X X X 0 1 0 0 0
(34) A-D0 interrupt control register
(007316) X X X X ? 0 0 0
(10) Oscillation stop detect register
(000D16)
0016
(35) UART1 receive/ACK interrupt control register (007416) X X X X ? 0 0 0
(11) Watchdog timer start register
(000E16)
??16
(36) Intelligent I/O interrupt control register 0
(007516) X X X X ? 0 0 0
(12) Watchdog timer control register
(000F16) 0 0 0 ? ? ? ? ?
(37) Timer B1 interrupt control register
(007616) X X X X ? 0 0 0
(13) Address match interrupt register 0
(001016)
0016
(38) Intelligent I/O interrupt control register 2
(007716) X X X X ? 0 0 0
(001116)
0016
(39) Timer B3 interrupt control register
(007816) X X X X ? 0 0 0
(001216)
0016
(40) Intelligent I/O interrupt control register 4
(007916) X X X X ? 0 0 0
(001416)
0016
(41) INT5 interrupt control register
(007A16) X X 0 0 ? 0 0 0
(001516)
0016
(42) Intelligent I/O interrupt control register 6
(007B16) X X X X ? 0 0 0
(001616)
0016
(43) INT3 interrupt control register
(007C16) X X 0 0 ? 0 0 0
(44) Intelligent I/O interrupt control register 8
(007D16) X X X X ? 0 0 0
0016
(45) INT1 interrupt control register
(007E16) X X 0 0 ? 0 0 0
0016
Intelligent I/O interrupt control register 10/
(46)
CAN interrupt 1 control register
(007F16) X X X X ? 0 0 0
(001A16)
0016
(47) Intelligent I/O interrupt control register 11/
CAN interrupt 2 control register
(008116) X X X X ? 0 0 0
(17) VDD control register 1
(001B16)
0016
(48) A -D1 interrupt control register
(008616) X X X X ? 0 0 0
(18) Address match interrupt register 3
(001C16)
0016
(49) DMA1 interrupt control register
(008816) X X X X ? 0 0 0
(001D16)
0016
(50) UART2 transmit /NACK interrupt control register (008916) X X X X ? 0 0 0
(001E16)
0016
(51) DMA3 interrupt control register
(19) VDD control register 1
(001F16)
0016
(52) UART3 transmit /NACK interrupt control register (008B16) X X X X ? 0 0 0
(20) DRAM control register
(004016) ? X X X ? ? ? ?
(21) DRAM refresh interval set register
(004116)
(22) Flash memory control register 0
(005716) X X 0 0 0 0 0 1
(55) Timer A3 interrupt control register
(23) DMA0 interrupt control register
(006816) X X X X ? 0 0 0
(56) UART2 bus collision detection interrupt (008F16) X X X X ? 0 0 0
control register
(24) Timer B5 interrupt control register
(006916) X X X X ? 0 0 0
(57) UART0 transmit /NACK interrupt control register (009016) X X X X ? 0 0 0
(25) DMA2 interrupt control register
(006A16) X X X X ? 0 0 0
(58) UART1/UART4 bus collision detection
interrupt control register
(14) Address match interrupt register 1
(Note 1)
(Note 2) (000B16)
8016
XXXXX0 0 0
(15) VDC control register for PLL
(001716) X X X X X X 0 1
(16) Address match interrupt register 2
(001816)
(001916)
??16
(53) Timer A1 interrupt control register
(006C16) X X X X ? 0 0 0
(008A16) X X X X ? 0 0 0
(008C16) X X X X ? 0 0 0
(54) UART4 transmit /NACK interrupt control register (008D16) X X X X ? 0 0 0
(008E16) X X X X ? 0 0 0
(009116) X X X X ? 0 0 0
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Note 1: When the VCC level is applied to the CNVSS pin, it is 0316 at a reset.
Note 2: When the BYTE pin is "L", bit 3 is "1". When the BYTE pin is "H", bit 3 is "0".
Figure 1.4.3. Device's internal status after a reset is cleared (1/10)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(59) UART1 transmit/NACK interrupt control register (009216) X X X X ? 0 0 0
(92)
Interrupt enable register 7
(00B716) 0 X X 0 0 0 0 0
(60) Key input interrupt control register
(009316) X X X X ? 0 0 0
(93)
Interrupt enable register 8
(00B816) 0 0 X 0 0 0 0 0
(61) Timer B0 interrupt control register
(009416) X X X X ? 0 0 0
(94)
Interrupt enable register 9
(00B916) 0 X X X 0 0 0 0
(62) Intelligent I/O interrupt control register 1
(009516) X X X X ? 0 0 0
(95)
Interrupt enable register 10
(00BA16) 0 X X X 0 0 0 0
(63) Timer B2 interrupt control register
(009616) X X X X ? 0 0 0
(96)
Interrupt enable register 11
(00BB16) 0 X X 0 0 0 0 0
(64) Intelligent I/O interrupt control register 3
(009716) X X X X ? 0 0 0
(97)
Group 0 time measurement/waveform
generate register 0
(00C016)
??16
(65) Timer B4 interrupt control register
(009816) X X X X ? 0 0 0
(00C116)
??16
(66) Intelligent I/O interrupt control register 5
(009916) X X X X ? 0 0 0
(00C216)
??16
(67) INT4 interrupt control register
(009A16) X X 0 0 ? 0 0 0
(00C316)
??16
(68) Intelligent I/O interrupt control register 7
(009B16) X X X X ? 0 0 0
(00C416)
??16
(69) INT2 interrupt control register
(009C16) X X 0 0 ? 0 0 0
(00C516)
??16
(70) Intelligent I/O interrupt control register 9/
CAN interrupt 0 control register
(009D16) X X X X ? 0 0 0
(00C616)
??16
(71) INT0 interrupt control register
(009E16) X X 0 0 ? 0 0 0
(00C716)
??16
(72) Exit priority register
(009F16) X X 0 X 0 0 0 0
(00C816)
??16
(00C916)
??16
(00CA16)
??16
(00CB16)
??16
(00CC16)
??16
(00CD16)
??16
(00CE16)
??16
(00CF16)
??16
(98)
(99)
Group 0 time measurement/waveform
generate register 1
Group 0 time measurement/waveform
generate register 2
(100) Group 0 time measurement/waveform
generate register 3
(101) Group 0 time measurement/waveform
generate register 4
(73) Interrupt request register 0
(00A016) X X 0 0 X 0 0 X
(74) Interrupt request register 1
(00A116) X X 0 0 X 0 0 X
(102) Group 0 time measurement/waveform
generate register 5
(75) Interrupt request register 2
(00A216) X X 0 0 X 0 X X
(76) Interrupt request register 3
(00A316) X X 0 0 0 0 0 X
(103) Group 0 time measurement/waveform
generate register 6
(77) Interrupt request register 4
(00A416) 0 0 X 0 0 0 0 X
(78) Interrupt request register 5
(00A516) X X X 0 0 0 0 X
(104) Group 0 time measurement/waveform
generate register 7
(79) Interrupt request register 6
(00A616) X X X 0 0 0 0 X
(80) Interrupt request register 7
(00A716) 0 X X 0 0 0 0 X
(105) Group 0 waveform generate control register 0
(00D016) 0 X 0 0 X 0 0 0
(81) Interrupt request register 8
(00A816) 0 0 X 0 0 0 0 X
(106) Group 0 waveform generate control register 1
(00D116) 0 X 0 0 X 0 0 0
(82) Interrupt request register 9
(00A916) 0 X X 0 0 0 0 X
(107) Group 0 waveform generate control register 4
(00D416) 0 X 0 0 X 0 0 0
(83) Interrupt request register 10
(00AA16) 0 X X 0 0 0 0 X
(108) Group 0 waveform generate control register 5
(00D516) 0 X 0 0 X 0 0 0
(84) Interrupt request register 11
(00AB16) 0 X X 0 0 0 0 X
(109) Group 0 time measurement control register 0
(00D816)
0016
(85) Interrupt enable register 0
(00B016) X X 0 0 X 0 0 0
(110) Group 0 time measurement control register 1
(00D916)
0016
(86) Interrupt enable register 1
(00B116) X X 0 0 X 0 0 0
(111) Group 0 time measurement control register 2
(00DA16)
0016
(87) Interrupt enable register 2
(00B216) X X 0 0 X 0 X 0
(112) Group 0 time measurement control register 3
(00DB16)
0016
(88) Interrupt enable register 3
(00B316) X X 0 0 0 0 0 0
(113) Group 0 time measurement control register 4
(00DC16)
0016
(89) Interrupt enable register 4
(00B416) 0 0 X 0 0 0 0 0
(114) Group 0 time measurement control register 5
(00DD16)
0016
(90) Interrupt enable register 5
(00B516) X X X 0 0 0 0 0
(115) Group 0 time measurement control register 6
(00DE16)
0016
(91) Interrupt enable register 6
(00B616) X X X 0 0 0 0 0
(116) Group 0 time measurement control register 7
(00DF16)
0016
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Figure 1.4.3. Device's internal status after a reset is cleared (2/10)
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(117) Group 0 base timer register
Mitsubishi Microcomputers
(00E016)
??16
(144) Group 1 time measurement/waveform
(010416)
??16
(010516)
??16
(010616)
??16
(010716)
??16
(010816)
??16
(010916)
??16
(010A16)
??16
(010B16)
??16
(010C16)
??16
(010D16)
??16
(010E16)
??16
(010F16)
??16
generate register 2
(118) Group 0 base timer control register 0
(00E116)
??16
(00E216)
0016
(145) Group 1 time measurement/waveform
generate register 3
(119) Group 0 base timer control register 1
(00E316)
0016
(120) Group 0 time measurement prescaler register 6 (00E416)
0016
(146) Group 1 time measurement/waveform
generate register 4
(121) Group 0 time measurement prescaler register 7 (00E516)
0016
(122) Group 0 function enable register
0016
(00E616)
(147) Group 1 time measurement/waveform
generate register 5
(123) Group 0 function select register
(00E716)
0016
(124) Group 0 SI/O receive buffer register
(00E816)
??16
(148) Group 1 time measurement/waveform
generate register 6
(00E916) X 0 0 0 X X X X
(125) Group 0 transmit buffer/receive data register (00EA16)
??16
(149) Group 1 time measurement/waveform
generate register 7
(126) Group 0 receive input register
(00EC16)
??16
(127) Group 0 SI/O communication mode register (00ED16)
0016
(150) Group 1 waveform generate control register 0 (011016) 0 X 0 0 X 0 0 0
(128) Group 0 transmit output register
??16
(151) Group 1 waveform generate control register 1 (011116) 0 X 0 0 X 0 0 0
(00EE16)
(129) Group 0 SI/O communication control register (00EF16) 0 0 0 0 X 0 1 1
(152) Group 1 waveform generate control register 2 (011216) 0 X 0 0 X 0 0 0
(130) Group 0 data compare register 0
(00F016)
??16
(153) Group 1 waveform generate control register 3 (011316) 0 X 0 0 X 0 0 0
(131) Group 0 data compare register 1
(00F116)
??16
(154) Group 1 waveform generate control register 4 (011416) 0 X 0 0 X 0 0 0
(132) Group 0 data compare register 2
(00F216)
??16
(155) Group 1 waveform generate control register 5 (011516) 0 X 0 0 X 0 0 0
(133) Group 0 data compare register 3
(00F316)
??16
(156) Group 1 waveform generate control register 6 (011616) 0 X 0 0 X 0 0 0
(134) Group 0 data mask register 0
(00F416)
??16
(157) Group 1 waveform generate control register 7 (011716) 0 X 0 0 X 0 0 0
(135) Group 0 data mask register 1
(00F516)
??16
(158) Group 1 time measurement control register 1 (011916)
0016
(136) Group 0 receive CRC code register
(00F816)
??16
(159) Group 1 time measurement control register 2 (011A16)
0016
(00F916)
??16
(160) Group 1 time measurement control register 6 (011E16)
0016
(00FA16)
0016
(161) Group 1 time measurement control register 7 (011F16)
0016
(00FB16)
0016
(162) Group 1 base timer register
(012016)
??16
(00FC16)
0016
(012116)
??16
(139) Group 0 SI/O expansion receive control register (00FD16)
0016
(163) Group 1 base timer control register 0
(012216)
0016
(164) Group 1 base timer control register 1
(012316)
0016
(137) Group 0 transmit CRC code register
(138) Group 0 SI/O expansion mode register
(140) Group 0 SI/O special communication
interrupt detect register
(141) Group 0 SI/O expansion transmit
control register
(142) Group 1 time measurement/waveform
generate register 0
(143) Group 1 time measurement/waveform
(00FE16) 0 0 0 0 0 0 X X
(00FF16) 0 0 0 0 0 X X X
(010016)
??16
(010116)
??16
(010216)
??16
(010316)
??16
generate register 1
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Figure 1.4.3. Device's internal status after a reset is cleared (3/10)
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(165) Group 1 time measurement prescaler register 6 (012416)
0016
(166) Group 1 time measurement prescaler register 7 (012516)
0016
(167) Group 1 function enable register
(012616)
0016
(168) Group 1 function select register
(012716)
0016
(169) Group 1 SI/O receive buffer register
(012816)
??16
(191) Group 2 waveform generate register 4
(192) Group 2 waveform generate register 5
(193) Group 2 waveform generate register 6
(012916) X 0 0 0 X X X X
(194) Group 2 waveform generate register 7
??16
(014916)
??16
(014A16)
??16
(014B16)
??16
(014C16)
??16
(014D16)
??16
(014E16)
??16
(170) Group 1 transmit buffer/receive data register (012A16)
??16
(012C16)
??16
(014F16)
??16
(172) Group 1 SI/O communication mode register (012D16)
0016
(195) Group 2 waveform generate control register 0 (015016)
0016
(012E16)
??16
(196) Group 2 waveform generate control register 1 (015116)
0016
(197) Group 2 waveform generate control register 2 (015216)
0016
(171) Group 1 receive input register
(173) Group 1 transmit output register
(174) Group 1 SI/O communication control register (012F16) 0 0 0 0 X 0 1 1
(175) Group 1 data compare register 0
(013016)
??16
(198) Group 2 waveform generate control register 3 (015316)
0016
(176) Group 1 data compare register 1
(013116)
??16
(199) Group 2 waveform generate control register 4 (015416)
0016
(177) Group 1 data compare register 2
(013216)
??16
(200) Group 2 waveform generate control register 5 (015516)
0016
(178) Group 1 data compare register 3
(013316)
??16
(201) Group 2 waveform generate control register 6 (015616)
0016
(179) Group 1 data mask register 0
(013416)
??16
(202) Group 2 waveform generate control register 7 (015716)
0016
(180) Group 1 data mask register 1
(013516)
??16
(203) Group 2 base timer register
(016016)
??16
(181) Group 1 receive CRC code register
(013816)
??16
(016116)
??16
(013916)
??16
(204) Group 2 base timer control register 0
(016216)
0016
(013A16)
0016
(205) Group 2 base timer control register 1
(016316)
0016
(013B16)
0016
(206) Base timer start register
(016416) X X X X 0 0 0 0
(013C16)
0016
(207) Group 2 function enable register
(016616)
0016
(184) Group 1 SI/O expansion receive control register (013D16)
0016
(208) Group 2 RTP output buffer register
(016716)
0016
(182) Group 1 transmit CRC code register
(183) Group 1 SI/O expansion mode register
(013E16) 0 0 0 0 0 0 X X
interrupt detect register
(186) Group 1 SI/O expansion transmit control register (013F16) 0 0 0 0 0 X X X
(185) Group 1 SI/O special communication
(187) Group 2 waveform generate register 0
(188) Group 2 waveform generate register 1
(189) Group 2 waveform generate register 2
(190) Group 2 waveform generate register 3
(014016)
??16
(014116)
??16
(014216)
??16
(014316)
??16
(014416)
??16
(014516)
??16
(014616)
??16
(014716)
??16
(209) Group 2 SI/O communication mode register (016A16) 0 0 XX X 0 0 0
(210) Group 2 SI/O communication control register (016B16) 0 0 0 0 X 1 1 0
(211) Group 2 SI/O transmit buffer register
(016C16)
??16
(016D16) ? ? ? X X ? ? ?
(212) Group 2 SI/O receive buffer register
(016E16)
??16
(016F16) X XX ? X XX X
(213) Group 2 IEBus address register
(017016)
??16
(017116) X XXX ? ? ? ?
(214) Group 2 IEBus control register
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Figure 1.4.3. Device's internal status after a reset is cleared (4/10)
30
(014816)
(017216) 0 0 XX X 0 0 0
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(215) Group 2 IEBus transmit interrupt
cause detect register
(017316) X XX 0 0 0 0 0
(238) Group 3 waveform generate mask register 4 (019816)
??16
(216) Group 2 IEBus receive interrupt
cause detect register
(017416) X XX 0 0 0 0 0
(019916)
??16
(217) Input function select register
(017816)
(239) Group 3 waveform generate mask register 5 (019A16)
??16
(218) Group 3 SI/O communication mode register (017A16) 0 0 XX 0 0 0 0
(019B16)
??16
(219) Group 3 SI/O communication control register (017B16) 0 0 ? 0 X ? ? 0
(240) Group 3 waveform generate mask register 6 (019C16)
??16
(220) Group 3 SI/O transmit buffer register
(221) Group 3 SI/O receive buffer register
(222) Group 3 waveform generate register 0
(223) Group 3 waveform generate register 1
(224) Group 3 waveform generate register 2
(225) Group 3 waveform generate register 3
(226) Group 3 waveform generate register 4
(227) Group 3 waveform generate register 5
0016
(017C16)
??16
(019D16)
??16
(017D16)
??16
(241) Group 3 waveform generate mask register 7 (019E16)
??16
(017E16)
??16
(019F16)
??16
(017F16)
??16
(01A016)
??16
(018016)
??16
(01A116)
??16
(018116)
??16
(243) Group 3 base timer control register 0
(01A216)
0016
(018216)
??16
(244) Group 3 base timer control register 1
(01A316) 0 X X 0 X 0 0 0
(018316)
??16
(245) Group 3 function enable register
(01A616)
0016
(018416)
??16
(246) Group 3 RTP output buffer register
(01A716)
0016
(018516)
??16
(247) Group 3 high-speed HDLC
(018616)
??16
(018716)
??16
(018816)
??16
(018916)
??16
(018A16)
??16
(242) Group 3 base timer register
(01AB16) 0 0 X X X X X 0
communication control register 1
(248) Group 3 high-speed HDLC
0016
(01AC16)
communication control register
(249) Group 3 high-speed HDLC
(01AD16)
??16
communication register
(250) Group 3 high-speed HDLC transmit counter (01AE16)
0016
(251) Group 3 high-speed HDLC data
(01AF16)
0016
(01B016)
0016
(01B116)
0016
(01B216)
0016
(01B316)
0016
(01B416)
0016
(01B516)
0016
(01B616)
0016
(01B716)
0016
(01B816)
0016
(01B916)
0016
(01BA16)
0016
(01BB16)
0016
(01BC16)
0016
(01BD16)
0016
compare register 0
(228) Group 3 waveform generate register 6
(229) Group 3 waveform generate register 7
(018B16)
??16
(018C16)
??16
(018D16)
??16
(018E16)
??16
(252) Group 3 high-speed HDLC data
mask register 0
(253) Group 3 high-speed HDLC data
compare register 1
(018F16)
??16
(230) Group 3 waveform generate control register 0 (019016)
0016
(254) Group 3 high-speed HDLC data
mask register 1
(231) Group 3 waveform generate control register 1 (019116)
0016
(232) Group 3 waveform generate control register 2 (019216)
0016
(255) Group 3 high-speed HDLC data
compare register 2
(233) Group 3 waveform generate control register 3 (019316)
0016
(234) Group 3 waveform generate control register 4 (019416)
0016
(256) Group 3 high-speed HDLC data
mask register 2
(235) Group 3 waveform generate control register 5 (019516)
0016
(236) Group 3 waveform generate control register 6 (019616)
0016
(257) Group 3 high-speed HDLC data
compare register 3
(237) Group 3 waveform generate control register 7 (019716)
0016
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Figure 1.4.3. Device's internal status after a reset is cleared (5/10)
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(258) Group 3 high-speed HDLC data
(01BE16)
0016
(282) CAN0 message slot buffer 0 data 6
(01EC16)
??16
(Note)
mask register 3
(01BF16)
0016
(283) CAN0 message slot buffer 0 data 7
(01ED16)
??16
(Note)
(259) A-D1 register 0
(260) A-D1 register 1
(01C016)
??16
(284) CAN0 message slot buffer 0 time stamp high (01EE16)
(Note)
??16
(01C116)
??16
(285) CAN0 message slot buffer 0 time stamp low (01EF16)
(Note)
??16
(01C216)
??16
(286) CAN1 message slot buffer 0 standard ID 0
(01F016) XX X ? ? ? ? ?
(01C316)
??16
(287) CAN1 message slot buffer 0 standard ID 1
(01F116) XX ? ? ? ? ? ?
(01C416)
??16
(288) CAN1 message slot buffer 0 extended ID 0
(01F216) XX X X ? ? ? ?
(01C516)
??16
(289) CAN1 message slot buffer 0 extended ID 1
(01F316)
(Note)
(Note)
(261) A-D1 register 2
(Note)
??16
(Note)
(262) A-D1 register 3
(01C616)
??16
(290) CAN1 message slot buffer 0 extended ID 2
(01C716)
??16
(291) CAN1 message slot buffer 0 data length code (01F516) XX X X ? ? ? ?
(Note)
(01C816)
??16
(292) CAN1 message slot buffer 0 data 0
(01F416) XX ? ? ? ? ? ?
(Note)
(263) A-D1 register 4
(01F616)
??16
(Note)
(01C916)
??16
(293) CAN1 message slot buffer 0 data 1
(01F716)
??16
(Note)
(264) A-D1 register 5
(01CA16)
??16
(294) CAN1 message slot buffer 0 data 2
(01F816)
??16
(Note)
(01CB16)
??16
(295) CAN1 message slot buffer 0 data 3
(01F916)
??16
(Note)
(265) A-D1 register 6
(01CC16)
??16
(296) CAN1 message slot buffer 0 data 4
(01FA16)
??16
(Note)
(01CD16)
??16
(297) CAN1 message slot buffer 0 data 5
(01FB16)
??16
(Note)
(266) A-D1 register 7
(01CE16)
??16
(298) CAN1 message slot buffer 0 data 6
(01FC16)
??16
(Note)
(01CF16)
??16
(299) CAN1 message slot buffer 0 data 7
(01FD16)
??16
(Note)
(267) A-D1 control register 2
(01D416) X 0 0 X X 0 0 0
(300) CAN1 message slot buffer 0 time stamp high (01FE16)
(Note)
??16
(268) A-D1 control register 0
(01D616)
(301) CAN1 message slot buffer 0 time stamp low (01FF16)
(Note)
??16
(269) A-D1 control register 1
(01D716) XX 0 0 0 0 0 0
(270) CAN0 message slot buffer 0 standard ID 0
(01E016) XX X ? ? ? ? ?
(271) CAN0 message slot buffer 0 standard ID 1
(01E116) XX ? ? ? ? ? ?
0016
(302) CAN0 control register 0
(020016) X X 0 1 0 X 0 1
(Note)
(020116) XXXX 0 0 0 0
(Note)
(303) CAN0 status register
(Note)
(272) CAN0 message slot buffer 0 extended ID 0
(020216)
0016
(Note)
(01E216) XX X X ? ? ? ?
(020316) X 0 0 0 0 X 0 1
(Note)
(273) CAN0 message slot buffer 0 extended ID 1
(01E316)
??16
(304) CAN0 expansion ID register
(Note)
(274) CAN0 message slot buffer 0 extended ID 2
(020416)
0016
(Note)
(01E416) XX ? ? ? ? ? ?
(020516)
0016
(Note)
(275) CAN0 message slot buffer 0 data length code (01E516) XX X X ? ? ? ?
(Note)
(276) CAN0 message slot buffer 0 data 0
(01E616)
(305) CAN0 configuration register
(020616) 0 0 0 0 X XXX
(Note)
??16
(020716)
0016
(020816)
0016
(Note)
(277) CAN0 message slot buffer 0 data 1
(01E716)
??16
(306) CAN0 time stamp register
(Note)
(278) CAN0 message slot buffer 0 data 2
(01E816)
(Note)
??16
(020916)
0016
(020A16)
0016
(Note)
(279) CAN0 message slot buffer 0 data 3
(01E916)
??16
(307) CAN0 transmit error count register
(Note)
(280) CAN0 message slot buffer 0 data 4
(01EA16)
(Note)
??16
(308) CAN0 receive error count register
(Note)
(281) CAN0 message slot buffer 0 data 5
(01EB16)
(020B16)
0016
(Note)
??16
(Note)
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit (bit 0 at address 024216) to 1 after reset.
Figure 1.4.3. Device's internal status after a reset is cleared (6/10)
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Rev.B2 for proof reading
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(309) CAN0 slot interrupt status register
Mitsubishi Microcomputers
(020C16)
0016
(339) X0 register/Y0 register
(02C016)
??16
(02C116)
??16
(02C216)
??16
(02C316)
??16
(02C416)
??16
(02C516)
??16
(02C616)
??16
(02C716)
??16
(02C816)
??16
(02C916)
??16
(02CA16)
??16
(02CB16)
??16
(02CC16)
??16
(02CD16)
??16
(02CE16)
??16
(02CF16)
??16
(02D016)
??16
(02D116)
??16
(02D216)
??16
(02D316)
??16
(02D416)
??16
(02D516)
??16
(02D616)
??16
(02D716)
??16
(02D816)
??16
(02D916)
??16
(02DA16)
??16
(02DB16)
??16
(02DC16)
??16
(02DD16)
??16
(02DE16)
??16
(02DF16)
??16
(Note)
(310) CAN0 slot interrupt mask register
(020D16)
0016
(021016)
0016
(340) X1 register/Y1 register
(Note)
(021116)
(311) CAN0 error interrupt mask register
0016
(021416) XXX X X 0 0 0
(341) X2 register/Y2 register
(Note)
(312) CAN0 error interrupt status register
(021516) XXX X X 0 0 0
(Note)
(313) CAN0 baud rate prescaler
(021716)
0116
(342) X3 register/Y3 register
(Note)
(314) CAN0 global mask register standard ID0
(022816) XXX 0 0 0 0 0
(Note)
(315) CAN0 global mask register standard ID1
(022916) XX 0 0 0 0 0 0
(343) X4 register/Y4 register
(Note)
(316) CAN0 global mask register extended ID0
(022A16)
??16
(Note)
(317) CAN0 global mask register extended ID1
(022B16)
??16
(344) X5 register/Y5 register
(Note)
(318) CAN0 global mask register extended ID2
(022C16)
??16
(Note)
(319) CAN0 message slot 0 control register /
CAN0 local mask register A standard ID0
(023016) XXX 0 0 0 0 0
(320) CAN0 message slot 1 control register /
CAN0 local mask register A standard ID1
(023116) XX 0 0 0 0 0 0
(321) CAN0 message slot 2 control register /
CAN0 local mask register A extended ID0
(023216)
(322) CAN0 message slot 3 control register /
CAN0 local mask register A extended ID1
(023316)
(323) CAN0 message slot 4 control register /
CAN0 local mask register A extended ID2
(023416)
(324) CAN0 message slot 5 control register
(023516)
(345) X6 register/Y6 register
(Note)
(Note)
0016
(346) X7 register/Y7 register
(Note)
0016
(Note)
0016
(347) X8 register/Y8 register
(Note)
0016
(Note)
(325) CAN0 message slot 6 control register
(023616)
0016
(348) X9 register/Y9 register
(Note)
(326) CAN0 message slot 7 control register
(023716)
0016
(Note)
(327) CAN0 message slot 8 control register /
CAN0 local mask register B standard ID0
(023816) XXX 0 0 0 0 0
(328) CAN0 message slot 9 control register /
CAN0 local mask register B standard ID1
(023916) XX 0 0 0 0 0 0
(329) CAN0 message slot 10 control register /
CAN0 local mask register B extended ID0
(023A16)
(330) CAN0 message slot 11 control register /
CAN0 local mask register B extended ID1
(023B16)
(331) CAN0 message slot 12 control register /
CAN0 local mask register B extended ID2
(023C16)
(332) CAN0 message slot 13 control register
(023D16)
(349) X10 register/Y10 register
(Note)
(Note)
0016
(350) X11 register/Y11 register
(Note)
0016
(Note)
0016
(351) X12 register/Y12 register
(Note)
0016
(Note)
(333) CAN0 message slot 14 control register
(023E16)
0016
(352) X13 register/Y13 register
(Note)
(334) CAN0 message slot 15 control register
(023F16)
0016
(Note)
(335) CAN0 slot buffer select register
(024016)
0016
(353) X14 register/Y14 register
(Note)
(336) CAN0 control register 1
(024116) XX 0 0 0 0 X X
(Note)
(337) CAN0 sleep control register
(024216) XX X X XX X 0
(354) X15 register/Y15 register
(Note)
(338) CAN0 acceptance filter support register
(024416)
0016
(Note)
(024516)
0116
(355) XY control register
(02E016) XX XX XX 0 0
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit (bit 0 at address 024216) to 1 after reset.
Figure 1.4.3. Device's internal status after a reset is cleared (7/10)
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(356) UART1 special mode register 4
(02E416)
0016
(382) Three-phase output buffer register 0
(030A16) X X 0 0 0 0 0 0
(357) UART1 special mode register 3
(02E516)
0016
(383) Three-phase output buffer register 1
(030B16) X X 0 0 0 0 0 0
(358) UART1 special mode register 2
(02E616)
0016
(384) Dead time timer
(030C16)
(359) UART1 special mode register
(02E716)
0016
(385) Timer B2 interrupt occurrence
??16
(030D16) XXX X ? ? ? ?
frequency set counter
(360) UART1 transmit-receive mode register
(02E816)
0016
(361) UART1 bit rate generator
(02E916)
??16
(362) UART1 transmit buffer register
(02EA16)
??16
(386) Timer B3 register
(387) Timer B4 register
(02EB16) XXX X XX X ?
(363) UART1 transmit-receive control register 0
(02EC16)
0816
(364) UART1 transmit-receive control register 1
(02ED16)
0216
(365) UART1 receive buffer register
(02EE16)
??16
(02EF16) ? ? ? ? ? XX ?
(388) Timer B5 register
??16
(031116)
??16
(031216)
??16
(031316)
??16
(031416)
??16
(031516)
??16
(389) Timer B3 mode register
(031B16) 0 0 ? X 0 0 0 0
(390) Timer B4 mode register
(031C16) 0 0 ? X 0 0 0 0
(366) UART4 special mode register 4
(02F416)
0016
(391) Timer B5 mode register
(031D16) 0 0 ? 0 0 0 0 0
(367) UART4 special mode register 3
(02F516)
0016
(392) External interrupt cause select register
(031F16)
0016
(368) UART4 special mode register 2
(02F616)
0016
(393) UART3 special mode register 4
(032416)
0016
(369) UART4 special mode register
(02F716)
0016
(394) UART3 special mode register 3
(032516)
0016
(370) UART4 transmit-receive mode register
(02F816)
0016
(395) UART3 special mode register 2
(032616)
0016
(371) UART4 bit rate generator
(02F916)
??16
(396) UART3 special mode register
(032716)
0016
(372) UART4 transmit buffer register
(02FA16)
??16
(397) UART3 transmit-receive mode register
(032816)
0016
(02FB16) XXX X XX X ?
(398) UART3 bit rate generator
(032916)
??16
(373) UART4 transmit-receive control register 0
(02FC16)
0816
(399) UART3 transmit buffer register
(032A16)
??16
(374) UART4 transmit-receive control register 1
(02FD16)
0216
(375) UART4 receive buffer register
(02FE16)
??16
(032B16) XXX XX X X ?
(400) UART3 transmit-receive control register 0
(032C16)
0816
(02FF16) ? ? ? ? ? XX ?
(401) UART3 transmit-receive control register 1
(032D16)
0216
(376) Timer B3,B4,B5 count start flag
(030016) 0 0 0 X XX XX
(402) UART3 receive buffer register
(032E16)
??16
(377) Timer A1-1 register
(030216)
??16
(030316)
??16
(403) UART2 special mode register 4
(033416)
0016
(030416)
??16
(404) UART2 special mode register 3
(033516)
0016
(030516)
??16
(405) UART2 special mode register 2
(033616)
0016
(030616)
??16
(406) UART2 special mode register
(033716)
0016
(030716)
??16
(407) UART2 transmit-receive mode register
(033816)
0016
(380) Three-phase PWM control register 0
(030816)
0016
(408) UART2 bit rate generator
(033916)
??16
(381) Three-phase PWM control register 1
(030916)
0016
(378) Timer A2-1 register
(379) Timer A4-1 register
(032F16) ? ? ? ? ? X X ?
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Figure 1.4.3. Device's internal status after a reset is cleared (8/10)
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(432) Timer B1 mode register
(035C16) 0 0 ? X 0 0 0 0
(033B16) XXX X XX X ?
(433) Timer B2 mode register
(035D16) 0 0 ? X 0 0 0 0
(410) UART2 transmit/receive control register 0
(033C16)
0816
(434) Timer B2 special mode register
(035E16) XXX X X X X 0
(411) UART2 transmit/receive control register 1
(033D16)
0216
(435) Count source prescaler register
(035F16) 0 XXX 0 0 0 0
(412) UART2 receive buffer register
(033E16)
??16
(436) UART0 pecial mode register 4
(036416)
0016
(033F16) ? ? ? ? ? X X ?
(437) UART0 special mode register 3
(036516)
0016
(413) Count start flag
(034016)
(438) UART0 special mode register 2
(036616)
0016
(414) Clock prescaler reset flag
(034116) 0 X X XXX XX
(439) UART0 special mode register
(036716)
0016
(415) One-shot start flag
(034216)
0016
(440) UART0 transmit/receive mode register
(036816)
0016
(416) Trigger select register
(034316)
0016
(441) UART0 bit rate generator
(036916)
??16
(417) Up-down flag
(034416)
0016
(442) UART0 transmit buffer register
(036A16)
??16
(418) Timer A0
(034616)
??16
(034716)
??16
(443) UART0 transmit/receive control register 0
(036C16)
0816
(034816)
??16
(444) UART0 transmit/receive control register 1
(036D16)
0216
(034916)
??16
(445) UART0 receive buffer register
(036E16)
??16
(034A16)
??16
(034B16)
??16
(446) PLL control register 0
(037616) 0 0 1 1 0 1 0 0
(034C16)
??16
(447) DMA0 cause select register
(037816) 0 X 0 0 0 0 0 0
(034D16)
??16
(448) DMA1 cause select register
(037916) 0 X 0 0 0 0 0 0
(034E16)
??16
(449) DMA2 cause select register
(037A16) 0 X 0 0 0 0 0 0
(034F16)
??16
(450) DMA3 cause select register
(037B16) 0 X 0 0 0 0 0 0
(035016)
??16
(451) CRC data register
(037C16)
??16
(035116)
??16
(037D16)
??16
(035216)
??16
(452) CRC input register
(037E16)
??16
(035316)
??16
(453) A-D0 register 0
(038016)
??16
(035416)
??16
(038116)
??16
(035516)
??16
(038216)
??16
(038316)
??16
(038416)
??16
(038516)
??16
(038616)
??16
(038716)
??16
(409) UART2 transmit buffer register
(419) Timer A1
(420) Timer A2
(421) Timer A3
(422) Timer A4
(423) Timer B0
(424) Timer B1
(425) Timer B2
(033A16)
??16
0016
(426) Timer A0 mode register
(035616) 0 0 0 0 0 X 0 0
(427) Timer A1 mode register
(035716) 0 0 0 0 0 X 0 0
(428) Timer A2 mode register
(035816) 0 0 0 0 0 X 0 0
(429) Timer A3 mode register
(035916) 0 0 0 0 0 X 0 0
(430) Timer A4 mode register
(035A16) 0 0 0 0 0 X 0 0
(431) Timer B0 mode register
(035B16) 0 0 ? 0 0 0 0 0
(036B16) X XXX XXX ?
(036F16) ? ? ? ? ? X X ?
(454) A-D0 register 1
(455) A-D0 register 2
(456) A-D0 register 3
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM are undefined when the microcomputer is reset. The initial values must therefore be set.
Figure 1.4.3. Device's internal status after a reset is cleared (9/10)
35
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Reset
(457) A-D0 register 4
(458) A-D0 register 5
(459) A-D0 register 6
(460) A-D0 register 7
(038816)
??16
(486) Port P9
(03C516)
(038916)
??16
(487) Port P8 direction register
(03C616) 0 0 X 0 0 0 0 0
(038A16)
??16
(488) Port P9 direction register
(03C716)
0016
(038B16)
??16
(489) Port P10
(03C816)
??16
(038C16)
??16
(490) Port P11
(Note)
(038D16)
??16
(491) Port P10 direction register
(Note) (03CA16)
(038E16)
??16
(492) Port P11 direction register
(Note) (03CB16) XXX 0 0 0 0 0
(038F16)
??16
(493) Port P12
(Note) (03CC16)
??16
(494) Port P13
(Note) (03CD16)
??16
(03C916) XXX ? ? ? ? ?
0016
(461) A-D0 control register 2
(039416) X 0 0 0 0 0 0 0
(462) A-D0 control register 0
(039616)
0016
(495) Port P12 direction register
(Note) (03CE16)
0016
(463) A-D0 control register 1
(039716)
0016
(496) Port P13 direction register
(Note)
(03CF16)
0016
(464) D-A register 0
(039816)
??16
(497) Port P14
(Note)
(03D016) X ? ? ? ? ? ? ?
(465) D-A register 1
(039A16)
??16
(498) Port P15
(Note)
(03D116)
(466) D-A control register
(039C16) XXXX XX 0 0
(499) Port P14 direction register
(Note)
(03D216) X 0 0 0 0 0 0 0
(03A016) XXXX 0 0 0 0
(500) Port P15 direction register
(Note)
(03D316)
0016
(501) Pull-up control register 2
(03DA16)
0016
(03DB16)
0016
(467) Function select register A8
(Note)
(468) Function select register A9
(Note) (03A116)
0016
??16
(469) Function select register C
(03AF16) 0 0 X 0 0 0 0 0
(502) Pull-up control register 3
(470) Function select register A0
(03B016)
0016
(503) Pull-up control register 4
(471) Function select register A1
(03B116)
0016
(504) Port P0
(03E016)
??16
(472) Function select register B0
(03B216)
0016
(505) Port P1
(03E116)
??16
(473) Function select register B1
(03B316)
0016
(506) Port P0 direction register
(03E216)
0016
(474) Function select register A2
(03B416) XX XXX 0 0 0
(507) Port P1 direction register
(03E316)
0016
(475) Function select register A3
(03B516)
(508) Port P2
(03E416)
??16
(476) Function select register B2
(03B616) XX XXX 0 0 0
(509) Port P3
(03E516)
??16
(477) Function select register B3
(03B716)
(510) Port P2 direction register
(03E616)
0016
(511) Port P3 direction register
(03E716)
0016
0016
0016
(03B916) XX XX 0 0 0 0
(Note) (03DC16) XX XX 0 0 0 0
(478) Function select register A5
(Note)
(479) Function select register A6
(Note) (03BC16)
0016
(512) Port P4
(03E816)
??16
(480) Function select register A7
(Note) (03BD16)
0016
(513) Port P5
(03E916)
??16
(481) Port P6
(03C016)
??16
(514) Port P4 direction register
(03EA16)
0016
(482) Port P7
(03C116)
??16
(515) Port P5 direction register
(03EB16)
0016
(483) Port P6 direction register
(03C216)
0016
(516) Pull-up control register 0
(03F016)
0016
(484) Port P7 direction register
(03C316)
0016
(517) Pull-up control register 1
(03F116) XX XX 0 0 0 0
(485) Port P8
(03C416)
??16
(518) Port control register
(03FF16) XX XX X XX 0
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values must therefore be set.
Note :This register exists in 144-pin version.
Figure 1.4.3. Device's internal status after a reset is cleared (10/10)
36
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
SFR
Address
Register
000016
000116
000216
000316
000416 Processor mode register 0
000516 Processor mode register 1
000616 System clock control register 0
000716 System clock control register 1
000816 Wait control register
000916 Address match interrupt control register
000A16 Protect register
000B16 External data bus width control register
000C16 Main clock divided register
000D16 Oscillation stop detect register
000E16 Watchdog timer start register
000F16 Watchdog timer control register
001016
001116 Address match interrupt register 0
001216
001316
001416
001516 Address match interrupt register 1
001616
001716 VDC control register for PLL
001816
001916 Address match interrupt register 2
001A16
001B16 VDC control register 1
001C16
001D16 Address match interrupt register 3
001E16
001F16 VDC control register 0
002016
002116 Emulator interrupt vector table register
002216
002316 Emulator interrupt detect register
002416 Emulator protect register
002516
002616
002716
002816
002916
002A16
002B16
002C16
002D16
002E16
002F16
PM0
PM1
CM0
CM1
WCR
AIER
PRCR
DS
MCD
CM2
WDTS
WDC
RMAD0
RAMD1
PLV
RAMD2
VDC1 *
RAMD3
VDC0 *
EIAD0 *
EITD *
EPRR *
Address
Register
003016 ROM area set register
003116 Debug moritor area set register
003216 Expansion area set register 0
003316 Expansion area set register 1
003416 Expansion area set register 2
003516 Expansion area set register 3
003616
003716
003816
003916
003A16
003B16
003C16
003D16
003E16
003F16
004016 DRAM control register
004116 DRAM refresh interval set register
004216
004316
004416
004516
004616
004716
004816
004916
004A16
004B16
004C16
004D16
004E16
004F16
005016
005116
005216
005316
005416
005516 Flash memory control register 2
005616 Flash memory control register 1
005716 Flash memory control register 0
005816
005916
005A16
005B16
005C16
005D16
005E16
005F16
ROA *
DBA *
EXA0 *
EXA1 *
EXA2 *
EXA3 *
DRAMCONT
REFCNT
FMR2 *
FMR1 *
FMR0
The blank area is reserved and cannot be used by user.
*: User cannot use this. Do not access to the register.
37
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Rev.B2 for proof reading
The blank area is reserved and cannot be used by user.
38
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
Address
Register
006016
006116
006216
006316
006416
006516
006616
006716
006816 DMA0 interrupt control register
DM0IC
006916 Timer B5 interrupt control register
TB5IC
006A16 DMA2 interrupt control register
DM2IC
006B16 UART2 receive /ACK interrupt control register
S2RIC
006C16 Timer A0 interrupt control register
TA0IC
006D16 UART3 receive /ACK interrupt control register
S3RIC
006E16 Timer A2 interrupt control register
TA2IC
006F16 UART4 receive /ACK interrupt control register
S4RIC
007016 Timer A4 interrupt control register
TA4IC
007116 UART0/UART3 bus collision detection interrupt control register BCN0IC
007216 UART0 receive/ACK interrupt control register
S0RIC
007316 A-D0 interrupt control register
AD0IC
007416 UART1 receive/ACK interrupt control register
S1RIC
007516 Intelligent I/O interrupt control register 0
IIO0IC
007616 Timer B1 interrupt control register
TB1IC
007716 Intelligent I/O interrupt control register 2
IIO2IC
007816 Timer B3 interrupt control register
TB3IC
007916 Intelligent I/O interrupt control register 4
IIO4IC
007A16 INT5 interrupt control register
INT5IC
007B16 Intelligent I/O interrupt control register 6
IIO6IC
007C16 INT3 interrupt control register
INT3IC
007D16 Intelligent I/O interrupt control register 8
IIO8IC
007E16 INT1 interrupt control register
INT1IC
007F16 Intelligent I/O interrupt control register 10/
IIO10IC
CAN interrupt 1 control register
CAN1ICI
008016
008116 Intelligent I/O interrupt control register 11/
IIO11IC
CAN interrupt 2 control register
CAN2IC
008216
008316
008416
008516
008616 A-D1 interrupt control register
AD1IC
008716
008816 DMA1 interrupt control register
DM1IC
008916 UART2 transmit /NACK interrupt control register
S2TIC
008A16 DMA3 interrupt control register
DM3IC
008B16 UART3 transmit /NACK interrupt control register
S3TIC
008C16 Timer A1 interrupt control register
TA1IC
008D16 UART4 transmit /NACK interrupt control register
S4TIC
008E16 Timer A3 interrupt control register
TA3IC
008F16 UART2 bus collision detection interrupt control register BCN2IC
Mitsubishi Microcomputers
Address
Register
009016 UART0 transmit /NACK interrupt control register
S0TIC
009116 UART1/UART4 bus collision detection interrupt control register BCN1IC
009216 UART1 transmit/NACK interruptcontrol register
S1TIC
009316 Key input interrupt control register
KUPIC
009416 Timer B0 interrupt control register
TB0IC
009516 Intelligent I/O interrupt control register 1
IIO1IC
009616 Timer B2 interrupt control register
TB2IC
009716 Intelligent I/O interrupt control register 3
IIO3IC
009816 Timer B4 interrupt control register
TB4IC
009916 Intelligent I/O interrupt control register 5
IIO5IC
009A16 INT4 interrupt control register
INT4IC
009B16 Intelligent I/O interrupt control register 7
IIO7IC
009C16 INT2 interrupt control register
INT2IC
009D16 Intelligent I/O interrupt control register 9/
IIO9IC
CAN interrupt 0 control register
CAN0ICI
009E16 INT0 interrupt control register
INT0IC
009F16 Exit priority register
RLVL
00A016
00A116
00A216
00A316
00A416
00A516
00A616
00A716
00A816
00A916
00AA16
00AB16
00AC16
00AD16
00AE16
00AF16
00B016
00B116
00B216
00B316
00B416
00B516
00B616
00B716
00B816
00B916
00BA16
00BB16
00BC16
00BD16
00BE16
00BF16
Interrupt request register 0
Interrupt request register 1
Interrupt request register 2
Interrupt request register 3
Interrupt request register 4
Interrupt request register 5
Interrupt request register 6
Interrupt request register 7
Interrupt request register 8
Interrupt request register 9
Interrupt request register 10
Interrupt request register 11
IIO0IR
IIO1IR
IIO2IR
IIO3IR
IIO4IR
IIO5IR
IIO6IR
IIO7IR
IIO8IR
IIO9IR
IIO10IR
IIO11IR
Interrupt enable register 0
Interrupt enable register 1
Interrupt enable register 2
Interrupt enable register 3
Interrupt enable register 4
Interrupt enable register 5
Interrupt enable register 6
Interrupt enable register 7
Interrupt enable register 8
Interrupt enable register 9
Interrupt enable register 10
Interrupt enable register 11
IIO0IE
IIO1IE
IIO2IE
IIO3IE
IIO4IE
IIO5IE
IIO6IE
IIO7IE
IIO8IE
IIO9IE
IIO10IE
IIO11IE
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Rev.B2 for proof reading
SFR
Address
Register
00C016
Group 0 TM /WG register 0
G0TM0/G0PO0
00C116
00C216
Group 0 TM /WG register 1
G0TM1/G0PO1
00C316
00C416
Group 0 TM /WG register 2
G0TM2/G0PO2
00C516
00C616
Group 0 TM /WG register 3
G0TM3/G0PO3
00C716
00C816
Group 0 TM /WG register 4
G0TM4/G0PO4
00C916
00CA16
Group 0 TM /WG register 5
G0TM5/G0PO5
00CB16
00CC16
Group 0 TM /WG register 6
G0TM6/G0PO6
00CD16
00CE16
Group 0 TM /WG register 7
G0TM7/G0PO7
00CF16
00D016 Group 0 waveform generate control register 0 G0POCR0
00D116 Group 0 waveform generate control register 1 G0POCR1
00D216
00D316
00D416 Group 0 waveform generate control register 4 G0POCR4
00D516 Group 0 waveform generate control register 5 G0POCR5
00D616
00D716
00D816 Group 0 time measurement control register 0 G0TMCR0
00D916 Group 0 time measurement control register 1 G0TMCR1
00DA16 Group 0 time measurement control register 2 G0TMCR2
00DB16 Group 0 time measurement control register 3 G0TMCR3
00DC16 Group 0 time measurement control register 4 G0TMCR4
00DD16 Group 0 time measurement control register 5 G0TMCR5
00DE16 Group 0 time measurement control register 6 G0TMCR6
00DF16 Group 0 time measurement control register 7 G0TMCR7
00E016
Group 0 base timer register
G0BT
00E116
00E216 Group 0 base timer control register 0
G0BCR0
00E316 Group 0 base timer control register 1
G0BCR1
00E416 Group 0 time measurement prescaler register 6 G0TPR6
00E516 Group 0 time measurement prescaler register 7 G0TPR7
00E616 Group 0 function enable register
G0FE
00E716 Group 0 function select register
G0FS
00E816
Group 0 SI/O receive buffer register
G0BF
00E916
00EA16 Group 0 transmit buffer/receive data register
G0DR
00EB16
00EC16 Group 0 receive input register
G0RI
00ED16 Group 0 SI/O communication mode register
G0MR
00EE16 Group 0 transmit output register
G0TO
00EF16 Group 0 SI/O communication control register
G0CR
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Address
Register
00F016 Group 0 data compare register 0
G0CMP0
00F116 Group 0 data compare register 1
G0CMP1
00F216 Group 0 data compare register 2
G0CMP2
00F316 Group 0 data compare register 3
G0CMP3
00F416 Group 0 data mask register 0
G0MSK0
00F516 Group 0 data mask register 1
G0MSK1
00F616
00F716
00F816
Group 0 receive CRC code register
G0RCRC
00F916
00FA16
Group 0 transmit CRC code register
G0TCRC
00FB16
00FC16 Group 0 SI/O expansion mode register
G0EMR
00FD16 Group 0 SI/O expansion receive control register G0ERC
00FE16 Group 0 SI/O special communication interrupt detect register G0IRF
00FF16 Group 0 SI/O expansion transmit control register G0ETC
010016
Group 1 TM /WG register 0
G1TM0/G1PO0
010116
010216
Group 1 TM /WG register 1
G1TM1/G1PO1
010316
010416
Group 1 TM /WG register 2
G1TM2/G1PO2
010516
010616
Group 1 TM /WG register 3
G1TM3/G1PO3
010716
010816
Group 1 TM /WG register 4
G1TM4/G1PO4
010916
010A16
Group 1 TM /WG register 5
G1TM5/G1PO5
010B16
010C16
Group 1 TM /WG register 6
G1TM6/G1PO6
010D16
010E16
Group 1 TM /WG register 7
G1TM7/G1PO7
010F16
011016 Group 1 waveform generate control register 0 G1POCR0
011116 Group 1 waveform generate control register 1 G1POCR1
011216 Group 1 waveform generate control register 2 G1POCR2
011316 Group 1 waveform generate control register 3 G1POCR3
011416 Group 1 waveform generate control register 4 G1POCR4
011516 Group 1 waveform generate control register 5 G1POCR5
011616 Group 1 waveform generate control register 6 G1POCR6
011716 Group 1 waveform generate control register 7 G1POCR7
011816
011916 Group 1 time measurement control register 1 G1TMCR1
011A16 Group 1 time measurement control register 2 G1TMCR2
011B16
011C16
011D16
011E16 Group 1 time measurement control register 6 G1TMCR6
011F16 Group 1 time measurement control register 7 G1TMCR7
The blank area is reserved and cannot be used by user.
39
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Rev.B2 for proof reading
Address
Register
012016
Group 1 base timer register
G1BT
012116
012216 Group 1 base timer control register 0
G1BCR0
012316 Group 1 base timer control register 1
G1BCR1
012416 Group 1 time measurement prescaler register 6 G1TPR6
012516 Group 1 time measurement prescaler register 7 G1TPR7
012616 Group 1 function enable register
G1FE
012716 Group 1 function select register
G1FS
012816
Group 1 SI/O receive buffer register
G1BF
012916
012A16 Group 1 transmit buffer/receive data register
G1DR
012B16
012C16 Group 1 receive input register
G1RI
012D16 Group 1 SI/O communication mode register
G1MR
012E16 Group 1 transmit output register
G1TO
012F16 Group 1 SI/O communication control register
G1CR
013016 Group 1 data compare register 0
G1CMP0
Group 1 data compare register 1
Group 1 data compare register 2
Group 1 data compare register 3
Group 1 data mask register 0
Group 1 data mask register 1
G1CMP1
G1CMP2
G1CMP3
G1MSK0
G1MSK1
Group 1 receive CRC code register
G1RCRC
Group 1 transmit CRC code register
G1TCRC
Group 1 SI/O expansion mode register
G1EMR
Group 1 SI/O expansion receive control register G1ERC
Group 1 SI/O special communication interrupt detect register G1IRF
Group 1 SI/O expansion transmit control register G1ETC
Group 2 waveform generate register 0
G2PO0
Group 2 waveform generate register 1
G2PO1
Group 2 waveform generate register 2
G2PO2
Group 2 waveform generate register 3
G2PO3
Group 2 waveform generate register 4
G2PO4
Group 2 waveform generate register 5
G2PO5
Group 2 waveform generate register 6
G2PO6
Group 2 waveform generate register 7
G2PO7
The blank area is reserved and cannot be used by user.
40
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
013116
013216
013316
013416
013516
013616
013716
013816
013916
013A16
013B16
013C16
013D16
013E16
013F16
014016
014116
014216
014316
014416
014516
014616
014716
014816
014916
014A16
014B16
014C16
014D16
014E16
014F16
Mitsubishi Microcomputers
Address
Register
015016 Group 2 waveform generate control register 0 G2POCR0
015116 Group 2 waveform generate control register 1 G2POCR1
015216 Group 2 waveform generate control register 2 G2POCR2
015316 Group 2 waveform generate control register 3 G2POCR3
015416 Group 2 waveform generate control register 4 G2POCR4
015516 Group 2 waveform generate control register 5 G2POCR5
015616 Group 2 waveform generate control register 6 G2POCR6
015716 Group 2 waveform generate control register 7 G2POCR7
015816
015916
015A16
015B16
015C16
015D16
015E16
015F16
016016
Group 2 base timer register
G2BT
016116
016216 Group 2 base timer control register 0
G2BCR0
016316 Group 2 base timer control register 1
G2BCR1
016416 Base timer start register
BTSR
016516
016616 Group 2 function enable register
G2FE
016716 Group 2 RTP output buffer register
G2RTP
016816
016916
016A16 Group 2 SI/O communication mode register
G2MR
016B16 Group 2 SI/O communication control register
G2CR
016C16
Group 2 SI/O transmit buffer register
G2TB
016D16
016E16
Group 2 SI/O receive buffer register
G2RB
016F16
017016
Group 2 IEBus address register
IEAR
017116
017216 Group 2 IEBus control register
IECR
017316 Group 2 IEBus transmit interrupt cause detect register
IETIF
017416 Group 2 IEBus receive interrupt cause detect register
IERIF
017516
017616
017716
017816 Input function select register
IPS
017916
017A16 Group 3 SI/O communication mode register
G3MR
017B16 Group 3 SI/O communication control register
G3CR
017C16
Group 3 SI/O transmit buffer register
G3TB
017D16
017E16
Group 3 SI/O receive buffer register
G3RB
017F16
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SFR
Address
Register
018016
Group 3 waveform generate register 0
G3PO0
018116
018216
Group 3 waveform generate register 1
G3PO1
018316
018416
Group 3 waveform generate register 2
G3PO2
018516
018616
Group 3 waveform generate register 3
G3PO3
018716
018816
Group 3 waveform generate register 4
G3PO4
018916
018A16
Group 3 waveform generate register 5
G3PO5
018B16
018C16
Group 3 waveform generate register 6
G3PO6
018D16
018E16
Group 3 waveform generate register 7
G3PO7
018F16
019016 Group 3 waveform generate control register 0 G3POCR0
019116 Group 3 waveform generate control register 1 G3POCR1
019216 Group 3 waveform generate control register 2 G3POCR2
019316 Group 3 waveform generate control register 3 G3POCR3
019416 Group 3 waveform generate control register 4 G3POCR4
019516 Group 3 waveform generate control register 5 G3POCR5
019616 Group 3 waveform generate control register 6 G3POCR6
019716 Group 3 waveform generate control register 7 G3POCR7
019816
Group 3 waveform generate mask register 4
G3MK4
019916
019A16
Group 3 waveform generate mask register 5
G3MK5
019B16
019C16
Group 3 waveform generate mask register 6
G3MK6
019D16
019E16
Group 3 waveform generate mask register 7
G3MK7
019F16
01A016
Group 3 base timer register
G3BT
01A116
01A216 Group 3 base timer control register 0
G3BCR0
01A316 Group 3 base timer control register 1
G3BCR1
01A416
01A516
01A616 Group 3 function enable register
G3FE
01A716 Group 3 RTP output buffer register
G3RTP
01A816
01A916
01AA16
01AB16 Group 3 high-speed HDLC communication control register 1
HDLC1
01AC16 Group 3 high-speed HDLC communication control register
HDLC
01AD16 Group 3 high-speed HDLC communication register HDLCF
01AE16
Group 3 high-speed HDLC transmit counter
HDLCC
01AF16
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Address
Register
01B016
Group 3 high-speed HDLC data compare register 0 HDLCCP0
01B116
01B216
Group 3 high-speed HDLC data mask register 0
HDLCMK0
01B316
01B416
Group 3 high-speed HDLC data compare register1
HDLCCP1
01B516
01B616
Group 3 high-speed HDLC data mask register 1
HDLCMK1
01B716
01B816
Group 3 high-speed HDLC data compare register 2 HDLCCP2
01B916
01BA16
Group 3 high-speed HDLC data mask register 2
HDLCMK2
01BB16
01BC16
Group 3 high-speed HDLC data compare register 3 HDLCCP3
01BD16
01BE16
Group 3 high-speed HDLC data mask register 3
HDLCMK3
01BF16
01C016
A-D1 register 0
AD10
01C116
01C216
A-D1 register 1
AD11
01C316
01C416
A-D1 register 2
AD12
01C516
01C616
A-D1 register 3
AD13
01C716
01C816
A-D1 register 4
AD14
01C916
01CA16
A-D1 register 5
AD15
01CB16
01CC16
A-D1 register 6
AD16
01CD16
01CE16
A-D1 register 7
AD17
01CF16
01D016
01D116
01D216
01D316
01D416 A-D1 control register 2
AD1CON2
01D516
01D616 A-D1 control register 0
AD1CON0
01D716 A-D1 control register 1
AD1CON1
01D816
01D916
01DA16
01DB16
01DC16
01DD16
01DE16
01DF16
The blank area is reserved and cannot be used by user.
41
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
Address
Register
01E016 CAN0 message slot buffer 0 standard ID0
C0SLOT0_0
01E116 CAN0 message slot buffer 0 standard ID1
C0SLOT0_1
01E216 CAN0 message slot buffer 0 extend ID0
C0SLOT0_2
01E316 CAN0 message slot buffer 0 extend ID1
C0SLOT0_3
01E416 CAN0 message slot buffer 0 extend ID2
C0SLOT0_4
01E516 CAN0 message slot buffer 0 data length code C0SLOT0_5
01E616 CAN0 message slot buffer 0 data 0
C0SLOT0_6
01E716 CAN0 message slot buffer 0 data 1
C0SLOT0_7
01E816 CAN0 message slot buffer 0 data 2
C0SLOT0_8
01E916 CAN0 message slot buffer 0 data 3
C0SLOT0_9
01EA16 CAN0 message slot buffer 0 data 4
C0SLOT0_10
01EB16 CAN0 message slot buffer 0 data 5
C0SLOT0_11
01EC16 CAN0 message slot buffer 0 data 6
C0SLOT0_12
01ED16 CAN0 message slot buffer 0 data 7
C0SLOT0_13
01EE16 CAN0 message slot buffer 0 time stamp highC0SLOT0_14
01EF16 CAN0 message slot buffer 0 time stamp low C0SLOT0_15
01F016 CAN0 message slot buffer 1 standard ID0
C0SLOT1_0
01F116 CAN0 message slot buffer 1 standard ID1
C0SLOT1_1
01F216 CAN0 message slot buffer 1 extend ID0
C0SLOT1_2
01F316 CAN0 message slot buffer 1 extend ID1
C0SLOT1_3
01F416 CAN0 message slot buffer 1 extend ID2
C0SLOT1_4
01F516 CAN0 message slot buffer 1 data length code C0SLOT1_5
01F616 CAN0 message slot buffer 1 data 0
C0SLOT1_6
01F716 CAN0 message slot buffer 1 data 1
C0SLOT1_7
01F816 CAN0 message slot buffer 1 data 2
C0SLOT1_8
01F916 CAN0 message slot buffer 1 data 3
C0SLOT1_9
01FA16 CAN0 message slot buffer 1 data 4
C0SLOT1_10
01FB16 CAN0 message slot buffer 1 data 5
C0SLOT1_11
01FC16 CAN0 message slot buffer 1 data 6
C0SLOT1_12
01FD16 CAN0 message slot buffer 1 data 7
C0SLOT1_13
01FE16 CAN0 message slot buffer 1 time stamp highC0SLOT1_14
01FF16 CAN0 message slot buffer 1 time stamp low C0SLOT1_15
020016
CAN0 control register 0
C0CTLR0
020116
020216
CAN0 status register
C0STR
020316
020416
CAN0 expansion ID register
C0IDR
020516
020616
CAN0 configuration register
C0CONR
020716
020816
CAN0 time stamp register
C0TSR
020916
020A16 CAN0 transmit error count register
C0TEC
020B16 CAN0 receive error count register
C0REC
020C16
CAN0 slot interrupt status register
C0SISTR
020D16
020E16
020F16
Address
Register
021016
CAN0 slot interrupt mask register
021116
021216
021316
021416 CAN0 error interrupt mask register
021516 CAN0 error interrupt status register
021616
021716 CAN0 baud rate prescaler
021816
021916
021A16
021B16
021C16
021D16
021E16
021F16
022016
022116
022216
022316
022416
022516
022616
022716
022816 CAN0 global mask register standard ID0
022916 CAN0 global mask register standard ID1
022A16 CAN0 global mask register extend ID0
022B16 CAN0 global mask register extend ID1
022C16 CAN0 global mask register extend ID2
022D16
022E16
022F16
023016 CAN0 message slot 0 control register /
CAN0 local mask register A standard ID0
023116 CAN0 message slot 1 control register /
CAN0 local mask register A standard ID1
023216 CAN0 message slot 2 control register /
CAN0 local mask register A extend ID0
023316 CAN0 message slot 3 control register /
CAN0 local mask register A extend ID1
023416 CAN0 message slot 4 control register /
CAN0 local mask register A extend ID2
023516 CAN0 message slot 5 control register
023616 CAN0 message slot 6 control register
023716 CAN0 message slot 7 control register
023816 CAN0 message slot 8 control register /
CAN0 local mask register B standard ID0
C0SIMKR
C0EIMKR
C0EISTR
C0BPR
C0GMR0
C0GMR1
C0GMR2
C0GMR3
C0GMR4
C0MCTL0/
C0LMAR0
C0MCTL1/
C0LMAR1
C0MCTL2/
C0LMAR2
C0MCTL3/
C0LMAR3
C0MCTL4/
C0LMAR4
C0MCTL5
C0MCTL6
C0MCTL7
C0MCTL8/
C0LMBR0
The blank area is reserved and cannot be used by user.
Note 1: CAN0 message slot i control registers (i=0 to 15) are allocated to addresses 023016 to 023F16 by switching
banks.
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
Address
Register
023916 CAN0 message slot 9 control register /
CAN0 local mask register B standard ID1
023A16 CAN0 message slot 10 control register /
CAN0 local mask register B extend ID0
023B16 CAN0 message slot 11 control register /
CAN0 local mask register B extend ID1
023C16 CAN0 message slot 12 control register /
CAN0 local mask register B extend ID2
023D16 CAN0 message slot 13 control register
023E16 CAN0 message slot 14 control register
023F16 CAN0 message slot 15 control register
024016 CAN0 slot buffer select register
024116 CAN0 control register 1
024216 CAN0 sleep control register
024316
024416
CAN0 acceptance filter support register
024516
Mitsubishi Microcomputers
C0MCTL9/
C0LMBR1
C0MCTL10/
C0LMBR2
C0MCTL11/
C0LMBR3
C0MCTL12/
C0LMBR4
C0MCTL13
C0MCTL14
C0MCTL15
C0SBS
C0CTLR1
C0SLPR
C0AFS
Address
Register
02C016
X0 register/Y0 register
02C116
02C216
X1 register/Y1 register
02C316
02C416
X2 register/Y2 register
02C516
02C616
X3 register/Y3 register
02C716
02C816
X4 register/Y4 register
02C916
02CA16
X5 register/Y5 register
02CB16
02CC16
X6 register/Y6 register
02CD16
02CE16
X7 register/Y7 register
02CF16
02D016
X8 register/Y8 register
02D116
02D216
X9 register/Y9 register
02D316
02D416
X10 register/Y10 register
02D516
02D616
X11 register/Y11 register
02D716
02D816
X12 register/Y12 register
02D916
02DA16
X13 register/Y13 register
02DB16
02DC16
X14 register/Y14 register
02DD16
02DE16
X15 register/Y15 register
02DF16
02E016 XY control register
02E116
02E216
02E316
02E416 UART1 special mode register 4
02E516 UART1 special mode register 3
02E616 UART1 special mode register 2
02E716 UART1 special mode register
02E816 UART1 transmit-receive mode register
02E916 UART1 bit rate generator
02EA16
UART1 transmit buffer register
02EB16
02EC16 UART1 transmit-receive control register 0
02ED16 UART1 transmit-receive control register 1
02EE16
UART1 receive buffer register
02EF16
X0R/Y0R
X1R/Y1R
X2R/Y2R
X3R/Y3R
X4R/Y4R
X5R/Y5R
X6R/Y6R
X7R/Y7R
X8R/Y8R
X9R/Y9R
X10R/Y10R
X11R/Y11R
X12R/Y12R
X13R/Y13R
X14R/Y14R
X15R/Y15R
XYC
U1SMR4
U1SMR3
U1SMR2
U1SMR
U1MR
U1BRG
U1TB
U1C0
U1C1
U1RB
The blank area is reserved and cannot be used by user.
43
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Rev.B2 for proof reading
030116
030216
030316
030416
030516
030616
030716
030816
030916
030A16
030B16
030C16
030D16
030E16
030F16
031016
031116
031216
031316
031416
031516
031616
031716
031816
031916
031A16
031B16
031C16
031D16
031E16
031F16
U4SMR4
U4SMR3
U4SMR2
U4SMR
U4MR
U4BRG
U4TB
U4C0
U4C1
U4RB
TBSR
Timer A1-1 register
TA11
Timer A2-1 register
TA21
Timer A4-1 register
TA41
Three-phase PWM control register 0
INVC0
Three-phase PWM control register 1
INVC1
Three-phase output buffer register 0
IDB0
Three-phase output buffer register 1
IDB1
Dead time timer
DTT
Timer B2 interrupt occurrence frequency set counter ICTB2
Timer B3 register
TB3
Timer B4 register
TB4
Timer B5 register
TB5
Timer B3 mode register
Timer B4 mode register
Timer B5 mode register
External interrupt cause select register
TB3MR
TB4MR
TB5MR
IFSR
The blank area is reserved and cannot be used by user.
44
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
Address
Register
02F016
02F116
02F216
02F316
02F416 UART4 special mode register 4
02F516 UART4 special mode register 3
02F616 UART4 special mode register 2
02F716 UART4 special mode register
02F816 UART4 transmit-receive mode register
02F916 UART4 bit rate generator
02FA16
UART4 transmit buffer register
02FB16
02FC16 UART4 transmit-receive control register 0
02FD16 UART4 transmit-receive control register 1
02FE16
UART4 receive buffer register
02FF16
030016 Timer B3,B4,B5 count start flag
Mitsubishi Microcomputers
Address
Register
032016
032116
032216
032316
032416 UART3 special mode register 4
032516 UART3 special mode register 3
032616 UART3 special mode register 2
032716 UART3 special mode register
032816 UART3 transmit-receive mode register
032916 UART3 bit rate generator
032A16
UART3 transmit buffer register
032B16
032C16 UART3 transmit-receive control register 0
032D16 UART3 transmit-receive control register 1
032E16
UART3 receive buffer register
032F16
033016
033116
033216
033316
033416
033516
033616
033716
033816
033916
033A16
033B16
033C16
033D16
033E16
033F16
034016
034116
034216
034316
034416
034516
034616
034716
034816
034916
034A16
034B16
034C16
034D16
034E16
034F16
UART2 special mode register 4
UART2 special mode register 3
UART2 special mode register 2
UART2 special mode register
UART2 transmit-receive mode register
UART2 bit rate generator
U3SMR4
U3SMR3
U3SMR2
U3SMR
U3MR
U3BRG
U3TB
U3C0
U3C1
U3RB
U2SMR4
U2SMR3
U2SMR2
U2SMR
U2MR
U2BRG
UART2 transmit buffer register
U2TB
UART2 transmit/receive control register 0
UART2 transmit/receive control register 1
U2C0
U2C1
UART2 receive buffer register
U2RB
Count start flag
Clock prescaler reset flag
One-shot start flag
Trigger select register
Up-down flag
TABSR
CPSRF
ONSF
TRGSR
UDF
Timer A0 register
TA0
Timer A1 register
TA1
Timer A2 register
TA2
Timer A3 register
TA3
Timer A4 register
TA4
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Rev.B2 for proof reading
036116
036216
036316
036416
036516
036616
036716
036816
036916
036A16
036B16
036C16
036D16
036E16
036F16
037016
037116
037216
037316
037416
037516
037616
037716
037816
037916
037A16
037B16
037C16
037D16
037E16
037F16
UART0 special mode register 4
UART0 special mode register 3
UART0 special mode register 2
UART0 special mode register
UART0 transmit/receive mode register
UART0 bit rate generator
TB0
TA1
TA2
TA0MR
TA1MR
TA2MR
TA3MR
TA4MR
TB0MR
TB1MR
TB2MR
TB2SC
TCSPR
U0SMR4
U0SMR3
U0SMR2
U0SMR
U0MR
U0BRG
UART0 transmit buffer register
U0TB
UART0 transmit/receive control register 0
UART0 transmit/receive control register 1
U0C0
U0C1
UART0 receive buffer register
U0RB
PLL control register 0
PLC0
DMA0 cause select register
DMA1 cause select register
DMA2 cause select register
DMA3 cause select register
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
Address
Register
035016
Timer B0 register
035116
035216
Timer B1 register
035316
035416
Timer B2 register
035516
035616 Timer A0 mode register
035716 Timer A1 mode register
035816 Timer A2 mode register
035916 Timer A3 mode register
035A16 Timer A4 mode register
035B16 Timer B0 mode register
035C16 Timer B1 mode register
035D16 Timer B2 mode register
035E16 Timer B2 special mode register
035F16 Count source prescaler register
036016
Mitsubishi Microcomputers
Address
038016
A-D0 register 0
038116
038216
A-D0 register 1
038316
038416
A-D0 register 2
038516
038616
A-D0 register 3
038716
038816
A-D0 register 4
038916
038A16
A-D0 register 5
038B16
038C16
A-D0 register 6
038D16
038E16
A-D0 register 7
038F16
039016
039116
039216
039316
039416
039516
039616
039716
039816
039916
039A16
039B16
039C16
039D16
039E16
039F16
Register
AD00
AD01
AD02
AD03
AD04
AD05
AD06
AD07
A-D0 control register 2
AD0CON2
A-D0 control register 0
A-D0 control register 1
D-A register 0
AD0CON0
AD0CON1
DA0
D-A register 1
D-A control register
DA1
DACON
DM0SL
DM1SL
DM2SL
DM3SL
CRC data register
CRCD
CRC input register
CRCIN
The blank area is reserved and cannot be used by user.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
<144-pin version>
Address
Register
03A016 Function select register A8
03A116 Function select register A9
03A216
03A316
03A416
03A516
03A616
03A716
03A816
03A916
03AA16
03AB16
03AC16
03AD16
03AE16
03AF16 Function select register C
03B016 Function select register A0
03B116 Function select register A1
03B216 Function select register B0
03B316 Function select register B1
03B416 Function select register A2
03B516 Function select register A3
03B616 Function select register B2
03B716 Function select register B3
03B816
03B916 Function select register A5
03BA16
03BB16
03BC16 Function select register A6
03BD16 Function select register A7
03BE16
03BF16
03C016 Port P6 register
03C116 Port P7 register
03C216 Port P6 direction register
03C316 Port P7 direction register
03C416 Port P8 register
03C516 Port P9 register
03C616 Port P8 direction register
03C716 Port P9 direction register
03C816 Port P10 register
03C916 Port P11 register
03CA16 Port P10 direction register
03CB16 Port P11 direction register
03CC16 Port P12 register
03CD16 Port P13 register
03CE16 Port P12 direction register
03CF16 Port P13 direction register
PS8
PS9
PSC
PS0
PS1
PSL0
PSL1
PS2
PS2
PSL2
PSL3
PS5
PS6
PS7
P6
P7
PD6
PD7
P8
P9
PD8
PD9
P10
P11
PD10
PD11
P12
P13
PD12
PD13
The blank area is reserved and cannot be used by user.
46
Address
Register
03D016 Port P14 register
03D116 Port P15 register
03D216 Port P14 direction register
03D316 Port P15 direction register
03D416
03D516
03D616
03D716
03D816
03D916
03DA16 Pull-up control register 2
03DB16 Pull-up control register 3
03DC16 Pull-up control register 4
03DD16
03DE16
03DF16
03E016 Port P0 register
03E116 Port P1 register
03E216 Port P0 direction register
03E316 Port P1 direction register
03E416 Port P2 register
03E516 Port P3 register
03E616 Port P2 direction register
03E716 Port P3 direction register
03E816 Port P4 register
03E916 Port P5 register
03EA16 Port P4 direction register
03EB16 Port P5 direction register
03EC16
03ED16
03EE16
03EF16
03F016 Pull-up control register 0
03F116 Pull-up control register 1
03F216
03F316
03F416
03F516
03F616
03F716
03F816
03F916
03FA16
03FB16
03FC16
03FD16
03FE16
03FF16 Port control register
P14
P15
PD14
PD15
PUR2
PUR3
PUR4
P0
P1
PD0
PD1
P2
P3
PD2
PD3
P4
P5
PD4
PD5
PUR0
PUR1
PCR
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
SFR
<100-pin version>
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
Address
Register
03A016
03A116
03A216
03A316
03A416
03A516
03A616
03A716
03A816
03A916
03AA16
03AB16
03AC16
03AD16
03AE16
03AF16 Function select register C
PSC
03B016 Function select register A0
PS0
03B116 Function select register A1
PS1
03B216 Function select register B0
PSL0
03B316 Function select register B1
PSL1
03B416 Function select register A2
PS2
03B516 Function select register A3
PS3
03B616 Function select register B2
PSL2
03B716 Function select register B3
PSL3
03B816
03B916
03BA16
03BB16
03BC16
03BD16
03BE16
03BF16
03C016 Port P6 register
P6
03C116 Port P7 register
P7
03C216 Port P6 direction register
PD6
03C316 Port P7 direction register
PD7
03C416 Port P8 register
P8
03C516 Port P9 register
P9
03C616 Port P8 direction register
PD8
03C716 Port P9 direction register
PD9
03C816 Port P10 register
P10
03C916
03CA16 1234567890123456789012345678901212345678901234567890123456789012
Port P10 direction register
PD10
1234567890123456789012345678901212345678901234567890123456789012
03CB16 1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
03CC16
03CD16 1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
03CE16 1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
03CF16 1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
12345678901234567890123456789
Address
Register
03D016
03D116 1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
03D216 1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
03D316 1234567890123456789012345678901212345678901234567890123456789012
1234567890123456789012345678901212345678901234567890123456789012
03D416
03D516
03D616
03D716
03D816
03D916
03DA16 Pull-up control register 2
PUR2
03DB1612345678901234567890123456789012123456789
Pull-up control register 3
PUR3
12345678901234567890123456789012123456789
03DC1612345678901234567890123456789012123456789
03DD16
03DE16
03DF16
03E016 Port P0 register
P0
03E116 Port P1 register
P1
03E216 Port P0 direction register
PD0
03E316 Port P1 direction register
PD1
03E416 Port P2 register
P2
03E516 Port P3 register
P3
03E616 Port P2 direction register
PD2
03E716 Port P3 direction register
PD3
03E816 Port P4 register
P4
03E916 Port P5 register
P5
03EA16 Port P4 direction register
PD4
03EB16 Port P5 direction register
PD5
03EC16
03ED16
03EE16
03EF16
03F016 Pull-up control register 0
PUR0
03F116 Pull-up control register 1
PUR1
03F216
03F316
03F416
03F516
03F616
03F716
03F816
03F916
03FA16
03FB16
03FC16
03FD16
03FE16
03FF16 Port control register
PCR
The blank area is reserved and cannot be used by user.
1234567
1234567
Note 1: 1234567
1234567 Addresses 03CB 16, 03CE 16 , 03CF16 , 03D216 , 03D316 does not exist in 100-pin version. Must set
"FF16" to the addresses at initial setting.
12345
12345
Note 2: 12345Addresses 03DC16 area does not exist in 100-pin version. Must set "0016" to addresses 03DC16 at initial setting.
1234
1234Addresses 03A016, 03A116, 03B916, 03BC16, 03BD16, 03C916, 03CC16, 03CD16, 03D3016, 03D116
Note 3:
does not exist in 100-pin version.
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Software Reset
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Software Reset
Writing “1” to bit 3 of the processor mode register 0 (address 000416) applies a (software) reset to the
microcomputer. A software reset has the same effect as a hardware reset. The contents of internal RAM
are preserved.
Processor Mode
(1) Types of Processor Mode
One of three processor modes can be selected: single-chip mode, memory expansion mode, and microprocessor mode. The functions of some pins, memory map, and access space differ according to the
selected processor mode.
• Single-chip mode
In single-chip mode, only internal memory space (SFR, internal RAM, and internal ROM) can be
accessed. Ports P0 to P15 can be used as programmable I/O ports or as I/O ports for the internal
peripheral functions.
• Memory expansion mode
In memory expansion mode, external memory can be accessed in addition to the internal memory
space (SFR, internal RAM, and internal ROM).
In this mode, some of the pins function as an address bus, a data bus, and as control signals. The
number of pins assigned to these functions depends on the bus and register settings. (See “Bus
Settings” for details.)
• Microprocessor mode
In microprocessor mode, the SFR, internal RAM and external memory space can be accessed. The
internal ROM area cannot be accessed.
In this mode, some of the pins function as the address bus, the data bus, and as control signals. The
number of pins assigned to these functions depends on the bus and register settings. (See “Bus
Settings” for details.)
(2) Setting Processor Modes
The processor mode is set using the CNVSS pin and the processor mode bits (bits 1 and 0 at address
000416). Do not set the processor mode bits to “102”.
Regardless of the level of the CNVSS pin, changing the processor mode bits selects the mode. Therefore, never change the processor mode bits when changing the contents of other bits. Also do not
attempt to shift to or from the microprocessor mode within the program stored in the internal ROM area.
• Applying VSS to CNVSS pin
The microcomputer begins operation in single-chip mode after being reset. Memory expansion mode
is selected by writing “012” to the processor mode is selected bits.
• Applying VCC to CNVSS pin
The microcomputer starts to operate in microprocessor mode after being reset.
Figure 1.6.1 and 1.6.2 show the processor mode register 0 and 1.
Figure 1.6.3 shows the memory maps applicable for each processor modes.
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Mitsubishi Microcomputers
M32C/83 group
Processor Mode
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Processor mode register 0 (Note 1)
b7
b6
0
b5
b4
b3
b2
b1
b0
Symbol
PM0
Bit
symbol
Address
000416
When reset
8016 (CNVss = "L")
0316 (CNVss = "H")
Bit name
Function
R W
b1 b0
PM00
PM01
0 0: Single-chip mode
0 1: Memory expansion mode
Processor mode bit
(Note 2) 1 0: Must not be set
1 1: Microprocessor mode
PM02
R/W mode select bit
0: RD / BHE / WR
(Note 3) 1: RD / WRH / WRL
PM03
Software reset bit
The device is reset when this bit is
set to "1". The value of this bit is "0"
when read
b5 b4
PM04
PM05
0 0 : Multiplexed bus is not used
Multiplexed bus space
0 1 : Allocated to CS2 space
select bit
0 1 : Allocated to CS1 space
(Note 4) 1 1 : Allocated to entire CS space
(Note 5)
Must always be set to "0"
Reserved bit
PM07
0 : BCLK is output
(Note 7)
1 : Function set by bit 0,1 of system
(Note 6)
clock control register 0
BCLK output disable bit
Note 1: Set bit 1 of the protect register (address 000A16) to "1" when writing new values to this register.
Note 2: Do not set the processor mode bits and other bits simultaneously when setting the processor
mode bits to 012 or 112 . Set the other bits first,and then change the processor mode bits.
Note 3: When using 16-bit bus width in DRAM controler, must set this bit to "1".
Note 4: Valid in microprocessor and memory expansion modes 1, 2 and 3. Do not use multiplex bus
when mode 0 is selected. Do not set to allocated to CS2 space when mode 2 is selected.
Note 5: After the reset has been released, the M32C/83 group MCU operates using the separate bus. As
a result, in microprocessor mode, you cannot select the full CS space multiplex bus.
When you select the full CS space multiplex bus in memory expansion mode, the address bus
operates with 64 Kbytes boundaries, for each chip select.
Mode 0: Multiplexed bus cannot be used.
Mode 1: CS0 to CS2 when you select full CS space.
Mode 2: CS0 to CS1 when you select full CS space.
Mode 3: CS0 to CS3 when you select full CS space.
Note 6: No BCLK is output in single chip mode even when "0" is set in PM07. When stopping clock
output in microprocessor or memory expansion mode, make the following settings: PM07="1", bit 0
(CM00) and bit 1 (CM01) of system clock control register 0 (address 000616) = "0". "L" is now
output from P53.
Note 7: When selecting BCLK, set bits 0 and 1 of system clock control register 0 (CM00, CM01) to "0".
Figure 1.6.1. Processor mode register 0
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Processor Mode
Processor mode register 1 (Note 1)
b7
0
b6
b5
b4
b3
b2
b1
b0
Symbol
PM1
Bit
symbol
When reset
0X0000002
Address
000516
Bit name
Function
R W
b1 b0
PM10
PM11
0 0 : Mode 0 (P44 to P47 : A20 to A23)
0 1 : Mode 1 (P44: A20,
P45 to P47: CS2 to CS0)
External memory area
mode bit
(Note 2) 1 0 : Mode 2 (P44, P45 : A20, A21,
P46, P47 : CS1, CS0)
1 1 : Mode 3
(Note 3)
(P44 to P47 : CS3 to CS0)
PM12
Internal memory wait bit
0 : No wait state
1 : Wait state inserted
PM13
SFR area wait bit 0
0 : One wait state inserted
1 : Two wait states inserted (Note 4)
b5 b4
PM14
PM15
0 0 : No ALE
0 1 : P53/BCLK
ALE pin select bit
(Note 2) 1 0 : P56/RAS
1 1 : P54/HLDA
(Note 5)
Nothing is assigned.
When write, set "0". When read, its content is indeterminate.
PM17
Reserved bit
Must set to "0"
Note 1: Set bit 1 of the protect register (address 000A16) to “1” when writing new values to this register.
Note 2: Valid in memory expansion mode or in microprocessor mode.
Note 3: When mode 3 is selected, DRAMC is not used.
Note 4: When accessing SFR area for CAN, PM13 must be set to "1".
Note 5: When selecting P53/BCLK, set bits 0 and 1 of system clock control register 0 (CM00, CM01) to "0".
Figure 1.6.2. Processor mode register 1
50
Internal reserved area
Internal ROM area
External area 3
Internal reserved area
Internal ROM area
No use
CS0
2Mbytes
External area 3
(External area 2)
(External area 2)
Each CS0 to CS3 can set 0 to 3 WAIT.
FFFFFF16 Internal ROM area
No use
Connect with
DRAM
0, 0.5 to 8MB
(When open area
is under 8MB,
cannot use the
rest of this area.)
CS2
2Mbytes
External area 1
CS1
2Mbytes
(Note1)
External area 0
SFR area
Internal RAM area
Internal reserved area
Connect with
DRAM
0, 0.5 to 8MB
(When not
connect with
DRAM, use as
external area.)
External area 1
External area 0
SFR area
Internal RAM area
Internal reserved area
Mode 1
Internal reserved area
Internal ROM area
CS0
3Mbytes
External area 3
(External area 2)
Connect with
DRAM
0, 0.5 to 8MB
(When open area
is under 8MB,
cannot use the
rest of this area.)
CS1
4Mbytes
(Note2)
External area 0
SFR area
Internal RAM area
Internal reserved area
Mode 2
External area 3
(External area 2)
Connect with
DRAM
0, 0.5 to 8MB
(When not
connect with
DRAM, use as
external area.)
External area 1
External area 0
SFR area
Internal RAM area
Internal reserved area
Mode 0
CS0
2Mbytes
External area 3
No use
(External area 2)
Connect with
DRAM
0, 0.5 to 8MB
(When open area
is under 8MB,
cannot use the
rest of this area.)
CS2
2Mbytes
External area 1
CS1
2Mbytes
(Note1)
External area 0
SFR area
Internal RAM area
Internal reserved area
Mode 1
Microprocessor mode
CS0
4Mbytes
External area 3
(External area 2)
Connect with
DRAM
0, 0.5 to 8MB
(When open area
is under 8MB,
cannot use the
rest of this area.)
CS1
4Mbytes
(Note2)
External area 0
SFR area
Internal RAM area
Internal reserved area
Mode 2
Note 1: 20000016–00800016=2016 Kbytes. 32 K less than 2 MB.
Note 2: 40000016–00800016=4064 Kbytes. 32 K less than 4 MB.
Internal reserved area
Internal ROM area
CS0, 1Mbytes
External area 3
No use
CS3, 1Mbytes
External area 2
(Cannot use as
DRAM area or
external area.)
No use
No use
CS1, 1Mbytes
External area 0
CS2, 1Mbytes
External area 1
No use
SFR area
Internal RAM area
Internal reserved area
Mode 3
CS0, 1Mbytes
External area 3
No use
CS3, 1Mbytes
External area 2
(Cannot use as
DRAM area or
external area.)
No use
No use
CS2, 1Mbytes
External area 1
CS1, 1Mbytes
External area 0
No use
SFR area
Internal RAM area
Internal reserved area
Mode 3
Rev.B2 for proof reading
F0000016
E0000016
C0000016
40000016
20000016
00080016
SFR area
Internal RAM area
Mode 0
Memory expanded mode
t
00040016
00000016
Single chip
mode
Processor Mode
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Mitsubishi Microcomputers
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
M32C/83 group
Figure 1.6.3. Memory maps in each processor mode
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Bus Settings
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Settings
The BYTE pin, bit 0 to 3 of the external data bus width control register (address 000B16), bits 4 and 5 of the
processor mode register 0 (address 000416) and bit 0 and 1 of the processor mode register 1 (address
000516) are used to change the bus settings.
Table 1.7.1 shows the factors used to change the bus settings, figure 1.7.1 shows external data bus width
control register and table 1.7.2 shows external area 0 to 3 and external area mode.
Table 1.7.1. Factors for switching bus settings
Bus setting
Switching external address bus width
Switching external data bus width
Switching between separate and multiplex bus
Selecting external area
Switching factor
External data bus width control register
BYTE pin (external area 3 only)
Bits 4 and 5 of processor mode register 0
Bits 0 and 1 of processor mode register 1
(1) Selecting external address bus width
You can select the width of the address bus output externally from the 16 Mbytes address space, the
number of chip select signals, and the address area of the chip select signals. (Note, however, that
____
when you select “Full CS space multiplex bus”, addresses A0 to A15 are output.) The combination of bits
0 and 1 of the processor mode register 1 allow you to set the external area mode.
When using DRAM controller, the DRAM area is output by multiplexing of the time splitting of the row
and column addresses.
(2) Selecting external data bus width
You can select 8-bit or 16-bit for the width of the external data bus for external areas 0, 1, 2, and 3. When
the data bus width bit of the external data bus width control register is “0”, the data bus width is 8 bits;
when “1”, it is 16 bits. The width can be set for each of the external areas. The default bus width for
external area 3 is 16 bits when the BYTE pin is “L” after a reset, or 8 bits when the BYTE pin is “H” after
a reset. The bus width selection is valid only for the external bus (the internal bus width is always 16
bits).
During operation, fix the level of the BYTE pin to “H” or “L”.
(3) Selecting separate/multiplex bus
The bus format can be set to multiplex or separate bus using bits 4 and 5 of the processor mode register 0.
• Separate bus
In this bus configuration, input and output is performed on separate data and address buses. The data
bus width can be set to 8 bits or 16 bits using the external data bus width control register. For all
programmable external areas, P0 is the data bus when the external data bus is set to 8 bits, and P1 is
a programmable IO port. When the external data bus width is set to 16 bits for any of the external
areas, P0 and P1 (although P1 is undefined for any 8-bit bus areas) are the data buses.
When accessing memory using the separate bus configuration, you can select a software wait using
the wait control register.
• Multiplex bus
In this bus configuration, data and addresses are input and output on a time-sharing basis. For areas
for which 8-bit has been selected using the external data bus width control register, the 8 bits D0 to D7
are multiplexed with the 8 bits A0 to A7. For areas for which 16-bit has been selected using the external
data bus width control register, the 16 bits D0 to D15 are multiplexed with the 16 bits A0 to A15. When
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Settings
accessing memory using the multiplex bus configuration, two waits are inserted regardless of whether
you select “No wait” or “1 wait” in the appropriate bit of the wait control register.
____
The default after a reset is a separate bus configuration, and the full CS space multiplex bus configu____
ration cannot be selected in microprocessor mode. If you select “Full CS space multiplex bus”, the 16
bits from A0 to A15 are output for the address
External data bus width control register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
DS
Bit symbol
DS0
Address
000B16
When reset
XXXXX0002
Bit name
Function
External area 0 data bus
width bit
External area 1 data bus
width bit
DS2
External area 2 data bus
width bit
0 : 8 bits data bus width
1 : 16 bits data bus width
0 : 8 bits data bus width
1 : 16 bits data bus width
0 : 8 bits data bus width
1 : 16 bits data bus width
DS3
External area 3 data bus
width bit (Note)
0 : 8 bits data bus width
1 : 16 bits data bus width
DS1
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
AA
A
AA
A
AA
A
AA
A
R W
Note: The value after a reset is determined by the input via the BYTE pin.
When BYTE pin is "L", DS3 is "1". When "H", it is "0".
Figure 1.7.1. External data bus width control register
Table 1.7.2. External area 0 to 3 and external area mode
External area mode
Mode 0
Mode 1
Memory expansion mode,
Microprocessor mode
00800016 to
1FFFFF16
<CS1 area>
00800016 to
1FFFFF16
Memory expansion mode,
Microprocessor mode
20000016 to
3FFFFF16
<CS2 area>
20000016 to
3FFFFF16
Memory expansion mode,
Microprocessor mode
40000016 to
BFFFFF16
External
area 3
External External External
area 1 area 0
area 2
(Note 2)
(Note 1)
Mode 2
<CS1 area>
00800016 to
1FFFFF16
No area is
selected.
<DRAMC area> <DRAMC area>
40000016 to
40000016 to
BFFFFF16
BFFFFF16
Mode 3
<CS1 area>
10000016 to
1FFFFF16
<CS2 area>
20000016 to
2FFFFF16
<CS3 area>
C0000016 to
CFFFFF16
Memory expansion mode
C0000016 to
EFFFFF16
<CS0 area>
C0000016 to
EFFFFF16
<CS0 area>
C0000016 to
EFFFFF16
<CS0 area>
E0000016 to
EFFFFF16
Microprocessor mode
C0000016 to
FFFFFF16
<CS0 area>
E0000016 to
FFFFFF16
<CS0 area>
C0000016 to
FFFFFF16
<CS0 area>
F0000016 to
FFFFFF16
Note 1: DRAMC area when using DRAMC.
Note 2: Set the external area mode (modes 0, 1, 2, and 3) using bits 0 and 1 of the processor mode register
1 (address 000516).
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Bus Settings
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Table 1.7.3. Each processor mode and port function
Processor
mode
Single-chip
mode
Multiplexed
bus space
select bit
“01”, “10”
CS1 or CS2 : multiplexed
bus, and the other :
separate bus
Data bus width
BYTE pin level
Memory
expansion mode
Memory expansion mode/microprocessor modes
“00”
“11” (Note 1)
Separate bus
All space multiplexed
bus
All external
area is 8 bits
Some external
area is 16 bits
All external
area is 8 bits
Some external
area is 16 bits
All external
area is 8 bits
Some external
area is 16 bits
P00 to P07
I/O port
Data bus
Data bus
Data bus
Data bus
I/O port
I/O port
P10 to P17
I/O port
I/O port
I/O port
Data bus
I/O port
I/O port
I/O port
P20 to P27
I/O port
Address bus
/data bus
Address bus
/data bus
Address bus
Address bus
Address bus
/data bus
Address bus
/data bus
P30 to P37
I/O port
Address bus
Address bus
Address bus
Address bus
Address bus
/data bus
Address bus
Address bus
I/O port
I/O port
(Note 2)
(Note 2)
Address bus
/data bus
(Note 2)
P40 to P43
I/O port
Address bus
P44 to P46
I/O port
CS (chip select) or address bus (A23)
(For details, refer to “Bus control”) (Note 5)
P47
I/O port
CS (chip select) or address bus (A23)
(For details, refer to “Bus control”) (Note 5)
P50 to P53
I/O port
Outputs RD, WRL, WRH, and BCLK or RD, BHE, WR, and BCLK
(For details, refer to “Bus control”) (Note 3,4)
P54
I/O port
HLDA(Note 3)
P55
I/O port
HOLD
HOLD
HOLD
HOLD
HOLD
HOLD
P56
I/O port
RAS (Note 3)
RAS (Note 3)
RAS (Note 3)
RAS (Note 3)
RAS (Note 3)
RAS (Note 3)
P57
I/O port
RDY
RDY
RDY
RDY
RDY
RDY
Address bus
HLDA(Note 3) HLDA(Note 3) HLDA(Note 3)
HLDA(Note 3) HLDA(Note 3)
Note 1:The default after a reset is the separate bus configuration, and "Full CS space multiplex bus" cannot be selected in
microprocessor mode. When you select "Full CS space multiplex bus" in extended memory mode, the address bus
operates with 64 Kbytes boundaries for each chip select.
Note 2: Address bus in separate bus configuration.
Note 3: The ALE output pin is selected using bits 4 and 5 of the processor mode register 1.
Note 4: When you have selected the DRAM controller and access the DRAM area, these are outputs CASL, CASH, DW, and
BCLK.
Note 5: The CS signal and address bus selection are set by the external area mode.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
Bus Control
The following explains the signals required for accessing external devices and software waits. The signals
required for accessing the external devices are valid when the processor mode is set to memory expansion mode and microprocessor mode.
(1) Address bus/data bus
_____
There are 24 pins, A0 to A22 and A23 for the address bus for accessing the 16 Mbytes address space.
_____
A23 is an inverted output of the MSB of the address.
The data bus consists of pins for data IO. The external data bus control register (address 000B16)
selects the 8-bit data bus, D0 to D7 for each external area, or the 16-bit data bus, D0 to D15. After a reset,
there is by default an 8-bit data bus for the external area 3 when the BYTE pin is High, or a 16-bit data
bus when the BYTE pin is Low.
When shifting from single-chip mode to extended memory mode, the value on the address bus is undefined until an external area is accessed.
When accessing a DRAM area with DRAM control in use, a multiplexed signal consisting of row address
and column address is output to A8 to A20.
(2) Chip select signals
_____
The chip select signals share A0 to A22 and A23. You can use bits 0 and 1 of the processor mode register
1 (address 000516) to set the external area mode, then select the chip select area and number of
address outputs.
In microprocessor mode, external area mode 0 is selected after a reset. The external area can be split
into a maximum of four Blocks or Areas using the chip select signals. Table 1.7.4 shows the external
areas specified by the chip select signals.
Table 1.7.4. External areas specified by the chip select signals
Memory space
expansion
mode
Chip select signal
Processor mode
CS0
CS1
CS2
CS3
(A23)
(A22)
(A21)
(A20)
00800016 to
1FFFFF16
(2016 Kbytes)
20000016 to
3FFFFF16
(2 Mbytes)
(A20)
00800016 to
3FFFFF16
(4064 Kbytes)
(A21)
(A20)
10000016 to
1FFFFF16
(1 Mbytes)
20000016 to
2FFFFF16
(1 Mbytes)
C0000016 to
CFFFFF16
(1 Mbytes)
Specified address range
Mode 0
Memory expansion mode
Mode 1
C0000016 to
DFFFFF16
(2 Mbytes)
Microprocessor mode
E0000016 to
FFFFFF16
(2 Mbytes)
Memory expansion mode
C0000016 to
EFFFFF16
(3 Mbytes)
Microprocessor mode
C0000016 to
FFFFFF16
(4 Mbytes)
Memory expansion mode
E0000016 to
EFFFFF16
(1 Mbytes)
Mode 2
Mode 3
Microprocessor mode
F0000016 to
FFFFFF16
(1 Mbytes)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
The chip select signal turns Low (active) in synchronize with the address bus. However, its turning High
depends on the area accessed in the next cycle. Figure 1.7.2 shows the output examples of the address
bus and chip select signals.
Example 1: After accessing the external area, the
address bus and chip select signal both are
changed in the next cycle.
The following example shows the other chip select
signal accessing area (j) in the cycle after having
accessed external area (i). In this case, the address
bus and chip select signal both change between the
two cycles.
Example 2: After accessing the external area, only the
chip select signal is changed in the next
cycle. (The address bus does not change.)
The following example shows the CPU accesses the
internal ROM/RAM area in the cycle after having
accessed external area. In this case, the chip select
signal changes between the two cycles but the
address bus does not.
Access to Access to
external internal
ROM/RAM
area
area
Access to Access to
external external
area (j)
area (i)
Data bus
Data
Data
Data bus
Data
Address bus
Address bus
Address
Chip select
(CSi)
Address
Chip select
Chip select
(CSj)
Example 3: After accessing the external area, only the
address bus is changed in the next cycle.
(The chip select signal does not change.)
The following example shows the same chip select
signal accessing area (i) in the cycle after having
accessed external area (i). In this case, the address
bus changes between the two cycles, but the chip
select signal does not.
Example 4: After accessing the external area, the
address bus and chip select signal both are
not changed in the next cycle.
The following example shows CPU does not access
any area in the cycle after having accessed external
area (no instruction pre-fetch is occurred). In this
case, the address bus and the chip select signal do
not change between the two cycles.
Access to Access to
external external
area (i)
area (i)
Data bus
Address bus
Chip select
(CSi)
Data
Address
Data
Access to
external
No access
area
Data bus
Address bus
Data
Address
Chip select
Note: These examples show the address bus and chip select signal for two consecutive cycles.
By combining these examples, chip select signal can be extended beyond two cycles.
Figure 1.7.2. Example of address bus and chip select signal outputs (Separate bus)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
(3) Read/write signals
With a 16-bit data bus, bit 2 of the processor mode register 0 (address 000416) selects the combinations
_____ ________
______
_____ ________
_________
of RD, BHE, and WR signals or RD, WRL, and WRH signals. With a 8-bit full space data bus, use the
_____ ______
________
combination of RD, WR, and BHE signals as read/write signals. (Set "0" to bit 2 of the processor mode
register 0 (address 000416).) When using both 8-bit and 16-bit data bus widths to access a 8-bit data bus
_____ ______
________
area, the RD, WR and BHE signals combination is selected regardless of the value of bit 2 of the
processor mode register 0 (address 000416).
Tables 1.7.5 and 1.7.6 show the operation of these signals.
_____ ______
________
After a reset has been cancelled, the combination of RD, WR, and BHE signals is automatically selected.
_____ _________
_________
When switching to the RD, WRL, and WRH combination, do not write to external memory until bit 2 of
the processor mode register 0 (address 000416) has been set (Note).
Note 1: Before attempting to change the contents of the processor mode register 0, set bit 1 of the
protect register (address 000A16) to “1”.
_____ ________
_________
Note 2: When using 16-bit data bus width for DRAM controller, select RD, WRL, and WRH signals.
_____
________
_________
Table 1.7.5. Operation of RD, WRL, and WRH signals
Data bus width
RD
WRL
WRH
L
H
H
H
L
H
16-bit
H
H
L
H
L
L
L (Note)
H
Not used
8-bit
H (Note)
L
Not used
______
Note: It becomes WR signal.
_____
______
Status of external data bus
Read data
Write 1 byte of data to even address
Write 1 byte of data to odd address
Write data to both even and odd addresses
Write 1 byte of data
Read 1 byte of data
________
Table 1.7.6. Operation of RD, WR, and BHE signals
Data bus width
16-bit
8-bit
RD
H
L
H
L
H
L
H
L
WR
L
H
L
H
L
H
L
H
BHE
L
L
H
H
L
L
Not used
Not used
A0
H
H
L
L
L
L
H/L
H/L
Status of external data bus
Write 1 byte of data to odd address
Read 1 byte of data from odd address
Write 1 byte of data to even address
Read 1 byte of data from even address
Write data to both even and odd addresses
Read data from both even and odd addresses
Write 1 byte of data
Read 1 byte of data
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
(4) ALE signal
The ALE signal latches the address when accessing the multiplex bus space. Latch the address when
the ALE signal falls. The ALE output pin is selected using bits 4 and 5 of the processor mode register 1
(address 000516).
The ALE signal is occurred regardless of internal area and external area.
When BYTE pin = “L”
When BYTE pin = “H”
ALE
ALE
Address
D0/A0 to D7/A7
A8 to A15
Data
(Note 1)
D0/A0 to D15/A15
Address
(Note 1)
Data
Address
A16 to A19
Address
A20 to A22, A23
(Note 2)
Address (Note 2)
A16 to A19
A20 to A22, A23
Address or CS
Address or CS
Note 1: Floating when reading.
Note 2: When full space multiplexed bus is selected, these are I/O ports.
Figure 1.7.3. ALE signal and address/data bus
(5) Ready signal
The ready signal facilitates access of external devices that require a long time for access. As shown in
________
Figure 1.7.2, inputting “L” to the RDY pin at the falling edge of BCLK causes the microcomputer to enter
________
the ready state. Inputting “H” to the RDY pin at the falling edge of BCLK cancels the ready state. Table
_____
1.7.7 shows the microcomputer status in the ready state. Figure 1.7.4 shows the example of the RD
________
signal being extended using the RDY signal.
Ready is valid when accessing the external area during the bus cycle in which the software wait is
________
applied. When no software wait is operating, the RDY signal is ignored, but even in this case, unused
pins must be pulled up.
Table 1.7.7. Microcomputer status in ready state (Note)
Item
Status
Oscillation
_____ _____
On
_____
RD/WR signal, address bus, data bus, CS
__________
ALE signal, HLDA, programmable I/O ports
Internal peripheral circuits
Maintain status when ready signal received
On
Note: The ready signal cannot be received immediately prior to a software wait.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
Separate bus (2 wait)
1st cycle
2nd cycle
3rd cycle
4th cycle
BCLK
AAAAAAAA
AAAAAAAA
RD
CSi
(i=0 to 3)
(Note)
RDY
tsu(RDY - BCLK)
RDY received timing
Multiplexed bus (2 wait)
1st cycle
2nd cycle
3rd cycle
4th cycle
BCLK
AAAAAA
AAAAAA
RD
CSi
(i=0 to 3)
(Note)
RDY
tsu(RDY - BCLK)
AA
: Wait using RDY signal
RDY received timing
: Wait using software
tsu(RDY-BCLK)=RDY input setup time
RDY signal received timing for i wait(s): i + 1 cycles (i = 1 to 3)
Note: Chip select (CSi) may get longer by a state of CPU such as an instruction queue buffer.
_____
________
Figure 1.7.4. Example of RD signal extended by RDY signal
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
(6) Hold signal
The hold signal is used to transfer the bus privileges from the CPU to the external circuits. Inputting “L”
__________
to the HOLD pin places the microcomputer in the hold state at the end of the current bus access. This
__________
__________
status is maintained and “L” is output from the HLDA pin as long as “L” is input to the HOLD pin. Table
1.7.8 shows the microcomputer status in the hold state. The bus is used in the following descending
__________
order of priority: HOLD, DMAC, CPU.
__________
HOLD > DMAC > CPU
_____
________
Figure 1.7.5. Example of RD signal extended by RDY signal
Table 1.7.8. Microcomputer status in hold state
Item
Status
Oscillation
ON
_____ _____
_____
_______
RD/WR signal, address bus, data bus, CS, BHE
Programmable I/O ports: P0 to P15
Floating
Maintains status when hold signal is received
__________
HLDA
Internal peripheral circuits
ALE signal
Output “L”
ON (but watchdog timer stops)
Output “L”
(7) External bus status when accessing to internal area
Table 1.7.9 shows external bus status when accessing to internal area
Table 1.7.9. External bus status when accessing to internal area
Item
Address bus
SFR accessing status
Internal ROM/RAM accessing status
Remain address of external area accessed immediately before
Data bus When read
Floating
When write
Floating
_____
______
________
_________
RD, WR, WRL, WRH
Output "H"
________
BHE
Remain external area status accessed immediately before
____
CS
Output "H"
ALE
ALE output
(8) BCLK output
BCLK output can be selected by bit 7 of the processor mode register 0 (address 000416 :PM07) and bit
1 and bit 0 of the system clock select register 0 (address 000616 :CM01, CM00). Setting PM07 to “0”
and CM01 and CM00 to “00” outputs the BCLK signal from P53. However, in single chip mode, BCLK
signal is inactive. When setting PM07 to “1”, the function is set by CM01 and CM00.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
_______
__________
__________
_____
(9) DRAM controller signals (RAS, CASL, CASH, and DW)
Bits 1, 2, and 3 of the DRAM control register (address 000416) select the DRAM space and enable the
DRAM controller. The DRAM controller signals are output when the DRAM area is accessed. Table
1.7.10 shows the operation of the respective signals.
_______
__________
__________
_____
Table 1.7.10. Operation of RAS, CASL, CASH, and DW signals
Data bus width
16-bit
8-bit
RAS
L
L
L
L
L
L
L
L
CASL
L
L
L
L
L
H
L
L
CASH
L
H
H
L
H
L
Not used
Not used
DW
H
H
H
L
L
L
H
L
Status of external data bus
Read data from both even and odd addresses
Read 1 byte of data from even address
Read 1 byte of data from odd address
Write data to both even and odd addresses
Write 1 byte of data to even address
Write 1 byte of data to odd address
Read 1 byte of data
Write 1 byte of data
(10) Software wait
A software wait can be inserted by setting the wait control register (address 000816). Figure 1.7.6 shows
wait control register.
You can use the external area i wait bits (where i = 0 to 3) of the wait control register to specify from “No
wait” to “3 waits” for the external memory area. When you select “No wait”, the read cycle is executed in
the BCLK1 cycle. The write cycle is executed in the BCLK2 cycle (which has 1 wait). When accessing
external memory using the multiplex bus, access has two waits regardless of whether you specify “No
wait” or “1 wait” in the appropriate external area i wait bits in the wait control register.
Software waits in the internal memory (internal RAM and internal ROM) can be set using the internal
memory wait bits of the processor mode register 1 (address 000516). Setting the internal memory wait
bit = “0” sets “No wait”. Setting the internal memory wait bit = “1” specifies a wait.
SFR area is accessed with either "1 wait" (BCLK 2-cycle) or "2 waits" (BCLK 3-cycle) by setting the SFR
wait bit (bit 3) of the processor mode register 1 (address 000516). SFR area of CAN must be accessed
with "2 waits".
Table 1.7.11 shows the software waits and bus cycles. Figures 1.7.7 and 1.7.8 show example bus timing
when using software waits.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
Wait control register (Note 1, 2)
b7 b6 b5 b4 b3
b2 b1 b0
Symbol
WCR
Address
000816
Bit symbol
WCR0
Bit name
External area 0
wait bit
WCR1
WCR2
External area 1
wait bit
WCR3
WCR4
Function
b1 b0
0 0: Without wait
0 1: With 1 wait
1 0: With 2 waits
1 1: With 3 waits
b3 b2
0 0: Without wait
0 1: With 1 wait
1 0: With 2 waits
1 1: With 3 waits
b5 b4
External area 2
wait bit
0 0: Without wait
0 1: With 1 wait
1 0: With 2 waits
1 1: With 3 waits
External area 3
wait bit
0 0: Without wait
0 1: With 1 wait
1 0: With 2 waits
1 1: With 3 waits
WCR5
WCR6
When reset
FF16
b7 b6
WCR7
AA
A
A
AA
A
AA
A
AA
AA
AA
A
A
AA
AA
R W
Note 1: When using the multiplex bus configuration, there are two waits regardless of whether you have
specified "No wait" or "1 wait". However, you can specify "2 waits" or "3 waits".
Note 2: When using the separate bus configuration, the read bus cycle is executed in the BCLK1 cycle,
and the write cycle is executed in the BCLK2 cycle (with 1 wait).
Figure 1.7.6. Wait control register
Table 1.7.11. Software waits and bus cycles
Area
Bus status
Internal
memory wait bit
External memory
area i wait bit
Internal
ROM/RAM
Separate bus
External
memory
area
Multiplex bus
Bus cycle
2 BCLK cycles
0
1
SFR
62
SFR area
wait bit
0
3 BCLK cycles
1 BCLK cycle
1
2 BCLK cycles
002
Read :1 BCLK cycle
Write : 2 BCLK cycles
012
2 BCLK cycles
102
3 BCLK cycles
112
4 BCLK cycles
002
3 BCLK cycle
012
3 BCLK cycles
102
3 BCLK cycles
112
4 BCLK cycles
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
< Separate bus (no wait) >
Mitsubishi Microcomputers
Bus cycle (Note)
Bus cycle (Note)
BCLK
Write signal
Read signal
Data bus
Address bus (Note 2)
Output
Address
Input
Address
Chip select (Note 2,3)
< Separate bus (with wait) >
Bus cycle (Note)
Bus cycle (Note)
BCLK
Write signal
Read signal
Output
Data bus
Address bus (Note 2)
Address
Input
Address
Chip select (Note 2,3)
< Separate bus with 2 wait >
Bus cycle (Note 1)
Bus cycle (Note 1)
BCLK
Write signal
Read signal
Data bus
Data output
Address bus (Note 2)
Address
Input
Address
Chip select (Note 2,3)
Note 1: This timing example shows bus cycle length. Read cycle and write cycle may be continued after this
bus cycle.
Note 2: Address bus and chip select may get longer depending on the state of CPU such as an instruction
queue buffer.
Note 3: When accessing same external area (same CS area) continuously, chip select may output
continuously.
Figure 1.7.7. Typical bus timings using software wait
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bus Control
< Separate bus (with 3 wait) >
Bus cycle (Note)
Bus cycle (Note)
BCLK
Write signal
Read signal
Data bus
Data output
Address
(Note 2)
Input
Address
Address
Chip select
(Note 2,3)
< Multiplexed bus (with 2 wait) >
Bus cycle (Note)
Bus cycle (Note)
BCLK
Write signal
Read signal
ALE
Address
Address
Address bus/Data bus
(Note 2)
Address
Data output
Address
Address
Input
Chip select
(Note 2,3)
< Multiplexed bus (with 3 wait) >
Bus cycle (Note)
Bus cycle (Note)
BCLK
Write signal
Read signal
Address
Address
Address bus
/Data bus (
Note 2)
Address
Data output
Address
Address
Input
ALE
Chip select
(Note 2,3)
Note 1: This timing example shows bus cycle length. Read cycle and write cycle may be continued after this
bus cycle.
Note 2: Address bus and chip select may get longer depending on the state of CPU such as an instruction
queue buffer.
Note 3: When accessing same external area (same CS area) continuously, chip select may output
continuously.
Figure 1.7.8. Typical bus timings using software wait
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
System Clock
Clock Generating Circuit
The clock generating circuit contains three oscillator circuits as follows:
(1) Main clock generating circuit
(2) Sub clock generating circuit
(3) Ring oscillator (oscillation stop detect function)
Table 1.8.1 lists the clock generating circuit specifications and Table 1.8.2 lists registers controlling each
clock generating circuit. Figure 1.8.1 shows block diagram of the system clock generating circuit. Figure
1.8.2 to 1.8.5 show clock control related registers.
Table 1.8.1. The clock oscillation circuit specifications
Item
Use of clock
Main clock
generating circuit
Sub clock
generating circuit
• CPU's operating
• CPU's operating
clock source
clock source
• Internal peripheral • Timer A/B's count
unit's operating
clock source
clock source
Ring oscillator
• CPU's operating
clock source when
main clock
frequency stops
Clock frequency
0 to 30 MHz
32.768 kHz
About 1 MHz
Usable oscillator
• Ceramic oscillator
• Crystal oscillator
• Crystal oscillator
Pins to connect
oscillator
XIN, XOUT
XCIN, XCOUT
Oscillation stop/
restart function
Presence
Presence
Presence
Oscillator status
after reset
Oscillating
Stopped
Stopped
Other
Externally derived clock can be input
Table 1.8.2. Control registers for each clock generating circuits
Clock generating circuit
Main clock
Sub clock
Oscillation stop detect function
Control register
System clock control register 0 (address 000616) :CM0
System clock control register 1 (address 000716) :CM1
Main clock divide register (address 000C16) : MCD
System clock control register 0 (address 000616) : CM0
System clock control register 1 (address 000716) :CM1
Oscillation stop detect register (address 000D16) : CM2
Note : CM0, CM1, CM2 and MCD registers are protected from a false write by program runaway. When you
want to rewrite these registers, set "1" to bit 0 of protect register (address 000A16) to release protect,
then rewrite the register.
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
Main clock
XIN
XOUT
fAD
Ring oscillator
circuit
f1
CM05
a
Divider 1
c
Sub clock
XCIN XCOUT
S Q
R
(Wait mode) WAIT instruction
b
f8
CM21
CM02
Divider 2
e
Divider 3
d
f2n
f
CM07
BCLK
fC
Software reset
CM04
RESET
1/32
NMI
fC32
Interrupt request level
judgment output
(Stop mode) Write "1" to CM10
S Q
R
CM0i : Bit i at system clock control register 0 (address 000616)
CM1i : Bit i at system clock control register 1 (address 000716)
CM2i : Bit i at oscillation stop detect register (address 000D16)
Divider 1
a
Divider 2
1/2
1/2
1/2
b
Bit 7 at address 035F16
c
1/n
d
1/2
Divide rate 2n (n=0 to 15) is set by bit 0 to 3 at count source prescaler register (address 035F16)
Divider 3
e
1/m
f
Divide rate m (m=1,2,3,4,6,8,10,12,14,16 ) is set by bit 0 to 4 at main clock divide register (address 000C16)
Ring
oscillator
Clock
from
XIN
Clock edge detect
/charge and
discharge
circuit control
Charge and
discharge
circuit
Interrupt
generating
circuit
Interrupt
request signal
Watchdog timer
interrupt
Ring oscillator circuit
Ring oscillator
clock
CM21 switch
select signal
Figure 1.8.1. Clock generating circuit
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
System clock control register 0 (Note 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
CM0
Bit symbol
CM00
Address
000616
Bit
name
Clock output function
select bit (Note 2)
CM01
CM02
WAIT peripheral
function clock stop bit
When reset
0000 X0002
Function
b1 b0
0 0 : I/O port P53
0 1 : fC output
1 0 : f8 output
1 1 : f32 output
0 : Do not stop peripheral clock
in wait mode
1 : Stop peripheral clock in
wait mode
(Note 3)
A
A
AA
A
AA
A
AA
A
A
AA
A
A
AA
RW
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Port XC select bit
0 : I/O port
CM04
1 : XCIN-XCOUT generation (Note 4)
CM05
Main clock (XIN-XOUT)
stop bit (Note 5)
0 : Main clock On
1 : Main clock Off (Note 6)
CM06
Watchdog timer
function select bit
0 : Watchdog timer interrupt
1 : Reset (Note 7)
CM07
System clock select bit 0 : XIN, XOUT
(Note 8)
1 : XCIN, XCOUT
Note 1: Set bit 0 of the protect register (address 000A16) to “1” before writing to this register.
Note 2: The port P53 dose not function as an I/O port in microprocessor or memory expansion
mode.
When outputting ALE to P53 (bits 5 and 4 of processor mode register 0 is "01"), set
these bits to "00".
The port P53 function is not selected, even when you set "00" in microprocessor or
memory expansion mode and bit 7 of the processor mode register 0 is "1".
Note 3: fc32 is not included. When this bit is set to "1", PLL cannot be used in WAIT.
Note 4: When XcIN-XcOUT is used, set port P86 and P87 to no pull-up resistance with the input
port.
Note 5: When entering the power saving mode, the main clock is stopped using this bit. To stop
the main clock, set system clock stop bit (CM07) to "1" while an oscillation of sub clock is
stable. Then set this bit to "1".
When XIN is used after returning from stop mode, set this bit to "0".
When this bit is "1", XOUT is "H". Also, the internal feedback resistance remains ON, so
XIN is pulled up to XOUT ("H" level) via the feedback resistance.
Note 6: When the main clock is stopped, the main clock division register (address 000C16) is set
to the division by 8 mode.
However, in ring oscillator mode, the main clock division register is not set to the division
by 8 mode when XIN-XOUT is stopped by this bit.
Note 7: When "1" has been set once, "0" cannot be written by software.
Note 8: Set this bit "0" to "1" when sub clock oscillation is stable by setting CM04 to "1".
Set this bit "1" to "0" when main clock oscillation is stable by setting CM05 to "0".
Do not set CM04 and CM05 simultaneously.
Figure 1.8.2. Clock control related register (1)
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
System clock control register 1 (Note 1)
b7 b6 b5 b4 b3 b2 b1 b0
0
0
1 0
0 0
0
Symbol
CM1
Bit symbol
CM10
Address
000716
When reset
001000002
Bit
Function
name
All clock stop control bit 0 : Clock on
1 : All clocks off (stop mode) (Note 3)
(Note 2)
Reserved bit
Must set to “0”
Reserved bit
Must set to “1”
Reserved bit
Must set to “0”
AA
AA
AA
A
RW
Note 1: Set bit 0 of the protect register (address 000A16) to “1” before writing to this register.
Note 2: When this bit is "1", XOUT is "H", and the internal feedback resistance is disabled. XCIN
and XCOUT are high-inpedance.
Note 3: When all clocks are stopped (stop mode), the main clock division register
(address 000C16) is set to the division by 8 mode.
Main clock division register (Note 1)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
MCD
Bit symbol
MCD0
Address
000C16
When reset
XXX010002
Bit name
Main clock division select
bit (Note 2, 4)
MCD1
MCD2
MCD3
MCD4
Function
b4 b3 b2 b1 b0
10010
00010
00011
00100
00110
01000
01010
01100
01110
00000
: No division mode
: Division by 2 mode
: Division by 3 mode
: Division by 4 mode
: Division by 6 mode
: Division by 8 mode
: Division by 10 mode
: Division by 12 mode
: Division by 14 mode
: Division by 16 mode
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
AA
A
A
AA
A
AA
A
AA
A
AA
A
AA
RW
Note 1: Set bit 0 of the protect register (address 000A16) to “1” before writing to this register.
Note 2: These bits are "010002" (8-division mode) when main clock is stopped or you shift to stop
mode. However, in ring oscillator mode, this register is not set to the division by 8 mode when
XIN-XOUT is stopped by main clock stop bit.
Note 3: Do not attempt to set combinations of values other than those shown in this figure.
Note 4: SFR area of CAN is accessed with no division mode.
Figure 1.8.3. Clock control related registers (2)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
Oscillation stop detect register
b7
b6
b5
b4
0 0 0 0
b3
b2
b1
b0
Symbol
CM2
Bit
symbol
(Note 1)
Address
000D16
When reset
0016
Bit name
Function
CM20
Oscillation stop detect
enable bit
CM21
Main clock switching bit 0: XIN selected
(Note 2,3) 1: Ring oscillator selected
CM22
Oscillation stop detect
flag
(Note 4)
0: Ignored
1: Detect oscillation stop
CM23
XIN clock monitor flag
(Note 5)
0: XIN oscillating
1: XIN not oscillating
Reserved bit
Must set to "0"
R W
0: Oscillation stop detect function disabled
1: Oscillation stop detect function enabled
Note 1: Set bit 0 of the protect register (address 000A16) to "1" before writing to this register.
Note 2: When XIN oscillation stop is detected in CM20="1", this bit becomes "1".
After this, although XIN starts oscillating, this bit does not become "0". When you change to XIN as
system clock after XIN restarts oscillating, write "0" to this bit.
Note 3: When CM20="1" and CM22="1", this bit cannot be written.
Note 4: When detecting oscillation stop, this bit becomes "1". "0" can be written by software.
When "0" is written during XIN oscillation stop, this bit does not becomes "1" although XIN oscillating stops.
Note 5: XIN state is judged by reading this bit several times in oscillation stop interrupt process program.
Figure 1.8.4. Clock control related register (3)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
Count source prescale register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TCSPR
Bit
symbol
Address
035F16
When reset
0XXX 00002
Bit name
Function
R W
b3 b2 b1b0
CNT0
CNT1
Division rate select bit
CNT2
CNT3
0 0 0 0: No-division
0 0 0 1: Division by 2
0 0 1 0: Division by 4
0 0 1 1: Division by 6
•
•
•
1 1 0 1: Division by 26
1 1 1 0: Division by 28
1 1 1 1: Division by 30
(Note)
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Operation enable bit
CST
0: Divider stops
1: Divider starts
Note : Write to these bits during the count stop.
VDC control register for PLL (Note 1)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PLV
Address
001716
When reset
XXXXXX012
Bit
symbol
Bit name
PLV00
PLL VDC enable bit
(Note 2)
0 : Cut off power to PLL
1 : Power to PLL
Reserved bit
Must set to "0"
Function
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note 1: When rewriting this register, set bit 3 of protect regiser (address 000A16) to "1".
Note 2: Set this bit to "0" before shifting to stop mode.
Figure 1.8.5. Clock control related register (4)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
(1) Main clock
The main clock is a clock source for CPU operation and peripheral I/O. Figure 1.8.6 shows example of a
main clock. When a reset, the clock oscillates and after a reset, the clock is divided by 8 to the BCLK
(CPU operating clock).
(a) Main clock On/Off function
• Main clock (XIN-XOUT) stop bit of system control register 0 (bit 5 at address 000616)
0: Main clock On
1: Main clock Off
Also, the clock is stopped by shifting to the stop mode.
• All clock stop control bit of system control register 1 (bit 0 at address 000716)
0: Clock on
1: All clocks off (stop mode)
Microcomputer
Microcomputer
(Built-in feedback resistance)
(Built-in feedback resistance)
XIN
XOUT
XIN
XOUT
Open
(Note)
Rd
Externally derived clock
CIN
COUT
Vcc
Vss
Note: Insert a damping resistance if required. The resistance will vary depending on
the oscillator setting. Use the value recommended by the maker of the oscillator.
Insert a feedback resistance between XIN and XOUT when an oscillation
manufacture required.
Figure 1.8.6. Examples of main clock
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
(2) Sub clock
The sub clock is a clock source for CPU operation and count source for timer A and B. Figure 1.8.7
shows example of sub clock. When the sub clock is used, set ports P86 and P87 to no pull-up resistance
with the input port. No sub clock is generated during and after a reset.
(a) Sub clock On/Off function
When you want to use sub clock, set the following bit and sub clock enabled.
• Port Xc select bit of system control register 0 (bit 4 at address 000616)
0: I/O port (sub clock off)
1: XIN-XOUT generation (sub-clock on)
Also, shifting to the stop mode stops the clock.
• All clock stop control bit of system control register 1 (bit 0 at address 000716)
0: Clock On
1: All clock stop (stop mode)
Microcomputer
Microcomputer
(Built-in feedback resistance)
(Built-in feedback resistance)
XCIN
XCOUT
XCIN
XCOUT
Open
(Note)
RCd
Externally derived clock
CCIN
CCOUT
Vcc
Vss
Note: Insert a damping resistance if required. The resistance will vary depending on
the oscillator and the oscillation drive capacity setting. Use the value
recommended by the maker of the oscillator.
When the oscillation drive capacity is set to low, check that oscillation is stable.
Insert a feedback resistance between XCIN and XCOUT when an oscillation
manufacture required.
Figure 1.8.7. Examples of sub clock
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
(3) Oscillation stop detect function (OSD function)
This function monitor the main clock (XIN pin). When main clock is stopped, internal ring oscillator starts
ocsillation and replace the main clock. Then oscillation stop detect interrupt process is operated.
When frequency of main clock is less or equal than 2MHz, this function does not work.
(a) OSD function enable/disable
• OSD enable bit of oscillation stop detect register (bit 0 at address 000D16)
0: OSD function disabled
1: OSD function enabled
Set OSD enable bit (bit 0) of oscillation stop detect register to "0" to disable OSD function before
setting stop mode. Stop mode is canceled before setting this bit to "1".
(b) Operation when oscillation stop detects
1) When XIN oscillation stops, a built in ring oscillation starts as a main clock automatically.
2) OSD interrupt request is generated, jump to an address FFFFF016 to FFFFF316 allocated fixed
vector table (watchdog timer interrupt vector) and execute program of jump address.
3) OSD interrupt shares vector table with watchdog timer interrupt. When using both OSD and watchdog timer interrupts, read and judge OSD flag in interrupt process routine.
OSD flag of oscillation stop detect register (bit 2 at address 000D16)
1: Oscillation stop detects
4) XIN does not become main clock although XIN On after oscillation stop detects. When you want XIN
to be main clock, execute a process shown in Figure 1.8.8.
XIN switching
XIN is ON
OFF
ON
Oscillation stop detect register (address 000D16)
bit 3: XIN clock monitor flag
0: XIN ON
1: XIN OFF
Confirm XIN is ON
Confirm XIN is ON several times
Write "0" to OSD flag
Write "0" to main clock
select bit
bit2: Oscillation stop detect flag
bit 1: Main clock select bit
0: XIN selected
1: Ring oscillator selected
End
Figure 1.8.8. Main clock switching sequence
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Wait Mode
CPU clock (BCLK)
Main clock, sub clock or clock from ring oscillator can be selected as clock source for BCLK.
System clock select bit of system clock control register (bit 7 at address 000616)
0: Main clock is selected (XIN-XOUT)
1: Sub clock is selected (XCIN-XCOUT)
Main clock select bit of oscillation stop detect register (bit 1 at address 000D16)
0: Main clock is selected (XIN-XOUT)
1: Clock from ring oscillator is selected
Table 1.8.3. BCLK source and setting bit
BCLK source
System clock select bit
Main clock select bit
(Bit 7 of address 000616)
(Bit 1 of address 000D16)
Main clock (XIN-XOUT)
0
0
Sub clock (XCIN-XCOUT)
1
0
Ring oscillator
0
1
When main clock or ring oscillator clock is selected as clock source for BCLK, the BCLK is the clock
derived by dividing the main clock or ring oscillator clock by 1, 2, 3, 4, 6, 8, 10, 12, 14 or 16.
Main clock divide rate select bit of main clock division register (bit 0 to 4 at address 000C16)
The BCLK is derived by dividing the main clock (XIN-XOUT) by 8 after a reset. (Main clock division register
= "XXX010002")
When main clock is stopped under changing to stop mode or selecting XIN-XOUT (main clock select bit =
"0"), the main clock division register is set to the division by 8 ("XXX010002").
When ring oscillator clock is selected as clock source for BCLK, although main clock is stoped, the
contents of main clock division register is maintained.
Peripheral function clock
Main clock, sub clock, PLL clock or ring oscillator clock can be selected as clock source for peripheral
function.
(1) f1, f8, f2n
The clock is derived from the main clock or by dividing it by 1, 8 or 2n (n=1 to 15). It is used for the
timer A and timer B counts and serial I/O and UART operation clock.
The f2n division rate is set by the count source prescaler register. Figure 1.8.5 shows the count source
prescaler register.
(2) fAD
This clock has the same frequency as the main clock or ring oscillator clock and is used for A-D
conversion.
(3) fC32
This clock is derived by dividing the sub clock by 32. It is used for the timer A and timer B counts.
(4) fPLL
This clock is 80 MHz generated by PLL synthesizer. It is used for the intelligent I/O group 3.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock Generating Circuit
Clock Output
You can output clock from the P53 pin.
• BCLK output function select bit of processor mode register 0 (bit 7 at address 000416)
• ALE select bits of processor mode register 1 (bit 4 and 5 at address 000516)
• Clock output function select bits of system clock select register (bits 1 and 0 at address 000616)
Table 1.8.4 shows clock output setting (single chip mode) and Table 1.8.5 shows clock output setting
(memory expansion/microprocessor mode).
Table 1.8.4. Clock output setting (single chip mode)
BCLK output function
select bit
Clock output function
select bit
PM07
Ignored
CM01
ALE pin select bit
P53/BCLK/ALE/CLKOUT
pin function
PM15
PM14
0
CM00
0
Ignored
Ignored
P53 I/O port
1
0
1
Ignored
Ignored
fc output (Note)
1
1
0
Ignored
Ignored
f8 output (Note)
1
1
1
Ignored
Ignored
f32 output (Note)
Note :Must use P57 as input port.
Table 1.8.5. Clock output setting (memory expansion/microprocessor mode)
BCLK output function
select bit
Clock output function
select bit
PM07
0
CM01
0
CM00
0
1
0
0
1
0
1
1
1
0
1
1
1
Ignored
0
0
ALE pin select bit
PM14
PM15
P53/BCLK/ALE/CLKOUT
pin function
BCLK output
"L" output (not P53)
"0, 0"
"1, 0"
"1, 1"
fc output
f8 output
f32 output
0
1
ALE output
Note: The processor mode register 0 and 1 are protected from false write by program run away.
Set bit 1 to "1" at protect register (address 000A16) and release protect before rewriting processor
mode register 0 and 1.
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Power Saving
Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Power Saving
There are three power save modes. Figure 1.8.9 shows the clock transition between each of the three
modes, (1), (2), and (3).
• Normal operating mode
CPU and peripheral function operate when supplying clock. Power dissipation is reduced by making
BCLK slow.
• Wait mode
BCLK is stopped. Peripheral function clock is stopped as desired. Main clock and sub clock isn't
stopped. Power dissipation is reduced than normal operating mode.
• Stop mode (Note 1)
Main clock, sub clock and PLL synthesizer are stopped. CPU and peripheral function clock are
stopped. Power dissipation is the most few in this mode.
Note :When using stop mode, oscillation stop detect function must be canceled.
(1) Normal operating mode
High-speed mode
Main clock one cycle forms CPU operating clock.
Medium-speed mode
The main clock divided into 2, 3, 4, 6, 8, 10, 12, 14, or 16 forms CPU operating clock.
Low-speed mode
Subclock (fc) forms CPU operating clock.
Low power-dissipation mode
This mode is selected when the main clock is stopped from low-speed mode. Only the peripheral
functions for which the subclock was selected as the count source continue to run.
Ring oscillator mode
The ring oscillator clock divided into 2, 3, 4, 6, 8, 10, 12, 14, or 16 forms CPU operating clock.
Ring oscillator low power-dissipation mode
This mode is selected when the main clock is stopped from low-speed mode.
When switching BCLK from ring oscillator to main clock, switch clock after main clock oscillates fully
stable. After setting divided by 8 (main clock division register =0816) in ring oscilltor mode, switching
to the middle mode (divided by 8) is recommended.
(2) Wait mode
In wait mode, BCLK is stopped and CPU and watchdog timer operated by BCLK are halted. The main
clock, subclock and ring oscillator clock continue to run.
(a) Shifting to wait mode
Execute WAIT instruction.
(b) Peripheral function clock stop function
The f1, f8 and f2n being supplied to the internal peripheral functions stops. The internal peripheral
functions operated by the clock stop.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Power Saving
WAIT peripheral function clock stop bit of system clock control register 0 (bit 2 at address 000616)
0: Do not stop f1, f8 and f2n in wait mode and do not stop supplying clock to PLL circuit
1: Stop f1, f8 and f2n in wait mode and stop supplying clock to PLL circuit
(c) The status of the ports in wait mode
Table 1.8.6 shows the status of the ports in wait mode.
(d) Exit from wait mode
Wait mode is cancelled by a hardware reset or interrupt. If a peripheral function interrupt is used to
cancel wait mode, set the following registers.
Interrupt priority set bits for exiting a stop/wait state of exit priority register (bits 0 to 2 at address
009F16) :RLVL0 to RLVL2
Set the same level as the flag register (FLG) processor interrupt level (IPL).
Interrupt priority set bits of interrupt control register (bits 0 to 2)
Set to a priority level above the level set by RLVL0 to RLVL2 bits
Interrupt enable flag of FLG register
I=1
When using an interrupt to exit Wait mode, the microcomputer resumes operating the clock that was operating when the WAIT command was executed as BCLK from the interrupt routine.
Table 1.8.6. Port status during wait mode
Pin
Memory expansion mode
Single-chip mode
Microprocessor mode
_______
_______
Address bus, data bus, CS0 to CS3,
Retains status before wait mode
________
BHE
_____
______
________
_________
______
_________
________
RD, WR, WRL, WRH, DW, CASL, CASH
________
“H” (Note)
“H” (Note)
RAS
__________
HLDA,BCLK
“H”
ALE
“L”
Port
Retains status before wait mode
CLKOUT
When fC selected
Does not stop
When f8, f32 selected
Does not stop when the WAIT peripheral function clock stop bit is
“0”. When the WAIT peripheral function clock stop bit is “1”, the
status immediately prior to entering wait mode is maint ained.
________
________
Note :When self-refresh is done in operating DRAM control, CAS and RAS becomes “L”.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Power Saving
(3) Stop mode
All oscillation, main clock, subclock, and PLL synthesizer stop in this mode. Because the oscillation of
BCLK and peripheral clock stops in stop mode, peripheral functions such as the A-D converter, timer A
and B, serial I/O, intelligent I/O and watchdog timer do not function.
The content of the internal RAM is retained provided that VCC remains above 2.5V.
When changing to stop mode, the main clock division register (000C16) is set to “XXX010002” (division by
8 mode).
(a) Changing to stop mode
All clock stop control bit of system clock control register 1 (bit 0 at address 000716)
0: Clock ON
1: All clocks off (stop mode)
Before changing to stop mode, set bit 7 of PLL control register 0 (address 037616) to "0" to stop PLL.
Also, set bit 0 of VDC control register for PLL (address 001716) to "1" to turn PLL circuit power off.
(b) The status of the ports in stop mode
Table 1.8.7 shows the status of the ports in stop mode.
(c) Exit from stop mode
Stop mode is cancelled by a hardware reset or interrupt. If a peripheral function interrupt is used to
cancel stop mode, set the following registers.
• Interrupt priority set bits for exiting a stop/wait state of exit priority register (bits 0 to 2 at address 009F16) :RLVL0 to RLVL2
Set the same level as the flag register (FLG) processor interrupt level (IPL).
• Interrupt priority set bits of interrupt control register (bits 0 to 2)
Set to a priority level above the level set by RLVL0 to RLVL2 bits
• Interrupt enable flag of FLG register
I=1
When exiting from stop mode using peripheral interrupt request, CPU operates the following BCLK
and the relevant interrupt routine is executed.
• When subclock was set as BCLK before changing to stop mode, subclock is set to BCLK after
cancelled stop mode
• When main clock was set as BCLK before changing to stop mode, the main clock division by 8 is set
to BCLK after cancelled stop mode.
Table 1.8.7. Port status during stop mode
Pin
Memory expansion mode
Single-chip mode
Microprocessor mode
_______
_______
_______
Address bus, data bus, CS0 to CS3, BHE
_____
______
________
_________
______
_________
________
RD, WR, WRL, WRH, DW, CASL, CASH
________
Retains status before stop mode
“H” (Note)
“H” (Note)
RAS
__________
HLDA, BCLK
“H”
ALE
“H”
Port
Retains status before stop mode
CLKOUT
When fc selected
“H”
When f8, f32 selected
Retains status before stop mode
________
________
Note :When self-refresh is done in operating DRAM control, CAS and RAS becomes “L”.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Power Saving
Reset
Interrupt
Middle-speed mode
(divided by 8 mode)
Note 1
All oscillation is stopped
WAIT instruction
CM10="1"
Stop mode
High-speed /
middle-speed mode
Note 1, 5
interrupt
CPU operation
is stopped
Note 2, 4
All oscillation is stopped
CM10="1"
Stop mode
Note 3
WAIT instruction
Low-speed/ low power
dissipation mode
Wait mode
interrupt
Wait mode
Interrupt
Note 1
XIN oscillation is stopped
Detect
oscillation stop
Interrupt
Ring oscillator / ring oscillator Note 6
low power dissipation mode
WAIT instruction
interrupt
Wait mode
Normal operation mode
Note 1 :Switch clocks after the main clock oscillation is fully stabled.
Note 2 :Switch clocks after oscillation of sub clock is fully stable.
Note 3 :The main clock division register is set to the division by 8 mode (MCD="0816").
Note 4 :When changing to low power dissipation mode, the main clock division register is set to
the division by 8 mode (MCD="0816").
Note 5 :Low power dissipation mode can not be changed to high-speed / middle-speed mode.
Note 6 :Other oscillation mode cannot be changed to low power dissipation mode.
Figure 1.8.9. Clock transition
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Power Saving
Main clock is oscillating
Sub clock is stopped
Middle-speed mode (divided-by-8 mode)
Transition of normal mode
Please change according to a direction of an arrow.
BCLK :f(XIN)/8
CM07=“0” MCD=“0816”
High-speed/middle-speed mode
MCD=“XX16”
Main clock is oscillating
Sub clock is stopped
Main clock is oscillating
Sub clock is oscillating
Note 1, 3
High-speed mode
CM04=“1”
MCD=“XX16”
Note 1, 3
High-speed mode
BCLK :f(XIN)
CM07=“0” MCD=“1216”
CM04=“0”
Middle-speed mode
(divided-by-2, 3, 4, 6, 8, 10, 12, 14 and 16 mode)
BCLK :f(XIN)/division rate
CM07=“0” MCD=“XX16”
CM21=“0”
Note 1
BCLK :f(XIN)
CM07=“0” MCD=“1216”
Middle-speed mode
(divided-by-2, 3, 4, 6, 8, 10, 12, 14 and 16 mode)
CM04=“1”
Note 3
Note 3
CM07=“0”
MCD=“XX16”
CM04=“0”
Note 1
Note 3
CM07=“0” Note 1
MCD=“XX16” Note
CM07=“1”
3
Note 2
Low-speed/low power dissipation mode
Main clock is stopped
Sub clock is oscillating
Low power
dissipation mode
CM07=“1”
CM05=“1”
Note 2
Main clock is oscillating
Sub clock is oscillating
Low-speed mode
CM05=“1”
BCLK :f(XCIN)
BCLK :f(XCIN)
CM07=“1”
CM07=“1”
CM05=“0”
Note 4
Ring oscillator/ring oscillator low power dissipation mode
Ring oscillator is selected
Main clock is stopped
Sub clock is stopped
Ring oscillator is selected
Main clock is oscillating
Sub clock is oscillating (stopped)
Ring oscillator mode
Ring oscillator low power
dissipation mode
BCLK: Ring oscillator clock/division rate
CM21="1"
CM05="1"
CM05=“1”
CM04="0"
CM05=“0”
(CM04="1")
Note 1: Switch clocks after oscillation of main clock is fully stable.
Note 2: Switch clocks after oscillation of sub clock is fully stable.
Note 3: Set the desired division to the main clock division register (MCD).
Note 4: Set to divided by 8 mode (MCD is set to "0816").
Figure 1.8.10. Clock transition
80
CM21=“1”
Note 1
BCLK :f(XIN)/division rate
CM07=“0” MCD=“XX16”
BCLK: Ring oscillator clock/division rate
CM21="1"
CM05="0"
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Protection
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Protection
The protection function is provided so that the values in important registers cannot be changed in the event
that the program runs out of control. Figure 1.8.11 shows the protect register. The following registers are
protected by the protect register.
(1) Registers protected by PRC0 (bit 0)
• System clock control registers 0 and 1 (addresses 000616 and 000716)
• Main clock division register (address 000C16)
• Oscillation stop detect register (address 000D16)
• PLL control register 0 (address 037616)
(2) Registers protected by PRC1 (bit 1)
• Processor mode registers 0 and 1 (addresses 000416 and 000516)
• Three-phase PWM control registers 0 and 1 (addresses 030816 and 030916)
(3) Registers protected by PRC2 (bit 2)
• Port P9 direction register (address 03C716)
• Function select register A3 (address 03B516)
(4) Registers protected by PRC3 (bit 3)
• VDC control register for PLL (address 001716)
• VDC control register 0 (address 001F16)
If, after “1” (write-enabled) has been written to the PRC2, a value is written to any address, the bit automatically reverts to “0” (write-inhibited). Change port P9 input/output and function select register A3 immediately after setting "1" to PRC2. Interrupt and DMA transfer should not be inserted between instructions.
However, the PRC0, PRC1 and PRC3 do not automatically return to “0” after a value has been written to an
address. The program must therefore be written to return these bits to “0”.
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Protect register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
PRCR
Bit
symbol
PRC0
PRC1
PRC2
PRC3
Bit name
Address
000A16
When reset
XXXX00002
Function
Protect bit 0
Enables writing to system clock control registers 0
and 1 (addresses 000616 and 000716), main clock
division register (address 000C16), oscillation stop
detect register (address 000D16) and PLL control
register 0 (address 037616)
0 : Write-inhibited
1 : Write-enabled
Protect bit 1
Enables writing to processor mode registers 0 and
1 (addresses 000416 and 000516) and threephase PWM control register 0 and 1 (addresses
030816 and 030916)
0 : Write-inhibited
1 : Write-enabled
Enables writing to port P9 direction register (
address 03C716) and function select register A3
Protect bit 2
(address 03B516)
(Note 1) 0 : Write-inhibited
1 : Write-enabled
Protect bit 3
Enables writing to VDC control register for PLL (
address 001716), VDC control register 0 and 1 (
addresses 001F16 and 001B16)
0 : Write-inhibited
(Note 2)
1 : Write-enabled
R W
A
A
A
A
Nothing is assigned.
When write, set “0”. When read, their contents are indeterminate.
Note 1: Writing a value to an address after “1” is written to this bit returns the bit
to “0”. Other bits do not automatically return to “0” and they must therefore
be reset by the program.
Note 2: User cannot use. Writing to VDC control registers 0 and 1 (addresses
001F16, 001B16) is enabled so that a careful handling is required.
Figure 1.8.11. Protect register
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Interrupt Outline
Types of Interrupts
• Maskable interrupt
• Non-maskable interrupt
: An interrupt which can be disabled by the interrupt enable flag (I flag) or
whose interrupt priority can be changed by priority level.
: An interrupt which cannot be disabled by the interrupt enable flag (I flag) or
whose interrupt priority cannot be changed by priority level.
Figure 1.9.1 lists the types of interrupts.










Hardware
Special















Interrupt
Software
Undefined instruction (UND instruction)
Overflow (INTO instruction)
BRK instruction
BRK2 instruction
INT instruction
Reset
NMI
Watchdog timer
Ocsillation stop detection
Single step
Address matched
_______
Peripheral I/O*1
*1 Peripheral I/O interrupts are generated by the peripheral functions built into the microcomputer
system. High-speed interrupt can be used as highest priority in peripheral I/O interrupts.
Figure 1.9.1. Classification of interrupts
Software Interrupts
Software interrupts are generated by some instruction that generates an interrupt request when executed. Software interrupts are nonmaskable interrupts.
(1) Undefined-instruction interrupt
This interrupt occurs when the UND instruction is executed.
(2) Overflow interrupt
This interrupt occurs if the INTO instruction is executed when the O flag is 1.
The following lists the instructions that cause the O flag to change:
ABS, ADC, ADCF, ADD, ADDX, CMP, CMPX, DIV, DIVU, DIVX, NEG, RMPA, SBB, SCMPU, SHA,
SUB, SUBX
(3) BRK interrupt
This interrupt occurs when the BRK instruction is executed.
(4) BRK2 interrupt
This interrupt occurs when the BRK2 instruction is executed. This interrupt is used exclusively for
debugger purposes. You normally do not need to use this interrupt.
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Interrupts
(5) INT instruction interrupt
This interrupt occurs when the INT instruction is executed after specifying a software interrupt number
from 0 to 63. Note that software interrupt numbers 7 to 54 and 57 are assigned to peripheral I/O
interrupts. This means that by executing the INT instruction, you can execute the same interrupt
routine as used in peripheral I/O interrupts.
The stack pointer used in INT instruction interrupt varies depending on the software interrupt number.
For software interrupt numbers 0 to 31, the U flag is saved when an interrupt occurs and the U flag is
cleared to 0 to choose the interrupt stack pointer (ISP) before executing the interrupt sequence. The
previous U flag before the interrupt occurred is restored when control returns from the interrupt routine. For software interrupt numbers 32 to 63, such stack pointer switchover does not occur.
However, in peripheral I/O interrupts, the U flag is saved when an interrupt occurs and the U flag is
cleared to 0 to choose ISP.
Therefore movement of U flag is different by peripheral I/O interrupt or INT instruction in software
interrupt number 32 to 54 and 57.
Hardware Interrupts
There are Two types of hardware Interrupts; special interrupts and Peripheral I/O interrupts.
(1) Special interrupts
Special interrupts are nonmaskable interrupts.
• Reset
____________
•
•
•
•
•
84
A reset occurs when the RESET pin is pulled low.
______
NMI interrupt
______
This interrupt occurs when the NMI pin is pulled low.
Watchdog timer interrupt
This interrupt is caused by the watchdog timer.
Ocsillation stop detect interrupt
This interrupt is caused by the ocsillation stop detect function.
It occurs when detecting the XIN ocsillation is stopped.
Single-step interrupt
This interrupt is used exclusively for debugger purposes. These interrupts normally do not need to use
this interrupt. A single-step interrupt occurs when the D flag is set (= 1); in this case, an interrupt is
generated each time an instruction is executed.
Address-match interrupt
This interrupt occurs when the program's execution address matches the contents of the address
match register while the address match interrupt enable bit is set (= 1).
This interrupt does not occur if any address other than the start address of an instruction is set in the
address match register.
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Interrupts
(2) Peripheral I/O interrupts
A peripheral I/O interrupt is generated by one of the built-in peripheral functions. Built-in peripheral
functions are dependent on classes of products, so the interrupt factors too are dependent on classes
of products. The interrupt vector table is the same as the one for software interrupt numbers 7 through
54 and 57 the INT instruction uses. Peripheral I/O interrupts are maskable interrupts.
• UART related interrupt (UART0 to 4)
- UART transmission/NACK interrupt
- UART reception/ACK interrupt
- Bus collision detection, start/stop condition detection interrupts
This is an interrupt that the serial I/O bus collision detection generates. When I2C mode is selected,
start, stop condition interrupt is selected.
• DMA0 through DMA3 interrupts
• Key-input interrupt
___
A key-input interrupt occurs if an “L” is input to the KI pin.
• A-D conversion interrupt (AD0, 1)
• Timer A interrupt (TA0 to 4)
• Timer B interrupt (TB0 to 5)
_____
_______
________
• INT interrupt (INT0 to INT5 )
_____
_____
An INT interrupt selects an edge sense or a level sense. In edge sense, an INT interrupt occurs if
_____
_____
either a rising edge or a falling edge is input to the INT pin. In level sense, an INT interrupt occurs if
_____
either a "H" level or a "L" level is input to the INT pin.
• Intelligent I/O interrupt
• CAN interrupt
High-speed interrupts
High-speed interrupts are interrupts in which the response is executed at 5 cycles and the return is 3
cycles.
When a high-speed interrupt is received, the flag register (FLG) and program counter (PC) are saved to
the save flag register (SVF) and save PC register (SVP) and the program is executed from the address
shown in the vector register (VCT).
Execute an FREIT instruction to return from the high-speed interrupt routine.
High-speed interrupts can be set by setting “1” in the high-speed interrupt specification bit allocated to bit
3 of the exit priority register. Setting “1” in the high-speed interrupt specification bit makes the interrupt set
to level 7 in the interrupt control register a high-speed interrupt.
You can only set one interrupt as a high-speed interrupt. When using a high-speed interrupt, do not set
multiple interrupts as level 7 interrupts. When using high speed interrupt, DMA II cannot be used.
The interrupt vector for a high-speed interrupt must be set in the vector register (VCT).
When using a high-speed interrupt, you can use a maximum of two DMAC channels.
The execution speed is improved when register bank 1 is used with high speed interrupt register selected
by not saving registers to the stack but to the switching register bank. In this case, switch register bank
mode for high-speed interrupt routine.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Interrupts and Interrupt Vector Tables
If an interrupt request is accepted, a program branches to the interrupt routine set in the interrupt vector
table. Set the first address of the interrupt routine in each vector table. Figure 1.9.2 shows the format for
specifying the address.
Two types of interrupt vector tables are available — fixed vector table, in which addresses are fixed, and
relocatable vector table, in which addresses can be varied by the setting.
AAAAAAAA
AAAAAAAA
AAAAAAAA
AAAAAAAA
AAAAAAAA
MSB
LSB
Vector address + 0
Low address
Vector address + 1
Mid address
Vector address + 2
High address
Vector address + 3
0 0 16
Figure 1.9.2. Format for specifying interrupt vector addresses
• Fixed vector tables
The fixed vector table is a table in which addresses are fixed. The vector tables are located in an area
extending from FFFFDC16 to FFFFFF16. Each vector comprises four bytes. Set the first address of
interrupt routine in each vector table. Table 1.9.1 shows the interrupts assigned to the fixed vector
tables and addresses of vector tables.
Table 1.9.1. Interrupt factors (fixed interrupt vector addresses)
Interrupt source
Vector table addresses
Remarks
Address (L) to address (H)
Undefined instruction
FFFFDC16 to FFFFDF16
Interrupt on UND instruction
Overflow
FFFFE016 to FFFFE316
Interrupt on INTO instruction
BRK instruction
FFFFE416 to FFFFE716
If contents of FFFFE716 is filled with FF16, program
execution starts from the address shown by the vector in
the relocatable vector table
Address match
FFFFE816 to FFFFEB16
There is an address-matching interrupt enable bit
Watchdog timer
FFFFF016 to FFFFF316
Share it with watchdog timer and oscillation stop detect
NMI
FFFFF816 to FFFFFB16
External interrupt by input to NMI pin
Reset
FFFFFC16 to FFFFFF16
interrupt
_______
86
_______
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
• Vector table dedicated for emulator
Table 1.9.2 shows interrupt vector address, which is vector table register dedicated for emulator (address 00002016 to 00002216). These instructions are not effected with interrupt enable flag (I flag)
(non maskable interrupt).
This interrupt is used exclusively for debugger purposes. You normally do not need to use this interrupt. Do not access the interrupt vector table register dedicated for emulator (address 00002016 to
00002216).
Table 1.9.2. Interrupt vector table register for emulator
Interrupt source
Vector table addresses
Remarks
Address (L) to address (H)
BRK2 instruction Interrupt vector table register for emulator
Single step
Interrupt for debugger
00002016 to 00002216
• Relocatable vector tables
The addresses in the relocatable vector table can be modified, according to the user’s settings. Indicate the first address using the interrupt table register (INTB). The 256-byte area subsequent to the
address the INTB indicates becomes the area for the relocatable vector tables. One vector table
comprises four bytes. Set the first address of the interrupt routine in each vector table. Table 1.9.3
shows the interrupts assigned to the relocatable vector tables and addresses of vector tables.
Set an even address to the start address of vector table setting in INTB so that operating efficiency is
increased.
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Interrupts
Table 1.9.3. Interrupt causes (variable interrupt vector addresses) (1/2)
Softwear interrupt number
88
Vector table address
Address(L)to address(H) (Note 1)
(Note
2)
Softwear interrupt number 0
+0 to +3 (000016 to 000316)
Interrutp source
Softwear interrupt number 7
Softwear interrupt number 8
Softwear interrupt number 9
Softwear interrupt number 10
Softwear interrupt number 11
Softwear interrupt number 12
Softwear interrupt number 13
Softwear interrupt number 14
Softwear interrupt number 15
Softwear interrupt number 16
Softwear interrupt number 17
Softwear interrupt number 18
Softwear interrupt number 19
Softwear interrupt number 20
Softwear interrupt number 21
Softwear interrupt number 22
Softwear interrupt number 23
Softwear interrupt number 24
Softwear interrupt number 25
Softwear interrupt number 26
Softwear interrupt number 27
Softwear interrupt number 28
Softwear interrupt number 29
Softwear interrupt number 30
Softwear interrupt number 31
Softwear interrupt number 32
Softwear interrupt number 33
Softwear interrupt number 34
Softwear interrupt number 35
Softwear interrupt number 36
Softwear interrupt number 37
Softwear interrupt number 38
Softwear interrupt number 39
+28 to +31 (001C16 to 001F16)
+32 to +35 (002016 to 002316)
+36 to +39 (002416 to 002716)
+40 to +43 (002816 to 002B16)
+44 to +47 (002C16 to 002F16)
+48 to +51 (003016 to 003316)
+52 to +55 (003416 to 003716)
+56 to +59 (003816 to 003B16)
+60 to +63 (003C16 to 003F16)
+64 to +67 (004016 to 004316)
+68 to +71 (004416 to 004716)
+72 to +75 (004816 to 004B16)
+76 to +79 (004C16 to 004F16)
+80 to +83 (005016 to 005316)
+84 to +87 (005416 to 005716)
+88 to +91 (005816 to 005B16)
+92 to +95 (005C16 to 005F16)
+96 to +99 (006016 to 006316)
+100 to +103 (006416 to 006716)
+104 to +107 (006816 to 006B16)
+108 to +111 (006C16 to 006F16)
+112 to +115 (007016 to 007316)
+116 to +119 (007416 to 007716)
+120 to +123 (007816 to 007B16)
+124 to +127 (007C16 to 007F16)
+128 to +131 (008016 to 008316)
+132 to +135 (008416 to 008716)
+136 to +139 (008816 to 008B16)
+140 to +143 (008C16 to 008F16)
+144 to +147 (009016 to 009316)
+148 to +151 (009416 to 009716)
+152 to +155 (009816 to 009B16)
+156 to +159 (009C16 to 009F16)
Softwear interrupt number 40
+160 to +163 (00A016 to 00A316)
Softwear interrupt number 41
+164 to +167 (00A416 to 00A716)
Softwear interrupt number 42
Softwear interrupt number 43
Softwear interrupt number 44
Softwear interrupt number 45
Softwear interrupt number 46
Softwear interrupt number 47
Softwear interrupt number 48
Softwear interrupt number 49
Softwear interrupt number 50
Softwear interrupt number 51
Softwear interrupt number 52
Softwear interrupt number 53
Softwear interrupt number 54
+168 to +171 (00A816 to 00AB16)
+172 to +175 (00AC16 to 00AF16)
+176 to +179 (00B016 to 00B316)
+180 to +183 (00B416 to 00B716)
+184 to +187 (00B816 to 00BB16)
+188 to +191 (00BC16 to 00BF16)
+192 to +195 (00C016 to 00C316)
+196 to +199 (00C416 to 00C716)
+200 to +203 (00C816 to 00CB16)
+204 to +207 (00CC16 to 00CF16)
+208 to +211 (00D016 to 00D316)
+212 to +215 (00D416 to 00D716)
+216 to +219 (00D816 to 00DB16)
A-D channel 1
DMA0
DMA1
DMA2
DMA3
Timer A0
Timer A1
Timer A2
Timer A3
Timer A4
UART0 transmit/NACK (Note 3)
UART0 receive/ACK (Note 3)
UART1 transmit/NACK (Note 3)
UART1 receive/ACK (Note 3)
Timer B0
Timer B1
Timer B2
Timer B3
Timer B4
INT5
INT4
INT3
INT2
INT1
INT0
Timer B5
UART2 transmit/NACK (Note 3)
UART2 receive/ACK (Note 3)
UART3 transmit/NACK (Note 3)
UART3 receive/ACK (Note 3)
UART4 transmit/NACK (Note 3)
UART4 receive/ACK (Note 3)
Bus collision detection, start/stop condition
detection (UART2)(Note 3)
Bus collision detection, start/stop condition
detection (UART3/UART0)(Note 3)
Bus collision detection, start/stop condition
detection (UART4/UART1)(Note 3)
A-D channel 0
Key input interrupt
Intelligent I/O interrupt 0
Intelligent I/O interrupt 1
Intelligent I/O interrupt 2
Intelligent I/O interrupt 3
Intelligent I/O interrupt 4
Intelligent I/O interrupt 5
Intelligent I/O interrupt 6
Intelligent I/O interrupt 7
Intelligent I/O interrupt 8
Intelligent I/O interrupt 9/CAN interrupt 0
Intelligent I/O interrupt 10/CAN interrupt 1
BRK instruction
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Interrupts
Table 1.9.3. Interrupt causes (variable interrupt vector addresses) (2/2)
Softwear interrupt number
Vector table address
Address(L)to address(H) (Note 1)
Softwear interrupt number 55
+220 to +223 (00DC16 to 00DF16)
Softwear interrupt number 56
+224 to +227 (00E016 to 00E316)
Softwear interrupt number 57
+228 to +231 (00E416 to 00E716)
Softwear interrupt number 58 (Note 2) +232 to +235 (00E816 to 00EB16)
to
to
Softwear interrupt number 63
+252 to +255 (00FC16 to 00FF16)
Interrutp source
Softwea interrupt
Softwea interrupt
Intelligent I/O interrupt 11/CAN interrupt 2
Softwea interrupt
Note 1: Address relative to address in interrupt table register (INTB).
Note 2: Cannot be masked by I flag.
Note 3: When IIC mode is selected, NACK/ACK, start/stop condition detection interrupts are selected. The fault error
____
interrupt is selected when SS pin is selected.
Interrupt request reception
The following lists the conditions under which an interrupt request is acknowledged:
• Interrupt enable flag (I flag)
=1
• Interrupt request bit
=1
• Interrupt priority level
> Processor interrupt priority level (IPL)
The interrupt enable flag (I flag), the processor interrupt priority level (IPL), interrupt request bit and
interrupt priority level select bit are all independent of each other, so they do not affect any other bit.
There are I flag and IPL in flag register (FLG). This flag and bit are described below.
Interrupt Enable Flag (I Flag) and processor Interrupt Priority Level (IPL)
I flag is used to disable/enable maskable interrupts. When this flag is set (= 1), all maskable interrupts
are enabled; when the flag is cleared to 0, they are disabled. This flag is automatically cleared to 0
after a reset.
IPL is configured with three bits, for specification of up to eight processor interrupt priority levels from
level 0 to level 7.
If a requested interrupt has priority greater than the processor interrupt priority level (IPL), the interrupt
is enabled.
Table 1.9.4 shows interrupt enable levels in relation to the processor interrupt priority level (IPL).
Table 1.9.4. IPL and Interrupt Enable Levels
Processor interrupt priority level (IPL)
Enabled interrupt priority levels
IPL2
IPL1
IPL0
0
0
0
Interrupt levels 1 and above are enabled.
0
0
1
Interrupt levels 2 and above are enabled.
0
1
0
Interrupt levels 3 and above are enabled.
0
1
1
Interrupt levels 4 and above are enabled.
1
0
0
Interrupt levels 5 and above are enabled.
1
0
1
Interrupt levels 6 and above are enabled.
1
1
0
Interrupt levels 7 and above are enabled.
1
1
1
All maskable interrupts are disabled.
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Interrupts
Interrupt control registers and Exit priority register
Peripheral I/O interrupts have their own interrupt control registers. Figure 1.9.3 and 1.9.4 show the
interrupt control registers and figure 1.9.5 shows exit priority register.
Interrupt control register
AA
A
AA
AA
AAAA
AAA
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TAiIC(i=0 to 4)
TBiIC(i=0 to 5)
SiTIC(i=0 to 4)
SiRIC(i=0 to 4)
BCNiIC(i=0 to 4)
DMiIC(i=0 to 3)
ADiIC(i=0,1)
KUPIC (i=0)
IIOiIC(i=0 to 5)
IIOiIC(i=6 to 11)
CANiIC(i=0 to 2)
Bit symbol
ILVL0
Address
006C16, 008C16, 006E16, 008E16, 007016
009416, 007616, 009616, 007816, 009816, 006916
009016, 009216, 008916, 008B16, 008D16
007216, 007416, 006B16, 006D16, 006F16
007116, 009116, 008F16, 007116(Note 1), 009116(Note 2)
006816, 008816, 006A16, 008A16
007316, 008616
009316
007516, 009516, 007716, 009716, 007916, 009916
007B16, 009B16, 007D16, 009D16, 007F16, 008116
009D16, 007F16, 008116
Bit name
Interrupt priority level
select bit
ILVL1
ILVL2
IR
Interrupt request bit
Function
b2 b1 b0
000:
001:
010:
011:
100:
101:
110:
111:
When reset
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
XXXXX0002
AA
A
A
AAAA
AA
AA
A
A
AAAA
R
W
Level 0 (interrupt disabled)
Level 1
Level 2
Level 3
Level 4
Level 5
Level 6
Level 7
0 : Interrupt not requested
1 : Interrupt requested
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
(Note 3)
Note 1: UART0 bus collision and start/stop condition detection interrupt control register is shared with UART3.
Note 2: UART1 bus collision and start/stop condition detection interrupt control register is shared with UART4.
Note 3: This bit can only be accessed for reset (= 0), but cannot be accessed for set (= 1).
Figure 1.9.3. Interrupt control register (1)
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Interrupts
AA
A
A
AA
Interrupt control register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
INTiIC(i=0 to 2)
INTiIC(i=3 to 5)(*1)
Bit symbol
ILVL0
Address
009E16, 007E16, 009C16
007C16, 009A16, 007A16
Bit name
Function
Interrupt priority level
select bit
ILVL1
ILVL2
IR
Interrupt request bit
POL
Polarity select bit
LVS
Level sense/edge
sense select bit
When reset
XX00 X0002
XX00 X0002
b2 b1 b0
0 0 0 : Level 0 (interrupt disabled)
0 0 1 : Level 1
0 1 0 : Level 2
0 1 1 : Level 3
1 0 0 : Level 4
1 0 1 : Level 5
1 1 0 : Level 6
1 1 1 : Level 7
0: Interrupt not requested
1: Interrupt requested
0 : Selects falling edge or L level
(Note 2) 1 : Selects rising edge or H level
0 : Edge sense
1 : Level sense
(Note 3)
AA
A
A
A
A
AA
AA
AA
AA
R
W
(Note 1)
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Note 1: This bit can only be accessed for reset (= 0), but cannot be accessed for set (= 1).
Note 2: When related bit of external interrupt cause select register (address 031F16) are used for both edge,
select the falling edge (=0).
Note 3: When level sense is selected, set related bit of external interrupt cause select register (address 031F16) to
one edge.
*1 When using 16-bit data bus width in microprocessor mode or memory expansion mode, INT3 to INT5 are used
for data bus. In this case, set the interrupt disabled to INT3IC, INT4IC and INT5IC.
Figure 1.9.4. Interrupt control register (2)
Bit 0 to 2: Interrupt Priority Level Select Bits (ILVL0 to ILVL2)
Interrupt priority levels are set by ILVL0 to ILVL2 bits. When an interrupt request is generated, the
interrupt priority level of this interrupt is compared with IPL. This interrupt is enabled only when its
interrupt priority level is greater than IPL. This means that you can disable any particular interrupt by
setting its interrupt priority level to 0.
Bit 3: Interrupt Request Bit (IR)
This bit is set (= 1) by hardware when an interrupt request is generated. The bit is cleared (= 0) by
hardware when the interrupt request is acknowledged and jump to the interrupt vector.
This bit can be cleared (= 0) (but never be set to 1) in software.
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Interrupts
Exit priority register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
RLVL
Bit
symbol
Bit name
Interrupt priority set bits
for exiting Stop/Wait
state
(Note 1)
RLVL2
FSIT
Function
R W
b2 b1 b0
RLVL0
RLVL1
When reset
XX0X00002
Address
009F16
0 0 0 : Level 0
0 0 1 : Level 1
0 1 0 : Level 2
0 1 1 : Level 3
1 0 0 : Level 4
1 0 1 : Level 5
1 1 0 : Level 6
1 1 1 : Level 7
0: Interrupt priority level 7 = normal
High-speed interrupt
interrupt
set bit
(Note 2) 1: Interrupt priority level 7 =
high-speed interrupt
Nothing is assigned.
When write, set "0". When read, its content is indeterminate.
DMA II
DMA II select bit
(Note 3)
0: Interrupt priority level 7 = normal
interrupt or high-speed interrupt
1: Interrupt priority level 7 =
DMA II transfer
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Note 1: Exits the Stop or Wait mode when the requested interrupt priority level is higher than
that set in the exit priority register.
Set to the same value as the processor interrupt priority level (IPL) set in the flag
register (FLG).
Note 2: The high-speed interrupt can only be specified for interrupts with interrupt priority level
7. Specify interrupt priority level 7 for only one interrupt.
Note 3: Do not set this bit to 0 after once setting it to 1.
When this bit is 1, do not set the high-speed interrupt select bit to 0. (This cannot be
used simultaneously with the high-speed interrupt.)
Transfers by DMAC II are unaffected by the interrupt enable flag (I flag) and processor
interrupt priority level (IPL).
Figure 1.9.5. Exit priority register
Bit 0 to 2: Interrupt priority set bits for exiting Stop/Wait state (RLVL0 to RLVL2)
When using an interrupt to exit Stop mode or Wait mode, the relevant interrupt must be enabled and
set to a priority level above the level set by the RLVL0 to RLVL2 bits. Set the RLVL0 to RLVL2 bits to
the same level as the flag register (FLG) IPL.
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Interrupts
Interrupt Sequence
An interrupt sequence — what are performed over a period from the instant an interrupt is accepted to the
instant the interrupt routine is executed — is described here.
If an interrupt occurs during execution of an instruction, the processor determines its priority when the
execution of the instruction is completed, and transfers control to the interrupt sequence from the next
cycle. If an interrupt occurs during execution of either the SCMPU, SIN, SMOVB, SMOVF, SMOVU,
SSTR, SOUT or RMPA instruction, the processor temporarily suspends the instruction being executed,
and transfers control to the interrupt sequence.
In the interrupt sequence, the processor carries out the following in sequence given:
(1) CPU gets the interrupt information (the interrupt number and interrupt request level) by reading
address 00000016 (address 00000216 when high-speed interrupt). After this, the related interrupt
request bit is "0".
(2) Saves the contents of the flag register (FLG) immediately before the start of interrupt sequence in the
temporary register (Note) within the CPU.
(3) Sets the interrupt enable flag (I flag), the debug flag (D flag), and the stack pointer select flag (U flag)
to “0” (the U flag, however does not change if the INT instruction, in software interrupt numbers 32
through 63, is executed)
(4) Saves the contents of the temporary register (Note) within the CPU in the stack area. Saves in the
flag save register (SVF) in high-speed interrupt.
(5) Saves the content of the program counter (PC) in the stack area. Saves in the PC save register
(SVP) in high-speed interrupt.
(6) Sets the interrupt priority level of the accepted instruction in the IPL.
After the interrupt sequence is completed, the processor resumes executing instructions from the first
address of the interrupt routine.
Note: This register cannot be utilized by the user.
Interrupt Response Time
'Interrupt response time' is the period between the instant an interrupt occurs and the instant the first
instruction within the interrupt routine has been executed. This time comprises the period from the occurrence of an interrupt to the completion of the instruction under execution at that moment (a) and the time
required for executing the interrupt sequence (b). Figure 1.9.6 shows the interrupt response time.
Interrupt request generated
Interrupt request acknowledged
Time
Instruction
(a)
Interrupt sequence
Instruction in interrupt
routine
(b)
Interrupt response time
(a) The period from the occurrence of an interrupt to the completion of the instruction under execution.
(b) The time required for executing the interrupt sequence.
Figure 1.9.6. Interrupt response time
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Interrupts
Time (a) varies with each instruction being executed. The DIVX instruction requires a maximum time of
29* cycles.
Time (b) is shown in table 1.9.5.
* It is when the divisor is immediate or register. When the divisor is memory, the following value is
added.
• Normal addressing
:2+X
• Index addressing
:3+X
• Indirect addressing
: 5 + X + 2Y
• Indirect index addressing
: 6 + X + 2Y
X is number of wait of the divisor area. Y is number of wait of the indirect address stored area.
When X and Y are in odd address or in 8 bit bus area, double the value of X and Y.
Table 1.9.5 Interrupt Sequence Execution Time
Interrupt
Peripheral I/O
Interrupt vector address
16 bits data bus
8 bits data bus
14 cycles
16 cycles
16 cycles
16 cycles
12 cycles
14 cycles
14 cycles
14 cycles
Even address (Note 2)
13 cycles
15 cycles
Overflow
Even address (Note 2)
14 cycles
16 cycles
BRK instruction (Relocatable vector table)
Even address
17 cycles
19 cycles
19 cycles
19 cycles
19 cycles
21 cycles
Even address
Odd address
INT instruction
(Note 1)
Even address
Odd address
(Note 1)
_______
NMI
Watchdog timer
Undefined instruction
Address match
Odd address
Single step
(Note 1)
Even address (Note 2)
BRK2 instruction
BRK instruction (Fixed vector table)
High-speed interrupt (Note 3)
Vector table is internal register
Note 1: Allocate interrupt vector addresses in even addresses as much as possible.
Note 2: The vector table is fixed to even address.
Note 3: The high-speed interrupt is independent of these conditions.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Changes of IPL When Interrupt Request Acknowledged
When an interrupt request is acknowledged, the interrupt priority level of the acknowledged interrupt is
set to the processor interrupt priority level (IPL).
If an interrupt request is acknowledged that does not have an interrupt priority level, the value shown in
Table 1.9.6 is set to the IPL.
Table 1.9.6 Relationship between Interrupts without Interrupt Priority Levels and IPL
Interrupt sources without interrupt priority levels
Value that is set to IPL
_______
Watchdog timer, NMI
7
Reset
0
Other
Not changed
Saving Registers
In an interrupt sequence, only the contents of the flag register (FLG) and program counter (PC) are
saved to the stack area.
The order in which these contents are saved are as follows: First, the FLG register is saved to the stack
area. Next, the 16 high-order bits and 16 low-order bits of the program counter expanded to 32-bit are
saved. Figure 1.9.7 shows the stack status before an interrupt request is acknowledged and the stack
status after an interrupt request is acknowledged.
In a high-speed interrupt sequence, the contents of the flag register (FLG) are saved to the flag save
register (SVF) and program counter (PC) are saved to PC save register (SVP).
If there are any other registers you want to be saved, save them in software at the beginning of the
interrupt routine. The PUSHM instruction allows you to save all registers except the stack pointer (SP)
by a single instruction.
In high speed interrupt, switch register bank, then register bank 1 is used as high speed interrupt register.
In this case, switch register bank mode for high-speed interrupt routine.
Stack area
Address
Address
LSB
MSB
Stack area
MSB
LSB
m-6
m-6
m-5
m-5
Program counter
(PCL)
Program counter
(PC M)
m–4
m–4
Program counter
(PC H)
m–3
m–3
m–2
m–2
m–1
m
m+1
m–1
Content of
previous stack
Content of
previous stack
[SP]
Stack pointer
value before
interrupt occurs
Stack status before interrupt request is acknowledged
m
m+1
0
[SP]
New stack
pointer value
0
Flag register
(FLGL)
Flag register
(FLG H)
Content of
previous stack
Content of
previous stack
Stack status after interrupt request is acknowledged
Figure 1.9.7. Stack status before and after an interrupt request is acknowledged
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Interrupts
Return from Interrupt Routine
As you execute the REIT instruction at the end of the interrupt routine, the contents of the flag register
(FLG) and program counter (PC) that have been saved to the stack area immediately preceding the
interrupt sequence are automatically restored. In high-speed interrupt, as you execute the FREIT instruction at the end of the interrupt routine, the contents of the flag register (FLG) and program counter
(PC) that have been saved to the save registers immediately preceding the interrupt sequence are automatically restored.
Then control returns to the routine that was under execution before the interrupt request was acknowledged, and processing is resumed from where control left off.
If there are any registers you saved via software in the interrupt routine, be sure to restore them using an
instruction (e.g., POPM instruction) before executing the REIT or FREIT instruction.
When switching the register bank before executing REIT and FREIT instruction, switched to the register
bank immediately before the interrupt sequence.
Interrupt Priority
If two or more interrupt requests are sampled active at the same time, the interrupt with the highest
priority will be acknowledged.
Maskable interrupts (Peripheral I/O interrupts) can be assigned any desired priority by setting the interrupt priority level select bit accordingly. If some maskable interrupts are assigned the same priority level,
the priority between these interrupts are resolved by the priority that is set in hardware.
Certain nonmaskable interrupts such as a reset (reset is given the highest priority) and watchdog timer
interrupt have their priority levels set in hardware. Figure 1.9.8 lists the hardware priority levels of these
interrupts.
Software interrupts are not subjected to interrupt priority. They always cause control to branch to an
interrupt routine whenever the relevant instruction is executed.
Interrupt Resolution Circuit
Interrupt resolution circuit selects the highest priority interrupt when two or more interrupt requests are
sampled active at the same time.
Figure 1.9.9 shows the interrupt resolution circuit.
_______
Reset > NMI > Watchdog > Peripheral I/O > Single step > Address match
Figure 1.9.8. Interrupt priority that is set in hardware
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Interrupts
High
Mitsubishi Microcomputers
Priority level of each interrupt
Level 0 (initial value)
A-D1 conversion
DMA0
DMA1
Bus collision/start, stop
condition(UART2)
DMA2
Bus collision/start, stop
condition/fault error (UART0,3)
DMA3
Bus collision/start, stop
condition/fault error (UART1,4)
Timer A0
A-D0 conversion
Timer A1
Key input interrupt
Timer A2
Intelligent I/O interrupt 0
Timer A3
Intelligent I/O interrupt 1
Timer A4
Intelligent I/O interrupt 2
UART0 transmission/NACK
Intelligent I/O interrupt 3
UART0 reception/ACK
Intelligent I/O interrupt 4
UART1 transmission/NACK
Intelligent I/O interrupt 5
UART1 reception/ACK
Intelligent I/O interrupt 6
Timer B0
Intelligent I/O interrupt 7
Timer B1
Intelligent I/O interrupt 8
Timer B2
Intelligent I/O interrupt 9
/CAN interrupt 0
Timer B3
Intelligent I/O interrupt 10
/CAN interrupt 1
Timer B4
Intelligent I/O interrupt 11
/CAN interrupt 2
INT5
INT4
Stop/wait return interrupt level
(RLVL)
Interrupt
request
accepted.
To CLK
INT3
INT2
INT1
INT0
Timer B5
Processor interrupt priority level
(IPL)
Interrupt enable flag (I flag)
Instruction fetch
Address match
UART2 transmission/NACK
Interrupt
request
accepted.
To CPU
Watchdog timer
UART2 reception/ACK
DBC
UART3 transmission/NACK
NMI
Reset
UART3 reception/ACK
UART4 transmission/NACK
Low
UART4 reception/ACK
Priority of peripheral I/O interrupts
(if priority levels are same)
Figure 1.9.9. Interrupt resolution circuit
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Interrupts
______
INT Interrupts
________
________
INT0 to INT5 are external input interrupts. The level sense/edge sense switching bits of the interrupt control
register select the input signal level and edge at which the interrupt can be set to occur on input signal level
and input signal edge. The polarity bit selects the polarity.
With the external interrupt input edge sense, the interrupt can be set to occur on both rising and falling
edges by setting the INTi interrupt polarity switch bit of the interrupt request select register (address
031F16) to “1”. When you select both edges, set the polarity switch bit of the corresponding interrupt control
register to the falling edge (“0”).
When you select level sense, set the INTi interrupt polarity switch bit of the interrupt request select register
(address 031F16) to “0”.
Figure 1.9.10 shows the interrupt request select register.
External interrupt request cause select register
AAA
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
IFSR
Bit symbol
Address
031F16
When reset
0016
Bit name
Function
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
IFSR0
INT0 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR1
INT1 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR2
INT2 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR3
INT3 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR4
INT4 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR5
INT5 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR6
UART0/3 interrupt
cause select bit
0 : UART3 bus collision /start,stop
detect/false error detect
1 : UART0 bus collision /start,stop
detect/false error detect
IFSR7
UART1/4 interrupt
cause select bit
0 : UART4 bus collision /start,stop
detect/false error detect
1 : UART1 bus collision /start,stop
detect/false error detect
R W
Note :When level sense is selected, set this bit to "0".
When both edges are selected, set the corresponding polarity switching bit of INT interrupt control
register to "0" (falling edge).
Figure 1.9.10. External interrupt request cause select register
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Interrupts
______
NMI Interrupt
______
______
______
An NMI interrupt is generated when the input to the P85/NMI pin changes from “H” to “L”. The NMI interrupt
is a non-maskable external interrupt. The pin level can be checked in the port P85 register (bit 5 at address
03C416).
This pin cannot be used as a normal port input.
Notes:
______
______
______
When not intending to use the NMI function, be sure to connect the NMI pin to VCC (pulled-up). The NMI
interrupt is non-maskable. Because it cannot be disabled, the pin must be pulled up.
Key Input Interrupt
If the direction register of any of P104 to P107 is set for input and a falling edge is input to that port, a key
input interrupt is generated. A key input interrupt can also be used as a key-on wakeup function for cancelling the wait mode or stop mode. However, if you intend to use the key input interrupt, do not use P104 to
P107 as A-D input ports. Figure 1.9.11 shows the block diagram of the key input interrupt. Note that if an “L”
level is input to any pin that has not been disabled for input, inputs to the other pins are not detected as an
interrupt.
Setting the key input interrupt disable bit (bit 7 at address 03AF16) to “1” disables key input interrupts from
occurring, regardless of the setting in the interrupt control register. When “1” is set in the key input interrupt
disable register, there is no input via the port pin even when the direction register is set to input.
Port P104-P107 pull-up
select bit
Pull-up
transistor
Port P107 direction
register
Key input interrupt control
register
(address 009316)
Port P107 direction register
P107/KI3
Pull-up
transistor
Port P106 direction
register
Interrupt control
circuit
P106/KI2
Pull-up
transistor
Key input interrupt
request
Port P105 direction
register
P105/KI1
Pull-up
transistor
Port P104 direction
register
P104/KI0
Figure 1.9.11. Block diagram of key input interrupt
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Address Match Interrupt
An address match interrupt is generated when the address match interrupt address register contents match
the program counter value. Four address match interrupts can be set, each of which can be enabled and
disabled by an address match interrupt enable bit. Address match interrupts are not affected by the interrupt enable flag (I flag) and processor interrupt priority level (IPL).
Figure 1.9.12 shows the address match interrupt-related registers.
Set the start address of an instruction to the address match interrupt register.
Address match interrupt is not generated when address such as the middle of instruction or table data is
set.
Address match interrupt enable register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
AIER
Address
000916
When reset
XXXX00002
AAAAAAAAAAAAAA
AAAAAAAAAAAAAA
AA
A
AAAAAAAAAAAAAA
AA
A
AAAAAAAAAAAAAA
AA
A
AAAAAAAAAAAAAA
AA
A
AAAAAAAAAAAAAA
AA
A
AAAAAAAAAAAAAA
Bit symbol
Bit name
AIER0
Address match interrupt 0
enable bit
Function
0 : Interrupt disabled
1 : Interrupt enabled
AIER1
Address match interrupt 1
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
AIER2
Address match interrupt 2
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
AIER3
Address match interrupt 3
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
RW
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Address match interrupt register i (i = 0, 1)
(b23)
b7
(b16)(b15)
b0 b7
(b8)
b0 b7
b0
Symbol
RMAD0
RMAD1
RMAD2
RMAD3
Function
Address setting register for address match
interrupt
Figure 1.9.12. Address match interrupt-related registers
100
Address
001216 to 001016
001616 to 001416
001A16 to 001816
001E16 to 001C16
When reset
00000016
00000016
00000016
00000016
AAA
Values that can be set
00000016 to FFFFFF16
R W
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Intelligent I/O and CAN Interrupt
Group 0 to 3 intelligent I/O interrupts and CAN interrupt are assigned to software interrupt numbers 44 to 54
and 57.
As intelligent I/O interrupt request, there are base timer interrupt request signals, time measurement interrupt request signals, waveform generation interrupt request signals and interrupt request signals from various communication circuits.
Figure 1.9.13 shows the intelligent I/O interrupts and CAN interrupt block diagram, figure 1.9.14 shows the
interrupt request register and figure 1.9.15 shows interrupt enable register.
AAA
AAA
AAA
AAA
AAA
AAA
AAA
AAA
AAA
"0"
D
Interrupt request A
Write "0" to interrupt
request flag A
Q
R
Write "0" to interrupt
request flag B
Interrupt
request bit
"0"
D
Interrupt request B
"1" Interrupt
enable bit A
Q
R
D
Q
R
"1" Interrupt
enable bit B
Cleared when
an Interrupt
request
received
"0"
D
Interrupt request n
Write "0" to interrupt
request flag n
Q
R
"1" Interrupt
enable bit n
Interrupt request
latch bit
Interrupt request flag
n=A to L
Figure 1.9.13. Intelligent I/O and CAN interrupt block diagram
When using the intelligent I/O or CAN interrupt as an starting factor for DMA II, the interrupt latch bit must be
set to "0" in order to enable only the interrupt request factor used by the interrupt enable register.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Interrupt request register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
IIOiIR
Bit
symbol
Address
See below
When reset
0000 000X2
Bit name
Function
R W
Nothing is assigned.
When write, set "0". When read, the content is indeterminate.
0 : Interrupt request not present
1 : Interrupt request present
(Note)
0 : Interrupt request not present
1 : Interrupt request present
(Note)
Interrupt request flag 3
0 : Interrupt request not present
1 : Interrupt request presence
(Note)
IRF4
Interrupt request flag 4
0 : Interrupt request not present
1 : Interrupt request present
(Note)
IRF5
Interrupt request flag 5
0 : Interrupt request not present
1 : Interrupt request present
(Note)
IRF6
Interrupt request flag 6
0 : Interrupt request not present
1 : Interrupt request present
(Note)
IRF7
Interrupt request flag 7
0 : Interrupt request not present
1 : Interrupt request present
(Note)
IRF1
Interrupt request flag 1
IRF2
Interrupt request flag 2
IRF3
Note: "0" can be written.
Interrupt request register table
Symbol
Address
bit7
(IRF7)
bit6
(IRF6)
bit5
(IRF5)
bit4
(IRF4)
bit3
(IRF3)
bit2
(IRF2)
bit1
(IRF1)
bit0
-
IIO0IR
00A016
-
-
IIO1IR
00A116
-
-
SIO0r
G0RI
-
SIO0t
G0TO
-
PO13
TM02
-
PO14
TM00/PO00
IIO2IR
00A216
-
-
SIO1r
G1RI
-
-
TM12/PO12
-
IIO3IR
00A316
-
IIO4IR
00A416
-
-
SIO1t
G1TO
PO27
PO10
TM03
-
IIO5IR
00A516
BEAN0
BEAN1
-
-
-
BT1
PO32
-
SIO2r
PO33
PO21
TM05/PO05
IIO6IR
00A616
-
-
-
-
SIO2t
PO34
PO20
TM06
IIO7IR
00A716
-
IE0
-
-
BT0
PO35
PO22
TM07
IIO8IR
-
00A816
IE1
IE2
-
BT2
PO36
PO23
TM11/PO11
-
IIO9IR
00A916
CAN0
-
-
-
PO31
PO24
PO15
-
IIO10IR
00AA16
CAN1
-
-
-
PO30
PO25
TM16/PO16
-
IIO11IR
00AB16
CAN2
-
-
BT3
PO37
PO26
TM01/PO01
-
BTi
TMij
POij
SIOir/SIOit
GiTO/GiRI
BEANi
IE
CANi
-
TM17/PO17 TM04/PO04
-
: Interrupt request from base timer of intelligent I/O group i
: Interrupt request from time measurement function ch j of intelligent I/O group i
: Interrupt request from waveform generator function ch j of intelligent I/O group i
: Interrupt request from communication function of intelligent I/O group i (r:reception, t:transmission)
: Interrupt request from HDLC data processing function of intelligent I/O group i
(RI:reception input, TO:transmission output)
: Interrupt request from special communication function of intelligent I/O group i (i=0,1)
: Interrupt request from IEBus communication function of intelligent I/O group 2
: Interrupt request from AN communication function (i=0 to 2)
: Nothing is assigned in this bit.
Figure 1.9.14. Interrupt request registers
Bit 1 to bit 7: Interrupt request flag (IRF1 to IRF7)
To retain respective interrupt requests and judge interrupt kind occurred in the interrupt process routine.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Interrupt enable register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
IIOiIE
Bit
symbol
Address
See below
When reset
0016
Bit name
Function
R W
IRLT
Interrupt request latch bit
0: Interrupt request is not latched(used by DMA II)
1: Interrupt request is latched(used by interrupt)
ITE1
Interrupt enable bit 1
0: Interrupt of corresponding interrupt
request flag (IRF1) disabled
1: Interrupt of corresponding interrupt
request flag (IRF1) enabled
ITE2
Interrupt enable bit 2
ITE3
Interrupt enable bit 3
ITE4
Interrupt enable bit 4
0: Interrupt of corresponding interrupt
request flag (IRF4) disabled
1: Interrupt of corresponding interrupt
request flag (IRF4) enabled
ITE5
Interrupt enable bit 5
0: Interrupt of corresponding interrupt
request flag (IRF5) disabled
1: Interrupt of corresponding interrupt
request flag (IRF5) enabled
ITE6
Interrupt enable bit 6
ITE7
Interrupt enable bit 7
0: Interrupt of corresponding interrupt
request flag (IRF2) disabled
1: Interrupt of corresponding interrupt
request flag (IRF2) enabled
0: Interrupt of corresponding interrupt
request flag (IRF3) disabled
1: Interrupt of corresponding interrupt
request flag (IRF3) enabled
0: Interrupt of corresponding interrupt
request flag (IRF6) disabled
1: Interrupt of corresponding interrupt
request flag (IRF6) enabled
0: Interrupt of corresponding interrupt
request flag (IRF7) disabled
1: Interrupt of corresponding interrupt
request flag (IRF7) enabled
Interrupt request register table
Address
bit7
(ITE7)
bit6
(ITE6)
bit5
(ITE5)
bit4
(ITE4)
bit3
(ITE3)
bit2
(ITE2)
bit1
(ITE1)
bit1
(IRLT)
IIO0IE
00B016
-
-
IIO1IE
00B116
-
-
SIO0r
G0RI
-
SIO0t
G0TO
-
PO13
TM02
IRLT
PO14
TM00/PO00
IIO2IE
00B216
-
-
SIO1r
G1RI
IRLT
-
TM12/PO12
-
IIO3IE
00B316
-
-
SIO1t
IRLT
G1TO
PO27
PO10
TM03
IIO4IE
00B416
BEAN0
BEAN1
IRLT
-
BT1
PO32
IIO5IE
00B516
-
IIO6IE
00B616
-
-
-
SIO2r
PO33
PO21
TM05/PO05
IRLT
-
-
SIO2t
PO34
PO20
TM06
IIO7IE
00B716
IRLT
IE0
-
-
BT0
PO35
PO22
TM07
IIO8IE
IRLT
00B816
IE1
IE2
-
BT2
PO36
PO23
TM11/PO11
IRLT
IIO9IE
00B916
CAN0
-
-
-
PO31
PO24
PO15
IRLT
IIO10IE
00BA16
CAN1
-
-
-
PO30
PO25
TM16/PO16
IRLT
IIO11IE
00BB16
CAN2
-
-
BT3
PO37
PO26
TM01/PO01
IRLT
Symbol
BTi
TMij
POij
SIOir/SIOit
GiTO/GiRI
BEANi
IE
CANi
-
TM17/PO17 TM04/PO04
IRLT
: Interrupt request from base timer of intelligent I/O group i is enabled
: Interrupt request from time measurement function ch j of intelligent I/O group i is enabled
: Interrupt request from waveform generator function ch j of intelligent I/O group i is enabled
: Interrupt request from communication function of intelligent I/O group i (r:reception, t:transmission) is enabled
: Interrupt request from HDLC data processing function of intelligent I/O group i (RI:reception input,
TO:transmission output) is enabled
: Interrupt request from special communication function of intelligent I/O group i (i=0,1) is enabled
: Interrupt request from IEBus communication function of intelligent I/O group 2 is enabled
: Interrupt request from CAN communication function (i=0 to 2) is enabled
: Nothing is assigned in this bit. (Set "0" to these bits.)
Figure 1.9.15. Interrupt enable registers
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
Bit 0: Interrupt request latch bit (IRLT)
An interrupt signal or latched signal of the interrupt signal is selected as an interrupt request signal.
When the latched signal of an interrupt signal is used, this flag must be set to "0" after interrupt request
flag is read in interrupt process routine, . If this flag is not set to "0" and interrupt process is completed,
although interrupt request occurs again, interrupt will not occur.
Bit 1 to bit 7: Interrupt enable bit (ITE 1 to ITE 7)
To enable/disable respective interrupts.
Precautions for Interrupts
(1) Reading addresses 00000016 and 00000216
• When maskable interrupt occurs, CPU reads the interrupt information (the interrupt number and interrupt request level) in the interrupt sequence from address 00000016. When a high-speed interrupt
occurs, CPU reads from address 00000216.
The interrupt request bit of the certain interrupt will then be set to “0”.
However, reading addresses 00000016 and 00000216 by software does not set request bit to “0”.
(2) Setting the stack pointer
• The value of the stack pointer immediately after reset is initialized to 00000016. Accepting an interrupt
before setting a value in the stack pointer may cause runaway. Be sure to set a value in the stack
_______
pointer before accepting an interrupt. When using the NMI interrupt, initialize the stack point at the
_______
beginning of a program. Any interrupt including the NMI interrupt is generated immediately after executing the first instruction after reset. Set an even number to the stack pointer. Set an even address
to the stack pointer so that operating efficiency is increased.
_______
(3) The NMI interrupt
_______
• As for the NMI interrupt pin, this interrupt cannot be disabled. Connect it to the Vcc pin via a pull-up
resistor if unused.
_______
• The NMI pin also serves as P85, which is exclusively input. Reading the contents of the P8 register
allows reading the pin value. Use the reading of this pin only for establishing the pin level at the time
_______
when the NMI interrupt is input.
_______
• A low level signal with more than 1 clock cycle (BCLK) is necessary for NMI pin.
(4) External interrupt
• Edge sense
Either a low level or a high level for at least 250 ns is necessary for the signal input to pins INT0
to INT5 regardless of the CPU operation clock.
• Level sense
Either a low level or a high level of 1 cycle of BCLK + at least 200 ns width is necessary for the signal
input to pins INT0 to INT5 regardless of the CPU operation clock. (When XIN=20MHz and no division
mode, at least 250 ns width is necessary.)
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Interrupts
• When the polarity of the INT0 to INT5 pins is changed, the interrupt request bit is sometimes set to "1".
After changing the polarity, set the interrupt request bit to "0". Figure 1.9.12 shows the procedure for
______
changing the INT interrupt generate factor.
Set the interrupt priority level to level 0
(Disable INTi interrupt)
Set the polarity select bit
Clear the interrupt request bit to “0”
Set the interrupt priority level to level 1 to 7
(Enable the accepting of INTi interrupt request)
______
Figure 1.9.16. Switching condition of INT interrupt request
(5) Rewrite the interrupt control register
• When an instruction to rewrite the interrupt control register is executed but the interrupt is disabled, the
interrupt request bit is not set sometimes even if the interrupt request for that register has been generated. This will depend on the instruction. If this creates problems, use the below instructions to change
the register.
Instructions : AND, OR, BCLR, BSET
(6) Rewrite interrupt request register
• When writing to "0" to this register, the following instructions must be used.
Instructions : AND, BCLR
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Watchdog Timer
Watchdog Timer
The watchdog timer has the function of detecting when the program is out of control. The watchdog timer is
a 15-bit counter which down-counts the clock derived by dividing the BCLK using the prescaler. Whether a
watchdog timer interrupt is generated or reset is selected when an underflow occurs in the watchdog timer.
Watchdog timer interrupt is selected when bit 6 (CM06) of the system control register 0 (address 000816) is
"0" and reset is selected when CM06 is "1". No value other than "1" can be written in CM06. Once reset is
selected (CM06="1"), watchdog timer interrupt cannot be selected by software.
When XIN is selected for the BCLK, bit 7 (WDC7) of the watchdog timer control register (address 000F16)
selects the prescaler division ratio (by 16 or by 128). When XCIN is selected as the BCLK, the prescaler is
set for division by 2 regardless of WDC7. Therefore, the watchdog timer cycle can be calculated as follows.
However, errors can arise in the watchdog timer cycle due to the prescaler.
When XIN is selected in BCLK
Watchdog timer cycle =
Prescaler division ratio (16 or 128) x watchdog timer count (32768)
BCLK
When XCIN is selected in BCLK
Watchdog timer cycle =
Prescaler division ratio (2) x watchdog timer count (32768)
BCLK
For example, when BCLK is 20MHz and the prescaler division ratio is set to 16, the monitor timer cycle is
approximately 26.2 ms, and approximately 17.5 ms when BCLK is 30MHz.
The watchdog timer is initialized by writing to the watchdog timer start register (address 000E16) and when
a watchdog timer interrupt request is generated. The prescaler is initialized only when the microcomputer is
reset. After a reset is cancelled, the watchdog timer and prescaler are both stopped. The count is started by
writing to the watchdog timer start register (address 000E16). CM06 is initialized only at reset. After reset,
watchdog timer interrupt is selected.
The watchdog timer and the prescaler stop in stop mode, wait mode and hold status. After exiting these
modes and status, counting starts from the previous value.
In the stop mode, wait mode and hold state, the watchdog timer and prescaler are stopped. Counting is
resumed from the held value when the modes or state are released. Figure 1.10.1 shows the block diagram
of the watchdog timer. Figure 1.10.2 and 1.10.3 show the watchdog timer-related registers.
Prescaler
1/16
BCLK
1/128
“CM07 = 0”
“WDC7 = 0”
"CM06=0"
Watchdog timer
interrupt request
“CM07 = 0”
“WDC7 = 1”
Watchdog timer
HOLD
"CM06=1"
“CM07 = 1”
Reset
1/2
Write to the watchdog timer
start register
(address 000E16)
RESET
Figure 1.10.1. Block diagram of watchdog timer
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Watchdog Timer
Watchdog timer control register
b7
b6
b5
b4
b3
b2
b1
b0
0 0
Symbol
Address
When reset
WDC
000F16
000XXXXX2
Bit
symbol
Bit name
Function
R W
High-order bit of watchdog timer
WDC7
Reserved bit
Must always be set to "0"
Prescaler select bit
0 : Divided by 16
1 : Divided by 128
Watchdog timer start register
b7
b0
Symbol
WDTS
Address
000E16
When reset
Indeterminate
Function
R W
The watchdog timer is initialized and starts counting after a write
instruction to this register. The watchdog timer value is always initialized
to "7FFF16" regardless of the value written.
Figure 1.10.2. Watchdog timer control and start registers
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Watchdog Timer
System clock control register 0 (Note 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
CM0
Bit symbol
CM00
Address
000616
Bit
name
Clock output function
select bit (Note 2)
CM01
CM02
WAIT peripheral
function clock stop bit
When reset
0000 X0002
Function
b1 b0
0 0 : I/O port P53
0 1 : fC output
1 0 : f8 output
1 1 : f32 output
0 : Do not stop peripheral clock
in wait mode
1 : Stop peripheral clock in
wait mode
(Note 3)
AA
AA
AA
A
A
A
A
A
A
A
AA
A
AA
RW
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Port XC select bit
0 : I/O port
CM04
1 : XCIN-XCOUT generation (Note 4)
CM05
Main clock (XIN-XOUT)
stop bit (Note 5)
0 : Main clock On
1 : Main clock Off (Note 6)
CM06
Watchdog timer
function select bit
0 : Watchdog timer interrupt
1 : Reset (Note 7)
CM07
System clock select bit
(Note 8)
0 : XIN, XOUT
1 : XCIN, XCOUT
Note 1: Set bit 0 of the protect register (address 000A16) to “1” before writing to this register.
Note 2: The port P53 dose not function as an I/O port in microprocessor or memory expansion
mode.
When outputting ALE to P53 (bits 5 and 4 of processor mode register 0 is "01"), set
these bits to "00".
The port P53 function is not selected, even when you set "00" in microprocessor or
memory expansion mode and bit 7 of the processor mode register 0 is "1".
Note 3: fc32 is not included. When this bit is set to "1", PLL cannot be used in WAIT.
Note 4: When XcIN-XcOUT is used, set port P86 and P87 to no pull-up resistance with the input
port.
Note 5: When entering the power saving mode, the main clock is stopped using this bit. To stop
the main clock, set system clock stop bit (CM07) to "1" while an oscillation of sub clock is
stable. Then set this bit to "1".
When XIN is used after returning from stop mode, set this bit to "0".
When this bit is "1", XOUT is "H". Also, the internal feedback resistance remains ON, so
XIN is pulled up to XOUT ("H" level) via the feedback resistance.
Note 6: When the main clock is stopped, the main clock division register (address 000C16) is set
to the division by 8 mode.
However, in ring oscillator mode, the main clock division register is not set to the division
by 8 mode when XIN-XOUT is stopped by this bit.
Note 7: When "1" has been set once, "0" cannot be written by software.
Note 8: Set this bit "0" to "1" when sub clock oscillation is stable by setting CM04 to "1".
Set this bit "1" to "0" when main clock oscillation is stable by setting CM05 to "0".
Do not set CM04 and CM05 simultaneously.
Figure 1.10.3. System clock control register 0
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
DMAC
This microcomputer has four DMAC (direct memory access controller) channels that allow data to be sent
to memory without using the CPU. DMAC is a function that transmit delete data of a source address (8 bits
/16 bits) to a destination address when transmission request occurs. When using three or more DMAC
channels, the register bank 1 and high-speed interrupt register are used as DMAC registers. If you are
using three or more DMAC channels, you cannot use high-speed interrupts. The CPU and DMAC use the
same data bus, but the DMAC has a higher bus access privilege than the CPU, and because of the use of
cycle-steeling, operations are performed at high-speed from the occurrence of a transfer request until one
word (16 bits) or 1 byte (8 bits) of data have been sent. Figure 1.11.1 shows the mapping of registers used
by the DMAC. Table 1.11.1 shows DMAC specifications. Figures 1.11.2 to 1.11.5 show the structures of the
registers used.
As the registers shown in Figure 1.11.1 are allocated in the CPU, use LDC instruction when writing. When
writing to DCT2, DCT3, DRC2, DRC3, DMA2 and DMA3, set register bank select flag (B flag) to "1" and use
MOV instruction to set R0 to R3, A0 and A1 registers. When writing to DSA2 and DSA3, set register bank
select flag (B flag) to "1" and use LDC instruction to set SB and FB registers.
DMAC related registers
DMD0
DMD1
DMA mode register 0, 1
DCT0
DCT1
DMA 0, 1 transfer count register
DRC0
DRC1
DMA 0, 1 transfer count reload register
DMA0
DMA1
DMA 0, 1 memory address register
DSA0
DSA1
DMA 0, 1 SFR address register
DRA0
DRA1
DMA 0, 1 memory address reload register
When using three or more DMAC channels
The register bank 1 is used as a DMAC register
When using three or more DMAC channels
The high-speed interrupt register is used as a DMAC
register
Flag save register
DCT2 (R0)
DMA2 transfer count register
SVF
DCT3 (R1)
DMA3 transfer count register
DRA2 (SVP)
DMA2 memory address reload register
DRC2 (R2)
DMA2 transfer count reload register
DRA1 (VCT)
DMA3 memory address reload register
DRC3 (R3)
DMA3 transfer count reload register
DMA2 (A0)
DMA2 memory address register
DMA3 (A1)
DMA3 memory address register
DSA2 (SB)
DMA2 SFR address register
DSA3 (FB)
DMA3 SFR address register
When using DMA2 and DMA3, use the CPU
registers shown in parentheses.
Figure 1.11.1. Register map using DMAC
In addition to writing to the software DMA request bit to start DMAC transfer, the interrupt request signals
output from the functions specified in the DMA request factor select bits are also used. However, in contrast
to the interrupt requests, repeated DMA requests can be received, regardless of the interrupt flag.
(Note, however, that the number of actual transfers may not match the number of transfer requests if the
DMA request cycle is shorter than the DMR transfer cycle. For details, see the description of the DMAC
request bit.)
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DMAC
Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Table 1.11.1. DMAC specifications
Item
Specification
No. of channels
4 (cycle steal method)
Transfer memory space
• From any address in the 16 Mbytes space to a fixed address (16
Mbytes space)
• From a fixed address (16 Mbytes space) to any address in the 16 M
bytes space
Maximum No. of bytes transferred 128 Kbytes (with 16-bit transfers) or 64 Kbytes (with 8-bit transfers)
________
________
DMA request factors (Note)
Falling edge of INT0 to INT3 or both edge
Timer A0 to timer A4 interrupt requests
Timer B0 to timer B5 interrupt requests
UART0 to UART4 transmission and reception interrupt requests
A-D conversion interrupt requests
Intelligent I/O interrupt
Software triggers
Channel priority
DMA0 > DMA1 > DMA2 > DMA3 (DMA0 is the first priority)
Transfer unit
Transfer address direction
8 bits or 16 bits
forward/fixed (forward direction cannot be specified for both source and
destination simultaneously)
Transfer mode
• Single transfer
Transfer ends when the transfer count register is "000016".
• Repeat transfer
When the transfer counter is "000016", the value in the transfer
counter reload register is reloaded into the transfer counter and the
DMA transfer is continued
DMA interrupt request generation timing When the transfer counter register changes from "000116" to "000016".
DMA startup
• Single transfer
Transfer starts when DMA transfer count register is more than
"000116" and the DMA is requested after “012” is written to the
channel i transfer mode select bits
• Repeat transfer
Transfer starts when the DMA is requested after “112” is written to the
channel i transfer mode select bits
DMA shutdown
• Single transfer
When “002” is written to the channel i transfer mode select bits and
DMA transfer count register becomes "000016" by DMA transfer or
write
• Repeat transfer
When “002” is written to the channel i transfer mode select bits
Reload timing
When the transfer counter register changes from "000116" to "000016" in
repeat transfer mode.
Reading / writing the register
Registers are always read/write enabled.
Number of DMA transfer cycles Between SFR and internal RAM : 3 cycles
Between external I/O and external memory : minimum 3 cycles
Note: DMA transfer doed not affect any interrupt.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
DMAi request cause select register (i=0 to 3)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
DMiSL(i=0 to 3)
Bit
symbol
Address
037816, 037916, 037A16, 037B16
Bit name
When reset
0X0000002
Function
R W
DSEL0
DSEL1
DSEL2
Refer to function table
DMA request cause
select bit
(Note 1)
DSEL3
DSEL4
DSR
If software trigger is selected, a DMA request
Software DMA
is generated by setting this bit to "1" (When
request bit
(Note 2)
read, the value of this bit is always "0")
Nothing is assigned. When write, set "0".
When read, its content is indeterminate.
DRQ
0 : Not requested
DMA request bit
(Note 2, 3) 1 : Requested
Note 1: Set DMA inhibit before changing the DMA request cause. Set DRQ bit to "1" simultaneously.
e.g.) MOV.B #083h, DMiSL ; Set timer A0
Note 2: When setting DSR to "1", set DRQ bit to "1" using OR instruction etc. simultaneously.
e.g.) OR.B #0A0h, DMiSL
Note 3: Do not write "0" to this bit. There is no need to clear the DMA request bit.
Figure 1.11.2. DMAC register (1)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
Table 1.11.2. DMAi request cause select register function
Setting value
b4 b3 b2 b1 b0
DMA request cause
DMA0
DMA1
DMA2
DMA3
0 0 0 0 0
Software trigger
0 0 0 0 1
Falling edge of INT0 pin Falling edge of INT1 pin Falling edge of INT2 pin Falling edge of INT3 pin
0 0 0 1 0
Both edges of INT0
Both edges of INT1
Both edges of INT2
0 0 0 1 1
Timer A0
0 0 1 0 0
Timer A1
0 0 1 0 1
Timer A2
0 0 1 1 0
Timer A3
0 0 1 1 1
Timer A4
0 1 0 0 0
Timer B0
0 1 0 0 1
Timer B1
0 1 0 1 0
Timer B2
0 1 0 1 1
Timer B3
0 1 1 0 0
Timer B4
0 1 1 0 1
Timer B5
0 1 1 1 0
UART0 transmit
0 1 1 1 1
UART0 receive /ACK
1 0 0 0 0
UART1 transmit
1 0 0 0 1
UART1 receive /ACK
1 0 0 1 0
UART2 transmit
1 0 0 1 1
UART2 receive /ACK
1 0 1 0 0
UART3 transmit
1 0 1 0 1
UART3 receive /ACK
1 0 1 1 0
UART4 transmit
1 0 1 1 1
UART4 receive /ACK
Both edges of INT3
(Note 1)
(Note 1)
(Note 2)
(Note 2)
(Note 2)
(Note 2)
(Note 2)
1 1 0 0 0
A-D0
A-D1
A-D0
A-D1
1 1 0 0 1
Intelligent I/O interrupt
control register 0
Intelligent I/O interrupt
control register 7
Intelligent I/O interrupt
control register 2
Intelligent I/O interrupt
control register 9
1 1 0 1 0
Intelligent I/O interrupt
control register 1
Intelligent I/O interrupt
control register 8
Intelligent I/O interrupt
control register 3
Intelligent I/O interrupt
control register 10
1 1 0 1 1
Intelligent I/O interrupt
control register 2
Intelligent I/O interrupt
control register 9
Intelligent I/O interrupt
control register 4
Intelligent I/O interrupt
control register 11
1 1 1 0 0
Intelligent I/O interrupt
control register 3
Intelligent I/O interrupt
control register 10
Intelligent I/O interrupt
control register 5
Intelligent I/O interrupt
control register 0
1 1 1 0 1
Intelligent I/O interrupt
control register 4
Intelligent I/O interrupt
control register 11
Intelligent I/O interrupt
control register 6
Intelligent I/O interrupt
control register 1
1 1 1 1 0
Intelligent I/O interrupt
control register 5
Intelligent I/O interrupt
control register 0
Intelligent I/O interrupt
control register 7
Intelligent I/O interrupt
control register 2
1 1 1 1 1
Intelligent I/O interrupt
control register 6
Intelligent I/O interrupt
control register 1
Intelligent I/O interrupt
control register 8
Intelligent I/O interrupt
control register 3
Note 1: When INT3 pin is data bus in microprocessor mode, INT3 edge cannot be used as DMA3 request cause.
Note 2: UARTi receive /ACK switched by setting of UARTi special mode register and UARTi special mode
register 2 (i=0 to 3)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
DMA mode register 0
(CPU internal register)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
DMD0
When reset
0016
Function
Bit name
Bit symbol
Channel 0 transfer
mode select bit
b1 b0
BW0
Channel 0 transfer
unit select bit
0 : 8 bits
1 : 16 bits
RW0
Channel 0 transfer
direction select bit
0 : Fixed address to memory (forward direction)
1 : Memory (forward direction) to fixed address
MD10
Channel 1 transfer
mode select bit
b5 b4
BW1
Channel 1 transfer
unit select bit
0 : 8 bits
1 : 16 bits
RW1
Channel 1 transfer 0 : Fixed address to memory (forward direction)
direction select bit 1 : Memory (forward direction) to fixed address
MD00
MD01
MD11
0 0 : DMA inhibit
0 1 : Single transfer
1 0 : Must not be set
1 1 : Repeat transfer
0 0 : DMA inhibit
0 1 : Single transfer
1 0 : Must not be set
1 1 : Repeat transfer
AA
A
A
AA
A
AA
A
AA
A
AA
A
A
A
A
AA
R W
DMA mode register 1
(CPU internal register)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
DMD1
Bit symbol
MD20
MD21
When reset
0016
Function
Bit name
b1 b0
Channel 2 transfer
0 0 : DMA inhibit
mode select bit
0 1 : Single transfer
1 0 : Must not be set
1 1 : Repeat transfer
BW2
Channel 2 transfer 0 : 8 bits
unit select bit
1 : 16 bits
RW2
Channel 2 transfer 0 : Fixed address to memory (forward direction)
direction select bit 1 : Memory (forward direction) to fixed address
MD30
Channel 3 transfer b5 b4
0 0 : DMA inhibit
mode select bit
0 1 : Single transfer
1 0 : Must not be set
1 1 : Repeat transfer
MD31
BW3
Channel 3 transfer 0 : 8 bits
unit select bit
1 : 16 bits
RW3
Channel 3 transfer 0 : Fixed address to memory (forward direction)
direction select bit 1 : Memory (forward direction) to fixed address
A
A
AA
A
A
AA
A
A
A
A
A
AA
A
AA
A
AA
R W
Figure 1.11.3. DMAC register (2)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
DMAi transfer count register (i = 0 to 3)
(CPU internal register)
b15
b0
Symbol
DCT0
(Note 2)
DCT1
(Note 2)
DCT2 (bank 1;R0) (Note 3)
DCT3 (bank 1;R1) (Note 3)
Function
Set transfer number
Address
(CPU internal register)
(CPU internal register)
(CPU internal register)
(CPU internal register)
When reset
XXXX16
XXXX16
000016
000016
Setting range
AA
R W
000016 to FFFF16
Note 1: When "0" is set to this register, data transfer is not done even if DMA
is requested.
Note 2: Use LDC instruction to write to this register.
Note 3: When setting DCT2 and DCT3, set "1" to the register bank select flag
(B flag) of flag register (FLG), then set desired value to R0 and R1 of
register bank 1. Use MOV instruction to write to this register.
DMAi transfer count reload register (i = 0 to 3)
(CPU internal register)
b15
b0
Symbol
DRC0
(Note 1)
DRC1
(Note 1)
DRC2 (bank 1;R2) (Note 2)
DRC3 (bank 1;R3) (Note 2)
Function
Set transfer number
Address
(CPU internal register)
(CPU internal register)
(CPU internal register)
(CPU internal register)
When reset
XXXX16
XXXX16
000016
000016
Setting range
000016 to FFFF16
AA
A
A
AA
RW
Note 1: Use LDC instruction to write to this register.
Note 2: When setting DRC2 and DRC3, set "1" to the register bank select
flag (B flag) of flag register (FLG), then set desired value to R2 and
R3 of register bank 1. Use MOV instruction to write to this register.
Figure 1.11.4. DMAC register (3)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
DMAi memory address register (i = 0 to 3)
(CPU internal register)
b0
b23
Symbol
DMA0
(Note 2)
DMA1
(Note 2)
DMA2 (bank 1;A0) (Note 3)
DMA3 (bank 1;A1) (Note 3)
Function
Address
(CPU internal register)
(CPU internal register)
(CPU internal register)
(CPU internal register)
Setting range
Set source or destination memory address
(Note 1)
When reset
XXXXXX16
XXXXXX16
00000016
00000016
AA
A
A
AA
R W
00000016 to FFFFFF16
(16 Mbytes area)
Note 1: When the transfer direction select bit is "0" (fixed address to memory), this register
is destination memory address.
When the transfer direction select bit is "1" (memory to fixed address), this register
is source memory address.
Note 2: Use LDC instruction to write to this register.
Note 3: When setting DMA2 and DMA3, set "1" to the register bank select flag (B flag) of
flag register (FLG), and set desired value to A0 and A1 of register bank 1. Use
MOV instruction to write to this register.
DMAi SFR address register (i = 0 to 3)
(CPU internal register)
b0
b23
Symbol
DSA0
(Note 2)
DSA1
(Note 2)
DSA2 (bank 1;SB) (Note 3)
DSA3 (bank 1;FB) (Note 4)
Function
Address
(CPU internal register)
(CPU internal register)
(CPU internal register)
(CPU internal register)
Setting range
Set source or destination fixed address
(Note 1)
When reset
XXXXXX16
XXXXXX16
00000016
00000016
AA
RW
00000016 to FFFFFF16
(16 Mbytes area)
Note 1: When the transfer direction select bit is "0" (fixed address to memory), this register
is source fixed address.
When the transfer direction select bit is "1" (memory to fixed address), this register
is destination fixed address.
Note 2: Use LDC instruction to write to this register.
Note 3: When setting DSA2, set "1" to the register bank select flag (B flag) of flag register
(FLG), and set desired value to SB of register bank 1. Use LDC instruction to write
to this register.
Note 4: When setting DSA3, set "1" to the register bank select flag (B flag) of flag register
(FLG), and set desired value to FB of register bank 1. Use LDC instruction to write
to this register.
DMAi memory address reload register (i = 0 to 3) (Note 1)
(CPU internal register)
b23
b0
Symbol
DRA0
DRA1
DRA2 (bank 1;SVP) (Note 2)
DRA3 (bank 1;VCT) (Note 3)
Function
Set source or destination memory address
Address
(CPU internal register)
(CPU internal register)
(CPU internal register)
(CPU internal register)
Setting range
When reset
XXXXXX16
XXXXXX16
XXXXXX16
XXXXXX16
AA
R W
00000016 to FFFFFF16
(16 Mbytes area)
Note 1: Use LDC instruction to write to this register.
Note 2: When setting DRA2, set desired value to save PC register (SVP).
Note 3: When setting DRA3, set desired value to vector register (VCT).
Figure 1.11.5. DMAC register (4)
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DMAC
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
(1) Transfer cycle
The transfer cycle consists of the bus cycle in which data is read from memory or from the SFR area
(source read) and the bus cycle in which the data is written to memory or to the SFR area (destination
write). The number of read and write bus cycles depends on the source and destination addresses. In
memory expansion mode and microprocessor mode, the number of read and write bus cycles also depends on the level of the BYTE pin. Also, the bus cycle is longer when software waits are inserted.
(a) Effect of source and destination addresses
When 16-bit data is transferred on a 16-bit data bus, and the source and destination both start at odd
addresses, there are one more source read cycle and destination write cycle than when the source
and destination both start at even addresses.
(b) Effect of external data bus width control register
When in memory expansion mode or microprocessor mode, the transfer cycle changes according to
the data bus width at the source and destination.
1. When transferring 16 bits of data and the data bus width at the source and at the destination is 8
bits (data bus width bit = “0”), there are two 8-bit data transfers. Therefore, two bus cycles are
required for reading and two cycles for writing.
2. When transferring 16 bits of data and the data bus width at the source is 8 bits (data bus width bit
= “0”) and the data bus width at the destination is 16 bits (data bus width bit = “1”), the data is read
in two 8-bit blocks and written as 16-bit data. Therefore, two bus cycles are required for reading
and one cycle for writing.
3. When transferring 16 bits of data and the data bus width at the source is 16 bits (data bus width bit
= “1”) and the data bus width at the destination is 8 bits (data bus width bit = “0”), 16 bits of data are
read and written as two 8-bit blocks. Therefore, one bus cycle is required for reading and two
cycles for writing.
(c) Effect of software wait
When the SFR area or a memory area with a software wait is accessed, the number of cycles is
increased for the soffware wait by 1 bus cycle. The length of the cycle is determined by BCLK.
Figure 1.11.6 shows the example of the transfer cycles for a source read. Figure 1.11.6 shows the destination is external area, the destination write cycle is shown as two cycle (one bus cycle) and the source
read cycles for the different conditions. In reality, the destination write cycle is subject to the same conditions as the source read cycle, with the transfer cycle changing accordingly. When calculating the transfer
cycle, remember to apply the respective conditions to both the destination write cycle and the source read
cycle. For example (2) in Figure 1.11.6, if data is being transferred in 16-bit units on an 8-bit bus, two bus
cycles are required for both the source read cycle and the destination write cycle.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
(1) •When 8-bit data is transferred
•When 16-bit data is transferred on a 16-bit data bus and the source address is even
BCLK
Address
bus
CPU use
Source
Destination
CPU use
RD signal
WR signal
Data
bus
CPU use
Destination
Source
CPU use
(2) •When 16-bit data is transferred and the source address is odd
•When 16-bit data is transferred and the width of data bus at the source is 8-bit
(When the width of data bus at the destination is 8-bit, there are also two destination write cycles).
BCLK
Address
bus
CPU use
Source
Source + 1
CPU use
Destination
RD signal
WR signal
Data
bus
CPU use
Source
Source + 1
CPU use
Destination
(3) •When one wait is inserted into the source read under the conditions in (1)
BCLK
Address
bus
CPU use
Source
Destination
CPU use
RD signal
WR signal
Data
bus
CPU use
Source
CPU use
Destination
(4) •When one wait is inserted into the source read under the conditions in (2)
(When 16-bit data is transferred and the width of data but at the destination is 8-bit, there are
two destination write cycles).
BCLK
Address
bus
CPU use
Source
Source + 1
Destination
CPU use
RD signal
WR signal
Data
bus
CPU use
Source
Source + 1
Destination
CPU use
Note: The same timing changes occur with the respective conditions at the destination as at the source.
Figure 1.11.6. Example of the transfer cycles for a source read
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
(2) DMAC transfer cycles
Any combination of even or odd transfer read and write addresses is possible. Table 1.11.2 shows the
number of DMAC transfer cycles.
The number of DMAC transfer cycles can be calculated as follows:
No. of transfer cycles per transfer unit = No. of read cycles x j + No. of write cycles x k
Table 1.11.2. No. of DMAC transfer cycles
Transfer unit
8-bit transfers
(BWi = “0”)
16-bit transfers
(BWi = “1”)
Bus width
Access address
16-bit
(DSi = “1”)
8-bit
(DSi = “0”)
16-bit
(DSi = “1”)
8-bit
(DSi = “0”)
Even
Odd
Even
Odd
Even
Odd
Even
Odd
Memory expansion mode
Microprocessor mode
No. of read No. of write No. of read No. of write
cycles
cycles
cycles
cycles
1
1
1
1
1
1
1
1
—
—
1
1
—
—
1
1
1
1
1
1
2
2
2
2
—
—
2
2
—
—
2
2
Single-chip mode
Coefficient j, k
Internal memory
External memory
Internal ROM/RAM
Internal ROM/RAM
SFR area
Separate bus
Separate bus
Separate bus
Separate bus
Multiplex bus
No wait
One wait
No wait
One wait
Two waits
Three waits
Coefficient j
1
2
2
1
2
3
4
3
Coefficient k
1
2
2
2
2
3
4
3
DMA Request Bit
The DMAC can issue DMA requests using preselected DMA request factors for each channel as triggers.
The DMA transfer request factors include the reception of DMA request signals from the internal peripheral functions, software DMA factors generated by the program, and external factors using input from
external interrupt signals.
See the description of the DMAi factor selection register for details of how to select DMA request factors.
DMA requests are received as DMA requests when the DMAi request bit is set to “1” and the channel i
transfer mode select bits are “01” or “11”. Therefore, even if the DMAi request bit is “1”, no DMA request
is received if the channel i transfer mode select bit is “00”. In this case, DMAi request bit is cleared.
Because the channel i transfer mode select bits default to “00” after a reset, remember to set the channel
i transfer mode select bit for the channel to be activated after setting the DMAC related registers. This
enables receipt of the DMA requests for that channel, and DMA transfers are then performed when the
DMAi request bit is set.
The following describes when the DMAi request bit is set and cleared.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
(1) Internal factors
The DMAi request flag is set to “1” in response to internal factors at the same time as the interrupt
request bit of the interrupt control register for each factor is set. This is because, except for software
trigger DMA factors, they use the interrupt request signals output by each function.
The DMAi request bit is cleared to "0" when the DMA transfer starts or the DMA transfer is disabled
(channel i transfer mode select bits are "00" and the DMAi transfer count register is "0").
(2) External factors
______
These are DMA request factors that are generated by the input edge from the INTi pin (where i indi______
cates the DMAC channel). When the INTi pin is selected by the DMAi request factor select bit as an
external factor, the inputs from these pins become the DMA request signals.
When an external factor is selected, the DMAi request bit is set, according to the function specified in the
______
DMA request factor select bit, on either the falling edge of the signal input via the INTi pins, or both edges.
When an external factor is selected, the DMAi request bit is cleared, in the same way as the DMAi
request bit is cleared for internal factors, when the DMA transfer starts or the DMA transfer is in
disable state.
(3) Relationship between external factor request input and DMAi request bits, and DMA transfer timing
When the request inputs to DMAi occur in the same sampling cycle (between the falling edge of BCLK
and the next falling edge), the DMAi request bits are set simultaneously, but if the DMAi enable bits
are all set, DMA0 takes priority and the transfer starts. When one transfer unit is complete, the bus
privilege is returned to the CPU. When the CPU has completed one bus access, DMA1 transfer starts,
and, when one transfer unit is complete, the privilege is again returned to the CPU.
The priority is as follows: DMA0 > DMA1 > DMA2 > DMA3.
Figure 1.11.7. DMA transfer example by external factors shows what happens when DMA0 and DMA1
requests occur in the same sampling cycle.
In this example, DMA transfer request signals are input simultaneously from
external factors and the DMA transfers are executed in the minimum cycles.
BCLK
AAA
AAA
DMA0
A
AA
AAAAAAA
A
AA
A
DMA1
CPU
INT0
AAA
AAA AA
AAA
AAAA
Bus
priviledge
acquired
DMA0
request bit
INT1
DMA1
request bit
Figure 1.11.7. DMA transfer example by external factors
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC
Precautions for DMAC
(1) Do not clear the DMA request bit of the DMAi request cause select register.
In M32C/83, when a DMA request is generated while the channel is disabled (Note), the DMA transfer is
not executed and the DMA request bit is cleared automatically.
Note :The DMA is disabled or the transfer count register is "0".
(2) When DMA transfer is done by a software trigger, set DSR and DRQ of the DMAi request cause select
register to "1" simultaneously using the OR instruction.
e.g.) OR.B #0A0h, DMiSL
; DMiSL is DMAi request cause select register
(3) When changing the DMAi request cause select bit of the DMAi request cause select register, set "1" to
the DMA request bit, simultaneously. In this case, the corresponding DMA channel is set to disabled. At
least 8 + 6 x N (N: enabled channel number) clock cycles are needed from the instruction to write to the
DMAi request cause select bit to enable DMA.
e.g.) When DMA request cause is changed to timer A0 and using DMA0 in single transfer after
DMA initial setting
push.w R0
; Store R0 register
stc
DMD0, R0
; Read DMA mode register 0
and.b
#11111100b, R0L
; Clear DMA0 transfer mode select bit to "00"
ldc
R0, DMD0
; DMA0 disabled
mov.b
#10000011b, DM0SL
; Select timer A0
; (Write "1" to DMA request bit simultaneously)
nop
At least 8 + 6 x N cycles
(N: enabled channel number)
:
ldc
pop.w
120
R0, DMD0
R0
; DMA0 enabled
; Restore R0 register
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC II
DMAC II
When requested by an interrupt from any peripheral I/O, the DMAC performs a memory-to-memory transfer, an immediate data transfer, or an arithmetic transfer (to transfer the sum of two data added).
Specifications of DMAC II are shown in Table 1.12.1.
Table 1.12.1 Specifications of DMAC II
Item
Specification
Causes to activate DMAC II
Interrupt request from any peripheral I/O whose interrupt priority is set to
"level 7" by the Interrupt Control Register
Transfer data
(1) Memory -> memory (memory-to-memory transfer)
(2) Immediate data -> memory (immediate data transfer)
(3) Memory (or immediate data) + memory -> memory (arithmetic transfer)
Unit of transfer
Transferred in 8 or 16 bits
Transfer space
64-Kbyte space at address up to 0FFFF16
Direction of transfer
Fixed or forward address
Can be selected individually for the source and the destination of transfer.
Transfer mode
(1) Single transfer
(2) Burst transfer
Chained transfer function
Parameters (transfer count, transfer address, and other information)
are switched over when the transfer counter reaches zero.
Interrupt at end of transfer
Interrupt is generated when the transfer counter reaches zero.
Multiple transfer function
Multiple data transfers can be performed by one DMA II transfer request generated.
(Note)
Note : When transfer unit is 16 bits and destination address is 0FFFF16, data is transfered to addresses
0FFFF16 and 1000016. When source address is 0FFFF16, data is transfered as in the previous.
Settings of DMAC II
DMAC II can be enabled for use by setting up the following registers and tables.
• Exit Priority Register (address 009F16)
• DMAC II Index
• Interrupt Control Register for the peripheral I/O that requests a transfer by DMAC II
• Relocatable Vector Table for the peripheral I/O that requests a transfer by DMAC II
• When using an intelligent I/O or CAN interrupt, Interrupt Enable Register’s interrupt request latch bit
(bit 0)
(1) Exit priority register (address 009F16)
If this register’s DMAC II select bit (bit 5) and fast interrupt select bit (bit 3) respectively are set to 1 and
0, DMAC II is activated by an interrupt request from any peripheral I/O whose interrupt priority is set to
“level 7” by the interrupt priority level select bit.
The configuration of the exit priority register is shown in Figure 1.12.1.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC II
Exit priority register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
RLVL
Bit
symbol
Bit name
Interrupt priority set bits
for exiting Stop/Wait
state
(Note 1)
RLVL2
FSIT
Function
R W
b2 b1 b0
RLVL0
RLVL1
When reset
XX0X00002
Address
009F16
0 0 0 : Level 0
0 0 1 : Level 1
0 1 0 : Level 2
0 1 1 : Level 3
1 0 0 : Level 4
1 0 1 : Level 5
1 1 0 : Level 6
1 1 1 : Level 7
0: Interrupt priority level 7 = normal
High-speed interrupt
interrupt
set bit
(Note 2) 1: Interrupt priority level 7 =
high-speed interrupt
Nothing is assigned.
When write, set "0". When read, its content is indeterminate.
DMA II
DMA II select bit
(Note 3)
0: Interrupt priority level 7 = normal
interrupt or high-speed interrupt
1: Interrupt priority level 7 =
DMA II transfer
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Note 1: Exits the Stop or Wait mode when the requested interrupt priority level is higher than
that set in the exit priority register.
Set to the same value as the processor interrupt priority level (IPL) set in the flag
register (FLG).
Note 2: The high-speed interrupt can only be specified for interrupts with interrupt priority level
7. Specify interrupt priority level 7 for only one interrupt.
Note 3: Do not set this bit to 0 after once setting it to 1.
When this bit is 1, do not set the high-speed interrupt select bit to 0. (This cannot be
used simultaneously with the high-speed interrupt.)
Transfers by DMAC II are unaffected by the interrupt enable flag (I flag) and processor
interrupt priority level (IPL).
Figure 1.12.1. Exit priority register
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC II
(2) DMAC II Index
The DMAC II Index is a data table, comprised of 8 to 18 bytes (max. 32 kbytes when multiple transfer
function is selected), which contains such parameters as transfer mode, transfer counter, transfer
source address (or immediate data), operation address, transfer destination address, chained transfer address, and end-of-transfer interrupt address.
This DMAC II Index is located in the RAM area.
Configuration of the DMAC II Index is shown in Figure 1.12.2. The configuration of the DMAC II Index
by transfer mode is shown in Table 1.12.2.
Memory-to-memory transfer, Immediate transfer,
Arithmetic transfer
Multiple transfer
16 bits
DMAC II Index
start address (BASE)
16 bits
Transfer mode
(MOD)
BASE
Transfer mode
(MOD)
BASE + 2
Transfer counter
(COUNT)
BASE + 2
Transfer counter
(COUNT)
BASE + 4
Transfer source address (or imm data)(SADR)
BASE + 4
Transfer source address
(SADR1)
BASE + 6
Operation address
(OADR)
BASE + 6
Transfer destination address
(DADR1)
BASE + 8
Transfer destination address
(DADR)
BASE + 8
Transfer source address
(SADR2)
BASE + 10
Chained transfer address
(CADR0)
(Note2)
BASE + 12
Chained transfer address
(CADR1)
(Note2)
BASE + 14
End-of-transfer interrupt address
(IADR0)
BASE + 16
End-of-transfer interrupt address
(IADR1)
(Note1)
BASE + 10 Transfer destination address
(DADR2)
(Note3)
BASE + 28 Transfer source address
(SADR7)
(Note3)
BASE + 30 Transfer destination address
(DADR7)
Note 1: Delete this data when not using the arithmetic transfer function.
Note 2: Delete this data when not using the chained transfer function.
Note 3: Delete this data when not using an end-of-transfer interrupt.
Figure 1.12.2. DMAC II index
• Transfer mode (MOD)
This two-byte data sets DMAC II transfer mode. Configuration of transfer modes is shown in Figure
1.12.3.
• Transfer counter (COUNT)
This two-byte data sets the number of times transfer is performed.
• Transfer source address (SADR)
This two-byte data sets the memory address from which data is transferred or immediate data.
• Operation address (OADR)
This two-byte data sets the memory address to be operated on for calculation. This data is added to
the table only when using the arithmetic transfer function.
• Transfer destination address (DADR)
This two-byte data sets the memory address to which data is transferred.
• Chained transfer address (CADR)
This four-byte data sets the DMAC II Index start address for the next DMAC II transfer to be performed. This data is added to the table only when using the chained transfer function.
• End-of-transfer interrupt address (IADR)
This four-byte data sets the jump address for end-of-transfer interrupt processing. This data is added
to the table only when using an end-of-transfer interrupt.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC II
Table 1.12.2. The configuration of the DMAC II Index by transfer mode
Transmit data
Memory-to-memory transfer
/immediate data transfer
Arithmetic transfer
Multiple transfer
Chained transfer
Not use
Use
Not use
Use
Not use
Use
Not use
Use
Cannot use
Interrupt at
end of transfer
Not use
Not use
Use
Use
Not use
Not use
Use
Use
Cannot use
DMAC II
index
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
COUNT
COUNT
COUNT
COUNT
COUNT
COUNT
COUNT
COUNT
COUNT
SADR
SADR
SADR
SADR
SADR
SADR
SADR
SADR
SADR1
DADR
DADR
DADR
DADR
OADR
OADR
OADR
OADR
DADR1
CADR0
IADR0
CADR0
DADR
DADR
DADR
DADR
CADR1
IADR1
CADR1
10 bytes
CADR0
IADR0
CADR0
CADR1
IADR1
CADR1
SADRi
14 bytes
14 bytes
IADR0
DADRi
IADR1
i=1 to 7
Max. 32 bytes
(when i=7)
8 bytes
12 bytes
12 bytes
IADR0
IADR1
16 bytes
18 bytes
Transfer mode(MOD)
b15
(b7)
b8
(b0)b7
b0
Bit
symbol
Bit name
Function
(MULT=0)
SIZE
Transfer unit
select bit
0: 8 bits
1: 16 bits
IMM
Transfer data
select bit
0: Immedeate data
1: Memory
UPDS
Transfer source
0: Fixed address
direction select bit 1: Forward address
UPDD
Transfer distination 0: Fixed address
direction select bit 1: Forward address
OPER Alithmatic transfer 0: Not used
/CNT0 function select bit 1: Used
BRST Burst transfer
/CNT1 select bit
0: Single transfer
1: Burst transfer
0: Interrupt not used
INTE End of transfer
/CNT2 interrupt select bit 1: Interrupt used
CHAIN
Chained transfer
select bit
Function
(MULT=1)
Must set to "1"
b6 b5 b4
0 0 0: Do not
set this
0 0 1: Once
0 1 0: Twice
:
:
1 1 0: 6 times
1 1 1: 7 times
0: Chained transfer not used
Must set to "0"
1: Chained transfer used
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
MULT
Figure 1.12.3. Transfer mode
124
Multiple transfer
select bit
0: Not multiple transfer 1: Multiple transfer
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC II
(3) Interrupt Control Register for Peripheral I/O
For peripheral I/O interrupts used to request a transfer by DMAC II, set the Interrupt Control Register
for each peripheral I/O to select “level 7” for their interrupt priority.
(4) Relocatable Vector Table for Peripheral I/O
In the relocatable vector table for each peripheral I/O that requests a transfer by DMAC II, set the
DMAC II Index start address. (When using chained transfers, the relocatable vector table must be
located in the RAM.)
(5) Interrupt Enable Register’s interrupt request latch bit (bit 0)
When using an intelligent I/O or CAN interrupt to activate DMAC II, set to 0 the Interrupt Enable
Register’s interrupt request latch bit (bit 0) for the intelligent I/O or CAN interrupt that requests a
transfer by DMAC II.
Operation of DMAC II
The DMAC II function is selected by setting the DMAC II select bit (bit 5 at address 009F16) to 1. All
peripheral I/O interrupt requests which have had their interrupt priorities set to “level 7” by the Interrupt
Control Register comprise DMAC II interrupt requests. These interrupt requests (priority level = 7) do not
generate an interrupt, however.
When an interrupt request is generated by any peripheral I/O whose interrupt priority is set to “level 7,”
DMAC II is activated no matter which state the I flag and processor interrupt priority level(IPL) is in. If an
_______
interrupt request with higher priority than that (e.g., NMI or watchdog timer) occurs, this higher priority
interrupt has precedence over and is accepted before DMAC II transfers. The pending DMAC II transfer
is started after the interrupt processing sequence for that interrupt finishes.
Transfer data
DMAC II transfers data in units of 8 or 16 bits as described below.
• Memory-to-memory transfer: Data is transferred from any memory location in the 64-Kbyte space to
any memory location in the same space.
• Immediate data transfer: Data is transferred as immediate data to any memory location in the 64Kbyte space.
• Arithmetic transfer: Two 8 or16 bits of data are added together and the result is transferred to any
memory location in the 64-Kbyte space.
When transfer unit is 16 bits and destination address is 0FFFF16, data is transfered to addresses
0FFFF16 and 1000016. When source address is 0FFFF16, data is transfered as in the previous.
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DMAC II
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
(1) Memory-to-memory transfer
Data can be transferred from any memory location in the 64-Kbyte space to any memory location in
the same space in one of the following four ways:
• Transfer from a fixed address to another fixed address
• Transfer from a fixed address to a variable address
• Transfer from a variable address to a fixed address
• Transfer from a variable address to another variable address
If variable address mode is selected, the transfer address is incremented for the next DMA II transfer
to be performed. When transferred in units of 8 bits, the transfer address is incremented by one; when
transferred in units of 16 bits, the transfer address is incremented by two. If the transfer source or
destination address exceeds 0FFFF16 as a result of address incrementation, the transfer source or
destination address recycles back to 0000016.
(2) Immediate data transfer
Data is transferred as immediate data to any memory location in the 64-Kbyte space. A fixed or
variable address can be selected for the transfer destination address. Store the immediate data in the
DMAC II Index’s transfer source address. When transferring 8-bit immediate data, set the data in the
lower byte position of the transfer source address. (The upper byte is ignored.)
(3) Arithmetic transfer
Data in two memory locations of the 64-Kbyte space or immediate data and data in any memory
location of the 64-Kbyte space are added together and the result is transferred to any memory location
in the 64-Kbyte space. Set the memory location to be operated on or immediate data in the DMAC II
Index’s transfer source address field and the other memory location to be operated on in the DMAC II
Index’s operation address field. When performing this mode of transfer on two memory locations, a
fixed or variable address can be selected for the transfer source and transfer destination addresses. If
the transfer source address is chosen to be variable, the operation address also becomes variable.
When performing this mode of transfer on immediate data and any memory location, a fixed or variable address can be selected for the transfer destination address.
Transfer modes
DMAC II supports single and burst transfers. Use the burst transfer select bit (bit 5) for transfer mode
setup in the DMAC II index to choose single or burst transfer mode. Use the DMAC II index transfer
counter to set the number of times a transfer is performed. Neither single transfer nor burst transfer is
performed if the value “000016” is set in the transfer counter.
(1) Single transfer
For a DMAC II transfer request, 8 or 16 bits of data (one transfer unit) is transferred once. If the
transfer source or transfer destination address is chosen to be variable, the next DMA II transfer is
performed on an incremented memory address.
The transfer counter is decremented by each DMA II transfer performed. When using the end-of-transfer
interrupt facility, an end-of-transfer interrupt is generated at the time the transfer counter reaches zero.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC II
(2) Burst transfer
For a DMAC II transfer request, data transfers are performed in succession a number of times as set
by the DMAC II Index transfer counter. When using the end-of-transfer interrupt facility, an end-oftransfer interrupt is generated at the time a burst transfer finishes (i.e., when the transfer counter
reaches zero after being decremented for each data transfer performed).
(3) Multiple transfers
For multiple transfers, use the multiple transfer select bit (bit 15) for transfer mode setup in the DMAC
II Index. Setting this bit to 1 selects the multiple transfer function. For the multiple transfer function,
memory to memory transfer can be performed.
Multiple transfers are performed for one DMAC II transfer request received. Use DMAC II Index transfer mode bits 4–6 to set the number of transfers to be performed. (Setting these bits to 001 performs
one transfer; setting these bits to 111 performs 7 transfers. Setting these bits to 000 is inhibited.)
The transfer source and transfer destination addresses are alternately incremented beginning with the
DMAC II Index BASE address + 4 (as many times as the number of transfers performed).
When using multiple transfer function, arithmetic transfer, burst transfer, end-of-transfer interrupt and
chained transfer cannot be used.
(4) Chained transfer
For chained transfers, use the chained transfer select bit (bit 7) for transfer mode setup in the DMAC
II Index. Setting this bit to 1 selects the chained transfer function. The following describes how a
chained transfer is performed.
1) When a DMA II transfer request (interrupt request from any peripheral I/O) is received, a DMAC II
Index transfer is performed corresponding to the received request.
2) When the DMAC II Index transfer counter reaches zero, the chained transfer address in the DMAC
II Index (i.e., the start address of the DMAC II Index that contains a description of the next DMAC II
transfer to be performed) is written to the relocatable vector table for the peripheral I/O.
3) From the next DMA II transfer request on, transfers are performed based on the DMAC II Index
indicated by the rewritten relocatable vector table of the peripheral I/O.
Before the chained transfer function can be used, the relocatable vector table must be located in the
RAM area.
(5) End-of-transfer interrupt
For end-of-transfer interrupts, use the end-of-transfer interrupt select bit (bit 6) for transfer mode setup
in the DMAC II Index. Setting this bit to 1 selects the end-of-transfer interrupt function. Set the jump
address for end-of-transfer interrupt processing in the DMAC II Index’s end-of-transfer interrupt address field. An end-of-transfer interrupt is generated when the DMAC II Index transfer counter reaches
zero.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DMAC II
Execution time
The number of DMAC II execution cycles is calculated by the equation below.
For other than multiple transfers, t = 6 + (26 + A + B + C + D) X m + (4 + E) X n (cycles)
For multiple transfers, t = 21 + (11 + B + C) X k (cycles)
where
A: If the source of transfer is immediate data, A = 0; if it is memory, A = –1
B: If the source address of transfer is a variable address, B = 0; if it is a fixed address, B = 1
C: If the destination address of transfer is a variable address, C = 0; if it is a fixed address, C = 1
D: If the arithmetic function is not selected, D = 0; if the arithmetic function is selected and the source of
transfer is immediate data or fixed address memory, D = 7; if the arithmetic function is selected and the
source of transfer is variable address memory, D = 8
E: If the chained transfer function is not selected, E = 0; if the chained transfer function is selected, E = 4
m: For single transfer, m = 1; for burst transfer, m = the value set by the transfer counter
n: If the transfer count is one, n = 0; if the transfer count is two or greater, n = 1
k: Number of transfers set by transfer mode bits 4–7
The above equation applies only when all of the following conditions are met, however.
• No bus wait states are inserted.
• The DMAC II Index is set to an even address.
• During word transfer, the transfer source address, transfer destination address, and operation address
all are set to an even address.
Note that the first instruction in end-of-transfer interrupt processing is executed 7 cycles after DMAC II
transfers are completed.
When using an end-of-transfer interrupt (transfer counter = 2) after performing a memory to memory
single transfer twice from a variable source address to a fixed destination address, with the chained
transfer function unselected
A=0
B=1
C=0
D=0
E=0
First DMAC II transfer
t=6+27X1+4X1=37 cycle
Second DMAC II transfer t=6+27X1+4X0=33 cycle
DMAC II transfer request
Application
program
DMAC II transfer
(First time)
DMAC II transfer request
Application
program
37 cycles
Transfer counter = 2
33 cycles
128
End of transfer interrupt program
8 cycles
Transfer counter = 1
Down count of transfer counter
Transfer counter = 1
Figure 1.12.4. Transfer Time
DMAC II transfer
(Second time)
Down count of transfer counter
Transfer counter = 0
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer
Timer
There are eleven 16-bit timers. These timers can be classified by function into timers A (five) and timers B
(six). All these timers function independently. Figures 1.13.1 and 1.13.2 show the block diagram of timers.
Clock prescaler
f1
XIN
1/8
f8
1/2n
f2n
(n = 0 to 15
however, no division when n=0)
Count source
prescaler register
1/32
XCIN
Clock prescaler reset flag (bit 7
at address 034116) set to “1”
fC32
Reset
f1 f8 f2n fC32
• Timer mode
• One-shot mode
• PWM mode
Timer A0 interrupt
TA0IN
Noise
filter
Timer A0
• Event counter mode
• Timer mode
• One-shot mode
• PWM mode
TA1IN
Noise
filter
Timer A1 interrupt
Timer A1
• Event counter mode
• Timer mode
• One-shot mode
• PWM mode
Timer A2 interrupt
TA2IN
Noise
filter
Timer A2
• Event counter mode
• Timer mode
• One-shot mode
• PWM mode
Timer A3 interrupt
TA3IN
Noise
filter
Timer A3
• Event counter mode
• Timer mode
• One-shot mode
• PWM mode
Timer A4 interrupt
TA4IN
Noise
filter
Timer A4
• Event counter mode
Timer B2 overflow
Figure 1.13.1. Timer A block diagram
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer
Clock prescaler
f1
XIN
1/8
f8
1/2n
f2n
Count source
prescaler register
1/32
XCIN
Clock prescaler reset flag (bit 7
at address 034116) set to “1”
fC32
Reset
(n = 0 to 15
however, no division when n=0)
f1 f8 f2n fC32
Timer B2 overflow (to timer A count source)
• Timer mode
• Pulse width measuring mode
TB0IN
Timer B0 interrupt
Noise
filter
Timer B0
• Event counter mode
• Timer mode
• Pulse width measuring mode
TB1IN
Noise
filter
Timer B1 interrupt
Timer B1
• Event counter mode
• Timer mode
• Pulse width measuring mode
TB2IN
Noise
filter
Timer B2 interrupt
Timer B2
• Event counter mode
• Timer mode
• Pulse width measuring mode
TB3IN
Timer B3 interrupt
Noise
filter
Timer B3
• Event counter mode
• Timer mode
• Pulse width measuring mode
TB4IN
Noise
filter
Timer B4 interrupt
Timer B4
• Event counter mode
• Timer mode
• Pulse width measuring mode
TB5IN
Noise
filter
Timer B5
• Event counter mode
Figure 1.13.2. Timer B block diagram
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Timer B5 interrupt
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Timer A
Figure 1.14.1 shows the block diagram of timer A. Figures 1.14.2 to 1.14.6 show the timer A-related registers.
Except in event counter mode, timers A0 through A4 all have the same function. Use the timer Ai mode
register (i = 0 to 4) bits 0 and 1 to choose the desired mode.
Timer A has the four operation modes listed as follows:
• Timer mode: The timer counts an internal count source.
• Event counter mode: The timer counts pulses from an external source or a timer over flow.
• One-shot timer mode: The timer outputs one effective pulse until the count reaches “000016”.
• Pulse width modulation (PWM) mode: The timer outputs pulses of a given width.
Data bus high-order bits
Clock source
selection
f1
f8
f32
Low-order
8 bits
• Timer
(gate function)
fC32
AAAA
A
AAAA
A
A
Data bus low-order bits
• Timer
• One shot
• PWM
High-order
8 bits
Reload register (16)
• Event counter
Counter (16)
Polarity
selection
Up count/down count
Clock selection
TAiIN
(i = 0 to 4)
Count start flag
Always down count except
in event counter mode
(Address 034016)
Down count
TB2 overflow
External
trigger
TAj overflow
(j = i – 1. Note, however, that j = 4 when i = 0)
Up/down flag
(Address 034416)
TAi
Timer A0
Timer A1
Timer A2
Timer A3
Timer A4
Addresses
034716 034616
034916 034816
034B16 034A16
034D16 034C16
034F16 034E16
TAj
Timer A4
Timer A0
Timer A1
Timer A2
Timer A3
TAk
Timer A1
Timer A2
Timer A3
Timer A4
Timer A0
TAk overflow
(k = i + 1. Note, however, that k = 0 when i = 4)
TAiOUT
Pulse output
(i = 0 to 4)
Toggle flip-flop
Figure 1.14.1. Block diagram of timer A
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Timer Ai register (i = 0 to 4) (Note 1)
(b15)
b7
(b8)
b0 b7
b0
Symbol
Address
TAi (i = 0 to 2) 034716,034616, 034916,034816, 034B16,034A16
TAi (i = 3, 4)
034D16,034C16, 034F16,034E16
Function
Timer mode
Event counter
mode
Values that can be set
R W
000016 to FFFF16
16-bit counter (set to dividing ratio)
16-bit counter (set to dividing ratio)
When reset
Indeterminate
Indeterminate
(Note 2)
One-shot timer
mode
16-bit counter (set to one shot width)
Pulse width
modulation mode
(16-bit PWM)
16-bit pulse width modulator
(set to PWM pulse “H” width)
Pulse width
modulation mode
(8-bit PWM)
Low-order 8 bits : 8-bit prescaler
(Note 5, 7)
(set to PWM period)
High-order 8 bits : 8-bit pulse width modulator
(set to PWM pulse “H” width)
(Note 6)
000016 to FFFF16
000016 to FFFF16
(Note 3)
000016 to FFFE16
(Note 4, 7)
(Note 3)
0016 to FE16
(High-order address)
0016 to FF16
(Low-order address)
(Note 3)
Note 1: Read and write data in 16-bit units.
Note 2: Counts pulses from an external source or timer overflow.
Note 3: Use MOV instruction to write to this register.
Note 4: When setting value is n, PWM period and “H” width of PWM pulse are as follows:
PWM period : (216 - 1) / fi
PWM pulse “H” width : n / fi
Note 5: When setting value of high-order address is n and setting value of low-order address is m, PWM period and
“H” width of PWM pulse are as follows:
PWM period : (2 8 - 1) X (m + 1) / fi
PWM pulse “H” width : (m + 1)n / fi
Note 6: When the timer Ai register is set to "000016", the counter does not operate and the timer Ai interrupt request
is not generated. When the pulse is set to output, the pulse does not output from the TAiOUT pin.
Note 7: When the timer Ai register is set to "000016", the pulse width modulator does not operate and the output
level of the TAiOUT pin remains "L" level, therefore the timer Ai interrupt request is not generated. This also
occurs in the 8-bit pulse width modulator mode when the significant 8 high-order bits in the timer Ai register
are set to "0016".
Figure 1.14.2. Timer A-related registers (1)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Timer Ai mode register (i = 0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TAiMR(i=0 to 4)
Bit symbol
TMOD0
Address
035616, 035716, 035816, 035916, 035A16
Bit name
Operation mode
select bit
TMOD1
MR0
When reset
00000X002
Function
R W
b1 b0
0 0 : Timer mode
0 1 : Event counter mode
1 0 : One-shot timer mode
1 1 : Pulse width modulation
(PWM) mode
This bit is invalid in M32C/80 series.
Port output control is set by the function select
registers A, B and C.
MR1
Function varies with each
operation mode
MR2
MR3
TCK0
TCK1
Count source
select bit
Function varies with each
operation mode
Count start flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TABSR
Address
034016
Bit symbol
Bit name
When reset
0016
Function
TA0S
Timer A0 count
start flag
0 : Stops counting
1 : Starts counting
TA1S
Timer A1 count
start flag
0 : Stops counting
1 : Starts counting
TA2S
Timer A2 count
start flag
0 : Stops counting
1 : Starts counting
TA3S
Timer A3 count
start flag
0 : Stops counting
1 : Starts counting
TA4S
Timer A4 count
start flag
0 : Stops counting
1 : Starts counting
TB0S
Timer B0 count
start flag
0 : Stops counting
1 : Starts counting
TB1S
Timer B1 count
start flag
0 : Stops counting
1 : Starts counting
TB2S
Timer B2 count
start flag
0 : Stops counting
1 : Starts counting
R W
Figure 1.14.3. Timer A-related registers (2)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Up/down flag (Note 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
UDF
Address
034416
Bit symbol
Bit name
TA0UD
Timer A0 up/down flag
TA1UD
Timer A1 up/down flag
TA2UD
Timer A2 up/down flag
TA3UD
TA4UD
TA2P
When reset
0016
Function
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
A
A
R W
0 : Down count
1 : Up count
(Note 2)
0 : Down count
1 : Up count
(Note 2)
0 : Down count
1 : Up count
(Note 2)
Timer A3 up/down flag
0 : Down count
1 : Up count
(Note 2)
Timer A4 up/down flag
0 : Down count
1 : Up count
(Note 2)
0 : two-phase pulse signal
processing disabled
1 : two-phase pulse signal
processing enabled
(Note 3)
Timer A2 two-phase pulse
signal processing select bit
TA3P
Timer A3 two-phase pulse
signal processing select bit
0 : two-phase pulse signal
processing disabled
1 : two-phase pulse signal
processing enabled
(Note 3)
TA4P
Timer A4 two-phase pulse
signal processing select bit
0 : two-phase pulse signal
processing disabled
1 : two-phase pulse signal
processing enabled
(Note 3)
Note 1: Use MOV instruction to write to this register.
Note 2: This specification becomes valid when the up/down flag content is selected for up/down switching cause.
Note 3: When not using the two-phase pulse signal processing function, set the select bit to “0”.
One-shot start flag
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
ONSF
Address
034216
Bit symbol
When reset
0016
Bit name
Function
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
RW
TA0OS
Timer A0 one-shot start flag
0 : Invalid
1 : Timer start
TA1OS
Timer A1 one-shot start flag
0 : Invalid
1 : Timer start
(Note 1)
TA2OS
Timer A2 one-shot start flag
0 : Invalid
1 : Timer start
(Note 1)
TA3OS
Timer A3 one-shot start flag
0 : Invalid
1 : Timer start
(Note 1)
TA4OS
Timer A4 one-shot start flag
0 : Invalid
1 : Timer start
(Note 1)
TAZIE
TA0TGL
Z phase input enable bit
Timer A0 event/trigger
select bit
TA0TGH
0 : Invalid
1 : Valid
b7 b6
(Note 1)
0 0 : Input on TA0IN is selected (Note 2)
0 1 : TB2 overflow is selected
1 0 : TA4 overflow is selected
1 1 : TA1 overflow is selected
Note 1: When read, the value is “0”.
Note 2: Set the corresponding pin output function select register to I/O port, and port direction register to “0”.
Figure 1.14.4. Timer A-related registers (3)
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Trigger select register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TRGSR
Address
034316
Bit symbol
TA1TGL
Bit name
Timer A1 event/trigger
select bit
TA1TGH
TA2TGL
Timer A2 event/trigger
select bit
TA2TGH
TA3TGL
Timer A3 event/trigger
select bit
TA3TGH
TA4TGL
When reset
0016
Timer A4 event/trigger
select bit
TA4TGH
Function
b1 b0
0 0 : Input on TA1IN is selected (Note)
0 1 : TB2 overflow is selected
1 0 : TA0 overflow is selected
1 1 : TA2 overflow is selected
b3 b2
0 0 : Input on TA2IN is selected (Note)
0 1 : TB2 overflow is selected
1 0 : TA1 overflow is selected
1 1 : TA3 overflow is selected
b5 b4
0 0 : Input on TA3IN is selected (Note)
0 1 : TB2 overflow is selected
1 0 : TA2 overflow is selected
1 1 : TA4 overflow is selected
b7 b6
0 0 : Input on TA4IN is selected (Note)
0 1 : TB2 overflow is selected
1 0 : TA3 overflow is selected
1 1 : TA0 overflow is selected
Note: Set the corresponding port function select register A to I/O port, and port direction register to “0”.
R W
A
A
A
A
A
A
A
A
A
Clock prescaler reset flag
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
CPSRF
Address
034116
Bit symbol
Bit name
When reset
0XXXXXXX2
Function
RW
Nothing is assigned.
When write, set “0”. When read, their contents are
indeterminate.
CPSR
Clock prescaler reset flag
0 : Ignored
1 : Prescaler is reset
(When read, the value is “0”)
A
A
Figure 1.14.5. Timer A-related registers (4)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Count source prescaler register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TCSPR
Address
035F16
Bit symbol
CNT0
When reset
0XXXXXXX2
Bit name
Count value set bits
CNT1
Function
0 0 0 0 : No division
0 0 0 1 : Division by 2
0 0 1 0 : Division by 4
0 0 1 1 : Division by 6
(Note 1)
CNT2
1 1 0 1 : Division by 26
1 1 1 0 : Division by 28
1 1 1 1 : Division by 30
CNT3
Nothing is assigned.
When write, set “0”. When read, their contents are
indeterminate.
CST
Count start bit
Note 1: Set count start bit to “0” before writing to count value set bits.
Note 2: When this bit is set to “0”, divider circuit is inactive.
Figure 1.14.6. Timer A-related registers (5)
136
0 : Stops counting
1 : Starts counting
A
AA
A
RW
b3 b2 b1 b0
(Note 2)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
(1) Timer mode
In this mode, the timer counts an internally generated count source. (See Table 1.14.1.) Figure 1.14.7
shows the timer Ai mode register in timer mode.
Table 1.14.1. Specifications of timer mode
Item
Specification
Count source
f1, f8, f2n, fC32
Count operation
• Down count
• When the timer underflows, it reloads the reload register contents before continuing
counting
Divide ratio
1/(m+1) m : Set value
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing When the timer underflows
TAiIN pin function
Programmable I/O port or gate input
TAiOUT pin function
Programmable I/O port or pulse output (Setting by corresponding function select
registers A, B and C)
Read from timer
Write to timer
Count value can be read out by reading timer Ai register
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
• Gate function
Counting can be started and stopped by the TAiIN pin’s input signal
• Pulse output function
Select function
Each time the timer underflows, the TAiOUT pin’s polarity is reversed
Timer Ai mode register (i = 0 to 4) (Timer mode)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TAiMR(i=0 to 4)
Bit symbol
TMOD0
TMOD1
Address
035616, 035716, 035816, 035916, 035A16
Bit name
Operation mode
select bit
When reset
00000X002
Function
R W
b1 b0
0 0 : Timer mode
MR0
This bit is invalid in M32C/80 series.
Port output control is set by the function select
registers A, B and C.
MR1
Gate function
select bit
b4 b3
0 X : Gate function not available
(Note 1)
(TAiIN pin is a normal port pin)
1 0 : Timer counts only when TAiIN (Note 2)
pin is held “L”
1 1 : Timer counts only when TAiIN (Note 2)
pin is held “H”
MR2
MR3
0 (Set to “0” in timer mode)
TCK0
Count source
select bit
TCK1
b7 b6
0 0 : f1
0 1 : f8
1 0 : f2n
1 1 : fC32
(Note 3)
Note 1: X value can be “0” or “1”.
Note 2: Set the corresponding function select register A to I/O port, and port direction register to “0”.
Note 3: n = 0 to 15. n is set by the count source prescaler register (address 035F16).
Figure 1.14.7. Timer Ai mode register in timer mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
(2) Event counter mode
In this mode, the timer counts an external signal or an internal timer’s overflow. Timers A0 and A1 can
count a single-phase external signal. Timers A2, A3, and A4 can count a single-phase and a two-phase
external signal. Table 1.14.2 lists timer specifications when counting a single-phase external signal.
Table 1.14.3 lists timer specifications when counting a two-phase external signal. Figure 1.14.8 shows
the timer Ai mode register in event counter mode.
Table 1.14.2. Timer specifications in event counter mode (when not processing two-phase pulse signal)
Item
Count source
Specification
• External signals input to TAiIN pin (effective edge can be selected by software)
• TB2 overflows or underflows, TAj overflows or underflows
Count operation
• Up count or down count can be selected by external signal or software
• When the timer overflows or underflows, it reloads the reload register contents
before continuing counting (Note)
Divide ratio
• 1/ (FFFF16 - n + 1) for up count
• 1/ (n + 1) for down count
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
n : Set value
Interrupt request generation timing The timer overflows or underflows
TAiIN pin function
Programmable I/O port or count source input
TAiOUT pin function
Programmable I/O port, pulse output, or up/down count select input (Setting by corresponding function select registers A, B and C)
Read from timer
Count value can be read out by reading timer Ai register
Write to timer
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
Select function
• Free-run count function
Even when the timer overflows or underflows, the reload register content is not
reloaded to it
• Pulse output function
Each time the timer overflows or underflows, the TAiOUT pin’s polarity is reversed
Note: This does not apply when the free-run function is selected.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Timer Ai mode register (i = 0 to 4) (Event counter mode)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TAiMR(i=0 to 4)
Bit
symbol
Address
035616, 035716, 035816, 035916, 035A16
Function
Bit name
TMOD0 Operation mode
select bit
TMOD1
(When not using two-phase
pulse signal processing)
When reset
00000X002
Function
(When using two-phase
pulse signal processing)
R W
b1 b0
0 1 : Event counter mode
(Note 1)
MR0
This bit is invalid in M32C/80 series.
Port output control is set by the function select registers A, B and C.
MR1
Count polarity
select bit
(Note 2)
MR2
Up/down
1 (Set to “1” when using
0 : Up/down flag's content
switching cause 1 : TAiOUT pin's input signal two-phase pulse signal
select bit
(Note 3) processing)
MR3
0 (Set to “0” in Event counter mode)
TCK0
Count operation 0 : Reload type
1 : Free-run type
type select bit
TCK1
Two-phase pulse
0 (Set to “0” when not
signal processing
using two-phase pulse
operation select
bit (Note 4,Note 5) signal processing)
0 : Counts external
0 (Set to “0” when using
signal's falling edges two-phase pulse signal
1 : Counts external
processing)
signal's rising edges
0 : Normal processing
operation
1 : Multiply-by-4
processing operation
Note 1: Count source is select by the event/trigger select bit (addresses 034216, 034316) in event counter mode.
Note 2: This bit is valid when only counting an external signal.
Note 3: Set the corresponding function select register A to I/O port, and port direction register to “0”.
Signal of TAiOUT pin counts down at the time of “L” and counts up at the time of “H”.
Note 4: This bit is valid for timer A3 mode register.
Timer A0 and A1 can be “0” or “1”.
Timer A2 is fixed to normal processing operation and timer A4 is fixed to multiply-by-4
processing operation.
Note 5: When performing two-phase pulse signal processing, make sure the two-phase pulse
signal processing operation select bit (address 034416) is set to “1”. Also, always be
sure to set the event/trigger select bit (address 034316) to “00”.
Figure 1.14.8. Timer Ai mode register in event counter mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Table 1.14.3. Timer specifications in event counter mode
Item
Specification
Count source
Two-phase pulse signals input to TAiIN or TAiOUT pin
Count operation
• Up count or down count can be selected by two-phase pulse signal
• When the timer overflows or underflows, the reload register content is
reloaded and the timer starts over again (Note 1)
Divide ratio
• 1/ (FFFF16 - n + 1) for up count
• 1/ (n + 1) for down count
Count start condition
n : Set value
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing
Timer overflows or underflows
TAiIN pin function
Two-phase pulse input
TAiOUT pin function
Two-phase pulse input (Set corresponding function select register A for I/O port)
Read from timer
Count value can be read out by reading timer A2, A3, or A4 register
Write to timer
• When counting stopped
When a value is written to timer A2, A3, or A4 register, it is written to both reload
register and counter
• When counting in progress
When a value is written to timer A2, A3, or A4 register, it is written to only reload
register. (Transferred to counter at next reload time.)
Select function
(Note 2)
• Normal processing operation (TimerA2 and timer A3)
The timer counts up rising edges or counts down falling edges on the TAiIN pin when
input signal on the TAiOUT pin is “H”
TAiOUT
TAiIN
(i=2,3)
Up
count
Up
count
Up
count
Down
count
Down
count
Down
count
• Multiply-by-4 processing operation (TimerA3 and timer A4)
If the phase relationship is such that the TAiIN pin goes “H” when the input signal on
the TAiOUT pin is “H”, the timer counts up rising and falling edges on the TAiOUT and
TAiIN pins. If the phase relationship is such that the TAiIN pin goes “L” when the input
signal on the TAiOUT pin is “H”, the timer counts down rising and falling edges on the
TAiOUT and TAiIN pins.
TAiOUT
Count up all edges
Count down all edges
TAiIN
(i=3,4)
Count up all edges
Count down all edges
(when processing two-phase pulse signal with timers A2, A3, and A4)
Note 1: This does not apply when the free-run function is selected.
Note 2: Timer A3 is selectable. Timer A2 is fixed to normal processing operation and timer A4 is fixed to
multiply-by-4 operation.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
• Counter Resetting by Two-Phase Pulse Signal Processing
This function resets the timer counter to “0” when the Z-phase (counter reset) is input during twophase pulse signal processing.
This function can only be used in timer A3 event counter mode, two-phase pulse signal processing,
free-run type, and multiply-by-4 processing. The Z phase is input to the INT2 pin.
When the Z-phase input enable bit (bit 5 at address 034216) is set to “1”, the counter can be reset by
Z-phase input. For the counter to be reset to “0” by Z-phase input, you must first write “000016” to the
timer A3 register (addresses 034D16 and 034C16).
The Z-phase is input when the INT2 input edge is detected. The edge polarity is selected by the INT2
polarity switch bit (bit 4 at address 009C16). The Z-phase must have a pulse width greater than 1 cycle
of the timer A3 count source. Figure 1.14.9 shows the relationship between the two-phase pulse (A
phase and B phase) and the Z phase.
The counter is reset at the count source following Z-phase input. Figure 1.14.10 shows the timing at
which the counter is reset to “0”.
Note that timer A3 interrupt requests occur successively two times when timer A3 underflow and INT2
input reload occures at the same time.
Do not use timer A3 interrupt request when this function is used.
TA3OUT
(A phase)
TA3IN
(B phase)
Count source
INT2 (Note)
(Z phase)
The pulse must be wider than this width.
Note: When the rising edge of INT2 is selected.
Figure 1.14.9. The relationship between the two-phase pulse (A phase and B phase) and the Z phase
TA3OUT
(A phase)
TA3IN
(B phase)
Count source
INT2 (Note)
(Z phase)
Count value
m
m+1
1
Becoming “0” at this timing.
2
3
4
5
Note: When the rising edge of INT2 is selected.
Figure 1.14.10. The counter reset timing
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
(3) One-shot timer mode
In this mode, the timer operates only once. (See Table 1.14.4.) When a trigger occurs, the timer starts
up and continues operating for a given period. Figure 1.14.11 shows the timer Ai mode register in oneshot timer mode.
Table 1.14.4. Timer specifications in one-shot timer mode
Item
Specification
Count source
f1, f8, f2n, fC32
Count operation
• The timer counts down
• When the count reaches 000016, the timer stops counting after reloading a new
count
• If a trigger occurs when counting, the timer reloads a new count and restarts counting
Divide ratio
1/n
n : Set value
Count start condition
• An external trigger is input
• The timer overflows
• The one-shot start flag is set (= 1)
Count stop condition
• A new count is reloaded after the count has reached 000016
• The count start flag is reset (= 0)
Interrupt request generation timing The count reaches 000016
TAiIN pin function
Programmable I/O port or trigger input
TAiOUT pin function
Programmable I/O port or pulse output (Setting by corresponding function select registers A, B and C)
Read from timer
When timer Ai register is read, it indicates an indeterminate value
Write to timer
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Timer Ai mode register (i = 0 to 4) (One-shot timer mode)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TAiMR(i=0 to 4)
Address
035616, 035716, 035816, 035916, 035A16
Bit symbol
Bit name
TMOD0
Operation mode select bit
TMOD1
When reset
00000X002
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
RW
Function
b1 b0
1 0 : One-shot timer mode
MR0
This bit is invalid in M32C/80 series.
Port output control is set by the function select registers A, B and C.
MR1
External trigger select bit 0 : Falling edge of TAiIN pin's input signal (Note 2)
(Note 1) 1 : Rising edge of TAiIN pin's input signal (Note 2)
MR2
Trigger select bit
MR3
0 (Set to “0” in one-shot timer mode)
TCK0
Count source select bit
TCK1
– –
0 : One-shot start flag is valid
1 : Selected by event/trigger select register
b7 b6
0 0 : f1
0 1 : f8
1 0 : f2n
1 1 : fC32
Note 1: Valid only when the TAiIN pin is selected by the event/trigger select bit
(addresses 034216 and 034316). If timer overflow is selected, this bit can be “1” or “0”.
Note 2: Set the corresponding function select register A to I/O port, and port direction register to “0”.
Note 3: n = 0 to 15. n is set by the count source prescaler register (address 035F16).
(Note 3)
Figure 1.14.11. Timer Ai mode register in one-shot timer mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
(4) Pulse width modulation (PWM) mode
In this mode, the timer outputs pulses of a given width in succession. (See Table 1.14.5.) In this mode, the
counter functions as either a 16-bit pulse width modulator or an 8-bit pulse width modulator. Figure
1.14.12 shows the timer Ai mode register in pulse width modulation mode. Figure 1.14.13 shows the
example of how a 16-bit pulse width modulator operates. Figure 1.14.14 shows the example of how an 8bit pulse width modulator operates.
Table 1.14.5. Timer specifications in pulse width modulation mode
Item
Specification
Count source
f1, f8, f2n, fC32
Count operation
• The timer counts down (operating as an 8-bit or a 16-bit pulse width modulator)
• The timer reloads a new count at a rising edge of PWM pulse and continues counting
• The timer is not affected by a trigger that occurs when counting
16-bit PWM
• High level width
• Cycle time
8-bit PWM
Count start condition
(216-1)
n / fi
n : Set value
/ fi fixed
• High level width n
(m+1) / fi n : values set to timer Ai register’s high-order address
• Cycle time (28-1)
(m+1) / fi m:values set to timer Ai register’s low-order address
• External trigger is input
• The timer overflows
• The count start flag is set (= 1)
Count stop condition
• The count start flag is reset (= 0)
Interrupt request generation timing
PWM pulse goes “L”
TAiIN pin function
Programmable I/O port or trigger input
TAiOUT pin function
Pulse output (TAiOUT is selected by corresponding function select registers A, B and C)
Read from timer
When timer Ai register is read, it indicates an indeterminate value
Write to timer
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Timer Ai mode register (i = 0 to 4) (Pulse width modulator mode)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TAiMR(i=0 to 4)
Bit symbol
TMOD0
TMOD1
Address
035616, 035716, 035816, 035916, 035A16
Bit name
Operation mode
select bit
When reset
00000X002
Function
b1 b0
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
R W
1 1 : Pulse width modulator (PWM) mode
MR0
This bit is invalid in M32C/80 series.
Port output control is set by the function select registers A, B and C.
MR1
External trigger select bit 0: Falling edge of TAiIN pin's input signal (Note 2)
(Note 1)
MR2
Trigger select bit
MR3
16/8-bit PWM mode
select bit
TCK0
Count source select bit
TCK1
– –
1: Rising edge of TAiIN pin's input signal (Note 2)
0: Count start flag is valid
1: Selected by event/trigger select register
0: Functions as a 16-bit pulse width modulator
1: Functions as an 8-bit pulse width modulator
b7 b6
0 0 : f1
0 1 : f8
1 0 : f2n
1 1 : fC32
Note 1: Valid only when the TAiIN pin is selected by the event/trigger select bit
(addresses 034216 and 034316). If timer overflow is selected, this bit can be “1” or “0”.
Note 2: Set the corresponding function select register A to I/O port, and port direction register to “0”.
Note 3: n = 0 to 15. n is set by the count source prescaler register (address 035F16).
(Note 3)
Figure 1.14.12. Timer Ai mode register in pulse width modulation mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer A
Condition : Reload register = 000316, when external trigger
(rising edge of TAiIN pin input signal) is selected
1 / fi X (2 16 – 1)
Count source
“H”
TAiIN pin
input signal
“L”
Trigger is not generated by this signal
1 / fi X n
PWM pulse output
from TAiOUT pin
“H”
Timer Ai interrupt
request bit
“1”
“L”
“0”
fi : Frequency of count source
(f1, f8, f2n, fC32)
Cleared to “0” when interrupt request is accepted, or cleared by software
Note: n = 000016 to FFFE16.
Figure 1.14.13. Example of how a 16-bit pulse width modulator operates
Condition : Reload register high-order 8 bits = 0216
Reload register low-order 8 bits = 0216
External trigger (falling edge of TAiIN pin input signal) is selected
1 / fi X (m + 1) X (2 8 – 1)
Count source (Note1)
TAiIN pin input signal
“H”
AAAAAAAAAAAAAAA
AAAAAAAAAAAAAAA
“L”
1 / fi X (m + 1)
“H”
Underflow signal of
8-bit prescaler (Note2) “L”
1 / fi X (m + 1) X n
PWM pulse output
from TAiOUT pin
“H”
Timer Ai interrupt
request bit
“1”
“L”
“0”
fi : Frequency of count source
(f1, f8, f2n, fC32)
Cleared to “0” when interrupt request is accepted, or cleaerd by software
Note 1: The 8-bit prescaler counts the count source.
Note 2: The 8-bit pulse width modulator counts the 8-bit prescaler's underflow signal.
Note 3: m = 0016 to FF16; n = 0016 to FE16.
Figure 1.14.14. Example of how an 8-bit pulse width modulator operates
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
Timer B
Figure 1.15.1 shows the block diagram of timer B. Figures 1.15.2 and 1.15.4 show the timer B-related
registers. Use the timer Bi mode register (i = 0 to 5) bits 0 and 1 to choose the desired mode.
Timer B has three operation modes listed as follows:
• Timer mode: The timer counts an internal count source.
• Event counter mode: The timer counts pulses from an external source or a timer overflow.
• Pulse period/pulse width measuring mode: The timer measures an external signal's pulse period or
pulse width.
Data bus high-order bits
Data bus low-order bits
Clock source selection
High-order 8 bits
Low-order 8 bits
f1
• Timer
• Pulse period/pulse width measurement
f8
f32
fC32
Reload register (16)
Counter (16)
• Event counter
Count start flag
Polarity switching
and edge pulse
TBiIN
(i = 0 to 5)
(address 034016)
Counter reset circuit
Can be selected in only
event counter mode
TBi
Timer B0
Timer B1
Timer B2
Timer B3
Timer B4
Timer B5
TBj overflow
(j = i – 1. Note, however,
j = 2 when i = 0,
j = 5 when i = 3)
Address
035116 035016
035316 035216
035516 035416
031116 031016
031316 031216
031516 031416
TBj
Timer B2
Timer B0
Timer B1
Timer B5
Timer B3
Timer B4
Figure 1.15.1. Block diagram of timer B
Timer Bi register (i = 0 to 6) (Note 1)
(b15)
b7
(b8)
b0 b7
b0
Symbol
Address
TBi (i = 0 to 2) 035116,035016, 035316,035216, 035516,035416
TBi (i = 3 to 5) 031116,031016, 031316,031216, 031516,031416
Function
Timer mode
16-bit counter (set to dividing ratio)
Event counter mode
16-bit counter (set to dividing ratio)
When reset
Indeterminate
Indeterminate
Values that can be set
RW
000016 to FFFF16
(Note 2)
000016 to FFFF16
Pulse period / pulse width Measures a pulse period or width
measurement mode
Note 1: Read and write data in 16-bit units.
Note 2: Counts external pulses input or a timer overflow.
Figure 1.15.2. Timer B-related registers (1)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
Timer Bi mode register (i = 0 to 5)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
When reset
TBiMR(i=0 to 5) 035B16, 035C16, 035D16, 031B16, 031C16, 031DB16 00XX00002
Bit symbol
TMOD0
Bit name
Operation mode
select bit
TMOD1
R W
Function
b1 b0
0 0 : Timer mode
0 1 : Event counter mode
1 0 : Pulse period/pulse width
measurement mode
1 1 : Don't set it up
MR0
MR1
Function varies with each
operation mode
MR2
(Note 1)
(Note 2)
MR3
TCK0
TCK1
Count source
select bit
Function varies with each
operation mode
Note 1: Bit 4 is valid only by timer B0 and timer B3.
Note 2: In timer B1, timer B2, timer B4 and timer B5, nothing is assigned by bit 4(There is not R/W).
When write, set “0”. When read, its content is indeterminate.
Count start flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TABSR
Address
034016
Bit symbol
Bit name
Function
TA0S
Timer A0 count
start flag
0 : Stops counting
1 : Starts counting
TA1S
Timer A1 count
start flag
0 : Stops counting
1 : Starts counting
TA2S
Timer A2 count
start flag
0 : Stops counting
1 : Starts counting
TA3S
Timer A3 count
start flag
0 : Stops counting
1 : Starts counting
TA4S
Timer A4 count
start flag
0 : Stops counting
1 : Starts counting
TB0S
Timer B0 count
start flag
0 : Stops counting
1 : Starts counting
TB1S
Timer B1 count
start flag
0 : Stops counting
1 : Starts counting
TB2S
Timer B2 count
start flag
0 : Stops counting
1 : Starts counting
Figure 1.15.3. Timer B-related registers (2)
148
When reset
0016
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
Timer B3, B4,B5 count start flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TBSR
Bit symbol
Address
030016
When reset
000XXXXX2
Bit name
Function
R W
Nothing is assigned.
When write, set "0". When read, its content is indeterminate.
TB3S
Timer B3 count
start flag
0 : Stops counting
1 : Starts counting
TB4S
Timer B4 count
start flag
0 : Stops counting
1 : Starts counting
TB5S
Timer B5 count
start flag
0 : Stops counting
1 : Starts counting
Clock prescaler reset flag
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
CPSRF
Bit symbol
Address
034116
Bit name
When reset
0XXXXXXX2
Function
RW
Nothing is assigned.
When write, set “0”. When read, their contents are
indeterminate.
CPSR
Clock prescaler reset flag
0 : Ignored
1 : Prescaler is reset
(When read, the value is “0”)
A
A
Figure 1.15.4. Timer B-related registers (3)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
(1) Timer mode
In this mode, the timer counts an internally generated count source. (See Table 1.15.1.) Figure 1.15.5
shows the timer Bi mode register in timer mode.
Table 1.15.1. Timer specifications in timer mode
Item
Specification
Count source
f1, f8, f2n, fC32
Count operation
• Counts down
• When the timer underflows, it reloads the reload register contents before continuing
counting
Divide ratio
1/(m+1)m : Set value
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing The timer underflows
TBiIN pin function
Programmable I/O port
Read from timer
Count value is read out by reading timer Bi register
Write to timer
• When counting stopped
When a value is written to timer Bi register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Bi register, it is written to only reload register
(Transferred to counter at next reload time)
AA
A
AA
A
Timer Bi mode register (i = 0 to 5) (Timer mode)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TBiMR(i=0 to 5)
Bit symbol
TMOD0
TMOD1
MR0
MR1
Address
035B16, 035C16, 035D16, 031B16, 031C16, 031D16
Bit name
Operation mode select bit
Function
MR3
TCK0
R
b1 b0
0 0 : Timer mode
Invalid in timer mode.
Can be “0” or “1”.
0 (Set to “0” in timer mode)
MR2
(Note 1)
(Note 2)
Nothing is assigned. (i = 1, 2, 4, 5)
When write, set "0". When read, its content is indeterminate.
Invalid in timer mode. When write, set "0". When read in timer
mode, its content is indeterminate.
Count source select bit
TCK1
b7 b6
0 0 : f1
0 1 : f8
1 0 : f2n
1 1 : fC32
(Note 3)
Note 1: R/W is valid only in timer B0 and timer B3.
Note 2: In timer B1, timer B2, timer B4 and timer B5, nothing is assigned by bit 4(There is not R/W).
When write, set “0”. When read, its content is indeterminate.
Note 3: n = 0 to 15. n is set by the count source prescaler register (address 035F16).
Figure 1.15.5. Timer Bi mode register in timer mode
150
A
A
A
A
AA
AA
AA
AA
AA
AA
When reset
00XX00002
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
(2) Event counter mode
In this mode, the timer counts an external signal or an internal timer's overflow. (See Table 1.15.2.)
Figure 1.15.6 shows the timer Bi mode register in event counter mode.
Table 1.15.2. Timer specifications in event counter mode
Item
Specification
• External signals input to TBiIN pin
Effective edge of count source can be a rising edge, a falling edge, or falling and
rising edges as selected by software
• TBj overflows or underflows
Count operation
• Counts down
• When the timer underflows, it reloads the reload register contents before continuing
counting
Divide ratio
1/(n+1)
n : Set value
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing The timer underflows
TBiIN pin function
Count source input (Set the corresponding function select register A to I/O port.)
Read from timer
Count value can be read out by reading timer Bi register
Write to timer
• When counting stopped
When a value is written to timer Bi register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Bi register, it is written to only reload register
(Transferred to counter at next reload time)
Count source
AA
AA
Timer Bi mode register (i = 0 to 5) (Event counter mode)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TBiMR(i=0 to 5)
Bit symbol
TMOD0
TMOD1
MR0
MR1
MR2
Address
035B16, 035C16, 035D16, 031B16, 031C16, 031D16
Bit name
Function
Operation mode
select bit
b1 b0
Count polarity select
bit
b3 b2
0 1 : Event counter mode
When reset
00XX00002
A
A
A
AA
A
AA
AA
AA
R
W
0 0 : Counts external signal's falling edges
0 1 : Counts external signal's rising edges
1 0 : Counts external signal's falling and
rising edges
(Note 1) 1 1 : Inhibited
0 (Set to “0” in event counter mode)
(Note 2)
Nothing is assigned. (i = 1, 2, 4, 5)
(Note 3)
When write, set “0”. When read, its content is indeterminate.
MR3
TCK0
TCK1
Invalid in event counter mode. When write, set "0". When
read in event counter mode, its content is indeterminate.
Invalid in event counter mode.
Can be “0” or “1”.
Event clock select bit 0 : Input from TBiIN pin
1 : TBj overflow
Note 1: Valid only when input from the TBiIN pin is selected as the event clock.
If timer's overflow is selected, this bit can be “0” or “1”.
Note 2: R/W is valid only in timer B0 and timer B3.
Note 3: In timer B1, timer B2, timer B4 and timer B5, nothing is assigned by bit 4(There is not R/W).
When write, set “0”. When read, its content is indeterminate.
Note 4: Set the corresponding function select register A to I/O port, and port direction register to “0”.
Note 5: j = i – 1; however, j = 2 when i = 0, j = 5 when i = 3.
AA
AA
(Note 4)
(Note 5)
Figure 1.15.6. Timer Bi mode register in event counter mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
(3) Pulse period/pulse width measurement mode
In this mode, the timer measures the pulse period or pulse width of an external signal. (See Table 1.15.3.)
Figure 1.15.7 shows the timer Bi mode register in pulse period/pulse width measurement mode. Figure
1.15.8 shows the operation timing when measuring a pulse period. Figure 1.15.9 shows the operation
timing when measuring a pulse width.
Table 1.15.3. Timer specifications in pulse period/pulse width measurement mode
Item
Specification
Count source
f1, f8, f2n, fC32
Count operation
• Count up
• Counter value “000016” is transferred to reload register at measurement pulse's
effective edge and the timer continues counting
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing • When measurement pulse's effective edge is input (Note 1)
• When an overflow occurs. (Simultaneously, the timer Bi overflow flag changes to “1”.
The timer Bi overflow flag changes to “0” when the count start flag is “1” and a value
is written to the timer Bi mode register.)
TBiIN pin function
Measurement pulse input (Set the corresponding function select register A to I/O port.)
Read from timer
When timer Bi register is read, it indicates the reload register’s content
(measurement result) (Note 2)
Write to timer
Cannot be written to
Note 1: An interrupt request is not generated when the first effective edge is input after the timer has started
counting.
Note 2: The value read out from the timer Bi register is indeterminate until the second effective edge is input
after the timer.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
Timer Bi mode register (i = 0 to 5) (Pulse period / pulse width measurement mode)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TBiMR(i=0 to 5)
Bit symbol
TMOD0
TMOD1
MR0
MR1
Address
035B16, 035C16, 035D16, 031B16, 031C16, 031D16
Bit name
Operation mode
select bit
Measurement mode
select bit
When reset
00XX00002
Function
b1 b0
1 0 : Pulse period / pulse width
measurement mode
b3 b2
0 0 : Pulse period measurement 1
0 1 : Pulse period measurement 2
1 0 : Pulse width measurement
1 1 : Must not be set
(Note 1)
A
AA
A
AA
AA
A
AA
A
A
AA
A
AA
A
AA
A
AA
R
W
0 (Set to “0” in pulse period/pulse width measurement mode)
(Note 2)
Nothing is assigned (i = 1, 2, 4, 5).
(Note 3)
When write, set "0". When read, its content is indeterminate.
Timer Bi overflow
0 : Timer did not overflow
MR3
(Note 4) 1 : Timer has overflowed
flag
b7 b6
TCK0
Count source
0 0 : f1
select bit
0 1 : f8
1 0 : f2n
(Note 5)
TCK1
1 1 : fC32
Note 1: Do the next measurement, In the measurement mode select bit.
Pulse period measurement 1 (bit 3, bit 2=“0 0”) : Interval between measurement pulse's falling edge to falling edge.
Pulse period measurement 2 (bit 3, bit 2=“0 1”) : Interval between measurement pulse's rising edge to rising edge.
Pulse width measurement (bit 3, bit 2=“1 0”) : Interval between measurement pulse's falling edge to rising edge,
and between rising edge to falling edge.
Note 2: R/W is valid only in timer B0 and timer B3.
Note 3: In timer B1, timer B2, timer B4 and timer B5, nothing is assigned by bit 4(There is not R/W).
When write, set “0”. When read, its content is indeterminate.
Note 4: It is indeterminate when reset.
The timer Bi overflow flag changes to “0” when the count start flag is “1” and a value is written to the
timer Bi mode register. This flag cannot be set to “1” by software.
Note 5: n = 0 to 15. n is set by the count source prescaler register (address 035F16).
MR2
Figure 1.15.7. Timer Bi mode register in pulse period/pulse width measurement mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timer B
When measuring measurement pulse time interval from falling edge to falling edge
Count source
“H”
Measurement pulse
Reload register
transfer timing
“L”
Transfer
(indeterminate value)
Transfer
(measured value)
counter
(Note 1)
(Note 1)
(Note 2)
Timing at which counter
reaches “000016”
“1”
Count start flag
“0”
Timer Bi interrupt
request bit
“1”
Timer Bi overflow flag
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software.
“0”
Note 1: Counter is initialized at completion of measurement.
Note 2: Timer has overflowed.
Figure 1.15.8. Operation timing when measuring a pulse period
Count source
Measurement pulse
Reload register
transfer timing
“H”
“L”
counter
Transfer
(indeterminate
value)
(Note 1)
Transfer
(measured value)
(Note 1)
Transfer
(measured
value)
(Note 1)
Transfer
(measured value)
(Note 1)
(Note 2)
Timing at which counter
reaches “000016”
Count start flag
“1”
“0”
Timer Bi interrupt
request bit
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software.
Timer Bi overflow flag
“1”
“0”
Note 1: Counter is initialized at completion of measurement.
Note 2: Timer has overflowed.
Figure 1.15.9. Operation timing when measuring a pulse width
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Three-phase motor control timers’ functions
Three-phase motor control timers’ functions
Use of more than one built-in timer A and timer B provides the means of outputting three-phase motor
driving waveforms.
Figures 1.16.1 through 1.16.5 show registers related to timers for three-phase motor control.
Three-phase PWM control register 0 (Note 4)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
When reset
INVC0
030816
0016
Bit symbol
Bit name
Description
INV00
Effective interrupt output
polarity select bit
0: A timer B2 interrupt occurs when the
timer A1 reload control signal is “1”.
1: A timer B2 interrupt occurs when the
timer A1 reload control signal is “0”.
(Note 3)
INV01
Effective interrupt output
specification bit
(Note 2)
0: Not specified.
1: Selected by the INV00 bit.
Mode select bit
0: Normal mode
1: Three-phase PWM output mode
INV02
(Note 4)
R W
(Note 3)
0: Output disabled
1: Output enabled
INV03
Output control bit
INV04
0: Feature disabled
Positive and negative
phases concurrent L output 1: Feature enabled
disable function enable bit
INV05
0: Not detected yet
Positive and negative
phases concurrent L output 1: Already detected
detect flag
INV06
Modulation mode select
bit
0: Triangular wave modulation mode (Note 6)
1: Sawtooth wave modulation mode (Note 7)
INV07
Software trigger bit
0: Ignored
1: Trigger generated
(Note 5)
(Note 8)
Note 1: Set bit 1 of the protect register (address 000A16) to “1” before writing to this register.
Note 2: Set bit 1 of this register to “1” after setting timer B2 interrupt occurrences frequency set counter.
Note 3: Effective only in three-phase mode 1(Three-phase PWM control register's bit 1 = “1”).
Note 4: Selecting three-phase PWM output mode causes the dead time timer, the U, V, W phase output control circuits,
and the timer B2 interrupt frequency set circuit works.
For U, U, V, V, W and W output from P80, P81, and P72 through P75, setting of function select registers A, B and
C is required.
Note 5: No value other than “0” can be written.
Note 6: The dead time timer starts in synchronization with the falling edge of timer Ai output. The data transfer from the
three-phase buffer register to the three-phase output shift register is made only once in synchronization with the
transfer trigger signal after writing to the three-phase output buffer register.
Note 7: The dead time timer starts in synchronization with the falling edge of timer A output and with the transfer trigger
signal. The data transfer from the three-phase output buffer register to the three-phase output shift register is
made with respect to every transfer trigger.
Note 8: The value, when read, is “0”.
Figure 1.16.1. Registers related to timers for three-phase motor control
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Three-phase motor control timers’ functions
Three-phase PWM control register 1 (Note 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
Address
When reset
INVC1
030916
0016
Bit symbol
Bit name
Description
INV10
Timer Ai start trigger signal 0: Timer B2 overflow signal
1: Timer B2 overflow signal,
select bit
signal for writing to timer B2
INV11
Timer A1-1, A2-1, A4-1
control bit
(Note 2)
INV12
Dead time timer count
source select bit
0 : f1
1 : f1/2
INV13
Carrier wave detect flag
0: Rising edge of triangular waveform
1: Falling edge of triangular waveform
Output polarity control bit
0 : Low active
1 : High active
Dead time invalid bit
0: Dead time valid bit
1: Dead time invalid bit
Dead time timer trigger
select bit
0: Triggers from corresponding timer
1: Rising edge of corresponding phase
(Note 3)
output
Waveform reflect timing
select bit
0: Synchronized with raising edge of
triangular waveform
1: Synchronized with timer B2 overflow
(Note 4)
INV14
INV15
INV16
INV17
R W
0: Three-phase mode 0
1: Three-phase mode 1
Note 1: Set bit 1 of the protect register (address 000A16) to “1” before writing to this register.
Note 2: INV13 is valid only in triangular waveform mode (INV06=0) and three-phase mode (INV11=1).
Note 3:Usually set to “1”.
Note 4:INV17 is valid only in three-phase mode 1.
Three-phase output buffer register i (i=0, 1) (Note)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
IDBi (i=0,1)
Bit Symbol
Address
030A16, 030B16
Bit name
When reset
XX00 00002
Function
DUi
U phase output buffer i
Setting in U phase output buffer i
DUBi
U phase output buffer i
Setting in U phase output buffer i
DVi
V phase output buffer i
Setting in V phase output buffer i
DVBi
V phase output buffer i
Setting in V phase output buffer i
DWi
W phase output buffer i
Setting in W phase output buffer i
DWBi
W phase output buffer i
Setting in W phase output buffer i
Nothing is assigned.
When write, set “0”. When read, their contents are “0”.
Note: When executing read instruction of this register, the contents of three-phase shift register is read out.
Figure 1.16.2. Registers related to timers for three-phase motor control
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Three-phase motor control timers’ functions
Dead time timer (Note)
b7
b0
Symbol
DTT
Address
030C16
When reset
Indeterminate
Function
Values that can be set
8-bits counter (set dead time timer)
R W
1 to 255
Note: Use MOV instruction to write to this register.
Timer B2 interrupt occurrences frequency set counter (Note 1 to 4)
b7
b0
Symbol
ICTB2
Address
030D16
When reset
Indeterminate
Function
Values that can be set
Set occurrence frequency of timer B2
interrupt request
R
W
1 to 15
Nothing is assigned.
When write, set to “0”.
Note 1: Use MOV instruction to write to this register.
Note 2: When the effective interrupt output specification bit (INV01: bit 1 at 030816) is set to “1” and three-phase
motor control timer is operating, do not rewrite to this register.
Note 3: Do not write to this register at the timing of timer B2 overflow.
Note 4: Setting of this register is valid only when bit 2 (INV02) of three-phase PWM control register 0 is set to "1".
Timer Ai, Ai-1 register (Note 1 to 3)
(b15)
b7
(b8)
b0 b7
b0
Symbol
TAi (i 1, 2, 4)
TAi1 (i 1, 2, 4)
Address
When reset
034916,034816, 034B16,034A16, 034F16,034E16 Indeterminate
030316,030216, 030516,030416, 030716,030616 Indeterminate
Function
Values that can be set
Three-phase PWM pulse width modulator
(decide PWM output pulse width)
R
W
R
W
000016 to FFFF16
Note 1: Read and write data in 16-bit units.
Note 2: When set “000016” to the timer Ai register, counter doesn't move, and timer Ai interrupt isn't generated.
Note 3: Use MOV instruction to write to this register.
Timer B2 register (Note)
(b15)
b7
(b8)
b0 b7
b0
Symbol
TB2
Address
035516,035416
Function
Set the period of carrier wave
When reset
Indeterminate
Values that can be set
000016 to FFFF16
Note : Read and write data in 16-bit units.
Figure 1.16.3. Registers related to timers for three-phase motor control
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Three-phase motor control timers’ functions
Timer B2 special mode register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TB2SC
Bit symbol
PWCOM
Address
035E16
When reset
XXXXXXX02
Bit name
Timer B2 reload timing
switching bit
Function
0 : Next underflow
1 : Synchronized rising edge of
triangular wave
AA
R W
Nothing is assigned.
When write, set “0”. When read, its content is “0”.
Trigger select register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TRGSR
Bit symbol
TA1TGL
Address
034316
Bit name
Timer A2 event/trigger
select bit
Set bit 3 and bit 2 to “0 1” before using
to the W phase output control circuit.
(Note)
Inhibited in Three-phase PWM mode.
TA3TGH
TA4TGL
A
A
A
AA
A
A
AA
A
AA
A
A
AA
Set bit 1 and bit 0 to “0 1” before using
to the V phase output control circuit.
(Note)
TA2TGH
TA3TGL
Function
Timer A1 event/trigger
select bit
TA1TGH
TA2TGL
When reset
0016
Timer A4 event/trigger
select bit
TA4TGH
R W
Set bit 7 and bit 6 to “0 1” before using
to the U phase output control circuit.
(Note)
Note: Set the corresponding port function select register A to I/O port, and port direction register to “0”.
Count start flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TABSR
Bit symbol
Address
034016
Bit name
When reset
0016
Function
TA0S
Timer A0 count
start flag
0 : Stops counting
1 : Starts counting
TA1S
Timer A1 count
start flag
0 : Stops counting
1 : Starts counting
TA2S
Timer A2 count
start flag
0 : Stops counting
1 : Starts counting
TA3S
Timer A3 count
start flag
0 : Stops counting
1 : Starts counting
TA4S
Timer A4 count
start flag
0 : Stops counting
1 : Starts counting
TB0S
Timer B0 count
start flag
0 : Stops counting
1 : Starts counting
TB1S
Timer B1 count
start flag
0 : Stops counting
1 : Starts counting
TB2S
Timer B2 count
start flag
0 : Stops counting
1 : Starts counting
Figure 1.16.4. Registers related to timers for three-phase motor control
158
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Three-phase motor control timers’ functions
Three-phase motor driving waveform output mode (three-phase PWM output mode)
Setting “1” in the mode select bit (bit 2 at 030816) shown in Figure 1.16.1 causes three-phase PWM
output mode that uses four timers A1, A2, A4, and B2. As shown in Figure 1.16.4 and 1.16.5 set timers
A1, A2, and A4 in one-shot timer mode, set the trigger in timer B2, and set timer B2 in timer mode using
the respective timer mode registers.
Timer Ai mode register (i = 1, 2, 4)
b7
b6
b5
b4
0
1
b3
b2
b1
b0
1
0
Symbol
TAiMR(i=1, 2, 4)
Address
035716, 035816, 035A16
Bit symbol
Bit name
TMOD0
Operation mode select bit
TMOD1
When reset
00000X002
1 0 : One-shot timer mode
MR0
This bit is invalid in M32C/80 series.
Port output control is set by the function select registers A, B and C.
MR1
External trigger select bit
Invalid in Three-phase PWM output mode.
MR2
Trigger select bit
1 : Selected by event/trigger select register
MR3
0 (Set to “0” in one-shot timer mode)
TCK0
Count source select bit
TCK1
b7 b6
0 0 : f1
0 1 : f8
1 0 : f2n
1 1 : fC32
(Note)
Note: n = 0 to 15. n is set by the count source prescaler register (address 035F16).
AAA
A
AA
AA
A
AA
A
A
A
A
A
AA
A
AA
A
AA
A
AA
AA
R W
Function
b1 b0
Timer B2 mode register
b7
b6
b5
b4
0
b3
b2
b1
b0
0
0
Symbol
TB2MR
Bit symbol
TMOD0
Address
035D16
When reset
00XX00002
Bit name
Function
b1 b0
Operation mode select bit
0 0 : Timer mode
TMOD1
MR0
MR1
Invalid in timer mode
Can be “0” or “1”
MR2
0 (Set to “0” in timer mode)
MR3
Invalid in timer mode.
When write, set “0”. When read in timer mode, its content is
indeterminate.
TCK0
Count source select bit
TCK1
b7 b6
0 0 : f1
0 1 : f8
1 0 : f2n
1 1 : fC32
Note: n = 0 to 15. n is set by the count source prescaler register (address 035F16).
AA
A
A
A
AA
A
AA
A
A
R W
A
A
AA
(Note)
Figure 1.16.5. Timer mode registers in three-phase PWM output mode
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Figure 1.16.6 shows the block diagram for three-phase waveform mode. The Low active output polarity
in three-phase waveform mode, the positive-phase waveforms (U phase, V phase, and W phase) and
___
___
___
negative waveforms (U phase, V phase, and W phase), six waveforms in total, are output from P80, P81,
P72, P73, P74, and P75 as active on the “L” level. Of the timers used in this mode, timer A4 controls the
___
___
U phase and U phase, timer A1 controls the V phase and V phase, and timer A2 controls the W phase
___
and W phase respectively; timer B2 controls the periods of one-shot pulse output from timers A4, A1,
and A2.
In outputting a waveform, dead time can be set so as to cause the “L” level of the positive waveform
___
output (U phase, V phase, and W phase) not to lap over the “L” level of the negative waveform output (U
___
___
phase, V phase, and W phase).
To set short circuit time, use three 8-bit timers, sharing the reload register, for setting dead time. A value
from 1 through 255 can be set as the count of the timer for setting dead time. The timer for setting dead
time works as a one-shot timer. If a value is written to the dead timer (030C16), the value is written to the
reload register shared by the three timers for setting dead time.
Any of the timers for setting dead time takes the value of the reload register into its counter, if a start
trigger comes from its corresponding timer, and performs a down count in line with the clock source
selected by the dead time timer count source select bit (bit 2 at 030916). The timer can receive another
trigger again before the workings due to the previous trigger are completed. In this instance, the timer
performs a down count from the reload register’s content after its transfer, provoked by the trigger, to the
timer for setting dead time.
Since the timer for setting dead time works as a one-shot timer, it starts outputting pulses if a trigger
comes; it stops outputting pulses as soon as its content becomes 0016, and waits for the next trigger to
come.
___
___
The positive waveforms (U phase, V phase, and W phase) and the negative waveforms (U phase, V
___
phase, and W phase) in three-phase waveform mode are output, from respective ports by means of
setting “1” in the output control bit (bit 3 at 030816). Setting “0” in this bit causes the ports to be the highimpedance state. This bit can be set to “0” not only by use of the applicable instruction, but by entering
_______
a falling edge in the NMI terminal or by resetting. Also, if “1” is set in the positive and negative phases
concurrent L output disable function enable bit (bit 4 at 030816) causes one of the pairs of U phase and
___
___
___
U phase, V phase and V phase, and W phase and W phase concurrently go to “L”, as a result, the output
control bit becomes the high-impedance state.
160
Timer A4-1
T Q
INV11
(One-shot timer mode)
Timer A4 counter
Reload
Timer A1-1
(One-shot timer mode)
Timer A1 counter
Reload
Timer A2-1
(One-shot timer mode)
INV11
T Q
To be set to “0” when timer A2 stops
Timer A2 counter
Reload
1/2
INV06
INV06
Trigger
signal for
transfer
INV06
f1
0
1
A
T
Q
T
Q
T
Q
D
Q
For short circuit
prevention
V phase output signal
V phase output signal
W phase output signal
W phase output signal
n = 1 to 255
Dead time timer setting (8)
W phase output
control circuit
Trigger
Trigger
U phase output signal
Three-phase output
shift register
(U phase)
INV05
INV04
RESET
NMI
INV14
R
INV03 D Q
Diagram for switching to P80, P81 and P72 - P75 is not shown.
T
D Q
D Q
T
D Q
T
D Q
T
T
D Q
D Q
T
Interrupt request bit
U phase output signal
Dead time timer setting (8)
n = 1 to 255
T
DUB0
D
DU0
V phase output
control circuit
Trigger
Trigger
D
DUB1
D
DU1
Bit 0 at 030B16
Bit 0 at 030A16
Dead time timer setting (8)
n = 1 to 255
Reload register
Interrupt occurrence
frequency set counter
n = 1 to 15
U phase output control circuit
Trigger
Trigger
0
1
W(P75)
W(P74)
V(P73)
V(P72)
U(P81)
U(P80)
Rev.B2 for proof reading
Trigger
Timer A2
INV11
T Q
To be set to “0” when timer A1 stops
Trigger
Timer A1
To be set to “0” when timer A4 stops
Trigger
Timer A4
Trigger signal for
timer Ai start
INV07
INV00
Circuit for interrupt occurrence
frequency set counter
t
(Timer mode)
Timer B2
Signal to be
written to B2
INV10
Overflow
INV01
INV11
INV13
Three-phase motor control timers’ functions
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Figure 1.16.6. Block diagram for three-phase waveform mode
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Three-phase motor control timers’ functions
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Triangular wave modulation
To generate a PWM waveform of triangular wave modulation, set “0” in the modulation mode select bit
(bit 6 at 030816). Also, set “1” in the timers A4-1, A1-1, A2-1 control bit (bit 1 at 030916). In this mode,
each of timers A4, A1, and A2 has two timer registers, and alternately reloads the timer register’s content to the counter every time timer B2 counter’s content becomes 000016. If “0” is set to the effective
interrupt output specification bit (bit 1 at 030816), the frequency of interrupt requests that occur every
time the timer B2 counter’s value becomes 000016 can be set by use of the timer B2 counter (030D16)
for setting the frequency of interrupt occurrences. The frequency of occurrences is given by (setting;
setting ≠ 0).
Setting “1” in the effective interrupt output specification bit (bit 1 at 0308 16) provides the means to
choose which value of the timer A1 reload control signal to use, “0” or “1”, to cause timer B2’s interrupt
request to occur. To make this selection, use the effective interrupt output polarity selection bit (bit 0 at
030816).
An example of U phase waveform is shown in Figure 1.16.7, and the description of waveform output
workings is given below. Set “1” in DU0 (bit 0 at 030A16). And set “0” in DUB0 (bit 1 at 030A16). In
addition, set “0” in DU1 (bit 0 at 030B16) and set “1” in DUB1 (bit 1 at 030B16). Also, set “0” in the
effective interrupt output specification bit (bit 1 at 030816) to set a value in the timer B2 interrupt occurrence frequency set counter. By this setting, a timer B2 interrupt occurs when the timer B2 counter’s
content becomes 000016 as many as (setting) times. Furthermore, set “1” in the effective interrupt output
specification bit (bit 1 at 030816), set in the effective interrupt polarity select bit (bit 0 at 030816) and set
“1” in the interrupt occurrence frequency set counter (030D16). These settings cause a timer B2 interrupt
to occur every other interval when the U phase output goes to “H”.
When the timer B2 counter’s content becomes 000016, timer A4 starts outputting one-shot pulses. In this
instance, the content of DU1 (bit 0 at 030B16) and that of DU0 (bit 0 at 030A16) are set in the three-phase
output shift register (U phase), the content of DUB1 (bit 1 at 030B16) and that of DUB0 (bit 1 at 030A16)
___
are set in the three-phase shift register (U phase). After triangular wave modulation mode is selected,
however, no setting is made in the shift register even though the timer B2 counter’s content becomes
000016.
___
The value of DU0 and that of DUB0 are output to the U terminal (P8 0) and to the U terminal (P81)
respectively. When the timer A4 counter counts the value written to timer A4 (034F16, 034E16) and when
timer A4 finishes outputting one-shot pulses, the three-phase shift register’s content is shifted one posi___
tion, and the value of DU1 and that of DUB1 are output to the U phase output signal and to U phase
output signal respectively. At this time, one-shot pulses are output from the timer for setting dead time
used for setting the time over which the “L” level of the U phase waveform doesn’t overlap the Low level
___
of the U phase waveform, which has the opposite phase of the former. The U phase waveform output
that started from the “H” level keeps its level until the timer for setting dead time finishes outputting oneshot pulses even though the three-phase output shift register’s content changes from “1” to “0” by the
effect of the one-shot pulses. When the timer for setting dead time finishes outputting one-shot pulses,
“0” already shifted in the three-phase shift register goes active, and the U phase waveform changes to
the Low level. When the timer B2 counter’s content becomes 000016, the timer A4 counter starts counting the value written to timer A4-1 (030716, 030616), and starts outputting one-shot pulses. When timer
A4 finishes outputting one-shot pulses, the three-phase shift register’s content is shifted one position,
but if the three-phase output shift register’s content changes from “0” to “1” as a result of the shift, the
output level changes from “L” to “H” without waiting for the timer for setting dead time to finish outputting
one-shot pulses. A U phase waveform is generated by these workings repeatedly. With the exception
that the three-phase output shift register on the U phase side is used, the workings in generating a U
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Three-phase motor control timers’ functions
phase waveform, which has the opposite phase of the U phase waveform, are the same as in generating
a U phase waveform. In this way, a waveform can be picked up from the applicable terminal in a manner
in which the “L” level of the U phase waveform doesn’t lap over that of the U phase waveform, which has
the opposite phase of the U phase waveform. The width of the “L” level too can be adjusted by varying
___
___
the values of timer B2, timer A4, and timer A4-1. In dealing with the V and W phases, and V and W
phases, the latter are of opposite phase of the former, have the corresponding timers work similarly to
___
dealing with the U and U phases to generate an intended waveform.
A carrier wave of triangular waveform
Carrier wave
Signal wave
Timer B2
Timber B2 interrupt occurres
Rewriting timer A4 and timer A4-1.
Possible to set the number of overflows to generate an
interrupt by use of the interrupt occurrences frequency
set circuit
Trigger signal for
timer Ai start
(timer B2 overflow
signal)
m
Timer A4 output
n
m
n
m
p
Control signal for
timer A4 reload
o
The three-phase
shift register
shifts in
synchronization
with the falling
edge of the A4
output.
U phase
output signal
U phase
output signal
U phase
(Note 1)
U phase
Dead time
U phase
(Note 2)
U phase
Dead time
INV13(Triangular wave
modulation detect flag)
(Note 3)
Note 1: When INV14="0" (output wave Low active)
Note 2: When INV14="1" (output wave High active)
Note 3: Set to triangular wave modulation mode and to three-phase mode 1.
Figure 1.16.7. Timing chart of operation (1)
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Three-phase motor control timers’ functions
Assigning certain values to DU0 (bit 0 at 030A16) and DUB0 (bit 1 at 030A16), and to DU1 (bit 0 at
030B16) and DUB1 (bit 1 at 030B16) allows you to output the waveforms as shown in Figure 1.16.8, that
___
___
is, to output the U phase alone, to fix U phase to “H”, to fix the U phase to “H,” or to output the U phase
alone.
A carrier wave of triangular waveform
Carrier wave
Signal wave
Timer B2
Rewriting timer A4 every timer B2 interrupt occurres.
Timer B2 interrupt occurres.
Rewriting three-phase buffer register.
Trigger signal for
timer Ai start
(timer B2 overflow
signal)
Timer A4 output
m
n
m
n
m
p
Control signal for
timer A4 reload
U phase
output signal
U phase
output signal
U phase
U phase
Dead time
Note: Set to triangular wave modulation mode and to three-phase mode 1.
Figure 1.16.8. Timing chart of operation (2)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Sawtooth modulation
To generate a PWM waveform of sawtooth wave modulation, set “1” in the modulation mode select bit
(bit 6 at 030816). Also, set “0” in the timers A4, A1, and A2-1 control bit (bit 1 at 030916). In this mode, the
timer registers of timers A4, A1, and of A2 comprise conventional timers A4, A1, and A2 alone, and
reload the corresponding timer register’s content to the counter every time the timer B2 counter’s content becomes 000016. The effective interrupt output specification bit (bit 1 at 030816) and the effective
interrupt output polarity select bit (bit 0 at 030816) go nullified.
An example of U phase waveform is shown in Figure 1.16.9, and the description of waveform output
workings is given below. Set “1” in DU0 (bit 0 at 030A16), and set “0” in DUB0 (bit 1 at 030A16). In
addition, set “0” in DU1 (bit 0 at 030B16) and set “1” in DUB1 (bit 1 at 030B16).
When the timber B2 counter’s content becomes 000016, timer B2 generates an interrupt, and timer A4
starts outputting one-shot pulses at the same time. In this instance, the contents of the three-phase
buffer registers DU1 and DU0 are set in the three-phase output shift register (U phase), and the contents
of DUB1 and DUB0 are set in the three-phase output register (U phase). After this, the three-phase
buffer register’s content is set in the three-phase shift register every time the timer B2 counter’s content
becomes 000016.
___
The value of DU0 and that of DUB0 are output to the U terminal (P80) and to the U terminal (P81)
respectively. When the timer A4 counter counts the value written to timer A4 (034F16, 034E16) and when
timer A4 finishes outputting one-shot pulses, the three-phase output shift register’s content is shifted
one position, and the value of DU1 and that of DUB1 are output to the U phase output signal and to the
___
U output signal respectively. At this time, one-shot pulses are output from the timer for setting dead time
used for setting the time over which the “L” level of the U phase waveform doesn’t lap over the “L” level
___
of the U phase waveform, which has the opposite phase of the former. The U phase waveform output
that started from the “H” level keeps its level until the timer for setting dead time finishes outputting oneshot pulses even though the three-phase output shift register’s content changes from “1” to “0 ”by the
effect of the one-shot pulses. When the timer for setting dead time finishes outputting one-shot pulses,
0 already shifted in the three-phase shift register goes effective, and the U phase waveform changes to
the “L” level. When the timer B2 counter’s content becomes 000016, the contents of the three-phase
buffer registers DU1 and DU0 are set in the three-phase shift register (U phase), and the contents of
___
DUB1 and DUB0 are set in the three-phase shift register (U phase) again.
A U phase waveform is generated by these workings repeatedly. With the exception that the three___
___
phase output shift register on the U phase side is used, the workings in generating a U phase waveform,
which has the opposite phase of the U phase waveform, are the same as in generating a U phase
waveform. In this way, a waveform can be picked up from the applicable terminal in a manner in which
the “L” level of the U phase waveform doesn’t lap over that of the U phase waveform, which has the
opposite phase of the U phase waveform. The width of the “L” level can also be adjusted by varying the
___
___
values of timer B2 and timer A4. In dealing with the V and W phases, and V and W phases, the latter are
of opposite phase of the former, have the corresponding timers work similarly to dealing with the U and
___
U phases to generate an intended waveform.
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Three-phase motor control timers’ functions
A carrier wave of sawtooth waveform
Carrier wave
Signal wave
Timer B2
Interrupt occurres.
Rewriting the value of timer A4.
Trigger signal for
timer Ai start
(timer B2 overflow
signal)
Timer A4 output
m
n
Data transfer is made from the threephase buffer registers to the threephase shift registers in step with the
timing of the timer B overflow.
o
U phase output
signal
U phase
output signal
U phase
U phase
Dead time
Note: Set to sawtooth modulation mode and to three-phase mode 0.
Figure 1.16.9. Timing chart of operation (3)
166
p
The three-phase
shift registers
shifts in
synchronization
with the falling
edge of timer A4.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
___
Setting “1” both in DUB0 and in DUB1 provides a means to output the U phase alone and to fix the U
phase output to “H” as shown in Figure 1.16.10.
A carrier wave of sawtooth waveform
Carrier wave
Signal wave
Timer B2
Interrupt occurres.
Rewriting the value of timer A4.
Trigger signal for
timer Ai start
(timer B2 overflow
signal)
Timer A4 output
Interrupt occurres.
Rewriting the value of timer A4.
Rewriting three-phase
output buffer register
m
n
Data transfer is made from the threephase buffer registers to the threephase shift registers in step with the
timing of the timer B overflow.
p
The three-phase
shift registers shifts
in synchronization
with the falling
edge of timer A4.
U phase
output signal
U phase
output signal
U phase
U phase
Dead time
Note: Set to sawtooth modulation mode and to three-phase mode 0.
Figure 1.16.10. Timing chart of operation (4)
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Serial I/O
Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
Serial I/O is configured as five channels: UART0 to UART4.
UARTi (i=0 to 4) each have an exclusive timer to generate a transfer clock, so they operate independently
of each other.
Figure 1.17.1 shows the block diagram of UARTi.
UARTi has two operation modes: a clock synchronous serial I/O mode and a clock asynchronous serial I/O
mode (UART mode). The contents of the serial I/O mode select bits (bits 0 to 2 at addresses 036816,
02E816, 033816, 032816 and 02F816) determine whether UARTi is used as a clock synchronous serial I/O
or as a UART.
It has the bus collision detection function that generates an interrupt request if the TxD pin and the RxD pin
are different in level.
Figures 1.17.2 through 1.17.8 show the registers related to UARTi.
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Serial I/O
TxD
polarity
reversing
circuit
RxD polarity
reversing circuit
RxDi
UART reception
1/16
Clock source selection
f1
f8
f2n
Clock synchronous type
Bit rate
generator
Internal
Reception
control circuit
Receive
clock
UART transmission
1 / (ni+1)
1/16
(Note)
Transmit
clock
Transmission
control circuit
Clock synchronous type
External
Transmit/
receive
unit
TxDi
Clock synchronous type
(when internal clock is selected)
1/2
Clock synchronous type
(when internal clock is selected)
CLK
polarity
reversing
circuit
CLKi
CTS/RTS
selected
Clock synchronous type
(when external clock is
selected)
CTS/RTS disabled
RTS2
CTSi / RTSi
Vcc
CTS/RTS disabled
CTS2
ni : Values set to UARTi bit rate generator (UiBRG)
Note :UART 2 is not CMOS output but N channel open drain output.
No reverse
RxD data
reverse circuit
RxDi
Reverse
Clock
synchronous type
PAR
disabled
1SP
SP
SP
UARTi receive register
UART(7 bits)
PAR
2SP
PAR
enabled
0
UART
(7 bits)
UART
(8 bits)
Clock
synchronous
type
0
0
0
UART
0
Clock
synchronous type
UART
(9 bits)
0
0
UART
(8 bits)
UART
(9 bits)
D8
D7
D6
D5
D4
D3
D2
D1
D0
Logic reverse circuit + MSB/LSB conversion circuit
Data bus high-order bits
Data bus low-order bits
UARTi receive
buffer register
Address 036E16
Address 036F16
Address 02EE16
Address 02EF16
Address 033E16
Address 033F16
Address 032E16
Address 032F16
Address 02FE16
Address 02FF16
Logic reverse circuit + MSB/LSB conversion circuit
D7
D8
D6
D5
D4
D3
D2
D1
D0
Address 036A16
Address 036B16
Address 02EA16
Address 02EB16
Address 033A16
Address 033B16
Address 032A16
Address 032B16
Address 02FA16
Address 02FB16
UART
(8 bits)
UART
(9 bits)
PAR
enabled
2SP
SP
SP
UART
(9 bits)
UARTI transmit buffer
register
Clock
synchronous type
UART
PAR
1SP
PAR
disabled
Clock
synchronous
type
“0”
UART
(7 bits)
UART
(8 bits)
UARTi transmit register
UART(7 bits)
Clock
synchronous type
Error signal output
disable
SP : Stop bit
PAR : Parity bit
i
: 0 to 4
No reverse
TxD data
reverse circuit
Error signal
output circuit
Error signal output
enable
TxDi
Reverse
Figure 1.17.1. Block diagram of UARTi
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
UARTi transmit buffer register (i=0 to 4) (Note)
b15
(b7)
b8
(b0) b7
b0
Symbol
UiTB(i=0,1,2)
Address
036B16, 036A16, 02EB16, 02EA16, 033B16, 033A16
Indeterminate
UiTB(i=3,4)
032B16, 032A16, 02FB16, 02FA16
Indeterminate
Bit
symbol
Function
(Clock synchronous serial I/O mode)
Transmit data
When reset
Function
(UART mode)
R W
Transmit data
Transmit data (9th bit)
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Note: Use MOV instruction to write to this register.
UARTi receive buffer register (i = 0 to 4)
b15
(b7)
b8
(b0)b7
b0
Symbol
UiRB(i=0,1,2)
UiRB(i=3,4)
Bit
symbol
Address
036F16,036E16, 02EF16,02EE16, 033F16,033E16
032F16,032E16, 02FF16,02FE16
When reset
Indeterminate
Indeterminate
Function
(Clock synchronous
serial I/O mode)
R W
Bit name
Receive data
Function
(UART mode)
Receive data
Receive data(9th bit)
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
ABT
OER
FER
Arbitration lost
0: Not detectet
detecting flag (Note 1) 1: Detected
0: No overrun error
0: No overrun error
1:
Overrun
error
found
1: Overrun error found
(Note 2)
Overrun error flag
Framing error flag
Invalid
0: No framing error
1: Framing error found
Invalid
0: No parity error
1: Parity error found
Invalid
0: No error
1: Error found
(Note 2)
PER
SUM
Invalid
Parity error flag
(Note 2)
Error sum flag
(Note 2)
Note 1: Arbitration lost detecting flag must always write "0".
Note 2: Bits 15 through 12 are set to 0002 when the serial I/O mode select bit (bits 2 to 0 at addresses 036816,
02E816, 033816, 032816, 02F816) are set to "0002" or the receive enable bit is set to "0".
(Bit 15 is set to "0" when bits 14 to 12 all are set to "0".)
Bits 14 and 13 are also set to "0" when the lower byte of the UARTi receive buffer register (addresses
036E16, 02EE16, 033E16, 032E16, 02FE16) is read.
Figure 1.17.2. Serial I/O-related registers (1)
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
UARTi bit rate generator (i=0 to 4) (Note 1, 2)
b7
Symbol
b0
Address
036916, 02E916, 033916, 032916, 02F916
UiBRG(i=0 to 4)
Function
When reset
Indeterminate
Values that can be set R W
Assuming that set value = n, BRGi divides
the count source by n+1
0016 to FF16
Note 1: Use MOV instruction to write to this register.
Note 2: Write a value to this register while transmit/receive halts.
UARTi transmit/receive mode register (i=0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
UiMR(i=0 to 4)
Bit
symbol
Address
036816, 02E816, 033816, 032816, 02F816
Bit name
SMD0
SMD1
Serial I/O mode
select bit
Function
(Clock synchronous
serial I/O mode)
When reset
0016
Function
(UART mode)
b2 b1 b0
b2 b1 b0
0 0 0: Serial I/O invalid
0 0 1: Serial I/O mode
0 1 0: I2C mode
Must not be set
except above
0 0 0: Serial I/O invalid
1 0 0: Transfer data 7 bits long
1 0 1: Transfer data 8 bits long
1 1 0: Transfer data 9 bits long
Must not be set
except above
SMD2
Internal/external 0 : Internal clock
(Note 1)
clock select bit 1 : External clock
0 : Internal clock
1 : External clock
STPS
Stop bit length
select bit
Invalid
0 : One stop bit
1 : Two stop bits
PRY
Odd/even parity
select bit
Invalid
Valid when bit 6 = "1"
0 : Odd parity
1 : Even parity
CKDIR
(Note 2)
PRYE Parity enable bit Invalid
R W
(Note 2)
0 : Parity disabled
1 : Parity enabled
TxD,RxD input/
0: No reversed
IOPOL output polarity
switch bit (Note 3) 1: Reversed
Note 1: Select CLK output by the corresponding function select registers A, B and C.
Note 2: Set the corresponding function select register A to the I/O port.
Note 3: Normally set "0".
Figure 1.17.3. Serial I/O-related registers (2)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
UARTi transmit/receive control register 0 (i=0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
UiC0(i=0 to 4)
Bit
symbol
CLK0
CLK1
Address
036C16, 02EC16, 033C16, 032C16, 02FC16
Function
(Clock synchronous
serial I/O mode)
Bit name
When reset
0816
Function
(UART mode)
R W
b1 b0
0 0: f1 is selected
BRG count source 0 1: f8 is selected
select bit
1 0: f2n is selected
1 1: Must not be set
CRS
CST/RTS function
select bit
Valid when bit 4 = “0”
0 : CTS function is selected
1 : RTS function is selected
TXEPT
Transmit register
empty flag
0 : Data present in transmit register
(during transmission)
1 : No data present in transmit register
(transmission completed)
CRD
CTS/RTS disable
bit
0 : CTS/RTS function enabled
1 : CTS/RTS function disabled
NCH Data output select
(Note 3) bit
(Note 1)
(Note 2)
0 : TXDi pin is CMOS output
1 : TXDi pin is N-channel open drain output
0 : Transmit data is output
at falling edge of transfer
clock and receive data
Set to “0”
is input at rising edge
1 : Transmit data is output
at rising edge of transfer
clock and receive data
is input at falling edge
CKPOL
CLK polarity
select bit
UFORM
Transfer format
0 : LSB first
select bit (Note 4) 1 : MSB first
Note 1: Set the corresponding function select register A to I/O port, and port direction register to “0”
Note 2: Select RTS output using the corresponding function select registers A, B and C.
Note 3: UART2 transfer pin (TxD2:P70) is N-channel open drain output. It is not set to CMOS output.
Note 4: Valid only in clock syncronous serial I/O mode and 8 bits UART mode.
Figure 1.17.4. Serial I/O-related registers (3)
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
UARTi transmit/receive control register 1 (i=0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
UiC1(i=0 to 4)
Bit
symbol
Address
036D16, 02ED16, 033D16, 032D16, 02FD16
Function
(Clock synchronous
serial I/O mode)
Bit name
When reset
0216
Function
(UART mode)
TE
Transmit
enable bit
0: Transmission disabled
1: Transmission enabled
TI
Transmit buffer
empty flag
0: Data present in transmit buffer register
0: No data present in transmit buffer register
RE
Receive
enable bit
0: Reception disabled
1: Reception enabled
RI
Receive
complete flag
0: Data present in receive buffer register
0: No data present in receive buffer register
UARTi transmit
interrupt cause
select bit
UARTi
UiRRM continuous
receive mode
enable bit
UiIRS
UiLCH
R W
0: Transmit buffer empty (TI = 1)
1: Transmit is completed (TXEPT = 1)
0: Continuous receive
mode disabled
1: Continuous receive Set to “0”
mode enabled
0: No reverse
1: Reverse
Data logic
select bit
divide
Clock divide synchronizing stop bit
SCLKSTPB Clock
synchronizing stop bit 0: Synchronizing stop
Set to “0”
signal
output
/error
/UiERE
1: Synchronous start (Note)
enable bit
Note :When this bit and bit 7 of UARTi special mode register 2 are set, clock synchronizing function is used.
UARTi special mode register (i=0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
UiSMR(i=0 to 4)
Bit
symbol
Address
036716, 02E716, 033716, 032716, 02F716
Bit name
Function
(Clock synchronous
serial I/O mode)
IIC mode
select bit
0: Normal mode
1: IIC mode
Set to "0"
ABC
Arbitration lost
detecting flag
control bit
0: Update per bit
1: Update per byte
Set to "0"
BBS
Bus busy flag
0: STOP condition
detected
1: START condition
detected
Set to "0"
ACSE
SSS
SCLKDIV
0016
Function
(UART mode)
IICM
SCLL sync
0: Disabled
LSYN output enable
1: Enabled
bit
Bus collision
ABSCS detect sampling Set to "0"
clock select bit
When reset
R W
(Note 1)
Set to "0"
0: Rising edge of transfer clock
1: Underflow signal of timer Ai
(Note 2)
Auto clear function
select bit of transmit Set to "0"
enable bit
0: No auto clear function
1: Auto clear at
occurrence of bus
Transmit start
condition
select bit
Set to "0"
0: Ordinary
1: Falling edge of RxDi
Clock divide
set bit
0: Divided-by-2
(Note 3) Set to "0"
1: No divided
Note 1: Nothing but "0" may be written.
Note 2: UART0: timer A3 underflow signal, UART1: timer A4 underflow signal, UART2: timer A0 underflow signal,
UART3: timer A3 underflow signal, UART4: timer A4 underflow signal.
Note 3: When this bit and bit 7 of UARTi transmit/receive control register 1 are set, clock synchronizing
function is used.
Figure 1.17.5. Serial I/O-related registers (4)
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
UARTi special mode register 2 (i=0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
UiSMR2(i=0 to 4)
Bit
symbol
Address
036616, 02E616, 033616, 032616, 02F616
Bit name
Function
IICM2
IIC mode select
bit 2
0: NACK/ACK interrupt (DMA source - ACK)
Transfer to receive buffer at the rising
edge of last bit of receive clock
Receive interrupt occurs at the rising edge
of last bit of receive clock
1: UART transfer/receive interrupt (DMA
source - UART receive)
Transfer to receive buffer at the falling
edge of last bit of receive clock
Receive interrupt occurs at the falling
edge of last bit of receive clock
CSC
Clock
synchronous bit
0: Disabled
1: Enabled
SWC
SCL wait output bit
0: Disabled
1: Enabled
ALS
SDA output stop bit
0: Disabled
1: Enabled
STC
UARTi initialize bit
0: Disabled
1: Enabled
SWC2
SCL wait output
bit 2
0: UARTi clock
1: 0 output
SDHI
SDA output inhibit
bit
0: Disabled
1: Enabled (high impedance)
Clock divide
SU1HIM synchronizing
enable bit
Figure 1.17.6. Serial I/O-related registers (5)
174
When reset
0016
0: Synchronous disabled
1: Synchronous enabled
R W
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
UARTi special mode register 3 (i=0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
UiSMR3(i=0 to 4)
Bit
symbol
SSE
Address
036516, 02E516, 033516, 032516, 02F516
Bit name
When reset
0016
Function
R W
SS port function
0: SS function disabled
enable bit (Note 1) 1: SS function enabled
CKPH
Clock phase
set bit
0: Without clock delay
1: With clock delay
DINC
Serial input port
set bit
0: Select TxDi and RxDi (master mode)
0: Select STxDi and SRxDi (slave mode)
NODC
Clock output
select bit
0: CLKi is CMOS output
(Note 2)
1: CLKi is N-channel open drain output (Note 3)
Fault error flag
0: Without fault error
1: With fault error
ERR
(Note 4)
b7 b6 b5
DL0
DL1
SDAi(TxDi) digital
delay time set bit
(Note 5,6)
DL2
000 :Without delay
001 :2-cycle of BRG count source
010 :3-cycle of BRG count source
011 :4-cycle of BRG count source
100 :5-cycle of BRG count source
101 :6-cycle of BRG count source
110 :7-cycle of BRG count source
111 :8-cycle of BRG count source
Note 1: Set SS function after setting CTS/RTS disable bit (bit 4 of UARTi transfer/receive control
register 0) to "1".
Note 2: Set CLKi and TxDi both for output using the CLKi and TxDi function select register A. Set the
RxDi function select register A for input/output port and the port direction register to "0".
Note 3: Set STxDi for output using the STxDi function select registers A and B. Set the CLKi and
SRxDi function select register A for input/output port and the port direction register to "0".
Note 4: Nothing but "0" may be written.
Note 5: These bits are used for SDAi (TxDi) output digital delay when using UARTi for IIC interface.
Otherwise, must set to "000".
Note 6: When external clock is selected, delay is increased approximately 100ns.
Figure 1.17.7. Serial I/O-related registers (6)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Serial I/O
UARTi special mode register 4 (i=0 to 4)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
UiSMR4(i=0 to 4)
Bit
symbol
Address
036416, 02E416, 033416, 032416, 02F416
Bit name
When reset
0016
Function
R W
Start condition
0: Clear
STAREQ generate bit (Note) 1: Start
Restart condition
0: Clear
RSTAREQ generate bit (Note) 1: Start
Stop condition
0: Clear
STPREQ generate bit (Note) 1: Start
SCL, SDA output
STSPSEL select bit
0: Ordinal block
1: Start/stop condition generate block
ACKD
ACK data bit
0: ACK
1: NACK
ACKC
ACK data output
enable bit
0: SI/O data output
1: ACKD output
SCLHI
SCL output stop
enable bit
0: Disabled
1: Enabled
SWC9
SCL wait output
bit 3
0: SCL "L" hold disabled
1: SCL "L" hold enabled
Note :When start condition is generated, these bits automatically become "0".
AA
A
AA
A
AAAA
AA
External interrupt request cause select register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
IFSR
Bit symbol
Address
031F16
Bit name
When reset
0016
Function
IFSR0
INT0 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR1
INT1 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR2
INT2 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR3
INT3 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR4
INT4 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR5
INT5 interrupt polarity
select bit (Note)
0 : One edge
1 : Both edges
IFSR6
UART0/3 interrupt
cause select bit
0 : UART3 bus collision /start,stop
detect/false error detect
1 : UART0 bus collision /start,stop
detect/false error detect
IFSR7
UART1/4 interrupt
cause select bit
0 : UART4 bus collision /start,stop
detect/false error detect
1 : UART1 bus collision /start,stop
detect/false error detect
AA
A
A
AA
A
A
AA
AA
AA
AA
AA
R W
Note :When level sense is selected, set this bit to "0".
When both edges are selected, set the corresponding polarity switching bit of INT interrupt control
register to "0" (falling edge).
Figure 1.17.8. Serial I/O-related registers (7)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock synchronous serial I/O mode
(1) Clock synchronous serial I/O mode
The clock synchronous serial I/O mode uses a transfer clock to transmit and receive data. Tables 1.18.1
and 1.18.2 list the specifications of the clock synchronous serial I/O mode.
Table 1.18.1. Specifications of clock synchronous serial I/O mode (1/2)
Item
Specification
Transfer data format
• Transfer data length: 8 bits
Transfer clock
• When internal clock is selected (bit 3 at addresses 036816, 02E816, 033816, 032816,
02F816 = “0”) : fi/ 2(m+1) (Note 1)
_
fi = f1, f8, f2n(Note 2)
CLK is selected by the corresponding peripheral function select register A, B and C.
• When external clock is selected (bit 3 at addresses 036816, 02E816, 033816 , 032816,
02F816= “1”) : Input from CLKi pin
_
Set the corresponding function select register A to I/O port
_______
_______
_______
_______
Transmission/reception control
• CTS function/RTS function/CTS, RTS function chosen to be invalid
Transmission start condition
• To start transmission, the following requirements must be met:
_ Transmit enable bit (bit 0 at addresses 036D16, 02ED16, 033D16, 032D16, 02FD16) = “1”
_ Transmit buffer empty flag (bit 1 at addresses 036D16, 02ED16, 033D16, 032D16, 02FD16) = “0”
_______
_______
_
When CTS function selected, CTS input level = “L”
_
TxD output is selected by the corresponding peripheral function select register A, B and C.
• Furthermore, if external clock is selected, the following requirements must also be met:
_
CLKi polarity select bit (bit 6 at addresses 036C16, 02EC16, 033C16, 032C16,
_
CLKi polarity select bit (bit 6 at addresses 036C16, 02EC16, 033C16, 032C16,
02FC16) = “0”: CLKi input level = “H”
02FC16) = “1”: CLKi input level = “L”
Reception start condition
• To start reception, the following requirements must be met:
_
Receive enable bit (bit 2 at addresses 036D 16, 02ED16, 033D16, 032D16, 02FD16) = “1”
_
Transmit enable bit (bit 0 at addresses 036D 16, 02ED16, 033D16, 032D16, 02FD16) = “1”
_
Transmit buffer empty flag (bit 1 at addresses 036D16, 02ED16, 033D16, 032D16, 02FD16) = “0”
• Furthermore, if external clock is selected, the following requirements must also be met:
_
CLKi polarity select bit (bit 6 at addresses 036C16, 02EC16, 033C16, 032C16,
02FC16) = “0”: CLKi input level = “H”
_
CLKi polarity select bit (bit 6 at addresses 036C16, 02EC16, 033C16, 032C16,
02FC16) = “1”: CLKi input level = “L”
Interrupt request
generation timing
• When transmitting
_
Transmit interrupt cause select bit (bit 4 at address 036D16, 02ED16, 033D16,
032D16, 02FD16) = “0”: Interrupts requested when data transfer from UARTi transfer buffer register to UARTi transmit register is completed
_
Transmit interrupt cause select bit (bit 4 at address 036D16, 02ED16, 033D16,
032D16, 02FD16) = “1”: Interrupts requested when data transmission from UARTi
transfer register is completed
• When receiving
_
Interrupts requested when data transfer from UARTi receive register to UARTi
receive buffer register is completed
Note 1: “m” denotes the value 0016 to FF16 that is set to the UART bit rate generator.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock synchronous serial I/O mode
Table 1.18.2. Specifications of clock synchronous serial I/O mode (2/2)
Item
Specification
• Overrun error (Note)
Error detection
This error occurs when the next data is started to receive and 6.5 transfer clock is
elapsed before UARTi receive buffer register are read out.
Select function
• CLK polarity selection
Whether transmit data is output/input at the rising edge or falling edge of the transfer
clock can be selected
• LSB first/MSB first selection
Whether transmission/reception begins with bit 0 or bit 7 can be selected
• Continuous receive mode selection
Reception is enabled simultaneously by a read from the receive buffer register
• Reversing serial data logic
Whether to reverse data in writing to the transmission buffer register or reading the
reception buffer register can be selected.
• TxD, RxD I/O polarity reverse
This function is reversing TxD port output and RxD port input. All I/O data level is
reversed.
Note : If an overrun error occurs, the UARTi receive buffer will have the next data written in.
Table 1.18.3 lists the functions of the input/output pins during clock synchronous serial I/O mode. Note
that for a period from when the UARTi operation mode is selected to when transfer starts, the TxDi pin
outputs a “H”. (If the N-channel open drain is selected, this pin is in floating state.)
Table 1.18.3. Input/output pin functions in clock synchronous serial I/O mode
Pin name
Function
Method of selection
TxDi
Serial data output
(P63, P67, P70, (Note 1)
P92, P96)
(Outputs dummy data when performing reception only)
RxDi
Serial data input
(P62, P66, P71, (Note 2)
P91, P97)
Port P62, P66, P71, P91 and P97 direction register (bits 2 and 6 at address
03C216, bit 1 at address 03C316, bit 1 and 7 at address 03C716)= “0”
(Can be used as an input port when performing transmission only)
Transfer clock output
CLKi
(P61, P65, P72, (Note 1)
P90, P95)
Transfer clock input
(Note 2)
Internal/external clock select bit (bit 3 at addresses 036816, 02E816,
033816, 032816, 02F816) = “0”
CTSi/RTSi
CTS input
(P60, P64, P73, (Note 2)
P93, P94)
Internal/external clock select bit (bit 3 at addresses 036816, 02E816,
033816, 032816, 02F816) = “1”
Port P61, P65, P72, P90 and P95 direction register (bits 1 and 5 at address
03C216, bit 2 at address 03C316, bit 0 and 5 at address 03C716) = “0”
CTS/RTS disable bit (bit 4 at addresses 036C16, 02EC16, 033C16, 032C16,
02FC16) =“0”
CTS/RTS function select bit (bit 2 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) = “0”
Port P60, P64, P73, P93 and P94 direction register (bits 0 and 4 at address
03C216, bit 3 at address 03C316, bits 3 and 4 at address 03C716) = “0”
RTS output (Note 1)
CTS/RTS disable bit (bit 4 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) = “0”
CTS/RTS function select bit (bit 2 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) = “1”
Programmable I/O port
(Note 2)
CTS/RTS disable bit (bit 4 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) = “1”
________
Note 1: Select TxD output, CLK output and RTS output by the corresponding function select registers A, B and C.
Note 2: Select I/O port by the corresponding function select register A.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock synchronous serial I/O mode
• Example of transmit timing (when internal clock is selected)
Tc
Transfer clock
Transmit enable
bit (TE)
Transmit buffer
empty flag (Tl)
“1”
“0”
Data is set in UARTi transmit buffer register
“1”
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
“H”
CTSi
TCLK
“L”
Stopped pulsing because CTS = “H”
Stopped pulsing because transfer enable bit = “0”
CLKi
TxDi
D0 D 1 D2 D3 D4 D5 D6 D7
Transmit
register empty
flag (TXEPT)
D0 D 1 D2 D3 D4 D5 D 6 D7
D 0 D1 D2 D 3 D 4 D 5 D6 D7
“1”
“0”
Transmit interrupt “1”
request bit (IR)
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings:
• Internal clock is selected.
• CTS function is selected.
• CLK polarity select bit = “0”.
• Transmit interrupt cause select bit = “0”.
Tc = TCLK = 2(m + 1) / fi
fi: frequency of BRGi count source (f1, f8, f2n)
m: value set to BRGi
• Example of receive timing (when external clock is selected)
“1”
Receive enable
bit (RE)
“0”
Transmit enable
bit (TE)
“0”
Transmit buffer
empty flag (Tl)
“1”
Dummy data is set in UARTi transmit buffer register
“1”
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
“H”
RTSi
“L”
1 / fEXT
CLKi
Receive data is taken in
D0 D 1 D2 D3 D4 D 5 D6 D7
RxDi
Receive complete “1”
flag (Rl)
“0”
Receive interrupt
request bit (IR)
“1”
Over run error
flag(OER)
“1”
Transferred from UARTi receive register
to UARTi receive buffer register
D 0 D1 D2 D3 D 4
D5
D6
D7
D0 D1 D2 D 3
D4 D 5 D
Read out from UARTi receive buffer register
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
“0”
Shown in ( ) are bit symbols.
The above timing applies to the following settings:
• External clock is selected.
• RTS function is selected.
• CLK polarity select bit = “0”.
The following conditions are met when the CLKi
input before data reception = “H”
• Transmit enable bit “1”
• Receive enable bit “1”
• Dummy data write to UARTi transmit buffer register
fEXT: frequency of external clock
Figure 1.18.1. Typical transmit/receive timings in clock synchronous serial I/O mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock synchronous serial I/O mode
(a) Polarity select function
As shown in Figure 1.18.2, the CLK polarity select bit (bit 6 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) allows selection of the polarity of the transfer clock.
• When CLK polarity select bit = “0”
CLKi
TXDi
D0
D1
D2
D3
D4
D5
D6
D7
R XD i
D0
D1
D2
D3
D4
D5
D6
D7
Note 1: The CLK pin level when not
transferring data is “H”.
• When CLK polarity select bit = “1”
CLKi
TXDi
D0
D1
D2
D3
D4
D5
D6
D7
RXDi
D0
D1
D2
D3
D4
D5
D6
D7
Note 2: The CLK pin level when not
transferring data is “L”.
Figure 1.18.2. Polarity of transfer clock
(b) LSB first/MSB first select function
As shown in Figure 1.18.3, when the transfer format select bit (bit 7 at addresses 036C16, 02EC16,
033C16, 032C16, 02FC16) = “0”, the transfer format is “LSB first”; when the bit = “1”, the transfer format
is “MSB first”.
• When transfer format select bit = “0”
CLKi
TXDi
D0
D1
D2
D3
D4
D5
D6
D7
LSB first
R XD i
D0
D1
D2
D3
D4
D5
D6
D7
D2
D1
D0
• When transfer format select bit = “1”
CLKi
TXDi
D7
D6
D5
D4
D3
MSB first
RXDi
D7
D6
D5
D4
D3
D2
D1
D0
Note: This applies when the CLK polarity select bit = “0”.
Figure 1.18.3. Transfer format
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock synchronous serial I/O mode
(c) Continuous receive mode
If the continuous receive mode enable bit (bit 5 at address 036D16, 02ED 16, 033D16, 032D16,
02FD16) is set to “1”, the unit is placed in continuous receive mode. In this mode, when the receive
buffer register is read out, the unit simultaneously goes to a receive enable state without having to set
dummy data back to the transmit buffer register again.
(d) Serial data logic switch function
When the data logic select bit (bit6 at address 036D16, 02ED16, 033D16, 032D16, 02FD16) = “1”, and
writing to transmit buffer register or reading from receive buffer register, data is reversed. Figure
1.18.4 shows the timing example of serial data logic switch.
•When LSB first
Transfer clock
“H”
“L”
TxDi
“H”
(no reverse) “L”
TxDi
“H”
(reverse) “L”
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
Figure 1.18.4. Timing for switching serial data logic
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock asynchronous serial I/O (UART) mode
(2) Clock asynchronous serial I/O (UART) mode
The UART mode allows transmitting and receiving data after setting the desired transfer rate and transfer
data format. Tables 1.19.1 and 1.19.2 list the specifications of the UART mode. Figure 1.19.1 shows the
UARTi transmit/receive mode register.
Table 1.19.1. Specifications of UART Mode (1/2)
Item
Transfer data format
Specification
• Character bit (transfer data): 7 bits, 8 bits, or 9 bits as selected
• Start bit: 1 bit
• Parity bit: Odd, even, or nothing as selected
• Stop bit: 1 bit or 2 bits as selected
Transfer clock
• When internal clock is selected (bit 3 at addresses 036816, 02E816, 033816, 032816,
02F816 = “0”) : fi/16(m+1) (Note 1) fi = f1, f8, f2n
• When external clock is selected (bit 3 at addresses 036816, 02E816, 033816, 032816,
02F816 =“1”) : fEXT/16(m+1)(Note 1, 2)
_______
_______
_______ _______
Transmission/reception control • CTS function, RTS function, CTS/RTS function chosen to be invalid
Transmission start condition
• To start transmission, the following requirements must be met:
- Transmit enable bit (bit 0 at addresses 036D 16, 02ED16, 033D16, 032D16, 02FD16) = “1”
- Transmit buffer empty flag (bit 1 at addresses 036D16, 02ED16, 033D16, 032D16,
02FD16) = “0”
_______
_______
- When CTS function selected, CTS input level = “L”
- TxD output is selected by the corresponding peripheral function select register A, B
and C.
Reception start condition
• To start reception, the following requirements must be met:
- Receive enable bit (bit 2 at addresses 036D16, 02ED16, 033D16, 032D16, 02FD16) = “1”
- Start bit detection
Interrupt request
generation timing
• When transmitting
- Transmit interrupt cause select bits (bit 4 at address 036D16, 02ED16, 033D16,
032D16, 02FD16) = “0”: Interrupts requested when data transfer from UARTi transfer
buffer register to UARTi transmit register is completed
- Transmit interrupt cause select bits (bit 4 at address 036D16, 02ED16, 033D16,
032D16, 02FD16) = “1”: Interrupts requested when data transmission from UARTi
transfer register is completed
• When receiving
- Interrupts requested when data transfer from UARTi receive register to UARTi
receive buffer register is completed
Error detection
• Overrun error (Note 3)
This error occurs when the next data is started to receive and 6.5 transfer
clock is elapsed before UARTi receive buffer register are read out.
Note 1: ‘m’ denotes the value 0016 to FF16 that is set to the UARTi bit rate generator.
Note 2: fEXT is input from the CLKi pin.
Note 3: If an overrun error occurs, the UARTi receive buffer will be over written with the next data.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock asynchronous serial I/O (UART) mode
Table 1.19.2. Specifications of UART Mode (2/2)
Item
Specification
Error detection
• Framing error
This error occurs when the number of stop bits set is not detected
• Parity error
If parity is enabled this error occurs when, the number of 1’s in parity and character
bits does not match the number of 1’s set
• Error sum flag
This flag is set (= 1) when any of the overrun, framing, and parity errors is e n c o u n tered
Select function
• Serial data logic switch
This function reveres the logic value of transferring data. Start bit, parity bit and stop
bit are not reversed.
• TxD, RxD I/O polarity switch
This function reveres the TxD port output and RxD port input. All I/O data level is
reversed.
Table 1.19.3 lists the functions of the input/output pins in UART mode. Note that for a period from when
the UARTi operation mode is selected to when transfer starts, the TxDi pin outputs a “H”. (If the Nchannel open drain is selected, this pin is in floating state.)
Table 1.19.3. Input/output pin functions in UART mode
Pin name
Function
Method of selection
TxDi
(P63, P67, P70,
P92, P96)
Serial data output
(Note 1)
RxDi
(P62, P66, P71,
P91, P97)
Serial data input
(Note 2)
Port P62, P66, P71, P91 and P97 direction register (bits 2 and 6 at address
03C216, bit 1 at address 03C316, bit 1 and 7 at address 03C716)= “0”
(Can be used as an input port when performing transmission only)
CLKi
(P61, P65, P72,
P90, P95)
Programmable I/O port
(Note 2)
Internal/external clock select bit (bit 3 at addresses 036816, 02E816,
033816, 032816, 02F816) = “0”
Transfer clock input
(Note 2)
Internal/external clock select bit (bit 3 at addresses 036816, 02E816,
033816, 032816, 02F816) = “1”
Port P61, P65, P72, P90 and P95 direction register (bits 1 and 5 at address
03C216, bit 2 at address 03C316, bits 0 and 5 at address 03C716) = “0”
CTS input
(Note 2)
CTS/RTS disable bit (bit 4 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) =“0”
CTS/RTS function select bit (bit 2 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) = “0”
Port P60, P64, P73, P93 and P94 direction register (bits 0 and 4 at address
03C216, bit 3 at address 03C316, bits 3 and 4 at address 03C716) = “0”
RTS output (Note 1)
CTS/RTS disable bit (bit 4 at addresses 036C16, 02EC16, 033C16, 032C16,
02FC16) = “0”
CTS/RTS function select bit (bit 2 at addresses 036C16, 02EC16, 033C16,
032C16, 02FC16) = “1”
Programmable I/O port
(Note 2)
CTS/RTS disable bit (bit 4 at addresses 036C16, 02EC16, 033C16, 032C16,
02FC16) = “1”
CTSi/RTSi
(P60, P64, P73,
P93, P94)
________
Note 1: Select TxD output, CLK output and RTS output by the corresponding function select registers A, B and C.
Note 2: Select I/O port by the corresponding function select register A.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock asynchronous serial I/O (UART) mode
• Example of transmit timing when transfer data is 8 bits long (parity enabled, one stop bit)
The transfer clock stops momentarily as CTS is “H” when the stop bit is checked.
The transfer clock starts as the transfer starts immediately CTS changes to “L”.
Tc
Transfer clock
Transmit enable
bit(TE)
“1”
Transmit buffer
empty flag(TI)
“1”
“0”
Data is set in UARTi transmit buffer register.
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
“H”
CTSi
“L”
Start
bit
TxDi
Parity
bit
ST D0 D1 D2 D3 D4 D5 D6 D7
Transmit register
empty flag (TXEPT)
“1”
Transmit interrupt
request bit (IR)
“1”
P
Stopped pulsing because transmit enable bit = “0”
Stop
bit
SP
ST D0 D1 D2 D3 D4 D5 D6 D7
P
ST D0 D1
SP
“0”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings :
• Parity is enabled.
• One stop bit.
• CTS function is selected.
• Transmit interrupt cause select bit = “1”.
Tc = 16 (m + 1) / fi or 16 (m + 1) / fEXT
fi : frequency of BRGi count source (f1, f8, f2n)
fEXT : frequency of BRGi count source (external clock)
m : value set to BRGi
• Example of transmit timing when transfer data is 9 bits long (parity disabled, two stop bits)
Tc
Transfer clock
Transmit enable
bit(TE)
“1”
Transmit buffer
empty flag(TI)
“1”
“0”
Data is set in UARTi transmit buffer register
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
Start
bit
TxDi
Stop
bit
Stop
bit
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP SP
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SPSP
ST D0 D1
“1”
Transmit register
empty flag (TXEPT)
“0”
Transmit interrupt
request bit (IR)
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings :
• Parity is disabled.
• Two stop bits.
• CTS function is disabled.
• Transmit interrupt cause select bit = “0”.
Tc = 16 (m + 1) / fi or 16 (m + 1) / fEXT
fi : frequency of BRGi count source (f1, f8, f2n)
fEXT : frequency of BRGi count source (external clock)
m : value set to BRGi
Figure 1.19.1. Typical transmit timings in UART mode
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clock asynchronous serial I/O (UART) mode
• Example of receive timing when transfer data is 8 bits long (parity disabled, one stop bit)
BRGi count
source
Receive enable bit
“1”
“0”
Stop bit
Start bit
RxDi
D1
D0
D7
Sampled “L”
Receive data taken in
Transfer clock
Reception triggered when transfer clock
“1” is generated by falling edge of start bit
Receive
complete flag
Transferred from UARTi receive register to
UARTi receive buffer register
“0”
“H”
“L”
RTSi
Receive interrupt
request bit
Becomes “L” by reading the receive buffer
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
The above timing applies to the following settings :
•Parity is disabled.
•One stop bit.
•RTS function is selected.
Figure 1.19.2. Typical receive timing in UART mode
(a) Function for switching serial data logic
When the data logic select bit (bit 6 of address 036D16, 02ED16, 033D16, 032D16, 02FD16) is assigned
1, data is inverted in writing to the transmission buffer register or reading the reception buffer register.
Figure 1.19.3 shows the example of timing for switching serial data logic.
• When LSB first, parity enabled, one stop bit
Transfer clock
“H”
“L”
TxDi
“H”
(no reverse)
“L”
TxDi
“H”
(reverse)
“L”
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
ST : Start bit
P : Even parity
SP : Stop bit
Figure 1.19.3. Timing for switching serial data logic
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Clock asynchronous serial I/O (UART) mode
Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
(b) TxD, RxD I/O polarity reverse function
This function is to reverse TxD pin output and RxD pin input. The level of any data to be input or output
(including the start bit, stop bit(s), and parity bit) is reversed. Set this function to “0” (not to reverse) for
normal use.
(c) Bus collision detection function
This function is to sample the output level of the TxD pin and the input level of the RxD pin at the rising
edge of the transfer clock; if their values are different, then an interrupt request occurs. Figure 1.19.4
shows the example of detection timing of a bus collision (in UART mode).
UART0 and UART3 are allocated to software interrupt number 40. UART1 and UART4 are allocated
to software interrupt number 41. When selecting UART 0, 3, 1 or 4 bus collision detect function, bit 6
or 7 of external interrupt cause select register (address 031F16) must be set.
Transfer clock
“H”
“L”
TxDi
“H”
ST
SP
ST
SP
“L”
RxDi
“H”
“L”
Bus collision detection
interrupt request signal
“1”
Bus collision detection
interrupt request bit
“1”
“0”
“0”
ST : Start bit
SP : Stop bit
Figure 1.19.4. Detection timing of a bus collision (in UART mode)
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UARTi Special Mode Register
UARTi Special Mode Register
UARTi (i=0 to 4) operate the IIC bus interface (simple IIC bus) using the UARTi special mode register
(addresses 036716, 02E716, 033716, 032716 and 02F716) and UARTi special mode register 2 (addresses
036616, 02E616, 033616, 032616 and 02F616). UARTi add special functions using UARTi special mode
resister 3 (addresses 036516, 02E516, 035516, 032516 and 02F516).
(1) IIC Bus Interface Mode
The I2C bus interface mode is provided with UARTi.
Table 1.21.1 shows the construction of the UARTi special mode register and UARTi special mode register 2.
When the I2C mode select bit (bit 0 in addresses 036716, 02E716, 033716, 032716 and 02F716) is set to
“1”, the I2C bus (simple I2C bus) interface circuit is enabled.
To use the I2C bus, set the SCLi and the SDAi of both master and slave to output with the function select
register. Also, set the data output select bit (bit 5 in address 036C16, 02EC16, 033C16, 032C16 and
02FC16) to N-channel open drain output.
Table 1.21.1 shows the relationship of the IIC mode select bit to control. To use the chip in the clock
synchronized serial I/O mode or UART mode, always set this bit to “0”.
Table 1.21.1. Features in I2C mode
Bus collision detection
I2C mode (IICM=1) (Note 1)
Start condition detection or stop
condition detection
UARTi transmission
No acknowledgment detection (NACK)
UARTi reception
Acknowledgment detection (ACK)
4 UARTi transmission output delay
Not delayed
Delayed
5 P63, P67, P70, P92, P96 at the time when UARTi
is in use
TxDi (output)
SDAi (input/output)
6 P62, P66, P71, P91, P97 at the time when UARTi
is in use
RxDi (input)
SCLi (input/output)
7 P61, P65, P72, P90, P95 at the time when UARTi
is in use
CLKi
P61, P65, P72, P90, P95 (Note 3)
8 DMA factor at the time
UARTi reception
Acknowledgment detection (ACK)
Function
Normal mode (IICM=0)
(Note 2)
1 Factor of interrupt number 39 to 41
2 Factor of interrupt number 17, 19, 33, 35, 37
3 Factor of interrupt number 18, 20, 34, 36, 38
9 Noise filter width
(Note 2)
(Note 2)
15ns
50ns
10 Reading P62, P66, P71, P91, P97
Reading the terminal when 0 is
assigned to the direction register
Reading the terminal regardless of the
value of the direction register
11 Initial value of UARTi output
H level (when 0 is assigned to
the CLK polarity select bit)
The value set in latch P63, P67, P70,
P92, P96 when the port is selected
(Note 3)
Note 1: Make the settings given below when I2C mode is used.
Set 0 1 0 in bits 2, 1, 0 of the UARTi transmission/reception mode register.
Disable the RTS/CTS function. Choose the MSB First function.
Note 2: Follow the steps given below to switch from one factor to another.
1. Disable the interrupt of the corresponding number.
2. Switch from a factor to another.
3. Reset the interrupt request flag of the corresponding number.
4. Set an interrupt level of the corresponding number.
Note 3: Set an initial value of SDA transmission output when IIC mode (IIC mode select bit = "1") is valid and serial I/O is invalid.
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UARTi Special Mode Register
TXDi/SDA
Timer
Selector
To DMAi
I/O
UARTi
IICM=1
IICM=0 or IICM2=1
delay
Transmission register
UARTi
IICM=0
SDHI
ALS
D
Q
Noize
Filter
IICM=1 and
IICM2=0
To DMAi
Arbitration
T
UARTi transmission/
NACK interrupt
request
IICM=0 or
IICM2=1
IICM=1
Reception register
IICM=0
UARTi
IICM=1 and
IICM2=0
Start condition detection
S
R
Q
UARTi reception/ACK
interrupt request
DMAi request
Bus
busy
Stop condition detection
RxDi/SCL
D Q
T
R
I/0
NACK
D Q
T
L-synchronous
output enabling bit
Falling edge
detection
Data register
ACK
9th pulse
Selector
External clock
Bus collision
detection
UARTi
R
Falling edge of 9th pulse
SWC2
IICM=1
Noize
Filter
Noize
Filter
IICM=1
Internal clock
UARTi
IICM=1
IICM=0
CLK
control
S
Bus collision/start, stop
condition detection
interrupt request
IICM=0
SWC
Port reading
UARTi
IICM=0
CLKi
Serector
* With IICM set to 1, the port terminal is to be readable
even if 1 is assigned to P71 of the direction register.
I/0
Timer
Figure 1.21.1. Functional block diagram for I2C mode
Figure 1.21.1 is a block diagram of the IIC bus interface.
The control bits of the IIC bus interface is explained as follow:
UARTi Special Mode Register (UiSMR:Addresses 036716, 02E716, 033716, 032716, 02F716)
Bit 0 is the IIC mode select bit. When set to “1”, ports operate respectively as the SDAi data transmission-reception pin, SCLi clock I/O pin and port. A delay circuit is added to SDAi transmission output,
therefore after SCLi is sufficiently L level, SDAi output changes. Port (SCLi) is designed to read pin
level regardless of the content of the port direction register. SDAi transmission output is initially set to
port in this mode. Furthermore, interrupt factors for the bus collision detection interrupt, UARTi transmission interrupt and UARTi reception interrupt change respectively to the start/stop condition detection interrupts, acknowledge non-detection interrupt and acknowledge detection interrupt.
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UARTi Special Mode Register
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
The start condition detection interrupt is generated when the falling edge at the SDAi pin is detected
while the SCLi pin is in the H state. The stop condition detection interrupt is generated when the rising
edge at the SDAi pin is detected while the SCLi pin is in the H state.
The acknowledge non-detection interrupt is generated when the H level at the SDAi pin is detected at
the 9th rise of the transmission clock.
The acknowledge detection interrupt is generated when the L level at the SDAi pin is detected at the
9th rise of the transmission clock. Also, DMA transfer can be started when the acknowledge is detected and UARTi transmission is selected as the DMAi request factor.
Bit 1 is the arbitration lost detection flag control bit (ABC). Arbitration detects a conflict between data
transmitted at SCLi rise and data at the SDAi pin. This detection flag is allocated to bit 11 in UARTi
transmission buffer register (addresses 036F16, 02EF16, 033F16, 032F16, 02FF16). It is set to “1” when
a conflict is detected. With the arbitration lost detection flag control bit, it can be selected to update the
flag in units of bits or bytes. When this bit is set to “1”, update is set to units of byte. If a conflict is then
detected, the arbitration lost detection flag control bit will be set to “1” at the 9th rise of the clock. When
updating in units of byte, always clear (“0” interrupt) the arbitration lost detection flag control bit after
the 1st byte has been acknowledged but before the next byte starts transmitting.
Bit 2 is the bus busy flag (BBS). It is set to “1” when the start condition is detected, and reset to “0”
when the stop condition is detected.
Bit 3 is the SCLi L synchronization output enable bit (LSYN). When this bit is set to “1”, the port data
register is set to “0” in sync with the L level at the SCLi pin.
Bit 4 is the bus collision detection sampling clock select bit (ABSCS). The bus collision detection
interrupt is generated when RxDi and TxDi level do not conflict with one another. When this bit is “0”,
a conflict is detected in sync with the rise of the transfer clock. When this bit is “1”, detection is made
when timer Ai (timer A3 with UART0, timer A4 with UART1, timer A0 with UART2, timer A3 with
UART3 and timer A4 with UART4) underflows. Operation is shown in Figure 1.21.2.
Bit 5 is the transmission enable bit automatic clear select bit (ACSE). By setting this bit to “1”, the
transmission bit is automatically reset to “0” when the bus collision detection interrupt factor bit is “1”
(when a conflict is detected).
Bit 6 is the transmission start condition select bit (SSS). By setting this bit to “1”, TxDi transmission
starts in sync with the rise at the RxDi pin.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register
1. Bus collision detect sampling clock select bit (Bit 4 of the UARTi special mode register)
0: Rising edges of the transfer clock
CLKi
TxDi/RxDi
1: Timer Ai underflow
Timer Ai
2. Auto clear function select bit of transmit enable bit (Bit 5 of the UARTi special mode
register)
CLKi
TxDi/RxDi
Bus collision
detect interrupt
request bit
Transmit
enable bit
3. Transmit start condition select bit (Bit 6 of the UARTi special mode register)
0: In normal state
CLKi
TxDi
Enabling transmission
With "1: falling edge of RxDi" selected
CLKi
TxDi
RxDi
Figure 1.21.2. Some other functions added
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UARTi Special Mode Register
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register 2 (UiSMR2:Addresses 036616, 02E616, 033616, 032616, 02F616)
Bit 0 is the IIC mode select bit 2 (IICM2). Table 1.21.2 gives control changes by bit when the IIC mode
select bit is “1”. Start and stop condition detection timing characteristics are shown in Figure 1.21.4.
Always set bit 7 (start/stop condition control bit) to “1”.
Bit 1 is the clock synchronizing bit (CSC). When this bit is set to “1”, and the rising edge is detected at
pin SCLi while the internal SCL is High level, the internal SCL is changed to Low level, the baud rate
generator value is reloaded and the Low sector count starts. Also, while the SCLi pin is Low level, and
the internal SCL changes from Low level to High, baud rate generator stops counting. If the SCLi pin
is H level, counting restarts. Because of this function, the UARTi transmission-reception clock takes
the AND condition for the internal SCL and SCLi pin signals. This function operates from the clock half
period before the 1st rise of the UARTi clock to the 9th rise. To use this function, select the internal
clock as the transfer clock.
Bit 2 is the SCL wait output bit (SWC). When this bit is set to “1”, output from the SCLi pin is fixed to L
level at the clock’s 9th rise. When set to “0”, the Low output lock is released.
Bit 3 is the SDA output stop bit (ALS). When this bit is set to “1”, an arbitration lost is generated. If the
arbitration lost detection flag is “1”, then the SDAi pin simultaneously becomes high impedance.
Bit 4 is the UARTi initialize bit (STC). While this bit is set to “1”, the following operations are performed
when the start condition is detected.
1. The transmission shift register is initialized and the content of the transmission register is transmitted to the transmission shift register. As such, transmission starts with the 1st bit of the next
input clock. However, the UARTi output value remains the same as when the start condition was
detected, without changing from when the clock is input to when the 1st bit of data is output.
2. The reception shift register is initialized and reception starts with the 1st bit of the next input
clock.
3. The SCL wait output bit is set to “1”. As such, the SCLi pin becomes Low level at the rise of the
9th bit of the clock.
When UART transmission-reception has started using this function, the content of the transmission
buffer available flag does not change. Also, to use this function, select an external clock as the transfer
clock.
Bit 5 is SCL wait output bit 2 (SWC2). When this bit is set to “1” and serial I/O is selected, an Low level
can be forcefully output from the SCLi pin even during UART operation. When this bit is set to “0', the
Low output from the SCLi pin is canceled and the UARTi clock is input and output.
Bit 6 is the SDA output disable bit (SDHI). When this bit is set to “1”, the SDAi pin is forced to high
impedance. To overwrite this bit, do so at the rise of the UARTi transfer clock. The arbitration lost
detection flag may be set.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register
Table 1.21.2. Functions changed by I2C mode select bit 2
Function
IICM2 = 0
IICM2 = 1
Interrupt no. 17, 19, 33, 35, 37 factor
Acknowledge not detect
(NACK)
UARTi transfer (rising edge of the
last bit)
Interrupt no. 18, 20, 34, 36, 38 factor
Acknowledge detect (ACK)
UARTi receive (falling edge of the
last bit)
DMA factor
Acknowledge detect (ACK)
UARTi receive (falling edge of the
last bit)
Data transfer timing from UART receive shift register to receive buffer
Rising edge of the last bit of receive clock
Rising edge of the last bit of receive clock
UART receive / ACK interrupt request generation timing
Rising edge of the last bit of receive clock
Rising edge of the last bit of receive clock
3 to 6 cycles < set up time (Note)
3 to 6 cycles < hold time (Note)
Set up time
Hold time
SCL
SDA
(Start condition)
SDA
(Stop condition)
Note : Cycle number shows main clock input oscillation frequency f(XIN) cycle number.
Figure 1.21.3. Start/stop condition detect timing characteristics
UARTi Special Mode Register 3 (UiSMR3:Addresses 036516, 02E516, 033516, 032516, 02F516)
Bit 1 is clock phase set bit (CKPH). When both the IIC mode select bit (bit 0 of UARTi special mode
select register) and the IIC mode select bit 2 (bit 0 of UiSMR2 register) are "1", functions changed by
these bits are shown in table 1.21.3 and figure 1.21.4.
Bits 5 to 7 are SDAi digital delay setting bits (DL0 to DL2). By setting these bits, it is possible to turn the
SDAi delay OFF or set the BRG count source delay to 2 to 8 cycles.
Table 1.21.3. Functions changed by clock phase set bits
192
Function
CKPH = 0, IICM = 1, IICM2 = 1
CKPH = 1, IICM = 1, IICM2 = 1
SCL initial and last value
Initial value = H, last value = L
Initial value = L, last value = L
Transfer interrupt factor
Rising edge of 9th bit
Falling edge of 10th bit
Data transfer times from UART receive shift register to receive buffer
register
Falling edge of 9th bit
Two times :falling edge of 9th bit
and rising edge of 9th bit
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register
• CKPH= "0" (IICM=1, IICM2=1)
SCL
SDA
D7
D6
D5
D4
D3
D2
D1
D0
D8
(Internal clock, transfer data 9 bits long and MSB first selected.)
Receive interrupt
Transmit interrupt
Transfer to receive buffer
• CKPH= "1" (IICM=1, IICM2=1)
SCL
SDA
D7
D6
D5
D4
D3
D2
D1
D0
D8
(Internal clock, transfer data 9 bits long and MSB first selected.)
Receive interrupt
Transmit interrupt
Transfer to receive buffer
Figure 1.21.4. Functions changed by clock phase set bits
UARTi Special Mode Register 4 (UiSMR4:Addresses 036416, 02E416, 033416, 032416, 02F416)
Bit 0 is the start condition generate bit (STAREQ). When the SCL, SDA output select bit (bit 3 of
UiSMR4 register) is "1" and this bit is "1", then the start condition is generated.
Bit 1 is the restart condition generate bit (RSTAREQ). When the SCL, SDA output select bit (bit 3 of
UiSMR4 register) is "1" and this bit is "1", then the restart condition is generated.
Bit 2 is the stop condition generate bit (STPREQ). When the SCL, SDA output select bit (bit 3 of
UiSMR4 register) is "1" and this bit is "1", then the stop condition is generated.
Bit 3 is SCL, SDA output select bit (STSPSEL). Functions changed by these bits are shown in table
1.21.4 and figure 1.21.5.
Table 1.21.4. Functions changed by SCL, SDA output select bit
Function
STSPSEL = 0
STSPSEL = 1
SCL, SDA output
Output of SI/O control circuit
Output of start/stop condition
control circuit
Star/stop condition interrupt factor
Start/stop condition detection
Completion of start/stop condition
generation
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register
• When slave mode (CKDIR=0, STSPSEL=0)
SCL
SDA
Start condition detection
interrupt
Stop condition detection
interrupt
• When master mode (CKDIR=1, STSPSEL=1)
STSPSEL=0
STSPSEL=1
STSPSEL=0
STSPSEL=1 STSPSEL=0
SCL
SDA
STAREQ=1
Start condition detection
interrupt
STPREQ=1
Stop condition detection
interrupt
Figure 1.21.5 Functions changed by SCL, SDA output select bit
Bit 4 is ACK data bit (ACKD). When the SCL, SDA output select bit (bit 3 of UiSMR4 register) is "0"
and the ACK data output enable bit (bit 5 of UiSMR4 register) is "1", then the content of ACK data bit
is output to SDAi pin.
Bit 5 is ACK data output enable bit (ACKC). When the SCL, SDA output select bit (bit 3 of UiSMR4
register) is "0" and this bit is "1", then the content of ACK data bit is output to SDAi pin.
Bit 6 is SCL output stop bit (SCLHI). When this bit is "1", SCLi output is stopped at stop condition
detection. (Hi-impedance status).
Bit 7 is SCL wait output bit 3 (SWC9). When this bit is "1", SCLi output is fixed to "L" at falling edge of
10th bit of clock. When this bit is "0", SCLi output fixed to "L" is released.
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register
(2) Serial Interface Special Function
_____
UARTi can control communications on the serial bus using the SSi input pins (Figure 1.21.6). The master
outputting the transfer clock transfers data to the slave inputting the transfer clock. In this case, in order to
_____
prevent a data collision on the bus, the master floats the output pin of other slaves/masters using the SSi
input pins.
_____
SSi input pins function between the master and slave are as follows.
IC1
IC2
P13
P12
P93(SS3)
P93(SS3)
P90(CLK3)
P90(CLK3)
P91(RxD3)
P91(STxD3)
P92(TxD3)
P92(SRxD3)
M16C/80 (M)
M16C/80 (S)
IC3
P93(SS3)
P90(CLK3)
M :Master
S :Slave
P91(STxD3)
P92(SRxD3)
M16C/80 (S)
Figure 1.21.6. Serial bus communication control example using the SS input pins
< Slave Mode (STxDi and SRxDi are selected, DINC = 1) >
_____
When an H level signal is input to an SSi input pin, the STxDi and SRxDi pins both become high
_____
impedance, hence the clock input is ignored. When an "L" level signal is input to an SSi input pin, the
clock input becomes effective and serial communications are enabled.
< Master Mode (TxDi and RxDi are selected, DINC = 0) >
_____
_____
The SSi input pins are used with a multiple master system. When an SSi input pin is H level, transmis_____
sion has priority and serial communications are enabled. When an L signal is input to an SSi input pin,
another master exists, and the TxDi, RxDi and CLKi pins all become high impedance. Moreover, the
trouble error interrupt request bit becomes “1”. Communications do not stop even when a trouble error
is generated during communications. To stop communications, set bits 0, 1 and 2 of the UARTi transmission-reception mode register (addresses 036816, 02E816, 033816, 032816 and 02F816) to “0”.
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register
Clock Phase Setting
With bit 1 of UARTi special mode register 3 (UiSMR3:addresses 036516, 02E516, 033516, 032516,
02F516) and bit 6 of UARTi transmission-reception control register 0 (addresses 036C16, 02EC16,
033C16, 032C16, 02FC16), four combinations of transfer clock phase and polarity can be selected.
Bit 6 of UARTi transmission-reception control register 0 sets transfer clock polarity, whereas bit 1 of
UiSMR3 register sets transfer clock phase.
Transfer clock phase and polarity must be the same between the master and slave involved in the
transfer.
< Master (Internal Clock) (DINC = 0) >
Figure 1.21.7 shows the transmission and reception timing.
< Slave (External Clock) (DINC = 1) >
_____
• With “0” for CKPH bit (bit 1 of UiSMR3 register), when an SSi input pin is H level, output data is high
_____
impedance. When an SSi input pin is L level, the serial transmission start condition is satisfied,
though output is indeterminate. After that, serial transmission is synchronized with the clock. Figure
1.21.8 shows the timing.
_____
_____
• With “1” for CKPH bit, when an SSi input pin is H level, output data is high impedance. When an SSi
input pin is L level, the first data is output. After that, serial transmission is synchronized with the
clock.Figure 1.21.9 shows the thing.
"H"
Master SS input
"L"
"H"
Clock output
(CKPOL=0, CKPH=0) "L"
"H"
Clock output
(CKPOL=1, CKPH=0) "L"
Clock output
"H"
(CKPOL=0, CKPH=1) "L"
"H"
Clock output
(CKPOL=1, CKPH=1) "L"
Data output timing
"H"
"L"
D0
D1
D2
D3
D4
D5
D6
Data input timing
Figure 1.21.7. The transmission and reception timing in master mode (internal clock)
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
UARTi Special Mode Register
"H"
SS input
"L"
"H"
Clock input
(CKPOL=0, CKPH=0) "L"
"H"
Clock input
(CKPOL=1, CKPH=0) "L"
Data output timing
"H"
(Note)
"L"
Data input timing
D0
D1
D2
D3
D4
D5
D6
D7
Highinpedance
Highinpedance
Indeterminate
Note :UART2 output is an N-channel open drain and needs to be pulled-up externally.
Figure 1.21.8. The transmission and reception timing (CKPH=0) in slave mode (external clock)
"H"
SS input
"L"
"H"
Clock input
(CKPOL=0, CKPH=0) "L"
"H"
Clock input
(CKPOL=1, CKPH=0) "L"
Data output timing
(Note)
"H"
"L"
D0
D1
D2
D3
D4
D5
D6
D7
Highinpedance
Highinpedance
Data input timing
Note :UART2 output is an N-channel open drain and needs to be pulled-up externally.
Figure 1.21.9. The transmission and reception timing (CKPH=1) in slave mode (external clock)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN Module
The microcomputer incorporates Full-CAN modules compliant with CAN (Controller Area Network) 2.0B
specification.
These Full-CAN modules are outlined below.
Table 1.22.1 Outline of the CAN module
Item
Protocol
Number of message slots
Polarity
Acceptance filter
Baud rate
Remote frame automatic
answering function
Timestamp function
BasicCAN mode
Transmit abort function
Loopback function
Return from bus-off function
Description
Compliant with CAN 2.0B specification
16 slots
0: Dominant
1: Recessive
Global mask: 1 mask (for message slots 0–13)
Local mask: 2 masks (for message slots 14 and 15 each)
1 time quantum (Tq) = (BRP + 1) / CPU clock (Note)
(BRP = baud rate prescaler set value)
Baud rate = 1 / (Tq period x number of Tq’s in one bit) ---Max. 1 Mbps
BRP: 1-255 (0: Inhibited)
Number of Tq’s in one bit =
Synchronization Segment +
Propagation Time Segment +
Phase Buffer Segment 1 +
Phase Buffer Segment 2
Synchronization Segment
: 1 Tq (fixed)
Propagation Time Segment
: 1 to 8 Tq
Phase Buffer Segment 1
: 2 to 8 Tq
Phase Buffer Segment 2
: 2 to 8 Tq
The message slot that received a remote frame automatically transmits it.
This timestamp function is based on a 16-bit counter. A count period can
be derived from the CAN bus bit period (as the fundamental period) by
dividing it by 1, 2, 3, or 4.
The BasicCAN function is realized by using message slots 14 and 15.
This function is used to cancel a transmit request.
The data the CAN module itself transmitted is received.
Forcibly placed into an error active state from a bus-off state.
Note: Use a specification conforming resonator whose maximum permissible error of oscillation is not
greater than 1.58%
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
Data bus
Sleep control
register
Baud rate
prescaler
BCLK
Control register
Global
mask register
Configuration
register
Local
mask register A
Expansion ID
register
Local
mask register B
Error interrupt
mask register
Message
slot buffer 0
Slot interrupt
mask register
Slot interrupt
status register
Acceptance
filter support
register
Status
register
Slot buffer
select register
Message slot 0
control register
Error interrupt
status register
Transmit error
count register
Receive error
count register
Message
slot 0
Acceptance
Filter
CANOUT
CANIN
CAN protocol
controller
Ver 2.0B
16 bits timer
Time stamp
register
Message box
(slot 0 to 15)
Interrupt
control circuit
Interrupt request
Figure 1.22.1 CAN module blobk diagram
CAN0 message slot buffer 0 and 1 can be selected by setting of slot buffer select register. Figure 1.22.2
shows the message slot buffer and 16 bytes of message slots. Figure 1.22.26 to 1.22.30 show related
registers.
CAN0 message slot buffer 0 (addresses 01E016 to 01EF16)
CAN0 message slot buffer 1 (addresses 01F016 to 01FF16)
CAN0 message slot buffer 0 standard ID0
CAN0 message slot buffer 0 standard ID1
CAN0 message slot buffer 0 standard ID0
CAN0 message slot buffer 0 extend ID0
CAN0 message slot buffer 0 standard ID1
CAN0 message slot buffer 0 extend ID1
CAN0 message slot buffer 0 extended ID0
CAN0 message slot buffer 0 extend ID2
CAN0 message slot buffer 0 extended ID1
CAN0 message slot buffer 0 data length code
CAN0 message slot buffer 0 extended ID2
CAN0 message slot buffer 0 data 0
CAN0 message slot buffer 0 data length code
CAN0 message slot buffer 0 data 1
CAN0 message slot buffer 0 data 0
CAN0 message slot buffer 0 data 2
CAN0 message slot buffer 0 data 1
CAN0 message slot buffer 0 data 3
CAN0 message slot buffer 0 data 2
CAN0 message slot buffer 0 data 4
CAN0 message slot buffer 0 data 3
CAN0 message slot buffer 0 data 5
CAN0 message slot buffer 0 data 4
CAN0 message slot buffer 0 data 6
CAN0 message slot buffer 0 data 5
CAN0 message slot buffer 0 data 7
CAN0 message slot buffer 0 data 6
CAN0 message slot buffer 0 time stamp high
CAN0 message slot buffer 0 data 7
CAN0 message slot buffer 0 time stamp low
CAN0 message slot buffer 0 time stamp high
CAN0 message slot buffer 1 time stamp low
CAN0 message slot 0 to 15
CAN0 message slot 0 standard ID0
CAN0 message slot 0 standard ID1
CAN0 CAN0
message
slot 0 extend
ID00 standard ID0
message
slot buffer
CAN0 CAN0
message
slot 0 extend
ID10 standard ID1
message
slot buffer
CAN0 CAN0
message
slot 0 extend
ID20 extended ID0
message
slot buffer
CAN0 CAN0
message
slot 0 data
length0code
message
slot buffer
extended ID1
CAN0 CAN0
message
slot 0 data
0
message
slot buffer
0 extended ID2
CAN0 CAN0
message
slot 0 data
1
message
slot buffer
0 data length code
CAN0 CAN0
message
slot 0 data
2
message
slot buffer
0 data 0
CAN0 CAN0
message
slot 0 data
3
message
slot buffer
0 data 1
CAN0 CAN0
message
slot 0 data
4
message
slot buffer
0 data 2
CAN0 CAN0
message
slot 0 data
5
message
slot buffer
0 data 3
CAN0 CAN0
message
slot 0 data
6
message
slot buffer
0 data 4
CAN0 CAN0
message
slot 0 data
7
message
slot buffer
0 data 5
CAN0 CAN0
message
slot 0 time
stamp0high
message
slot buffer
data 6
CAN0 CAN0
message
slot 0 time
stamp0low
message
slot buffer
data 7
CAN0 message slot 15 time stamp low
Figure 1.22.2. Message slot buffer and message slots
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 control register 0
b15
(b7)
b8
(b0)b7
b0
0
Symbol
Address
When reset (Note 1)
C0CTLR0
020116, 020016
XXXX 0000 XX01 0X012
Bit
symbol
Reset 0
Loopback
Bit name
R W
Function
CAN reset bit 0
0: Reset released
1: Reset requested
Loop back mode
select bit
0: Loop back function disabled
1: Loop back function enabled
Nothing is assigned. When write, set to "0".
When read, its contents is indeterminate.
BasicCAN
Reset 1
Basic CAN mode
select bit
0 : Basic CAN mode function disabled
1 : Basic CAN mode function enabled
CAN reset bit 1
0 : Reset released
1 : Reset requested
Reserved bit
Must set to "0".
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
b9 b8
Time stamp
prescaler select bit
0 0: CAN bus bit clock is selected
TSReset
Time stamp
counter reset bit
0 : Count enabled
1 : Count reset (set 000016)
(Note 2)
ECReset
Error counter
reset bit
0 : Normal operation mode
1 : Error counter reset
(Note 2)
TSPre0
TSPre1
0 1: Division by 2 of CAN bus bit clock is selected
1 0: Division by 3 of CAN bus bit clock is selected
1 1: Division by 4 of CAN bus bit clock is selected
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note 1: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Note 2: Only writing 1 is accepted. The bit is automatically cleared to 0 in hardware.
Figure 1.22.3 CAN0 control register 0
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CAN Module
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
1. CAN0 control register 0
Bit 0: CAN reset bits 0 and 1 (Reset0 and Reset1)
If the Reset0 and Reset1 bits both are set from 1 to 0, CAN communication is enabled after detecting
11 consecutive recessive bits. The CAN Timestamp Register starts counting at the same time communication is enabled.
In no case will the CAN be reset unless transmission of all messages are completed.
Note 1: Reset0 and Reset1 bits must both be cleared to "0" or set to "1" simutnously.
Note 2: Setting a new transmit request is inhibited before the CAN Status Register State_Reset bit is
set to 1 and the CAN module is reset after setting the Reset0 and Reset1 bits to 1.
Note 3: When the CAN module is reset by setting the Reset0 and Reset1 bits to 1, the CAN
Timestamp Register (C0TSR), CAN Transmit Error Counter (C0TEC), and CAN Receive
Error Counter (C0REC) are initialized to 0.
Note 4: If Reset0 and Reset1 bits sre set to "1" during communication, the CANOUT pin output goes
"H" immediately after that. Therefore, setting these bits to 1 while the CAN module is sending
a frame may cause a CAN bus error.
Note 5: To CAN communication, function select register A1 (PS1), function select register A2 (PS2),
function select register B1 (PSL1), function select register B2 (PSL2), function select register
C (PSC) and input function select register (IPS) must be set. These registers must be set
when CAN module is reset.
Bit 1: Loopback mode select bit (LoopBack)
Setting the LoopBack bit to 1 enables loopback mode, so that if any receive slot whose ID matches
that of a frame the CAN module itself transmitted exists, the frame is received.
Note 1: ACK is not returned for the transmit frame.
Note 2: Do not set or reset the LoopBack bit while the CAN module is operating (CAN Status Register
State_Reset bit = 0).
Bit 3: BasicCAN mode select bit (BasicCAN)
If this bit is set to 1, message slots 14 and 15 operate in BasicCAN mode.
• Operation during BasicCAN mode
In BasicCAN mode, message slots 14 and 15 are used with a dual-structured buffer. The received
frames whose IDs are found matching by acceptance filtering are stored in slots 14 and 15 alternately. When slot 14 is active (i.e., the next received frame is to be stored in slot 14), this acceptance
filtering is accomplished using the ID that is set in slot 14 and local mask A; when slot 15 is active, it
is accomplished using the ID that is set in slot 15 and local mask B. Frame types of both data frame
and remote frame can be received.
When using BasicCAN mode, setting the IDs of two slots and the mask registers the same way helps
to reduce the possibility of causing an overrun error.
• Procedure for entering BasicCAN mode
Make the following settings during initialization.
(1) Set the BasicCAN bit to 1.
(2) Set the IDs of slots 14 and 15 and Local Mask Registers A and B. (We recommend setting the
same value)
(3) Set the frame format to be handled with slots 14 and 15 (standard or extended) in the CAN
Extended ID Register. (We recommend setting the same format)
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CAN Module
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
(4) Set the Message Slot Control Registers for slots 14 and 15 to receive data frames.
Note 1: Do not set or reset the BasicCAN bit while the CAN module is operating (CAN Status Register State_Reset bit = 0).
Note 2: Slot 14 is the first slot to become active after clearing the Reset0 bit.
Note 3: Even during BasicCAN mode, slot 0 through slot 13 can be used in the same way as when
operating normally.
Bit 8, 9: Timestamp prescaler select bits (TSPre0, 1)
These bits select the count clock source for the timestamp counter.
Note 1: Do not set or reset these TSPre0, 1 bits while the CAN module is operating (CAN Status
Register State_Reset bit = 0).
Bit 10: Timestamp counter reset bit (TSReset)
Setting this bit to 1 clears the value of the CAN Timestamp Register (C0TSR) to 000016. This bit is
automatically cleared after the CAN Timestamp Register (C0TSR) has its value cleared to 000016.
Bit 11: Error counter reset bit (ECReset)
Setting this bit to 1 clears the Receive Error Counter Register (C0REC) and Transmit Error Counter
Register (C0TEC), with the CAN module forcibly placed in an error active state. This bit is automatically cleared upon entering an error active state.
Note 1: When in an error active state, the CAN module becomes ready to communicate when it
detects 11 consecutive recessive bits on the CAN bus.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 control register 1
b7
b0
0 0
0
Symbol
Address
When reset (Note)
C0CTLR1
024116
XX0000XX2
Bit
symbol
Bit name
Function
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
BankSel
Reserved bit
Must set to "0".
CAN0 bank select bit
0 : Message slot control register
selected
1 : Mask register selected
Reserved bit
Must set to "0".
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.4. CAN0 control register 1
2. CAN0 control register 1
Bit 3: CAN0 bank select bit (BankSel)
This bit selects between registers allocated to the addresses 022016 through 023F16.
Setting the BankSel bit to 0 selects the CAN0 Message Slot Control Register. Setting the BankSel bit
to 1 selects the CAN0 Mask Register.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 sleep control register
b7
b0
Symbol
Address
When reset
C0SLPR
024216
XXXXXXX02
Bit
symbol
Sleep
Bit name
Sleep mode control bit
Function
0 : Sleep mode On
1 : Sleep mode Off
R W
(Note)
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: After CAN sleep mode is canceled, set up the CAN configuration. While the CAN module is in sleep
mode, no SFR registers for the CAN, except the sleep mode control register, can be accessed for
read or write.
Figure 1.22.5. CAN0 sleep control register
3. CAN0 sleep control register
Bit 0: Sleep mode control bit (Sleep)
The CAN module isn't supplied with a clock by setting the Sleep bit to 0, and is shifted to sleep mode.
The CAN module is supplied with a clock by setting the Sleep bit to 1, and is released from sleep
mode.
Note: Sleep mode can be shifted to only after CAN is reset (State_Reset bit = 1).
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 status register
b15
(b7)
b8
(b0)b7
b0
Symbol
C0STR
Bit
symbol
Address
020316,020216
Bit name
Function
R W
b3 b2 b1 b0
MBox0
MBox1
When reset (Note)
X000 0X01 0000 00002
Active slot
determination bit
MBox2
MBox3
0
0
0
0
0
0
0
1
0
1
1
0
•
•
1 1 0
1 1 1
1 1 1
0 : Slot 0
0 : Slot 1
1 : Slot 2
0 : Slot 3
•
•
1 : Slot 13
0 : Slot 14
1 : Slot 15
TrmSucc
Transmission-finished
status
0: Transmission not finished
1: Transmission finished
RecSucc
Reception-finished
status
0: Reception not finished
1: Reception finished
TrmState
Transmission status
0: Not transmitting
1: Transmitting
RecState
Reception status
0: Not receiving
1: Receiving
State_Reset
CAN reset status
0: Operating
1: Reset
State_LoopBack Loop back status
0: Normal mode
1: Loop back mode
Nothing is assigned. When write, set to "0".
When read, its content is indeterminate.
State_BasicCAN Basic CAN status
0: Normal mode
1: Basic CAN mode
State_BusError
CAN bus error
0: No error occurred
1: Error occurred
State_ErrPas
Error passive status
0: Not error passive state
1: Error passive state
State_BusOff
Bus-off status
0: Not bus-off state
1: Bus-off state
Nothing is assigned. When write, set to "0".
When read, its content is indeterminate.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.6. CAN0 status register
4. CAN0 status register
Bits 0–3: Active slot determination bits (MBox)
When the CAN module finished transmitting data or finished storing received data, the relevant slot
number is stored in these bits.
The MBox bits cannot be cleared to 0 in software.
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CAN Module
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bit 4: Transmission-finished status (TrmSucc)
[Set condition]
This bit is set to 1 when the CAN module finished transmitting data normally.
[Clear condition]
This bit is cleared when the CAN module finished receiving data normally.
Bit 5: Reception-finished status (RecSucc)
[Set condition]
This bit is set to 1 when the CAN module finished receiving data normally (regardless of whether the
received message has been stored in a message slot). However, this bit is not set if the received
message is one that was transmitted in loopback mode.
[Clear condition]
This bit is cleared when the CAN module finished transmitting data normally.
Bit 6: Transmission status (TrmState)
[Set condition]
This bit is set to 1 when the CAN module is operating as a transmit node.
[Clear condition]
This bit is cleared when the CAN module goes to a bus-idle state or starts operating as a receive
node.
Bit 7: Reception status (RecState)
[Set condition]
This bit is set to 1 when the CAN module is operating as a receive node.
[Clear condition]
This bit is cleared when the CAN module goes to a bus-idle state or starts operating as a transmit
node.
Bit 8: CAN reset status (State_Reset)
When the State_Reset bit = 1, it means that the CAN module is in a reset state.
[Set condition]
This bit is set to 1 when CAN module is in a reset state.
[Clear condition]
This bit is cleared by clearing the Reset0 or Reset1 bits to 0.
Bit 9: Loopback status (State_loopBack)
When the State_loopBack bit = 1, it means that the CAN module is operating in loopback mode.
[Set condition]
This bit is set to 1 by setting the CAN control register LoopBack bit to 1.
[Clear condition]
This bit is cleared by clearing the LoopBack bit to 0.
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CAN Module
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bit 11: BasicCAN status (State_BasicCAN)
When the State_BasicCAN bit = 1, it means that the CAN module is operating in BasicCAN mode.
[Set condition]
This bit is set to 1 when the CAN module is operating in BasicCAN mode.
Conditions for the CAN module to operate in BasicCAN mode are as follows:
• The CAN Control Register BasicCAN bit is set to 1.
• Slots 14 and 15 both are set for data frame reception.
[Clear condition]
This bit is cleared by clearing the BasicCAN bit to 0.
Bit 12: CAN bus error (State_BusError)
[Set condition]
This bit is set to 1 when an error on the CAN bus is detected.
[Clear condition]
This bit is cleared when the CAN module finished transmitting or receiving normally. Clearing of this
bit does not depend on whether the received message has been stored in a message slot.
Note :When this bit is 1, although CAN module is reset, this bit does not become to 0.
Bit 13: Error passive status (State_ErrPas)
When the State_ErrPas bit = 1, it means that the CAN module is in an error-passive state.
[Set condition]
This bit is set to 1 when the value of C0TEC register or C0REC register exceeds 127, with the CAN
module in an error-passive state.
[Clear condition]
This bit is cleared when the CAN module goes from the error-passive state to any other error state.
Note :When this bit is 1, then CAN module is reset, this bit becomes 0 automatically.
Bit 14: Bus-off status (State_BusOff)
When the State_BusOff bit = 1, it means that the CAN module is in a bus-off state.
[Set condition]
This bit is set to 1 when the value of the C0TEC register exceeds 255, with the CAN module in a busoff state.
[Clear condition]
This bit is cleared when the CAN module returns from the bus-off state.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 extended ID register
b15
(b7)
b8
(b0)b7
b0
Symbol
C0IDR
Address
020516,020416
When reset (Note)
000016
Bit
symbol
Bit name
IDE15
Expansion ID15 (slot 15)
0: Standard ID format
1: Extended ID format
IDE14
Expansion ID14 (slot 14)
0: Standard ID format
1: Extended ID format
IDE13
Expansion ID13 (slot 13)
0: Standard ID format
1: Extended ID format
IDE12
Expansion ID12 (slot 12)
0: Standard ID format
1: Extended ID format
IDE11
Expansion ID11 (slot 11)
0: Standard ID format
1: Extended ID format
IDE10
Expansion ID10 (slot 10)
0: Standard ID format
1: Extended ID format
IDE9
Expansion ID9 (slot 9)
0: Standard ID format
1: Extended ID format
IDE8
Expansion ID8 (slot 8)
0: Standard ID format
1: Extended ID format
IDE7
Expansion ID7 (slot 7)
0: Standard ID format
1: Extended ID format
IDE6
Expansion ID6 (slot 6)
0: Standard ID format
1: Extended ID format
IDE5
Expansion ID5 (slot 5)
0: Standard ID format
1: Extended ID format
IDE4
Expansion ID4 (slot 4)
0: Standard ID format
1: Extended ID format
IDE3
Expansion ID3 (slot 3)
0: Standard ID format
1: Extended ID format
IDE2
Expansion ID2 (slot 2)
0: Standard ID format
1: Extended ID format
IDE1
Expansion ID1 (slot 1)
0: Standard ID format
1: Extended ID format
IDE0
Expansion ID0 (slot 0)
0: Standard ID format
1: Extended ID format
Function
R W
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.7. CAN0 extended ID register
5. CAN0 extended ID register
This register selects the format of a frame handled by the message slot that corresponds to each bit
in this register.
Setting any bit to 0 selects the standard (Standard ID) format.
Setting any bit to 1 selects the extended (Extended ID) format.
Note 1: When setting or resetting any bit in this register, make sure the corresponding slot has no
transmit or receive request.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 configuration register
b15
(b7)
b8
(b0)b7
b0
0
Symbol
Address
When reset (Note)
C0CONR
020716,020616
000X16
Bit
symbol
Bit name
Function
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
SAM
Sampling number
0: Sampled once
1: Sampled three times
b7 b6 b5
PTS0
PTS1
Propagation Time
Segment
PTS2
0 0 0: Propagation Time Segment = 1Tq
0 0 1: Propagation Time Segment = 2Tq
0 1 0: Propagation Time Segment = 3Tq
0 1 1: Propagation Time Segment = 4Tq
1 0 0: Propagation Time Segment = 5Tq
1 0 1: Propagation Time Segment = 6Tq
1 1 0: Propagation Time Segment = 7Tq
1 1 1: Propagation Time Segment = 8Tq
b10 b9 b8
PBS10
PBS11
Phase Buffer
Segment 1
PBS12
0 0 0: Must not be set
0 0 1: Phase Buffer Segment 1 = 2Tq
0 1 0: Phase Buffer Segment 1 = 3Tq
0 1 1: Phase Buffer Segment 1 = 4Tq
1 0 0: Phase Buffer Segment 1 = 5Tq
1 0 1: Phase Buffer Segment 1 = 6Tq
1 1 0: Phase Buffer Segment 1 = 7Tq
1 1 1: Phase Buffer Segment 1 = 8Tq
b13 b12 b11
PBS20
PBS21
Phase Buffer
Segment 2
PBS22
SJW0
0 0 0: Must not be set
0 0 1: Phase Buffer Segment 2 = 2Tq
0 1 0: Phase Buffer Segment 2 = 3Tq
0 1 1: Phase Buffer Segment 2 = 4Tq
1 0 0: Phase Buffer Segment 2 = 5Tq
1 0 1: Phase Buffer Segment 2 = 6Tq
1 1 0: Phase Buffer Segment 2 = 7Tq
1 1 1: Phase Buffer Segment 2 = 8Tq
b15 b14
reSynchronization
Jump Width
SJW1
0 0: SJW = 1Tq
0 1: SJW = 2Tq
1 0: SJW = 3Tq
1 1: SJW = 4Tq
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.8. CAN0 configuration register
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CAN Module
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
6. CAN0 configuration register
Bit 4: SAM bit (SAM)
This bit sets the sampling number per one bit.
0: The value sampled at the last of the Phase Buffer Segment 1 becomes the bit value.
1: The bit value is determined by the majority operation circuit using values sampled at the following
three points: the last of the Phase Buffer Segment 1, before 1Tq, and before 2Tq.
Bits 5–7: PTS bits (RTS00-RTS02)
These bits set the width of Propagation Time Segment.
Bits 8–10: PBS1 bits (PBS10-PBS12)
These bits set the width of Phase Buffer Segment 1. The PBS1 bits must be set to 1 or greater.
Bits 11–13: PBS2 bits (PBS20-PBS22)
These bits set the width of Phase Buffer Segment 2. The PBS2 bits must be set to 1 or greater.
Bits 14, 15: SJW bits (SJW0, SJW1)
These bits set the width of reSynchronization Jump Width. The SJW bits must be set to a value equal
to or less than PBS2.
Table 1.22.2 Bit Timing Setup Example when the CPU Clock = 30 MHz
Baud rate
BRP
Tq period (ns) 1 bit's Tq number PTS+PBS1
1Mbps
1
66.7
15
12
1
66.7
15
11
1
66.7
15
10
2
100
10
7
2
100
10
6
2
100
10
5
500Kbps
2
100
20
16
2
100
20
15
2
100
20
14
3
133.3
15
12
3
133.3
15
11
3
133.3
15
10
4
166.7
12
9
4
166.7
12
8
4
166.7
12
7
5
200
10
7
5
200
10
6
5
200
10
5
210
PBS2
2
3
4
2
3
4
3
4
5
2
3
4
2
3
4
2
3
4
Sample point
87%
80%
73%
80%
70%
60%
85%
80%
75%
87%
80%
73%
83%
75%
67%
80%
70%
60%
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 time stamp register
b15
(b7)
b8
(b0)b7
(Upper 8-bit)
b0
Symbol
C0TSR
(Lower 8-bit)
Address
020916,020816
When reset (Note)
000016
Function
Setting range
R W
000016 to FFFF16
16 bits count value
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.9. CAN0 time stamp register
7. CAN0 Timestamp register
The CAN module incorporates a 16-bit counter. The count period for this counter can be derived
from the CAN bus bit period by dividing it by 1, 2, 3, or 4 using the CAN0 control register0
(C0CTLR0)’s TSPre0, 1 bits.
When the CAN module finishes transmitting or receiving, the CAN0 Timestamp Register (C0TSR)
value is captured and the value is automatically stored in a message slot.
The C0TSR register starts counting upon clearing the C0CTLR register’s Reset and Reset1 bits to 0.
Note 1: Setting the C0CTLR0 register’s Reset0 and Reset1 bits to 1 resets CAN, and the C0TSR
register thereby initialized to 000016. Also, setting the TSReset (timestamp counter reset) bit
to 1 initializes the C0TSR register to 000016 on-the-fly (while the CAN remains operating;
CAN0 status register's State_Reset bit is "0").
Note 2: During loopback mode, if any receive slot exists in which a message can be stored, the
C0TSR register value is stored in the corresponding slot when the CAN module finished
receiving. (This storing of the C0TSR register value does not occur at completion of transmission.)
CAN0 transmit error count register
b7
b0
8-bit
Symbol
Address
When reset (Note)
C0TEC
020A16
0016
Function
R W
Transmit error count value
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.10. CAN0 transmit error count register
8. CAN0 transmit error count register
When in an error active or an error passive state, the transmit error count value is stored in this
register. The count is decremented when the CAN module finished transmitting normally or
incremented when an error occurred while transmitting.
When in a bus-off state, an indeterminate value is stored in this register. The register is reset to 0016
upon returning to an error active state.
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 reception error count register
b7
b0
8-bit
Symbol
C0REC
Address
020B16
When reset (Note)
0016
Function
R W
Reception error count value
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.11. CAN0 reception error count register
9. CAN0 reception error count register
When in an error active or an error passive state, the receive error count value is stored in this
register. The count is decremented when the CAN module finished receiving normally or incremented
when an error occurred while receiving.
When C0REC > 128 (error passive state) at the time the CAN module finished receiving normally, the
C0REC register is set to 127.
When in a bus-off state, an indeterminate value is stored in this register. The register is reset to 0016
upon returning to an error active state.
CAN0 baud rate prescaler
b7
b0
8-bit
Symbol
C0BRP
Address
021716
Function
Baud rate prescaler value selected
When reset (Note 1)
0116
Setting range
R W
0116 to FF16
(Note 2)
Note 1: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Note 2: Do not set to "0016" (division by 1).
Figure 1.22.12. CAN0 baud rate register
10. CAN0 baud rate prescaler
This register is used to set the Tq period, the CAN bit time. The CAN baud rate is determined by (Tq
period x number of Tq’s in one bit).
Tq period = (C0BRP+1)/CPU clock
CAN baud rate = 1 / (Tq period x number of Tq’s in one bit)
Number of Tq’s in one bit = Synchronization Segment +
Propagation Time Segment +
Phase Buffer Segment 1 +
Phase Buffer Segment 2
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 slot interrupt status register
b15
(b7)
b8
(b0)b7
b0
Symbol
C0SISTR
Bit
symbol
Address
020D16,020C16
When reset (Note 1)
000016
Bit name
R W
Function
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS14
Slot 14 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS13
Slot 13 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS12
Slot 12 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS11
Slot 11 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
Slot 10 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS9
Slot 9 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS8
Slot 8 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS7
Slot 7 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS6
Slot 6 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS5
Slot 5 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS4
Slot 4 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS3
Slot 3 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS2
Slot 2 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
Slot 1 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
Slot 0 interrupt
request status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
SIS15
SIS10
SIS1
SIS0
Slot 15 interrupt
Note 1: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Note 2: "0" can be set. When set to "1", the previous value is remained.
Figure 1.22.13. CAN slot interrupt status register
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CAN Module
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
9. CAN0 slot interrupt status register
When using CAN interrupts, the CAN0 Slot Interrupt Status Register helps to know which slot requested
an interrupt.
• For transmit slots
The status is set to 1 when the CAN module finished storing the CAN Timestamp Register value in
the message slot after completing transmission.
To clear this bit, write 0 in software (Note 1).
• For receive slots
The status is set to 1 when the CAN module finished storing the received message in the message
slot after completing reception.
To clear this bit, write 0 in software (Note 1).
Note 1: To clear any bit of the CAN Interrupt Status Register, write 0 to the bit to be cleared and 1 to
all other bits, without using bit clear instructions.
Example : Assembler language
mov.w #07FFFh, C0SISTR
C language
c0sister = 0x7FFF;
Note 2: For remote frame receive slots whose automatic answering function is enabled, the slot
interrupt status bit is set when the CAN module finished receiving a remote frame and when
it finished transmitting a data frame.
Note 3: For remote frame transmit slots, the slot interrupt status bit is set when the CAN module
finished transmitting a remote frame and when it finished receiving a data frame.
Note 4: If the slot interrupt status bit is set by an interrupt request at the same time it is cleared by
writing in software, the former has priority, i.e., the slot interrupt status bit is set.
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 slot interrupt mask register
b15
(b7)
b8
(b0)b7
b0
Symbol
C0SIMKR
Bit
symbol
Address
021116,021016
Bit name
When reset (Note)
000016
Function
SIM15
Slot 15 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM14
Slot 14 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM13
Slot 13 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM12
Slot 12 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM11
Slot 11 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM10
Slot 10 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM9
Slot 9 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM8
Slot 8 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM7
Slot 7 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM6
Slot 6 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM5
Slot 5 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM4
Slot 4 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM3
Slot 3 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM2
Slot 2 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM1
Slot 1 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
SIM0
Slot 0 interrupt
request mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
R W
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.14. CAN0 slot interrupt mask register
12. CAN0 slot interrupt mask register
This register controls CAN interrupts by enabling or disabling interrupt requests generated by each
corresponding slot at completion of transmission or reception. Setting any bit of this register (SIMn
where n = 0–15) to 1 enables the interrupt request to be generated by the corresponding slot at
completion of transmission or reception.
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 error interrupt mask register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0EIMKR
Bit
symbol
Address
021416
Bit name
When reset (Note)
XXXX X0002
Function
BOIM
Bus off interrupt
mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
EPIM
Error passive interrupt
mask bit
0: Interrupt request masked (disabled)
1: Interrupt request enabled
BEIM
CAN bus error interrupt 0: Interrupt request masked (disabled)
1: Interrupt request enabled
mask bit
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.15. CAN0 error interrupt mask register
13. CAN0 error interrupt mask register
Bit 0: Bus-off interrupt mask bit (BOIM)
This bit controls CAN interrupts by enabling or disabling interrupt requests generated when the CAN
module goes to a bus-off state. Setting this bit to 1 enables a bus-off interrupt request.
Bit 1: Error passive interrupt mask bit (EPIM)
This bit controls CAN interrupts by enabling or disabling interrupt requests generated when the CAN
module goes to an error passive state. Setting this bit to 1 enables an error passive interrupt request.
Bit 2: CAN bus error interrupt mask bit (BEIM)
This bit controls CAN interrupts by enabling or disabling interrupt requests generated by occurrence
of a CAN bus error. Setting this bit to 1 enables a CAN bus error interrupt request.
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 error interrupt status register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0EISTR
Bit
symbol
Address
021516
When reset (Note 1)
XXXX X0002
Bit name
Function
R W
BOIS
Bus off interrupt
status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
EPIS
Error passive interrupt
status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
BEIS
CAN bus error interrupt
status bit
0: Interrupt not requested
1: Interrupt requested
(Note 2)
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note 1: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Note 2: "0" can be set. When set to "1", the previous value is remained.
Figure 1.22.16. CAN0 error interrupt status register
14. CAN0 error interrupt status register
When using CAN interrupts, the CAN Error Interrupt Status Register helps to verify the causes of
error-derived interrupts.
Bit 0: Bus-off interrupt status bit (BOIS)
This bit is set to 1 when the CAN module goes to a bus-off state.
To clear this bit, write 0 in software (Note 1).
Bit 1: Error passive interrupt status bit (EPIS)
This bit is set to 1 when the CAN module goes to an error passive state.
To clear this bit, write 0 in software (Note 1).
Bit 2: CAN bus error interrupt status bit (BEIS)
This bit is set to 1 when a CAN communication error is detected.
To clear this bit, write 0 in software (Note 1).
Note 1: To clear any bit of the CAN Error Interrupt Status Register, write 0 to the bit to be cleared and
1 to all other bits, without using bit clear instructions.
Example: Assembler language
mov.B #006h, C0EISTR
C language
c0eistr = 0x06;
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
C0SISTR
C0SIMKR
Slot 15 transmit/receive finished
Data bus
b0
SIS15
F/F
b0
SIM15
F/F
19-source inputs
(Level)
CAN0 transmit/ receive
error interrupt
Slot 14 transmit/receive finished
b1
SIS14
F/F
b1
SIM14
F/F
Slot 13 transmit/receive finished
b2
SIS13
F/F
b2
SIM13
F/F
Slot 12 transmit/receive finished
b3
SIS12
F/F
b3
SIM12
F/F
Slot 11 transmit/receive finished
b4
SIS11
F/F
b4
SIM11
F/F
Slot 10 transmit/receive finished
b5
SIS10
F/F
b5
SIM10
F/F
Slot 9 transmit/receive finished
b6
SIS9
F/F
b6
SIM9
F/F
Slot 8 transmit/receive finished
b7
SIS8
F/F
b7
SIM8
F/F
To 11 other input sources on the next page
Figure 1.22.17. CAN0 transmit, receive and error interrupt block diagram (1/3)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
C0SISTR
C0SIMKR
Slot 7 transmit/receive finished
Data bus
b8
SIS7
F/F
b8
SIM7
F/F
19-source inputs
To previous page
(Level)
Slot 6 transmit/receive finished
b9
SIS6
F/F
b9
SIM6
F/F
Slot 5 transmit/receive finished
b10
SIS5
F/F
b10
SIM5
F/F
Slot 4 transmit/receive finished
b11
SIS4
F/F
b11
SIM4
F/F
Slot 3 transmit/receive finished
b12
SIS3
F/F
b12
SIM3
F/F
Slot 2 transmit/receive finished
b13
SIS2
F/F
b13
SIM2
F/F
Slot 1 transmit/receive finished
b14
SIS1
F/F
b14
SIM1
F/F
Slot 0 transmit/receive finished
b15
SIS0
F/F
b15
SIM0
F/F
To 3 other input sources on the next page
Figure 1.22.18. CAN0 transmit, receive and error interrupt block diagram (2/3)
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
C0EISTR
C0EIMKR
CAN bus error occur
Data bus
b2
BEIS
F/F
b2
BEIM
F/F
19-source inputs
To the previous page
(Level)
Shift to error passive state
b1
EPIS
F/F
b1
EPIM
F/F
Shift to bus off state
b0
BOIS
F/F
b0
BOIM
F/F
Figure 1.22.19. CAN0 transmit, receive and error interrupt block diagram (3/3)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 global mask register standard ID0
CAN0 local mask register A, B standard ID0
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
When reset (Note)
C0GMR0
C0LMAR0
022816
023016
XXX0 00002
XXX0 00002
C0LMBR0
023816
XXX0 00002
Bit
symbol
Bit name
Function
SID6M Standard ID6
0: ID not checked
1: ID checked
SID7M Standard ID7
0: ID not checked
1: ID checked
SID8M Standard ID8
0: ID not checked
1: ID checked
SID9M Standard ID9
0: ID not checked
1: ID checked
SID10M Standard ID10
0: ID not checked
1: ID checked
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.20. CAN0 global mask register standard ID0 and CAN0 local mask register A, B standard ID0
15. CAN0 global mask register standard ID0
CAN0 local mask register A, B standard ID0
The mask registers used for acceptance filtering consist of the global mask register, local mask
register A, and local mask register B.
The global mask register takes care of message slots 0–13 whereas local mask registers A and B are
used for message slots 14 and 15, respectively.
• If any bit of this register is set to 0, its corresponding ID bit is masked during acceptance filtering.
(The masked bit is not checked for ID; the ID is assumed to be matching.)
• If any bit of this register is set to 1, its corresponding ID bit is compared with the received ID during
acceptance filtering. If it matches the ID that is set in any message slot, the received data is stored
in that slot.
Note 1: The global mask register can only be modified when none of the slots 0–13 has receive
requests set.
Note 2: The local mask register A can only be modified when slot 14 has no receive requests set.
Note 3: The local mask register B can only be modified when slot 15 has no receive requests set.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 global mask register standard ID1
CAN0 local mask register A, B standard ID1
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
When reset (Note)
C0GMR1
022916
XX00 00002
C0LMAR1
C0LMBR1
023116
023916
XX00 00002
XX00 00002
Bit
symbol
Bit name
Function
SID0M
Standard ID0
0: ID not checked
1: ID checked
SID1M
Standard ID1
0: ID not checked
1: ID checked
SID2M
Standard ID2
0: ID not checked
1: ID checked
SID3M
Standard ID3
0: ID not checked
1: ID checked
SID4M
Standard ID4
0: ID not checked
1: ID checked
SID5M
Standard ID5
0: ID not checked
1: ID checked
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.21. CAN0 global mask register standard ID1 and CAN0 local mask register A, B standard ID1
16. CAN0 global mask register standard ID1
CAN0 local mask register A, B standard ID1
The mask registers used for acceptance filtering consist of the global mask register, local mask
register A, and local mask register B.
The global mask register takes care of message slots 0–13 whereas local mask registers A and B are
used for message slots 14 and 15, respectively.
• If any bit of this register is set to 0, its corresponding ID bit is masked during acceptance filtering.
(The masked bit is not checked for ID; the ID is assumed to be matching.)
• If any bit of this register is set to 1, its corresponding ID bit is compared with the received ID during
acceptance filtering. If it matches the ID that is set in any message slot, the received data is stored
in that slot.
Note 1: The global mask register can only be modified when none of the slots 0–13 has receive
requests set.
Note 2: The local mask register A can only be modified when slot 14 has no receive requests set.
Note 3: The local mask register B can only be modified when slot 15 has no receive requests set.
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Mitsubishi Microcomputers
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 global mask register extend ID0
CAN0 local mask register A, B extend ID0
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
When reset (Note)
C0GMR2
C0LMAR2
022A16
023216
XXXX 00002
XXXX 00002
C0LMBR2
023A16
XXXX 00002
Bit
symbol
Bit name
Function
EID14M Extend ID14
0: ID not checked
1: ID checked
EID15M Extend ID15
0: ID not checked
1: ID checked
EID16M Extend ID16
0: ID not checked
1: ID checked
EID17M Extend ID17
0: ID not checked
1: ID checked
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.22. CAN0 global mask register extend ID0 and CAN0 local mask register A, B extend ID0
17. CAN0 global mask register extend ID0
CAN0 local mask register A, B extend ID0
The mask registers used for acceptance filtering consist of the global mask register, local mask
register A, and local mask register B.
The global mask register takes care of message slots 0–13 whereas local mask registers A and B are
used for message slots 14 and 15, respectively.
• If any bit of this register is set to 0, its corresponding ID bit is masked during acceptance filtering.
(The masked bit is not checked for ID; the ID is assumed to be matching.)
• If any bit of this register is set to 1, its corresponding ID bit is compared with the received ID during
acceptance filtering. If it matches the ID that is set in any message slot, the received data is stored
in that slot.
Note 1: The global mask register can only be modified when none of the slots 0–13 has receive
requests set.
Note 2: The local mask register A can only be modified when slot 14 has no receive requests set.
Note 3: The local mask register B can only be modified when slot 15 has no receive requests set.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 global mask register extend ID1
CAN0 local mask register A, B extend ID1
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0GMR3
C0LMAR3
C0LMBR3
Bit
symbol
Address
022B16
023316
023B16
Bit name
When reset (Note)
0016
0016
0016
Function
EID6M
Extend ID6
0: ID not checked
1: ID checked
EID7M
Extend ID7
0: ID not checked
1: ID checked
EID8M
Extend ID8
0: ID not checked
1: ID checked
EID9M
Extend ID9
0: ID not checked
1: ID checked
EID10M Extend ID10
0: ID not checked
1: ID checked
EID11M Extend ID11
0: ID not checked
1: ID checked
EID12M Extend ID12
0: ID not checked
1: ID checked
EID13M Extend ID13
0: ID not checked
1: ID checked
R W
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.23. CAN0 global mask register extend ID1 and CAN0 local mask register A, B extend ID1
18. CAN0 global mask register extend ID1
CAN0 local mask register A, B extend ID1
The mask registers used for acceptance filtering consist of the global mask register, local mask
register A, and local mask register B.
The global mask register takes care of message slots 0–13, whereas local mask registers A and B
are used for message slots 14 and 15, respectively.
• If any bit of this register is set to 0, its corresponding ID bit is masked during acceptance filtering.
(The masked bit is not checked for ID; the ID is assumed to be matching.)
• If any bit of this register is set to 1, its corresponding ID bit is compared with the received ID during
acceptance filtering. If it matches the ID that is set in any message slot, the received data is stored
in that slot.
Note 1: The global mask register can only be modified when none of the slots 0–13 has receive
requests set.
Note 2: The local mask register A can only be modified when slot 14 has no receive requests set.
Note 3: The local mask register B can only be modified when slot 15 has no receive requests set.
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 global mask register extend ID2
CAN0 local mask register A, B extend ID2
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0GMR4
C0LMAR4
Address
022C16
023416
XX00 00002
XX00 00002
C0LMBR4
023C16
XX00 00002
Bit
symbol
Bit name
When reset (Note)
Function
EID0M
Extend ID0
0: ID not checked
1: ID checked
EID1M
Extend ID1
0: ID not checked
1: ID checked
EID2M
Extend ID2
0: ID not checked
1: ID checked
EID3M
Extend ID3
0: ID not checked
1: ID checked
EID4M
Extend ID4
0: ID not checked
1: ID checked
EID5M
Extend ID5
0: ID not checked
1: ID checked
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.24. CAN0 global mask register extend ID2 and CAN0 local mask register A, B extend ID2
19. CAN0 global mask register extend ID2
CAN0 local mask register A, B extend ID2
The mask registers used for acceptance filtering consist of the global mask register, local mask
register A, and local mask register B.
The global mask register takes care of message slots 0–13, whereas local mask registers A and B
are used for message slots 14 and 15, respectively.
• If any bit of this register is set to 0, its corresponding ID bit is masked during acceptance filtering.
(The masked bit is not checked for ID; the ID is assumed to be matching.)
• If any bit of this register is set to 1, its corresponding ID bit is compared with the received ID during
acceptance filtering. If it matches the ID that is set in any message slot, the received data is stored
in that slot.
Note 1: The global mask register can only be modified when none of the slots 0–13 has receive
requests set.
Note 2: The local mask register A can only be modified when slot 14 has no receive requests set.
Note 3: The local mask register B can only be modified when slot 15 has no receive requests set.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 message slot i control register (i=0 to 15)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0MCTLi(i=0 to 5)
C0MCTLi(i=6 to 11)
C0MCTLi(i=12 to 15)
Bit
symbol
When receive,
NewData
When transmit,
SentData
When receive,
InvalData
When transmit,
TrmActive
Address
023016, 023116, 023216, 023316, 023416, 023516
023616, 023716, 023816, 023916, 023A16, 023B16
023C16, 023D16, 023E16, 023F16
Bit name
When reset (Note 1)
0016
0016
0016
R W
Function
When transmitting
When receiving (Note 2)
Transmit/receive
0: Not transmitted yet 0: Not received yet
finished flag
1: Finished transmitting 1: Finished receiving
When transmitting
When receiving
Transmitting/
0: Stopped transmitting
0: Stopped receiving
receiving flag
1: Accepted transmit request 1: Storing received data
MsgLost Overwrite flag
0: Over run error not occurred
1: Over run error occurred
Using BasicCan mode
0: Data flame received (status)
Remote flame
1: Remote flame received (status)
RemActive transmit/receive
Not using BasicCan mode
status flag
0: Data flame
1: Remote flame
(Note 2)
(Note 2)
RspLock
Automatic answering 0: Automatic answering of remote flame enable
disable bit
1: Automatic answering of remote flame disable
Remote
Remote frame
set bit
0: Transmit/receive data flame
1: Transmit/receive remote flame
RecReq
Receive
request bit
0: Reception not requested
1: Reception requested
TrmReq
Transmit
request bit
0: Transmission not requested
1: Transmission requested
Note 1: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Note 2: "0" can be set. When set to "1", the previous value is remained.
Figure 1.22.25. CAN0 message slot i control register
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
20. CAN0 message slot i control register
Bit 0: Transmission finished flag /reception finished flag (SentData, NewData)
This bit indicates that the CAN module finished transmitting or receiving a message.
• For transmit slots
The bit is set to 1 when the CAN module finished transmitting from the message slot.
This bit is cleared by writing 0 in software. However, it cannot be cleared when the TrmActive
(transmit/receive status) bit = 1.
• For receive slots
The bit is set to 1 when the CAN module finished receiving a message normally that is to be stored
in the message slot.
This bit is cleared by writing 0 in software. However, it cannot be cleared when the InvalData (transmit/receive status) bit = 1.
Note 1: Before reading received data from the message slot, be sure to clear the NewData (transmission/reception finished status) bit. Also, if the NewData bit is set to 1 after readout, it means
that new received data has been stored in the message slot while reading out from the slot,
and that the read data contains an indeterminate value. In this case, discard the read data
and clear the NewData bit before reading out from the slot again.
Note 2: The NewData bit is not set by a completion of remote frame transmission or reception.
Bit 1: Transmitting flag /receiving flag (TrmActive, InvalData)
This bit indicates that the CAN module is transmitting or receiving a message, with the message slot
being accessed. The bit is set to 1 when the CAN module is accessing the message slot and set to 0
when not accessing the message slot.
• For transmit slots
This bit is set to 1 when the message slot has its transmit request accepted. If the message slot
failed in arbitration, this bit is cleared to 0 by occurrence of a CAN bus error or completion of transmission.
• For receive slots
This bit is set to 1 when the CAN module is receiving a message, with the received message being
stored in the message slot. Note that the value read out from the message slot while this bit remains
set is indeterminate.
Bit 2: Overwrite flag (MsgLost)
This bit is useful for the receive slots, those that are set for reception. This bit is set to 1 when while
the message slot contains an unread received message, it is overwritten by a new received message.
This bit is cleared by writing 0 in software.
Bit 3: Remote frame transmit/receive status flag (RemActive)
This bit functions differently for slots 0–13 and slots 14, 15.
• For slots 0–13
If the slot is set for remote frame transmission (or reception), this bit is set to 1. Then, when the slot
finished transmitting (or receiving) a remote frame, this bit is cleared to 0.
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CAN Module
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
• For slots 14 and 15
The RemActive bit functions differently depending on how the CAN Control Register’s BasicCAN
(BasicCAN mode) bit is set.
When BasicCAN = 0 (operating normally), if the slot is set for remote frame transmission (or reception), the RemActive bit is set to 1.
When BasicCAN = 1 (operating in BasicCAN mode), the RemActive bit indicates which frame type
of message was received. During BasicCAN mode, slots 14 and 15 store the received data whether
it be a data frame or a remote frame.
If RemActive = 0, it means that the message stored in the slot is a data frame.
If RemActive = 1, it means that the message stored in the slot is a remote frame.
Bit 4: Automatic answering disable bit (RspLock)
This bit is useful for the slots set for remote frame reception, indicating the processing to be performed after receiving a remote frame.
If this bit is set to 0, the slot automatically changes to a transmit slot after receiving a remote frame
and the message stored in the slot is transmitted as a data frame.
If this bit is set to 1, the slot stops operating after receiving a remote frame.
Note 1: This bit must always be set to 0 for any slots other than those set for remote frame reception.
Bit 5: Remote frame set bit (Remote)
Set this bit to 1 for the message slots that handle a remote frame.
Message slots can be set to handle a remote frame in the following two ways.
• Set to transmit a remote frame and receive a data frame
The message stored in the message slot is transmitted as a remote frame. The slot automatically
changes to a data frame receive slot after it finished transmitting.
However, if it receives a data frame before it finishes transmitting a remote frame, the data frame is
stored in the message slot and the remote frame is not transmitted.
• Set to receive a remote frame and transmit a data frame
The slot receives a remote frame. The processing to be performed after receiving a remote frame
depends on how the RspLock (automatic answering disable) bit is set.
Bit 6: Receive request bit (RecReq)
Set this bit to 1 when using any message slot as a receive slot.
Set this bit to 0 when using any message slot as a data frame transmit or remote frame transmit slot.
If the TrmReq (transmit request) bit and RecReq (receive request) bit both are set to 1, the operation
of the CAN module is indeterminate.
Bit 7: Transmit request bit (TrmReq)
Set this bit to 1 when using any message slot as a transmit slot.
Set this bit to 0 when using any message slot as a data frame receive or remote frame receive slot.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 slot buffer select register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0SBS
Bit
symbol
Address
024016
When reset (Note 2)
0016
Bit name
Function
R W
b3 b2 b1 b0
SBS00
SBS01
SBS02
CAN0 message
slot buffer 0
number select bit
SBS03
0
0
0
0
1
1
1
1
0
0
0
1
1
1
1
1
•
•
•
0
1
1
0
0
0
1
1
0:
0:
1:
0:
0:
1:
0:
1:
slot 0
slot 1
slot 2
slot 3
•
•
•
slot 12
slot 13
slot 14
slot 15
(Note 1)
b3 b2 b1 b0
SBS10
SBS11
SBS12
CAN0 message
slot buffer 1
number select bit
SBS13
0
0
0
0
1
1
1
1
0
0
0
1
0
1
1
0
•
•
•
1 0
1 0
1 1
1 1
0:
0:
1:
0:
0:
1:
0:
1:
slot 0
slot 1
slot 2
slot 3
•
•
•
slot 12
slot 13
slot 14
slot 15
(Note 1)
Note 1: There is a total of 16 CAN0 message slots for transmission and reception uses, respectively.
Each message slot can be selected for use as a transmit or a receive slot.
Note 2: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
Figure 1.22.26. CAN0 slot buffer select register
21. CAN0 slot buffer select register
Bits 0-3: CAN0 message slot buffer 0 slot number select bits (SBS0)
The message slot whose number is selected with these bits appears in CAN0 message slot buffer 0.
Bits 4-7: CAN0 message slot buffer 1 slot number select bits (SBS1)
The message slot whose number is selected with these bits appears in CAN0 message slot buffer 1.
The selected message slot can be identified by reading the message slot buffer.
A message written to the message slot buffer is stored in the selected message slot.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 message slot buffer i standard ID0 (i=0,1) (Note)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
C0SLOTi_0(i=0,1)
01E016, 01F016
Bit
symbol
When reset
Indeterminate
Bit name
Function
SID6
Standard ID6
Message slot j (j=0 to 15)
SID7
Standard ID7
Message slot j (j=0 to 15)
SID8
Standard ID8
Message slot j (j=0 to 15)
SID9
Standard ID9
Message slot j (j=0 to 15)
SID10
Standard ID10
Message slot j (j=0 to 15)
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: CAN0 message slot j standard ID0 (j=0 to 15) is stored in this register. j is selected with the slot
buffer select register.
CAN0 message slot buffer i standard ID1(i=0,1) (Note)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0SLOTi_1(i=0,1)
Bit
symbol
Address
01E116, 01F116
Bit name
When reset
Indeterminate
Function
SID0
Standard ID0
Message slot j (j=0 to 15)
SID1
Standard ID1
Message slot j (j=0 to 15)
SID2
Standard ID2
Message slot j (j=0 to 15)
SID3
Standard ID3
Message slot j (j=0 to 15)
SID4
Standard ID4
Message slot j (j=0 to 15)
SID5
Standard ID5
Message slot j (j=0 to 15)
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: CAN0 message slot j standard ID1 (j=0 to 15) is stored in this register. j is selected with the slot
buffer select register.
Figure 1.22.27. CAN0 message slot buffer i standard ID0 and ID1
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 message slot buffer i extend ID0 (i=0,1) (Note 1, 2)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0SLOTi_2(i=0,1)
Bit
symbol
Address
01E216, 01F216
Bit name
When reset
Indeterminate
Function
EID14
Extended ID14
Message slot j (j=0 to 15)
EID15
Extended ID15
Message slot j (j=0 to 15)
EID16
Extended ID16
Message slot j (j=0 to 15)
EID17
Extended ID17
Message slot j (j=0 to 15)
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note 1: When receive slot is standard ID format, EID bits are indeterminate when saving received data.
Note 2: CAN0 message slot j extend ID0 (j=0 to 15) is stored in this register. j is selected with the slot
buffer select register.
CAN0 message slot buffer i extend ID1
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0SLOTi_3(i=0,1)
Bit
symbol
(i=0,1) (Note 1,2)
Address
01E316, 01F316
When reset
Indeterminate
Bit name
Function
EID6
Extended ID6
Message slot j (j=0 to 15)
EID7
Extended ID7
Message slot j (j=0 to 15)
EID8
Extended ID8
Message slot j (j=0 to 15)
EID9
Extended ID9
Message slot j (j=0 to 15)
EID10
Extended ID10
Message slot j (j=0 to 15)
EID11
Extended ID11
Message slot j (j=0 to 15)
EID12
Extended ID12
Message slot j (j=0 to 15)
EID13
Extended ID13
Message slot j (j=0 to 15)
R W
Note 1: When receive slot is standard ID format, EID bits are indeterminate when saving received data.
Note 2: CAN0 message slot j extend ID1 (j=0 to 15) is stored in this register. j is selected with the slot
buffer select register.
Figure 1.22.28. CAN0 message slot buffer i extended ID0 and ID1
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 message slot buffer i extend ID2 (i=0,1) (Note 1,2)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0SLOTi_4(i=0,1)
Bit
symbol
Address
01E416, 01F416
Bit name
When reset
Indeterminate
Function
EID0
Extended ID0
Message slot j (j=0 to 15)
EID1
Extended ID1
Message slot j (j=0 to 15)
EID2
Extended ID2
Message slot j (j=0 to 15)
EID3
Extended ID3
Message slot j (j=0 to 15)
EID4
Extended ID4
Message slot j (j=0 to 15)
EID5
Extended ID5
Message slot j (j=0 to 15)
R W
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note 1: When receive slot is standard ID format, EID bits are indeterminate when saving received data.
Note 2: CAN0 message slot j extend ID2 (j=0 to 15) is stored in this register. j is selected with the slot
buffer select register.
CAN0 message slot buffer i data length code (i=0,1)(Note)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
C0SLOTi_5(i=0,1)
Bit
symbol
Address
01E516, 01F516
Bit name
When reset
Indeterminate
Function
R W
DLC0
DLC1
Data length set bit
Message slot j (j=0 to 15)
DLC2
DLC3
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note : CAN0 message slot j data length code (j=0 to 15) is stored in this register. j is selected with the
slot buffer select register.
Figure 1.22.29. CAN0 message slot buffer i extended ID2 and CAN0 message slot buffer i data lengthcode
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 message slot buffer i data m (i=0,1 m=0 to 7)
b7
b0
Symbol
(Note)
Address
When reset
C0SLOT0_n(n=m+6,m=0 to 3) 01E616, 01E716, 01E816, 01E916
Indeterminate
C0SLOT0_n(n=m+6,m=4 to 7) 01EA16, 01EB16, 01EC16, 01ED16
Indeterminate
C0SLOT1_n(n=m+6,m=0 to 3) 01F616, 01F716, 01F816, 01F916
Indeterminate
C0SLOT1_n(n=m+6,m=4 to 7) 01FA16, 01FB16, 01FC16, 01FD16
Indeterminate
Function
Message slot j data m (j=0 to 15, m=0 to 7)
Setting range
R W
0016 to FF16
Note: j is selected with the slot buffer select register
CAN0 message slot buffer i time stamp high (i=0,1) (Note)
b7
b0
Symbol
Address
C0SLOTi_14(i=0,1) 01EE16, 01FE16
When reset
Indeterminate
Function
Message slot j time stamp high (j=0 to 15)
Setting range
R W
0016 to FF16
Note : CAN0 message slot j time stamp high (j=0 to 15) is stored in this register. j is selected with the
slot buffer select register.
CAN0 message slot buffer i time stamp low (i=0,1) (Note)
b7
b0
Symbol
Address
C0SLOTi_15(i=0,1) 01EF16, 01FF16
Function
Message slot j time stamp low (j=0 to 15)
When reset
Indeterminate
Setting range
R W
0016 to FF16
Note : CAN0 message slot j time stamp low (j=0 to 15) is stored in this register. j is selected with the
slot buffer select register.
Figure 1.22.30. CAN0 message slot buffer i data m and CAN0 message slot buffer i time stamp
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CAN Module
CAN0 acceptance filter support register
b15
b8
b7
b0
Symbol
C0AFS
Address
024516,024416
When reset (Note)
010016
Setting range
Function
Produces receive ID determination data
R W
000016 to FFFF16
Note: This applies when the CAN module is supplied with a clock by setting the sleep mode control bit
(bit 0 at address 024216) to 1 after reset.
b0
b15
Write
SID10 SID9 SID8 SID7 SID6
SID5 SID4 SID3 SID2 SID1 SID0
3-8 decode
b15
Read
b0
b7
b8
CSID7 CSID6 CSID5 CSID4 CSID3 CSID2 CSID1 CSID0 SID10 SID9 SID8 SID7 SID6 SID5 SID4 SID3
b7
From the receive ID of the standard format, this register produces data with
which to search the data table. After
searching the table using this data, the
CAN module determines whether the
receive ID is valid or not.
Top+0016
Top+0116
Top+DE16
Top+FE16
Top+FF16
b6
b5
b3
b1
b0
6F716 6F616 6F516 6F416 6F316 6F216 6F116 6F016
"0"
"0"
"0"
"0"
"1"
"0"
"0"
"0"
7F716 7F616 7F516 7F416 7F316 7F216 7F116 7F016
"0"
"0"
"0"
"0"
"0"
"0"
"0"
"1"
7FF16 7FE16 7FD16 7FC16 7FB16 7FA16 7F916 7F816
"0"
"0"
"1"
"0"
"0"
"0"
"0"
"0"
Bit search information
b15
b8
b7
b0
SID5 SID4 SID3 SID2 SID1 SID0
SID10SID9 SID8 SID7 SID6
0 0 1 1 0 0 1 1 0 0 0 1 1 0 1 1
Write to C0AFS
SID10
SID0
"6"
Receive ID
"F"
"3"
1 1 0 1 1 1 1 0 0 1 1
"D"
"E"
"3"
Divide to 8 bits and 3 bits
8 bits
b15
b8
3 bits
b7
b0
0 0 0 0 1 0 0 0 1 1 0 1 1 1 1 0
"0816"
Read from C0AFS
"D"
Bit search information
Bit search information
b7
0116
0216
0416
0816
1016
2016
4016
8016
0
0
0
0
0
0
0
1
b0
b3
0
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
0
0
0
0
"E"
Address search information
1
0
0
0
0
0
0
0
Figure 1.22.31. CAN0 acceptance filter support register
234
b2
00716 00616 00516 00416 00316 00216 00116 00016
"0"
"0"
"0"
"0"
"0"
"0"
"1"
"0"
00F16 00E16 00D16 00C16 00B16 00A16 00916 00816
"1"
"0"
"0"
"0"
"0"
"0"
"0"
"0"
Address search information
When receive ID is "6F316"
b4
Low-order 3 bits of receive ID
016
116
216
316
416
516
616
716
Because the value of
these three bits is 3,
bit 3 in the table below
is 1. (If the value of
these three bits is 4,
bit 4 in the table below
is 1.)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Intelligent I/O
Intelligent I/O uses multifunctional I/O ports for time measurement, waveform generation, clock-synchronous/asynchronous (UART) serial I/O, IE bus (Note) communications, HDLC data processing and more. A
single Intelligent I/O group comes with one 16-bit base timer for free running, eight 16-bit registers for time
measurement and waveform generation, and two shift registers for 8-bit and 16-bit communications.
The M32C/83 has four internal Intelligent I/O groups. Table 1.23.1 lists functions by group.
Table 1.23.1. List of functions of intelligent I/O
Function
Group 0
Group 1
Group 2
Group 3
Group 0,1
cascaded
Configuration
•Base timer
1
1
1
1
1
•TM
•TM/WG register (shared)
•WG register
4ch(2ch)
4chs(1ch)
–
–
4chs(2chs)
4chs(1ch)
–
–
8chs
–
–
8chs(3chs)
–
8chs(3chs)
8chs(2chs)
•Communication shift register
8bits X 2chs
8bits X 2chs
8bits X 2chs
–
–
Max. 4chs
(2chs)
√
2chs
–
–
•Digital filter function
•Trigger input prescale function
Max. 8chs
(3chs)
√
2chs
–
–
–
–
Max. 8chs
(3chs)
√
2chs
•Gate function for trigger input
2chs
2chs
–
–
2chs
•Single phase waveform output
•Phase delayed waveform output
•Set/reset waveform output
•Bit modulation PWM output
•Real-time port output
Max. 4chs
(1ch)
√
√
√
–
–
Max. 8chs
(3chs)
√
√
√
–
–
Max. 8chs
(3chs)
√
√
√
√
√
Max. 8chs
(2chs)
√
√
√
√
√
Max. 8chs
(1ch)
√
√
√
–
–
•Parallel real-time port output
–
–
√
√
–
8 bits fixed
8 bits fixed
Variable length –
–
√
√
√
–
√
–
–
√
–
–
–
–
Time measurement functions
WG function
Communication functions
•Bit length
•Communication mode
1. Clock synchronous serial I/O
√
2. UART
√
3. HDLC data processing
√
4. IE Bus sub set
–
Note 1: IE Bus is a trademark of NEC.
Note 2: 100-pin specification are in parentheses.
–
–
–
–
√ : Present
– : Not present
TM:Time Measurement
WG:Waveform Genaration
235
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Block diagrams for groups 0 to 3 are given in Figures 1.23.1 to 1.23.4.
Start bit
Reset request from
communication block
BT0S
BTS
Reset
Gr1 base timer reset
16-bit
Base timer
2 x (n+1)
Divider
f1
Base timer carry output
Digital
filter
INPC00
DF
Edge
select
Ch0 TM/WG
register
OUTC00/
IST x D0
PWM
output
INPC01
/ISCLK0
Digital
filter
DF
Edge
select
Ch1 TM/WG
register
INPC02
/ISRxD0
Digital
filter
DF
Edge
select
Ch2 TM register
INPC03
Digital
filter
DF
Edge
select
Ch3 TM register
INPC04
Digital
filter
DF
Edge
select
Ch4 TM/WG
register
OUTC01/
ISCLK0
PWM
output
OUTC04
PWM
output
(Note 1)
(Note 1)
Ch5 TM/WG
register
INPC05
Digital
filter
DF
Edge
select
INPC06
Digital
filter
DF
Edge
select
Gate
function
GT
Prescale
function
PR
INPC07
Digital
filter
DF
Edge
select
Gate
function
GT
Prescale
function
PR
OUTC05
Ch6 TM register
Ch7 TM register
8
Ch0 to ch7
interrupt request signal
/
TM input to Gr1
(When cascaded)
WG input to Gr1
(When cascaded)
Transmit interrupt
Clock
selector
SI/O transmit
buffer register
(8-bit)
SOF
generation circuit
Transmit
buffer
Bit insert circuit
Transmit
register
Transmit latch
Transmit data
generation circuit
Transmission
Transmit
CRC
Polarity
reversing
Start bit
generation circuit
Clock wait
control
circuit
Transmit output
register
(8-bit)
Parity bit
generation circuit
Transmit
shift register
Stop bit
generation circuit
HDLC data
transmit interrupt
Transmit
buffer
Arbitration
Clock
selector
(8bit)
Receive
buffer
Receive shit
register
Receive data
generation circuit
Receive
CRC
Receive input register
Reception
SI/O receive
buffer register
(8bit)
Bit insert
check
Polarity
reversing
Data register
(8-bit)
Stop bit
check
Buffer
register
Receive interrupt
Receive shift
register
Parity bit
check
Shift
register
HDLC data
process interrupt
Receive
buffer
Start bit
check
Special
interrupt
check
4
Special
communication
interrupt
/
Comparison
register
Comparison
(8-bit)
register
Comparison
Comparison
(8-bit)
register
register
(8-bit)
(8-bit)
4
/
Comparator
Comparator
(8-bit)
Comparator
(8-bit)
(8-bit)
Comparator
(8-bit)
4
/
Note 1: These pins aren't connected with external pins in 100-pin version.
Note 2: Each register becomes reset status after supplying a clock by setting of the base timer control register 0.
Figure 1. 23. 1. Block diagram of intelligent I/O group 0
236
TM: Time Measurement
WG: Waveform Generation
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Start bit
Reset request from
communication block
BT1S
BTS
Reset
Base timer carry input
f1
Gr0 base timer reset
16bits
Base timer
2 x (n+1)
Divider
WG input from Gr0
(When cascaded)
Ch0 TM/WG
register (Note)
TM input from Gr0
(When cascaded)
OUTC10
/IST x D1
/BE1OUT
PWM
output
INPC11
Digital
filter
DF
Edge
select
Ch1 TM/WG
register
INPC12
Digital
filter
DF
Edge
select
Ch2 TM/WG
register
OUTC11
/ISCLK1
OUTC12
PWM
output
Ch3 TM/WG
register
OUTC13
Ch4 TM/WG
register
OUTC14
PWM
output
Ch5 TM/WG
register
INPC16
Digital
filter
DF
Edge
select
DF
Edge
select
Gate
function
GT
Prescale
function
GT
Prescale
function
PR
Ch6 TM/WG
register
PR
Ch7 TM/WG
register
OUTC15
OUTC16
PWM
output
(Note 2)
INPC17
Digital
filter
Gate
function
(Note 2)
OUTC17
8
/
Ch0 to ch7
interrupt request signal
Transmit interrupt
Clock
selector
SI/O transmit
buffer register
(8-bit)
SOF
generation circuit
Transmit
buffer
Bit insert circuit
Transmit
register
Transmit latch
Transmit data
generation circuit
Transmission
Transmit
CRC
Polarity
reversing
Start bit
generation circuit
Clock wait
control
circuit
Transmit output
register (8-bit)
Parity bit
generation circuit
Transmit shift
register
Stop bit
generation circuit
Transmit
buffer
Arbitration
Receive input register
Clock
selector
Receive
CRC
(8bit)
Receive
buffer
Receive shit
register
Reception
Receive data
generation circuit
SI/O receive
buffer register
(8bit)
Bit insert
check
Polarity
reversing
Stop bit
check
Buffer
register
Special
interrupt
check
4
/
Comparison
register
Comparison
(8-bit)
register
Comparison
Comparison
(8-bit)
register
register
(8-bit)
(8-bit)
4
/
Comparator
Comparator
(8-bit)
Comparator
(8-bit)
Comparator
(8-bit)
(8-bit)
Receive interrupt
Receive shift
register
Parity bit
check
Shift
register
HDLC data
process interrupt
Receive
buffer
Start bit
check
Data register
(8-bit)
HDLC data
transmit interrupt
Special
communication
interrupt
4
/
Note 1: Ch0 TM register can be used in 32-bit cascade connections.
Note 2: These pins aren't connected with external pins in 100-pin version.
Note 3: Each register becomes reset status after supplying a clock by setting of the base timer control register 0.
TM: Time Measurement
WG: Waveform Generation
Figure 1. 23. 2. Block diagram of intelligent I/O group 1
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Reset
BT2S
BTS
16-bit
Base timer
2 x (n+1)
Divider
f1
Reset request from communication block
Gr1 base timer reset
ch0 interrupt request signal
Real time port
output value
ch0 WG register
IPS6
0
ISCLK20
ISCLK21
1
ISRxD20
ISRxD21
ISRxD22
1
Digital
filter
1
10
ch1 WG register
Bit modulation
PWM
ch2 WG register
Bit modulation
PWM
DF
0
OUTC21
/ISCLK2
OUTC22
PWM
output
control
DF
IPS4,5
ch3 WG register
Bit modulation
PWM
ch4 WG register
Bit modulation
PWM
ch5 WG register
Bit modulation
PWM
ch6 WG register
Bit modulation
PWM
ch7 WG register
OUTC20
/ISTxD2
PWM
output
control
0
Digital
filter
00
01
Bit modulation
PWM
OUTC23
OUTC24
PWM
output
control
OUTC25
OUTC26
PWM
output
control
Bit modulation
PWM
OUTC27
Waveform
generation
interrupt
8
Transmit buffer
register(8-bit)
Clock
selector
Bit
counter
(Note 1)
8
Transmit
register (8-bit)
Output control
function
Transmit parity
operation
Transmit
latch
Output
inverted
Byte counter
ACK operation
Arbitration
lost detect
Start bit
detect
IE start bit interrupt
Receive parity
operation
IE, serial I/O
interrupt control
IE transmit interrupt
IE receive interrupt
Serial I/O transmit interrupt
Serial I/O receive interrupt
Input
inverted
Receive shift
register (8-bit)
ID detect
Receive buffer
register (8-bit)
Statement
length detect
ALL "F" detect
Address detect
WG: Waveform Generation
Note 1: These pins aren't connected with external pins in 100-pin version.
Note 2: Each register becomes reset status after supplying a clock by setting of the base timer control register 0.
Figure 1. 23. 3. Block diagram of intelligent I/O group 2
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
BT3S
BTS
f1
2 x (n+1)
Divider
Reset
16-bit
Base timer
Gr2 base timer reset
ch0 interrupt request signal
Real time port
output value
ch0 WG register
Bit modulation
PWM
ch1 WG register
Bit modulation
PWM
ch2 WG register
Bit modulation
PWM
ch3 WG register
Bit modulation
PWM
ch4 WG register
Bit modulation
PWM
OUTC30
PWM
output
control
OUTC31
OUTC32
PWM
output
control
OUTC33
OUTC34
PWM
output
control
ch4 mask register
ch5 WG register
Bit modulation
PWM
OUTC35
(Note 1)
ch5 mask register
ch6 WG register
Bit modulation
PWM
OUTC36
PWM
output
control
ch6 mask register
ch7 WG register
Bit modulation
PWM
ch7 mask register
OUTC37
8
Waveform
generation
interrupt
WG: Waveform Generation
Note 1: These pins aren’t connected with external pins in 100-pin version.
Note 2: Each register becomes reset status after supplying a clock by setting of the base timer control register 0.
Figure 1. 23 . 4. Block diagram of intelligent I/O group 3
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Base timer (group 0 to 3)
The internally generated count source is a free run source. Base timer specifications are given in Table
1.23.2, base timer registers in Figures 1.23.5 to 1.23.9 and a block diagram in Figure 1.23.10.
Group i base timer register (i=0 to 3)
b15
(b7)
b8
(b0) b7
b0
Symbol
GiBT (i=0,1)
GiBT (i=2,3)
Address
00E116, 00E016, 012116, 012016
016116, 016016, 01A116, 01A016
When reset
Indeterminate
Indeterminate
Setting range
Function
Count value of the 16-bit base timer
R W
000016 to FFFF16
(Note)
Note : When this register is read while the base timer is being reset, the value is indeterminate.
The counter value is read if the register is output while the timer is running.
Written value while the base timer is being reset is ignored. The count starts from "000016" after
starting the base timer. When writing value while the base timer is operating, the count starts from
the written value immediately after written.
Group i base timer control register 0 (i=0 to 3) (Note)
b7
b0
Symbol
GiBCR0 (i=0 to 3)
Bit
symbol
Address
When reset
00E216, 012216, 016216, 01A216
0016
Bit name
Function
R W
b1 b0
BCK0
BCK1
0
0
1
1
DIV0
Divides the count source by 2x(n + 1)
for a setting value n (n = 0 to 31).
Count source
select bit
0 : Clock stop
1 : Must not be set
0 : Must not be set
1 : f1
b6 b5 b4 b3 b2
Count source
division ratio
select bit
(n=0) 0 0 0 0 0 : Division by 2
(n=1) 0 0 0 0 1 : Division by 4
(n=2) 0 0 0 1 0 : Division by 6
:
(n=30) 1 1 1 1 0 : Division by 62
(n=31) 1 1 1 1 1 : No division
Base timer
interrupt select bit
0 : Bit 15 overflow
1 : Bit 14 overflow
DIV1
DIV2
DIV3
DIV4
IT
Note: In cascade connections, set the same value to the base timer control register 0 of groups 0 and 1.
Figure 1. 23. 5. Base timer-related register (1)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Group i base timer control register 1 (i=0,1)
b7
b0
0
Symbol
Address
When reset
GiBCR1 (i=0,1)
00E316, 012316
0016
Bit
symbol
Bit name
Function
R W
RST0
Base timer reset
cause select bit 0
0: Synchronizes the base timer reset
without resetting the timer
1: Synchronizes the base timer reset
with resetting the timer
(Note1)
RST1
Base timer reset
cause select bit 1
0: Does not reset the base timer when
it matches WG register ch0
1: Reset the base timer when it matches
WG register ch0
(Note 2)
RST2
Base timer reset
cause select bit 2
0: Does not reset the base timer when
input to the INT pin is "L" level
1: Reset the base timer when input to
(Note 3)
the INT pin is "L" level
Reserved bit
BTS
Base timer
start bit
Must always set to "0".
0: Base timer reset
1: Base timer count start
b6 b5
Up / down
control bit
0 0 : Up mode
0 1 : Up / down mode (triangle wave)
1 0 : Two-phase pulse signal processing
mode
(Note 4)
1 1 : Must not be set
Groups 0 and 1
cascaded function
select bit
0: 16-bit TM / WG function
1: 32-bit TM / WG function
UD0
UD1
CAS
(Note 5)
Note 1: With group 0, reset synchronizing with group 1 base timer. With group 1, reset synchronizing with
group 0 base timer.
Note 2: The base timer is reset 2 clock cycles after it matches waveform generation register ch0.
Note 3: With group 0, the base timer is reset when "L" level is input to INT0. With group 1, it resets when
"L" level is input to INT1.
Note 4:Operation of this mode is equal to Timer A two-phase pulse signal processing except count value.
Note 5: In cascade connections, set to "8116" for group 0 base timer control register 1. Set to "1000 0XX02"
for group 1 base timer control register 1.
Figure 1. 23. 6. Base timer-related register (2)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Group 2 base timer control register 1
b7
b0
0 0
0
Symbol
Address
016316
G2BCR1
Bit
symbol
Bit name
When reset
0016
Function
RST0
Base timer
reset cause
select bit 0
0 : Synchronizes the group 1 base timer reset
without resetting the timer
1 : Synchronizes the group 1 base timer reset
with resetting the timer
RST1
Base timer
reset cause
select bit 1
0 : Does not reset the base timer when it matches WG
register ch0
1 : Reset the base timer when it matches WG register ch0 (Note)
RST2
Base timer
reset cause
select bit 2
0 : Does not reset the base timer when a reset is requested
from the communication additional circuit
1 : Reset the base timer when a reset is requested from
the communication additional circuit
RST3
Reserve bit
Must always set to "0".
BTS
Base timer
start bit
0 : Base timer reset
1 : Base timer count start
Reserve bit
Must always set to "0".
UD0
UD1
PRP
Parallel real-time 0 : Not use
port function
1 : Use
select bit
Note : The base timer is reset 2 clock cycles after it matches waveform generation register ch0.
Figure 1. 23. 7. Base timer-related register (3)
242
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Group 3 base timer control register 1
b7
b0
0
Symbol
Address
When reset
G3BCR1
01A316
0XX0 X0002
Bit
symbol
Bit name
Function
RST0
Base timer
reset cause
select bit 0
0 : Synchronizes the base timer 2 reset
without resetting the timer
1 : Synchronizes the base timer 2 reset
with resetting the timer
RST1
Base timer
reset cause
select bit 1
0 : Does not reset the base timer when it matches WG
register ch0
1 : Reset the base timer when it matches WG register ch0 (Note)
Reserved bit
Must always set to "0".
R W
Nothing is assigned. When write, set to "0".
When read, the content is indeterminate.
BTS
Base timer
start bit
0 : Base timer reset
1 : Base timer count start
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
PRP
Parallel real-time
0 : Not use
port function
1 : Use
select bit
WG: Waveform Generation
Note : The base timer is reset 2 clock cycles after it matches waveform generation register ch0.
Figure 1. 23. 8. Base timer-related register (4)
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Intelligent I/O
Base timer start register
b7
Mitsubishi Microcomputers
b0
(Note 1, 2)
Symbol
Address
When reset
BSTR
016416
XXXX 00002
Bit
symbol
Bit name
Function
BT0S
Group 0 base timer
start bit
0 : Base timer reset
1 : Base timer count start
BT1S
Group 1 base timer
start bit
0 : Base timer reset
1 : Base timer count start
BT2S
Group 2 base timer
0 : Base timer reset
start bit
(Note 2) 1 : Base timer count start
BT3S
Group 3 base timer
start bit
R W
0 : Base timer reset
1 : Base timer count start
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
Note 1: When starting multiple base timer with this register at the same time (including group 0 and 1
cascaded connection), do the followings. Do not need when starting base timer individually.
* Set the same values to each group’s base timer clock division ratio ( bits 6 to 0 of base timer
control register).
* When changing base timer clock division ratio, start base timer twice with the following
procedure.
(1) Start each group base timer using the base timer start register.
(2) After one clock, stop base timer by setting "0016" to base timer start register.
(3) Further after one clock, restart each group base timer using the base timer start register.
Note 2: This register is enabled after when group 2 base timer control register 0 is set.
Figure 1. 23. 9. Base timer-related register (5)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Table 1. 23.2. Base timer specifications
Item
Specifications
Count source
f1/2(n+1)
n: Set by count source division ratio select bit
(n=0 to 31, however, please note when n=31, the counter source is not divided.)
Count operation
Up count / down count
Count start condition
Writes "1" for the start bit in the base timer start register or base timer control
register 1. (After writing the bit, the base timer resets to "000016" and
counting starts.)
Count stop condition
Writes "0" for both the start bit in the base timer start register and base timer
control register 1.
Count reset condition Group 0, 1
(1) Synchronizes and resets the base timer with that of another group.
Group 0: Synchronizes base timer reset with the group 1 base timer.
Group 1: Synchronizes base timer reset with the group 0 base timer.
(2) Matches the value of the base timer to the value of WG register 0.
(3) Input "L" to INT pin
Group 0 : INT 0 pin
Group 1 : INT 1 pin
The above 3 factors can be used in conjunction with one another.
Group 2, 3
(1) Synchronizes and resets the base timer with that of another group.
Group 2: Synchronizes base timer reset with the group 1 base timer.
Group 3: Synchronizes base timer reset with the group 2 base timer.
(2) Matches the value of the base timer to the value of WG register 0.
(3) Reset request from communication additional circuit (group 2 only)
The above 3 factors can be used in conjunction with one another.
Interrupt request generation timing
When bit 14 or bit 15 overflows
Read from timer
•When the base timer is running
The count is output when the base timer is read.
•When the base timer not running
An undefined value is output when the base timer is read.
Write to timer
Possible. Values that are written while the base timer is resetting are
ignored. If values are written while the base timer is running, counting
continues after the values are written.
Count source
switching select bit
f1
2(n+1) divider
Base timer i
b14 b15
Interrupt timing
select bit
BT0S
Base timer i
interrupt request
Reset signal
BTS
Overflow signal
RST0
Other base timer reset
Matched to waveform
generation register 0
RST1
RST2
Input "L" to INT pin
(Group 0,1)
Figure 1. 23.10. Base timer block diagram
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
FFFF16
Contents of counter
800016
000016
b14
(Overflow signal)
"1"
b15
"1"
"0"
"0"
Figure 1. 23.11. Operation timing of base timer
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Time measurement (group 0 and 1)
Synchronizes external trigger input and stores the base timer value in the time measurement register j.
Specifications for the time measurement function are given in Table 1.23.3, the time measurement control
registers in Figures 1.23.12 to 1.23.13, and the operating timing of the time measurement function in Figure
1.23.14 and 15.
Group i time measurement control register j (i=0,1/j=0 to 7) (Note 1)
b7
b0
Symbol
GiTMCRj(i=0/j=0 to 3)
GiTMCRj(i=0/j=4 to 7)
GiTMCRj(i=1/j=1, 2)
GiTMCRj(i=1/j=6, 7)
Bit
symbol
Address
00D816, 00D916, 00DA16, 00DB16
00DC16, 00DD16, 00DE16, 00DF16
011916, 011A16
011E16, 011F16
Bit name
When reset
0016
0016
0016
0016
Function
R W
b1 b0
CST0
Time measurement
trigger select bit
CST1
0
0
1
1
0
1
0
1
: No time measurement
: Rising edge
: Falling edge
: Both edges
b3 b2
DF0
Digital filter function
select bit
DF1
0
0
1
1
0
1
0
1
: No digital filter
: Must not be set
: Base timer clock
: f1
GT
Gate function
select bit (Note 2, 4)
0 : Gate function not used
1 : Gate function used
GOC
Gate function release
select bit (Note 2, 3)
0 : No effect
1 : Release the gate when it
matches WG register
GSC
Gate function release
bit
(Note 2, 3)
0 : No effect
1 : Gate released
PR
Prescaler function
select bit
(Note 2)
0 : Not used
1 : Used
WG: Waveform Generation
Note 1: The 16-bit time measurement function is available for 8 channels (ch0 to 7) with group 0 and 4 channels
(ch1, 2, 6 and 7) with group 1. When using the 16-bit time measurement function, use the time
measurement register values for ch0, 3, 4 and 5 of group 1 as they are, or, if writing values, write "0016".
The 32-bit time measurement function can be used with 8 channels (ch0 to 7) by linking groups 0 and 1.
When using the 32-bit time measurement function, write the same value for time measurement registers
of similar channels in groups 0 and 1.
Note 2: These functions are available only for time measurement ch6 and 7 (time measurement registers 6
and 7). For ch0 to 5, set "0" for bits 4 to 7 of the time measurement register.
Note 3: These bits are valid only when "1" is set for the gate function select bit.
Note 4: The gate function cannot be used at the same time as the 32-bit time measurement function.
Figure 1. 23. 12. Time measurement-related register (1)
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Intelligent I/O
Group i time measurement prescale register j (i=0,1/j=6,7)
b7
b0
Symbol
GiTPRj(i=0/j=6, 7)
GiTPRj(i=1/j=6, 7)
Address
00E416, 00E516
012416, 012516
When reset
0016
0016
Function
Setting range
Prescales time measurement events.
(Generates the time measurement request after
an n + 1 count.)
(Note)
R W
0016 to FF16
Note : This function is only built into time measurement ch6 and 7 of Intelligent I/O groups 0 and 1.
Group i time measurement register j (i=0,1/j=0 to 7)
b15
(b7)
b8
(b0) b7
b0
Symbol
GiTMj(i=0/j=0 to 2)
GiTMj(i=0/j=3 to 5)
GiTMj(i=0/j=6,7)
GiTMj(i=1/j=0 to 2)
GiTMj(i=1/j=3 to 5)
GiTMj(i=1/j=6,7)
Address
00C116,00C016, 00C316,00C216, 00C516,00C416
00C716,00C616, 00C916,00C816, 00CB16,00CA16
00CD16,00CC16, 00CF16,00CE16
010116,010016, 010316,010216, 010516,010416
010716,010616, 010916,010816, 010B16,010A16
010D16,010C16, 010F16,010E16
Function
When reset
000016
000016
000016
000016
000016
000016
Setting range
R W
When an event occures, the value of the base
timer is stored.
Group i function select register (i=0, 1)
b7
b0
Symbol
GiFS (i=0,1)
Bit
symbol
Address
00E716, 012716
Bit name
FSC0
Ch0 TM/WG function
select bit
FSC1
Ch1 TM/WG function
select bit
FSC2
Ch2 TM/WG function
select bit
FSC3
Ch3 TM/WG function
select bit
FSC4
Ch4 TM/WG function
select bit
FSC5
Ch5 TM/WG function
select bit
FSC6
Ch6 TM/WG function
select bit
FSC7
Ch7 TM/WG function
select bit
When reset
0016
Function
R W
Whether the corresponding port
functions as TM or WG is selected
0 : WG function is selected
1 : TM function is selected
Note : In group 0, channles 2, 3, 6 and 7 cannot be selected in 16-bit mode. All channel can be selected
in 32-bit mode.
In group 1, channles 0 and 3 to 5 cannot be selected in 16-bit mode. All channel can be selected
in 32-bit mode.
Figure 1. 23. 13. Time measurement-related register (2)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
Table 1. 23.3. Specifications of time measurement function
Item
Specifications
Time resolution
t=1/(base timer count source)
Trigger input polarity select
•Rising edge •Falling edge •Both edges
Measurement start condition (Note)
Write "1" to the function enable bit
Measurement stop condition
Write "0" to the function enable bit
Time measurement timing
•Prescaler (only ch6 and ch7) : Every the (m+1) trigger input
•No prescaler
: Every trigger input
Interrupt request generation timing
Same timing as time measurement
INPC pin function
Trigger input pin
(Set the corresponding pin to input with the function select register)
Select function
•Digital filter function
Pulses will pass when they match either f1 or the base timerclock 3 times .
•Prescaler function (only for ch6 and ch7)
Counts trigger inputs and measures time by inputting a trigger of +1 the
value of the time measurement prescale register.
•Gate function (only for ch6 and ch7)
Prohibits the reception of trigger inputs after the time measurement starts
for the first trigger input. Trigger input is newly enabled when the below
conditions are satisfied.
(1) When the base timer i matches the value in WG register j
(2) When “1” is written for the gate function release bit
This bit automatically becomes “0” after the gate function is released.
Note: On channels where both the time measurement function and waveform output function can be used, select the
time measurement function for the function select register (addresses 00E716 and 012716).
Table 1. 23.4. List of time measurement channels with prescaler function and gate function
Group
Group 0
Group 1
Channel
TM register
WG register matehes signal to release gate function
ch6
TM register 6
Base timer 0 matches to WG register 4
ch7
TM register 7
Base timer 0 matches to WG register 5
ch6
TM register 6
Base timer 1 matches to WG register 4
ch7
TM register 7
Base timer 1 matches to WG register 5
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O
(a) When the rising edge has been selected as the trigger input polarity
Base timer
count source
Base timer
value
n-2
n-1
n
n+1
n+2
n+3
n+4
n+5
n+6
n+7
n+8
n+9 n+10 n+11 n+12 n+13 n+14
Trigger input
Time measurement
interrupts request
signal
Delay by 1 clock
Time measurement
register
n
n+5
n+8
(b) When both edges have been selected as the trigger input polarity
Base timer
count source
Base timer
value
n-2
n-1
n
n+1
n+2
n+3
n+4
n+5
n+6
n+7
n+8
n+9 n+10 n+11 n+12 n+13 n+14
Trigger input
Time measurement
interrupts request
signal
Time measurement
register
n
n+2
n+5
n+8
n+12
(c) When digital filter is used (count of digital filter)
Digital filter
count source
Trigger input
Triggers signal
after passing
through digital filter
Signals which do not match
3 times are stripped off
Figure 1. 23. 14 Operation timing of time measurement function
250
Max. 3.5 clock cycles
Trigger signal delayed
by digital filter
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Intelligent I/O
(a) When prescaler function is used (the value of time measurement prescaler register is "2".)
Base timer
counter source
Base timer
n-2
n-1
n
n+1 n+2
n+3
n+4
n+5
n+6
n+7
n+8
n+9 n+10 n+11 n+12 n+13 n+14
Trigger input
Internal time
measurement trigger
Prescaler
2
1
0
2
Time measurement
interrupts request signal
Time measurement
register
n+1
n+13
(b) When gate function is used (gate function released by matching WG register)
Base timer
counter source
FFFF16
WG register value (XXXX16)
Base timer
000016
Function enabled
flag
Trigger input
Internal time
measurement trigger
This trigger input is invalid
because of gate function.
Waveform generation
register match signal
Gate signal
Time measurement
interrupts request signal
Time measurement
register
Figure 1. 23. 15. Operation timing when gate function and prescaler function is used
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Intelligent I/O
Waveform generation (WG) function (group 0 to 3)
Waveforms are generated when the base timer value matches the value of WG register j.
There are five mode in WG function: single phase waveform output mode (group 0 to 3), phase delayed
waveform output mode (group 0 to 3), SR (Set/Reset) waveform output mode (group 0 to 3), bit modulation
PWM output mode (group 2 and 3) and parallel real-time port output mode (group 2 and 3).
The WG function related registers are shown in Figures 1.23.16 to 1.23.19.
Group i waveform generation register j (i=0 to 3/j=0 to 7)
b15
(b7)
b8
(b0) b7
b0
Symbol
GiPOj(i=0/j=0 to 2)
GiPOj(i=0/j=3 to 5)
GiPOj(i=0/j=6,7)
GiPOj(i=1/j=0 to 2)
GiPOj(i=1/j=3 to 5)
GiPOj(i=1/j=6,7)
GiPOj(i=2/j=0 to 2)
GiPOj(i=2/j=3 to 5)
GiPOj(i=2/j=6,7)
GiPOj(i=3/j=0 to 2)
GiPOj(i=3/j=3 to 5)
GiPOj(i=3/j=6,7)
Address
00C116,00C016, 00C316,00C216, 00C516,00C416
00C716,00C616, 00C916,00C816, 00CB16,00CA16
00CD16,00CC16, 00CF16,00CE16
010116,010016, 010316,010216, 010516,010416
010716,010616, 010916,010816, 010B16,010A16
010D16,010C16, 010F16,010E16
014116,014016, 014316,014216, 014516,014416
014716,014616, 014916,014816, 014B16,014A16
014D16,014C16, 014F16,014E16
018116,018016, 018316,018216, 018516,018416
018716,018616, 018916,018816, 018B16,018A16
018D16,018C16, 018F16,018E16
Function
When reset
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
XXXX16
Setting range
A compared value for waveform generation
is stored.
(Note)
R W
000016 to FFFF16
WG: Waveform Generation
Note: When resetting the base timer on ch0, the timer is reset 2 clock cycles after it matches the waveform
generation register of ch0.
Group 3 waveform generation mask register j (j=4 to 7)
b15
(b7)
b8
(b0) b7
b0
Symbol
Address
When reset
G3MKj (j=4,5)
G3MKj (j=6,7)
019916,019816, 019B16,019A16
XXXX16
019D16,019C16, 019F16,019E16
XXXX16
Function
Masks base timer value
Setting range
(Note 1)
(Note 2)
R W
000016 to FFFF16
Note 1: This function is provided only for the waveform generation functions on ch 4 to 7 of Intelligent I/O group 3.
Note 2: Comparison results are masked in bit positions where a "1" has been set for the register bits.
Figure 1. 23. 16. WG-related register (1)
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Group i waveform generation control register j (i=0 to 1/ j=0 to 7) (Note 1)
b7
b0
Symbol
GiPOCRj (i=0/j=0,1)
GiPOCRj (i=0/j=4,5)
GiPOCRj (i=1/j=0 to 3)
GiPOCRj (i=1/j=4 to 7)
Bit
symbol
Address
00D016, 00D116
When reset
0X00X0002
00D416, 00D516
011016, 011116, 011216, 011316
011416, 011516, 011616, 011716
0X00X0002
0X00X0002
0X00X0002
Bit name
Function
R W
b2 b1b0
MOD0
MOD1
Operation mode
select bit
MOD2
0 0 0 : Single PWM mode
(Note 2)
0 0 1 : S-R PWM mode
0 1 0 : Phase delayed PWM mode
0 1 1 : Must not be set
1 0 0 : Must not be set
1 0 1 : Must not be set
(Note 3)
1 1 0 : Must not be set
1 1 1 : Assigns communication output
to a port
(Note 4)
Must always set to "0"
When read, the value of this bit is indeterminate.
IVL
Output initial value
select bit
0: Outputs "0" as the initial value
1: Outputs "1" as the initial value
RLD
Reload timing
select bit
0: Reloads a new count when CPU
writes the count
1: Reloads a new count when the
base timer i is reset
Must always set "0"
When read, the value of this bit is indeterminate.
INV
Inverted output function 0: Output is not inverted
(Note 5) 1: Output is inverted
select bit
Note 1: Group 0 and 1 have 16-bit WG function and 32-bit WG function.
The 16-bit WG function is available for 4 channels (ch=0,1,4,5) with group 0 and 8 channels
(ch=0 to 7) with group 1. When using the 16-bit WG function, use the WG register values for ch2,
3, 6 and 7 of group 0 as they are, or, if writing values, write "0016".
The 32-bit WG function can be used with 8 channels (ch0 to 7) by linking groups 0 and 1.
When using the 32-bit WG function, write the same value for WG registers of similar channels in
groups 0 and 1.
Note 2: This setting is valid only on even-numbered channels. When this mode is selected, settings for
corresponding odd-numbered (even number + 1) channels are ignored. Waveforms are output for
even-numbered channels, not output for odd-numbered channels.
Note 3: When receiving in UART mode of group 0 and 1, group i WG control register 2 is set to be
"000001102".
Note 4: This setting is valid only for WG function ch0 and 1. Do not set this value for other channels.
Note 5: Inverted output function is allocated at the final stage of WG circuit. Therefore, when selecting
Figure 1. 23. 17. WG-related register (2)
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Group i waveform generation control register j (i=2 to 3/ j=0 to 7)
b7
b0
Symbol
Address
When reset
GiPOCRj (i=2/j=0 to 3)
GiPOCRj (i=2/j=4 to 7)
GiPOCRj (i=3/j=0 to 3)
GiPOCRj (i=3/j=4 to 7)
015016, 015116, 015216, 015316
0X00 X0002
015416, 015516, 015616, 015716
0X00 X0002
019016, 019116, 019216, 019316
0X00 X0002
019416, 019516, 019616, 019716
0X00 X0002
Bit
symbol
Bit name
Function
R W
b2 b1b0
MOD0
MOD1
Operation mode
select bit
MOD2
0 0 0 : Single PWM mode
(Note 1)
0 0 1 : S-R PWM mode
0 1 0 : Phase delayed PWM mode
0 1 1 : Must not be set
1 0 0 : Bit modulation PWM mode
1 0 1 : Must not be set
1 1 0 : Must not be set
1 1 1 : Assigns communication output
to a port
(Note 2)
PRT
Parallel RTP output
trigger select bit
0: Match of WG register j isn’t trigger
1: Match of WG register j is trigger
IVL
Output initial value
select bit
0: Outputs "0" as the initial value
1: Outputs "1" as the initial value
RLD
Reload timing
select bit
0: Reloads a new count when CPU
writes the count
1: Reloads a new count when the
base timer i is reset
RTP
RTP port function
select bit
0: Not use
1: Use
INV
Inverted output function 0: Output is not inverted
(Note 3) 1: Output is inverted
select bit
Note 1: This setting is valid only on even-numbered channels. When this mode is selected, settings for
corresponding odd-numbered (even number + 1) channels are ignored. Waveforms are output for
even-numbered channels, not output for odd-numbered channels.
Note 2: This setting is valid only for group 2 WG function ch0 and 1. Do not set this value for other channels.
Note 3: Inverted output function is allocated at the final stage of WG circuit. Therefore, when selecting "0"
output by IVL bit and inverted output by INV bit, "1" is output.
Group i function enable register (i=0 to 3)
b7
b0
Symbol
GiFE (i=0 to 3)
Bit
symbol
Bit name
IFE0
Ch0 function enable bit
IFE1
Ch1 function enable bit
IFE2
Ch2 function enable bit
IFE3
Ch3 function enable bit
IFE4
Ch4 function enable bit
IFE5
Ch5 function enable bit
IFE6
Ch6 function enable bit
IFE7
Ch7 function enable bit
Figure 1. 23. 18. WG-related register (3)
254
Address
00E616, 012616, 016616, 01A616
When reset
0016
Function
Whether the corresponding port
functions is selected
0 : Disables function on ch i
1 : Enables function on ch i
R W
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Group i function select register (i=0, 1)
b7
b0
Symbol
GiFS (i=0,1)
Bit
symbol
Address
00E716, 012716
Bit name
FSC0
Ch0 TM/WG function
select bit
FSC1
Ch1 TM/WG function
select bit
FSC2
Ch2 TM/WG function
select bit
FSC3
Ch3 TM/WG function
select bit
FSC4
Ch4 TM/WG function
select bit
FSC5
Ch5 TM/WG function
select bit
FSC6
Ch6 TM/WG function
select bit
FSC7
Ch7 TM/WG function
select bit
When reset
0016
Function
R W
Whether the corresponding port
functions as TM or WG is selected
0 : WG function is selected
1 : TM function is selected
Note : In group 0, channles 2, 3, 6 and 7 cannot be selected in 16-bit mode. All channel can be selected
in 32-bit mode.
In group 1, channles 0 and 3 to 5 cannot be selected in 16-bit mode. All channel can be selected
in 32-bit mode.
Group i RTP output buffer register (i=2,3)
b7
b0
Symbol
GiRTP (i=2,3)
Bit
symbol
Address
016716, 01A716
Bit name
RTP0
Ch0 RTP output buffer
RTP1
Ch1 RTP output buffer
RTP2
Ch2 RTP output buffer
RTP3
Ch3 RTP output buffer
RTP4
Ch4 RTP output buffer
RTP5
Ch5 RTP output buffer
RTP6
Ch6 RTP output buffer
RTP7
Ch7 RTP output buffer
When reset
0016
Function
R W
The corresponding port's output
value is set
0 : Output "0"
1 : Output "1"
Figure 1. 23. 19. WG-related register (4)
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Intelligent I/O
(1) Single phase waveform output mode (group 0 to 3)
This mode is set when the base timer value matches the value of WG register j, and reset when the base
timer overflows or the count is reset. Specifications for the single phase waveform output mode are given
in Table 1.23.5 and an operating chart for the single phase waveform output mode in Figure 1.23.20.
Table 1. 23.5. Specifications of single phase waveform output mode
Item
Specifications
Output waveform
•When free run operation
Period
: Base timer count source x 1/65536
"H" level width
: 1/base timer count source x (65536 - m)
•Resetting when the base timer matches WG register 0 (ch0)
Period
: Base timer count source x 1/(k+2)
"H" level width
: 1/base timer count source x (k+2-m)
m : values set to WG register j
k: values set to WG register 0
Waveform output start condition
Write "1" to the function enable bit(Note)
Waveform output stop condition
Write "0" to the function enable bit
Interrupt generation timing
When the base timer value matches the WG register j
OUTC pin
Pulse output (Corresponding pins are set with the function select register.)
Read from the WG register 0
The set value is output
Write to the WG register 0
Can always write
Select function
•Initial value setting function
Sets output level used at waveform output start
•Inverted output function
Inverts waveform output level and outputs the waveform from the OUTC pin
Note: On channels where both the time measurement function and waveform output function can be used, select the
waveform output function for the function select register (addresses 00E716 and 012716).
Reset when channel 0 (xxxa16) is matched
When WG register is "xxxa16"
Count source
xxxa xxxb xxxc xxxd
Base timer
Output
waveform
xxxe
ffff
0000 0001
xxxa xxxb 0000 0001 0002 0003
"H"
"L"
"1"
Interrupt
request flag "0"
Cleared by software.
Figure 1. 23. 20. Operation timing in single phase waveform output mode
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(2) Phase delayed waveform output mode (group 0 to 3)
This mode is repeatedly set and reset when the base timer value matches the value of WG register j.
Specifications for the phase delayed waveform output mode are given in Table 1.23.6 and an operation
timing in phase delayed waveform output mode in Figure 1.23.21.
Table 1. 23.6. Specifications of phase delayed waveform output mode
Item
Specifications
Output waveform
•When free run operation
Period
: Base timer count source x 1/65536 x 1/2
"H" and "L" level width
: 1/base timer count source x 65536
•Resetting when group i base timer matches WG register 0 (ch0)
Period
: Base timer count source x 1/(k+2) x 1/2
"H" and "L" level width
: 1/base timer count source x (k+2)
k : values set to WG register 0
Waveform output start condition
Write "1" to the function enable bit (Note)
Waveform output stop condition
Write "0" to the function enable bit
Interrupt generation timing
When the base timer value matches the WG register j
OUTCij pin
Pulse output (Corresponding pins are set with the function select register.)
Read from the WG register
The set value is output
Write to the WG register
Can always write
Select function
•Initial value setting function
Sets output level used at waveform output start
•Inverted output function
Inverts waveform output level and outputs the waveform from the OUTC pin
Note : On channels where both the time measurement function and waveform output function can be used, select the
waveform output function for the function select register (addresses 00E716 and 012716).
When WG register is "xxxb16"
Count source
Base timer
xxxa xxxb xxxc
Output
waveform
"H"
Interrupt
request flag
"1"
"0"
ffff
0000 0001
xxxa xxxb xxxc
xxxd
"L"
Cleared by software.
Cleared by software.
Figure 1. 23. 21. Operation timing in phase delayed waveform output mode
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(3) SR (Set/Reset) waveform output mode (group 0 to 3)
This mode is set when the base timer value matches the value of WG register j (j is an even-numbered
channel), and reset when the base timer matches the WG register (j + 1) or the base timer value is “0”.
Specifications for the SR waveform output mode are given in Table 1.23.7 and an operating chart for the
SR waveform output mode in Figure 1.23.22.
Table 1. 23.7. Specifications of SR waveform output mode
Item
Output waveform
Specifications
•When free run operation
Period
: Base timer count source x 1/65536
"H" level width
: 1/base timer count source x (m-p)
•Resetting when base timer matches WG register 0 (ch0)
Period
: Base timer count source x 1/(k+2) (Note 1)
"H" level width
: 1/base timer count source x (m-p)
m : values set to WG register j
p : values set to WG register i(j+1)
k : values set to WG register 0 (j is an even-numbered channel) (Note 2)
Waveform output start condition
Write "1" to the function enable bit (Note 3)
Waveform output stop condition
Write "0" to the function enable bit
Interrupt generation timing
When the base timer value matches the WG register j
OUTC pin (Note 4)
Pulse output (Corresponding pins are set with the function select register.)
Read from the WG register
The set value is output
Write to the WG register
Can always write
Select function (Note 5)
•Initial value setting function
Sets output level used at waveform output start
•Inverted output function
Inverts waveform output level and outputs the waveform from the OUTC pin
Note 1: The SR waveform output function that sets and resets the mode on ch0 and 1 cannot be used when the base
timer is reset by WG register 0 (ch0).
Note 2: Set WG register values for odd-numbered channels that are lower than even-numbered channels.
Note 3: On channels where both the time measurement function and waveform output function can be used, select the
waveform output function for the function select register (addresses 00E716 and 012716).
Note 4: SR waveforms are output for even-numbered channels only.
Note 5: Settings for the WG control register on the odd-numbered channels are ignored.
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When WG register j is "xxxb16" and WG register j + 1 is "yyya16"
Count source
Base timer
xxxa xxxb xxxc
Output
waveform
"H"
Channel j Interrupt
request flag
"1"
"0"
Channel j+1 Interrupt
request flag
"1"
"0"
yyy9 yyya yyyb yyyc
"L"
Cleared by software.
Cleared by software.
Figure 1. 23. 22. Operation timing in SR waveform output mode
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(4) Bit modulation PWM output mode (group 2 and 3)
This mode performs PWM to improve output resolution. Specifications for the bit modulation PWM mode
are given in Table 1.23.8 and an operating chart for the bit modulation PWM mode in Figure 1.23.23.
Table 1. 23.8. Specifications of bit modulation PWM mode
Item
Specifications
Output waveform
Period
: Base timer count source x 1/64
"H" level width (avelage)
: 1/base timer count source x [k+(m/1024)]
k : values set to WG register j (six high-order bits)
m : values set to WG register j (ten lower-order bits)
Waveform output start condition
Write "1" to the function enable bit
Waveform output stop condition
Write "0" to the function enable bit
Interrupt generation timing
When the base timer value matches the WG register j
OUTC pin
Pulse output (Corresponding pins are set with the function select register.)
Read from the WG register j
The set value is output
Write to the WG register j
Can always write
Select function
•Initial value setting function
Sets output level used at waveform output start
•Inverted output function
Inverts waveform output level and outputs the waveform from the OUTC pin
Sets PWM width
k=0 to 63 (3F16)
b15
Sets bit modulation frequency
m=0 to 1023 (3FF16)
b10 b9
b0
WG register j
1024 pulses
3F16
Base timer 6
low-order bits
Set value k
0016
k
Output waveform
Base timer
6 low-order bits
3F16
Set value k
0016
Base timer
count source
Internal signal
Output waveform
k
A
AA
AA
Increases the "L" level width for
1 clock cycle for an m number of
pulses out of 1,024
A
k+1
Figure 1. 23. 23. Operation timing in bit modulation PWM mode
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(5) Real-time port output mode (group 2 and 3)
This mode outputs the value set in the real-time port register from the OUTC pin when the base timer
value matches the value of WG register j. Specifications for the real-time port output mode are given in
Table 1.23.9 and a block diagram and timing chart of the real-time port output function in Figure 1.23.24.
Table 1. 23.9. Specifications of real-time port output mode
Item
Specifications
Waveform output start condition
Write "1" to the function enable bit
Waveform output stop condition
Write "0" to the function enable bit
Interrupt generation timing
When the base timer value matches the WG register j
OUTC pin
RTP output (Corresponding pins are set with the function select register.)
Read from the WG register j
The set value is output
Write to the WG register j
Can always write
Read from the RTP output buffer register The set value is output
Write to the RTP output buffer register
Can always write
Select function
•Initial value setting function
Sets output level used at waveform output start
•Inverted output function
Inverts waveform output level and outputs the waveform from the
OUTC pin
Base timer
AAA
AAA
AAA
AAA
AAA
AAA
RTP output buffer register
bit0
WG register 0
bit6
WG register 6
bit7
WG register 7
RTP output
DQ
OUTCi0
T
DQ
OUTCi6
T
DQ
OUTCi7
(i=2, 3)
T
When WG register j = "xxx816" and
bit j of RTP output buffer register = "1" (previous value is 0)
Count source
xxx5 xxx6 xxx7 xxx8
Base timer
xxx9 xxxa
xxxb xxxc xxxd xxxe
xxxf
"H"
Output waveform
"L"
"1"
Channel i
interrupt request flag "0"
Cleared by software.
Figure 1. 23. 24. Block diagram and operation timing of real-time port output function
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(6) Parallel real-time port output mode (group 2 and 3)
This mode outputs the value set in the real-time port register from the OUTC pin when the base timer
value matches the value of WG register j. Specifications for the parallel real-time port output mode are
given in Table 1.23.10 and a block diagram and timing chart of the real-time port output function in Figure
1.23.25.
Table 1. 23.10. Specifications of parallel real-time port output mode
Item
Specifications
Waveform output start condition
Write "1" to the function enable bit
Waveform output stop condition
Write "0" to the function enable bit
Interrupt generation timing
When the base timer value matches the WG register
OUTC pin
RTP output (Corresponding pins are set with the function select
register.)
Read from the WG register
The set value is output
Write to the WG register
Can always write
Read from the RTP output buffer register The set value is output
Write to the RTP output buffer register
Can always write
Select function
•Initial value setting function
Sets output level used at waveform output start
•Inverted output function
Inverts waveform output level and outputs the waveform from the
OUTC pin
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AA
AA
AA
AA
AA
AA
AA
AA
AA
AA
AA
Real-time port output
buffer register
Base timer
bit0
bit1
WG register 0
WG register 1
bit2
WG register 2
bit3
WG register 3
WG register 4
bit4
WG register 5
bit5
WG register 6
WG register 7
bit6
bit7
Real-time port output
DQ
OUTCi0
T
DQ
OUTCi1
T
DQ
OUTCi2
T
DQ
OUTCi3
T
DQ
OUTCi4
T
DQ
OUTCi5
T
DQ
OUTCi6
T
DQ
OUTCi7
T
(i=2, 3)
When WG register j = "xxx116" RTP output buffer register = "0xxx xx012"
WG register j + 1 = "xxx516"
RTP output buffer register = "1xxx xx102"
(this value is saved to RTP output buffer register as channel j interrupt request trigger)
WG register j + 2 = "xxxC16"
RTP output buffer register = "1xxx xx112"
(this value is saved to RTP output buffer register as channel j+1 interrupt request trigger)
Count source
xxx1 xxx2 xxx3 xxx4
Base timer
Output waveform
OUTCi0
Output waveform
OUTCi1
xxx5 xxx6 xxx7
xxxc xxxd xxxe
xxxf
"H"
"L"
"H"
"L"
Output waveform
OUTCi7
"H"
Channel j
interrupt request flag
"1"
"0"
Channel j+1
interrupt request flag
"1"
"0"
Channel j+2
interrupt request flag
"1"
"0"
"L"
Cleared by software.
Cleared by software.
Cleared by software.
Figure 1. 23. 25. Block diagram and operation timing of parallel real-time port output function
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Serial I/O (group 0 to 2)
Intelligent I/O groups 0 to 2 each have two internal 8-bit shift registers. When used in conjunction with the
time measurement (TM) function or WG function, these shift registers enable clock synchronous/asynchronous serial communications.
(1) Clock synchronous serial I/O mode (group 0, 1)
Intelligent I/O groups 0 and 1 each have communication block that have two internal 8-bit shift registers.
When used in conjunction with the communication block and WG function, these shift registers enable
8-bit clock synchronous and HDLC data process function. When used in conjunction with the communication block, TM function and WG function, these shift registers enable 8-bit clock asynchronous communication.
Table 1.23.11 lists using registers in group 0 and 1, figure 1.23.26 to 1.23.29 shows the related registers.
Table 1.23.11. Using registers in group 0 and 1
Clock synchronous serial I/O
UART
HDLC
Base timer control register 0
√
√
√
Base timer control register 1
√
√
√
Time measument control register 2
–
√
–
Waveform generate control register 0
√
√
√
Waveform generate control register 1
–
–
√
Waveform generate control register 2
√
√
–
Waveform generate control register 3
√
√
–
Waveform generate register 0
√
√
√
Waveform generate register 1
√
–
√
Time measument /Waveform generate register 2
√
√
–
Waveform generate register 3
√
√
–
Function select register
√
√
√
Function enable register
√
√
√
SI/O communication mode register
√
√
√
SI/O extended mode register
–
–
√
SI/O communication control register
√
√
√
SI/O extended transmit control register
–
–
√
SI/O extended receive control register
–
–
√
SI/O special communication interrupt detect register
–
–
√
SI/O receive buffer register
√
√
√
Transmit buffer
√
√
√
(Receive data register )
–
–
√
Data compare register j (j=0 to 3)
–
–
√
Data mask register j (j=0, 1)
–
–
√
Transmit CRC code register
–
–
√
Receive CRC code register
–
–
√
Transmit output register
–
–
√
Receive input register
–
–
√
√ : Use
264
– : Not use
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group i receive input register (i=0,1)
b7
b0
Symbol
Address
00EC16, 012C16
GiRI (i=0, 1)
When reset
Indeterminate
Function
Setting range
Data that is input to the receive data
process unit
R W
0016 to FF16
Group i transmit output register (i=0,1)
b7
b0
Symbol
Address
When reset
GiTO (i=0, 1)
00EE16, 012E16
Indeterminate
Function
Setting range
R W
Data that is output from the transmit data
process unit
Group i SI/O communication control register (i=0,1)
b7
b0
Symbol
GiCR (i=0,1)
Bit
symbol
Address
00EF16, 012F16
Bit name
When reset
0000 X0002
Function
Transmit buffer
empty flag
0 : Data present in transmit buffer register
1 : No data present in transmit buffer register
TXEPT
Transmit register
empty flag
0 : Data present in transmit register
(during transmission)
1 : No data present in transmit register
(transmission completed)
RI
Receive complete
flag
0 : No data present in receive buffer register
1 : Data present in receive buffer register
TI
R W
Nothing is assigned. When write, set to "0".
When read, the contents is indeterminate.
TE
Transmit enable bit
0 : Transmission disabled
1 : Transmission enabled
RE
Receive enable bit
0 : Reception disabled
1 : Reception enabled
IPOL
RxD input polarity
reverse select bit
0 : No reverse (Usually set to "0")
1 : Reverse
(Note)
OPOL
TxD output polarity 0 : No reverse (Usually set to "0")
(Note)
1 : Reverse
reverse select bit
Note :This bit is set to "1" in UART mode.
Figure 1. 23. 26. Group 0 and 1 related register (1)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group i SI/O receive buffer register (i=0,1)
b15 b14 b13 b12 b11 b10 b9 b8
(b7)(b6)(b5)(b4)(b3)(b2)(b1)(b0) b7
b0
Symbol
GiBF(i=0,1)
Bit
symbol
Address
00E916,00E816, 012916,012816
When reset
Indeterminate
Bit name
Function
Receive buffer
R W
Receive data
Nothing is assigned.
When read, their value are indeterminate.
OER
FER
PER
Overrun error flag
0 : No overrun error
(Note) 1 : Overrun error found
Framing error flag
0 : No Framing error
(Note) 1 : Framing error found
Parity error flag
(Note)
0 : No parity error
1 : Parity error found
Nothing is assigned.
When read, its value is indeterminate.
Note: Only effective for receive data.
Group i SI/O communication mode register (i=0,1)
b7
b0
Symbol
Address
00ED16, 012D16
GiMR (i=0,1)
Bit
symbol
When reset
0016
Bit name
Function
R W
b1 b0
GMD0
Communication mode
select bit
GMD1
0
0
1
1
0
1
0
1
: UART mode
: Serial I/O mode
: Special communication mode
: HDLC data process mode
CKDIR
Internal/external clock
select bit
0 : Internal clock
1 : External clock
STPS
Stop bit length
(Note 1)
select bit
0 : 1 stop bit
1 : 2 stop bits
PRY
Odd/even parity
select bit
(Note 1)
0 : Odd parity
1 : Even parity
PRYE
Parity enable
select bit
(Note 1)
0 : Parity disabled
1 : Parity enabled
UFORM
Transfer direction
select bit
0 : LSB first
1 : MSB first
IRS
Transmit interrupt
cause select bit
0 : Transmit buffer is empty
1 : Transmit is completed
(Note 2)
(Note 3)
Note 1: Can be used only in the UART mode.
Note 2: Select a pin for clock output by setting the waveform generation control register, input function select
register, and function select registers A, B and C.
Data transmission pins are the same as clock output pins.
Note 3: Select which pins will input the clock with the input function select register and set those pins to the
input port using function select register A.
Data input pins are the same as with clock input pins.
Figure 1. 23. 27. Group 0 and 1 related register (2)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group i SI/O expansion mode register (i=0,1) (Note 1)
b7
b0
Symbol
GiEMR (i=0,1)
Bit
symbol
Address
00FC16, 013C16
When reset
0016
Bit name
Function
Synchronous mode
select bit
0 : Normal mode
1 : Resynchronous mode
CRCV
CRC initial value
select bit
0 : "000016" is set
1 : "FFFF16" is set
ACRC
CRC initialization
select bit
0 : Not initialize
1 : Initialize
BSINT
Bit stuffing error
interrupt select bit
0 : Not use
1 : Use
RXSL
Reception source
select bit
0 : RxD pin
1 : Receive input register
TXSL
Transmission source
select bit
0 : TxD pin
1 : Transmit output register
SMODE
R W
(Note 2)
b7 b6
CRC0
CRC polynomial
select bit
CRC1
0
0
1
1
0
1
0
1
: X8+X4+X+1
: Must not be set
: X16+X15+X2+1
: X16+X12+X5+1
Note 1: Other than when in the special communication mode or HDLC data process mode, either
use the reset state as is or write "0016".
Note 2: Initialized when the data compare register matches.
Group i SI/O expansion transmit control register (i=0,1) (Note)
b7
b0
Symbol
GiETC (i=0,1)
Bit
symbol
Address
00FF16, 013F16
When reset
00000XXX2
Bit name
Function
R W
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
SOF
SOF transmit
request bit
0 : No SOF transmit request
1 : SOF transmit request
TCRCE
Transmit CRC
enable bit
0 : Not use
1 : Use
ABTE
Arbitration enable bit
0 : Not use
1 : Use
TBSF0
Transmit bit stuffing "1"
insert select bit
0 : "1" is not inserted
1 : "1" is inserted
TBSF1
Transmit bit stuffing "0"
insert select bit
0 : "0" is not inserted
1 : "0" is inserted
Note : Other than when in the special communication mode or HDLC data processing mode, either
use the reset state as is or write "0016".
Figure 1. 23. 28. Group 0 and 1 related register (3)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group i SI/O expansion receive control register (i=0,1) (Note 1)
b7
b0
Symbol
Address
00FD16, 013D16
GiERC (i=0,1)
Bit
symbol
CMP0E
CMP1E
CMP2E
CMP3E
RCRCE
RSHTE
RBSF0
RBSF1
When reset
0016
Bit name
Function
Data compare
function 0
select bit
Data compare
function 1
select bit
Data compare
function 2
select bit
Data compare
function 3
select bit
0 : Does not compare the received data with
data compare register 0
1 : Compare the received data with data compare register 0
0 : Does not compare the received data with
data compare register 1
1 : Compare the received data with data compare register 1
0 : Does not compare the received data with
data compare register 2
1 : Compare the received data with data compare register 2
0 : Does not compare the received data with
(Note 2)
data compare register 3
1 : Compare the received data with data compare register 3
Receive CRC
enable bit
0 : Not enable
1 : Enable
Receive shift
operation
enable bit
Receive bit
stuffing "1" delete
select bit
Receive bit
stuffing "1" delete
select bit
0 : Receive shift operation disabled
1 : Receive shift operation enabled
R W
0 : "1" is not deleted
1 : "1" is deleted
0 : "0" is not deleted
1 : "0" is deleted
Note 1: Other than when in the special communication mode or HDLC data processing mode, either
use the reset state as is or write "0016".
Note 2: To use the CRC initialization function (when bit 2 of SI/O expansion mode register is set to "1"),
set bit 3 to "1".
Group i special communication interrupt detect register (i=0,1) (Note)
b7
b0
Symbol
GiIRF (i=0,1)
Bit
symbol
Address
00FE16, 013E16
Bit name
When reset
0000 00XX2
Function
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
BSERR
ABT
IRF0
IRF1
IRF2
IRF3
Bit stuffing error 0 : Not detected
1 : Detected
detecting flag
Arbitration lost
detecting flag
Interrupt cause
determination
flag 0
Interrupt cause
determination
flag 1
Interrupt cause
determination
flag 2
Interrupt cause
determination
flag 3
0 : Not detected
1 : Detected
0 : Received data does not match data
compare register 0
1 : Received data matches data compare register 0
0 : Received data does not match data
compare register 1
1 : Received data matches data compare register 1
0 : Received data does not match data
compare register 2
1 : Received data matches data compare register 2
0 : Received data does not match data
compare register 3
1 : Received data matches data compare register 3
Note : Other than when in the special communication mode or HDLC data processing mode, either
use the reset state as is or write "0016".
Figure 1. 23. 29. Group 0 and 1 related register (4)
268
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group i transmit buffer/receive data register (i=0,1)
b7
b0
Symbol
Address
When reset
GiDR (i=0,1)
00EA16, 012A16
Indeterminate
Function
Setting range
R W
Transmit data for data compare is stored
Receive data for data compare is stored
Group i data compare register j (i=0,1/j=0 to 3)
b7
b0
Symbol
GiCMPj (i=0/j=o to 3)
GiCMPj (i=1/j=o to 3)
Address
00F016, 00F116, 00F216, 00F316
013016, 013116, 013216, 013316
Function
When reset
Indeterminate
Indeterminate
Setting range
Compare data
R W
0016 to FF16
Note : When using the data compare registers 0 and 1, the data mask registers 0 and 1 must be set.
Group i data mask register j (i=0,1/j=0,1)
b7
b0
Symbol
GiMSKj (i=0/j=0, 1)
GiMSKj (i=1/j=0, 1)
Address
00F416, 00F516
When reset
Indeterminate
013416, 013516
Indeterminate
Function
Setting range
Mask data for receive data (masked by "1")
0016 to FF16
R W
Group i transmit CRC code register (i=0,1)
b15
(b7)
b8
(b0) b7
b0
Symbol
Address
00FB16,00FA16, 013B16, 013A16
GiTCRC (i=0, 1)
Function
When reset
000016
Setting range
R W
Transmit CRC calculation results
(Note)
Note : Computed results are initialized when the transmit CRC enable bit (bit 4 of group i expanded
transmit control register) is set to "0".
Group i receive CRC code register (i=0,1)
b15
(b7)
b8
(b0) b7
b0
Symbol
Address
When reset
GiRCRC (i=0, 1)
00F916,00F816, 013916, 013816
000016
Function
Setting range
R W
Receive CRC calculation results
Note 1: Computed results are initialized when the receive CRC enable bit (bit 4 of group i expanded
reseive control register) is set to "0", or when the CRC initialization bit (bit 2 of group i SI/O
expansion mode register) is set to "1" and values match the data comparison register.
Note 2: Initialize to selected value when starting to receive.
Figure 1. 23. 30. Group 0 and 1 related register (5)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
• Clock synchronous serial I/O mode (group 0 and 1)
Table 1.23.12 gives specifications for the clock synchronous serial I/O mode.
Table 1.23.12. Specifications of clock synchronous serial I/O mode (group 0 and 1)
Item
Specification
Transfer data format
• Transfer data length:
Transfer clock
• When internal clock is selected
_ Transfer speed is determined when the base timer is reset by the ch0 WG function
8 bits fixed
Transfer rate (bps) = base timer count source (frequency) / (k+2) / 2
k : values set to WG register 0
_
Transfer clock is generated when the transfer clock in the phase delayed
waveform output mode
Transmit clock : ch3 WG function
Receive clock : ch2 WG function
Sets the same value in the WG registers on ch2 and ch3
• When external clock is selected
_
Transfer rate (bps) = Clock input to ISCLK pin
Transmission start condition To start transmission, the following requirements must be met:
• Transmit enable bit = “1”
• Write data to transmit buffer
Reception start condition
To start reception, the following requirements must be met:
• Receive enable bit = “1”
Interrupt request
generation timing
• When transmitting
_
_
When transmit buffer is empty, transmit interrupt cause select bit = “0”
When transmission is completed, transmit interrupt cause select bit = “1”
• When receiving
When data is transferred to SI/O receive buffer register
Error detection
• Overrun error
This error occurs when the next data is ready before the contents of SI/O receive
buffer register are read out
Select function
• LSB first/MSB first selection
When transmission/reception begins with bit 0 or bit 7, it can be selected
• Transmit/receive data polarity switching
This function is reversing ISTxD pin output and ISRxD pin input.
(All I/O data level is reversed.)
Note: Set the transmission clock to at least 6 divisions of the base timer clock.
Table 1.23.13 lists I/O pin functions for the clock synchronous serial I/O mode of groups 0 and 1.
From when the operating mode is selected until transmission starts, the ISTxDi pin is "H" level. Figure
1.23.31 shows typical transmit/receive timings in clock synchronous serial I/O mode in group 0 and 1.
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Table 1.23.13. I/O pin functions in clock synchronous serial I/O mode of group 0, group 1
Pin name
Function
Selected method
ISTxD
Serial data output
(P76, P150, P73, P110)
• Use the ch0 WG function
• Sets "111" for the operating mode select bit (bits 2, 1 and 0) in
WG control register 0
• Selects ISTxD output for the port using function select registers
A, B and C
ISRxD
Serial data input
(P80, P152, P75, P112)
• Selects a using port with input function select register
• Selects I/O with function select register A
• Sets a selected port to input using the port direction register
ISCLK
Transfer clock output
(P77, P151, P74, P111)
• Use the ch1 WG function
• Sets "111" for the operating mode select bit (bits 2, 1 and 0) in
WG control register 1
• Sets "0" for the internal/external clock select bit (bit 2) of the
SI/O communication mode register
• Selects ISCLK output for the port using function select registers
Transfer clock input
A, B and C
• Selects a using port with input function select register
• Sets "1" for the internal/external clock select bit (bit 2) of the
SI/O communication mode register
• Sets a selected port to input using the port direction register
• Selects I/O port with function select register A
Write to transmit buffer
T
Base timer resets using
ch0 WG function
Base timer
t
Receive clock using
ch2 WG function
Transmit clock using
ch3 WG function
Receive data
bit 0
(Input to INPCi2/ISRxDi pin
(i=0,1))
Transmit data
bit 0
bit 1
bit 1
bit 6
bit 2
bit 6
bit 7
bit 7
T: Transfer rate/2
t : Values set to ch2 WG register
Values set to ch3 WG register
Figure 1.23.31. Typical transmit/receive timings in clock synchronous serial I/O mode in group 0 and 1
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
(2) Clock asynchronous serial I/O mode (UART) (group 0 and 1)
Table 1.23.14 lists the specifications for the UART mode.
Table 1.23.14. Specifications of UART mode
Item
Specification
Transfer data format
• Character bit (transfer data)
• Start bit
: 8 bits
: 1 bit
• Parity bit
: Odd, even, or nothing selected
• Stop bit
: 1 bit or 2 bits selected
Transfer clock
• When internal clock is selected (Generates the transmit/receive clock in the phase
delayed waveform output mode)
Transfer speed is determined when the base timer is reset by the ch0 WG function
_
Transfer rate (bps) = base timer count source (frequency) / (k+2) / 2
k : values set to WG register 0
_
Transfer clock is generated when the transfer clock in the phase delayed
waveform output mode
Transmit clock : ch3 WG function
Receive clock : Change ch2 TM function to WG function
Detects falling edge of start bit
Changes to the WG mode when the time measurement interrupt arrives
• When external clock is selected
_
Transfer rate (bps) = Clock input to ISCLK pin
Transmission start condition To start transmission, the following requirements must be met:
• Transmit enable bit = “1”
• Write data to transmit buffer
Reception start condition
To start reception, the following requirements must be met:
Interrupt request
generation timing
• When transmitting
_ When transmit buffer is empty, transmit interrupt cause select bit = “0”
• Receive enable bit = “1”
_
When transmission is completed, transmit interrupt cause select bit = “1”
• When receiving
_
Error detection
When data is transferred to SI/O receive buffer register
• Overrun error
: This error occurs when the next data is ready before contents
• Framing error
of SI/O receive buffer register are read out
: This error occurs when the number of stop bits set is not detected
• Parity error
: This error occurs when if parity is enabled, the number of 1’s in
• Stop bit length
• Parity
: Stop bit length can be selected as 1 bit or 2 bits
: Parity can be turned on/off
parity and character bits does not match the number of 1’s set
Select function
: When parity is on, odd/even parity can be selected
• LSB first/MSB first selection :
Whether transmit/receive begins with bit 0 or bit 7 can be selected
• Transmit/receive data polarity switching :
This function is reversing ISTxD port output and ISRxD port input. (All I/O data level
are reversed.)
• Data transfer bit length
272
: Transmission data length can be set between 1 to 8 bits
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Write to transmit buffer
Base timer resets using ch0 WG function
k+2
Base timer
t
Transmit clock using
ch3 WG function
Start Bit
Transmit data
bit 0
bit 7
Parity
Stop Bit (1 bit)
t : Values set to ch3 WG register
Figure 1.23.32. Typical transmit timings in UART mode
Base timer resets using ch0 WG function
t : Values set to ch2 WG register
k+2
Base timer
t
Receive data
(Input to INPCi2/ISRxDi pin
(i=0,1))
Start Bit
bit 0
bit 7
Parity
Stop Bit (1 bit)
Receive clock using
ch2 WG function
Interrupt request
signal
Reception completed
interrupt request
Figure 1.23.33. Typical receive timing in UART mode
TxD, RxD I/O polarity reverse function
This function is to reverse TxD pin output and RxD pin input. The level of any data to be input or output
(including the start bit, stop bit(s), and parity bit) are reversed. TxD output polarity reverse select bit is
set to “0” (not to reverse) for usual use.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
(2) Clock synchronous serial I/O mode (group 2)
Intelligent I/O groups 2 has communication block that have two internal 8-bit shift registers. When used
in conjunction with the communication block and WG function, these shift registers enable variable clock
synchronous and IE Bus (Note) communications.
Table 1.23.16 lists using registers in group 2, figure 1.23.34 to 1.23.37 shows the related registers.
Note : IE Bus is a trademark of NEC corporation.
Table 1.23.16. Using registers in group 2
Clock synchronous serial I/O
IE Bus
Base timer control register 0
√
√
Base timer control register 1
√
√
Waveform generate control register 0
√
√
Waveform generate control register 1
–
√
Waveform generate control register 2
√
√
Waveform generate control register 3
–
√
Waveform generate control register 4
–
√ (Note 1)
Waveform generate control register 5
–
√
Waveform generate control register 6
–
√
Waveform generate control register 7
–
√
Waveform generate register 0
√
√
Waveform generate register 1
–
√
Waveform generate register 2
√
√
Waveform generate register 3
–
√
Waveform generate register 4
–
√
Waveform generate register 5
–
√
Waveform generate register 6
–
√
Waveform generate register 7
–
√
Function enable register
√
√
SI/O communication mode register
√
√
SI/O communication control register
√
√
IE Bus control register
–
√
IE Bus address register
–
√
IE Bus transmit interrupt cause detect register
–
√
IE Bus receive interrupt cause detect register
–
√
SI/O receive buffer register
√
√
SI/O transmit buffer register
√
√
√ : Use – : Not use
Note 1: When receiving slave, set corresponding value with 32.5 µs. Don't set 170 µs.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group 2 SI/O transmit buffer register
b15 b14 b13 b12 b11 b10 b9 b8
(b7)(b6)(b5)(b4)(b3)(b2)(b1)(b0) b7
b0
Symbol
G2TB
Bit
symbol
Address
016D16, 016C16
When reset
Indeterminate
Bit name
Transmit buffer
Function
R W
Transmit data
b10 b9 b8
SZ0
SZ1
Transfer bit length
select bit
SZ2
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
: 8-bit long
: 1-bit long
: 2-bit long
: 3-bit long
: 4-bit long
: 5-bit long
: 6-bit long
: 7-bit long
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
0 : No function
1 : Adds an ACK bit after the final
transmission bit
0 : Adds the parity bit after the transmitted data
Parity operation
1 : Repeats the parity check with the next
continuing bit (Note)
transmission
0 : No parity
Parity function
1 : Parity (Only even parity)
select bit
ACK function
select bit
A
PC
P
Note: When this bit is set to "1", set the parity function select bit to "0".
Group 2 SI/O receive buffer register
b15 b14 b13 b12 b11 b10 b9 b8
(b7)(b6)(b5)(b4)(b3)(b2)(b1)(b0) b7
b0
Symbol
G2RB
Bit
symbol
Address
016F16, 016E16
When reset
Indeterminate
Bit name
Receive buffer
Function
R W
Receive data
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
OER
Overrun error flag
0 : No overrun error
(Note) 1 : Overrun error found
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
Note : This bit is automatically set to "0" when communication unit reset is selected for the communication
mode select bit and the reception enable bit is set to "0".
Figure 1. 23. 34. Group 2 Intelligent I/O-related register (1)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group 2 IE Bus control register
b7
b0
Symbol
Address
017216
IECR
Bit
symbol
IEB
IETS
IEBBS
When reset
00XXX0002
Bit name
Function
R W
IE Bus enable bit
0 : IE Bus disabled
1 : IE Bus enabled
IE Bus transmit start
request bit
0 : Transmit completed
1 : Transmit start
IE Bus busy flag
0 : Idle state
1 : Busy state (start condition detected)
(Note)
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
DF
Digital filter
select bit
0 : No digital filter
1 : Digital filter
IEM
IE Bus mode
select bit
0 : Mode 1
1 : Mode 2
Note :When this bit is set to "0", hold "0" for at least 1 cycle of base timer .
Group 2 IE Bus address register
b15 b14 b13 b12 b11 b10 b9 b8
(b7)(b6)(b5)(b4)(b3)(b2)(b1)(b0) b7
b0
Symbol
IEAR
Address
017116, 017016
Function
Address data
Address data
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
Figure 1. 23. 35. Group 2 Intelligent I/O-related register (2)
276
When reset
Indeterminate
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group 2 IE Bus transmit interrupt cause determination register
b7
b0
Symbol
Address
017316
IETIF
Bit
symbol
When reset
XXX000002
Bit name
Function
R W
IETNF
Normal termination
flag
0 : Terminated in error
1 : Terminated normally
(Note)
IEACK
ACK error flag
0 : No error
1 : Error found
(Note)
IETMB
Max. transfer byte
error flag
0 : No error
1 : Error found
(Note)
Timing error flag
0 : No error
1 : Error found
(Note)
Arbitration lost flag
0 : No error
1 : Error found
(Note)
IETT
IEABL
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
Note : Only "0" can be written for this bit. Also, it is cleared to "0" when "0" is written for bit 0 of the IE Bus
control register. At this time, hold "0" for at least 1 cycle of base timer clock.
Group 2 IE Bus receive interrupt cause determination register
b7
b0
Symbol
IERIF
Bit
symbol
Address
017416
When reset
XXX000002
Bit name
Function
R W
IERNF
Normal termination
flag
0 : Terminated in error
1 : Terminated normally
(Note)
IEPAR
Parity error flag
0 : No error
1 : Error found
(Note)
IERMB
Max. transfer byte
error flag
0 : No error
1 : Error found
(Note)
Timing error flag
0 : No error
1 : Error found
(Note)
Other cause receive
completed flag
0 : No error
1 : Error found
(Note)
IERT
IERETC
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
Note : Only "0" can be written for this bit. Also, it is cleared to "0" when "0" is written for bit 0 of the IE Bus
control register. At this time, hold "0" for at least 1 cycle of base timer clock.
Figure 1. 23. 36. Group 2 Intelligent I/O-related register (3)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Group 2 SI/O communication mode register
b7
b0
Symbol
G2MR
Bit
symbol
Address
016A16
When reset
00XXX0002
Bit name
Function
R W
b1 b0
GMD0
Communication mode
select bit
GMD1
Internal/external clock
select bit
CKDIR
0 0 : Communication part is reset
(Overrun error flag is cleared)
0 1 : Serial I/O mode
1 0 : Special communication mode
1 1 : HDLC data process mode
0 : Internal clock
1 : External clock
(Note 2)
(Note 3)
Nothing is assigned. When write, set "0".
When read, their contents are indeterminate.
UFORM
Transfer direction
select bit
0 : LSB first
1 : MSB first
IRS
Transmit interrupt
cause select bit
0 : Transmit buffer is empty
1 : Transmit is completed
Note 1: Intelligent I/O group 2 has IE bus communication function as special communication function.
Note 2: Select a pin for clock output by setting the waveform generation control register, input function select
register, and function select registers A, B and C. Data transmission pins are the same as clock
output pins.
Note 3: Select which pins will input the clock with the input function select register and set those pins to the
input port using function select register A. Data input pins are the same as with clock input pins.
Group 2 SI/O communication control register
b7
b0
Symbol
G2CR
Address
016B16
When reset
0000 X0002
Bit
symbol
Bit name
TE
Transmit enable bit
0 : Transmission disabled
1 : Transmission enabled
Transmit register
empty flag
0 : Data present in transmit register
(during transmission)
1 : No data present in transmit register
(transmission completed)
Transmit buffer
empty flag
0 : Data present in transmit buffer register
1 : No data present in transmit buffer register
TXEPT
TI
Function
Nothing is assigned. When write, set to "0".
When read, the contents is indeterminate.
RE
Receive enable bit
0 : Reception disabled
1 : Reception enabled
RI
Receive complete
flag
0 : No data present in receive buffer register
1 : Data present in receive buffer register
OPOL
TxD output polarity
reverse select bit
0 : No reverse (Usually set to "0")
1 : Reverse
IPOL
RxD input polarity
reverse select bit
0 : No reverse (Usually set to "0")
1 : Reverse
Figure 1. 23. 37. Group 2 Intelligent I/O-related register (4)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
• Clock synchronous serial I/O mode (group 2)
Table 1.23.17 gives specifications for the group 2 clock synchronous serial I/O mode.
Table 1.23.17. Specifications of clock synchronous serial I/O mode
Item
Specification
Transfer data format
• Transfer data length:
Transfer clock
• When internal clock is selected, the transfer clock in the single waveform output
mode is generated.
_
_
Variable length (group2)
Transfer speed is determined when the base timer is reset by the ch0 WG function
Transfer rate (bps) = base timer count source (frequency) / (k+2)
k : values set to WG register 0
Transfer clock is generated by ch2 single phase WG function
Ch3 WG register = (k+2)/2 (Note 1)
• When external clock is selected
_
Transfer rate (bps) = Clock input to ISCLK pin (Note 2)
Transmission start condition • To start transmission, the following requirements must be met:
_ Transmit enable bit = “1”
_
Reception start condition
Interrupt request
generation timing
Write data to SI/O transmit buffer register
• To start reception, the following requirements must be met:
_
Receive enable bit = “1”
_
Transmit enable bit = “1”
_
Write data to SI/O transmit buffer register
• When transmitting
_
When SI/O communication buffer register is empty, transmit interrupt cause select
bit = “0”
_
When transmission is completed, transmit interrupt cause select bit = “1”
• When receiving
_
Error detection
When data is transferred to SI/O receive buffer register
• Overrun error
This error occurs when the next data is ready before the contents of SI/O receive
buffer register are read out
Select function
• LSB first/MSB first selection
When transmission/reception begins with bit 0 or bit 7, it can be selected.
• Transmit/receive data polarity switching
_ This function is reversing ISTxD pin output and ISRxD pin input.
(All I/O data level is reversed.)
• Data transfer bit length
_
Transmission data length can be set between 1 to 8 bits
Note 1: When the transfer clock and transfer data are transmission, transfer clock is set to at least 6 divisions of the base timer clock. Except this, transfer clock is set to at least 20 divisions of the base
timer clock.
Note 2: Transfer clock is set to at least 20 divisions of the base timer clock.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Intelligent I/O (Serial I/O)
Base timer resets using
ch0 WG function
k+2
Base timer
t
Writes data to the transmit register
(8 bits)
Writes data to the transmit register
(4 bits)
Transmit/Receive clock
using ch2 WG function
First writing to
the transmit buffer
bit 0
bit 7
bit 6
bit 2
bit 1
Second writing to
the transmit buffer
Receive data
bit 8
bit 0
bit 1
bit 2
bit 5
bit 6
bit 7
bit 10
bit 9
bit 8
Transfer to the receive register
bit 9
bit 11
bit 10
bit 11
Transfer to the receive register
t : Values set to ch2 WG register
Values set to ch3 WG register
Figure 1. 23. 38. Typical transmit/receive timings in clock synchronous serial I/O mode in group 2
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
A-D Converter
The A-D converter consists of two 10-bit successive approximation A-D converter circuit with a capacitive
coupling amplifier. Pins P100 to P107, P150 to P157, P00 to P07, P20 to P27, P95, and P96 are shared as the
analog signal input pins. Pins P150 to P157, P00 to P07 and P20 to P27 can be used as the analog signal
input pins and switched by analog input port select bit. However, P00 to P07 and P20 to P27 can be used in
single chip mode. Set input to direction register corresponding to a pin doing A-D conversion.
The result of A-D conversion is stored in the A-D registers of the selected pins.
Table 1.24.1 shows the performance of the A-D converter. Figure 1.24.1 shows the block diagram of the
A-D converter, and Figures 1.24.2 to 1.24.7 show the A-D converter-related registers.
This section is described to 144-pin version as example.
In 100-pin version, AN10 to AN17 cannot be selected because there is no P15.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
AN20
000
AN21
001
ADiCON2 :
TRG1, TRG0
AN22
010
ADTRG
AN23
011
TB2INT
EX TRGi
IIOG2 ch1 INT (i=0)
or
IIOG3 ch1 INT (i=1)
AN24
100
ADiCON0 :
TRG
AN25
101
AN26
110
AN27
111
AN00
000
AN01
001
AN02
010
AD0CON1 :
OPA0, OPA1
AN03
011
AN04
100
P96 ANEX1
AN0
01
11
11
010
AN3
011
AN4
001
00
01
010
1
0
1
AN153
AN154 P15
AN155
101
AN156
110
AD0CON0 :
CH2, CH1, CH0
111
AD1CON0 :
CH2, CH1, CH0
Comparator 0
AN157
111
Comparator 1
Address
A-D1 register 0
(01C116, 01C016)
(038316, 038216)
A-D0 register 1
A-D1 register 1
(01C316, 01C216)
(038516, 038416)
A-D0 register 2
A-D1 register 2
(01C516, 01C416)
(038716, 038616)
A-D0 register 3
A-D1 register 3
(01C716, 01C616)
(038916, 038816)
A-D0 register 4
A-D1 register 4
(01C916, 01C816)
(038B16, 038A16)
A-D0 register 5
A-D1 register 5
(01CB16, 01CA16)
(038D16, 038C16)
A-D0 register 6
A-D1 register 6
(01CD16, 01CC16)
(038F16, 038E16)
A-D0 register 7
A-D1 register 7
(01CF16, 01CE16)
Successive
conversion register
Successive
conversion register
Resister ladder
Resister ladder
Decoder
A-D0 register 0
Decoder
Address
(038116, 038016)
AD0 control register 0
(address 039616)
AD0 control register 1
(address 039716)
1
1/2
1
1
0
1
fAD
AD1 control register 0
(address 01D616)
AD1 control register 1
(address 01D716)
1/3
1
1/3
0
ØAD0
0
1/2
1
fAD
1/2
1/2
0
AD0CON0 : CSK0
AD0CON1 : CSK1
Figure 1.24.1. Block diagram of A-D converter
282
AN152
100
AD0CON2 : ADS
110
AN7
AN151
011
0
101
AN6
10
00
100
AN5
AN150
000
AD1CON2 :
APS1, APS0
001
AN2
AN07
111
000
AN1
P10
AN06
110
1X
P0
AN05
101
X1
P95 ANEX0
P2
0
AD1CON0 : CSK0
AD1CON1 : CSK1
ØAD1
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
Table 1.24.1. Performance of A-D converter
Item
Performance
Method of A-D conversion
Successive approximation (capacitive coupling amplifier)
Analog input voltage (Note 1)
0V to AVCC (VCC)
Operating clock ØAD (Note 2)
fAD, fAD/2, fAD/3 , fAD/4
Resolution
8-bit or 10-bit (selectable)
Operating modes
One-shot mode, repeat mode, single sweep mode, repeat sweep mode 0,
fAD=f(XIN)
and repeat sweep mode 1
Analog input pins
34 pins
AN, AN0, AN2, AN15(Note 3) each 8 pins
Extended input 2 pins (ANEX0(Note 4) and ANEX1(Note 5))
A-D conversion start condition
• Software trigger
A-D conversion starts when the A-D conversion start flag changes to “1”
• External trigger (can be retriggered)
A-D conversion starts by outbreak of the following factors chosen among in three
(Note 6)
· ADTRG/P97 input changes from “H” to “L”
· Timer B2 interrupt occurrences frequency counter overflow
· Interrupt of Intelligent I/O group 2 or 3 channel 1
Conversion speed per pin
• Without sample and hold function
8-bit resolution: 49 ØAD cycles
10-bit resolution: 59 ØAD cycles
• With sample and hold function
8-bit resolution: 28 ØAD cycles
10-bit resolution: 33 ØAD cycles
Note 1: Does not depend on use of sample and hold function.
Note 2: When f(XIN) is over 10 MHz, the fAD frequency must be under 10 MHz by dividing.
Without sample and hold function, set the fAD frequency to 250kHz or more.
With the sample and hold function, set the fAD frequency to 1MHz or more.
Note 3: When port P15 is used as analog input port, port P15 input peripheral function select bit (bit 2 of address
017816) must set to be "1".
Note 4: When port P95 is used as analog input port, port P95 output peripheral function select bit (bit 5 of address
03B716) must set to be "1".
Note 5: When port P96 is used as analog input port, port P96 output peripheral function select bit (bit 6 of address
03B716) must set to be "1".
Note 6: Set the port direction register to input.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
A-D0 control register 0
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1)
Symbol
Address
AD0CON0
039616
Bit
symbol
When reset
0016
Bit name
Function
R W
b2 b1 b0
CH0
CH1
Analog input pin
select bit
CH2
0 0 0 : AN0
0 0 1 : AN1
0 1 0 : AN2
0 1 1 : AN3
1 0 0 : AN4
1 0 1 : AN5
1 1 0 : AN6
1 1 1 : AN7
(Note 2, 3)
b4 b3
A-D operation
mode select bit 0
0 0 : One-shot mode
0 1 : Repeat mode
1 0 : Single sweep mode
1 1 : Repeat sweep mode 0
Repeat sweep mode 1
TRG
Trigger select bit
0 : Software trigger
1 : External trigger
(Note 4)
ADST
A-D conversion
start flag
0 : A-D conversion disabled
1 : A-D conversion started
(Note 5)
CKS0
Frequency select
bit
(Note 6)
0 : fAD/3 or fAD/4 is selected
1 : fAD/1 or fAD/2 is selected
MD0
MD1
(Note 2)
Note 1: If the A-D0 control register 0 is rewritten during A-D conversion, the conversion result is indeterminate.
Note 2: When changing A-D operation mode, set analog input pin again.
Note 3: This bit is disabled in single sweep mode, repeat sweep mode 0 and repeat sweep mode 1.
Note 4: External trigger request cause can be selected in external trigger request cause select bit (bit5
and bit 6 of address 039416).
Note 5: When External trigger is selected, set to "1" after selecting the external trigger request cause
using the external trigger request cause select bit.
Note 6: When f(XIN) is over 10 MHz, the
AD frequency must be under 10 MHz by dividing.
Figure 1.24.2. A-D converter-related registers (1)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
A-D0 control register 1
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1)
Symbol
AD0CON1
Bit
symbol
Address
039716
When reset
0016
Bit name
Function
R W
b0 b1
SCAN0
A-D sweep pin
select bit
0 0 : ANj0, ANj1 (ANj0)
0 1 : ANj0 to ANj3 (ANj0, ANj1) (Note 2, 3)
1 0 : ANj0 to ANj5 (ANj0 to ANj2)
1 1 : ANj0 to ANj7 (ANj0 to ANj3)
MD2
A-D operation
mode select bit 1
0 : Any mode other than repeat sweep mode 1
1 : Repeat sweep mode 1
BITS
8/10-bit mode
select bit
0 : 8-bit mode
1 : 10-bit mode
CKS1
Frequency select
0 : fAD/2 or fAD/4 is selected
bit
(Note 3) 1 : fAD/1 or fAD/3 is selected
VCUT
VREF connect bit
OPA0
External op-amp
connection mode
bit
(Note 4)
SCAN1
0 : VREF not connectec
1 : VREF connectec
b6 b7
OPA1
0 0 : ANEX0 and ANEX1 are not used (Note 5)
(Note 6)
0 1 : ANEX0 input is A-D converted
(Note 7)
1 0 : ANEX1 input is A-D converted
1 1 : External op-amp connection mode (Note 8)
Note 1: If the A-D0 control register 1 is rewritten during A-D conversion, the conversion result is indeterminate.
Note 2: This bit is invalid in One-shot mode and Repeat mode. Channel shown in the parentheses,
becomes valid when repeat sweep mode 1(bit2="1") is selected.
Note 3: When f(XIN) is over 10 MHz, the
AD frequency must be under 10 MHz by dividing.
Note 4: In single sweep mode and repeat sweep mode 0, 1, bit 7 and bit 6 cannot be set "01" and "10".
Note 5: When this bit is set, set "00" to bit6 and bit5 of function select register B3.
Note 6: When this bit is set, set "1" to bit5 of function select register B3.
Note 7: When this bit is set, set "1" to bit6 of function select register B3.
Note 8: When this bit is set, set "11" to bit6 and bit5 of function select register B3.
Figure 1.24.3. A-D converter-related registers (2)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
A-D0 control register 2
b7
b6
b5
b4
b3
b2
b1
b0
0 0 0
(Note 1)
Symbol
Address
AD0CON2
039416
Bit
Symbol
SMP
ADS
When reset
X000 00002
Bit name
Function
A-D conversion
method select bit
0 : Without sample and hold
1 : With sample and hold
Reserved bit
Must always set to "0"
R W
A-D Channel replace 0 : Channel replace is invalid
select bit
(Note 2) 1 : Channel replace is valid
b6 b5
TRG0
TRG1
PST
External trigger
request cause
select bit
0 0 : ADTRG is selected
0 1 : Timer B2 interrupt occurrence
frequency counter overflow is
selected
(Note 3)
1 0 : Group 2 channel 1 interrupt is
selected
1 1 : Must not be set
Simultaneous start bit 0 : Invalid
(Note 4) (Note 5) (Note 6) 1 : 2 circuit A-D simultaneous start
Note 1: If the A-D0 control register 2 is rewritten during A-D conversion, the conversion result is indeterminate
Note 2: When the A-D circuit of either of A-D0 and A-D1 are operated, do not write "1" to this bit.
Note 3: This bit is valid when software trigger is selected.
Note 4: When this bit read, the value is indeterminate.
Note 5: This is valid in three-phase PWM mode.
Note 6: Turn every setting of A-D0 and A-D1 into same, and start at the same time in sweep mode.
A-D0 register j (j=0 to 7)
b15
(b7)
b8
(b0)b7
b0
Symbol
AD0j(j=0 to 2)
AD0j(j=3 to 5)
AD0j(j=6,7)
Address
038116,038016, 038316,038216, 038516,038416
038716,038616, 038916,038816, 038B16,038A16
038D16,038C16, 038F16,038E16
Function
Eight low-order bits of A-D conversion result
During 10-bit mode : Two high-order bits of A-D conversion result
During 8-bit mode : When read, their contents are indeterminate
Nothing is assigned.
When write, set "0". When read, their contents are indeterminate.
Figure 1.24.4. A-D converter-related registers (3)
286
When reset
indeterminate
indeterminate
indeterminate
R W
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
A-D1 control register 0
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1)
Symbol
AD1CON0
Bit
symbol
Address
01D616
When reset
0016
Bit name
Function
R W
b2 b1 b0
CH0
CH1
Analog input pin
select bit
CH2
0 0 0 : ANj0
0 0 1 : ANj1
0 1 0 : ANj2
0 1 1 : ANj3
1 0 0 : ANj4
1 0 1 : ANj5
1 1 0 : ANj6
1 1 1 : ANj7
(Note 2, 3, 4)
(j=0, 2, 15)
b4 b3
A-D operation
mode select bit 0
0 0 : One-shot mode
0 1 : Repeat mode
1 0 : Single sweep mode
1 1 : Repeat sweep mode 0
Repeat sweep mode 1
TRG
Trigger select bit
0 : Software trigger
1 : External trigger
ADST
A-D conversion
start flag
0 : A-D conversion disabled
1 : A-D conversion started
Frequency select
bit
(Note 8)
0 : fAD/3 or fAD/4 is selected
1 : fAD/1 or fAD/2 is selected
MD0
MD1
CKS0
(Note 2)
(Note 5, 6)
(Note 7)
Note 1: If the A-D1 control register 0 is rewritten during A-D conversion, the conversion result is indeterminate.
Note 2: When changing A-D operation mode, set analog input pin again.
Note 3: This bit is disabled in single sweep mode, repeat sweep mode 0 and repeat sweep mode 1.
Note 4: j=0, 2, 15 is selected by analog input port select bits (bit1 and bit 2 of address 01D416).
Note 5: External trigger request cause can be selected in external trigger request cause select bit (bit5
and bit 6 of address 01D416).
Note 6: After selecting external trigger request cause, set to "1".
Note 7: When External trigger is selected, set to "1" after selecting the external trigger.
Note 8: When f(XIN) is over 10 MHz, the
AD
frequency must be under 10 MHz by dividing.
Figure 1.24.5. A-D converter-related registers (4)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
A-D1 control register 1
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1)
Symbol
Address
AD1CON1
01D716
Bit
symbol
When reset
XX0000002
Bit name
Function
R W
b1 b0
SCAN0
A-D sweep pin
select bit
0 0 : ANj0,ANj1 (ANj0)
0 1 : ANj0 to ANj3 (ANj0,ANj1) (Note 2, 3)
1 0 : ANj0 to ANj5 (ANj0 to ANj2)
1 1 : ANj0 to ANj7 (ANj0 to ANj3) (j=0, 2, 15)
MD2
A-D operation
mode select bit 1
0 : Any mode except repeat sweep mode 1
1 : Repeat sweep mode 1
BITS
8/10-bit mode
select bit
0 : 8-bit mode
1 : 10-bit mode
CKS1
Frequency select
0 : fAD/2 or fAD/4 is selected
bit
(Note 4) 1 : fAD/1 or fAD/3 is selected
VCUT
VREF connect bit
SCAN1
0 : VREF not connectec
1 : VREF connectec
Nothing is assigned.
When write, set to "0". When read,
their contents are indeterminate.
Note 1: If the A-D1 control register 1 is rewritten during A-D conversion, the conversion result is indeterminate.
Note 2: This bit is invalid in one-shot mode and repeat mode. Channel shown in the parentheses,
becomes valid when repeat sweep mode 1(bit 2 = "1") is selected.
Note 3: j=0, 2, 15 is selected by analog input port select bits (bit1 and bit 2 of address 01D416).
Note 4: When f(XIN) is over 10 MHz, the
AD frequency must be under 10 MHz by dividing.
Figure 1.24.6. A-D converter-related registers (5)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
A-D1 control register 2
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1)
Symbol
AD1CON2
Bit
Symbol
SMP
Address
01D416
When reset
X00XX0002
Bit name
A-D conversion
method select bit
Bit name
R W
0 : Without sample and hold
1 : With sample and hold
b2 b1
APS0
Analog input port
select bit
APS1
0 0 : P15
0 1 : Must not be set
1 0 : P0
1 1 : P2
Nothing is assigned.
When write, set to "0". When read, their contents are
indeterminate.
b6 b5
TRG0
External trigger
request cause
select bit
TRG1
0 0 : ADTRG is selected
0 1 : Timer B2 interrupt occurrence
frequency counter overflow is
selected
(Note 2)
1 0 : Group 3 channel 1 interrupt is
selected
1 1 : Must not be set
Nothing is assigned.
When write, set to "0". When read, its content is indeterminate.
Note 1: If the A-D1 control register 2 is rewritten during A-D conversion, the conversion.
Note 2: This is valid in three-phase PWM mode.
A-D1 register j (j=0 to 7)
b15
(b7)
b8
(b0)b7
b0
Symbol
AD1j(j=0 to 2)
AD1j(j=3 to 5)
AD1j(j=6,7)
Address
01C116,01C016, 01C316,01C216, 01C516,01C416
01C716,01C616, 01C916,01C816, 01CB16,01CA16
01CD16,01CC16, 01CF16,01CE16
Function
When reset
indeterminate
indeterminate
indeterminate
R W
Eight low-order bits of A-D conversion result
During 10-bit mode : Two high-order bits of A-D conversion result
During 8-bit mode : When read, their contents are indeterminate
Nothing is assigned.
When write, set to "0". When read, their contents are indeterminate.
Figure 1.24.7. A-D converter-related registers (6)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
(1) One-shot mode
In one-shot mode, the pin selected using the analog input pin select bit is used for one-shot A-D conversion. Table 1.24.2 shows the specifications of one-shot mode.
Table 1.24.2. One-shot mode specifications
Item
Specification
Function
The pin selected by the analog input pin select bit is used for one A-D conversion
Start condition
Writing “1” to A-Di conversion start flag, external trigger
Stop condition
• End of A-Di conversion (A-Di conversion start flag changes to “0”, except when
external trigger is selected)
• Writing “0” to A-D conversion start flag
Interrupt request generation timing
End of A-D conversion
Input pin
One of ANj0 to ANj7 (j =non, 0, 2, 15), ANEX0, ANEX1
Reading of result of A-D converter
Read A-D register corresponding to selected pin
(2) Repeat mode
In repeat mode, the pin selected using the analog input pin select bit is used for repeated A-D conversion.
Table 1.24.3 shows the A-D control register in repeat mode.
Table 1.24.3. Repeat mode specifications
Item
Function
Specification
The pin selected by the analog input pin select bit is used for repeated A-D conversion
Start condition
Writing “1” to A-D conversion start flag, external trigger
Stop condition
Writing “0” to A-D conversion start flag
Interrupt request generation timing
None generated
Input pin
One of ANj0 to ANj7 (j =non, 0, 2, 15), ANEX0, ANEX1
Reading of result of A-D converter
Read A-D register corresponding to selected pin
(3) Single sweep mode
In single sweep mode, the pins selected using the A-D sweep pin select bit are used for one-by-one A-D
conversion. Table 1.24.4 shows the A-D control register in single sweep mode.
Table 1.24.4. Single sweep mode specifications
Item
Function
Specification
The pins selected by the A-Di sweep pin select bit are used for one-by-one
A-D conversion
Start condition
Writing “1” to A-D converter start flag, external trigger
Stop condition
• End of A-Di conversion (A-D conversion start flag changes to “0”, except
when external trigger is selected)
• Writing “0” to A-Di conversion start flag
Interrupt request generation timing
End of sweep
Input pin
ANj0 and ANj1 (2 pins), ANj0 to ANj3 (4 pins), ANj0 to ANj5 (6 pins), or ANj0 to ANj7
(8 pins) (j =non, 0, 2, 15)
Reading of result of A-D converter
290
Read A-D register corresponding to selected pin
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
(4) Repeat sweep mode 0
In repeat sweep mode 0, the pins selected using the A-D sweep pin select bit are used for repeat sweep
A-D conversion. Table 1.24.5 shows the specifications of repeat sweep mode 0.
Table 1.24.5. Repeat sweep mode 0 specifications
Item
Function
Specification
The pins selected by the A-D sweep pin select bit are used for repeat sweep
A-D conversion
Start condition
Writing “1” to A-D conversion start flag
Stop condition
Writing “0” to A-D conversion start flag
Interrupt request generation timing None generated
Input pin
ANj0 and ANj1 (2 pins), ANj0 to ANj3 (4 pins), ANj0 to ANj5 (6 pins), or ANj0 to AN7
(8 pins) (j =non, 0, 2, 15)
Reading of result of A-D converter Read A-D register corresponding to selected pin
(5) Repeat sweep mode 1
In repeat sweep mode 1, all pins are used for A-D conversion with emphasis on the pin or pins selected
using the A-D sweep pin select bit. Table 1.26.6 shows the specifications of repeat sweep mode 1.
Table 1.26.6. Repeat sweep mode 1 specifications
Item
Function
Specification
All pins perform repeat sweep A-D conversion, with emphasis on the pin or pins
selected by the A-D sweep pin select bit
Example : AN0 selected
ANj0
ANj1
ANj0
ANj2
ANj0
ANj3
etc. (j =non, 0, 2, 15)
Start condition
Writing “1” to A-D conversion start flag
Stop condition
Writing “0” to A-D conversion start flag
Interrupt request generation timing
None generated
Input pin
ANj0 to ANj7 (j =non, 0, 2, 15)
With emphasis on the pin
ANj0 (1 pin), ANj0 and ANj1 (2 pins), ANj0 to ANj2 (3 pins), ANj0 to ANj3 (4 pins) (j
=non, 0, 2, 15)
Reading of result of A-D converter
Read A-D register corresponding to selected pin
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
(a) Resolution select function
8/10-bit mode select bit of A-D control register 1 (bit 3 at address 039716, 01D716)
When set to 10-bit precision, the low 8 bits are stored in the even addresses and the high 2 bits in the odd
addresses. When set to 8-bit precision, the low 8 bits are stored in the even addresses.
(b) Sample and hold
Sample and hold are selected by setting bit 0 of the A-D control register 2 (address 039416, 01D416) to
“1”. When sample and hold are selected, the rate of conversion of each pin increases. As a result, a 28
ØAD cycle is achieved with 8-bit resolution and 33 ØAD with 10-bit resolution. Sample and hold can be
selected in all modes. However, in all modes, be sure to specify before starting A-D conversion whether
sample and hold are to be used.
(c) Trigger select function
Can appoint start of conversion, by a combination of setting of trigger select bit (bit 5 at address 039616,
01D616) and external trigger request cause select bit (bit 5 and bit 6 at address 039416, 01D416), as
follows.
Table 1.24.7. Trigger select function setting
Trigger select bit="1"
Trigger select bit="0"
External trigger cause select bits
00
01
10
A-D0
Software trigger
ADTRG
Timer B2 OFCOI(Note)
Group 2 channel 1 interrupt
A-D1
Software trigger
ADTRG
Timer B2 OFCOI(Note)
Group 3 channel 1 interrupt
Timer B2 OFCOI : Timer B2 occurrence frequency counter overflow interrupt
Note :Valid in three-phase PWM mode.
(d) Two circuit same time start (software trigger)
Two A-D converters can start at the same time by setting simultaneous start bit (bit 7 of address 039416)
to “1”.
During the A-D circuit of either of A-D0 and A-D1 are operated, do not set “1” to the simultaneous start bit.
Do not set to "1" when external trigger is selected. When using this bit, do not set A-D conversion start
flag (bit 6 of address 039616, 01D616) to "1".
(e) Replace function of input pin
Setting "1" to A-D channel replace select bit of A-D0 control register 2 (ADS:bit 4 at address 039416) can
replace channel of A-D0 and A-D1. A-D conversion reliability is confirmed by replacing channels.
When ADS bit is "1", a corresponding pin of A-D0 register i is selected by analog input port select bits of
A-D1 control register 2 (bits 2 and 1 at address 01D416). In this case, A-D0 control register 0 and A-D1
control register 0 must be set to same value.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
Table 1.24.8. Setting of analog input port replace of A-D converter
Setting value
A-D conversion stored register
A-D channel replace select bit
Analog output port select bit
1
00
10
11
A-D0 register 0
AN150
AN00
AN20
A-D0 register 1
AN151
AN01
AN21
A-D0 register 2
AN152
AN02
AN22
A-D0 register 3
AN153
AN03
AN23
A-D0 register 4
AN154
AN04
AN24
A-D0 register 5
AN155
AN05
AN25
A-D0 register 6
AN156
AN06
AN26
A-D0 register 7
AN157
AN07
AN27
A-D1 register 0
AN0
A-D1 register 1
AN1
A-D1 register 2
AN2
A-D1 register 3
AN3
A-D1 register 4
AN4
A-D1 register 5
AN5
A-D1 register 6
AN6
A-D1 register 7
AN7
(f) Extended analog input pins
In one-shot mode and repeat mode, the input via the extended analog input pins ANEX0 and ANEX1 can
also be converted from analog to digital as AN0 and AN1 analog input signal respectively.
Set the related input peripheral function of the function select register B3 to disabled.
(g) External operation amp connection mode
In this mode, multiple external analog inputs via the extended analog input pins, ANEX0 and ANEX1, can
be amplified together by just one operation amp and used as the input for A-D conversion.
When bit 6 and bit 7 of the A-D control register 1 (address 039716) is “11”, input via AN0 to AN7 is output
from ANEX0.
The input from ANEX1 is converted from analog to digital and the result stored in the corresponding A-D
register. The speed of A-D conversion depends on the response of the external operation amp. Do not
connect the ANEX0 and ANEX1 pins directly. Figure 1.24.8 is an example of how to connect the pins in
external operation amp mode.
Set the related input peripheral function of the function select register B3 to disabled.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
Table 1.24.9. Setting of extended analog input pins
A-D0 control register 1
ANEX0 function
ANEX1 function
Bit 7
Bit 6
0
0
Not used
Not used
0
1
P95 analog input
Not used
1
0
Not used
P96 analog input
1
1
Output to external ope-amp
Input from external ope-amp
Resistance ladder
Successive conversion register
Analog
input
AN0
AN1
AN2
AN3
AN4
AN5
AN6
AN7
ANEX0
ANEX1
Comparator
External op-amp
Figure 1.24.8. Example of external op-amp connection mode
(h) Power consumption reduction function
VREF connect bit (bit 5 at addresses 039716, 01D716)
The VREF connect bit (bit 5 at address 039716, 01D716) can be used to isolate the resistance ladder of the
A-D converter from the reference voltage input pin (VREF) when the A-D converter is not used. Doing so
stops any current flowing into the resistance ladder from VREF, reducing the power dissipation.
When using the A-D converter, start A-D conversion only after connecting VREF.
Do not write A-D conversion start flag and VREF connect bit to “1” at the same time. Do not clear VREF
connect bit to “0” during A-D conversion. This VREF is without reference to D-A converter's VREF.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
A-D Converter
Precaution
After A-D conversion is complete, if the CPU reads the A-D register at the same time as the A-D conversion result is being saved to A-D register, wrong A-D conversion value is saved into the A-D register. This
happens when the internal CPU clock is selected from divided main clock or sub-clock.
• When using the one-shot or single sweep mode
Confirm that A-D conversion is complete before reading the A-D register.
(Note: When A-D conversion interrupt request bit is set, it shows that A-D conversion is completed.)
• When using the repeat mode or repeat sweep mode 0 or 1
Use the undivided main clock as the internal CPU clock.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
D-A Conversion
D-A Converter
This is an 8-bit, R-2R type D-A converter. The microcomputer contains two independent D-A converters of
this type.
D-A conversion is performed when a value is written to the corresponding D-A register. Bits 0 and 1 (D-A
output enable bits) of the D-A control register decide if the result of conversion is to be output. Set the
function select register A3 to I/O port, the related input peripheral function of the function select register B3
to disabled and the direction register to input mode. Do not set the target port to pulled-up when D-A output
is enabled.
Output analog voltage (V) is determined by a set value (n : decimal) in the D-A register.
V = VREF X n/ 256 (n = 0 to 255)
VREF : reference voltage (This is unrelated to bit 5 of A-D control register 1 (addresses 039716, 01D716)
Table 1.25.1 lists the performance of the D-A converter. Figure 1.25.1 shows the block diagram of the D-A
converter. Figure 1.25.2 shows the D-A control register. Figure 1.25.3 shows the D-A converter equivalent
circuit.
When the D-A converter is not used, set the D-A register to "00" and D-A output enable bit to "0".
Table 1.25.1. Performance of D-A converter
Item
Conversion method
R-2R method
Resolution
8 bits
Analog output pin
2 channels
Performance
Data bus low-order bits
A
D-A register i (8) (i = 0, 1)
(Address 039816, 039A16)
AAAAAA
AAAAAA
D-Ai output enable bit (i = 0, 1)
R-2R resistance ladder
Figure 1.25.1. Block diagram of D-A converter
296
P93 / DA0
P94 / DA1
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
D-A Conversion
D-A control register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
DACON
039C16
When reset
XXXXXX002
Bit
symbol
Bit name
DA0E
D-A0 output enable bit
0 : Output disabled
1 : Output enabled
DA1E
D-A1 output enable bit
0 : Output disabled
1 : Output enabled
Function
R W
Nothing is assigned.
When write, set to "0". When read, their contents are "0".
D-A register i
b7
b0
Symbol
DAi(i=0,1)
Address
039816, 039A16
When reset
Indeterminate
Setting range
Function
Output value of D-A conversion
R W
0016 to FF16
Figure 1.25.2. D-A control register
D-A0 output enable bit
"0"
R
R
R
R
R
R
R
R
2R
DA0
"1"
2R
2R
2R
2R
2R
2R
2R
LSB
MSB
D-A register 0
2R
"0"
"1"
AVSS
VREF
Note 1: In the above figure, the D-A register value is "2A16".
Note 2: This circuit is the same in D-A1.
Note 3: To save power dissipation when not using the D-A converter, set the D-A output enable bit to
"0" and the D-A register to "0016", and prevent current flowing to the R-2R resistance.
Figure 1.25.3. D-A converter equivalent circuit
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CRC
CRC Calculation Circuit
The Cyclic Redundancy Check (CRC) calculation circuit detects an error in data blocks. The microcomputer uses a generator polynomial of CRC_CCITT (X16 + X12 + X5 + 1) to generate CRC code.
The CRC code is a 16-bit code generated for a block of a given data length in multiples of 8 bits. The CRC
code is set in a CRC data register each time one byte of data is transferred to a CRC input register after
writing an initial value into the CRC data register. Generation of CRC code for one byte of data is completed in two machine cycles.
Figure 1.26.1 shows the block diagram of the CRC circuit. Figure 1.26.2 shows the CRC-related registers.
Figure 1.26.3 shows the CRC example.
Data bus high-order bits
AAAAA
AAAAAA
AAAAAAAAAA
AAAAA
AAAAAA
AAAAAAAAAA
AAAAAAAAAA
AAAAAAAAAA
AAAAAAAAAA
AAAAA
AAAAA
Data bus low-order bits
Eight low-order bits
Eight high-order bits
CRC data register (16)
(Addresses 037D16, 037C16)
CRC code generating circuit
x16 + x12 + x5 + 1
CRC input register (8)
(Address 037E16)
Figure 1.26.1. Block diagram of CRC circuit
CRC data register
b15
(b7)
b8
(b0) b7
b0
Symbol
CRCD
Address
037D16, 037C16
Function
CRC calculation output register
When reset
Indeterminate
Setting range
R W
000016 to FFFF16
CRC input register
b7
b0
Symbol
CRCIN
Address
037E16
Function
Data input register
Figure 1.26.2. CRC-related registers
298
When reset
Indeterminate
Setting range
0016 to FF16
R W
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CRC
b15
b0
CRC data register CRCD
[037D16, 037C16]
(1) Setting 000016
b7
b0
CRC input register
(2) Setting 0116
CRCIN
[037E16]
2 cycles
After CRC calculation is complete
b15
b0
CRC data register
118916
CRCD
[037D16, 037C16]
Stores CRC code
The code resulting from sending 0116 in LSB first mode is (1000 0000). Thus the CRC code in the generating polynomial,
(X16 + X12 + X5 + 1), becomes the remainder resulting from dividing (1000 0000) X16 by (1 0001 0000 0010 0001) in
conformity with the modulo-2 operation.
LSB
MSB
1000 1000
1 0001 0000 0010 0001 1000 0000 0000
1000 1000 0001
1000 0001
1000 1000
1001
LSB
0000
0000
0000
0001
0001
9
1
8
1
0000
1
1000
0000
1000
0000
Modulo-2 operation is
operation that complies
with the law given below.
0+0=0
0+1=1
1+0=1
1+1=0
-1 = 1
0
1
1000
MSB
Thus the CRC code becomes (1001 0001 1000 1000). Since the operation is in LSB first mode, the (1001 0001 1000 1000)
corresponds to 118916 in hexadecimal notation. If the CRC operation in MSB first mode is necessary in the CRC operation
circuit built in the M32C, switch between the LSB side and the MSB side of the input-holding bits, and carry out the CRC
operation. Also switch between the MSB and LSB of the result as stored in CRC data.
b7
b0
CRC input register
(3) Setting 2316
CRCIN
[037E16]
After CRC calculation is complete
b15
b0
0A4116
CRC data register
CRCD
[037D16, 037C16]
Stores CRC code
Figure 1.26.3. CRC example
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
X-Y Converter
X-Y Converter
X-Y conversion rotates the 16 x 16 matrix data by 90 degrees. It can also be used to invert the top and
bottom of the 16-bit data. Figure 1.27.1 shows the XY control register.
The Xi and the Yi registers are 16-bit registers. There are 16 of each (where i= 0 to 15).
The Xi and Yi registers are mapped to the same address. The Xi register is a write-only register, while the
Yi register is a read-only register. Be sure to access the Xi and Yi registers in 16-bit units from an even
address. Operation cannot be guaranteed if you attempt to access these registers in 8-bit units.
XY control register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
XYC
02E016
Bit
symbol
XYC0
XYC1
Bit name
When reset
XXXXXX002
Function
Read-mode set bit
0 : Data conversion
1 : No data conversion
Write-mode set bit
0 : No bit mapping conversion
1 : Bit mapping conversion
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Figure 1.27.1. XY control register
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
X-Y Converter
The reading of the Yi register is controlled by the read-mode set bit (bit 0 at address 02E016).
When the read-mode set bit (bit 0 at address 02E016) is “0”, specific bits in the Xi register can be read at the
same time as the Yi register is read.
For example, when you read the Y0 register, bit 0 is read as bit 0 of the X0 register, bit 1 is read as bit 0 of
the X1 register, ..., bit 14 is read as bit 0 of the X14 register, bit 15 as bit 0 of the X15 register. Similarly,
when you read the Y15 register, bit 0 is bit 15 of the X0 register, bit 1 is bit 15 of the X1 register, ..., bit 14 is
bit 15 of the X14 register, bit 15 is bit 15 of the X15 register.
Figure 1.27.2 shows the conversion table when the read mode set bit = “0”. Figure 1.27.3 shows the X-Y
conversion example.
Y15 register (0002DE16)
Y14 register (0002DC16)
Y13 register (0002DA16)
Y12 register (0002D816)
Y11 register (0002D616)
Y10 register (0002D416)
Y9 register (0002D216)
Y8 register (0002D016)
Y7 register (0002CE16)
Y6 register (0002CC16)
Y5 register (0002CA16)
Y4 register (0002C816)
Y3 register (0002C616)
Y2 register (0002C416)
Y1 register (0002C216)
Y0 register (0002C016)
Read address
Bit of Yi register
b15
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
AAA
A
AA
AA
A
AA
A
AA
A
AA
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
AA
AAA
A
AA
AA
A
AA
A
AA
A
AA
A
b0
Write address
X15 register (0002DE16)
X14 register (0002DC16)
X13 register (0002DA16)
X12 register (0002D816)
X11 register (0002D616)
X10 register (0002D416)
X9 register (0002D216)
X8 register (0002D016)
X7 register (0002CE16)
X6 register (0002CC16)
X5 register (0002CA16)
X4 register (0002C816)
X3 register (0002C616)
X2 register (0002C416)
X1 register (0002C216)
X0 register (0002C016)
b15
b0
Bit of Xi register
Figure 1.27.2. Conversion table when the read mode set bit = “0”
(X register)
X0-Reg
X1
X2
X3
X4
X5
X6
X7
X8
X9
X10
X11
X12
X13
X14
X15
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
b3
b2
b1
b0
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
b3
b2
b1
b0
(Y register)
Y0-Reg
Y1
Y2
Y3
Y4
Y5
Y6
Y7
Y8
Y9
Y10
Y11
Y12
Y13
Y14
Y15
A
AAAA
AA
A
A
AA
A
AA
A
A
AA
A
AA
AA
AA
AA
AA
A
A
A
Figure 1.27.3. X-Y conversion example
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
X-Y Converter
When the read-mode set bit (bit 0 at address 02E016) is “1”, you can read the value written to the Xi register
by reading the Yi register. Figure 1.27.4 shows the conversion table when the read mode set bit = “1”.
Write address
Read address
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
A
X15,Y15 register (0002DE16)
X14,Y14 register (0002DC16)
X13,Y13 register (0002DA16)
X12,Y12 register (0002D816)
X11,Y11 register (0002D616)
X10,Y10 register (0002D416)
X9,Y9 register (0002D216)
X8,Y8 register (0002D016)
X7,Y7 register (0002CE16)
X6,Y6 register (0002CC16)
X5,Y5 register (0002CA16)
X4,Y4 register (0002C816)
X3,Y3 register (0002C616)
X2,Y2 register (0002C416)
X1,Y1 register (0002C216)
X0,Y0 register (0002C016)
b15
b0
Bit of Xi register
Bit of Yi register
Figure 1.27.4. Conversion table when the read mode set bit = “1”
The value written to the Xi register is controlled by the write mode set bit (bit 1 at address 02E016).
When the write mode set bit (bit 1 at address 02E016) is “0” and data is written to the Xi register, the bit
stream is written directly.
When the write mode set bit (bit 1 at address 02E016) is “1” and data is written to the Xi register, the bit
sequence is reversed so that the high becomes low and vice versa. Figure 1.27.5 shows the conversion
table when the write mode set bit = “1”.
b15
b0
b15
b0
Write address
Bit of Xi register
Figure 1.27.5. Conversion table when the write mode set bit = “1”
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DRAM Controller
DRAM Controller
There is a built in DRAM controller to which it is possible to connect between 512 Kbytes and 8 Mbytes of
DRAM. Table 1.28.1 shows the functions of the DRAM controller.
Table 1.28.1. DRAM Controller Functions
DRAM space
512KB, 1MB, 2MB, 4MB, 8MB
Bus control
2CAS/1W
________
________
Refresh
CAS before RAS refresh, Self refresh-compatible
Function modes
EDO-compatible, fast page mode-compatible
Waits
1 wait or 2 waits, programmable
To use the DRAM controller, use the DRAM space select bit of the DRAM control register (address 004016)
to specify the DRAM size. Figure 1.28.1 shows the DRAM control register.
The DRAM controller cannot be used in external memory mode 3 (bits 1 and 2 at address 000516 are “112”).
Always use the DRAM controller in external memory modes 0, 1, or 2.
When the data bus width is 16-bit in DRAM area, set "1" to R/W mode select bit (bit 2 at address 000416).
Set wait time between after DRAM power ON and before memory processing, and processing necessary
for dummy cycle to refresh DRAM by software.
DRAM Control register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
DRAMCONT
Bit
symbol
WT
Address
004016
When reset
Indeterminate (Note 1)
Bit name
Wait select bit
(Note 2)
Function
R W
0 : Two wait
1 : One wait
b3 b2 b1
AR0
AR1
DRAM space select bit
AR2
0 0 0 : DRAM ignored
0 0 1 : Must not be set
0 1 0 : 0.5MB
0 1 1 : 1MB
1 0 0 : 2MB
1 0 1 : 4MB
1 1 0 : 8MB
1 1 1 : Must not be set
Nothing is assigned. When write, set to "0".
When read, their contents are indeterminate.
SREF
Self-refresh mode bit
(Note 3)
0 : Self-refresh OFF
1 : Self-refresh ON
Note 1: After reset, the content of this register is indeterminate. DRAM controller starts operation after
writing to this register.
Note 2: The number of cycles with 2 waits is 3-2-2. With 1 wait, it is 2-1-1.
Note 3: When you set to "1", both RAS and CAS change to "L". When you set to "0", RAS and CAS
change to "H" and then normal operation (read/write, refresh) is resumed. In stop mode, there is
no control.
Note 4: Set the bus width using the external data bus width control register (address 000B16). When
selecting 8-bit bus width, CASH is indeterminate.
Figure 1.28.1. DRAM control register
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DRAM Controller
• DRAM Controller Multiplex Address Output
The DRAM controller outputs the row addresses and column addresses as a multiplexed signal to the
address bus A8 to A20. Figure 1.28.2 shows the output format for multiplexed addresses.
8-bit bus mode
MA8
(A16)
MA7
(A15)
MA6
(A14)
MA5
(A13)
MA4
(A12)
MA3
(A11)
MA2
(A10)
MA1
(A9)
MA0
(A8)
A17
A16
A15
A14
A13
A12
A11
A10
A9
–
A8
A7
A6
A5
A4
A3
A2
A1
A0
–
Pin function
MA12 MA11 MA10 MA9
(A20) (A19) (A18) (A17)
Row address
(A20)
(A19)
A18
Column address
(A22)
(A22)
A19
512KB, 1MB
Row address
(A20)
A19
A18
A17
A16
A15
A14
A13
A12
A11
A10
A9
–
Column address
(A22)
A21
A20
A8
A7
A6
A5
A4
A3
A2
A1
A0
–
2MB, 4MB
Row address
Column address
A20
A19
A18
A17
A16
A15
A14
A13
A12
A11
A10
A9
–
(A22)
A22
A21
A8
A7
A6
A5
A4
A3
A2
A1
A0
–
8MB
16-bit bus mode
Pin function
MA12 MA11 MA10
(A20) (A19) (A18)
MA9
(A17)
MA8
(A16)
MA7
(A15)
MA6
(A14)
MA5
(A13)
MA4
(A12)
MA3
(A11)
MA2
(A10)
MA1
(A9)
MA0
(A8)
Row address
(A20)
(A19)
A18
A17
A16
A15
A14
A13
A12
A11
A10
(A9)
–
Column address
(A22)
(A20)
A9
A8
A7
A6
A5
A4
A3
A2
A1
(A0)
–
512KB
Row address
(A20)
A19
A18
A17
A16
A15
A14
A13
A12
A11
A10
(A9)
–
Column address
(A22)
A20
A9
A8
A7
A6
A5
A4
A3
A2
A1
(A0)
–
1MB, 2MB
Row address
A20
A19
A18
A17
A16
A15
A14
A13
A12
A11
A10
(A9)
–
Column address
A22
A21
A9
A8
A7
A6
A5
A4
A3
A2
A1
(A0)
–
4MB, 8MB (Note 2)
Note 1: ( ) invalid bit:
bits that change according to selected mode (8-bit/16-bit bus mode, DRAM
space).
Note 2: The figure is for 4Mx1 or 4Mx4 memory configuration. If you are using a 4Mx16 configuration,
use combinations of the following: For row addresses, MA0 to MA12; for column addresses
MA2 to MA8, MA11, and MA12. Or for row addresses MA1 to MA12; for column addresses
MA2 to MA9, MA11, MA12.
Note 3: "–" is indetermimate.
Figure 1.28.2. Output format for multiplexed addresses
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DRAM Controller
• Refresh
_______
_______
The refresh method is CAS before RAS. The refresh interval is set by the DRAM refresh interval set
register (address 004116). The refresh signal is not output in HOLD state. Figure 1.28.3 shows the
DRAM refresh interval set register.
Use the following formula to determine the value to set in the refresh interval set register.
Refresh interval set register value (0 to 255) = refresh interval time / (BCLK frequency X 32) - 1
DRAM refresh interval set register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
REFCNT
Bit
symbol
Address
004116
Bit name
When reset
Indeterminate
Function
R W
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0 0 0 0 : 1.1 µs
0 0 0 0 0 0 0 1 : 2.1 µs
0 0 0 0 0 0 1 0 : 3.2 µs
REFCNT0
REFCNT1
REFCNT2
(Note)
1 1 1 1 1 1 1 1 : 272.8 µs
REFCNT3
Refresh interval set bit
REFCNT4
REFCNT5
REFCNT6
REFCNT7
Note. Refresh interval at 30 MHz operating (no division).
Refresh interval = BCLK frequency X (refresh interval set bit + 1) X 32
Figure 1.28.3. DRAM refresh interval set register
The DRAM self-refresh operates in STOP mode, etc.
When shifting to self-refresh, select DRAM ignored by the DRAM space select bit. In the next instruction,
simultaneously set the DRAM space select bit and self-refresh ON by self-refresh mode bit. Also, insert
two NOPs after the instruction that sets the self-refresh mode bit to "1".
Do not access external memory while operating in self-refresh. (All external memory space access is
inhibited. )
When disabling self-refresh, simultaneously select DRAM ignored by the DRAM space select bit and selfrefresh OFF by self-refresh mode bit. In the next instruction, set the DRAM space select bit.
Do not access the DRAM space immediately after setting the DRAM space select bit.
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DRAM Controller
Example) One wait is selected by the wait select bit and 4MB is selected by the DRAM space select bit
Shifting to self-refresh
•••
mov.b #00000001b,DRAMCONT
;DRAM ignored, one wait is selected
mov.b #10001011b,DRAMCONT
;Set self-refresh, select 4MB and one wait
nop
;Two nops are needed
nop
;
•••
Disable self-refresh
•••
mov.b #00000001b,DRAMCONT
mov.b
nop
nop
•••
#00001011b,DRAMCONT
;Disable self-refresh, DRAM ignored, one wait is
;selected
;Select 4MB and one wait
;Inhibit instruction to access DRAM area
Figures 1.28.4 to 1.28.6 show the bus timing during DRAM access.
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DRAM Controller
< Read cycle (wait control bit = 0) >
BCLK
Row
address
MA0 to MA12
Column
address 1
Column
address 2
Column
address 3
RAS
CASH
CASL
'H'
DW
D0 to D15
(EDO mode)
Note : Only CASL is operating in 8-bit data bus width.
< Write cycle (wait control bit = 0) >
BCLK
MA0 to MA12
Row
address
Column
address 1
Column
address 2
Column
address 3
RAS
CASH
CASL
DW
D0 to D15
Note : Only CASL is operating in 8-bit data bus width.
Figure 1.28.4. The bus timing during DRAM access (1)
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
DRAM Controller
< Read cycle (wait control bit = 1) >
BCLK
Row
address
MA0 to MA12
Column
address 1
Column
address 2
Column
address 3
Column
address 4
RAS
CASH
CASL
'H'
DW
D0 to D15
(EDO mode)
Note : Only CASL is operating in 8-bit data bus width.
< Write cycle (wait control bit = 1) >
BCLK
MA0 to MA12
Row
address
Column
address 1
Column
address 2
RAS
CASH
CASL
DW
D0 to D15
Note : Only CASL is operating in 8-bit data bus width.
Figure 1.28.5. The bus timing during DRAM access (2)
308
Column
address 3
Column
address 4
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DRAM Controller
BCLK
RAS
CASH
CASL
"H"
DW
< CAS before RAS refresh cycle >
Note : Only CASL is operating in 8-bit data bus width.
BCLK
RAS
CASH
CASL
"H"
DW
< Self refresh cycle >
Note : Only CASL is operating in 8-bit data bus width.
Figure 1.28.6. The bus timing during DRAM access (3)
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Programmable I/O Port
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Ports
There are 123 programmable I/O ports in 144-pin version: P0 to P15 (excluding P85). There are 87 programmable I/O ports in 100-pin version: P0 to P10 (excluding P85). Each port can be set independently for
input or output using the direction register. A pull-up resistance for each block of 4 ports can be set. P85 is
an input-only port and has no built-in pull-up resistance.
Figures 1.29.1 to 1.29.4 show the programmable I/O ports.
Each pin functions as a programmable I/O port and as the I/O for the built-in peripheral devices.
To use the pins as the inputs for the built-in peripheral devices, set the direction register of each pin to input
mode. When the pins are used as the outputs for the built-in peripheral devices (other than the D-A converter), set the corresponding function select registers A, B and C. When pins are to be used as the outputs
for the D-A converter, set the function select register A3 of each pin to I/O port, and set the direction
registers to input mode.
See the descriptions of the respective functions for how to set up the built-in peripheral devices.
(1) Direction registers
Figurs 1.29.5 shows the direction registers.
These registers are used to choose the direction of the programmable I/O ports. Each bit in these registers corresponds one for one to each I/O pin.
In memory expansion and microprocessor mode, the contents of corresponding direction register of pins
_____
_______
_______ _______ _____ _________
_______ _______ _______
_____ _____
A0 to A22, A23, D0 to D15, MA0 to MA12, CS0 to CS3, WRL/WR/CASL, WRH/BHE/CASH, RD/DW, BCLK/
_________
_________
_______
_______
ALE/CLKOUT, HLDA/ALE, HOLD, ALE/RAS, and RDY are not changed.
Note: There is no direction register bit for P85.
(2) Port registers
Figure 1.29.6 shows the port registers.
These registers are used to write and read data for input and output to and from an external device. A
port register consists of a port latch to hold output data and a circuit to read the status of a pin. Each bit
in a port register corresponds one for one to each I/O pin.
In memory expansion and microprocessor mode, the contents of corresponding port register of pins A0 to
_____
_______
_______ _______ _____ _________
_______ _______ _______
_____ _____
A22, A23, D0 to D15, MA0 to MA12, CS0 to CS3, WRL/WR/CASL, WRH/BHE/CASH, RD/DW, BCLK/ALE/
_________
_________
_______
_______
CLKOUT, HLDA/ALE, HOLD, ALE/RAS, and RDY are not changed.
(3) Function select register A
Figures 1.29.7 to 1.29.11 show the function select registers A.
The register is used to select port output and peripheral function output when the port functions for both
port output and peripheral function output.
Each bit of this register corresponds to each pin that functions for both port output and peripheral function
output.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
(4) Function select register B
Figures 1.29.12 and 1.29.13 show the function select registers B.
This register selects the first peripheral function output and second peripheral function output when multiple peripheral function outputs are assigned to a pin. For pins with a third peripheral function, this register selects whether to enable the function select register C, or output the second peripheral function.
Each bit of this register corresponds to each pin that has multiple peripheral function outputs assigned to it.
This register is enabled when the bits of the corresponding function select register A are set for peripheral
functions.
The bit 3 to bit 6 of function select register B3 is ignored bit for input peripheral function. When using DA0/DA1
and ANEX0/ANEX1, set related bit to“1”. When not using DA0/DA1 or ANEX0/ANEX1, set related bit to “0”.
(5) Function select register C
Figure 1.29.14 shows the function select register C.
This register is used to select the first peripheral function output and the third peripheral function output
when three peripheral function outputs are assigned to a pin.
This register is effective when the bits of the function select register A of the counterpart pin have selected
a peripheral function and when the function select register B has made effective the function select
register C.
The bit 7 (PSC_7) is assigned the key-in interrupt inhibit bit. Setting “1” in the key-in interrupt inhibit bit
causes no key-in interrupts regardless of the settings in the interrupt control register even if “L” is entered
______
______
in pins KI0 to KI3. With “1” set in the key-in interrupt inhibit bit, input from a port pin cannot be effected
even if the port direction register is set to input mode.
(6) Pull-up control registers
Figures 1.29.15 to 1.29.17 show the pull-up control registers.
The pull-up control register can be set to apply a pull-up resistance to each block of 4 ports. When ports
are set to have a pull-up resistance, the pull-up resistance is connected only when the direction register is
set for input.
Since P0 to P5 operate as the bus in memory expansion mode and microprocessor mode, do not set the
pull-up control register. However, it is possible to select pull-up resistance presence to the usable port as
I/O port by setting.
(7) Port control register
Figure 1.29.18 shows the port control register.
This register is used to choose whether to make port P1 a CMOS port or an Nch open drain. In the Nch
open drain, the CMOS port’s Pch is kept always turned off so that the port P1 cannot be a complete open
drain. Thus the absolute maximum rating of the input voltage falls within the range from “- 0.3 V to Vcc +
0.3 V”.
The port control register functions similarly to the above. Also in the case in which port P1 can be used as
a port when the bus width in the full external areas comprises 8 bits in either microprocessor mode or in
memory expansion mode.
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Programmable I/O Port
Programmable I/O ports
Pull-up selection
Direction register
Port latch
Data bus
A
Input to respective peripheral functions
C
Analog signal
Option
Port
Circuit (B)
(A)
Input to respective
Hysteresis presence
peripheral functions
P00 to P07
P20 to P27
P30 to P37
P40 to P47
P50 to P52
P54
P55
P56
P57
P83, P84
P86
P87
P100 to P103
P104 to P107
(Note)
P114
P144 to P146
P152, P153
P156, P157
: Present,
: Not present
Note: These ports exist in 144-pin version.
Figure 1.29.1. Programmable I/O ports (1)
312
B
Circuit (C)
Analog I/F
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Programmable I/O ports with port control register
Pull-up selection
Direction register
Port P1 control
register
Port latch
Data bus
A
Input to respective peripheral functions
Option
Port
B
Circuit (B)
(A)
Input to respective
Hysteresis presence
peripheral functions
P10 to P14
P15 to P17
: Present,
: Not present
Figure 1.29.2. Programmable I/O ports (2)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Programmable I/O ports with function select register
Pull-up selection
D
Function select
register A
(Note 1)
Direction register
Output from each
peripheral function
Data bus
Port latch
A
Input to respective peripheral functions
C
Analog signal
Option
Port
P53
Circuit (B)
(A)
Input to respective
Hysteresis presence
peripheral functions
(Note 1)
P60, P61
P63 to P65, P67
P70, P71
(Note 2)
P72 to P77
P80, P81
P82
P90 to P92
P93 to P96
P97
P110
P111, P112
P113
P120
P121, P122
P123 to P127
P130 to P134
(Note 3)
P135, P136
P137
P140, P141
P142, P143
P150, P151
P154, P155
: Present,
: Not present
Note 1: P53 is clock output select bit for BCLK.
Note 2: P70 and P71 are N-channel open drain output.
Note 3: These ports exist in 144-pin version.
Figure 1.29.3. Programmable I/O ports (3)
314
B
Circuit (C)
Analog I/F
Circuit (D)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Input-only port
Data bus
NMI
Figure 1.29.4. Programmable I/O ports (4)
Port Pi direction register
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1, 2, 3)
Symbol
Address
When reset
PDi(i=0 to 5)
PDi(i=6 to 11)
03E216, 03E316, 03E616, 03E716, 03EA16, 03EB16
03C216, 03C316, 03C616, 03C716, 03CA16, 03CB16
0016
0016
PDi(i=12 to 15)
03CE16, 03CF16, 03D216, 03D316
0016
Bit
Symbol
Bit name
Function
PDi_0
Port Pi0 direction 0 : Input mode (Functions as an input port)
register
1 : Output mode (Functions as an output port)
PDi_1
Port Pi1 direction 0 : Input mode (Functions as an input port)
register
1 : Output mode (Functions as an output port)
PDi_2
Port Pi2 direction 0 : Input mode (Functions as an input port)
1 : Output mode (Functions as an output port)
register
PDi_3
Port Pi3 direction 0 : Input mode (Functions as an input port)
1 : Output mode (Functions as an output port)
register
PDi_4
Port Pi4 direction 0 : Input mode (Functions as an input port)
1 : Output mode (Functions as an output port)
register
PDi_5
PDi_6
PDi_7
R W
Port Pi5 direction 0 : Input mode (Functions as an input port)
1 : Output mode (Functions as an output port)
register
(Note 4)
Port Pi6 direction 0 : Input mode (Functions as an input port)
1 : Output mode (Functions as an output port)
register
(Note 4)
Port Pi7 direction 0 : Input mode (Functions as an input port)
1 : Output mode (Functions as an output port)
register
(Note 4)
Note 1: Set bit 2 of protect register (address 000A16) to "1" before rewriting to the port P9 direction register.
Note 2: In memory expansion and microprocessor mode, the contents of corresponding port direction register
of pins A0 to A22, A23, D0 to D15, MA0 to MA12, CS0 to CS3, WRL/WR/CASL, WRH/BHE/CASH,
RD/DW, BCLK/ALE/CLKOUT, HLDA/ALE, HOLD, ALE/RAS, and RDY are not changed.
Note 3: Port 11 to 15 registers exist in 144-pin version.
Note 4: Nothing is assigned in bit5 of Port P8 direction register, bit7 to bit5 of port P11 direction register and
bit7 of port P14 direction register.
When write, set to "0". When read, its content is indeterminate.
Figure 1.29.5. Direction register
315
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Port Pi register (Note 1, 2, 3)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Pi(i=0 to 5)
Pi(i=6 to 11)
Pi(i=12 to 15)
Bit
symbol
Address
03E016, 03E116, 03E416, 03E516, 03E816, 03E916
03C016, 03C116, 03C416, 03C516, 03C816, 03C916
03CC16, 03CD16, 03D016, 03D116
Bit name
Function
When reset
Indeterminate
Indeterminate
Indeterminate
R W
Pi_0
Port Pi0 register
0 : "L" level
1 : "H" level
(Note 4)
Pi_1
Port Pi1 register
0 : "L" level
1 : "H" level
(Note 4)
Pi_2
Port Pi2 register
0 : "L" level
1 : "H" level
Pi_3
Port Pi3 register
0 : "L" level
1 : "H" level
Pi_4
Port Pi4 register
0 : "L" level
1 : "H" level
Pi_5
Port Pi5 register
0 : "L" level
1 : "H" level
(Note 5) (Note 6)
Pi_6
Port Pi6 register
0 : "L" level
1 : "H" level
(Note 6)
Pi_7
Port Pi7 register
0 : "L" level
1 : "H" level
(Note 6)
Note 1: Data is input and output to and from each pin by reading and writing to and from each corresponding bit.
Note 2: In memory expansion and microprocessor mode, the contents of corresponding port direction register
of pins A0 to A22, A23, D0 to D15, MA0 to MA12, CS0 to CS3, WRL/WR/CASL, WRH/BHE/CASH,
RD/DW, BCLK/ALE/CLKOUT, HLDA/ALE, HOLD, ALE/RAS, and RDY are not changed.
Note 3: Port 11 to 15 direction registers exist in 144-pin version.
Note 4: Port P70 and P71 output high impedance because of N-channel open drain output.
Note 5: Port P85 is read only (There is not W).
Note 6: Nothing is assigned in bit7 to bit5 of port P11 and bit7 of port P14.
When write, set to "0". When read, its content is indeterminate.
Figure 1.29.6. Port register
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Function select register A0
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
When reset
PS0
03B016
0016
Bit
symbol
Bit name
PS0_0
Port P60 function
select bit
PS0_1
Port P61 function 0 : I/O port
1 : UART0 output (CLK0 output)
select bit
PS0_2
Port P62 function 0 : I/O port
1 : Function that was selected in bit2 of
select bit
function select register B0
PS0_3
Port P63 function 0 : I/O port
select bit
1 : UART0 output (TXD0/SDA0)
PS0_4
Port P64 function 0 : I/O port
1 : Function that was selected in bit4 of
select bit
function select register B0
PS0_5
Port P65 function 0 : I/O port
select bit
1 : UART1 output (CLK1 output)
PS0_6
Port P66 function 0 : I/O port
1 : Function that was selected in bit6 of
select bit
function select register B0
PS0_7
Port P67 function 0 : I/O port
select bit
1 : UART1 output (TXD1/SDA1)
Function
R W
0 : I/O port
1 : UART0 output (RTS0)
Function select register A1
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PS1
Bit
symbol
PS1_0
PS1_1
PS1_2
PS1_3
PS1_4
PS1_5
PS1_6
PS1_7
Address
03B116
Bit name
When reset
0016
Function
R W
Port P70 function 0 : I/O port
1 : Function that was selected in bit0 of
select bit
function select register B1
0
:
I/O port
Port P71 function
1 : Function that was selected in bit1 of
select bit
function select register B1
0
:
I/O port
Port P72 function
1 : Function that was selected in bit2 of
select bit
function select register B1
Port P73 function 0 : I/O port
1 : Function that was selected in bit3 of
select bit
function select register B1
0
:
I/O port
Port P74 function
1 : Function that was selected in bit4 of
select bit
function select register B1
0
:
I/O port
Port P75 function
1 : Function that was selected in bit5 of
select bit
function select register B1
0
:
I/O port
Port P76 function
1 : Function that was selected in bit6 of
select bit
function select register B1
Port P77 function 0 : I/O port
1 : Intelligent I/O group 0 output
select bit
(OUTC01/ISCLK0)
Figure 1.29.7. Function select register A (1)
317
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Function select register A2
b7
b6
b5
0 0
b4
b3
b2
b1
b0
0 0
Symbol
PS2
Address
03B416
When reset
00X000002
Bit
symbol
Bit name
PS2_0
Port P80 function
select bit
PS2_1
Port P81 function
select bit
PS2_2
Port P82 function
select bit
0 : I/O port
1 : Function that was selected in bit0 of
function select register B2
0 : I/O port
1 : Function that was selected in bit1 of
function select register B2
0 : I/O port
1 : Function that was selected in bit2 of
function select register B2
Reserve bit
Must always be "0".
Function
R W
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Reserve bit
Must always be "0".
Function select register A3 (Note)
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PS3
Bit
symbol
Address
03B516
Bit Name
When reset
0016
Function
PS3_0
Port P90 function
select bit
0 : I/O port
1 : UART3 output (CLK3)
PS3_1
Port P91 function
select bit
PS3_2
Port P92 function
select bit
0 : I/O port
1 : Function that was selected in bit1 of
function select register B3
0 : I/O port
1 : Function that was selected in bit2 of
function select register B3
PS3_3
Port P93 function
select bit
0 : I/O port
1 : UART3 output (RTS3)
PS3_4
Port P94 function
select bit
0 : I/O port
1 : UART4 output (RTS4)
PS3_5
Port P95 function
select bit
0 : I/O port
1 : UART4 output (CLK4)
PS3_6
Port P96 function
select bit
0 : I/O port
1 : UART4 output (TXD4/SDA4)
PS3_7
Port P97 function
select bit
0 : I/O port
1 : Function that was selected in bit7 of
function select register B3
Note :Set bit 2 of protect register (address 000A16) to "1" before rewriting to this register.
Figure 1.29.8. Function select register A (2)
318
R W
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Function select register A5
b7
b6
b5
b4
b3
b2
b1
b0
0
(Note)
Symbol
PS5
Address
03B916
Bit
symbol
PS5_0
PS5_1
When reset
XXX0 00002
Bit name
Function
R W
Port P110 function 0 : I/O port
1 : Intelligent I/O group 1 output
select bit
(OUTC10/ ISTXD1/BE1OUT)
0
:
I/O
port
Port P111 function
1 : Intelligent I/O group 1 output
select bit
(OUTC11/ ISCLK1)
PS5_2
Port P112 function 0 : I/O port
select bit
1 : Intelligent I/O group 1 output (OUTC12)
PS5_3
Port P113 function 0 : I/O port
select bit
1 : Intelligent I/O group 1 output (OUTC13)
Reserve bit
Must always be "0".
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This register exists in 144-pin version.
Function select register A6
b7
b6
b5
b4
b3
b2
b1
b0
(Note)
Symbol
PS6
Bit
symbol
Address
03BC16
Bit name
When reset
0016
Function
PS6_0
Port P120 function 0 : I/O port
1 : Intelligent I/O group 3 output (OUTC30)
select bit
PS6_1
Port P121 function 0 : I/O port
1 : Intelligent I/O group 3 output (OUTC31)
select bit
PS6_2
Port P122 function 0 : I/O port
select bit
1 : Intelligent I/O group 3 output (OUTC32)
PS6_3
Port P123 function 0 : I/O port
1 : Intelligent I/O group 3 output (OUTC33)
select bit
PS6_4
Port P124 function 0 : I/O port
1 : Intelligent I/O group 3 output (OUTC34)
select bit
PS6_5
Port P125 function 0 : I/O port
1 : Intelligent I/O group 3 output (OUTC35)
select bit
PS6_6
Port P126 function 0 : I/O port
1 : Intelligent I/O group 3 output (OUTC36)
select bit
PS6_7
Port P127 function 0 : I/O port
1 : Intelligent I/O group 3 output (OUTC37)
select bit
R W
Note: This register exists in 144-pin version.
Figure 1.29.9. Function select register A (3)
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Function select register A7
b6
b5
b4
b3
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
b7
Mitsubishi Microcomputers
b2
b1
b0
(Note)
Symbol
PS7
Address
03BD16
Bit
symbol
When reset
0016
Bit name
Function
PS7_0
Port P130 function 0 : I/O port
select bit
1 : Intelligent I/O group 2 output (OUTC24)
PS7_1
Port P131 function 0 : I/O port
select bit
1 : Intelligent I/O group 2 output (OUTC25)
PS7_2
Port P132 function 0 : I/O port
select bit
1 : Intelligent I/O group 2 output (OUTC26)
PS7_3
Port P133 function 0 : I/O port
select bit
1 : Intelligent I/O group 2 output (OUTC23)
PS7_4
Port P134 function 0 : I/O port
1 : Intelligent I/O group 2 output
select bit
(OUTC20/ISTXD2/IEOUT)
PS7_5
Port P135 function 0 : I/O port
select bit
1 : Intelligent I/O group 2 output (OUTC22)
PS7_6
Port P136 function 0 : I/O port
1 : Intelligent I/O group 2 output
select bit
(OUTC21/ISCLK2)
PS7_7
Port P137 function 0 : I/O port
select bit
1 : Intelligent I/O group 2 output (OUTC27)
R W
Note: This register exists in 144-pin version.
Function select register A8
b7
b6
b5
b4
0 0 0
b3
b2
b1
b0
(Note)
Symbol
PS8
Address
03A016
When reset
X00000002
Bit
symbol
Bit name
PS8_0
Port P140 function
select bit
0 : I/O port
1 : Intelligent I/O group 1 output (OUTC14)
PS8_1
Port P141 function
select bit
0 : I/O port
1 : Intelligent I/O group 1 output (OUTC15)
PS8_2
Port P142 function
select bit
0 : I/O port
1 : Intelligent I/O group 1 output (OUTC16)
PS8_3
Port P143 function
select bit
0 : I/O port
1 : Intelligent I/O group 1 output (OUTC17)
Reserve bit
Function
Must always be "0".
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This register exists in 144-pin version.
Figure 1.29.10. Function select register A (4)
320
R W
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Function select register A9
b7
b6
0 0
b5
b4
b3
b2
0 0
b1
b0
(Note)
Symbol
PS9
Bit
symbol
PS9_0
PS9_1
Address
03A116
When reset
0016
Bit name
Function
R W
Port P150 function 0 : I/O port
1 : Intelligent I/O group 0 output
select bit
(OUTC00/ ISTXD0/BE0OUT)
Port P151 function 0 : I/O port
1 : Intelligent I/O group 0 output
select bit
(OUTC01/ ISCLK0)
Reserve bit
Must always be "0".
PS9_4
Port P154 function 0 : I/O port
select bit
1 : Intelligent I/O group 0 output (OUTC04)
PS9_5
Port P155 function 0 : I/O port
select bit
1 : Intelligent I/O group 0 output (OUTC05)
Reserve bit
Must always be "0".
Note: This register exists in 144-pin version.
Figure 1.29.11. Function select register A (5)
321
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Function select register B0
b7
b6
0
b5
b4
0
b3
b2
0
b1
b0
0
0
Symbol
PSL0
Address
03B216
Bit
symbol
PSL0_2
Bit name
Must always be "0".
Port P62 peripheral
function select bit
0 : UART0 output (SCL0)
1 : UART0 output (STXD0)
Port P64 peripheral
function select bit
Reserve bit
PSL0_6
Function
Reserve bit
Reserve bit
PSL0_4
When reset
0016
Port P66 peripheral
function select bit
Reserve bit
R W
Must always be "0".
0 : UART1 output (RTS1)
1 : Intelligent I/O group 2 output
(OUTC21/ISCLK2)
Must always be "0".
0 : UART1 output (SCL1)
1 : UART1 output (STXD1)
Must always be "0".
Function select register B1
b7
0
b6
b5
b4
b3
b2
b1
b0
Symbol
PSL1
Bit
symbol
PSL1_0
PSL1_1
PSL1_2
PSL1_3
PSL1_4
Address
03B316
Bit name
Function
Port P70 peripheral 0 : Function that was selected in bit0 of
function select register C
function select bit 1 : Timer output (TA0OUT)
Port P71 peripheral 0 : Function that was selected in bit1 of
function select register C
function select bit 1 : UART2 output (STXD2)
Port P72 peripheral 0 : Function that was selected in bit2 of
function select register C
function select bit 1 : Timer output (TA1OUT)
Port P73 peripheral 0 : Function that was selected in bit3 of
function select register C
function select bit 1 : Three-phase PWM output (V)
Port P74 peripheral 0 : Function that was selected in bit4 of
function select register C
function select bit 1 : Three-phase PWM output (W)
PSL1_5
Port P75 peripheral 0 : Three-phase PWM output (W)
function select bit 1 : Intelligent I/O group 1 output (OUTC12)
PSL1_6
Port P76 peripheral 0 : Function that was selected in bit6 of
function select register C
function select bit 1 : Timer output (TA3OUT)
Reserve bit
Figure 1.29.12. Function select register B (1)
322
When reset
0016
Must always be "0".
R W
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Function select register B2
b7
b6
b5
0 0
b4
b3
0
0
b2
b1
b0
Symbol
PSL2
Address
03B616
Bit
symbol
Bit name
When reset
00X000002
Function
PSL2_0
Port P80 peripheral 0 : Timer output (TA4OUT)
function select bit
1 : Three-phase PWM output (U)
PSL2_1
Port P81 peripheral 0 : Three-phase PWM output (U)
1 : Intelligent I/O group 3 output
function select bit
(OUTC30)
PSL2_2
Port P82 peripheral 0 : Intelligent I/O group 3 output (OUTC32)
function select bit
1 : CAN output (CANOUT)
Reserve bit
R W
Must always be "0".
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Reserve bit
Must always be "0".
Function select register B3
b7
b6
b5
b4
b3
b2
b1
b0
0
Symbol
PSL3
Bit
symbol
Address
03B716
Bit name
Reserve bit
PSL3_1
PSL3_2
PSL3_3
PSL3_4
PSL3_5
When reset
0016
Function
R W
Must always be "0".
Port P91 peripheral 0 : UART3 output (SCL3)
function select bit
1 : UART3 output (STXD3)
0 : UART3 output (TXD3/SDA3)
Port P92 peripheral
1 : Intelligent I/O group 2 output
function select bit
(OUTC20/IEOUT)
Port P93 peripheral 0 : Input peripheral function enabled
(Note)
(Expect DA0 output)
function select bit
1 : Input peripheral function disabled (DA0 output)
Port P94 peripheral 0 : Input peripheral function enabled
(Note)
(Expect DA1 output)
function select bit
1 : Input peripheral function disabled (DA1 output)
0 : Input peripheral function enabled
Port P95 peripheral
(Expect ANEX0 output)
(Note)
function select bit
1 : Input peripheral function disabled (ANEX0 output)
PSL3_6
Port P96 peripheral 0 : Input peripheral function enabled
(Note)
(Expect ANEX1 output)
function select bit
1 : Input peripheral function disabled (ANEX1 output)
PSL3_7
Port P97 peripheral 0 : UART4 output (SCL4)
function select bit
1 : UART4 output (STXD4)
Note: Although DA0, DA1, ANEX0 and ANEX1 can be used when "0" is set in these bits, the power supply
may be increased.
Figure 1.29.13. Function select register B (2)
323
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Function select register C
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PSC
Bit
symbol
Address
03AF16
Bit name
When reset
00X000002
Function
R W
PSC_0
Port P70 peripheral 0 : UART2 output (TXD2/SDA2)
1 : Intelligent I/O group 2 output
function select bit
(OUTC20/ ISTXD2/IEOUT)
PSC_1
Port P71 peripheral 0 : UART2 output (SCL2)
function select bit 1 : Intelligent I/O group 2 output (OUTC22)
PSC_2
Port P72 peripheral 0 : UART2 output (CLK2)
function select bit 1 : Three-phase PWM output (V)
PSC_3
PSC_4
Port P73 peripheral 0 : UART2 output (RTS2)
1 : Intelligent I/O group 1 output
function select bit
(OUTC10/ ISTXD1/BE1OUT)
Port P74 peripheral 0 : Timer output (TA2OUT)
1 : Intelligent I/O group 1 output
function select bit
(OUTC11/ ISCLK1)
Noting is assigned. When write, set to "0".
When read, its content is indeterminate.
PSC_6
Port P76 peripheral 0 : Intelligent I/O group 0 output
(OUTC00/ISTXD0/BE0OUT)
function select bit 1 : CAN output (CANOUT)
PSC_7
Key input interrupt 0 : Enabled
disable bit
1 : Disabled
(Note)
Note: Although DA0, DA1, ANEX0 and ANEX1 can be used when "0" is set in this bit, the power supply
may be increased.
Figure 1.29.14. Function select register C
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Pull-up control register 0
b6
b5
b4
b3
b2
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
b7
Mitsubishi Microcomputers
b1
b0
(Note)
Symbol
Address
When reset
PUR0
03F016
000000002
Bit
symbol
Bit name
Function
PU00
P00 to P03 pull-up
0 : Not pulled high
1 : Pulled high
PU01
P04 to P07 pull-up
0 : Not pulled high
1 : Pulled high
PU02
P10 to P13 pull-up
0 : Not pulled high
1 : Pulled high
PU03
P14 to P17 pull-up
0 : Not pulled high
1 : Pulled high
PU04
P20 to P23 pull-up
0 : Not pulled high
1 : Pulled high
PU05
P24 to P27 pull-up
0 : Not pulled high
1 : Pulled high
PU06
P30 to P33 pull-up
0 : Not pulled high
1 : Pulled high
PU07
P34 to P37 pull-up
0 : Not pulled high
1 : Pulled high
R W
Note: Since P0 to P5 operate as the bus in memory expansion mode and microprocessor mode,
do not set the pull-up control register. However, it is possible to select pull-up resistance
presence to the usable port as I/O port by setting.
Pull-up control register 1
b7
b6
b5
b4
b3
b2
b1
b0
(Note)
Symbol
PUR1
Bit
symbol
Address
03F116
Bit name
When reset
XXXX00002
Function
PU10
P40 to P43 pull-up
0 : Not pulled high
1 : Pulled high
PU11
P44 to P47 pull-up
0 : Not pulled high
1 : Pulled high
PU12
P50 to P53 pull-up
0 : Not pulled high
1 : Pulled high
PU13
P54 to P57 pull-up
0 : Not pulled high
1 : Pulled high
R W
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: Since P0 to P5 operate as the bus in memory expansion mode and microprocessor mode,
do not set the pull-up control register. However, it is possible to select pull-up resistance
presence to the usable port as I/O port by setting.
Figure 1.29.15. Pull-up control register (1)
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Pull-up control register 2
b6
b5
b4
b3
b2
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
b7
Mitsubishi Microcomputers
b1
b0
(Note 1)
Symbol
Address
PUR2
03DA16
Bit
symbol
Bit name
When reset
000000002
Function
PU20
P60 to P63 pull-up
0 : Not pulled high
1 : Pulled high
PU21
P64 to P67 pull-up
0 : Not pulled high
1 : Pulled high
PU22
P70 to P73 pull-up
0 : Not pulled high
1 : Pulled high
PU23
P74 to P77 pull-up
0 : Not pulled high
1 : Pulled high
PU24
P80 to P83 pull-up
0 : Not pulled high
1 : Pulled high
PU25
P84 to P87 pull-up
0 : Not pulled high
1 : Pulled high
PU26
P90 to P93 pull-up
0 : Not pulled high
1 : Pulled high
PU27
P94 to P97 pull-up
0 : Not pulled high
1 : Pulled high
R W
(Note 2)
(Note 3)
Note 1: Since P70 and P71 are N-channel open drain ports, pull-up is not available for them.
Note 2: Except port P85.
<144-pin version>
Pull-up control register 3
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PUR3
Bit
symbol
Bit name
When reset
000000002
Function
PU30
P100 to P103 pull-up
0 : Not pulled high
1 : Pulled high
PU31
P104 to P107 pull-up
0 : Not pulled high
1 : Pulled high
PU32
P110 to P113 pull-up
0 : Not pulled high
1 : Pulled high
PU33
P114 pull-up
0 : Not pulled high
1 : Pulled high
PU34
P120 to P123 pull-up
0 : Not pulled high
1 : Pulled high
PU35
P124 to P127 pull-up
0 : Not pulled high
1 : Pulled high
PU36
P130 to P133 pull-up
0 : Not pulled high
1 : Pulled high
PU37
P134 to P137 pull-up
0 : Not pulled high
1 : Pulled high
Figure 1.29.16. Pull-up control register (2)
326
Address
03DB16
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
<100-pin version>
Pull-up control register 3
b7
b6
0 0
b5
b4
b3
b2
b1
b0
0 0 0 0
Symbol
PUR3
Address
03DB16
Bit
symbol
Bit name
b6
b5
b4
b3
b2
b1
b0
Function
PU30
P100 to P103 pull-up
0 : Not pulled high
1 : Pulled high
PU31
P104 to P107 pull-up
0 : Not pulled high
1 : Pulled high
Reserve bit
Must always be "0".
Pull-up control register 4
b7
When reset
0016
R W
(Note)
Symbol
PUR4
Bit
symbol
Address
03DC16
When reset
XXXX00002
Bit name
Function
PU40
P140 to P143 pull-up
0 : Not pulled high
1 : Pulled high
PU41
P144 to P146 pull-up
0 : Not pulled high
1 : Pulled high
PU42
P150 to P153 pull-up
0 : Not pulled high
1 : Pulled high
PU43
P154 to P157 pull-up
0 : Not pulled high
1 : Pulled high
R W
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note: This register exists in 144-pin version..
Figure 1.29.17. Pull-up control register (3)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Port control register
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1)
Symbol
PCR
Address
03FF16
Bit
symbol
PCR0
When reset
XXXXXXX02
Bit name
Port P1 control
register
Function
R W
0 : Function as common CMOS port
1 : Function as N-ch open drain port
(Note 2)
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
Note 1: Since P1 operates as the data bus in memory expansion mode and microprocessor
mode, do not set the port control register. However, it is possible to select CMOS port
or N-channel open drain pin to the usable port as I/O port by setting.
Note 2: This function is designed to permanently turn OFF the Pch of the CMOS port.
It dose not make port P1 a full open drain.
Therefore, the absolute maximum input voltage rating is [-3 to VCC + 3.0V].
Input function select register
b7
b0
Symbol
IPS
Bit
symbol
Address
017816
When reset
00000X002
Bit name
Function
Group 0 input pin
select bit 0
Assigns functions of INPC00, INPC01
/ISCLK0 and INPC02/ISRxD0/BE0IN
to the following ports.
0 : P76, P77, P80
1 : P150, P151, P152
IPS1
Group 1 input pin
select bit 1
Assigns functions of INPC11/ISCLK1
and INPC12/ISRxD1/BE1IN to the
following ports.
0 : P74, P75
1 : P111, P112
IPS2
P15 input peripheral
function select bit
0 : Input peripheral function is enabled
1 : Input peripheral function is disabled
(Note)
IPS3
CANIN function
pin select bit
0 : P77
1 : P83
IPS0
b5 b4
IPS4
ISRxD2/IEIN function
pin select bit
IPS5
IPS6
0
0
1
1
0
1
0
1
: P71
: P91
: P135
: Must not be set
ISCLK2 function
pin select bit
0 : P64
1 : P136
Reserve bit
Must always be "0".
Note: Although AD input pin can be used when "0" is set in this bit,
the power supply may be increased.
Figure 1.29.18. Port control register and input function select register
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Table 1.29.1. Example connection of unused pins in single-chip mode
Pin name
Connection
Ports P0 to P15 (excluding P85) After setting for input mode, connect every pin to VSS via a resistance
(Note 1) (pull-down); or after setting for output mode, leave these pins open.
XOUT (Note 2)
Open
NMI
Connect via resistance to VCC (pull-up)
AVCC
Connect to VCC
AVSS, VREF, BYTE
Connect to VSS
Note 1: Ports P11 to P15 exist in 144-pin version.
Note 2: With external clock input to XIN pin.
Table 1.29.2. Example connection of unused pins in memory expansion mode and microprocessor mode
Pin name
Connection
Ports P6 to P15 (excluding P85) After setting for input mode, connect every pin to VSS via a resistance
(pull-down); or after setting for output mode, leave these pins open.
(Note 1)
Open
BHE, ALE, HLDA,
XOUT(Note 2), BCLK
HOLD, RDY, NMI
Connect via resistance to VCC (pull-up)
AVCC
Connect to VCC
AVSS, VREF
Connect to VSS
Note 1: Ports P11 to P15 exist in 144-pin version.
Note 2: With external clock input to XIN pin.
Microcomputer
Microcomputer
Port P0 to P15 (except for P85)
Port P6 to P15 (except for P85)
(Note)
(Input mode)
·
·
·
(Input mode)
(Output mode)
(Input mode)
·
·
·
(Input mode)
·
·
·
Open
(Output mode)
Open
NMI
BHE
HLDA
ALE
XOUT
BCLK
NMI
XOUT
VCC
AVCC
BYTE
·
·
·
Open
Open
VCC
HOLD
RDY
AVSS
VREF
VSS
In single-chip mode
AVCC
AVSS
VREF
VSS
In memory expansion mode or
in microprocessor mode
Note : Ports P11 to P15 exist in 144-pin version.
Figure 1.29.19. Example connection of unused pins
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Programmable I/O Port
Table 1.29.3. Port P6 output control
PS0 register
PSL0 register
Bit 0 0: P60
Must
set to "0"
________
1: UART0 output (RTS0)(Note)
Bit 1 0: P61
Must set to "0"
1: UART0 output (CLK0)(Note)
Bit 2 0: P62
0: UART0 output (SCL0)
1: Selected by PSL0 register
1: UART0 output (STxD0)
Bit 3 0: P63
Must set to "0"
1: UART0 output (TxD0/SDA0)(Note)
________
Bit 4 0: P64
0: UART1 output (RTS1)
1: Selected by PSL0 register
1: Intelligent I/O group 2 (OUTC21/ISCLK2)
Bit 5 0: P65
Must set to "0"
1: UART1 output (CLK1)(Note)
Bit 6 0: P66
0: UART1 output (SCL1)
1: Selected by PSL0 register
1: UART1 output (STxD1)
Bit 7 0: P67
Must set to "0"
1: UART1 output (TxD1/SDA1)(Note)
PS0 register: Function select register A0
PSL0 register: Function select register B0
Note : Select "0" in corresponding bit of PSL0 register.
Table 1.29.4. Port P7 output control
PS1 register
Bit 0 0: P70
1: Selected by PSL1 register
PSL1 register
0: Selected by PSC register
1: TImer output (TA0OUT)(Note 1)
PSC register
0: UART2 output (TxD2/SDA2)
1: Intelligent I/O group 2
(OUTC20/ISTxD2/IEOUT)
Bit 1 0: P71
1: Selected by PSL1 register
0: Selected by PSC register
1: UART2 output (STxD2)(Note 1)
0: UART2 output (SCL2)
1: Intelligent I/O group 2
(OUTC22)
Bit 2 0: P72
1: Selected by PSL1 register
Bit 3 0: P73
1: Selected by PSL1 register
0: Selected by PSC register
1: TImer output (TA1OUT)(Note 1)
0: Selected by PSC register __
1: Three-phase PWM output (V)(Note 1)
0: UART2 output (CLK2)
1: Three-phase PWM output (V)
_______
0: UART2 output (RTS2)
1: Intelligent I/O group 1
(OUTC10/ISTxD1/BE1OUT)
Bit 4 0: P74
1: Selected by PSL1 register
0: Selected by PSC register
1: Three-phase PWM output (W)(Note 1)
0: TImer output (TA2OUT)
1: Intelligent I/O group 1
(OUTC11/ISCLK1)
Bit 5 0: P75
1: Selected by PSL1 register
0: Three-phase PWM output (W)(Note 1)
1: Intelligent I/O group 1
(OUTC12)
Must set to "0"
Bit 6 0: P76
0: Selected by PSC register
0: Intelligent I/O group 0
(OUTC00/ISTxD0/BE0OUT)
1: CAN output (CANOUT)
___
1: Selected by PSL1 register
Bit 7 0: P77
1: Intelligent I/O group 0
(OUTC01/ISCLK0)
1: TImer output (TA3OUT)
Must set to "0"
PS1 register: Function select register A1
PSL1 register: Function select register B1
PSC register: Function select register C
Note 1: Select "0" in corresponding bit of PSC register.
Note 2: Select "0" in corresponding bit of PSL1 register.
330
0: Key input interrupt signal enabled
1: Key input interrupt signal disabled
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Programmable I/O Port
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Table 1.29.5. Port P8 output control
PS2 register
PSL2 register
Bit 0 0: P80
0: Timer output (TA4OUT)
1: Selected by PSL2 register
1: Three-phase PWM output (U)
____
0: Three-phase PWM output (U)
Bit 1 0: P81
1: Selected by PSL2 register
1: Intelligent I/O group 3(OUTC30)
Bit 2 0: P82
0: Intelligent I/O group 3(OUTC32)
1: Selected by PSL2 register
1: CAN output (CANOUT)
Bit 3 to 7 Must set to "0"
PS2 register: Function select register A2
PSL2 register: Function select register B2
Table 1.29.6. Port P9 output control
PS3 register
PSL3 register
Bit 0 0: P90
Must set to "0"
1: UART3 output (CLK3)(Note)
Bit 1 0: P91
0: UART3 output (SCL3)
1: Selected by PSL3 register
1: UART3 output (STxD3)
Bit 2 0: P92
0: UART3 output (TxD3/SDA3)
1: Selected by PSL3 register
1: Intelligent I/O group 2 (OUTC20/IEOUT)
Bit 3 0: P93
0:
Except DA0 output
________
1: UART3 output (RTS3)(Note)
1: DA0 output
Bit 4 0: P94
0: Except DA1 output
________
1: UART4 output (RTS4)(Note)
1: DA1 output
Bit 5 0: P95
0: Except ANEX0
1: UART4 output (CLK4)(Note)
1: ANEX0
Bit 6 0: P96
0: Except ANEX1
1: UART4 output (TxD4/SDA4)(Note)
1: ANEX1
Bit 7 0: P97
0: UART4 output (SCL4)
1: Selected by PSL3 register
1: UART4 output (STxD4)
PS3 register: Function select register A3
PSL3 register: Function select register B3
Note : Select "0" in corresponding bit of PSL3 register.
Table 1.29.7. Port P11 output control
PS5 register
Bit 0 0: P110
1: Intelligent I/O group 1(OUTC10/ISTxD1/BE1OUT)
Bit 1 0: P111
1: Intelligent I/O group 1(OUTC11/ISCLK1)
Bit 2 0: P112
1: Intelligent I/O group 1(OUTC12)
Bit 3 0: P113
1: Intelligent I/O group 1(OUTC13)
Bit 4 to 7 Must set to "0"
PS5 register: Function select register A5
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Programmable I/O Port
Table 1.29.8. Port P12 output control
PS6 register
Bit 0 0: P120
1: Intelligent I/O group 3(OUTC30)
Bit 1 0: P121
1: Intelligent I/O group 3(OUTC31)
Bit 2 0: P122
1: Intelligent I/O group 3(OUTC32)
Bit 3 0: P123
1: Intelligent I/O group 3(OUTC33)
Bit 4 0: P124
1: Intelligent I/O group 3(OUTC34)
Bit 5 0: P125
1: Intelligent I/O group 3(OUTC35)
Bit 6 0: P126
1: Intelligent I/O group 3(OUTC36)
Bit 7 0: P127
1: Intelligent I/O group 3(OUTC37)
PS6 register: Function select register A6
Table 1.29.9. Port P13 output control
PS7 register
Bit 0 0: P130
1: Intelligent I/O group 2(OUTC24)
Bit 1 0: P131
1: Intelligent I/O group 2(OUTC25)
Bit 2 0: P132
1: Intelligent I/O group 2(OUTC26)
Bit 3 0: P133
1: Intelligent I/O group 2(OUTC23)
Bit 4 0: P134
1: Intelligent I/O group 2(OUTC20/ISTxD2/IEOUT)
Bit 5 0: P135
1: Intelligent I/O group 2(OUTC22)
Bit 6 0: P136
1: Intelligent I/O group 2(OUTC21/ISCLK2)
Bit 7 0: P137
1: Intelligent I/O group 2(OUTC27)
PS7 register: Function select register A7
Table 1.29.10. Port P14 output control
PS8 register
Bit 0 0: P140
1: Intelligent I/O group 1(OUTC14)
Bit 1 0: P141
1: Intelligent I/O group 1(OUTC15)
Bit 2 0: P142
1: Intelligent I/O group 1(OUTC16)
Bit 3 0: P143
1: Intelligent I/O group 1(OUTC17)
Bit 4 to 7 Must set to "0"
PS8 register: Function select register A8
332
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
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Programmable I/O Port
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Table 1.29.11. Port P15 output control
PS9 register
Bit 0 0: P150
1: Intelligent I/O group 0 (OUTC00/ISTxD0/BEOUT)
Bit 1 0: P151
1: Intelligent I/O group 0 (OUTC01/ISCLK0)
Bit 2 to 3 Must set to "0"
Bit 4 0: P154
1: Intelligent I/O group 0 (OUTC04)
Bit 5 0: P155
1: Intelligent I/O group 0 (OUTC05)
Bit 6 to 7 Must set to "0"
PS9 register: Function select register A9
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VDC
VDC
When power-supply voltage is 3.3V or under, set the internal VDC (Voltage Down Converter) unused.
Follow the steps given below to disable the VDC.
(1) Set bit 3 of the protect register to "1".
(2) Set the VDC control register 0 to "0F16".
(3) Set the VDC control register 0 to "8F16".
(4) Set bit 3 of the protect register to "0".
These steps must be performed after reset as immediately as possible with divide-by-8 clock. When the
VDC select bit has been set to "112" once, do not set any other values.
Figure 1.30.1 shows the VDC control register 0.
VDC control register 0
b7
b6
b5
b4
b3
b2
b1
b0
(Note 1)
Symbol
VDC0
Bit
symbol
Address
001B16
When reset
0016
Bit name
Function
b1b0
VDC00
1 1: VDC unused
VDC select bit
Do not set any values other than "11".
VDC01
b3 b2
1 1: VDC reference voltage Off
VDC02
VDC03
VDC reference voltage
select bit
Do not set any values other than "11".
VDC04
VDC05
Must set to "0"
Reserved bit
VDC06
VDC07
VDC enable bit
(Note 2)
0: VDC Off
1: VDC On
Note 1: Set bit 3 of the protect register (address 000A16) to "1" before rewriting this register.
Rewriting this register should be performed only when the VDC is to be off.
Note 2: This bit enables the setting of bit 0 to bit 3.
Set bit 7 to "0" first, and then write values to bit 0 to bit 3. After that, write "1" to bit 7.
The state changes at the time "1" is written to bit 7.
Figure 1.30.1. VDC control register
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Usage precaution
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage Precaution
Timer A (timer mode)
(1) Reading the timer Ai register while a count is in progress allows reading, with arbitrary timing, the
value of the counter. Reading the timer Ai register while reloading gets “FFFF16”. Reading the timer Ai
register after setting a value in the timer Ai register with a count halted but before the counter starts
counting gets a proper value.
Timer A (event counter mode)
(1) Reading the timer Ai register while a count is in progress allows reading, with arbitrary timing, the
value of the counter. Reading the timer Ai register while reloading gets “FFFF16” by underflow or
“000016” by overflow. Reading the timer Ai register after setting a value in the timer Ai register with a
count halted but before the counter starts counting gets a proper value.
(2) When stop counting in free run type, set timer again.
(3) In the case of using as “Free-Run type”, the timer register contents may be unknown when counting
begins. If the timer register is set before counting has started, then the starting value will be unknown.
• In the case where the up/down count will not be changed.
Enable the “Reload” function and write to the timer register before counting begins. Rewrite
the value to the timer register immediately after counting has started. If counting up, rewrite
“000016” to the timer register. If counting down, rewrite “FFFF16” to the timer register. This
will cause the same operation as “Free-Run type” mode.
• In the case where the up/down count has changed.
First set to “Reload type” operation. Once the first counting pulse has occurred, the timer
may be changed to “Free-Run type”.
Timer A (one-shot timer mode)
(1) Setting the count start flag to “0” while a count is in progress causes as follows:
• The counter stops counting and a content of reload register is reloaded.
• The TAiOUT pin outputs “L” level.
• The interrupt request generated and the timer Ai interrupt request bit goes to “1”.
(2) The output from the one-shot timer synchronizes with the count source generated internally. Therefore, when an external trigger has been selected, a delay of one cycle of count source as maximum
occurs between the trigger input to the TAiIN pin and the one-shot timer output.
(3) The timer Ai interrupt request bit goes to “1” if the timer's operation mode is set using any of the
following procedures:
• Selecting one-shot timer mode after reset.
• Changing operation mode from timer mode to one-shot timer mode.
• Changing operation mode from event counter mode to one-shot timer mode.
Therefore, to use timer Ai interrupt (interrupt request bit), set timer Ai interrupt request bit to “0” after
the above listed changes have been made.
(4) If a trigger occurs while a count is in progress, after the counter performs one down count following the
reoccurrence of a trigger, the reload register contents are reloaded, and the count continues. To
generate a trigger while a count is in progress, generate the second trigger after an elapse longer
than one cycle of the timer's count source after the previous trigger occurred.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
Timer A (pulse width modulation mode)
(1) The timer Ai interrupt request bit becomes “1” if setting operation mode of the timer in compliance with
any of the following procedures:
• Selecting PWM mode after reset.
• Changing operation mode from timer mode to PWM mode.
• Changing operation mode from event counter mode to PWM mode.
Therefore, to use timer Ai interrupt (interrupt request bit), set timer Ai interrupt request bit to “0” after
the above listed changes have been made.
(2) Setting the count start flag to “0” while PWM pulses are being output causes the counter to stop
counting. If the TAiOUT pin is outputting an “H” level in this instance, the output level goes to “L”, and
the timer Ai interrupt request bit goes to “1”. If the TAiOUT pin is outputting an “L” level in this instance,
the level does not change, and the timer Ai interrupt request bit does not becomes “1”.
Timer B (timer mode, event counter mode)
(1) Reading the timer Bi register while a count is in progress allows reading, with arbitrary timing, the
value of the counter. Reading the timer Bi register while reloading gets “FFFF16”. Reading the timer Bi
register after setting a value in the timer Bi register with a count halted but before the counter starts
counting gets a proper value.
Timer B (pulse period/pulse width measurement mode)
(1) If changing the measurement mode select bit is set after a count is started, the timer Bi interrupt
request bit goes to “1”.
(2) When the first effective edge is input after a count is started, an indeterminate value is transferred to
the reload register. At this time, timer Bi interrupt request is not generated.
(3) The value of the counter is indeterminate at the beginning of a count. Therefore, the timer Bi overflow
flag may go to “1” and timer Bi interrupt request may be generated during the interval between a count
start and an effective edge input.
Stop Mode and Wait Mode
____________
(1) When returning from stop mode by hardware reset, RESET pin must be set to “L” level until main clock
oscillation is stabilized.
(2) When shifting to WAIT mode or STOP mode, the program stops after reading from the WAIT instruction and the instruction that sets all clock stop control bits to “1” in the instruction queue. Therefore,
insert a minimum of 4 NOPs after the WAIT instruction and the instruction that sets all clock stop
control bits to “1” in order to flush the instruction queue.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
A-D Converter
(1) Write to each bit (except bit 6) of A-D i (i=0,1) control register 0, to each bit of A-D i control register 1,
and to each bit of A-D i control register 2 when A-D conversion is stopped (before a trigger occurs).
In particular, when the Vref connection bit is changed from “0” to “1”, start A-D conversion after an
elapse of 1 µs or longer.
(2) When changing A-D operation mode, select analog input pin again.
(3) Using one-shot mode or single sweep mode
Read the correspondence A-D register after confirming A-D conversion is finished. (It is known by AD conversion interrupt request bit.)
(4) Using repeat mode, repeat sweep mode 0 or repeat sweep mode 1
Use the undivided main clock as the internal CPU clock.
(5) When f(XIN) is faster than 10 MHz, make the frequency 10 MHz or less by dividing.
(6) Output impedance of sensor at A-D conversion (Reference value)
To carry out A-D conversion properly, charging the internal capacitor C shown in Figure 1.31.1 has to
be completed within a specified period of time T. Let output impedance of sensor equivalent circuit be
R0, microcomputer’s internal resistance be R, precision (error) of the A-D converter be X, and the AD converter’s resolution be Y (Y is 1024 in the 10-bit mode, and 256 in the 8-bit mode).
Vc is generally VC = VIN {1 – e
And when t = T,
VC=VIN –
–
e
t
C (R0 + R)
}
X
X
VIN=VIN(1 –
)
Y
Y
T
C (R0 + R)
=
T
=ln
C (R0 +R)
T
–R
X
C • ln
Y
–
Hence, R0 = –
–
X
Y
X
Y
With the model shown in Figure 1.31.1 as an example, when the difference between VIN and VC becomes
0.1LSB, we find impedance R0 when voltage between pins VC changes from 0 to VIN-(0.1/1024) VIN in
time T. (0.1/1024) means that A-D precision drop due to insufficient capacitor charge is held to 0.1LSB at
time of A-D conversion in the 10-bit mode. Actual error however is the value of absolute precision added
to 0.1LSB. When f(XIN) = 10 MHz, T = 0.3 µs in the A-D conversion mode with sample & hold. Output
impedance R0 for sufficiently charging capacitor C within time T is determined as follows.
T = 0.3 µs, R = 7.8 kΩ, C = 3 pF, X = 0.1, and Y = 1024 . Hence,
R0 = –
0.3 X 10-6
3.0 X 10 –12 • ln
0.1
– 7.8 X103
3.0 X 103
1024
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
Thus, the allowable output impedance of the sensor circuit capable of thoroughly driving the A-D converter turns out to be approximately 3.0 kΩ. Tables 1.31.1 and 1.31.2 show output impedance values
based on the LSB values.
Internal circuit of microprocessor
Sensor-equivalent circuit
R0
VIN
R (7.8k Ω)
C (3.0pF)
VC
Figure 1.31.1 A circuit equivalent to the A-D conversion terminal
(7) After A-D conversion is complete, if the CPU reads the A-D register at the same time as the A-D
conversion result is being saved to A-D register, wrong A-D conversion value is saved into the A-D
register. This happens when the internal CPU clock is selected from divided main clock or sub-clock.
• When using the one-shot or single sweep mode
Confirm that A-D conversion is complete before reading the A-D register.
(Note: When A-D conversion interrupt request bit is set, it shows that A-D conversion is completed.)
• When using the repeat mode or repeat sweep mode 0 or 1
Use the undivided main clock as the internal CPU clock.
Interrupts
(1) Setting the stack pointer
• The value of the stack pointer is initialized to 00000016 immediately after reset. Accepting an
interrupt before setting a value in the stack pointer may cause runaway. Be sure to set a value in
the stack pointer before accepting an interrupt.
_______
When using the NMI interrupt, initialize the stack pointer at the beginning of a program. Regard_______
ing the first instruction immediately after reset, generating any interrupts including the NMI interrupt is prohibited.
Set an even address to the stack pointer so that operating efficiency is increased.
_______
(2) The NMI interrupt
_______
• As for the NMI interrupt pin, an interrupt cannot be prohibited. Connect it to the VCC pin via a
resistance (pulled-up) if unused.
_______
• The NMI pin also serves as P8 5, which is exclusively input. Reading the contents of the P8
register allows reading the pin value. Use the reading of this pin only for establishing the pin level
_______
at the time when the NMI interrupt is input.
_______
• Signal of "L" level width more than 1 clock of CPU operation clock (BCLK) is necessary for NMI
pin.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
Tables 1.31.1. Output impedance values based on the LSB values (10-bit mode) Reference value
f(XIN)
(MHz)
Cycle
(µs)
Sampling time
(µs)
R
(kΩ)
C
(pF)
Resolution
(LSB)
R0max
(kΩ)
10
0.1
0.3
(3 X cycle,
Sample & hold
bit is enabled)
7.8
3.0
10
0.1
0.2
(2 X cycle,
Sample & hold
bit is disabled)
7.8
3.0
0.1
0.3
0.5
0.7
0.9
1.1
1.3
1.5
1.7
1.9
0.3
0.5
0.7
0.9
1.1
1.3
1.5
1.7
1.9
3.0
4.5
5.3
5.9
6.4
6.8
7.2
7.5
7.8
8.1
0.4
0.9
1.3
1.7
2.0
2.2
2.4
2.6
2.8
Tables 1.31.2. Output impedance values based on the LSB values (8-bit mode) Reference value
f(XIN)
(MHz)
10
Cycle
(µs)
Sampling time
(µs)
R
(kΩ)
C
(pF)
Resolution
(LSB)
R0max
(kΩ)
0.1
0.3
(3 X cycle,
Sample & hold
bit is enabled)
7.8
3.0
10
0.1
0.2
(2 X cycle,
Sample & hold
bit is disabled)
7.8
3.0
0.1
0.3
0.5
0.7
0.9
1.1
1.3
1.5
1.7
1.9
0.1
0.3
0.5
0.7
0.9
1.1
1.3
1.5
1.7
1.9
4.9
7.0
8.2
9.1
9.9
10.5
11.1
11.7
12.1
12.6
0.7
2.1
2.9
3.5
4.0
4.4
4.8
5.2
5.5
5.8
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M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
(3) External interrupt
• Edge sense
Either an “L” level or an “H” level of at least 250 ns width is necessary for the signal input to pins
_______
_______
INT0 to INT5 regardless of the CPU operation clock.
• Level sense
Either an “L” level or an “H” level of 1 cycle of BCLK + at least 200 ns width is necessary for the
_______
_______
signal input to pins INT0 to INT5 regardless of the CPU operation clock. (When XIN=30MHz and
no division mode, at least 233 ns width is necessary.)
_______
_______
• When the polarity of the INT0 to INT5 pins is changed, the interrupt request bit is sometimes set to
"1". After changing the polarity, set the interrupt request bit to "0". Figure 1.31.2 shows the
______
procedure for changing the INT interrupt generate factor.
Set the interrupt priority level to level 0
(Disable INTi interrupt)
Set the polarity select bit
Clear the interrupt request bit to “0”
Set the interrupt priority level to level 1 to 7
(Enable the accepting of INTi interrupt request)
______
Figure 1.31.2. Switching condition of INT interrupt request
(4) Rewrite the interrupt control register
• When a instruction to rewrite the interrupt control register is executed but the interrupt is disabled, the interrupt request bit is not set sometimes even if the interrupt request for that register
has been generated. This will depend on the instructions. If this creates problems, use the below
instructions to change the register.
Instructions : AND, OR, BCLR, BSET
DMAC
(1) Do not clear the DMA request bit of the DMAi request cause select register.
In M32C/83, when a DMA request is generated while the channel is disabled (Note), the DMA transfer is not executed and the DMA request bit is cleared automatically.
Note :The DMA is disabled or the transfer count register is "0".
(2) When DMA transfer is done by a software trigger, set DSR and DRQ of the DMAi request cause
select register to "1" simultaneously using the OR instruction.
e.g.) OR.B #0A0h, DMiSL
; DMiSL is DMAi request cause select register
(3) When changing the DMAi request cause select bit of the DMAi request cause select register, set "1"
to the DMA request bit, simultaneously. In this case, disable the corresponding DMA channel to
disabled before changing the DMAi request cause select bit. To enable DMA at least 8+6xN cycles
(N: enabled channel number) following the instruction to write to the DMAi request cause select
register are needed.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
Example) When DMA request cause is changed to timer A0 and using DMA0 in single transfer
after DMA initial setting
push.w
R0
; Store R0 register
stc
DMD0, R0
; Read DMA mode register 0
and.b
#11111100b, R0L
; Clear DMA0 transfer mode select bit to "00"
ldc
R0, DMD0
; DMA0 disabled
mov.b
#10000011b, DM0SL
; Select timer A0
; (Write "1" to DMA request bit simultaneously)
nop
At least 8 + 6 x N cycles
:
(N: enabled channel number)
ldc
R0, DMD0
; DMA0 enabled
pop.w R0
; Restore R0 register
Noise
(1) A bypass capacitor should be inserted between Vcc-Vss line for reducing noise and latch-up
Connect a bypass capacitor (approx. 0.1µF) between the Vcc and Vss pins using short wiring and
thicker circuit traces.
Precautions for using CLKOUT pin
When using the Clock Output function of P53/CLKOUT pin (f8, f32 or fc output) in single chip mode, use
port P57 as an input only port (port P57 direction register is "0").
Although port P57 may be set as an output port (port P57 direction register is "1"), it will become high
impedance and will not output "H" or "L" levels.
__________
HOLD signal
__________
When using the HOLD input while P40 to P47 and P50 to P52 are set as output ports in single-chip mode,
you must first set all pins for P40 to P47 and P50 to P52 as input ports, then shift to microprocessor mode
or memory expansion mode.
Reducing power consumption
(1) When A-D conversion is not performed, select the Vref not connected with the Vref connect bit of A-D
control register 1. When A-D conversion is performed, start the A-D conversion at least 1 µs or longer
after connecting Vref.
(2) When using AN4 (P104) to AN7 (P107), select the input disable of the key input interrupt signal with the
key input interrupt disable bit of the function select register C .
When selecting the input disable of the key input interrupt signal, the key input interrupt cannot be
used. Also, the port cannot be input even if the direction register of P104 to P107 is set to input (the
input result becomes undefined). When the input disable of the key input interrupt signal is selected,
use all AN4 to AN7 as A-D inputs.
(3) When ANEX0 and ANEX1 are used, select the input peripheral function disable with port P95 and P96
input peripheral function select bit of the function select register B3.
When the input peripheral function disable is selected, the port cannot be input even if the port direction register is set to input (the input result becomes undefined).
Also, it is not possible to input a peripheral function except ANEX0 and ANEX1.
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
(4) When D-A converter is not used, set output disabled with the D-A output enable bit of D-A control
register and set the D-A register to "0016".
(5) When D-A conversion is used, select the input peripheral function disabled with port P93 and P94 input
peripheral function select bit of the function select register B3.
When the input peripheral function disabled is selected, the port cannot be input even if the port
direction register is set to input (the input result becomes undefined).
Also, it is not possible to input a peripheral function.
DRAM controller
The DRAM self-refresh operates in stop mode, etc.
When shifting to self-refresh, select DRAM is ignored by the DRAM space select bit. In the next instruction, simultaneously set the DRAM space select bit and self-refresh ON by self-refresh mode bit. Also,
insert two NOPs after the instruction that sets the self-refresh mode bit to "1".
Do not access external memory while operating in self-refresh. (All external memory space access is
inhibited. )
When disabling self-refresh, simultaneously select DRAM is ignored by the DRAM space select bit and
self-refresh OFF by self-refresh mode bit. In the next instruction, set the DRAM space select bit.
Do not access the DRAM space immediately after setting the DRAM space select bit.
Example) One wait is selected by the wait select bit and 4MB is selected by the DRAM space select bit
Shifting to self-refresh
•••
mov.b #00000001b,DRAMCONT
;DRAM is ignored, one wait is selected
mov.b #10001011b,DRAMCONT
;Set self-refresh, select 4MB and one wait
nop
;Two nops are needed
nop
;
•••
Disable self-refresh
•••
mov.b #00000001b,DRAMCONT
mov.b
nop
nop
•••
#00001011b,DRAMCONT
;Disable self-refresh, DRAM ignored, one wait is
;selected
;Select 4MB and one wait
;Inhibit instruction to access DRAM area
Setting the registers
The registers shown in Table 1.31.3 include indeterminate bit when read. Set immidiate to these registers.
Store the content of the frequently used register to RAM, change the content of RAM, then transfer to the
register.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Usage precaution
Table 1.31.3 The object registers
Register name
Watchdog timer start register
Group0 receive input register
Group1 receive input register
Group2 SI/O transmit buffer register
UART4 bit rate generator
UART4 transfer buffer register
Timer A1-1 register
Timer A2-1 register
Timer A4-1 register
Dead time timer
Timer B2 interrupt occurrence frequency set counter
UART3 bit rate generator
UART3 transfer buffer register
Symbol
WDTS
G0RI
G1RI
G2TB
U4BRG
U4TB
TA11
TA21
TA41
DTT
ICTB2
U3BRG
U3TB
UART2 bit rate generator
U2BRG
UART2 transfer buffer register
U2TB
Up-down flag
UDF
Timer A0 register (Note)
TA0
Timer A1 register (Note)
TA1
(Note)
Timer A2 register
TA2
(Note)
Timer A3 register
TA3
Timer A4 register (Note)
TA4
UART0 bit rate generator
U0BRG
UART0 transfer buffer register
U0TB
UART1 bit rate generator
U1BRG
UART1 transfer buffer register
U1TB
A-D0 control register 2
ADCON2
Note: In one-shot timer mode and pulse width modulation mode.
Address
000E16
00EC16
012C16
016D16, 016C16
02F916
02FB16, 02FA16
030316, 030216
030516, 030416
030716, 030616
030C16
030D16
032916
032B16, 032A16
033916
033B16, 033A16
034416
034716, 034616
034916, 034816
034B16, 034A16
034D16, 034C16
034F16, 034E16
036916
036B16, 036A16
02E916
02EB16, 02EA16
039416
Notes on the microprocessor mode and transition after shifting from the microprocessor mode to the memory expansion mode / single-chip mode
In microprocessor mode, the SFR, internal RAM, and external memory space can be accessed.
For that reason, the internal ROM area cannot be accessed.
After the reset has been released and the operation of shifting from the microprocessor mode has started
(“H” applied to the CNVSS pin), the internal ROM area cannot be accessed even if the CPU shifts to the
memory expansion mode or single-chip mode.
Notes on CNVss pin reset at "H" level
When the CNVss pin is reset at "H" level, the contents of internal ROM cannot be read out.
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Electrical characteristics
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Electrical characteristics
Table 1.32.1. Absolute maximum ratings
Symbol
Parameter
Condition
Rated value
Unit
VCC
AVCC
Supply voltage
Analog supply voltage
VCC=AVCC
VCC=AVCC
-0.3 to 6.0
-0.3 to 6.0
V
V
VI
Input voltage
-0.3 to Vcc+0.3
V
-0.3 to 6.0
V
-0.3 to Vcc+0.3
V
-0.3 to 6.0
V
______________
RESET, CNVss, BYTE, P00-P07, P10-P17,
P20-P27, P30-P37, P40-P47, P50-P57, P60P67, P72-P77, P80-P87, P90-P97, P100-P107,
P110-P114, P120-P127, P130-P137, P140P146, P150-P157(Note1), VREF, XIN
P70, P71
VO
Output voltage P00-P07, P10-P17, P20-P27, P30-P37, P40P47, P50-P57, P60-P67, P72-P77, P80-P87,
P90-P97, P100-P107, P110-P114, P120-P127,
P130-P13 7, P14 0-P14 6 , P15 0-P15 7(Note1) ,
Pd
Topr
VREF, XIN
P70, P71
Power dissipation
Operating ambient temperature
Tstg
Storage temperature
Note 1: Ports P11 to P15 exist in 144-pin version.
Note 2: Specify a product of -40 to 85°C to use it.
344
Topr=25°C
500
mW
-20 to 85/-40 to 85(Note 2) °C
-65 to 150
°C
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Electrical characteristics
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Table 1.32.2. Recommended operating conditions (referenced to VCC = 3.0V to 5.5V at Topr = – 20
to 85oC / – 40 to 85oC(Note3) unless otherwise specified)
Symbol
Standard
Parameter
VCC
Supply voltage(When VDC-ON)
AVCC
Supply voltage(When VDC-pass through)
Analog supply voltage
VSS
AVSS
Supply voltage
Analog supply voltage
VIH
"H" input voltage P20 -P27, P3 0-P3 7, P40-P4 7, P50 -P5 7, P60-P6 7, P7 2-
Unit
Min.
3.0
Typ.
5.0
Max.
5.5
3.0
3.3
VCC
3.6
0
0
V
V
V
V
V
0.8Vcc
Vcc
V
0.8Vcc
0.8Vcc
6.0
Vcc
V
V
0.5Vcc
Vcc
V
0
0.2Vcc
V
P00-P07, P10-P17
(during single-chip mode)
0
0.2Vcc
V
P00-P07, P10-P17
(during memory-expansion and microprocessor modes)
0
0.16Vcc
V
-10.0
mA
-5.0
mA
10.0
mA
5.0
mA
0
30
MHz
0
0
20
20
MHz
MHz
P77, P80-P87, P90-P97, P100-P107, P110-P114, P120P127, P130-P137, P140-P146, P150-P157(Note5), XIN,
____________
RESET, CNVss, BYTE
P70, P71
P00-P07, P10-P17
(during single-chip mode)
P00-P07, P10-P17
(during memory-expansion and microprocessor modes)
VIL
"L" input voltage P20 -P27, P3 0-P3 7, P40-P4 7, P50 -P5 7, P60-P6 7, P7 0P77, P80-P87, P90-P97, P100-P107, P110-P114, P120P127, P130-P137, P140-P146, P150-P157(Note5), XIN,
____________
RESET, CNVss, BYTE
IOH(peak) "H" peak output
current
P00 -P07, P1 0-P1 7, P20-P2 7, P30 -P3 7, P40-P4 7, P5 0P5 7, P60-P6 7, P70-P7 7, P80-P8 4, P86, P8 7, P90-P9 7,
P100-P107, P110-P114, P120-P127, P130-P137, P140P146, P150-P157(Note5)
IOH(avg)
"H" average
output current
P00 -P07, P1 0-P1 7, P20-P2 7, P30 -P3 7, P40-P4 7, P5 0P5 7, P60-P6 7, P70-P7 7, P80-P8 4, P86, P8 7, P90-P9 7,
P100-P107, P110-P114, P120-P127, P130-P137, P140P146, P150-P157(Note5)
IOL(peak) "L" peak output
current
P00 -P07, P1 0-P1 7, P20-P2 7, P30 -P3 7, P40-P4 7, P5 0P5 7, P60-P6 7, P70-P7 7, P80-P8 4, P86, P8 7, P90-P9 7,
P100-P107, P110-P114, P120-P127, P130-P137, P140P146, P150-P157(Note5)
IOL(avg)
"L" average
output current
f(XIN)
P00 -P07, P1 0-P1 7, P20-P2 7, P30 -P3 7, P40-P4 7, P5 0P5 7, P60-P6 7, P70-P7 7, P80-P8 4, P86, P8 7, P90-P9 7,
P100-P107, P110-P114, P120-P127, P130-P137, P140P146, P150-P157(Note5)
Main clock input frequency
VDC-ON
Vcc=4.2 to 5.5V
VDC-pass through
Vcc=3.0 to 4.2V
Vcc=3.0 to 3.6V
32.768
kHz
f(XCIN) Sub-clock oscillation frequency
Note 1: The mean output current is the mean value within 100ms.
Note 2: The total IOL (peak) for ports P0, P1, P2, P86, P87, P9, P10, P11, P14 and P15 must be 80mA max. The total
IOH (peak) for ports P0, P1, P2, P86, P87, P9, P10, P11, P14 and P15 must be -80mA max. The total IOL (peak)
for ports P3, P4, P5, P6, P7,P80 to P84, P12 and P13 must be 80mA max. The total IOH (peak) for ports P3, P4,
P5, P6, P72 to P77, P80 to P84, P12 and P13 must be -80mA max.
Note 3: Specify a product of -40 to 85°C to use it.
Note 4: The specification of VIH and VIL of P87 is not when using as XCIN but when using programmable input port.
Note 5: Port P11 to P15 exist in 144-pin version.
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Electrical characteristics (Vcc = 5V)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Table 1.32.3. Electrical characteristics (referenced to VCC=5V, VSS=0V at
Topr=25oC, f(XIN)=30MHZ unless otherwise specified)
Symbol
VOH
Parameter
"H" output voltage
Condition
P00-P07, P10-P1 7, P20-P27, P30-P37, P40-P47, IOH=-5mA
P50-P57, P60-P67, P70-P7 7, P80-P84, P8 6, P87,
VCC = 5V
Standard
Unit
Min. Typ. Max.
3.0
V
4.7
V
3.0
3.0
V
V
P9 0 -P9 7 , P10 0 -P10 7 , P11 0 -P11 4 , P12 0 -P12 7 ,
P130-P137, P140-P146, P150-P157(Note1)
VOH
"H" output voltage
P00-P07, P10-P1 7, P20-P27, P30-P37, P40-P47, IOH=-200µA
P50-P57, P60-P67, P70-P7 7, P80-P84, P8 6, P87,
P9 0 -P9 7 , P10 0 -P10 7 , P11 0 -P11 4 , P12 0 -P12 7 ,
P130-P137, P140-P146, P150-P157(Note1)
VOH
"H" output voltage
XOUT
VOL
"H" output voltage
"L" output voltage
XCOUT
No load applied
P00-P07, P10-P1 7, P20-P27, P30-P37, P40-P47, IOH=5mA
P50-P57, P60-P67, P70-P7 7, P80-P84, P8 6, P87,
P9 0 -P9 7 , P10 0 -P10 7 , P11 0 -P11 4 , P12 0 -P12 7 ,
VOL
"L" output voltage
HIGH POWER
LOW POWER
IOH=-1mA
IOH=-0.5mA
3.0
P130-P137, P140-P146, P150-P157(Note1)
P00-P07, P10-P1 7, P20-P27, P30-P37, P40-P47, IOH=200µA
P50-P57, P60-P67, P70-P7 7, P80-P84, P8 6, P87,
P9 0 -P9 7 , P10 0 -P10 7 , P11 0 -P11 4 , P12 0 -P12 7 ,
2.0
V
V
0.45
V
P130-P137, P140-P146, P150-P157(Note1)
VOL
"L" output voltage
"L" output voltage
VT+-VT- Hysteresis
XOUT
HIGH POWER
IOL=1mA
2.0
V
LOW POWER
IOL=0.5mA
No load applied
2.0
V
V
0.2
1.0
V
0.2
VI=5V
1.8
5.0
V
µA
VI=0V
-5.0
µA
167
kΩ
XCOUT
__________
_______
________
HOLD, RDY, TA0IN-TA4IN, TB0IN-TB5IN, INT0________
________
________
INT5, AD TRG , CTS0-CTS4, CLK0-CLK4,
_______
0
______ ______
TA0 OUT-TA4 OUT, NMI, KI0-KI3, RxD0-RxD4,
SCL0-SCL4, SDA0-SDA4
VT+-VT- Hysteresis
IIH
"H" input current
___________
RESET
P00-P07, P10-P17, P20-P27, P30-P37, P40-P47,
P50-P57, P60-P67, P72-P77, P80-P87, P90-P97,
P10 0 -P10 7 , P11 0 -P11 4 , P12 0 -P12 7 , P13 0 P137, P140-P146, P150-P157(Note1),
___________
XIN, RESET, CNVss, BYTE
IIL
"L" input current
P00-P07, P10-P17, P20-P27, P30-P37, P40-P47,
P50-P57, P60-P67, P72-P77, P80-P87, P90-P97,
P10 0 -P10 7 , P11 0 -P11 4 , P12 0 -P12 7 , P13 0 P137, P140-P146, P150-P157(Note1),
___________
XIN, RESET, CNVss, BYTE
RPULLUP Pull-up resistance P00-P07, P10-P17, P20-P27, P30-P37, P40-P47,
VI=0V
30
50
P50-P57, P60-P67, P72-P77, P80-P84, P86, P87,
P90-P9 7, P100-P10 7, P110-P11 4, P120-P12 7,
RfXIN
RfXCIN
VRAM
ICC
P130-P137, P140-P146, P150-P157(Note1)
Feedback resistance XIN
1.5
MΩ
Feedback resistance XCIN
10
RAM retention voltage VDC-ON
2.5
Measuring condition:
Power supply
f(XIN)=30MHz, square wave, no division
38
In sigle-chip mode, the out- f(XCIN)=32kHz, with WAIT instruction executed
current
470
put pins are open and other
0.4
when clock is stopped Topr=25oC
pins are Vss.
MΩ
V
Note 1: Port P11 to P15 exist in 144-pin version.
346
54
mA
µA
20
µA
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Electrical characteristics (Vcc = 5V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Table 1.32.4. A-D conversion characteristics (referenced to VCC = AVCC = VREF = 5V, Vss = AVSS =
0V at Topr = 25oC, f(XIN) = 30MHZ unless otherwise specified)
Standard
Symbol
Parameter
Measuring condition
Unit
Min. Typ. Max.
VREF = VCC
10 Bits
Resolution
INL
DNL
Integral nonlinearity error
AN0 to AN7
VREF =
ANEX0, ANEX1
VCC = 5V
External op-amp
connection mode
Differential nonlinearity error
Offset error
tCONV
tCONV
tSAMP
VREF
VIA
Ladder resistance
Conversion time(10bit)
Conversion time(8bit)
Sampling time
Reference voltage
Analog input voltage
LSB
±7
LSB
±1
LSB
LSB
±3
±3
Gain error
RLADDER
±3
VREF = VCC
10
40
LSB
kΩ
3.3
µs
2.8
µs
µs
0.3
2
VCC
V
0
VREF
V
Note: Divide the frequency if f(XIN) exceeds 10 MHz, and make ØAD equal to or lower than 10 MHz.
Table 1.32.5. D-A conversion characteristics (referenced to VCC = VREF = 5V, VSS = AVSS = 0V
at Topr = 25oC, f(XIN) = 30MHZ unless otherwise specified)
Symbol
tsu
RO
IVREF
Parameter
Resolution
Absolute accuracy
Setup time
Output resistance
Reference power supply input current
Measuring condition
Min.
4
(Note)
Standard
Typ. Max.
10
8
1.0
3
20
1.5
Unit
Bits
%
µs
kΩ
mA
Note: This applies when using one D-A converter, with the D-A register for the unused D-A converter set to
“0016”.
The A-D converter's ladder resistance is not included.
Also, when the Vref is unconnected at the A-D control register 1, IVREF is sent.
347
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Timing (Vcc = 5V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Timing requirements (referenced to VCC = 5V, VSS = 0V at Topr = 25oC unless otherwise specified)
Table 1.32.6. External clock input
Symbol
Parameter
External clock input cycle time
External clock input HIGH pulse width
External clock input LOW pulse width
External clock rise time
External clock fall time
tc
tw(H)
tw(L)
tr
tf
Standard
Min.
Max.
Unit
ns
ns
ns
ns
ns
33
13
13
5
5
Table 1.32.7. Memory expansion and microprocessor modes
Symbol
Parameter
Standard
Unit
Min. Max.
tac1(RD-DB)
tac1(AD-DB)
tac2(RD-DB)
tac2(AD-DB)
tac3(RD-DB)
tac3(AD-DB)
Data input access time (RD standard, no wait)
Data input access time (AD standard, CS standard, no wait)
Data input access time (RD standard, with wait)
Data input access time (AD standard, CS standard, with wait)
Data input access time (RD standard, when accessing multiplex bus area)
Data input access time (AD standard, CS standard, when accessing
(Note)
(Note)
(Note)
(Note)
(Note)
(Note)
ns
ns
ns
ns
ns
ns
multiplex bus area)
tac4(RAS-DB)
tac4(CAS-DB)
tac4(CAD-DB)
tsu(DB-BCLK)
tsu(RDY-BCLK )
tsu(HOLD-BCLK )
th(RD-DB)
th(CAS -DB)
th(BCLK -RDY)
th(BCLK-HOLD )
td(BCLK-HLDA )
(Note)
(Note)
Data input access time (RAS standard, DRAM access)
Data input access time (CAS standard, DRAM access)
Data input access time (CAD standard, DRAM access)
Data input setup time
RDY input setup time
HOLD input setup time
Data input hold time
(Note)
26
26
30
0
0
0
0
Data input hold time
RDY input hold time
HOLD input hold time
HLDA output delay time
25
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: Calculated according to the BCLK frequency as follows:
Note that inserting wait or using lower operation frequency f(BCLK) is needed when
calculated value is negative.
tac1(RD – DB) =
10 9
f(BCLK) X 2
– 35
[ns]
9
tac1(AD – DB) =
10
f(BCLK)
– 35
[ns]
tac2(RD – DB) =
10 9X m
f(BCLK) X 2
– 35
[ns] (m=3, 5 and 7 when 1 wait, 2 wait and 3 wait, respectively)
tac2(AD – DB) =
10 X n
f(BCLK)
– 35
[ns] (n=2, 3 and 4 when 1 wait, 2 wait and 3 wait, respectively)
9
9
tac3(RD – DB) =
10 X m
– 35
f(BCLK) X 2
tac3(AD – DB) =
10 X n
– 35
f(BCLK) X 2
[ns] (m=3 and 5 when 2 wait and 3 wait, respectively)
9
[ns] (n=5 and 7 when 2 wait and 3 wait, respectively)
9
tac4(RAS – DB) =
10 X m
f(BCLK) X 2
tac4(CAS – DB) =
10 X n
– 35
f(BCLK) X 2
– 35
[ns] (m=3 and 5 when 1 wait and 2 wait, respectively)
9
[ns] (n=1 and 3 when 1 wait and 2 wait, respectively)
9
tac4(CAD – DB) =
348
10 X l
f(BCLK)
– 35
[ns] (l=1 and 2 when 1 wait and 2 wait, respectively)
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Timing (Vcc = 5V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Timing requirements (referenced to VCC = 5V, VSS = 0V at Topr = 25oC unless otherwise specified)
Table 1.32.8. Timer A input (count input in event counter mode)
Symbol
Parameter
tc(TA)
TAiIN input cycle time
tw(TAH)
TAiIN input HIGH pulse width
tw(TAL)
TAiIN input LOW pulse width
Standard
Min.
Max.
100
40
40
Unit
ns
ns
ns
Table 1.32.9. Timer A input (gating input in timer mode)
tc(TA)
TAiIN input cycle time
Standard
Min.
Max.
400
tw(TAH)
tw(TAL)
TAiIN input HIGH pulse width
TAiIN input LOW pulse width
200
200
Symbol
Parameter
Table 1.32.10. Timer A input (external trigger input in one-shot timer mode)
Standard
Symbol
Parameter
Max.
Min.
tc(TA)
200
TAiIN input cycle time
tw(TAH)
tw(TAL)
TAiIN input HIGH pulse width
TAiIN input LOW pulse width
100
100
Unit
ns
ns
ns
Unit
ns
ns
ns
Table 1.32.11. Timer A input (external trigger input in pulse width modulation mode)
Standard
Symbol
Parameter
Unit
Min.
Max.
ns
tw(TAH)
100
TAiIN input HIGH pulse width
tw(TAL)
TAiIN input LOW pulse width
100
ns
Table 1.32.12. Timer A input (up/down input in event counter mode)
Symbol
tc(UP)
tw(UPH)
tw(UPL)
tsu(UP-TIN)
th(TIN-UP)
Parameter
TAiOUT input cycle time
TAiOUT input HIGH pulse width
TAiOUT input LOW pulse width
TAiOUT input setup time
TAiOUT input hold time
Standard
Min.
Max.
2000
1000
1000
400
400
Unit
ns
ns
ns
ns
ns
349
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Rev.B2 for proof reading
Timing (Vcc = 5V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Timing requirements (referenced to VCC = 5V, VSS = 0V at Topr = 25oC unless otherwise specified)
Table 1.32.13. Timer B input (count input in event counter mode)
Symbol
tc(TB)
tw(TBH)
tw(TBL)
tc(TB)
tw(TBH)
tw(TBL)
Parameter
TBiIN input cycle time (counted on one edge)
TBiIN input HIGH pulse width (counted on one edge)
TBiIN input LOW pulse width (counted on one edge)
TBiIN input cycle time (counted on both edges)
TBiIN input HIGH pulse width (counted on both edges)
TBiIN input LOW pulse width (counted on both edges)
Standard
Min.
Max.
100
40
40
200
80
80
Unit
ns
ns
ns
ns
ns
ns
Table 1.28.14. Timer B input (pulse period measurement mode)
Symbol
tc(TB)
tw(TBH)
tw(TBL)
Parameter
TBiIN input cycle time
TBiIN input HIGH pulse width
TBiIN input LOW pulse width
Standard
Min.
Max.
400
200
200
Unit
ns
ns
ns
Table 1.32.15. Timer B input (pulse width measurement mode)
Symbol
tc(TB)
tw(TBH)
tw(TBL)
Parameter
TBiIN input cycle time
TBiIN input HIGH pulse width
TBiIN input LOW pulse width
Standard
Max.
Min.
400
200
200
Unit
ns
ns
ns
Table 1.32.16. A-D trigger input
Symbol
tc(AD)
tw(ADL)
Parameter
ADTRG input cycle time (trigger able minimum)
ADTRG input LOW pulse width
Standard
Max.
Min.
1000
125
Unit
ns
ns
Table 1.32.17. Serial I/O
Symbol
tc(CK)
tw(CKH)
tw(CKL)
td(C-Q)
th(C-Q)
tsu(D-C)
th(C-D)
Parameter
CLKi input cycle time
CLKi input HIGH pulse width
CLKi input LOW pulse width
TxDi output delay time
TxDi hold time
RxDi input setup time
RxDi input hold time
Standard
Min.
Max.
200
100
100
80
0
30
90
Unit
ns
ns
ns
ns
ns
ns
ns
_______
Table 1.32.18. External interrupt INTi inputs
Symbol
tw(INH)
tw(INL)
350
Parameter
INTi input HIGH pulse width
INTi input LOW pulse width
Standard
Min.
250
250
Max.
Unit
ns
ns
nt
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
Timing (Vcc = 5V)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Switching characteristics (referenced to VCC = 5V, VSS = 0V at Topr = 25oC, CM15 = “1” unless
otherwise specified)
Table 1.32.19. Memory expansion mode and microprocessor mode (no wait)
Measuring condition
Symbol
Parameter
td(BCLK-AD)
th(BCLK-AD)
th(RD-AD)
th(WR-AD)
td(BCLK-CS)
th(BCLK-CS)
th(RD-CS)
th(WR-CS)
td(BCLK-ALE)
th(BCLK-ALE)
td(BCLK-RD)
th(BCLK-RD)
td(BCLK-WR)
th(BCLK-WR)
td(DB-WR)
th(WR-DB)
tw(WR)
Address output delay time
Address output hold time (BCLK standard)
Address output hold time (RD standard)
Address output hold time (WR standard)
Chip select output delay time
Chip select output hold time (BCLK standard)
Chip select output hold time (RD standard)
Chip select output hold time (WR standard)
ALE signal output delay time
ALE signal output hold time
RD signal output delay time
RD signal output hold time
WR signal output delay time
WR signal output hold time
Data output delay time (WR standard)
Data output hold time (WR standard)
WR signal width
Figure 1.32.1
Standard
Min.
Max.
18
-3
0
(Note)
18
-3
0
(Note)
18
–2
18
-5
18
-3
(Note)
(Note)
(Note)
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: Calculated according to the BCLK frequency as follows:
td(DB – WR) =
10 9
– 20
f(BCLK)
[ns]
9
th(WR – DB) =
10
f(BCLK) X 2
– 10
[ns]
9
th(WR – AD) =
10
f(BCLK) X 2
– 10
[ns]
9
th(WR – CS) =
10
f(BCLK) X 2
– 10
[ns]
9
tw(WR) =
10
f(BCLK) X 2
– 15
[ns]
351
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
Timing (Vcc = 5V)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Switching characteristics (referenced to VCC = 5V, VSS = 0V at Topr = 25oC unless otherwise
specified)
Table 1.32.20. Memory expansion mode and microprocessor mode
(with wait, accessing external memory)
Symbol
td(BCLK-AD)
th(BCLK-AD)
th(RD-AD)
th(WR-AD)
td(BCLK-CS)
th(BCLK-CS)
th(RD-CS)
th(WR-CS)
td(BCLK-ALE)
th(BCLK-ALE)
td(BCLK-RD)
th(BCLK-RD)
td(BCLK-WR)
th(BCLK-WR)
td(DB-WR)
th(WR-DB)
tw(WR)
Measuring condition
Parameter
Address output delay time
Address output hold time (BCLK standard)
Address output hold time (RD standard)
Address output hold time (WR standard)
Chip select output delay time
Chip select output hold time (BCLK standard)
Chip select output hold time (RD standard)
Chip select output hold time (WR standard)
ALE signal output delay time
ALE signal output hold time
RD signal output delay time
RD signal output hold time
WR signal output delay time
WR signal output hold time
Data output delay time (WR standard)
Data output hold time (WR standard)
WR signal width
Figure 1.32.1
Standard
Min.
Max.
18
–3
0
(Note)
18
–3
0
(Note)
18
–2
18
–5
18
–3
(Note)
Unit
(Note)
(Note)
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: Calculated according to the BCLK frequency as follows:
td(DB – WR) =
10 9 X n
f(BCLK)
– 20
[ns] (n=1, 2 and 3 when 1 wait, 2 wait and 3 wait, respectively)
9
th(WR – DB) =
10
f(BCLK) X 2
– 10
[ns]
9
th(WR – AD) =
10
f(BCLK) X 2
– 10
[ns]
9
th(WR – CS) =
tw( WR) =
352
10
f(BCLK) X 2
10 9 X n
– 15
f(BCLK) X 2
– 10
[ns]
[ns] (n=1, 3 and 5 when 1 wait, 2 wait and 3 wait, respectively)
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Rev.B2 for proof reading
Mitsubishi Microcomputers
M32C/83 group
Timing (Vcc = 5V)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Switching characteristics (referenced to VCC = 5V, VSS = 0V at Topr = 25oC unless otherwise
specified)
Table 1.32.21. Memory expansion mode and microprocessor mode
(with wait, accessing external memory, multiplex bus area selected)
Symbol
Measuring condition
Parameter
td(BCLK-AD)
th(BCLK-AD)
th(RD-AD)
th(WR-AD)
td(BCLK-CS)
th(BCLK-CS)
th(RD-CS)
th(WR-CS)
td(BCLK-RD)
th(BCLK-RD)
td(BCLK-WR)
th(BCLK-WR)
td(DB-WR)
th(WR-DB)
Address output delay time
Address output hold time (BCLK standard)
Address output hold time (RD standard)
Address output hold time (WR standard)
Chip select output delay time
Chip select output hold time (BCLK standard)
Chip select output hold time (RD standard)
Chip select output hold time (WR standard)
RD signal output delay time
RD signal output hold time
WR signal output delay time
WR signal output hold time
Data output delay time (WR standard)
Data output hold time (WR standard)
td(BCLK-ALE)
th(BCLK-ALE)
td(AD-ALE)
th(ALE-AD)
ALE signal output delay time (BCLK standard)
ALE signal output hold time (BCLK standard)
ALE signal output delay time (address standard)
ALE signal output hold time (address standard)
tdz(RD-AD)
Address output flowting start time
Figure 1.32.1
Standard
Min.
Max.
18
-3
(Note)
(Note)
18
-3
(Note)
(Note)
18
-5
18
-3
(Note)
(Note)
18
–2
(Note)
(Note)
8
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: Calculated according to the BCLK frequency as follows:
th(RD – AD) =
10 9
f(BCLK) X 2
– 10
th(WR – AD) =
10 9
f(BCLK) X 2
– 10
th(RD – CS) =
10 9
f(BCLK) X 2
– 10
th(WR – CS) =
10 9
f(BCLK) X 2
– 10
td(DB – WR) =
10 X m
– 25
f(BCLK) X 2
[ns]
[ns]
[ns]
[ns]
9
th(WR – DB) =
td(AD – ALE) =
th(ALE – AD) =
10
f(BCLK) X 2
10
– 10
[ns]
9
f(BCLK) X 2
10
[ns] (m=3 and 5 when 2 wait and 3 wait, respectively)
9
– 20
[ns]
9
f(BCLK) X 2
– 10
[ns]
353
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Rev.B2 for proof reading
Timing (Vcc = 5V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 5V
Switching characteristics (referenced to VCC = 5V, VSS = 0V at Topr = 25oC unless otherwise
specified)
Table 1.32.22. Memory expansion mode and microprocessor mode
(with wait, accessing external memory, DRAM area selected)
Measuring
condition
Parameter
Symbol
td(BCLK-RAD)
th(BCLK-RAD)
td(BCLK-CAD)
th(BCLK-CAD)
th(RAS-RAD)
td(BCLK-RAS)
th(BCLK-RAS)
tRP
Row address output delay time
Row address output hold time (BCLK standard)
String address output delay time
String address output hold time (BCLK standard)
Row address output hold time after RAS output
td(BCLK-CAS)
th(BCLK-CAS)
td(BCLK-DW)
th(BCLK-DW)
tsu(DB-CAS)
th(BCLK-DB)
tsu(CAS-RAS)
CAS output delay time (BCLK standard)
CAS output hold time (BCLK standard)
DW output delay time (BCLK standard)
DW output hold time (BCLK standard)
CAS output setup time after DB output
DB signal output hold time (BCLK standard)
CAS output setup time before RAS output (refresh)
RAS output delay time (BCLK standard)
RAS output hold time (BCLK standard)
RAS "H" hold time
Note: Calculated according to the BCLK frequency as follows:
th(RAS – RAD) =
10 9
f(BCLK) X 2
tRP =
10 9
f(BCLK) X 2
tsu(DB – CAS) =
10 9
f(BCLK)
– 13
[ns]
X 3 – 20 [ns]
– 20
[ns]
9
tsu(CAS – RAS) =
354
10
f(BCLK) X 2
– 13
[ns]
Figure 1.32.1
Standard
Min.
Max.
18
-3
18
-3
(Note)
18
-3
(Note)
18
-3
18
-5
(Note)
-7
(Note)
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
nt
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Mitsubishi Microcomputers
M32C/83 group
Timing (Vcc = 5V)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
P0
P1
P2
P3
P4
P5
P6
P7
30pF
P8
P9
P10
P11
P12
P13
P14
P15
Figure 1.32.1. Port P0 to P15 measurement circuit
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
Vcc=5V
Memory Expansion Mode and Microprocessor Mode (without wait)
Read Timing
BCLK
td(BCLK-ALE)
18ns.max
th(BCLK-ALE)
-2ns.min
ALE
td(BCLK-CS)
18ns.max
th(BCLK-CS)
*1
-3ns.min
CSi
th(RD-CS)
tcyc
0ns.min
td(BCLK-AD)
th(BCLK-AD)
18ns.max*1
-3ns.min
ADi
BHE
td(BCLK-RD)
18ns.max
th(RD-AD)
0ns.min
tac1(RD-DB)*2
th(BCLK-RD)
RD
-5ns.min
tac1(AD-DB)*2
DB
Hi-Z
tsu(DB-BCLK)
th(RD-DB)
26ns.min*1
0ns.min
*1:It is a guarantee value with being alone. 35ns.max garantees as td(BCLK-AD)+tsu(DB-BCLK).
*2:It depends on operation frequency.
tac1(RD-DB)=(tcyc/2-35)ns.max
tac1(AD-DB)=(tcyc-35)ns.max
Write Timing ( Written by 2 cycles in selecting no wait)
BCLK
18ns.max
td(BCLK-ALE)
th(BCLK-ALE)
-2ns.min
ALE
th(BCLK-CS)
td(BCLK-CS)
-3ns.min
18ns.max
CSi
th(WR-CS)*3
tcyc
td(BCLK-AD)
ADi
BHE
th(BCLK-AD)
18ns.max
-3ns.min
td(BCLK-WR)
18ns.max
tw(WR)*3
WR,WRL,
WRH
th(WR-AD)*3
th(BCLK-WR)
-3ns.min
td(DB-WR)*3
th(WR-DB)*3
DBi
*3:It depends on operation frequency.
td(DB-WR)=(tcyc-20)ns.min
th(WR-DB)=(tcyc/2-10)ns.min
th(WR-AD)=(tcyc/2-10)ns.min
th(WR-CS)=(tcyc/2-10)ns.min
tw(WR)=(tcyc/2-15)ns.min
Figure 1.32.2. VCC=5V timing diagram (1)
356
Measuring conditions
• VCC=5V±10%
• Input timing voltage :Determined with VIH=2.5V, VIL=0.8V
• Output timing voltage :Determined with VOH=2.0V, VOL=0.8V
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
Vcc=5V
Memory Expansion Mode and Microprocessor Mode (with wait)
Read Timing
BCLK
18ns.max
td(BCLK-ALE) th(BCLK-ALE)
-2ns.min
ALE
th(BCLK-CS)
td(BCLK-CS)
-3ns.min
18ns.max*1
CSi
th(RD-CS)
tcyc
0ns.min
td(BCLK-AD)
th(BCLK-AD)
18ns.max*1
-3ns.min
td(BCLK-RD)
18ns.max
th(RD-AD)
0ns.min
ADi
BHE
RD
th(BCLK-RD)
tac2(RD-DB)*2
-5ns.min
tac2(AD-DB)*2
DB
Hi-Z
tsu(DB-BCLK)
26ns.min*1
th(RD-DB)
0ns.min
*1:It is a guarantee value with being alone. 35ns.max garantees as td(BCLK-AD)+tsu(DB-BCLK).
*2:It depends on operation frequency.
tac2(RD-DB)=(tcyc/2 x m-35)ns.max (m=3, 5 and 7 when 1 wait, 2 wait and 3 wait, respectively.)
tac2(AD-DB)=(tcyc x n-35)ns.max (n=2, 3 and 4 when 1 wait, 2 wait and 3 wait, respectively.)
Write Timing ( Written by 2 cycles in selecting no wait)
BCLK
18ns.max
td(BCLK-ALE)
th(BCLK-ALE)
-2ns.min
ALE
th(BCLK-CS)
td(BCLK-CS)
-3ns.min
18ns.max
CSi
tcyc
th(WR-CS)*3
td(BCLK-AD)
th(BCLK-AD)
18ns.max
ADi
BHE
-3ns.min
td(BCLK-WR)
WR,WRL,
WRH
18ns.max
tw(WR)*3
th(WR-AD)*3
th(BCLK-WR)
-3ns.min
td(DB-WR)*3
th(WR-DB)*3
DBi
*3:It depends on operation frequency.
Measuring conditions
td(DB-WR)=(tcyc x n-20)ns.min
• VCC=5V±10%
(n=1, 2 and 3 when 1 wait, 2 wait and 3 wait, respectively.)
• Input timing voltage
th(WR-DB)=(tcyc/2-10)ns.min
:Determined with VIH=2.5V, VIL=0.8V
th(WR-AD)=(tcyc/2-10)ns.min
• Output timing voltage
th(WR-CS)=(tcyc/2-10)ns.min
:Determined with VOH=2.0V, VOL=0.8V
tw(WR)=(tcyc/2 x n-15)ns.min
(n=1, 3 and 5 when 1 wait, 2 wait and 3 wait, respectively.)
Figure 1.32.3. VCC=5V timing diagram (2)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
Vcc=5V
Memory Expansion Mode and Microprocessor Mode
(When accessing external memory area with wait, and select multiplexed bus))
Read Timing
BCLK
18ns.max
th(BCLK-ALE)
td(BCLK-ALE)
-2ns.min
ALE
th(BCLK-CS)
tcyc
td(BCLK-CS)
-3ns.min
18ns.max
th(RD-CS)*1
CSi
td(AD-ALE)*1 th(ALE-AD)*1
ADi
/DBi
Address
Data input
tdz(RD-AD)
td(BCLK-AD)
ADi
BHE
tsu(DB-BCLK)
tac3(AD-DB)*1
td(BCLK-RD)
th(BCLK-RD)
18ns.max
0ns.min
26ns.min
tac3(RD-DB)*1
18ns.max
Address
th(RD-DB)
8ns.max
th(BCLK-AD)
-3ns.min
th(RD-AD)*1
-5ns.min
RD
*1:It depends on operation frequency.
td(AD-ALE)=(tcyc/2-20)ns.min
th(ALE-AD)=(tcyc/2-10)ns.min, th(RD-AD)=(tcyc/2-10)ns.min, th(RD-CS)=(tcyc/2-10)ns.min
tac3(RD-DB)=(tcyc/2 x m-35)ns.max (m=3 and 5 when 2 wait and 3 wait, respectively.)
tac3(AD-DB)=(tcyc/2 x n-35)ns.max (n=5 and 7 when 2 wait and 3 wait, respectively.)
Write Timing (Written by 2 cycles in selecting no wait)
BCLK
18ns.max
th(BCLK-ALE)
td(BCLK-ALE)
-2ns.min
ALE
CSi
th(BCLK-CS)
tcyc
td(BCLK-CS)
th(WR-CS)*2
18ns.max
-3ns.min
td(AD-ALE)*2 th(ALE-AD)*2
ADi
/DBi
18ns.max
*2:It depends on operation frequency.
td(AD-ALE)=(tcyc/2-20)ns.min
th(ALE-AD)=(tcyc/2-10)ns.min, th(WR-AD)=(tcyc/2-10)ns.min
th(WR-CS)=(tcyc/2-10)ns.min, th(WR-DB)=(tcyc/2-10)ns.min
td(DB-WR)=(tcyc/2 x m-25)ns.min
(m=3 and 5 when 2 wait and 3 wait, respectively.)
Figure 1.32.4. VCC=5V timing diagram (3)
358
th(BCLK-AD)
-3ns.min
18ns.max
td(BCLK-WR)
WR,WRL,
WRH
th(WR-DB)*2
td(DB-WR)*2
td(BCLK-AD)
ADi
BHE
Address
Data output
Address
th(BCLK-WR)
th(WR-AD)*2
-3ns.min
Measuring conditions
• VCC=5V±10%
• Input timing voltage
:Determined with VIH=2.5V, VIL=0.8V
• Output timing voltage
:Determined with VOH=2.0V, VOL=0.8V
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
Memory Expansion Mode and Microprocessor Mode
Vcc=5V
(When accessing DRAM area)
Read Timing
BCLK
tcyc
td(BCLK-RAD) th(BCLK-RAD)
18ns.max -3ns.min
MAi
td(BCLK-CAD)
th(BCLK-CAD)
18ns.max*1
-3ns.min
String address
Row address
th(RAS-RAD)*2
tRP*2
RAS
td(BCLK-RAS)
18ns.max*1
th(BCLK-RAS)
td(BCLK-CAS)
-3ns.min
18ns.max*1
CASL
CASH
th(BCLK-CAS)
-3ns.min
DW
tac4(CAS-DB)*2
tac4(CAD-DB)*2
tac4(RAS-DB)*2
DB
Hi-Z
tsu(DB-BCLK)
26ns.min*1
th(CAS-DB)
0ns.min
*1:It is a guarantee value with being alone. 35ns.max garantees as follows:
td(BCLK-RAS) + tsu(DB-BCLK)
td(BCLK-CAS) + tsu(DB-BCLK)
td(BCLK-CAD) + tsu(DB-BCLK)
*2:It depends on operation frequency.
tac4(RAS-DB)=(tcyc/2 x m-35)ns.max (m=3 and 5 when 1 wait and 2 wait, respectively.)
tac4(CAS-DB)=(tcyc/2 x n-35)ns.max (n=1 and 3 when 1 wait and 2 wait, respectively.)
tac4(CAD-DB)=(tcyc x l-35)ns.max (l=1 and 2 when 1 wait and 2 wait, respectively.)
th(RAS-RAD)=(tcyc/2-13)ns.min
tRP=(tcyc/2 x 3-20)ns.min
Measuring conditions
• VCC=5V±10%
• Input timing voltage
:Determined with VIH=2.5V, VIL=0.8V
• Output timing voltage
:Determined with VOH=2.0V, VOL=0.8V
Figure 1.32.5. VCC=5V timing diagram (4)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
Memory Expansion Mode and Microprocessor Mode
Vcc=5V
(When accessing DRAM area)
Write Timing
BCLK
tcyc
td(BCLK-RAD)
18ns.max
MAi
th(BCLK-RAD)
-3ns.min
td(BCLK-CAD)
th(BCLK-CAD)
18ns.max
-3ns.min
String address
Row address
th(RAS-RAD)*1
tRP*1
RAS
td(BCLK-RAS)
18ns.max
td(BCLK-CAS)
18ns.max
CASL
CASH
th(BCLK-RAS)
-3ns.min
th(BCLK-CAS)
td(BCLK-DW)
-3ns.min
18ns.max
DW
th(BCLK-DW)
tsu(DB-CAS)*1
DB
-5ns.min
Hi-Z
th(BCLK-DB)
-7ns.min
*1:It depends on operation frequency.
th(RAS-RAD)=(tcyc/2-13)ns.min
tRP=(tcyc/2 x 3-20)ns.min
tsu(DB-CAS)=(tcyc-20)ns.min
Measuring conditions
• VCC=5V±10%
• Input timing voltage
:Determined with VIH=2.5V, VIL=0.8V
• Output timing voltage
:Determined with VOH=2.0V, VOL=0.8V
Figure 1.32.6. VCC=5V timing diagram (5)
360
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
Memory expansion Mode and Microprocessor Mode
Refresh Timing (CAS before RAS refresh)
Vcc=5V
BCLK
td(BCLK-RAS)
tcyc
18ns.max
RAS
th(BCLK-RAS)
tsu(CAS-RAS)*1
CASL
CASH
-3ns.min
td(BCLK-CAS)
th(BCLK-CAS)
-3ns.min
18ns.max
DW
*1:It depends on operation frequency.
tsu(CAS-RAS)=(tcyc/2-13)ns.min
Refresh Timing (Self-refresh)
BCLK
td(BCLK-RAS)
tcyc
18ns.max
RAS
th(BCLK-RAS)
tsu(CAS-RAS)*1
CASL
CASH
td(BCLK-CAS)
18ns.max
-3ns.min
th(BCLK-CAS)
-3ns.min
DW
*1:It depends on operation frequency.
tsu(CAS-RAS)=(tcyc/2-13)ns.min
Measuring conditions
• VCC=5V±10%
• Input timing voltage
:Determined with VIH=2.5V, VIL=0.8V
• Output timing voltage
:Determined with VOH=2.0V, VOL=0.8V
Figure 1.32.7. VCC=5V timing diagram (6)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
tc(TA)
tw(TAH)
TAiIN input
tw(TAL)
tc(UP)
tw(UPH)
TAiOUT input
tw(UPL)
TAiOUT input
(Up/down input)
During event counter mode
TAiIN input
(When count on falling
edge is selected)
th(TIN–UP)
tsu(UP–TIN)
TAiIN input
(When count on rising
edge is selected)
tc(TB)
tw(TBH)
TBiIN input
tw(TBL)
tc(AD)
tw(ADL)
ADTRG input
tc(CK)
tw(CKH)
CLKi
tw(CKL)
th(C–Q)
TxDi
td(C–Q)
tsu(D–C)
RxDi
tw(INL)
INTi input
Figure 1.32.8. VCC=5V timing diagram (7)
362
tw(INH)
th(C–D)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 5V)
Memory Expansion Mode and Microprocessor Mode
(Valid only with wait)
BCLK
RD
(Separate bus)
WR, WRL, WRH
(Separate bus)
RD
(Multiplexed bus)
WR, WRL, WRH
(Multiplexed bus)
RDY input
th(BCLK–RDY)
tsu(RDY–BCLK)
(Valid with or without wait)
BCLK
tsu(HOLD–BCLK)
th(BCLK–HOLD)
HOLD input
HLDA output
td(BCLK–HLDA)
P0, P1, P2,
P3, P4,
P50 to P52
td(BCLK–HLDA)
Hi–Z
Note: Regardless of the level of the BYTE pin input and the setting of the port P40 to
P43 function select bit (PM06) of the processor mode register 0, all ports above
become the high-impedance state.
Measuring conditions :
• VCC=5V±10%
• Input timing voltage : Determined with VIH=4.0V, VIL=1.0V
• Output timing voltage : Determined with VOH=2.5V, VOL=2.5V
Figure 1.32.9. VCC=5V timing diagram (8)
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Electrical characteristics (Vcc = 3V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Electrical characteristics (Vcc = 3V)
VCC = 3V
Table 1.32.23. Electrical characteristics (referenced to VCC=3.3V, VSS=0V at
Topr=25oC, f(XIN)=20MHZ unless otherwise specified)
Symbol
VOH
Parameter
Condition
"H" output voltage P00-P07, P10-P17, P20-P27, P30-P37, P40-P47, IOH=-1mA
Standard
Unit
Min. Typ. Max.
2.7
V
P50-P57, P60-P67, P70-P77, P80-P84, P86, P87,
P9 0-P9 7, P10 0-P10 7, P110 -P114 , P120-P12 7,
VOH
P130-P137, P140-P146, P150-P157(Note1)
"H" output voltage XOUT
HIGH POWER
LOW POWER
"H" output voltage XCOUT
VOL
VOL
2.7
V
2.7
IOH=-50µA
No load applied
IOH=-0.1mA
V
V
3.0
"L" output voltage P00-P07, P10-P17, P20-P27, P30-P37, P40-P47, IOL=1mA
P50-P57, P60-P67, P70-P77, P80-P84, P86, P87,
0.5
P9 0-P9 7, P10 0-P10 7, P110 -P114 , P120-P12 7,
P130-P137, P140-P146, P150-P157(Note1)
"L" output voltage XOUT
HIGH POWER
IOL=0.1mA
LOW POWER
IOL=50µA
"L" output voltage XCOUT
No load applied
__________ _______
________
VT+-VT- Hysteresis
0.2
HOLD, RDY, TA0IN-TA4IN, TB0IN-TB5IN, INT0________
________
________
INT5, AD TRG , CTS0-CTS4, CLK0-CLK4,
_______
0.5
0.5
V
V
1.0
V
V
1.8
V
4.0
µA
-4.0
µA
120 500
kΩ
3.0
20.0
MΩ
MΩ
0
______ ______
TA0 OUT-TA4 OUT, NMI, KI0-KI3, RxD0-RxD4,
SCL0-SCL4, SDA0-SDA4
VT+-VT- Hysteresis
IIH
___________
RESET
"H" input current P00-P07, P10-P17, P20-P27, P30-P37, P40-P47, VI=3V
0.2
P50-P57, P60-P67, P72-P77, P80-P87, P90-P97,
P100-P107, P110-P114, P120-P127, P130-P137,
P140-P146, P150-P157(Note1),
___________
XIN, RESET, CNVss, BYTE
IIL
"L" input current
P00-P07, P10-P17, P20-P27, P30-P37, P40-P47, VI=0V
P50-P57, P60-P67, P72-P77, P80-P87, P90-P97,
P100-P107, P110-P114, P120-P127, P130-P137,
P140-P146, P150-P157(Note1),
___________
XIN, RESET, CNVss, BYTE
RPULLUP Pull-up resistance P00-P07, P10-P17, P20-P27, P30-P37, P40-P47, VI=0V
66
P50-P57, P60-P67, P72-P77, P80-P84, P86, P87,
P90-P97, P100-P107, P110Å`P114, P120-P127,
RfXIN
RfXCIN
VRAM
ICC
P130-P137, P140-P146, P150-P157(Note1)
Feedback resistance XIN
Feedback resistance XCIN
RAM retention voltage VDC-ON
VDC-pass through
Measuring condition:
Power supply
In sigle-chip mode,
current
the output pins are
open and other pins
are Vss.
2.5
2.0
f(XIN)=20MHz, square wave, no division
f(XCIN)=32kHz, with WAIT, VDC-pass through
26
5.0
f(XCIN)=32kHz, with WAIT, VDC-ON
when clock is stopped Topr=25oC
340
0.4
Note 1: Port P11 to P15 exist in 144-pin version.
364
V
V
38
20
mA
µA
µA
µA
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Electrical characteristics (Vcc = 3V)
VCC = 3V
Table 1.32.24. A-D conversion characteristics (referenced to VCC = AVCC = VREF = 3V, VSS = AVSS =
0V at Topr = 25oC, f(XIN) = 20MHZ unless otherwise specified)
Standard
Symbol
Parameter
Measuring condition
Unit
Min. Typ. Max
VREF = VCC
10
Resolution
Bits
LSB
Integral nonlinearity error No S&H function(8-bit)
±2
ISL
Differential nonlinearity error No S&H function(8-bit)
±1
LSB
DSL
LSB
No S&H function(8-bit)
±2
Offset error
±2
LSB
No S&H function(8-bit)
Gain error
VREF = VCC
RLADDER Ladder resistance
40
10
kΩ
tCONV
Conversion time(8bit)
9.8
µs
Reference voltage
VREF
V
2.7
VCC
Analog input voltage
0
VREF
V
VIA
S&H: Sample and hold
Note: Divide the frequency if f(XIN) exceeds 10 MHz, and make ØAD equal to or lower than 10 MHz.
Table 1.32.25. D-A conversion characteristics (referenced to VCC = VREF = 3V, VSS = AVSS = 0V,
at Topr = 25oC, f(XIN) = 20MHZ unless otherwise specified)
Standard
Symbol
Parameter
Measuring condition
Min. Typ. Max Unit
tsu
RO
IVREF
Resolution
Absolute accuracy
Setup time
Output resistance
Reference power supply input current
4
(Note)
10
8
1.0
3
20
1.0
Bits
%
µs
kΩ
mA
Note :This applies when using one D-A converter, with the D-A register for the unused D-A converter
set to “0016”. The A-D converter's ladder resistance is not included.
Also, the Vref is unconnected at the A-D control register 1, IVREF is sent.
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Timing (Vcc = 3V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 3V
Timing requirements (referenced to VCC = 3V, VSS = 0V at Topr = 25oC unless otherwise specified)
Table 1.32.26. External clock input
Symbol
Parameter
External clock input cycle time
External clock input HIGH pulse width
External clock input LOW pulse width
External clock rise time
External clock fall time
tc
tw(H)
tw(L)
tr
tf
Standard
Min.
Max.
Unit
ns
ns
ns
ns
ns
50
22
22
5
5
Table 1.32.27. Memory expansion and microprocessor modes
Symbol
Parameter
Standard Unit
Min. Max.
tac1(RD-DB)
tac1(AD-DB)
tac2(RD-DB)
tac2(AD-DB)
tac3(RD-DB)
tac3(AD-DB)
Data input access time (RD standard, no wait)
Data input access time (AD standard, CS standard, no wait)
Data input access time (RD standard, with wait)
Data input access time (AD standard, CS standard, with wait)
Data input access time (RD standard, when accessing multiplex bus area)
Data input access time (AD standard, CS standard, when accessing
(Note)
(Note)
(Note)
(Note)
(Note)
(Note)
ns
ns
ns
ns
ns
ns
multiplex bus area)
tac4(RAS-DB)
tac4(CAS-DB)
tac4(CAD-DB)
tsu(DB-BCLK)
tsu(RDY-BCLK )
tsu(HOLD-BCLK )
th(RD-DB)
th(CAS-DB)
th(BCLK -RDY)
th(BCLK-HOLD )
td(BCLK-HLDA )
Data input access time (RAS standard, DRAM access)
Data input access time (CAS standard, DRAM access)
Data input access time (CAD standard, DRAM access)
Data input setup time
RDY input setup time
HOLD input setup time
Data input hold time
Data input hold time
RDY input hold time
HOLD input hold time
HLDA output delay time
(Note)
(Note)
(Note)
30
40
60
0
0
0
0
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
25
ns
Note: Calculated according to the BCLK frequency as follows:
Note that inserting wait or using lower operation frequency f(BCLK) is needed when
calculated value is negative.
tac1(RD – DB) =
tac1(AD – DB) =
10
9
f(BCLK) X 2
10 9
f(BCLK)
– 35
[ns]
– 35
[ns]
tac2(RD – DB) =
10 9X m
f(BCLK) X 2
– 35
[ns] (m=3, 5 and 7 when 1 wait, 2 wait and 3 wait, respectively)
tac2(AD – DB) =
10 9 X n
f(BCLK)
– 35
[ns] (n=2, 3 and 4 when 1 wait, 2 wait and 3 wait, respectively)
tac3(RD – DB) =
10 9 X m
– 35
f(BCLK) X 2
tac3(AD – DB) =
10 X n
– 35
f(BCLK) X 2
[ns] (m=3 and 5 when 2 wait and 3 wait, respectively)
9
[ns] (n=5 and 7 when 2 wait and 3 wait, respectively)
9
tac4(RAS – DB) =
10 X m
f(BCLK) X 2
tac4(CAS – DB) =
10 X n
– 35
f(BCLK) X 2
– 35
[ns] (m=3 and 5 when 1 wait and 2 wait, respectively)
9
[ns] (n=1 and 3 when 1 wait and 2 wait, respectively)
9
tac4(CAD – DB) =
366
10 X l
f(BCLK)
– 35
[ns] (l=1 and 2 when 1 wait and 2 wait, respectively)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
VCC = 3V
Timing requirements (referenced to VCC = 3V, VSS = 0V at Topr = 25oC unless otherwise specified)
Table 1.32.28. Timer A input (counter input in event counter mode)
Symbol
Parameter
Standard
Min.
Max.
100
Unit
tc(TA)
TAiIN input cycle time
tw(TAH)
TAiIN input HIGH pulse width
40
ns
ns
tw(TAL)
TAiIN input LOW pulse width
40
ns
Table 1.32.29. Timer A input (gating input in timer mode)
Symbol
Parameter
Standard
Min.
Max.
Unit
tc(TA)
TAiIN input cycle time
400
ns
tw(TAH)
TAiIN input HIGH pulse width
200
ns
tw(TAL)
TAiIN input LOW pulse width
200
ns
Table 1.32.30. Timer A input (external trigger input in one-shot timer mode)
Symbol
Parameter
Standard
Min.
Max.
Unit
tc(TA)
TAiIN input cycle time
200
ns
tw(TAH)
TAiIN input HIGH pulse width
100
ns
tw(TAL)
TAiIN input LOW pulse width
100
ns
Table 1.32.31. Timer A input (external trigger input in pulse width modulation mode)
Symbol
Parameter
Standard
Min.
Max.
Unit
tw(TAH)
TAiIN input HIGH pulse width
100
ns
tw(TAL)
TAiIN input LOW pulse width
100
ns
Table 1.32.32. Timer A input (up/down input in event counter mode)
tc(UP)
TAiOUT input cycle time
Standard
Min.
Max.
2000
tw(UPH)
TAiOUT input HIGH pulse width
1000
tw(UPL)
TAiOUT input LOW pulse width
1000
ns
tsu(UP-TIN)
TAiOUT input setup time
400
ns
th(TIN-UP)
TAiOUT input hold time
400
ns
Symbol
Parameter
Unit
ns
ns
367
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Timing (Vcc = 3V)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 3V
Timing requirements (referenced to VCC = 3V, VSS = 0V at Topr = 25oC unless otherwise specified)
Table 1.32.33. Timer B input (counter input in event counter mode)
Symbol
Parameter
Standard
Min.
Max.
Unit
tc(TB)
TBiIN input cycle time (counted on one edge)
tw(TBH)
TBiIN input HIGH pulse width (counted on one edge)
40
ns
ns
tw(TBL)
TBiIN input LOW pulse width (counted on one edge)
40
ns
100
tc(TB)
TBiIN input cycle time (counted on both edges)
200
ns
tw(TBH)
TBiIN input HIGH pulse width (counted on both edges)
80
ns
tw(TBL)
TBiIN input LOW pulse width (counted on both edges)
80
ns
Table 1.32.34. Timer B input (pulse period measurement mode)
Symbol
Parameter
Standard
Max.
Unit
tc(TB)
TBiIN input cycle time
Min.
400
tw(TBH)
TBiIN input HIGH pulse width
200
ns
tw(TBL)
TBiIN input LOW pulse width
200
ns
Standard
Min.
Max.
Unit
ns
ns
Table 1.32.35. Timer B input (pulse width measurement mode)
Symbol
Parameter
tc(TB)
TBiIN input cycle time
400
tw(TBH)
TBiIN input HIGH pulse width
200
ns
tw(TBL)
TBiIN input LOW pulse width
200
ns
Table 1.32.36. A-D trigger input
Symbol
Parameter
tc(AD)
ADTRG input cycle time (trigger able minimum)
tw(ADL)
ADTRG input LOW pulse width
Standard
Min.
Max.
Unit
1000
ns
125
ns
Table 1.32.37. Serial I/O
Symbol
Parameter
Standard
tc(CK)
CLKi input cycle time
Min.
200
tw(CKH)
CLKi input HIGH pulse width
100
tw(CKL)
CLKi input LOW pulse width
100
td(C-Q)
TxDi output delay time
th(C-Q)
TxDi hold time
tsu(D-C)
th(C-D)
Max.
Unit
ns
ns
ns
80
ns
0
ns
RxDi input setup time
30
ns
RxDi input hold time
90
ns
_______
Table 1.32.38. External interrupt INTi inputs
Symbol
368
Parameter
Standard
tw(INH)
INTi input HIGH pulse width
Min.
250
tw(INL)
INTi input LOW pulse width
250
Max.
Unit
ns
ns
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
VCC = 3V
Switching characteristics (referenced to VCC = 3V, VSS = 0V at Topr = 25oC, CM15="1" unless
otherwise specified)
Table 1.32.39. Memory expansion and microprocessor modes (with no wait)
Measuring condition
Symbol
Parameter
td(BCLK-AD)
th(BCLK-AD)
th(RD-AD)
th(WR-AD)
td(BCLK-CS)
th(BCLK-CS)
th(RD-CS)
th(WR-CS)
td(BCLK-ALE)
th(BCLK-ALE)
td(BCLK-RD)
th(BCLK-RD)
td(BCLK-WR)
th(BCLK-WR)
td(DB-WR)
th(WR-DB)
Address output delay time
Address output hold time (BCLK standard)
Address output hold time (RD standard)
Address output hold time (WR standard)
Chip select output delay time
Chip select output hold time (BCLK standard)
tw(WR)
Write pulse width
Chip select output hold time (RD standard)
Chip select output hold time (WR standard)
ALE signal output delay time
ALE signal output hold time
RD signal output delay time
RD signal output hold time
WR signal output delay time
WR signal output hold time
Data output delay time (WR standard)
Data output hold time (WR standard)
Figure 1.32.1
Standard
Min.
Max.
18
0
0
(Note)
18
0
0
(Note)
18
–2
18
–3
18
0
(Note)
(Note)
(Note)
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: Calculated according to the BCLK frequency as follows:
td(DB – WR) =
th(WR – DB) =
10 9
– 20
f(BCLK)
10 9
f(BCLK) X 2
[ns]
– 10
[ns]
9
th(WR – AD) =
10
f(BCLK) X 2
– 10
[ns]
9
th(WR – CS) =
10
f(BCLK) X 2
– 10
[ns]
9
tw(WR) =
10
f(BCLK) X 2
– 15
[ns]
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Mitsubishi Microcomputers
M32C/83 group
Timing (Vcc = 3V)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 3V
Switching characteristics (referenced to VCC = 3V, VSS = 0V at Topr = 25oC unless otherwise
specified)
Table 1.32.40. Memory expansion and microprocessor modes
(with wait, accessing external memory)
Measuring condition
Symbol
Parameter
td(BCLK-AD)
th(BCLK-AD)
th(RD-AD)
th(WR-AD)
td(BCLK-CS)
th(BCLK-CS)
th(RD-CS)
th(WR-CS)
td(BCLK-ALE)
th(BCLK-ALE)
td(BCLK-RD)
th(BCLK-RD)
td(BCLK-WR)
th(BCLK-WR)
td(DB-WR)
th(WR-DB)
tw(WR)
Address output delay time
Address output hold time (BCLK standard)
Address output hold time (RD standard)
Address output hold time (WR standard)
Chip select output delay time
Chip select output hold time (BCLK standard)
Chip select output hold time (RD standard)
Chip select output hold time (WR standard)
ALE signal output delay time
ALE signal output hold time
RD signal output delay time
RD signal output hold time
WR signal output delay time
WR signal output hold time
Data output delay time (WR standard)
Data output hold time (WR standard)
Write pulse width
Figure 1.32.1
Standard
Min.
Max.
18
0
0
(Note)
18
0
0
(Note)
18
–2
18
–3
18
0
(Note)
(Note)
(Note)
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: Calculated according to the BCLK frequency as follows:
td(DB – WR) =
th(WR – DB) =
th(WR – AD) =
th(WR – CS) =
tw( WR) =
370
10 9 X n
f(BCLK)
10
– 20
f(BCLK) X 2
10
– 10
[ns]
9
f(BCLK) X 2
10
[ns] (n=1, 2 and 3 when 1 wait, 2 wait and 3 wait, respectively)
9
– 10
[ns]
9
f(BCLK) X 2
10 9 X n
f(BCLK) X 2
– 10
– 15
[ns]
[ns] (n=1, 3 and 5 when 1 wait, 2 wait and 3 wait, respectively)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
VCC = 3V
Switching characteristics (referenced to VCC = 3V, VSS = 0V at Topr = 25oC unless otherwise
specified)
Table 1.32.41. Memory expansion and microprocessor modes
(with wait, accessing external memory, multiplex bus area selected)
Symbol
Parameter
Measuring condition
td(BCLK-AD)
th(BCLK-AD)
th(RD-AD)
th(WR-AD)
td(BCLK-CS)
Address output delay time
Address output hold time (BCLK standard)
Address output hold time (RD standard)
Address output hold time (WR standard)
Chip select output delay time
th(BCLK-CS)
th(RD-CS)
th(WR-CS)
td(BCLK-RD)
th(BCLK-RD)
td(BCLK-WR)
th(BCLK-WR)
td(DB-WR)
th(WR-DB)
Chip select output hold time (BCLK standard)
Chip select output hold time (RD standard)
Chip select output hold time (WR standard)
RD signal output delay time
RD signal output hold time
WR signal output delay time
WR signal output hold time
Data output delay time (WR standard)
Data output hold time (WR standard)
td(BCLK-ALE)
th(BCLK-ALE)
td(AD-ALE)
th(ALE-AD)
tdz(RD-AD)
ALE signal output delay time (BCLK standard)
ALE signal output hold time (BCLK standard)
ALE signal output delay time (address standard)
ALE signal output hold time (address standard)
Address output flowting start time
Standard
Min.
Max.
18
0
(Note)
(Note)
18
0
(Note)
(Note)
Figure 1.32.1
18
–3
18
0
(Note)
(Note)
18
–2
(Note)
(Note)
8
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: Calculated according to the BCLK frequency as follows:
th(RD – AD) =
th(WR – AD) =
th(RD – CS) =
10 9
f(BCLK) X 2
10 9
f(BCLK) X 2
10 9
f(BCLK) X 2
– 10
– 10
–10
[ns]
[ns]
[ns]
th(WR – CS) =
10 9
f(BCLK) X 2
td(DB – WR) =
10 X m
– 25
f(BCLK) X 2
[ns] (m=3 and 5 when 2 wait and 3 wait, respectively)
th(WR – DB) =
10 9
f(BCLK) X 2
– 10
[ns]
td(AD – ALE) =
10 9
f(BCLK) X 2
– 20
th(ALE – AD) =
10 9
f(BCLK) X 2
– 10
– 10
[ns]
9
[ns]
[ns]
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Mitsubishi Microcomputers
M32C/83 group
Timing (Vcc = 3V)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
VCC = 3V
Switching characteristics (referenced to VCC = 3V, VSS = 0V at Topr = 25oC unless otherwise
specified)
Table 1.32.42. Memory expansion and microprocessor modes
(with wait, accessing external memory, DRAM area selected)
Measuring condition
Symbol
Parameter
td(BCLK-RAD)
th(BCLK-RAD)
td(BCLK-CAD)
th(BCLK-CAD)
th(RAS-RAD)
td(BCLK-RAS)
th(BCLK-RAS)
tRP
Row address output delay time
Row address output hold time (BCLK standard)
String address output delay time
String address output hold time (BCLK standard)
Row address output hold time after RAS output
td(BCLK-CAS)
th(BCLK-CAS)
td(BCLK-DW)
th(BCLK-DW)
tsu(DB-CAS)
th(BCLK-DB)
tsu(CAS-RAS)
CAS output delay time (BCLK standard)
CAS output hold time (BCLK standard)
Data output delay time (BCLK standard)
Data output hold time (BCLK standard)
CAS after DB output setup time
DB signal output hold time (BCLK standard)
CAS output setup time before RAS output (refresh)
RAS output delay time (BCLK standard)
RAS output hold time (BCLK standard)
RAS "H" hold time
Figure 1.32.1
Note: Calculated according to the BCLK frequency as follows:
th(RAS – RAD) =
10 9
f(BCLK) X 2
tRP =
10 9 X 3
f(BCLK) X 2
– 13
– 20
[ns]
[ns]
9
tsu(DB – CAS) =
10
f(BCLK)
– 20
[ns]
9
tsu(CAS – RAS) =
372
10
f(BCLK) X 2
– 13
[ns]
Standard
Min.
Max.
18
0
18
0
(Note)
18
0
(Note)
18
0
18
–3
(Note)
–7
(Note)
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
Vcc=3V
Memory expansion Mode and Microprocessor Mode (without wait)
Read Timing
BCLK
td(BCLK-ALE)
18ns.max
th(BCLK-ALE)
-2ns.min
ALE
th(BCLK-CS)
td(BCLK-CS)
0ns.min
18ns.max*1
CSi
th(RD-CS)
tcyc
0ns.min
td(BCLK-AD)
th(BCLK-AD)
18ns.max*1
0ns.min
ADi
BHE
td(BCLK-RD)
18ns.max
th(RD-AD)
0ns.min
tac2(RD-DB)*2
th(BCLK-RD)
RD
-3ns.min
tac2(AD-DB)*2
DB
Hi-Z
tsu(DB-BCLK)
th(RD-DB)
30ns.min*1
0ns.min
*1:It is a guarantee value with being alone. 35ns.max garantees as td(BCLK-AD)+tsu(DB-BCLK).
*2:It depends on operation frequency.
tac2(RD-DB)=(tcyc/2-35)ns.max
tac2(AD-DB)=(tcyc-35)ns.max
Write Timing
BCLK
td(BCLK-ALE)
18ns.max
th(BCLK-ALE)
-2ns.min
ALE
th(BCLK-CS)
td(BCLK-CS)
0ns.min
18ns.max
CSi
th(WR-CS)*3
tcyc
td(BCLK-AD)
ADi
BHE
th(BCLK-AD)
18ns.max
0ns.min
td(BCLK-WR)
18ns.max
tw(WR)*3
WR,WRL,
WRH
th(WR-AD)*3
th(BCLK-WR)
0ns.min
td(DB-WR)*3
th(WR-DB)*3
DBi
*3:It depends on operation frequency.
td(DB-WR)=(tcyc-20)ns.min
th(WR-DB)=(tcyc/2-10)ns.min
th(WR-AD)=(tcyc/2-10)ns.min
th(WR-CS)=(tcyc/2-10)ns.min
tw(WR)=(tcyc/2-15)ns.min
Measuring conditions
• VCC=3V±10%
• Input timing voltage :Determined with VIH=1.5V, VIL=0.5V
• Output timing voltage :Determined with VOH=1.5V, VOL=1.5V
Figure 1.32.10. VCC=3V timing diagram (1)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
Vcc=3V
Memory expansion Mode and Microprocessor Mode (with wait)
Read Timing
BCLK
18ns.max
td(BCLK-ALE) th(BCLK-ALE)
-2ns.min
ALE
CSi
td(BCLK-CS)
th(BCLK-CS)
18ns.max*1
0ns.min
th(RD-CS)
tcyc
0ns.min
th(BCLK-AD)
td(BCLK-AD)
18ns.max*1
ADi
BHE
0ns.min
td(BCLK-RD)
18ns.max
th(RD-AD)
0ns.min
RD
th(BCLK-RD)
tac2(RD-DB)*2
-3ns.min
tac2(AD-DB)*2
DB
Hi-Z
tsu(DB-BCLK)
30ns.min*1
th(RD-DB)
0ns.min
*1:It is a guarantee value with being alone. 35ns.max garantees as td(BCLK-AD)+tsu(DB-BCLK).
*2:It depends on operation frequency.
tac2(RD-DB)=(tcyc/2 x m-35)ns.max (m=3, 5 and 7 when 1 wait, 2 wait and 3 wait, respectively.)
tac2(AD-DB)=(tcyc x n-35)ns.max (n=2, 3 and 4 when 1 wait, 2 wait and 3 wait, respectively.)
Write Timing
BCLK
18ns.max
td(BCLK-ALE)
th(BCLK-ALE)
-2ns.min
ALE
th(BCLK-CS)
td(BCLK-CS)
0ns.min
18ns.max
CSi
th(WR-CS)*3
tcyc
td(BCLK-AD)
th(BCLK-AD)
18ns.max
0ns.min
ADi
BHE
td(BCLK-WR)
WR,WRL,
WRH
18ns.max
tw(WR)*3
th(WR-AD)*3
th(BCLK-WR)
td(DB-WR)
*3
0ns.min
th(WR-DB)*3
DBi
*3:It depends on operation frequency.
Measuring conditions
td(DB-WR)=(tcyc x n-20)ns.min
• VCC=3V±10%
(n=1, 2 and 3 when 1 wait, 2 wait and 3 wait, respectively.)
• Input timing voltage
th(WR-DB)=(tcyc/2-10)ns.min
:Determined with VIH=1.5V, VIL=0.5V
th(WR-AD)=(tcyc/2-10)ns.min
• Output timing voltage
th(WR-CS)=(tcyc/2-10)ns.min
tw(WR)=(tcyc/2 x n-15)ns.min
:Determined with VOH=1.5V, VOL=1.5V
(n=1, 3 and 5 when 1 wait, 2 wait and 3 wait, respectively.)
Figure 1.32.11. VCC=3V timing diagram (2)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
Vcc=3V
Memory expansion Mode and Microprocessor Mode
(When accessing external memory area with wait, and select multiplexed bus)
Read Timing
BCLK
td(BCLK-ALE)
th(BCLK-ALE)
18ns.max
-2ns.min
ALE
th(BCLK-CS)
tcyc
td(BCLK-CS)
0ns.min
18ns.max
th(RD-CS)*1
CSi
td(AD-ALE)*1 th(ALE-AD)*1
ADi
/DBi
Address
th(RD-DB)
8ns.max
td(BCLK-AD)
ADi
BHE
tsu(DB-BCLK)
tac3(AD-DB)*1
0ns.min
th(BCLK-AD)
30ns.min
tac3(RD-DB)*1
18ns.max
Address
Data input
tdz(RD-AD)
td(BCLK-RD)
th(BCLK-RD)
18ns.max
0ns.min
th(RD-AD)*1
-3ns.min
RD
*1:It depends on operation frequency.
td(AD-ALE)=(tcyc/2-20)ns.min
th(ALE-AD)=(tcyc/2-10)ns.min, th(RD-AD)=(tcyc/2-10)ns.min, th(RD-CS)=(tcyc/2-10)ns.min
tac3(RD-DB)=(tcyc/2 x m-35)ns.max (m=3 and 5 when 2 wait and 3 wait, respectively.)
tac3(AD-DB)=(tcyc/2 x n-35)ns.max (n=5 and 7 when 2 wait and 3 wait, respectively.)
Write Timing
BCLK
td(BCLK-ALE)
18ns.max
th(BCLK-ALE)
-2ns.min
ALE
CSi
th(BCLK-CS)
tcyc
td(BCLK-CS)
th(WR-CS)*2
18ns.max
0ns.min
td(AD-ALE)*2 th(ALE-AD)*2
ADi
/DBi
th(BCLK-AD)
0ns.min
18ns.max
td(BCLK-WR)
WR,WRL,
WRH
th(WR-DB)*2
td(DB-WR)*2
td(BCLK-AD)
ADi
BHE
Address
Data output
Address
18ns.max
*2:It depends on operation frequency.
td(AD-ALE)=(tcyc/2-20)ns.min
th(ALE-AD)=(tcyc/2-10)ns.min, th(WR-AD)=(tcyc/2-10)ns.min
th(WR-CS)=(tcyc/2-10)ns.min, th(WR-DB)=(tcyc/2-10)ns.min
td(DB-WR)=(tcyc/2 x m-25)ns.min
(m=3 and 5 when 2 wait and 3 wait, respectively.)
th(BCLK-WR)
th(WR-AD)*2
0ns.min
Measuring conditions
• VCC=3V±10%
• Input timing voltage
:Determined with VIH=1.5V, VIL=0.5V
• Output timing voltage
:Determined with VOH=1.5V, VOL=1.5V
Figure 1.32.12. VCC=3V timing diagram (3)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
Memory expansion Mode and Microprocessor Mode
Vcc=3V
(When accessing DRAM area with 2 wait)
Read Timing
BCLK
tcyc
td(BCLK-RAD)
th(BCLK-RAD)
18ns.max*1
MAi
td(BCLK-CAD)
th(BCLK-CAD)
18ns.max*1
0ns.min
0ns.min
String address
Row address
th(RAS-RAD)*2
tRP*2
RAS
td(BCLK-RAS)
18ns.max*1
th(BCLK-RAS)
td(BCLK-CAS)
0ns.min
18ns.max*1
CASL
CASH
th(BCLK-CAS)
0ns.min
DW
tac4(CAS-DB)*2
tac4(CAD-DB)*2
tac4(RAS-DB)*2
DB
Hi-Z
tsu(DB-BCLK)
th(CAS-DB)
30ns.min*1
0ns.min
*1:It is a guarantee value with being alone. 35ns.max garantees as follows:
td(BCLK-RAS) + tsu(DB-BCLK)
td(BCLK-CAS) + tsu(DB-BCLK)
td(BCLK-CAD) + tsu(DB-BCLK)
*2:It depends on operation frequency.
tac4(RAS-DB)=(tcyc/2 x m-35)ns.max (m=3 and 5 when 1 wait and 2 wait, respectively.)
tac4(CAS-DB)=(tcyc/2 x n-35)ns.max (n=1 and 3 when 1 wait and 2 wait, respectively.)
tac4(CAD-DB)=(tcyc x l-35)ns.max (l=1 and 2 when 1 wait and 2 wait, respectively.)
th(RAS-RAD)=(tcyc/2-13)ns.min
tRP=(tcyc/2 x 3-20)ns.min
Measuring conditions
• VCC=3V±10%
• Input timing voltage
:Determined with VIH=1.5V, VIL=0.5V
• Output timing voltage
:Determined with VOH=1.5V, VOL=1.5V
Figure 1.32.13. VCC=3V timing diagram (4)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
Memory expansion Mode and Microprocessor Mode
Vcc=3V
(When accessing DRAM area with 2 wait)
Write Timing
BCLK
tcyc
td(BCLK-RAD)
18ns.max
MAi
th(BCLK-RAD)
0ns.min
th(BCLK-CAD)
td(BCLK-CAD)
18ns.max
0ns.min
String address
Row address
tRP*1
th(RAS-RAD)*1
RAS
td(BCLK-RAS) td(BCLK-CAS)
18ns.max
18ns.max
CASL
CASH
th(BCLK-RAS)
0ns.min
th(BCLK-CAS)
td(BCLK-DW)
0ns.min
18ns.max
DW
th(BCLK-DW)
tsu(DB-CAS)*1
-3ns.min
Hi-Z
DB
th(BCLK-DB)
-7ns.min
*1:It depends on operation frequency.
th(RAS-RAD)=(tcyc/2-13)ns.min
tRP=(tcyc/2 x 3-20)ns.min
tsu(DB-CAS)=(tcyc-20)ns.min
Measuring conditions
• VCC=3V±10%
• Input timing voltage
:Determined with VIH=1.5V, VIL=0.5V
• Output timing voltage
:Determined with VOH=1.5V, VOL=1.5V
Figure 1.32.14. VCC=3V timing diagram (5)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
Memory expansion Mode and Microprocessor Mode
Refresh Timing (CAS before RAS refresh)
Vcc=3V
BCLK
td(BCLK-RAS)
tcyc
18ns.max
RAS
th(BCLK-RAS)
tsu(CAS-RAS)*1
CASL
CASH
0ns.min
td(BCLK-CAS)
th(BCLK-CAS)
0ns.min
18ns.max
DW
*1:It depends on operation frequency.
tsu(CAS-RAS)=(tcyc/2-13)ns.min
Refresh Timing (Self-refresh)
BCLK
td(BCLK-RAS)
tcyc
18ns.max
RAS
tsu(CAS-RAS)*1
CASL
CASH
td(BCLK-CAS)
18ns.max
DW
*1:It depends on operation frequency.
tsu(CAS-RAS)=(tcyc/2-13)ns.min
Measuring conditions
• VCC=3V±10%
• Input timing voltage
:Determined with VIH=1.5V, VIL=0.5V
• Output timing voltage
:Determined with VOH=1.5V, VOL=1.5V
Figure 1.32.15. VCC=3V timing diagram (6)
378
th(BCLK-RAS)
0ns.min
th(BCLK-CAS)
0ns.min
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
tc(TA)
tw(TAH)
TAiIN input
tw(TAL)
tc(UP)
tw(UPH)
TAiOUT input
tw(UPL)
TAiOUT input
(Up/down input)
During event counter mode
TAiIN input
(When count on falling
edge is selected)
th(TIN–UP)
tsu(UP–TIN)
TAiIN input
(When count on rising
edge is selected)
tc(TB)
tw(TBH)
TBiIN input
tw(TBL)
tc(AD)
tw(ADL)
ADTRG input
tc(CK)
tw(CKH)
CLKi
tw(CKL)
th(C–Q)
TxDi
td(C–Q)
tsu(D–C)
th(C–D)
RxDi
tw(INL)
INTi input
tw(INH)
Figure 1.32.16. VCC=3V timing diagram (7)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Timing (Vcc = 3V)
Memory Expansion Mode and Microprocessor Mode
(Valid only with wait)
BCLK
RD
(Separate bus)
WR, WRL, WRH
(Separate bus)
RD
(Multiplexed bus)
WR, WRL, WRH
(Multiplexed bus)
RDY input
tsu(RDY–BCLK)
th(BCLK–RDY)
(Valid with or without wait)
BCLK
tsu(HOLD–BCLK)
th(BCLK–HOLD)
HOLD input
HLDA output
P0, P1, P2,
P3, P4,
P50 to P52
td(BCLK–HLDA) td(BCLK–HLDA)
Hi–Z
Measuring conditions :
• VCC=3V±10%
• Input timing voltage : Determined with VIH=2.4V, VIL=0.6V
• Output timing voltage : Determined with VOH=1.5V, VOL=1.5V
Figure 1.32.17. VCC=3V timing diagram (8)
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description (Flash Memory Version)
Outline Performance
Table 1.33.1 shows the outline performance of the M32C/83 (flash memory version).
Table 1.33.1. Outline Performance of the M32C/83 (flash memory version)
Item
Performance
Power supply voltage
f(XIN)=30MHz, without wait, 4.2V to 5.5V
f(XIN)=20MHz, without wait, 3.0V to 3.6V
Program/erase voltage
4.2V to 5.5 V
Flash memory operation mode
Three modes (parallel I/O, standard serial I/O, CPU rewrite)
Erase block
division
: f(BCLK)=12.5MHz, with one wait
: f(BCLK)=6.25MHz, without wait
User ROM area
See Figure 1.33.3
Boot ROM area
One division (8 Kbytes) (Note 1)
Program method
In units of pages (in units of 256 bytes)
Erase method
Collective erase/block erase
Program/erase control method
Program/erase control by software command
Protect method
Protected for each block by lock bit
Number of commands
8 commands
Program/erase count
100 times
Data holding
10 years
ROM code protect
Parallel I/O and standard serial modes are supported.
Note: The boot ROM area contains a standard serial I/O mode control program which is stored in
it when shipped from the factory. This area can be erased and programmed in only parallel
I/O mode.
The following shows Mitsubishi plans to develop a line of M32C/83 products (flash memory version).
(1) ROM capacity
(2) Package
100P6S-A ... Plastic molded QFP
100P6Q-A ... Plastic molded QFP
144P6Q-A ... Plastic molded QFP
ROM size
(Bytes)
External
ROM
512K
M30835FJGP
M30833FJFP
M30833FJGP
256K
128K
Flash memory version
Figure 1.33.1. ROM Expansion
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description (Flash Memory Version)
The following lists the M32C/83 products to be supported in the future.
Table 1.33.2. Product List
ROM capacity
Type No
M30835FJGP
M30833FJGP
M30833FJFP
As of Nov., 2001
**
**
**
512 Kbytes
RAM capacity
31 Kbytes
Package type
Remarks
144P6Q-A
100P6Q-A
100P6S-A
** : Under development
Type No.
M3083 5 F J – XXX FP
Package type:
FP : Package
GP : Package
100P6S-A
100P6Q-A, 144P6Q-A
ROM No.
Omitted for external ROM version
and blank flash memory version
ROM capacity:
J : 512K bytes
Memory type:
M : Mask ROM version
S : External ROM version
F : Flash memory version
Shows RAM capacity, pin count, etc
(The value itself has no specific meaning)
M32C/83 Group
M16C Family
Figure 1.33.2. Type No., memory size, and package
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Description (Flash Memory Version)
Flash Memory
The M32C/83 (flash memory version) contains the flash memory that can be rewritten with a single voltage
of 5 V. For this flash memory, three flash memory modes are available in which to read, program, and
erase: parallel I/O and standard serial I/O modes in which the flash memory can be manipulated using a
programmer and a CPU rewrite mode in which the flash memory can be manipulated by the Central Processing Unit (CPU). Each mode is detailed in the pages to follow.
The flash memory is divided into several blocks as shown in Figure 1.33.3, so that memory can be erased
one block at a time. Each block has a lock bit to enable or disable execution of an erase or program
operation, allowing for data in each block to be protected.
In addition to the ordinary user ROM area to store a microcomputer operation control program, the flash
memory has a boot ROM area that is used to store a program to control rewriting in CPU rewrite and
standard serial I/O modes. This boot ROM area has had a standard serial I/O mode control program stored
in it when shipped from the factory. However, the user can write a rewrite control program in this area that
suits the user’s application system. This boot ROM area can be rewritten in only parallel I/O mode.
0F8000016
Block 10 : 64K bytes
0F9000016
Block 9 : 64K bytes
0FA000016
Block 8 : 64K bytes
0FB000016
Block 7 : 64K bytes
0FC000016
Block 6 : 64K bytes
0FD000016
0FE000016
Block 5 : 64K bytes
Block 4 : 64K bytes
0FF000016
Block 3 : 32K bytes
0FF800016
0FFA00016
0FFC00016
Note 1: The boot ROM area can be rewritten in only parallel input/
output mode. (Access to any other areas is inhibited.)
Note 2: To specify a block, use the maximum address in the block
that is an even address.
Block 2 : 8K bytes
Block 1 : 8K bytes
Block 0 : 16K bytes
0FFFFFF16
0FFE00016
0FFFFFF16
User ROM area
8K bytes
Boot ROM area
Figure 1.33.3. Block diagram of flash memory version
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CPU Rewrite Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CPU Rewrite Mode
In CPU rewrite mode, the on-chip flash memory can be operated on (read, program, or erase) under control
of the Central Processing Unit (CPU).
In CPU rewrite mode, only the user ROM area shown in Figure 1.33.3 can be rewritten; the boot ROM area
cannot be rewritten. Make sure the program and block erase commands are issued for only the user ROM
area and each block area.
The control program for CPU rewrite mode can be stored in either user ROM or boot ROM area. In the CPU
rewrite mode, because the flash memory cannot be read from the CPU, the rewrite control program must
be transferred to any area other than the internal flash memory before it can be executed.
Microcomputer Mode and Boot Mode
The control program for CPU rewrite mode must be written into the user ROM or boot ROM area in
parallel I/O mode beforehand. (If the control program is written into the boot ROM area, the standard
serial I/O mode becomes unusable.)
See Figure 1.33.3 for details about the boot ROM area.
Normal microcomputer mode is entered when the microcomputer is reset with pulling CNVSS pin low. In
this case, the CPU starts operating using the control program in the user ROM area.
When the microcomputer is reset by pulling the P55 pin low, the CNVSS pin high, and the P50 pin high, the
CPU starts operating using the control program in the boot ROM area. This mode is called the “boot”
mode. The control program in the boot ROM area can also be used to rewrite the user ROM area.
Block Address
Block addresses refer to the maximum even address of each block. These addresses are used in the
block erase command, lock bit program command, and read lock status command.
Outline Performance of CPU Rewrite Mode
In the CPU rewrite mode, the CPU erases, programs and reads the internal flash memory as instructed by
software commands. Operations must be executed from a memory other than the internal flash memory,
such as the internal RAM.
When the CPU rewrite mode select bit (bit 1 at address 037716) is set to “1”, transition to CPU rewrite mode
occurs and software commands can be accepted.
In the CPU rewrite mode, write to and read from software commands and data into even-numbered address (“0” for byte address A0) in 16-bit units. Always write 8-bit software commands into even-numbered
address. Commands are ignored with odd-numbered addresses.
Use software commands to control program and erase operations. Whether a program or erase operation
has terminated normally or in error can be verified by reading the status register.
Figure 1.34.1 shows the flash memory control register 0.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CPU Rewrite Mode (Flash Memory Version)
Flash memory control register 0
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
Address
When reset
FMR0
005716
XX0000012
Bit name
Bit symbol
Function
AA
AA
A
AA
A
AA
A
AA
A
AA
A
AA
A
FMR00
RY/BY signal status bit
0: Busy (being written or erased)
1: Ready
FMR01
CPU rewrite mode
select bit (Note 1)
0: Normal mode
(Software commands invalid)
1: CPU rewrite mode
(Software commands acceptable)
FMR02
Lock bit disable bit
(Note 2)
0: Block lock by lock bit data is
enabled
1: Block lock by lock bit data is
disabled
FMR03
Flash memory reset bit
(Note 3)
0: Normal operation
1: Reset
Reserved bit
FMR05
Must always be set to “0”
User ROM area select bit ( 0: Boot ROM area is accessed
Note 4) (Effective in only 1: User ROM area is accessed
boot mode)
Noting is assigned. When write, set to "0".
When read, their contents are indeterminate.
R WW
R
Note 1: For this bit to be set to “1”, the user needs to write a “0” and then a “1” to it in
succession. When it is not this procedure, it is not enacted in “1”. This is necessary to
ensure that no interrupt or DMA transfer will be executed during the interval. Use the
control program except in the internal flash memory for write to this bit. Also write to this
bit when NMI pin is "H" level.
Note 2: For this bit to be set to “1”, the user needs to write a “0” and then a “1” to it in succession
when the CPU rewrite mode select bit = “1”. When it is not this procedure, it is not
enacted in “1”. This is necessary to ensure that no interrupt or DMA transfer will be
executed during the interval.
Note 3: Effective only when the CPU rewrite mode select bit = 1. Set this bit to 0 subsequently
after setting it to 1 (reset).
Note 4: Use the control program except in the internal flash memory for write to this bit.
Figure 1.34.1. Flash memory control register
Flash memory control register (address 005716)
_____
Bit 0 of the flash memory control register 0 is the RY/BY signal status bit used exclusively to read the
operating status of the flash memory. During programming and erase operations, it is “0”. Otherwise, it is
“1”.
Bit 1 of the flash memory control register 0 is the CPU rewrite mode select bit. The CPU rewrite mode is
entered by setting this bit to “1”, so that software commands become acceptable. In CPU rewrite mode, the
CPU becomes unable to access the internal flash memory directly. Therefore, write bit 1 in an area other
than the internal flash memory. To set this bit to “1”, it is necessary to write “0” and then write “1” in
succession when NMI pin is "H" level. The bit can be set to “0” by only writing a “0” .
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CPU Rewrite Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Bit 2 of the flash memory control register 0 is a lock bit disable bit. By setting this bit to “1”, it is possible to
disable erase and write protect (block lock) effectuated by the lock bit data. The lock bit disable select bit
only disables the lock bit function; it does not change the lock data bit value. However, if an erase operation
is performed when this bit =“1”, the lock bit data that is “0” (locked) is set to “1” (unlocked) after erasure. To
set this bit to “1”, it is necessary to write “0” and then write “1” in succession. This bit can be manipulated
only when the CPU rewrite mode select bit = “1”.
Bit 3 of the flash memory control register 0 is the flash memory reset bit used to reset the control circuit of
the internal flash memory. This bit is used when exiting CPU rewrite mode and when flash memory access
has failed. When the CPU rewrite mode select bit is “1”, writing “1” for this bit resets the control circuit. To
release the reset, it is necessary to set this bit to “0”.
Bit 5 of the flash memory control register 0 is a user ROM area select bit which is effective in only boot
mode. If this bit is set to “1” in boot mode, the area to be accessed is switched from the boot ROM area to
the user ROM area. When the CPU rewrite mode needs to be used in boot mode, set this bit to “1”. Note
that if the microcomputer is booted from the user ROM area, it is always the user ROM area that can be
accessed and this bit has no effect. When in boot mode, the function of this bit is effective regardless of
whether the CPU rewrite mode is on or off. Use the control program except in the internal flash memory to
rewrite this bit.
Figure 1.34.2 shows a flowchart for setting/releasing the CPU rewrite mode. Always perform operation as
indicated in these flowcharts.
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CPU Rewrite Mode (Flash Memory Version)
Program in ROM
Start
Single-chip mode, memory expansion
mode, or boot mode
Set processor mode register (Note 1)
Transfer CPU rewrite mode control
program to internal RAM
Jump to transferred control program in RAM
(Subsequent operations are executed by control
program in this RAM)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Program in RAM
*1
(Boot mode only)
Set user ROM area select bit to “1”
Set CPU rewrite mode select bit to “1” (by
writing “0” and then “1” in succession)(Note 2)
Using software command execute erase,
program, or other operation
(Set lock bit disable bit as required)
Execute read array command or reset flash
memory by setting flash memory reset bit (by
writing “1” and then “0” in succession) (Note 3)
*1
Write “0” to CPU rewrite mode select bit
(Boot mode only)
Write “0” to user ROM area select bit (Note 4)
End
Note 1: During CPU rewrite mode, set the main clock frequency as shown below using the main clock division
register (address 000C16):
6.25 MHz or less when wait bit (bit 2 at address 000516) = “0” (without internal access wait state)
12.5 MHz or less when wait bit (bit 2 at address 000516) = “1” (with internal access wait state)
Note 2: For CPU rewrite mode select bit to be set to “1”, the user needs to write a “0” and then a “1” to it in
succession. When it is not this procedure, it is not enacted in “1”. This is necessary to ensure that no
interrupt or DMA transfer will be executed during the interval. Use the program except in the internal
flash memory for write to this bit. Also write to this bit when NMI pin is "H" level.
Note 3: Before exiting the CPU rewrite mode after completing erase or program operation, always be sure to
execute a read array command or reset the flash memory.
Note 4: “1” can be set. However, when this bit is “1”, user ROM area is accessed.
Figure 1.34.2. CPU rewrite mode set/reset flowchart
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CPU Rewrite Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Precautions on CPU Rewrite Mode
Described below are the precautions to be observed when rewriting the flash memory in CPU rewrite
mode.
(1) Operation speed
During CPU rewrite mode, set the main clock frequency as shown below using the main clock division
register (address 000C16):
6.25 MHz or less when wait bit (bit 2 at address 000516) = 0 (without internal access wait state)
12.5 MHz or less when wait bit (bit 2 at address 000516) = 1 (with internal access wait state)
(2) Instructions inhibited against use
The instructions listed below cannot be used during CPU rewrite mode because they refer to the
internal data of the flash memory:
UND instruction, INTO instruction, JMPS instruction, JSRS instruction, and BRK instruction
(3) Interrupts inhibited against use
The address match interrupt cannot be used during CPU rewrite mode because they refer to the
internal data of the flash memory. If interrupts have their vector in the variable vector table, they can be
_______
used by transferring the vector into the RAM area. The NMI and watchdog timer interrupts each can
be used to change the CPU rewrite mode select bit forcibly to normal mode (FMR01="0") upon occur_______
rence of the interrupt. Since the rewrite operation is halted when the NMI and watchdog timer interrupts occur, set the CPU rewite mode select bit to "1" and the erase/program operation needs to be
performed over again.
(4) Reset
Reset input is always accepted.
(5) Access disable
Write CPU rewrite mode select bit and user ROM area select bit in an area other than the internal flash
memory.
(6) How to access
For CPU rewrite mode select bit and lock bit disable bit to be set to “1”, the user needs to write a “0”
and then a “1” to it in succession. When it is not this procedure, it is not enacted in “1”. This is necessary to ensure that no interrupt or DMA transfer will be executed during the interval.
Write to the CPU rewrite mode select bit when NMI pin is "H" level.
(7)Writing in the user ROM area
If power is lost while rewriting blocks that contain the flash rewrite program with the CPU rewrite mode,
those blocks may not be correctly rewritten and it is possible that the flash memory can no longer be
rewritten after that. Therefore, it is recommended to use the standard serial I/O mode or parallel I/O
mode to rewrite these blocks.
(8)Using the lock bit
To use the CPU rewrite mode, use a boot program that can set and cancel the lock command.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CPU Rewrite Mode (Flash Memory Version)
Software Commands
Table 1.34.1 lists the software commands available with the M16C/62A (flash memory version).
After setting the CPU rewrite mode select bit to 1, write a software command to specify an erase or
program operation. Note that when entering a software command, the upper byte (D8 to D15) is ignored.
The content of each software command is explained below.
Table 1.34.1. List of software commands (CPU rewrite mode)
First bus cycle
Command
Mode
Address
Second bus cycle
Data
(D0 to D7)
Mode
Address
Read
X
Read array
Write
Read status register
Write
X
7016
Clear status register
Write
X
5016
Page program
Write
X
4116
Write
Block erase
Write
X
2016
Write
Erase all unlock block
Write
X
A716
Lock bit program
Write
X
Read lock bit status
Write
X
(Note 3)
X
(Note 6)
Third bus cycle
Data
(D0 to D7)
Data
Mode Address (D0 to D7)
FF16
SRD
(Note 2)
WA0 (Note 3) WD0 (Note 3) Write
(Note 4)
D016
Write
X
D016
7716
Write
BA
D016
7116
Read
BA
D6
BA
WA1
WD1
(Note 5)
Note 1: When a software command is input, the high-order byte of data (D8 to D15) is ignored.
Note 2: SRD = Status Register Data
Note 3: WA = Write Address, WD = Write Data
WA and WD must be set sequentially from 0016 to FE16 (byte address; however, an even address). The page size is
256 bytes.
Note 4: BA = Block Address (Enter the maximum address of each block that is an even address.)
Note 5: D6 corresponds to the block lock status. Block not locked when D6 = 1, block locked when D6 = 0.
Note 6: X denotes a given address in the user ROM area (that is an even address).
Read Array Command (FF16)
The read array mode is entered by writing the command code “FF16” in the first bus cycle. When an
even address to be read is input in one of the bus cycles that follow, the content of the specified
address is read out at the data bus (D0–D15), 16 bits at a time.
The read array mode is retained intact until another command is written.
Read Status Register Command (7016)
When the command code “7016” is written in the first bus cycle, the content of the status register is
read out at the data bus (D0–D7) by a read in the second bus cycle.
The status register is explained in the next section.
Clear Status Register Command (5016)
This command is used to clear the bits SR3 to 5 of the status register after they have been set. These
bits indicate that operation has ended in an error. To use this command, write the command code
“5016” in the first bus cycle.
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CPU Rewrite Mode (Flash Memory Version)
Page Program Command (4116)
Page program allows for high-speed programming in units of 256 bytes. Page program operation
starts when the command code “4116” is written in the first bus cycle. In the second bus cycle through
the 129th bus cycle, the write data is sequentially written 16 bits at a time. At this time, the addresses
A0-A7 need to be incremented by 2 from “0016” to “FE16.” When the system finishes loading the data,
it starts an auto write operation (data program and verify operation).
Whether the auto write operation is completed can be confirmed by reading the status register or the
flash memory control register 0. At the same time the auto write operation starts, the read status
register mode is automatically entered, so the content of the status register can be read out. The
status register bit 7 (SR7) is set to 0 at the same time the auto write operation starts and is returned to
1 upon completion of the auto write operation. In this case, the read status register mode remains
active until the Read Array command (FF16) or Read Lock Bit Status command (7116) is written or the
flash memory is reset using its reset bit.
____
The RY/BY signal status bit of the flash memory control register 0 is 0 during auto write operation and
1 when the auto write operation is completed as is the status register bit 7.
After the auto write operation is completed, the status register can be read out to know the result of the
auto write operation. For details, refer to the section where the status register is detailed.
Figure 1.34.3 shows an example of a page program flowchart.
Each block of the flash memory can be write protected by using a lock bit. For details, refer to the
section where the data protect function is detailed.
Additional writes to the already programmed pages are prohibited.
Start
Write 4116
n=0
Write address n and
data n
n = FE16
n=n+2
NO
YES
RY/BY signal
status bit
= 1?
YES
Check full status
Page program
completed
Figure 1.34.3. Page program flowchart
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CPU Rewrite Mode (Flash Memory Version)
Block Erase Command (2016/D016)
By writing the command code “2016” in the first bus cycle and the confirmation command code “D016”
in the second bus cycle that follows to the block address of a flash memory block, the system initiates
an auto erase (erase and erase verify) operation.
Whether the auto erase operation is completed can be confirmed by reading the status register or the
flash memory control register 0. At the same time the auto erase operation starts, the read status
register mode is automatically entered, so the content of the status register can be read out. The
status register bit 7 (SR7) is set to 0 at the same time the auto erase operation starts and is returned
to 1 upon completion of the auto erase operation. In this case, the read status register mode remains
active until the Read Array command (FF16) or Read Lock Bit Status command (7116) is written or the
flash memory is reset using its reset bit.
____
The RY/BY signal status bit of the flash memory control register 0 is 0 during auto erase operation and
1 when the auto erase operation is completed as is the status register bit 7.
After the auto erase operation is completed, the status register can be read out to know the result of
the auto erase operation. For details, refer to the section where the status register is detailed.
Figure 1.34.4 shows an example of a block erase flowchart.
Each block of the flash memory can be protected against erasure by using a lock bit. For details, refer
to the section where the data protect function is detailed.
Start
Write 2016
Write D016
Block address
RY/BY signal
status bit
= 1?
NO
YES
Check full status check
Block erase
completed
Figure 1.34.4. Block erase flowchart
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CPU Rewrite Mode (Flash Memory Version)
Erase All Unlock Blocks Command (A716/D016)
By writing the command code “A716” in the first bus cycle and the confirmation command code “D016”
in the second bus cycle that follows, the system starts erasing blocks successively.
Whether the erase all unlock blocks command is terminated can be confirmed by reading the status
register or the flash memory control register 0, in the same way as for block erase. Also, the status
register can be read out to know the result of the auto erase operation.
When the lock bit disable bit of the flash memory control register 0 = 1, all blocks are erased no matter
how the lock bit is set. On the other hand, when the lock bit disable bit = 0, the function of the lock bit
is effective and only nonlocked blocks (where lock bit data = 1) are erased.
Lock Bit Program Command (7716/D016)
By writing the command code “7716” in the first bus cycle and the confirmation command code “D016”
in the second bus cycle that follows to the block address of a flash memory block, the system sets the
lock bit for the specified block to 0 (locked).
Figure 1.34.5 shows an example of a lock bit program flowchart. The status of the lock bit (lock bit
data) can be read out by a read lock bit status command.
Whether the lock bit program command is terminated can be confirmed by reading the status register
or the flash memory control register 0, in the same way as for page program.
For details about the function of the lock bit and how to reset the lock bit, refer to the section where the
data protect function is detailed.
Start
Write 7716
Write D016
block address
NO
RY/BY signal
status bit
= 1?
YES
SR4 = 0?
NO
YES
Lock bit program
completed
Figure 1.34.5. Lock bit program flowchart
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Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CPU Rewrite Mode (Flash Memory Version)
Read Lock Bit Status Command (7116)
By writing the command code “7116” in the first bus cycle and then the block address of a flash
memory block in the second bus cycle that follows, the system reads out the status of the lock bit of the
specified block on to the data (D6).
Figure 1.34.6 shows an example of a read lock bit program flowchart.
Start
Write 7116
Enter block address
D6 = 0?
NO
YES
Blocks locked
Blocks not locked
Figure 1.34.6. Read lock bit status flowchart
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CPU Rewrite Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Data Protect Function (Block Lock)
Each block in Figure 1.33.3 has a nonvolatile lock bit to specify that the block be protected (locked)
against erase/write. The lock bit program command is used to set the lock bit to 0 (locked). The lock bit of
each block can be read out using the read lock bit status command.
Whether block lock is enabled or disabled is determined by the status of the lock bit and how the flash
memory control register 0’s lock bit disable bit is set.
(1) When the lock bit disable bit = 0, a specified block can be locked or unlocked by the lock bit status
(lock bit data). Blocks whose lock bit data = 0 are locked, so they are disabled against erase/write.
On the other hand, the blocks whose lock bit data = 1 are not locked, so they are enabled for erase/
write.
(2) When the lock bit disable bit = 1, all blocks are nonlocked regardless of the lock bit data, so they are
enabled for erase/write. In this case, the lock bit data that is 0 (locked) is set to 1 (nonlocked) after
erasure, so that the lock bit-actuated lock is removed.
Status Register
The status register indicates the operating status of the flash memory and whether an erase or program
operation has terminated normally or in an error. The content of this register can be read out by only
writing the read status register command (7016). Table 1.34.2 details the status register.
The status register is cleared by writing the Clear Status Register command (5016).
After a reset, the status register is set to “8016.”
Each bit in this register is explained below.
Write state machine (WSM) status (SR7)
After power-on, the write state machine (WSM) status is set to 1.
The write state machine (WSM) status indicates the operating status of the device, as for output on the
____
RY/BY pin. This status bit is set to 0 during auto write or auto erase operation and is set to 1 upon
completion of these operations.
Erase status (SR5)
The erase status informs the operating status of auto erase operation to the CPU. When an erase
error occurs, it is set to 1.
The erase status is reset to 0 when cleared.
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CPU Rewrite Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Program status (SR4)
The program status informs the operating status of auto write operation to the CPU. When a write
error occurs, it is set to 1.
The program status is reset to 0 when cleared.
When an erase command is in error (which occurs if the command entered after the block erase
command (2016) is not the confirmation command (D016), both the program status and erase status
(SR5) are set to 1.
When the program status or erase status = 1, the following commands entered by command write are
not accepted.
Also, in one of the following cases, both SR4 and SR5 are set to 1 (command sequence error):
(1) When the valid command is not entered correctly
(2) When the data entered in the second bus cycle of lock bit program (7716/D016), block erase
(2016/D016), or erase all unlock blocks (A716/D016) is not the D016 or FF16. However, if FF16 is
entered, read array is assumed and the command that has been set up in the first bus cycle is
canceled.
Block status after program (SR3)
If excessive data is written (phenomenon whereby the memory cell becomes depressed which results
in data not being read correctly), “1” is set for the program status after-program at the end of the page
write operation. In other words, when writing ends successfully, “8016” is output; when writing fails,
“9016” is output; and when excessive data is written, “8816” is output.
Table 1.34.2. Definition of each bit in status register
Definition
Each bit of
SRD
Status name
"1"
"0"
Ready
Busy
-
-
SR7 (bit7)
Write state machine (WSM) status
SR6 (bit6)
Reserved
SR5 (bit5)
Erase status
Terminated in error
Terminated normally
SR4 (bit4)
Program status
Terminated in error
Terminated normally
SR3 (bit3)
Block status after program
Terminated in error
Terminated normally
SR2 (bit2)
Reserved
-
-
SR1 (bit1)
Reserved
-
-
SR0 (bit0)
Reserved
-
-
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CPU Rewrite Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Full Status Check
By performing full status check, it is possible to know the execution results of erase and program
operations. Figure 1.34.7 shows a full status check flowchart and the action to be taken when each
error occurs.
Read status register
SR4=1 and SR5
=1 ?
YES
Command
sequence error
Execute the clear status register command (5016)
to clear the status register. Try performing the
operation one more time after confirming that the
command is entered correctly.
Block erase error
Should a block erase error occur, the block in error
cannot be used.
NO
SR5=0?
NO
YES
SR4=0?
NO
Program error (page
or lock bit)
YES
SR3=0?
NO
YES
Program error
(block)
Execute the read lock bit status command (7116) to
see if the block is locked. After removing lock,
execute write operation in the same way. If the
error still occurs, the page in error cannot be used.
After erasing the block in error, execute write
operation one more time. If the same error still
occurs, the block in error cannot be used.
End (block erase, program)
Note: When one of SR5 to SR3 is set to 1, none of the page program, block erase, erase all unlock
blocks and lock bit program commands is accepted. Execute the clear status register command
(5016) before executing these commands.
Figure 1.34.7. Full status check flowchart and remedial procedure for errors
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M32C/83 group
Functions To Inhibit Rewriting Flash Memory (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Functions To Inhibit Rewriting Flash Memory Version
To prevent the contents of the flash memory version from being read out or rewritten easily, the device
incorporates a ROM code protect function for use in parallel I/O mode and an ID code check function for
use in standard serial I/O mode.
ROM code protect function
The ROM code protect function reading out or modifying the contents of the flash memory version by
using the ROM code protect control address (0FFFFFF16) during parallel I/O mode. Figure 1.34.8 shows
the ROM code protect control address (0FFFFFF16). (This address exists in the user ROM area.)
If one of the pair of ROM code protect bits is set to 0, ROM code protect is turned on, so that the contents
of the flash memory version are protected against readout and modification. ROM code protect is implemented in two levels. If level 2 is selected, the flash memory is protected even against readout by a
shipment inspection LSI tester, etc. When an attempt is made to select both level 1 and level 2, level 2 is
selected by default.
If both of the two ROM code protect reset bits are set to “00,” ROM code protect is turned off, so that the
contents of the flash memory version can be read out or modified. Once ROM code protect is turned on,
the contents of the ROM code protect reset bits cannot be modified in parallel I/O mode. Use the serial I/
O or some other mode to rewrite the contents of the ROM code protect reset bits.
ROM code protect control address
b7
b6
b5
b4
b3
b2
b1
b0
1 1
Symbol
ROMCP
Address
0FFFFFF16
When reset
FF16
Bit name
Bit symbol
Reserved bit
Function
Always set this bit to 1.
ROM code protect level
2 set bit (Note 1, 2)
b3 b2
ROMCP2
ROM code protect reset
bit (Note 3)
b5 b4
ROMCR
ROMCP1
ROM code protect level
1 set bit (Note 1)
b7 b6
00: Protect enabled
01: Protect enabled
10: Protect enabled
11: Protect disabled
00: Protect removed
01: Protect set bit effective
10: Protect set bit effective
11: Protect set bit effective
00: Protect enabled
01: Protect enabled
10: Protect enabled
11: Protect disabled
Note 1: When ROM code protect is turned on, the on-chip flash memory is protected against
readout or modification in parallel input/output mode.
Note 2: When ROM code protect level 2 is turned on, ROM code readout by a shipment
inspection LSI tester, etc. also is inhibited.
Note 3: The ROM code protect reset bits can be used to turn off ROM code protect level 1 and
ROM code protect level 2. However, since these bits cannot be changed in parallel input/
output mode, they need to be rewritten in serial input/output or some other mode.
Figure 1.34.8. ROM code protect control address
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Mitsubishi Microcomputers
M32C/83 group
Functions To Inhibit Rewriting Flash Memory (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
ID Code Check Function
Use this function in standard serial I/O mode. When the contents of the flash memory are not blank, the ID
code sent from the peripheral unit is compared with the ID code written in the flash memory to see if they
match. If the ID codes do not match, the commands sent from the peripheral unit are not accepted. The ID
code consists of 8-bit data, the areas of which, beginning with the first byte, are 0FFFFDF16, 0FFFFE316,
0FFFFEB16, 0FFFFEF16, 0FFFFF316, 0FFFFF716, and 0FFFFFB16. Write a program which has had the
ID code preset at these addresses to the flash memory.
Address
0FFFFDC16 to 0FFFFDF16
ID1 Undefined instruction vector
0FFFFE016 to 0FFFFE316
ID2 Overflow vector
0FFFFE416 to 0FFFFE716
BRK instruction vector
0FFFFE816 to 0FFFFEB16
ID3 Address match vector
0FFFFEC16 to 0FFFFEF16
ID4
0FFFFF016 to 0FFFFF316
ID5 Watchdog timer vector
0FFFFF416 to 0FFFFF716
ID6
0FFFFF816 to 0FFFFFB16
ID7
0FFFFFC16 to 0FFFFFF16
NMI vector
Reset vector
4 bytes
Figure 1.34.9. ID code store addresses
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Appendix Parallel I/O Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Parallel I/O Mode
In this mode, the M32C/83 (flash memory version) operates in a manner similar to the flash memory
M5M29FB/T800 from Mitsubishi. Since there are some differences with regard to the functions not available with the microcomputer and matters related to memory capacity, the M32C/83 cannot be programed
by a programer for the flash memory.
Use an exclusive programer supporting M32C/83 (flash memory version).
Refer to the instruction manual of each programer maker for the details of use.
User ROM and Boot ROM Areas
In parallel I/O mode, the user ROM and boot ROM areas shown in Figure 1.33.3 can be rewritten. Both
areas of flash memory can be operated on in the same way.
Program and block erase operations can be performed in the user ROM area. The user ROM area and its
blocks are shown in Figure 1.33.3.
The boot ROM area is 8 Kbytes in size. In parallel I/O mode, it is located at addresses 0FFE00016 through
0FFFFFF16. Make sure program and block erase operations are always performed within this address
range. (Access to any location outside this address range is prohibited.)
In the boot ROM area, an erase block operation is applied to only one 8 Kbyte block. The boot ROM area
has had a standard serial I/O mode control program stored in it when shipped from the Mitsubishi factory.
Therefore, using the device in standard serial input/output mode, you do not need to write to the boot
ROM area.
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Standard Serial I/O Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Standard serial I/O mode
The standard serial I/O mode inputs and outputs the software commands, addresses and data needed to
operate (read, program, erase, etc.) the internal flash memory. This I/O is serial. There are actually two
standard serial I/O modes: mode 1, which is clock synchronized, and mode 2, which is asynchronized. Both
modes require a purpose-specific peripheral unit.
The standard serial I/O mode is different from the parallel I/O mode in that the CPU controls flash memory
rewrite (uses the CPU's rewrite mode), rewrite data input and so forth. It is started when the reset is re_____
________
leased, which is done when the P50 (CE) pin is "H" level, the P55 (EPM) pin "L" level and the CNVss pin "H"
level. (In the ordinary command mode, set CNVss pin to "L" level.)
This control program is written in the boot ROM area when the product is shipped from Mitsubishi. Accordingly, make note of the fact that the standard serial I/O mode cannot be used if the boot ROM area is
rewritten in the parallel I/O mode. Figures 1.35.1 to 1.35.3 show the pin connections for the standard serial
I/O mode. Serial data I/O uses UART1 and transfers the data serially in 8-bit units. Standard serial I/O
switches between mode 1 (clock synchronized) and mode 2 (clock asynchronized) according to the level of
CLK1 pin when the reset is released.
To use standard serial I/O mode 1 (clock synchronized), set the CLK1 pin to "H" level and the TxD1 pin to "L"
level, and release the reset. The CLK1 pin is connected to Vcc via pull-up resistance and the TxD1 is
connected to Vss via pull-down resistance. The operation uses the four UART1 pins CLK1, RxD1, TxD1 and
RTS1 (BUSY). The CLK1 pin is the transfer clock input pin through which an external transfer clock is input.
The TxD1 pin is for CMOS output. The RTS1 (BUSY) pin outputs an "L" level when ready for reception and
an "H" level when reception starts.
To use standard serial I/O mode 2 (clock asynchronized), set the CLK1 pin to "L" level and release the reset.
The operation uses the two UART1 pins RxD1 and TxD1.
In the standard serial I/O mode, only the user ROM area indicated in Figure 1.35.20 can be rewritten. The
boot ROM cannot.
In the standard serial I/O mode, a 7-byte ID code is used. When there is data in the flash memory, commands sent from the peripheral unit (programmer) are not accepted unless the ID code matches.
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Standard Serial I/O Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Pin functions (Flash memory standard serial I/O mode)
Pin
Name
Description
I/O
Apply 4.2V to 5.5V to Vcc pin and 0 V to Vss pin.
VCC,VSS
Power input
CNVSS
CNVSS
I
Connect to Vcc pin.
RESET
Reset input
I
Reset input pin. While reset is "L" level, a 20 cycle or longer clock
must be input to XIN pin.
XIN
Clock input
I
XOUT
Clock output
O
Connect a ceramic resonator or crystal oscillator between XIN
and XOUT pins. To input an externally generated clock, input it
to XIN pin and open XOUT pin.
BYTE
BYTE
I
Connect this pin to Vcc or Vss.
AVCC, AVSS
Analog power supply input
I
Connect AVSS to Vss and AVcc to Vcc, respectively.
VREF
Reference voltage input
I
Enter the reference voltage for A-D converter from this pin.
P00 to P07
Input port P0
I
P10 to P17
Input port P1
I
P20 to P27
Input port P2
I
P30 to P37
Input port P3
I
P40 to P47
Input port P4
I
P51 to P54,
P56, P57
Input port P5
I
P50
CE input
I
P55
EPM input
I
P60 to P63
Input port P6
I
P64
BUSY output
O
Standard serial mode 1: BUSY signal output pin
Standard serial mode 2: Monitors the program operation check
P65
SCLK input
I
Standard serial mode 1: Serial clock input pin
Standard serial mode 2: Input "L" level signal.
P66
RxD input
I
P67
TxD output
O
P70 to P77
Input port P7
I
P80 to P84, P86,
P87
Input port P8
I
P85
NMI input
I
P90 to P97
Input port P9
I
P100 to P107
Input port P10
I
P110 to P114
Input port P11
I
P120 to P127
Input port P12
I
P130 to P137
Input port P13
I
P140 to P146
Input port P14
I
P150 to P157
Input port P15
I
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open.
Input "H" level signal.
Input "L" level signal.
Input "H" or "L" level signal or open.
Serial data input pin
Serial data output pin. When using standard serial mode 1, an
"L" level must be input to TxD pin while the RESET pin is “L”.
For this reason, this pin should be pulled down. After being reset,
this pin functions as a data output pin. Thus adjust pull-down
resistance value with the system not to affect data transfer.
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open.
Connect this pin to Vcc.
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open.
Input "H" or "L" level signal or open. (Note)
Input "H" or "L" level signal or open. (Note)
Input "H" or "L" level signal or open. (Note)
Input "H" or "L" level signal or open. (Note)
Input "H" or "L" level signal or open. (Note)
Note: Port P11 to P15 exist in 144-pin version.
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Mitsubishi Microcomputers
Standard Serial I/O Mode (Flash Memory Version)
Mode setting
Signal
CNVss
EPM
RESET
CE
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Value
Vcc
Vss
Vss >> Vcc
Vcc
81
82
83
84
85
86
87
88
89
90
91
92
Connect
oscillation
circuit
M32C/83(100-pin) Group
Flash Memory Version
(100P6S)
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
SCLK
TxD
402
CE
EPM
BUSY
RxD
Vss
Vcc
Figure 1.35.1. Pin connections for standard serial I/O mode (1)
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30
RESET
93
94
95
96
97
98
99
100
CNVss
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Mitsubishi Microcomputers
Standard Serial I/O Mode (Flash Memory Version)
Mode setting
Signal
CNVss
EPM
RESET
CE
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Value
Vcc
Vss
Vss >> Vcc
Vcc
Connect
oscillation
circuit
M32C/83(100-pin) Group
Flash Memory Version
(100P6Q)
75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25
RESET
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
CNVSS
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
CE
BUSY
RX
D
VSS
VCC
EPM
SCLK
TX
D
Figure 1.35.2. Pin connections for standard serial I/O mode (2)
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Standard Serial I/O Mode (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Mode setting
Signal
Value
CNVss
Vcc
EPM
Vss
RESET
CE
Vss >> Vcc
Vcc
108 107 106 105 104 103 102 101 100
99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73
109
110
72
71
111
112
70
69
113
68
67
114
115
66
65
116
117
CE
64
118
119
63
62
120
121
61
60
122
123
59
58
M32C/83(144-pin) Group
Flash Memory Version
(144P6Q)
124
125
126
127
128
129
130
57
56
55
54
52
51
131
132
50
49
133
134
48
47
135
46
45
136
137
EPM
53
44
43
138
139
BUSY
42
SCLK
140
141
41
40
RxD
142
143
39
38
TxD
144
37
1
2
3
4
5
6
7
8
9
10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36
VCC
VSS
Connect
oscillation
circuit
RESET
CNVSS
Figure 1.35.3. Pin connections for standard serial I/O mode (3)
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Overview of standard serial I/O mode 1 (clock synchronized)
In standard serial I/O mode 1, software commands, addresses and data are input and output between the
MCU and peripheral units (serial programer, etc.) using 4-wire clock-synchronized serial I/O (UART1).
Standard serial I/O mode 1 is engaged by releasing the reset with the P65 (CLK1) pin "H" level.
In reception, software commands, addresses and program data are synchronized with the rise of the transfer clock that is input to the CLK1 pin, and are then input to the MCU via the RxD1 pin. In transmission, the
read data and status are synchronized with the fall of the transfer clock, and output from the TxD1 pin.
The TxD1 pin is for CMOS output. Transfer is in 8-bit units with LSB first.
When busy, such as during transmission, reception, erasing or program execution, the RTS1 (BUSY) pin is
"H" level. Accordingly, always start the next transfer after the RST1 (BUSY) pin is "L" level.
Also, data and status registers in memory can be read after inputting software commands. Status, such as
the operating state of the flash memory or whether a program or erase operation ended successfully or not,
can be checked by reading the status register. Here following are explained software commands, status
registers, etc.
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Software Commands
Table 1.35.1 lists software commands. In the standard serial I/O mode 1, erase operations, programs and
reading are controlled by transferring software commands via the RxD1 pin. Software commands are
explained here below.
Table 1.35.1. Software commands (Standard serial I/O mode 1)
Control command
1st byte
transfer
2nd byte
3rd byte
4th byte 5th byte 6th byte
1
Page read
FF16
Address
(middle)
Address
(high)
Data
output
Data
output
Data
output
Data
output to
259th byte
2
Page program
4116
Address
(middle)
Address
(high)
Data
input
Data
input
Data
input
Data input
to 259th
byte
3
Block erase
2016
Address
(high)
D016
4
Erase all unlocked blocks
A716
Address
(middle)
D016
5
Read status register
7016
SRD
output
SRD1
output
6
Clear status register
5016
7
Read lock bit status
7116
Address
(middle)
Address
(high)
Lock bit
data
output
8
Lock bit program
7716
Address
(middle)
Address
(high)
D016
9
Lock bit enable
7A16
10 Lock bit disable
7516
Address
(high)
Checksum
F516
Address
(low)
12 Download function
Address
(middle)
Size
FA16 Size (low)
(high)
13 Version data output function
FB16
Version
data
output
Version
data
output
Version
data
output
14 Boot ROM area output
function
FC16
Address
(middle)
Address
(high)
Data
output
15 Read check data
Check
FD16 data (low)
11 Code processing function
Check
data
(high)
When ID is
not verified
Not
acceptable
Not
acceptable
Not
acceptable
Not
acceptable
Acceptable
Not
acceptable
Not
acceptable
Not
acceptable
Not
acceptable
Not
acceptable
ID size
ID1
To
Data required
input number
of times
Version Version
data
data
output output
Data
output
Data
output
To ID7
Version
data
output to
9th byte
Data
output to
259th
byte
Acceptable
Not
acceptable
Acceptable
Not
acceptable
Not
acceptable
Note 1: Shading indicates transfer from flash memory microcomputer to peripheral unit. All other data is transferred from the peripheral unit to the flash memory microcomputer.
Note 2: SRD refers to status register data. SRD1 refers to status register data1 .
Note 3: All commands can be accepted when the flash memory is totally blank.
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Page Read Command
This command reads the specified page (256 bytes) in the flash memory sequentially one byte at a
time. Execute the page read command as explained here following.
(1) Transfer the “FF16” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) From the 4th byte onward, data (D0–D7) for the page (256 bytes) specified with addresses A8 to
A23 will be output sequentially from the smallest address first in sync with the rise of the clock.
CLK1
RxD1
(M32C reception data)
TxD1
(M32C transmit data)
FF16
A8 to
A15
A16 to
A23
data0
data255
RTS1(BUSY)
Figure 1.35.4. Timing for page read
Page Program Command
This command writes the specified page (256 bytes) in the flash memory sequentially one byte at a
time. Execute the page program command as explained here following.
(1) Transfer the “4116” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) From the 4th byte onward, as write data (D0–D7) for the page (256 bytes) specified with addresses
A8 to A23 is input sequentially from the smallest address first, that page is automatically written.
When reception setup for the next 256 bytes ends, the RTS1 (BUSY) signal changes from the “H” to
the “L” level. The result of the page program can be known by reading the status register. For more
information, see the section on the status register.
Each block can be write-protected with the lock bit. For more information, see the section on the data
protection function. Additional writing is not allowed with already programmed pages.
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CLK1
RxD1
(M32C reception data)
4116
A8 to
A15
A16 to
A23
data0
data255
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.5. Timing for the page program
Block Erase Command
This command erases the data in the specified block. Execute the block erase command as explained
here following.
(1) Transfer the “2016” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) Transfer the verify command code “D016” with the 4th byte. With the verify command code, the
erase operation will start for the specified block in the flash memory. Write the highest address of
the specified block for addresses A16 to A23.
When block erasing ends, the RTS1 (BUSY) signal changes from the “H” to the “L” level. After block
erase ends, the result of the block erase operation can be known by reading the status register. For
more information, see the section on the status register.
Each block can be erase-protected with the lock bit. For more information, see the section on the data
protection function.
CLK1
RxD1
(M32C reception data)
2016
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.6. Timing for block erasing
408
A8 to
A15
A16 to
A23
D016
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Erase All Unlocked Blocks Command
This command erases the content of all blocks. Execute the erase all unlocked blocks command as
explained here following.
(1) Transfer the “A716” command code with the 1st byte.
(2) Transfer the verify command code “D016” with the 2nd byte. With the verify command code, the
erase operation will start and continue for all blocks in the flash memory.
When block erasing ends, the RTS1 (BUSY) signal changes from the “H” to the “L” level. The result of the
erase operation can be known by reading the status register. Each block can be erase-protected with the
lock bit. For more information, see the section on the data protection function.
CLK1
RxD1
(M32C reception data)
A716
D016
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.7. Timing for erasing all unlocked blocks
Read Status Register Command
This command reads status information. When the “7016” command code is sent with the 1st byte, the
contents of the status register (SRD) specified with the 2nd byte and the contents of status register 1
(SRD1) specified with the 3rd byte are read.
CLK1
RxD1
(M32C reception data)
7016
TxD1
(M32C transmit data)
SRD
output
SRD1
output
RTS1(BUSY)
Figure 1.35.8. Timing for reading the status register
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Clear Status Register Command
This command clears the bits (SR3–SR5) which are set when the status register operation ends in
error. When the “5016” command code is sent with the 1st byte, the aforementioned bits are cleared.
When the clear status register operation ends, the RTS1 (BUSY) signal changes from the “H” to the “L”
level.
CLK1
RxD1
(M32C reception data)
5016
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.9. Timing for clearing the status register
Read Lock Bit Status Command
This command reads the lock bit status of the specified block. Execute the read lock bit status command as explained here following.
(1) Transfer the “7116” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) The lock bit data of the specified block is output with the 4th byte. The 6th bit (D6) of output data
is the lock bit data. Write the highest address of the specified block for addresses A8 to A23.
CLK1
RxD1
(M32C reception data)
7116
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.10. Timing for reading lock bit status
410
A8 to
A15
A16 to
A23
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Lock Bit Program Command
This command writes “0” (lock) for the lock bit of the specified block. Execute the lock bit program
command as explained here following.
(1) Transfer the “7716” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) Transfer the verify command code “D016” with the 4th byte. With the verify command code, “0” is
written for the lock bit of the specified block. Write the highest address of the specified block for
addresses A8 to A23.
When writing ends, the RTS1 (BUSY) signal changes from the “H” to the “L” level. Lock bit status can
be read with the read lock bit status command. For information on the lock bit function, reset procedure and so on, see the section on the data protection function.
CLK1
RxD1
(M32C reception data)
7716
A8 to
A15
A16 to
A23
D016
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.11. Timing for the lock bit program
Lock Bit Enable Command
This command enables the lock bit in blocks whose bit was disabled with the lock bit disable command. The command code “7A16” is sent with the 1st byte of the serial transmission. This command
only enables the lock bit function; it does not set the lock bit itself.
CLK1
RxD1
(M32C reception data)
7A16
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.12. Timing for enabling the lock bit
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Lock Bit Disable Command
This command disables the lock bit. The command code “7516” is sent with the 1st byte of the serial
transmission. This command only disables the lock bit function; it does not set the lock bit itself.
However, if an erase command is executed after executing the lock bit disable command, “0” (locked)
lock bit data is set to “1” (unlocked) after the erase operation ends. In any case, after the reset is
cancelled, the lock bit is enabled.
CLK1
RxD1
(M32C reception data)
7516
TxD1
(M32C transmit data)
RTS1(BUSY)
Figure 1.35.13. Timing for disabling the lock bit
ID Check
This command checks the ID code. Execute the boot ID check command as explained here following.
(1) Transfer the “F516” command code with the 1st byte.
(2) Transfer addresses A0 to A7, A8 to A15 and A16 to A23 of the 1st byte of the ID code with the 2nd,
3rd and 4th bytes respectively.
(3) Transfer the number of data sets of the ID code with the 5th byte.
(4) The ID code is sent with the 6th byte onward, starting with the 1st byte of the code.
CLK1
RxD1
(M32C reception
data)
F516
DF16
TxD1
(M32C transmit
data)
RTS1(BUSY)
Figure 1.35.14. Timing for the ID check
412
FF16
0F16
ID size
ID1
ID7
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Download Command
This command downloads a program to the RAM for execution. Execute the download command as
explained here following.
(1) Transfer the “FA16” command code with the 1st byte.
(2) Transfer the program size with the 2nd and 3rd bytes.
(3) Transfer the check sum with the 4th byte. The check sum is added to all data sent with the 5th
byte onward.
(4) The program to execute is sent with the 5th byte onward.
When all data has been transmitted, if the check sum matches, the downloaded program is executed.
The size of the program will vary according to the internal RAM.
CLK1
RxD1
(M32C reception data)
Check
sum
FA16
Program
data
Program
data
Data size (low)
TxD1
(M32C transmit data)
Data size (high)
RTS1(BUSY)
Figure 1.35.15. Timing for download
Version Information Output Command
This command outputs the version information of the control program stored in the boot area. Execute
the version information output command as explained here following.
(1) Transfer the “FB16” command code with the 1st byte.
(2) The version information will be output from the 2nd byte onward. This data is composed of 8
ASCII code characters.
CLK1
RxD1
(M32C reception data)
TxD1
(M32C transmit data)
FB16
'V'
'E'
'R'
'X'
RTS1(BUSY)
Figure 1.35.16. Timing for version information output
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Boot ROM Area Output Command
This command outputs the control program stored in the boot ROM area in one page blocks (256
bytes). Execute the boot ROM area output command as explained here following.
(1) Transfer the “FC16” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) From the 4th byte onward, data (D0–D7) for the page (256 bytes) specified with addresses A8 to
A23 will be output sequentially from the smallest address first, in sync with the rise of the clock.
CLK1
RxD1
(M32C reception data)
FC16
A8 to
A15
TxD1
(M32C transmit data)
A16 to
A23
data0
data255
RTS1(BUSY)
Figure 1.35.17. Timing for boot ROM area output
Read Check Data
This command reads the check data that confirms that the write data, which was sent with the page
program command, was successfully received.
(1) Transfer the "FD16" command code with the 1st byte.
(2) The check data (low) is received with the 2nd byte and the check data (high) with the 3rd.
To use this read check data command, first execute the command and then initialize the check data.
Next, execute the page program command the required number of times. After that, when the read
check command is executed again, the check data for all of the read data that was sent with the page
program command during this time is read. The check data is the result of CRC operation of write
data.
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
CLK1
RxD1
(M32C reception data)
FD16
TxD1
(M32C transmit data)
Check data (low)
Check data (high)
RTS1(BUSY)
Figure 1.35.18. Timing for the read check data
ID Code
When the flash memory is not blank, the ID code sent from the peripheral units and the ID code written
in the flash memory are compared to see if they match. If the codes do not match, the command sent
from the peripheral units is not accepted. An ID code contains 8 bits of data. Area is, from the 1st byte,
addresses 0FFFFDF 16, 0FFFFE3 16, 0FFFFEB 16 , 0FFFFEF 16, 0FFFFF3 16 , 0FFFFF7 16 and
0FFFFFB16. Write a program into the flash memory, which already has the ID code set for these
addresses.
Address
0FFFFDC16 to 0FFFFDF16
ID1 Undefined instruction vector
0FFFFE016 to 0FFFFE316
ID2 Overflow vector
0FFFFE416 to 0FFFFE716
BRK instruction vector
0FFFFE816 to 0FFFFEB16
ID3 Address match vector
0FFFFEC16 to 0FFFFEF16
ID4
0FFFFF016 to 0FFFFF316
ID5 Watchdog timer vector
0FFFFF416 to 0FFFFF716
ID6
0FFFFF816 to 0FFFFFB16
ID7
0FFFFFC16 to 0FFFFFF16
NMI vector
Reset vector
4 bytes
Figure 1.35.19. ID code storage addresses
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Data Protection (Block Lock)
Each of the blocks in Figure 1.35.20 have a nonvolatile lock bit that specifies protection (block lock)
against erasing/writing. A block is locked (writing “0” for the lock bit) with the lock bit program command.
Also, the lock bit of any block can be read with the read lock bit status command.
Block lock disable/enable is determined by the status of the lock bit itself and execution status of the lock
bit disable and lock enable bit commands.
(1) After the reset has been cancelled and the lock bit enable command executed, the specified block
can be locked/unlocked using the lock bit (lock bit data). Blocks with a “0” lock bit data are locked
and cannot be erased or written in. On the other hand, blocks with a “1” lock bit data are unlocked
and can be erased or written in.
(2) After the lock bit enable command has been executed, all blocks are unlocked regardless of lock bit
data status and can be erased or written in. In this case, lock bit data that was “0” before the block
was erased is set to “1” (unlocked) after erasing, therefore the block is actually unlocked with the
lock bit.
0F8000016
Block 10 : 64K bytes
0F9000016
Block 9 : 64K bytes
0FA000016
Block 8 : 64K bytes
0FB000016
Block 7 : 64K bytes
0FC000016
Block 6 : 64K bytes
0FD000016
0FE000016
Block 5 : 64K bytes
Block 4 : 64K bytes
0FF000016
Block 3 : 32K bytes
0FF800016
0FFA00016
0FFC00016
Block 2 : 8K bytes
Block 1 : 8K bytes
Block 0 : 16K bytes
0FFFFFF16
User ROM area
Figure 1.35.20. Blocks in the user area
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Status Register (SRD)
The status register indicates operating status of the flash memory and status such as whether an erase
operation or a program ended successfully or in error. It can be read by writing the read status register
command (7016). Also, the status register is cleared by writing the clear status register command (5016).
Table 1.35.2 gives the definition of each status register bit. After clearing the reset, the status register
outputs “8016”.
Table 1.35.2. Status register (SRD)
Definition
SRD bits
Status name
"1"
SR0 (bit0)
Reserved
-
-
SR1 (bit1)
Reserved
-
-
SR2 (bit2)
Reserved
-
-
SR3 (bit3)
Block status after program
Terminated in error
Terminated normally
SR4 (bit4)
Program status
Terminated in error
Terminated normally
SR5 (bit5)
Erase status
Terminated in error
Terminated normally
SR6 (bit6)
Reserved
-
Busy
SR7 (bit7)
Write state machine (WSM) status
Ready
-
"0"
Program Status After Program (SR3)
If excessive data is written (phenomenon whereby the memory cell becomes depressed which results
in data not being read correctly), “1” is set for the program status after-program at the end of the page
write operation. In other words, when writing ends successfully, “8016” is output; when writing fails,
“9016” is output; and when excessive data is written, “8816” is output.
If “1” is written for any of the SR5, SR4 or SR3 bits, the page program, block erase, erase all unlocked
blocks and lock bit program commands are not accepted. Before executing these commands, execute
the clear status register command (5016) and clear the status register.
Program Status (SR4)
The program status reports the operating status of the auto write operation. If a write error occurs, it is
set to “1”. When the program status is cleared, it is set to “0”.
Erase Status (SR5)
The erase status reports the operating status of the auto erase operation. If an erase error occurs, it is
set to “1”. When the erase status is cleared, it is set to “0”.
Write State Machine (WSM) Status (SR7)
The write state machine (WSM) status indicates the operating status of the flash memory. When
power is turned on, “1” (ready) is set for it. The bit is set to “0” (busy) during an auto write or auto erase
operation, but it is set back to “1” when the operation ends.
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Status Register 1 (SRD1)
Status register 1 indicates the status of serial communications, results from ID checks and results from
check sum comparisons. It can be read after the SRD by writing the read status register command (7016).
Also, status register 1 is cleared by writing the clear status register command (5016).
Table 1.35.3 gives the definition of each status register 1 bit. “0016” is output when power is turned ON
and the flag status is maintained even after the reset.
Table 1.35.3. Status register 1 (SRD1)
Definition
SRD1 bits
Status name
"1"
"0"
SR8 (bit0)
Reserved
-
-
SR9 (bit1)
Data receive time out
Time out
Normal operation
SR10 (bit2)
ID check completed bits
00
01
10
11
SR12 (bit4)
Checksum match bit
Match
Mismatch
SR13 (bit5)
Reserved
-
-
SR14 (bit6)
Reserved
-
-
SR15 (bit7)
Boot update completed bit
Update completed
Not update
SR11 (bit3)
Not verified
Verification mismatch
Reserved
Verified
Data Reception Time Out (SR9)
This flag indicates when a time out error is generated during data reception. If this flag is attached
during data reception, the received data is discarded and the microcomputer returns to the command
wait state.
ID Check Completed Bits (SR11 and SR10)
These flags indicate the result of ID checks. Some commands cannot be accepted without an ID
check.
Check Sum Consistency Bit (SR12)
This flag indicates whether the check sum matches or not when a program, is downloaded for execution using the download function.
Boot Update Completed Bit (SR15)
This flag indicates whether the control program was downloaded to the RAM or not, using the download function.
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Appendix Standard Serial I/O Mode 1 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Full Status Check
Results from executed erase and program operations can be known by running a full status check. Figure
1.35.21 shows a flowchart of the full status check and explains how to remedy errors which occur.
Read status register
SR4=1 and SR5
=1 ?
YES
Command
sequence error
Execute the clear status register command (5016)
to clear the status register. Try performing the
operation one more time after confirming that the
command is entered correctly.
Block erase error
Should a block erase error occur, the block in error
cannot be used.
NO
SR5=0?
NO
YES
SR4=0?
NO
Execute the read lock bit status command (7116) to
see if the block is locked. After removing lock,
execute write operation in the same way. If the
error still occurs, the page in error cannot be used.
Program error (page
or lock bit)
YES
SR3=0?
NO
YES
Program error
(block)
After erasing the block in error, execute write
operation one more time. If the same error still
occurs, the block in error cannot be used.
End (block erase, program)
Note: When one of SR5 to SR3 is set to 1, none of the page program, block erase, erase all unlock
blocks and lock bit program commands is accepted. Execute the clear status register command
(5016) before executing these commands.
Figure 1.35.21. Full status check flowchart and remedial procedure for errors
Example Circuit Application for The Standard Serial I/O Mode 1
The below figure shows a circuit application for the standard serial I/O mode 1. Control pins will vary
according to peripheral unit (programmer), therefore see the peripheral unit (programmer) manual for
more information.
Clock input
Data output
CLK1
TXD1
M32C/83
Flash memory version
BUSY output
Data input
RTS1(BUSY)
CNVss
RXD1
P50(CE)
P55(EPM)
NMI
(1) Control pins and external circuitry will vary according to peripheral unit (programmer). For more
information, see the peripheral unit (programmer) manual.
(2) In this example, the microprocessor mode and standard serial I/O mode are switched via a switch.
Figure 1.35.22. Example circuit application for the standard serial I/O mode 1
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Overview of standard serial I/O mode 2 (clock asynchronized)
In standard serial I/O mode 2, software commands, addresses and data are input and output between the
MCU and peripheral units (serial programer, etc.) using 2-wire clock-asynchronized serial I/O (UART1).
Standard serial I/O mode 2 is engaged by releasing the reset with the P65 (CLK1) pin "L" level.
The TxD1 pin is for CMOS output. Data transfer is in 8-bit units with LSB first, 1 stop bit and parity OFF.
After the reset is released, connections can be established at 9,600 bps when initial communications (Figure 1.35.23) are made with a peripheral unit. However, this requires a main clock with a minimum 2 MHz
input oscillation frequency. Baud rate can be changed from 9,600 bps to 19,200, 38,400, 57,600 or 115,200
bps by executing software commands. However, communication errors may occur because of the oscillation frequency of the main clock. If errors occur, change the main clock's oscillation frequency and the baud
rate.
After executing commands from a peripheral unit that requires time to erase and write data, as with erase
and program commands, allow a sufficient time interval or execute the read status command and check
how processing ended, before executing the next command.
Data and status registers in memory can be read after transmitting software commands. Status, such as
the operating state of the flash memory or whether a program or erase operation ended successfully or not,
can be checked by reading the status register. Here following are explained initial communications with
peripheral units, how frequency is identified and software commands.
Initial communications with peripheral units
After the reset is released, the bit rate generator is adjusted to 9,600 bps to match the oscillation frequency of the main clock, by sending the code as prescribed by the protocol for initial communications
with peripheral units (Figure 1.35.23).
(1) Transmit "0016" from a peripheral unit 16 times. (The MCU with internal flash memory sets the bit
rate generator so that "0016" can be successfully received.)
(2) The MCU with internal flash memory outputs the "B016" check code and initial communications end
successfully *1. Initial communications must be transmitted at a speed of 9,600 bps and a transfer
interval of a minimum 15 ms. Also, the baud rate at the end of initial communications is 9,600 bps.
*1. If the peripheral unit cannot receive "B016" successfully, change the oscillation frequency of the main
clock.
MCU with internal
flash memory
Peripheral unit
Reset
(1) Transfer "0016" 16 times
At least 15ms
transfer interval
1st
"0016"
2nd
"0016"
15 th
"0016"
16th
"0016"
"B016"
(2) Transfer check code "B016"
The bit rate generator setting completes (9600bps)
Figure 1.35.23. Peripheral unit and initial communication
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
How frequency is identified
When "0016" data is received 16 times from a peripheral unit at a baud rate of 9,600 bps, the value of the
bit rate generator is set to match the operating frequency (2 - 30 MHz). The highest speed is taken from
the first 8 transmissions and the lowest from the last 8. These values are then used to calculate the bit
rate generator value for a baud rate of 9,600 bps.
Baud rate cannot be attained with some operating frequencies. Table 1.35.4 gives the operation frequency and the baud rate that can be attained for.
Table 1.35.4 Operation frequency and the baud rate
Operation frequency
(MHZ)
Baud rate
9,600bps
Baud rate
19,200bps
Baud rate
38,400bps
Baud rate
57,600bps
Baud rate
115,200bps
30MHz
√
√
√
√
–
20MHz
√
√
√
√
√
16MHZ
√
√
√
√
–
12MHZ
√
√
√
√
–
11MHZ
√
√
√
√
–
10MHZ
√
√
√
√
–
8MHZ
√
√
√
√
–
7.3728MHZ
√
√
√
√
–
6MHZ
√
√
√
–
–
5MHZ
√
√
√
–
–
4.5MHZ
√
√
√
√
–
4.194304MHZ
√
√
√
–
–
4MHZ
√
√
–
–
–
3.58MHZ
√
√
√
√
–
3MHZ
√
√
√
–
–
2MHZ
√
–
–
–
–
√ : Communications possible
– : Communications not possible
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Software Commands
Table 1.35.5 lists software commands. In the standard serial I/O mode 2, erase operations, programs and
reading are controlled by transferring software commands via the RxD1 pin. Standard serial I/O mode 2
adds five transmission speed commands - 9,600, 19,200, 38,400, 57,600 and 115,200 bps - to the software commands of standard serial I/O mode 1. Software commands are explained here below.
Table 1.35.5. Software commands (Standard serial I/O mode 2)
Control command
1st byte
transfer
2nd byte
3rd byte
4th byte 5th byte 6th byte
1
Page read
FF16
Address
(middle)
Address
(high)
Data
output
Data
output
Data
output
2
Page program
4116
Address
(middle)
Address
(high)
Data
input
Data
input
Data
input
3
Block erase
2016
Address
(high)
D016
4
Erase all unlocked blocks
A716
Address
(middle)
D016
5
Read status register
7016
SRD
output
SRD1
output
6
Clear status register
5016
7
Read lock bit status
7116
Address
(middle)
Address
(high)
8
Lock bit program
7716
Address
(middle)
Address
(high)
9
Lock bit enable
7A16
10 Lock bit disable
7516
Address
(low)
12 Download function
Address
(middle)
Size
FA16 Size (low)
(high)
13 Version data output function
FB16
Version
data
output
Version
data
output
Version
data
output
14 Boot ROM area output
function
FC16
Address
(middle)
Address
(high)
Data
output
Address
(high)
Checksum
Not
acceptable
Not
acceptable
Not
acceptable
Acceptable
Not
acceptable
Not
acceptable
Lock bit
data
output
D016
F516
11 Code processing function
Data
output to
259th byte
Data input
to 259th
byte
When ID is
not verified
Not
acceptable
Not
acceptable
Not
acceptable
Not
acceptable
ID size
ID1
To
Data required
input number
of times
Version Version
data
data
output output
Data
output
Data
output
To ID7
Version
data
output to
9th byte
Data
output to
259th byte
Acceptable
Not
acceptable
Acceptable
Not
acceptable
15 Read check data
Check
FD16 data (low)
16 Baud rate 9600
B016
B016
Acceptable
17 Baud rate 19200
B116
B116
Acceptable
18 Baud rate 38400
B216
B216
Acceptable
19 Baud rate 57600
B316
B316
Acceptable
20 Baud rate 115200
B416
B416
Acceptable
Check
data
(high)
Not
acceptable
Note 1: Shading indicates transfer from flash memory microcomputer to peripheral unit. All other data is transferred from the peripheral unit to the flash memory microcomputer.
Note 2: SRD refers to status register data. SRD1 refers to status register data 1.
Note 3: All commands can be accepted when the flash memory is totally blank.
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Page Read Command
This command reads the specified page (256 bytes) in the flash memory sequentially one byte at a
time. Execute the page read command as explained here following.
(1) Transfer the “FF16” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) From the 4th byte onward, data (D0–D7) for the page (256 bytes) specified with addresses A8 to
A23 will be output sequentially from the smallest address first in sync with the rise of the clock.
RxD1
(M32C reception data)
A8 to
A15
FF16
A16 to
A23
TxD1
(M32C transmit data)
data0
data255
Figure 1.35.24. Timing for page read
Page Program Command
This command writes the specified page (256 bytes) in the flash memory sequentially one byte at a
time. Execute the page program command as explained here following.
(1) Transfer the “4116” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) From the 4th byte onward, as write data (D0–D7) for the page (256 bytes) specified with addresses
A8 to A23 is input sequentially from the smallest address first, that page is automatically written.
The result of the page program can be known by reading the status register. For more information, see
the section on the status register.
Each block can be write-protected with the lock bit. For more information, see the section on the data
protection function. Additional writing is not allowed with already programmed pages.
RxD1
(M32C reception data)
4116
A8 to
A15
A16 to
A23
data0
data255
TxD1
(M32C transmit data)
Figure 1.35.25. Timing for the page program
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Block Erase Command
This command erases the data in the specified block. Execute the block erase command as explained
here following.
(1) Transfer the “2016” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) Transfer the verify command code “D016” with the 4th byte. With the verify command code, the
erase operation will start for the specified block in the flash memory. Write the highest address of
the specified block for addresses A16 to A23.
After block erase ends, the result of the block erase operation can be known by reading the status
register. For more information, see the section on the status register.
Each block can be erase-protected with the lock bit. For more information, see the section on the data
protection function.
RxD1
(M32C reception data)
2016
A8 to
A15
A16 to
A23
D016
TxD1
(M32C transmit data)
Figure 1.35.26. Timing for block erasing
Erase All Unlocked Blocks Command
This command erases the content of all blocks. Execute the erase all unlocked blocks command as
explained here following.
(1) Transfer the “A716” command code with the 1st byte.
(2) Transfer the verify command code “D016” with the 2nd byte. With the verify command code, the
erase operation will start and continue for all blocks in the flash memory.
The result of the erase operation can be known by reading the status register. Each block can be eraseprotected with the lock bit. For more information, see the section on the data protection function.
RxD1
(M32C reception data)
A716
TxD1
(M32C transmit data)
Figure 1.35.27. Timing for erasing all unlocked blocks
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Read Status Register Command
This command reads status information. When the “7016” command code is sent with the 1st byte, the
contents of the status register (SRD) specified with the 2nd byte and the contents of status register 1
(SRD1) specified with the 3rd byte are read.
RxD1
(M32C reception data)
7016
SRD
output
TxD1
(M32C transmit data)
SRD1
output
Figure 1.35.28. Timing for reading the status register
Clear Status Register Command
This command clears the bits (SR3–SR5) which are set when the status register operation ends in
error. When the “5016” command code is sent with the 1st byte, the aforementioned bits are cleared.
RxD1
(M32C reception data)
5016
TxD1
(M32C transmit data)
Figure 1.35.29. Timing for clearing the status register
Read Lock Bit Status Command
This command reads the lock bit status of the specified block. Execute the read lock bit status command as explained here following.
(1) Transfer the “7116” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) The lock bit data of the specified block is output with the 4th byte. The 6th bit (D6) of output data
is the lock bit data. Write the highest address of the specified block for addresses A8 to A23.
RxD1
(M32C reception data)
7116
TxD1
(M32C transmit data)
A8 to
A15
A16 to
A23
DQ6
Figure 1.35.30. Timing for reading lock bit status
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Lock Bit Program Command
This command writes “0” (lock) for the lock bit of the specified block. Execute the lock bit program
command as explained here following.
(1) Transfer the “7716” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) Transfer the verify command code “D016” with the 4th byte. With the verify command code, “0” is
written for the lock bit of the specified block. Write the highest address of the specified block for
addresses A8 to A23.
Lock bit status can be read with the read lock bit status command. For information on the lock bit
function, reset procedure and so on, see the section on the data protection function.
RxD1
(M32C reception data)
7716
A8 to
A15
A16 to
A23
D016
TxD1
(M32C transmit data)
Figure 1.35.31. Timing for the lock bit program
Lock Bit Enable Command
This command enables the lock bit in blocks whose bit was disabled with the lock bit disable command. The command code “7A16” is sent with the 1st byte of the serial transmission. This command
only enables the lock bit function; it does not set the lock bit itself.
RxD1
(M32C reception data)
TxD1
(M32C transmit data)
Figure 1.35.32. Timing for enabling the lock bit
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Lock Bit Disable Command
This command disables the lock bit. The command code “7516” is sent with the 1st byte of the serial
transmission. This command only disables the lock bit function; it does not set the lock bit itself.
However, if an erase command is executed after executing the lock bit disable command, “0” (locked)
lock bit data is set to “1” (unlocked) after the erase operation ends. In any case, after the reset is
cancelled, the lock bit is enabled.
RxD1
(M32C reception data)
7516
TxD1
(M32C transmit data)
Figure 1.35.33. Timing for disabling the lock bit
ID Check
This command checks the ID code. Execute the boot ID check command as explained here following.
(1) Transfer the “F516” command code with the 1st byte.
(2) Transfer addresses A0 to A7, A8 to A15 and A16 to A23 of the 1st byte of the ID code with the 2nd,
3rd and 4th bytes respectively.
(3) Transfer the number of data sets of the ID code with the 5th byte.
(4) The ID code is sent with the 6th byte onward, starting with the 1st byte of the code.
RxD1
(M32C reception
data)
F516
DF16
FF16
0F16
ID size
ID1
ID7
TxD1
(M32C transmit
data)
Figure 1.35.34. Timing for the ID check
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Download Command
This command downloads a program to the RAM for execution. Execute the download command as
explained here following.
(1) Transfer the “FA16” command code with the 1st byte.
(2) Transfer the program size with the 2nd and 3rd bytes.
(3) Transfer the check sum with the 4th byte. The check sum is added to all data sent with the 5th
byte onward.
(4) The program to execute is sent with the 5th byte onward.
When all data has been transmitted, if the check sum matches, the downloaded program is executed.
The size of the program will vary according to the internal RAM.
RxD1
(M32C reception data)
Check
sum
FA16
Program
data
Program
data
Data size (low)
TxD1
(M32C transmit data)
Data size (high)
Figure 1.35.35. Timing for download
Version Information Output Command
This command outputs the version information of the control program stored in the boot area. Execute
the version information output command as explained here following.
(1) Transfer the “FB16” command code with the 1st byte.
(2) The version information will be output from the 2nd byte onward. This data is composed of 8
ASCII code characters.
RxD1
(M32C reception data)
TxD1
(M32C transmit data)
FB16
'V'
Figure 1.35.36. Timing for version information output
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'R'
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Boot ROM Area Output Command
This command outputs the control program stored in the boot ROM area in one page blocks (256
bytes). Execute the boot ROM area output command as explained here following.
(1) Transfer the “FC16” command code with the 1st byte.
(2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively.
(3) From the 4th byte onward, data (D0–D7) for the page (256 bytes) specified with addresses A8 to
A23 will be output sequentially from the smallest address first, in sync with the rise of the clock.
CLK1
RxD1
(M32C reception data)
FC16
A8 to
A15
A16 to
A23
TxD1
(M32C transmit data)
data0
data255
RTS1(BUSY)
Figure 1.35.37. Timing for boot ROM area output
Read Check Data
This command reads the check data that confirms that the write data, which was sent with the page
program command, was successfully received.
(1) Transfer the "FD16" command code with the 1st byte.
(2) The check data (low) is received with the 2nd byte and the check data (high) with the 3rd.
To use this read check data command, first execute the command and then initialize the check data.
Next, execute the page program command the required number of times. After that, when the read
check command is executed again, the check data for all of the read data that was sent with the page
program command during this time is read. The check data is the result of CRC operation of write
data.
RxD1
(M32C reception data)
FD16
TxD1
(M32C transmit data)
Check data (low)
Check data (high)
Figure 1.35.38. Timing for the read check data
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Baud Rate 9600
This command changes baud rate to 9,600 bps. Execute it as follows.
(1) Transfer the "B016" command code with the 1st byte.
(2) After the "B016" check code is output with the 2nd byte, change the baud rate to 9,600 bps.
RxD1
(M32C reception data)
B016
TxD1
(M32C transmit data)
B016
Figure 1.35.39. Timing of baud rate 9600
Baud Rate 19200
This command changes baud rate to 19,200 bps. Execute it as follows.
(1) Transfer the "B116" command code with the 1st byte.
(2) After the "B116" check code is output with the 2nd byte, change the baud rate to 19,200 bps.
RxD1
(M32C reception data)
B116
TxD1
(M32C transmit data)
B116
Figure 1.35.40. Timing of baud rate 19200
Baud Rate 38400
This command changes baud rate to 38,400 bps. Execute it as follows.
(1) Transfer the "B216" command code with the 1st byte.
(2) After the "B216" check code is output with the 2nd byte, change the baud rate to 38,400 bps.
RxD1
(M32C reception data)
B216
TxD1
(M32C transmit data)
Figure 1.35.41. Timing of baud rate 38400
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
Mitsubishi Microcomputers
M32C/83 group
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Baud Rate 57600
This command changes baud rate to 57,600 bps. Execute it as follows.
(1) Transfer the "B316" command code with the 1st byte.
(2) After the "B316" check code is output with the 2nd byte, change the baud rate to 57,600 bps.
RxD1
(M32C reception data)
B316
TxD1
(M32C transmit data)
B316
Figure 1.35.42. Timing of baud rate 57600
Baud Rate 115200
This command changes baud rate to 115,200 bps. Execute it as follows.
(1) Transfer the "B416" command code with the 1st byte.
(2) After the "B416" check code is output with the 2nd byte, change the baud rate to 19,200 bps.
RxD1
(M32C reception data)
B416
TxD1
(M32C transmit data)
B416
Figure 1.35.43. Timing of baud rate 115200
ID Code
When the flash memory is not blank, the ID code sent from the peripheral units and the ID code written
in the flash memory are compared to see if they match. If the codes do not match, the command sent
from the peripheral units is not accepted. An ID code contains 8 bits of data. Area is, from the 1st byte,
addresses 0FFFFDF 16 , 0FFFFE3 16 , 0FFFFEB 16 , 0FFFFEF 16, 0FFFFF3 16 , 0FFFFF7 16 and
0FFFFFB16. Write a program into the flash memory, which already has the ID code set for these
addresses.
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Appendix Standard Serial I/O Mode 2 (Flash Memory Version)
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER
Address
0FFFFDC16 to 0FFFFDF16
ID1 Undefined instruction vector
0FFFFE016 to 0FFFFE316
ID2 Overflow vector
0FFFFE416 to 0FFFFE716
BRK instruction vector
0FFFFE816 to 0FFFFEB16
ID3 Address match vector
0FFFFEC16 to 0FFFFEF16
ID4
0FFFFF016 to 0FFFFF316
ID5 Watchdog timer vector
0FFFFF416 to 0FFFFF716
ID6
0FFFFF816 to 0FFFFFB16
ID7
0FFFFFC16 to 0FFFFFF16
NMI vector
Reset vector
4 bytes
Figure 1.35.44. ID code storage addresses
Example Circuit Application for The Standard Serial I/O Mode 2
The below figure shows a circuit application for the standard serial I/O mode 2.
CLK1
Monitor output
RTS1(BUSY)
Data input
RXD1
Data output
TXD1
M32C/80 Flash
memory version
CNVss
NMI
P50(CE)
P55(EPM)
In this example, the microprocessor mode and standard serial I/O mode
are switched via a switch.
Figure 1.35.45. Example circuit application for the standard serial I/O mode 2
432
REVISION HISTORY
Rev.
Date
M32C/83 GROUP DATA SHEET
Description
Page
Errror
Correct
100-pin version is added.
B1
1/8/2001
B1
30/8/
2001
Flash memory version is added.
Others
2,3
3
Tables 1.1.1 and 1.1.2
Interrupt: 12 internal/external sources
(intelligent I/O and CAN module)
Supply voltage
Delate
3.0 to 3.6V (f(XIN)=20MHz without wait) add
A-D converter
10 bits (8 channels) x 2 circuits, max 26 inputs
10 bits x 2 circuits, standard 10 inputs, max 26 inputs
7
Table 1.1.3 Pin 26
10-12 Figures 1.1.4, 1.1.5, Table 1.1.7
CANIN addition
CANIN is added to Pin 17(GP) and pin 19(FP)
11
12
Figure 1.1.5 Pin 97 AN00
Pin 32 (FP) Vcc
AN0
Delate
13
Pin 34 (FP) Vss
Vcc position to pin 64(FP)
Delate
Pin 62
Vss position to pin 66(FP)
RxD4/SCL4/STxD4 position to pin 98 (FP)
Pin 64
Pin 100
AN20 to AN27
AN30 to AN37
AN00 to AN07
AN20 to AN27
14
Table 1.1.5
17
Table1.1.12 P120 to P127 ISCLK description
AN10 to AN17
18
Figure 1.1.6 System clock oscillation circuit
28, 29 Figure 1.4.3 (122), (167)
(123), (168)
Delate
AN150 to AN157
PLL oscillation stop detect addition
Group0 receive buffer register, Group1 receive buffer
register
Group0 transmit buffer/receive data register, Group1
transmit buffer/receive data register
46
Note 1: Addresses 03C916, 03CB16 to 03D316
Addresses 03A016, 03A116, 03B916, 03BC16, 03BD16,
03C916, 03CB16 to 03D316
48
70
Figure 1.6.1 Note 2
Figure 1.8.6 When reset of PLL control register 0
Addition. Displase after the former Note 2
72
0X11 0100
Figure 1.8.8 Count value set bit
0011 0100
Division rate select bit
Count start bit
Count stop/start
Operation enable bit
Divider stops/starts
Note 2
Addition
Delate
Stop mode is canceled before setting this bit to "1".
76
Line 10
77
135
Line 8
1:Sub clock is selected
Figure 1.14.2 Values that can be set Pulse width
1: Clock from ring oscillator is selected
modulation mode (8-bit PWM)
0016 to FF16(High-order and low-order address)
0016 to FE16(High-order address) 0016 to FF16(Low-
230
Line 5, Bit 1 TrmActive
order address)
TrmData
266
Table1.23.11 Waveform generate control register
1when clock synchronous serial I/O
280
√
When the transfer clock and transfer data are trans-
Table1.23.17 Note 1:
mission, transfer clock is set to at least 6 divisions of
(1/7)
REVISION HISTORY
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Date
M32C/83 GROUP DATA SHEET
Description
Page
Errror
Correct
the base timer clock. Except this, transfer clock is set
to at least 20 divisions of the base timer clock.
Addition
Note 2
285
284
Figure 1.23.37
Table1.24.1 A-D conversion start condition
• Timer B2 interrupt
B2
2, 3, 4 Table 1.1.1, 1.1.2
Feb/1/
Clock generating circuit
2002
Power consumption
6,10,
11
Fig 1.1.3-1.1.5
18
Fig 1.1.6
PLL
24
27
28
Delay timing of base timer
• Timer B2 interrupt occurrences frequency counter
overflow
4 built-in...circuit
PLL freq. synthe.
3 built-in clock generation circuits
Delete
29mA
44mA
26mA
38mA
Note: P70 and P71 are N-channel...output.-> Add
System clock generator
Delete
Oscillation stop detection
7th line
Ring oscillator
Since the value.....due to the interruption. -> Add
Fig 1.4.3 (1)
(2) Processor mode register 1
XX00 X000 -> X000 00XX
(3) System clock control register 0
(10) Oscillation stop detect register
80 -> 0000 X000
XXXX 0000 -> 00
(17) VDC control register 1
(21) DRAM refresh interval set register
Add
XXXX ?000 -> ??
(46) CAN interrupt 1 control register
(47) CAN interrupt 2 control register
Add
Add
Fig 1.4.3 (2)
(70) CAN interrupt 0 control register
Add
28-31 Fig 1.4.3(2) (97)-(104), Fig 1.4.3(3) (142)-(149),
Fig 1.4.3(4) (187)-(194), Fig 1.4.3(5) (222)-(229)
Group 0 -3 time measurement/
waveform generation register 0-7
00 -> ??
29, 30 Fig 1.4.3(3) (124), Fig 1.4.3(4) (169)
Group 0,1 SI/O communication buffer register
Fig 1.4.3(3) (125), Fig 1.4.3(4) (170)
Group 0,1 receive data register
Group 0,1 SI/O receive buffer register
Group 0,1 transmit buffer/receive data register
(129) Group 0 SI/O comm cont register
X000 XXX -> 000 X011
(186) Group 1 SI/O expansion trans cont register 0000 00XX -> 0000 0XXX
31
Fig 1.4.3(5) (238)-(241)
Group 3 waveform generate mask register 4-7
32
Fig 1.4.3(6)
33
Fig 1.4.3(7) (309)-(338)
(314)-(318),(321),(323),(329),(331),(336)
Note added
Reset values changed
(337) CAN0 clock control register
Fig 1.4.3(10) (461) A-D control register 2
CAN0 sleep control register
X000 XXX0 -> X000 0000
36
(270)-(308)
(270)-(302)
00 -> ??
Note added
Reset value changed
(2/7)
REVISION HISTORY
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Date
M32C/83 GROUP DATA SHEET
Description
Page
38
Errror
Correct
Address 007F16
Address 008116
CAN interrupt 1 control register added
CAN interrupt 2 control register added
CAN interrupt 0 control register added
61
Address 009D16
(10) Software wait, 11th line
SFR area is accessed.....with “2 waits”.
Fig 1.8.2 System clock control register 0
Add
67
When reset: 0816
Note 3: When selecting fc,.....as input port.
0000 X0002
Delete
79
Fig 1.8.9
Note 7: When using PLL.....cannot be used.
Delete
90
110
Fig 1.9.3, Symbol CAN0ICi
Table 1.11.1, DMA request factors
CANiIC
Intelligent I/O interrupt -> add
128
133
Fig 1.12.4, the number of cycles
Fig 1.14.3, Timer Ai mode register, MR0
Change
Port output.....registers A and B.
Table 1.14.1, 1.14.2, 1.14,4, 1.14,5
Port output.....registers A, B and C.
137,
TAiOUT pin function
Function select register C -> add
138,
142,
144
137
Fig 1.14.7 Timer Ai mode register
bit 2 (MR0)
Location of Note 3 (b7, b6): 11
Function select register C -> add
10
Fig 1.14.8 Timer Ai mode register
bit 2 (MR0)
Function select register C -> add
143,
145
Fig 1.14.11, 1.14.12 Timer Ai mode register
bit 2 (MR0)
Function select register C -> add
10
159
Location of Note 3 (b7, b6): 11
Fig 1.16.5 Timer Ai mode register
161
bit 2 (MR0)
Fig 1.16.6
Function select register C -> add
Reload register
172
n = 1 to 255
Fig 1.17.4 UARTi transmit/receive control register 0
173
Note 2
Function select register C -> add
Fig 1.17.5 UARTi transmit/receive control register 1
199
Function of bit 7: Error signal output enable bit
Fig 1.22.1
Clock control register
200
Fig 1.22.3
201
Bit 10 Time stamp count reset bit
5th line: In no case will the CAN module be .....
Time stamp counter reset bit
In no case will the CAN be.....
202
Bit 3: BasicCAN mode bit
Bit 8,9: Timestamp prescaler bits
Bit 3: BasicCAN mode select bit
Bit 8, 9: Timestamp prescaler select bits
Bit 11, 1st line: Receive Error Counter
Transmit Error Counter
Receive Error Counter Register
Transmit Error Counter Register
Fig 1.22.8
bit 4: Reserved bit
6. CAN0 configuration register
Sampling number
Explanation of Bit 4 -> add
139
209
210
Reload register
Time stamp count register
Bit 4 0: Forced reset
(3/7)
Set to “0”
Sleep control register
Time stamp register
0: Reset requested
REVISION HISTORY
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Date
M32C/83 GROUP DATA SHEET
Description
Page
211
Errror
Correct
Note:1 Setting the C0CTLR0 register’s Reset0 bit
to 1 resets the CAN protocol control unit, with the
Note 1: Setting the C0CTLR0 register’s Reset0 and
Reset1 bits to 1 resets the CAN, and the C0TSR
C0TSR register thereby initialized to 000016. Also,
setting the TSReset (timestamp count reset) bit to
register is thereby initialized to 000016. Also, setting
the TSReset (timestamp counter reset) bit to 1 ini-
1 initializes the C0TSR register to 000016 on-thefly (while the CAN protocol control unit remains
tializes the C0TSR register to 000016 on-the-fly (while
the CAN remains operating; CAN0 status register’s
operating).
State_Reset bit is “0”).
212
Tq period = (C0BRP+1)
Tq period = (C0BRP+1)/CPU clock
220
Fig 1.22.19
b0
b2
b2
b1
226
Fig 1.22.25
bit 0
bit 1, When transmit, TrmData
Note 2 -> add
When transmit, TrmActive
bit 3
bit 6, 7, Transmit request flag
Note 2 -> add
Transmit request bit
229
230,
Fig 1.22.26, explanation of function
Fig 1.22.27, 1.22.28, 1.22.29
Change
231,
232
Explanation of function
Message slot j (j=0 to 15) -> change
233
Fig 1.22.30, CAN0 message slot butter i data m
Symbol
C0SLOT0_m (m=0 to 3)
C0SLOT0_n (n=m+6, m=0 to 3)
C0SLOT0_m (m=4 to 7)
C0SLOT1_m (m=0 to 3)
C0SLOT0_n (n=m+6, m=4 to 7)
C0SLOT1_n (n=m+6, m=0 to 3)
235
C0SLOT1_m (m=4 to 7)
Table 1.23.1 Group 2, WG register
C0SLOT1_n (n=m+6, m=4 to 7)
- -> 8chs
Group 3 Comm shift register
Fig 1.23.5, Group i base timer cont reg 0
16bits x 2chs -> -
240
Delete
245
Bit 2 to bit 6, explanations on fPLL
Table 1.23.2, Count reset condition, Group 2, 3
245
(3) Reset request ..... circuit
Fig 1.23.10 fPLL
(3) Reset request ..... circuit (group 2 only)
Delete
246
248
Fig 1.23.11
Fig 1.23.13, the values when reset: 0016
Newly added
000016
249
Table 1.23.3, select function, digital filter function
Strips off pulses less than 3 cycles long from f1
Pulses will pass when they match either f1 or the base
250
and the base timerclock.
Fig 1.23.14, (c)
timerclock 3 times.
Change
252
256
Fig 1.23.16, reset values for both registers
Fig 1.23.20, When WG register is “xxxb16”
000016 -> XXXX16
When WG register is “xxxa16”
270
Table 1.23.12
Transmission start condition
• Write data to transmit buffer register
Interrupt request generation timing
• Write data to transmit buffer
•When transmitting
- When SI/O transmit buffer register is.....
- When transmit buffer is .....
•When receiving
When....to SI/O communication buffer register
When.....to SI/O receive buffer register
(4/7)
REVISION HISTORY
Rev.
Date
M32C/83 GROUP DATA SHEET
Description
Page
Errror
Correct
270
Select function
This.....TxD pin output and RxD pin input.
This.....ISTxD pin output and ISRxD pin input.
271
Table 1.23.13, Transfer clock input
•Selects I/O with function.....
•Select I/O port with function.....
271
Fig 1.23.31
Write to communication buffer
Write to receive buffer
272
(Input to INPC2/ISRxD0 pin)
Table 1.23.14
(Input to INPCi2/ISRxDi pin (i=0, 1))
Transmission start condition
• Write data to transmit buffer register
• Write data to transmit buffer
Interrupt request generation timing
•When transmitting
- When SI/O transmit buffer register is.....
•When receiving
- When transmit buffer is .....
When....to SI/O communication buffer register
Error detection
When.....to SI/O receive buffer register
• Overrun error:
.....before contents of receive buffer register....
.....before contents o SI/O receive buffer register.....
273
Fig 1.23.32
Write to communication buffer
Write to receive buffer
273
Fig 1.23.33
(Input to INPC2/ISRxD0 pin)
(Input to INPCi2/ISRxDi pin (i=0, 1))
279
Table 1.23.17
Transmission start condition
• Write data to transmit buffer register
Reception start condition
• Write data to SI/O transmit buffer register
• Write data to transmit buffer register
Interrupt request generation timing
• Write data to SI/O transmit buffer register
•When receiving
When....to SI/O communication buffer register
When.....to SI/O receive buffer register
Select function
This.....TxD pin output and RxD pin input.
This.....ISTxD pin output and ISRxD pin input.
286
Fig 1.24.4, A-D control register 2
When reset: X000 XXX02
X000 00002
287,
288
Fig 1.24.5, Note 4 and Fig 1.24.6, Note 3
..... by A-D sweep pin select bits.....
.....by analog input port select bits.....
292
(e) Replace function of input pin
2nd line: .....of A-D0 and A-D2.
.....of A-D0 and A-D1.
293
(f) , at the end of 2nd line
(g) 3rd line: ....., input via AN00 to AN07 is.....
as AN0.....respectively. -> add
, input via AN0 to AN7 is.....
294
Table 1.24.9 P00 analog input
P01 analog input
P95 analog input
P96 analog input
312
Fig 1.29.1, P00 to P07, P20 to P27: -
(5/7)
REVISION HISTORY
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Date
M32C/83 GROUP DATA SHEET
Description
Page
313
Errror
Correct
Fig 1.29.2
Delete
Pull-up selection
Pull-up selection
Direction register
Direction register
Port P1 control
register
Data bus
Port P1 control
register
Port latch
Data bus
Circuit (C)
314
Port latch
Delete
P15 to P17, Circuit (B): Fig 1.29.3
Add
Pull-up selection
D
Function select
register A
Pull-up selection
(Note 1)
D
(Note 1)
Function select
register A
Direction register
Direction register
Output from each
peripheral function
Output from each
peripheral function
P121, P122, Circuit (B): 326
331
Fig 1.29.16, Pull-up register 2, Note 1
Table 1.29.5
Delete
_____
331
334
337
340
Bit 0, 1: Three-phase PWM output (U)
Bit 1, 0: Three-phase PWM output (U)
1: Three-phase PWM output (U)
_____
0: Three-phase PWM output (U)
Table 1.29.6, PS4
PSL4
PS3
PSL3
Bit 1, UART0
Bit 2, UART4
UART3
UART3
Bit 3, UART1
Bit 4, 5 UART1
UART3
UART4
A4
B4
A3
B3
VDC
A-D Converter
Add
1st line: A-D
1st line: A-D
A-D i (i=0,1)
A-D i
2nd line: .....and to bit 0 of A-D control register 2... .....and to each bit of A-D i control register 2.....
(3) External interrupt
• Level sense, 2nd line: (When XIN=20MHz and..) (When XIN=30MHz and .....)
3rd line: (....., at least 250 ns.....) (....., at least 233 ns.....)
_______
_______
• When the polarity of INT0 and INT5 pins is.....
341
• When the polarity of INT0 to INT5 pins is.....
Reducing power consumption, (2)
343
1st line, last line: AN04, AN07
Table 1.30.3 G0CR 00EF16
AN4, AN7
G0RI 00EC16
343
G1RI 012F16
U0BRG 036116
G1RI 012C16
U0BRG 036916
U0TB 036316, 036216
U1BRG 036916
U0TB 036B16, 036A16
U1BRG 02E916
U1TB 036B16, 036A16
Notes on CNVss pin reset at “H” level
(6/7)
U1TB
Add
02EB16, 02EA16
REVISION HISTORY
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Date
M32C/83 GROUP DATA SHEET
Description
Page
344-
Errror
Correct
Electric characteristics
Add
380
385 Fig 1.34.1, Address 037716
Address 005716
_____
_____
385
Bit 0: RY/BY status bit
Flash memory control register (address 005716)
RY/BY signal status bit
390
1st line: .....the RY/BY status flag.....
13th line of Page Program Command (4116) and
391
Fig 1.34.3: RY/BY status flag
11th line of Block Erase Command (2016/D016)
392
and Fig 1.34.4: RY/BY status flag
_____
Fig 1.34.5: RY/BY status flag
RY/BY signal status bit
_____
RY/BY signal status bit
3rd paragraph, 1st line
....., set the CLK1 pin to “H” level and....
....., set the CLK1 pin to “H” level and the TxD1 pin to
_____
_____
_____
_____
_____
400
.....the RY/BY signal status bit.....
RY/BY signal status bit
_____
“L” level, and.....
400
3rd paragraph, 2nd line
401
The CLK1 pin is connected to Vcc.....resistance.
P67 When using standard.....transfer.
419
421
Fig 1.35.22, Data output
Pulled down
How frequency is identified, 2nd line: (2 - 20MHz) (2 - 30MHz)
(7/7)
Add
Add
Keep safety first in your circuit designs!
●
Mitsubishi Electric Corporation puts the maximum effort into making semiconductor
products better and more reliable, but there is always the possibility that trouble may
occur with them. Trouble with semiconductors may lead to personal injury, fire or
property damage. Remember to give due consideration to safety when making your
circuit designs, with appropriate measures such as (i) placement of substitutive,
auxiliary circuits, (ii) use of non-flammable material or (iii) prevention against any
malfunction or mishap.
Notes regarding these materials
●
●
●
●
●
●
●
●
These materials are intended as a reference to assist our customers in the selection
of the Mitsubishi semiconductor product best suited to the customer's application;
they do not convey any license under any intellectual property rights, or any other
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Mitsubishi Electric Corporation assumes no responsibility for any damage, or
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Please contact Mitsubishi Electric Corporation or an authorized Mitsubishi Semicon
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MITSUBISHI SEMICONDUCTORS
M32C/83 Group DATA SHEET REV. B2
February First Edition 2002
Editioned by
Committee of editing of Mitsubishi Semiconductor DATA SHEET
Published by
Mitsubishi Electric Corp., Kitaitami Works
This book, or parts thereof, may not be reproduced in any form without
permission of Mitsubishi Electric Corporation.
©2002 MITSUBISHI ELECTRIC CORPORATION