MITSUBISHI M37630M4T

MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
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DESCRIPTION
The 7630 group is a single chip 8-bit microcomputer designed with
CMOS silicon gate technology.
Being equipped with a CAN (Controller Area Network) module circuit, the microcomputer is suited to drive automotive equipments.
The CAN module complies with CAN specification version 2.0, part
B and allows priority-based message management.
In addition to the microcomputers simple instruction set, the ROM,
RAM and I/O addresses are placed in the same memory map to
enable easy programming.
The built-in ROM is available as mask ROM or One Time PROM.
For development purposes, emulator- and EPROM-type microcomputers are available as well.
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FEATURES
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Interrupts . . . . . . . . . . . . . . . . . . . . . . . . 24 sources, 24 vectors
Timers
16-bit Timers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 channels
8-bit Timers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 channels
Serial I/Os
Clock synchronous. . . . . . . . . . . . . . . . . . . . . . . . . . . 1 channel
UART . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 channel
CAN module
(CAN specification version 2.0, part B) . . . . . . . . . . . 1 channel
A-D converter . . . . . . . . . . . . . . . . . . . . . . . . 8-bits x 8 channels
Watchdog timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Clock Generating Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Built-in with internal feedback resistor
Power source voltage
(at 10 MHz oscillation frequency). . . . . . . . . . . . . . . 4.0 to 5.5 V
Power dissipation
In high-speed mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 mW
(at 8 MHz oscillation frequency, at 5 V power source voltage)
Operating temperature range. . . . . . . . . . . . . . . . . –40 to 85 °C
Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44QFP (44P6N-A)
Basic machine-language instructions . . . . . . . . . . . . . . . . . . 71
Minimum instruction execution time
(at 10 MHz oscillation frequency) . . . . . . . . . . . . . . . . . . 0.2 µs
Memory size
ROM . . . . . . . . . . . . . . . . . 16252 bytes (M37630M4T-XXXFP)
RAM . . . . . . . . . . . . . . . . . . . 512 bytes (M37630M4T-XXXFP)
I/O ports
Programmable I/O ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
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APPLICATION
Automotive controls
P11/INT0
P07/AN7
P06/AN6
P05/AN5
P04/AN4
P03/AN3
27
26
25
24
23
P12/INT1
29
28
P14/CNTR0
P13/TX0
30
P15/CNTR1
32
31
P16/PWM
33
PIN CONFIGURATION (TOP VIEW)
P17
P20/SIN
P21/SOUT
P22/SCLK
P23/SRDY
VSS
P24/URXD
P25/UTXD
34
22
35
21
36
20
41
15
P26/URTS
P27/UCTS
P30
42
14
43
13
44
12
19
37
M37630M4T-XXXFP
38
39
18
17
M37630E4T-XXXFP
1
2
3
4
5
6
7
8
9
10
11
P31/CTX
P33
P34
P40/KW0
P41/KW1
P42/KW2
P43/KW3
P44/KW4
P45/KW5
P46/KW6
16
P32/CRX
40
P02/AN2
P01/AN1
P00/AN0
VREF
AVSS
VCC
XOUT
XIN
VSS
RESET
P47/KW7
Package type: 44P6N-A
44-pin plastic molded QFP
Fig. 1
Pin configuration of M37630M4T–XXXFP
MITSUBISHI
ELECTRIC
1
Fig. 2
2
M37630MXT-XXXFP FUNCTIONAL BLOCK DIAGRAM (PACKAGE: 44P6N-A)
Functional block diagram
Clock
output
XOUT
Clock
input
XIN
Reset
input
RESET
VCC
16
15
13
17
VSS
14
AVSS
39
18
Clock generating circuit
CPU
A (8)
ROM
RAM
WDT
X (8)
Timer X (16)
Timer 1 (8)
Timer Y (16)
Timer 2 (8)
2
Y (8)
S (8)
PCH (8)
PWM
Timer 3 (8)
PCL (8)
PS (8)
MITSUBISHI
ELECTRIC
CAN
UART
2
Serial I/O
4
A-D Converter
INT0, INT1
4
8
2
P2 (8)
12 11 10 9 8 7 6 5
4 3 2 1 44
43 42 41 40 38 37 36 35
3
P1 (7)
34 33 32 31 30 29 28
P0 (8)
19
27 26 25 24 23 22 21 20
VREF input
I/O port P4
I/O port P3
I/O port P2
I/O port P1
I/O port P0
MITSUBISHI MICROCOMPUTERS
P3 (5)
7630 Group
P4 (8)
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
key on
wake up
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
PIN DESCRIPTION
Table 1: Pin description
Pin
Name
Input/Output
Description
VCC, VSS
Power source
voltage
Power supply pins; apply 4.0 to 5.5 V to VCC and 0 V to VSS
AVSS
Analog power
source voltage
Ground pin for A-D converter. Connect to VSS
RESET
Reset input
Input
XIN
Clock input
Input
XOUT
Clock output
Output
Input and output pins of the internal clock generating circuit. Connect a ceramic or
quartz–crystal resonator between the XIN and XOUT pins. When an external clock
source is used, connect it to XIN and leave XOUT open.
VREF
Reference voltage input
Input
Reference voltage input pin for A-D converter
P00/AN0—
P07/AN7
I/O port P0
I/O
CMOS I/O ports or analog input ports
Input
CMOS input port or external interrupt input port. The active edge (rising or falling) of
external interrupts can be selected. This pin will be used as VPP pin during PROM
programming of One Time PROM Versions.
P11/INT0
Reset pin. This pin must be kept at “L” level for more than 2 µs, to enter the reset
state. If the crystal or ceramic resonator requires more time to stabilize, extend the
“L” level period.
P12/INT1
CMOS I/O port or external interrupt input port. The active edge (rising or falling) of
external interrupts can be selected.
P13/TX0
CMOS I/O port or input pin used in the bi-phase counter mode
P14/CNTR0
I/O port P1
I/O
CMOS I/O port or timer X input pin used for the event counter, pulse width measurement and bi-phase counter mode
P15/CNTR1
CMOS I/O port or timer Y input pin used for the event counter, pulse width and pulse
period measurement mode
P16/PWM
CMOS I/O port or PWM output pin used in the PWM mode of timers 2 and 3
P17
CMOS I/O port
P20/SIN
P21/SOUT
P22/SCLK
P23/SRDY
CMOS I/O ports or clock synchronous serial I/O pins
I/O port P2
I/O
P24/URXD
P25/UTXD
P26/URTS
P27/UCTS
CMOS I/O ports or asynchronous serial I/O pins
P30
CMOS I/O port
P31/CTX
CMOS I/O port or CAN transmit data pin
I/O port P3
I/O
P32/CRX
CMOS I/O port or CAN receive data pin
P33—P34
CMOS I/O port
P40/KW0—
P47/KW7
I/O port P4
I/O
CMOS I/O ports. These ports can be used for key-on wake-up when configured as
inputs.
MITSUBISHI
ELECTRIC
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MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
PART NUMBERING
Product
M37630
M
4
T–
XXX
FP
Package type
FP: 44P6N-A package
FS: 80D0 package
ROM number
Omitted in One Time PROM version (blank) and EPROM version
T: Automotive use
ROM/PROM size
4: 16384 bytes
The first 128 bytes and the last 4 bytes of ROM are reserved areas.
They cannot be used.
Memory type
M: Mask ROM version
E: EPROM or One Time PROM version
Fig. 3
4
Part numbering
MITSUBISHI
ELECTRIC
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
GROUP EXPANSION
Memory Size
Mitsubishi plans to expand the 7630 group as follows:
ROM/PROM size . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Kbytes
RAM size. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 512 bytes
Memory Type
Package
Support mask ROM, One Time PROM and EPROM versions.
44P6N-A . . . . . . . . . . . . . . . . .0.8mm-pitch plastic molded QFP
80D0 . . . . . . . . . . . 0.8mm-pitch ceramic LCC (EPROM version)
ROM
External
60K
48K
32K
28K
24K
20K
Under development
M37630M4T
16K
12K
M37630E4T
Mass product
8K
384
512
640
768
896
1024
RAM size (bytes)
Fig. 4
Memory expansion plan
Currently supported products are listed below:
Table 2: List of supported products
Product
(P)ROM size (bytes)
ROM size for User ( )
As of March 1998
RAM size (bytes)
M37630M4T-XXXFP
M37630E4T-XXXFP
M37630E4FP
M37630E4FS
Remarks
Package
Mask ROM version
16384
512
44P6N-A
(16252)
One Time PROM version
One Time PROM version (blank)
80D0
MITSUBISHI
ELECTRIC
EPROM version
5
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
FUNCTIONAL DESCRIPTION
Central Processing Unit (CPU)
CPU Mode Register CPUM
The core of 7630 group microcomputers is the 7600 series CPU.
This core is based on the standard instruction set of 740 series;
however the performance is improved by allowing to execute the
same instructions as that of the 740 series in less cycles. Refer to
the 7600 Series Software Manual for details of the instruction set.
The CPU mode register contains the stack page selection bit and
internal system clock selection bit. The CPU mode register is allocated to address 000016.
7
0
CPU mode register (address 000016)
CPUM
Processor mode bits (set these bits to “00”)
b1 b0
0 0: Single–chip mode
0 1: Not used
1 0: Not used
1 1: Not used
Stack page selection bit
0 : 0 page
1 : 1 page
Not used (“0” when read, do not write “1”)
Internal system clock selection bit
0 : φ=f(XIN) divided by 2 (high–speed mode)
1 : φ=f(XIN) divided by 8 (middle–speed mode)
Not used (“0” when read, do not write “1”)
Fig. 5
6
Structure of CPU mode register
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ELECTRIC
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
MEMORY
Special Function Register (SFR) Area
Interrupt Vector Area
The special function register (SFR) area contains the registers
relating to functions such as I/O ports and timers.
The interrupt vector area is for storing jump destination addresses
used at reset or when an interrupt is generated.
RAM
Zero Page
RAM is used for data storage and for stack area of subroutine calls
and interrupts.
This area can be accessed most efficiently by means of the zero
page addressing mode.
ROM
Special Page
ROM is used for storing user’s program code as well as the interrupt vector area.
This area can be accessed most efficiently by means of the special
page addressing mode.
RAM area
Address
XXXX16
000016
192
011F16
004016
256
015F16
384
01DF16
006016
512
025F16
00FF16
640
02DF16
768
035F16
896
03DF16
1024
045F16
1536
06DF16
2048
085F16
RAM size
(byte)
CAN
SFRs
Zero page
User RAM
XXXX16
086016
ROM area
Fig. 6
SFR area
Not used
ROM size
(byte)
Address
YYYY16
Address
ZZZZ16
4096
F00016
F08016
YYYY16
8192
E00016
E08016
ZZZZ16
12288
D00016
D08016
16384
C00016
C08016
20480
B00016
B08016
24576
A00016
A08016
28672
900016
908016
32768
800016
808016
36864
700016
708016
40960
600016
608016
45056
500016
508016
49152
400016
408016
53248
300016
308016
57344
200016
208016
61440
100016
108016
ROM
Reserved ROM area
FF0016
FFCA16
FFFB16
FFFC16
FFFF16
Interrupt vector area
Special page
Reserved ROM area
Memory map diagram
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ELECTRIC
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MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
SPECIAL FUNCTION REGISTERS (SFR)
000016
000116
000216
000316
000416
000516
000616
000716
000816
000916
000A16
000B16
000C16
000D16
CPU mode register
Not used
Interrupt request register A
Interrupt request register B
Interrupt request register C
Interrupt control register A
Interrupt control register B
Interrupt control register C
Port P0 register
Port P0 direction register
Port P1 register
Port P1 direction register
Port P2 register
Port P2 direction register
000E16 Port P3 register
000F16 Port P3 direction register
001016 Port P4 register
001116 Port P4 direction register
001216 Serial I/O shift register
001316 Serial I/O control register
001416 A-D conversion register
001516 A-D control register
001616 Timer 1
001716 Timer 2
001816 Timer 3
001916 Timer 123 mode register
001A16
001B16
001C16
001D16
001E16
001F16
002016
002116
002216
002316
002416
002516
002616
002716
002816
002916
002A16
002B16
002C16
002D16
002E16
002F16
Fig. 7
8
Timer XL
Timer XH
Timer YL
Timer YH
Timer X mode register
Timer Y mode register
UART mode register
UART baud rate generator
UART control register
UART status register
UART transmit buffer register 1
UART transmit buffer register 2
UART receive buffer register 1
UART receive buffer register 2
Port P0 pull-up control register
Port P1 pull-up control register
Port P2 pull-up control register
Port P3 pull-up control register
Port P4 pull-up/down control register
Interrupt polarity selection register
Watchdog timer register
Polarity control register
CPUM
IREQA
IREQB
IREQC
ICONA
ICONB
ICONC
P0
P0D
P1
P1D
P2
P2D
P3
P3D
P4
P4D
SIO
SIOCON
AD
ADCON
T1
T2
T3
T123M
TXL
TXH
TYL
TYH
TXM
TYM
UMOD
UBRG
UCON
USTS
UTBR1
UTBR2
URBR1
URBR2
PUP0
PUP1
PUP2
PUP3
PUP4
IPOL
WDT
PCON
003016
003116
003216
003316
003416
003516
003616
003716
003816
003916
003A16
003B16
003C16
003D16
CAN transmit control register
CAN bus timing control register 1
CAN bus timing control register 2
CAN acceptance code register 0
CAN acceptance code register 1
CAN acceptance code register 2
CAN acceptance code register 3
CAN acceptance code register 4
CAN acceptance mask register 0
CAN acceptance mask register 1
CAN acceptance mask register 2
CAN acceptance mask register 3
CAN acceptance mask register 4
CAN receive control register
003E16 CAN transmit abort register
003F16 Reserved
004016 CAN transmit buffer register 0
004116 CAN transmit buffer register 1
004216 CAN transmit buffer register 2
004316 CAN transmit buffer register 3
004416 CAN transmit buffer register 4
004516 CAN transmit buffer register 5
004616 CAN transmit buffer register 6
004716 CAN transmit buffer register 7
004816 CAN transmit buffer register 8
004916 CAN transmit buffer register 9
004A16
004B16
004C16
004D16
004E16
004F16
005016
005116
005216
005316
005416
005516
005616
005716
005816
005916
005A16
005B16
005C16
005D16
005E16
005F16
Memory map of special register (SFR)
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ELECTRIC
CAN transmit buffer register A
CAN transmit buffer register B
CAN transmit buffer register C
CAN transmit buffer register D
Reserved
Reserved
CAN receive buffer register 0
CAN receive buffer register 1
CAN receive buffer register 2
CAN receive buffer register 3
CAN receive buffer register 4
CAN receive buffer register 5
CAN receive buffer register 6
CAN receive buffer register 7
CAN receive buffer register 8
CAN receive buffer register 9
CAN receive buffer register A
CAN receive buffer register B
CAN receive buffer register C
CAN receive buffer register D
Reserved
Reserved
CTRM
CBTCON1
CBTCON2
CAC0
CAC1
CAC2
CAC3
CAC4
CAM0
CAM1
CAM2
CAM3
CAM4
CREC
CABORT
CTB0
CTB1
CTB2
CTB3
CTB4
CTB5
CTB6
CTB7
CTB8
CTB9
CTBA
CTBB
CTBC
CTBD
CRB0
CRB1
CRB2
CRB3
CRB4
CRB5
CRB6
CRB7
CRB8
CRB9
CRBA
CRBB
CRBC
CRBD
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
I/O PORTS
The 7630 group has 35 programmable I/O pins and one input pin
arranged in five I/O ports (ports P0 to P4). The I/O ports are controlled by the corresponding port registers and port direction registers; each I/O pin can be controlled separately.
When data is read from a port configured as an output port, the port
latch’s contents are read instead of the port level. A port configured
7
as an input port becomes floating and its level can be read. Data
written to this port will affect the port latch only; the port remains
floating.
Refer to Structure of port- and port direction registers, Structure of
port I/Os (1) and Structure of port I/Os (2).
0
Port Pi register (i = 0 to 4) (address 000816 + 2 · i)
Pi
Port Pij control bit (j = 0 to 7)
0 : “L” level
1 : “H” level
Note :
7
The control bits corresponding to P10, P35, P36 and P37 are not used
(“0” when read, do not write “1”).
0
Port Pi direction register (i = 0 to 4) (address 000916 + 2 · i)
PiD
Port Pij direction control bit (j = 0 to 7)
0 : Port configured as input
1 : Port configured as output
Note : The direction control bits corresponding to P10, P11, P35, P36 and
P37 are not used (“0” when read, do not write “1”). Port direction registers are undefined when read (write only).
Fig. 8
Structure of port- and port direction registers
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ELECTRIC
9
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
(1) Ports P00/AN0 to P07/AN7
(4) Port P13/TX0
Pull-up control bit
Pull-up control bit
Analog input selection
direction
register
Direction
register
Data bus
Port latch
Port latch
Data bus
ADC input
Analog input selection
Timer bi-phase mode input
(5) Ports P14/CNTR0, P15/CNTR1
Pull-up control bit
(2) Port P11/INT0
Direction
register
Interrupt input
Port latch
Data bus
Data bus
Timer bi-phase mode input
(3) Port P12/INT1
(6) Port P16/PWM
Pull-up control bit
Pull-up control bit
PWM output enable
Direction
register
Data bus
Port latch
Direction
register
Data bus
Interrupt input
Fig. 9
10
Port latch
PWM output
Structure of port I/Os (1)
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ELECTRIC
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
(7) Ports P17, P30, P33, P34
(12) Ports P24/URXD, P27/UCTS
Transmission or reception* in
Pull-up control bit
progress
Transmit or receive* enable bit
Direction
register
Pull-up control bit
Direction
register
Port latch
Data bus
Port latch
Data bus
URXD or UCTS input
(8) Port P20/SIN
(13) Ports P25/UTXD, P26/URTS
Transmission or reception** in
progress
Pull-up control bit
SIO Port Select
Direction
register
Port latch
Data bus
Port latch
Data bus
Pull-up control bit
Transmit or receive** enable bit
Direction
register
UTXD or URTS output
SIO1 input
(*) for UCTS
(**) for URTS
(14) Port P31/CTX
(9) Port P21/SOUT
Pull-up control bit
Pull-up control bit
SIO port selection bit
Transmit complete signal
Direction
register
CAN port selection bit
Direction
register
Port latch
Data bus
Port latch
Data bus
CTX output
SIO output
(15) Port P32/CRX
CAN dominant level control bit
Pull-up/down control bit
(10) Port P22/SCLK
Direction
register
Pull-up control bit
Clock selection bit
Port selection bit
direction
register
Data bus
Port latch
Port latch
Data bus
CAN interrupt
SIO clock output
External clock input
CRX input
(16) Ports P40/KW0 to P47/KW7
Key-on wake-up control bit
Pull-up/down control bit
(11) Port P23/SRDY
Pull-up control bit
Direction
register
SRDY output selection bit
Direction
register
Data bus
Data bus
Port latch
Port latch
Key-on wake-up interrupt
SRDY output
Fig. 10
Structure of port I/Os (2)
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ELECTRIC
11
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
Port Pull-up/pull-down Function
Each pin of ports P0 to P4 except P11 is equipped with a programmable pull-up transistor. P32/CRX and P40/KW0 to P47/KW7 are
equipped with programmable pull-down transistors as well. The
pull-up function of P0 to P3 can be controlled by the corresponding
7
port pull-up control registers (see Structure of port pull-up/down
control registers). The pull-up/down function of ports P3 2 and P4
can be controlled by the corresponding port pull-up/pull-down registers together with the polarity control register (see Structure of
polarity control register).
0
Port Pi pull-up control register (address 002816 + i) (i = 0, 2)
PUP0, PUP2
Pij pull-up transistor control bit (j = 0 to 7)
0 : Pull-up transistor disabled
1 : Pull-up transistor enabled
7
0
Port P1 pull-up control register (address 002916)
PUP1
Not used (“0” when read, do not write “1”)
P1j pull-up transistor control bit (j = 2 to 7)
7
0
Port P3 pull-up control register (address 002B16)
PUP3
P3j pull-up transistor control bit (j = 0, 1)
P32 pull-up/down transistor control bit
P3j pull-up transistor control bit (j = 3, 4)
Not used (“0” when read, do not write “1”)
7
0
Port P4 pull-up/down control register (address 002C16)
PUP4
P4j pull-up/down transistor control bit (j = 0 to 7)
0 : Pull-up/down transistor disabled
1 : Pull-up/down transistor enabled
Fig. 11
Structure of port pull-up/down control registers
7
0
Polarity control register (address 002F16)
PCON
Key-on wake-up polarity control bit
0 : Low level active
1 : High level active
CAN module dominant level control bit
0 : Low level dominant
1 : High level dominant
Not used (undefined when read)
Fig. 12
12
Structure of polarity control register
MITSUBISHI
ELECTRIC
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
Port Overvoltage Application
When configured as input ports, P1 to P4 may be subjected to overvoltage (VI > VCC) if the input current to the applicable port is limited
to the specified values (see “Table 8:”). Use a serial resistor of
appropriate size to limit the input current. To estimate the resistor
value, assume the port voltage to be VCC at overvoltage condition.
•
Avoid to subject ports to overvoltage causing VCC to rise above
5.5 V.
•
The overvoltage condition causing input current flowing through
the internal port protection circuits has a negative effect on the
ports noise immunity. Therefore, careful and intense testing of
the target system’s noise immunity is required. Refer to the
“countermeasures against noise” of the corresponding users
manual.
•
Port P0 must not be subjected to overvoltage conditions.
Notes:
•
Subjecting ports to overvoltage may effect the supply voltage.
Assure to keep VCC and VSS within the target limits.
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INTERRUPTS
There are 24 interrupts: 6 external, 17 internal, and 1 software.
Interrupt Control
Each interrupt except the BRK instruction interrupt has both an
interrupt request bit and an interrupt enable bit, and is controlled by
the interrupt disable flag. An interrupt occurs when the corresponding interrupt request and enable bits are “1” and the interrupt disable flag is “0”. Interrupt enable bits can be cleared or set by
software. Interrupt request bits can be cleared by software but cannot be set by software. The BRK instruction interrupt and reset cannot be disabled with any flag or bit. The I flag disables all interrupts
except the BRK instruction interrupt and reset. If several interrupt
requests occur at the same time, the interrupt with the highest priority is accepted first.
Interrupt Operation
Upon acceptance of an interrupt, the following operations are automatically performed.
1. The processing being executed is stopped.
14
2.
3.
4.
The contents of the program counter and processor status
register are automatically pushed onto the stack.
Concurrently with the push operation, the interrupt jump
destination address is read from the vector table into the
program counter.
The interrupt disable flag is set and the corresponding interrupt
request bit is cleared.
Notes on use
When the active edge of an external interrupt (INT0, INT1, CNTR0,
CNTR1, CWKU or KOI) is changed, the corresponding interrupt
request bit may also be set. Therefore, take the following sequence.
(1) Disable the external interrupt which is selected.
(2) Change the active edge in interrupt edge selection register.
(in the case of CNTR0: Timer X mode register; in the case of
CNTR1: Timer Y mode register)
(3) Clear the interrupt request bit to “0”.
(4) Enable the external interrupt which is selected.
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.
Table 3: Interrupt vector addresses and priority
Vector Address (Note 1)
Interrupt source
Priority
High
Low
Interrupt Request Generating
Conditions
Remarks
Reset (Note 2)
1
FFFB16
FFFA16
At Reset
Non-maskable
Watchdog timer
2
FFF916
FFF816
At Watchdog timer underflow
Non-maskable
INT0
3
FFF716
FFF616
At detection of either rising or falling
edge of INT0 interrupt
External Interrupt
(active edge selectable)
INT1
4
FFF516
FFF416
At detection of either rising or falling
edge of INT1 interrupt
External Interrupt
(active edge selectable)
5
FFF316
FFF216
At CAN module successful
transmission of message
Valid when CAN module is
activated and request transmit
CAN successful
receive
6
FFF116
FFF016
At CAN module successful reception
of message
Valid when CAN module is
activated
CAN overrun
7
FFEF16
FFEE16
If CAN module receives message
when receive buffers are full.
Valid when CAN module is
activated
CAN error
passive
8
FFED16
FFEC16
When CAN module enters into error
passive state
Valid when CAN module is
active
CAN error bus off
9
FFEB16
FFEA16
When CAN module enters into bus
off state
Valid when CAN module is
active
CAN wake up
10
FFE916
FFE816
When CAN module wakes up via
CAN bus
Timer X
11
FFE716
FFE616
At Timer X underflow or overflow
Timer Y
12
FFE516
FFE416
At Timer Y underflow
Timer 1
13
FFE316
FFE216
At Timer 1 underflow
Timer 2
14
FFE116
FFE016
At Timer 2 underflow
Timer 3
15
FFDF16
FFDE16
At Timer 3 underflow
CNTR0
16
FFDD16
FFDC16
At detection of either rising or falling
edge in CNTR0 input
External Interrupt
(active edge selectable)
CNTR1
17
FFDB16
FFDA16
At detection of either rising or falling
edge in CNTR1 input
External Interrupt
(active edge selectable)
UART receive
18
FFD916
FFD816
At completion of UART receive
Valid when UART is selected
UART transmit
19
FFD716
FFD616
At completion of UART transmit
Valid when UART is selected
UART transmit
buffer empty
20
FFD516
FFD416
At UART transmit buffer empty
Valid when UART is selected
UART receive
error
21
FFD316
FFD216
When UART reception error occurs.
Valid when UART is selected
Serial I/O
22
FFD116
FFD016
At completion of serial I/O data
transmit and receive
Valid when serial I/O is
selected
A-D conversion
23
FFCF16
FFCE16
At completion of A-D conversion
Key-on wake-up
24
FFCD16
FFCC16
At detection of either rising or falling
edge of P4 input
External Interrupt
(active edge selectable)
BRK instruction
25
FFCB16
FFCA16
At BRK instruction execution
Non-maskable
CAN successful
transmit
Notes 1: Vector addresses contain interrupt jump destination address
2: Reset function in the same way as an interrupt with the highest priority
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Interrupt request bit
Interrupt enable bit
Interrupt disable flag I
BRK instruction
Reset
Fig. 13
Interrupt request
Interrupt control
For the external interrupts INT0 and INT1, the active edge causing
the interrupt request can be selected by the INT0 and INT1 interrupt
edge selection bits of the interrupt polarity selection register (IPOL);
please refer to Fig. 14 below.
7
0
Interrupt polarity selection register (Address 002D16)
IPOL
Not used (returns to “0” when read, do not write “1” in this bit)
INT0 interrupt edge selection bit
INT1 interrupt edge selection bit
Not used (returns to “0” when read, do not write “1” in these bits)
0 : Falling edge active
1 : Rising edge active
Fig. 14
16
Structure of interrupt polarity selection register
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7
0
Interrupt request register A
(address 000216)
IREQA
Interrupt control register A
(address 000516)
ICONA
Not used (returns to ”0” when read)
External interrupt INT0 enable bit
External interrupt INT1 enable bit
CAN successful transmission
interrupt enable bit
CAN successful receive
interrupt enable bit
CAN overrun interrupt enable bit
CAN error passive
interrupt enable bit
CAN bus off interrupt enable bit
0
7
Not used
(returns to ”0” when read)
External interrupt INT0 request bit
External interrupt INT1 request bit
CAN successful transmission
interrupt request bit
CAN successful receive
interrupt request bit
CAN overrun interrupt request bit
CAN error passive
interrupt request bit
CAN bus off interrupt request bit
7
0
0 Interrupt control register B
(address 000616)
ICONB
7
Interrupt request register B
(address 000316)
IREQB
CAN wake–up interrupt enable bit
CAN wake up
interrupt request bit
Timer X interrupt enable bit
Timer X interrupt request bit
Timer Y interrupt enable bit
Timer Y interrupt request bit
Timer 1 interrupt enable bit
Timer 1 interrupt request bit
Timer 2 interrupt enable bit
Timer 2 interrupt request bit
Timer 3 interrupt enable bit
Timer 3 interrupt request bit
CNTR0 interrupt enable bit
CNTR0 interrupt request bit
CNTR1 interrupt enable bit
CNTR1 interrupt request bit
7
0
Interrupt request register C
(address 000416)
IREQC
7
0
UART receive complete
(receive buffer full)
interrupt request bit
UART transmit complete
(transmit register empty)
interrupt request bit
UART transmit buffer empty
interrupt request bit
UART receive error interrupt
request bit
Serial I/O interrupt request bit
AD conversion complete
interrupt request bit
Key-on wake-up interrupt request bit
Not used (returns to ”0” when read)
0 : No interrupt request
1 : Interrupt requested
Fig. 15
Interrupt control register C
(address 000716)
ICONC
UART receive complete
(receive buffer full)
interrupt enable bit
UART transmit complete
(transmit register empty)
interrupt enable bit
UART transmit buffer empty
interrupt enable bit
UART receive error interrupt
enable bit
Serial I/O interrupt enable bit
AD conversion complete
interrupt enable bit
Key-on wake-up interrupt enable bit
Not used (returns to ”0” when read)
0:
1:
Interrupt disabled
Interrupt enabled
Structure of interrupt request and control registers A, B and C
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KEY-ON WAKE-UP
“Key-on wake-up” is one way of returning from a power-down state
caused by the STP or WIT instruction. Any terminal of port P4 can
be used to generate the key-on wake-up interrupt request. The
active polarity can be selected by the key-on wake-up polarity con-
trol bit of PCON (see Fig. 12). If any pin of port P4 has the selected
active level applied, the key-on wake-up interrupt request will be set
to “1”. Please refer to Fig. 16.
key-on wake-up control bit
P4Dj
PUP4j
port P4j/KWj
…
key-on wake-up interrupt
port P4j I/O circuit
j = 0 to 7
Fig. 16
18
Block diagram of key-on wake-up circuit
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TIMERS
The 7630 group has five timers: two 16-bit timers and three 8-bit
timers . All these timers will be described in detail below.
φ
16-bit Timers
Timers X and Y are 16-bit timers with multiple operating modes.
Please refer to Fig. 17.
TYM1,0
1/4
1/16
1/64
1/128
“00”
TXM5,4
“01”
TXM7
“00”, “11”
“01”
“10”
“10”
“11”
TXL latch (8)
TXH latch (8)
TXL counter (8)
TXH counter (8)
TX interrupt request
count
direction
control
P13/TX0
down
edge detector
“00”, “10”,
“11”
“01”
sign generator
P14/CNTR0
TXM5, 4
edge detector
“0”
CNTR0 interrupt request
“1”
1/2
1/8
1/32
“00”
“01”
TXM6
TXM5, 4=“11”
TYM7
TYM3, 2
“0x”, “11”
TYH latch (8)
TYL counter (8)
TYH counter (8)
TYM5, 4
“10”
1/64 “11”
TYL latch (8)
TY interrupt request
“10”
TYM5, 4=“11”
rising edge detector
falling edge detector
P15/CNTR1
TYM5, 4=“01”
“0”
“1”
“11”
TYM6
Fig. 17
CNTR1 interrupt request
“0x”, “10”
TYM5, 4
Block diagram of timers X and Y (φ is internal system clock)
Timer X
Timer X is a 16-bit timer with a 16-bit reload latch supporting the following operating modes:
(1) Timer mode
(2) Bi-phase counter mode
(3) Event counter mode
(4) Pulse width measurement mode
These modes can be selected by the timer X mode register (TXM).
In the timer- and pulse width measurement mode, the timer’s count
source can be selected by the timer X count source selection bits of
the timer Y mode register (TYM). Please refer to the Figures below
for the TXM and TYM bit assignment.
On read or write access to timer X, note that the high-order and loworder bytes must be accessed in the specific order.
Write method
When writing to the timer X, write the low-order byte first. The data
written is stored in a temporary register which is assigned to the
same address as TXL. Next, write the high-order byte. When this is
finished, the data is placed in the timer X high-order reload latch
and the low-order byte is transferred from its temporary register to
the timer X low-order reload latch. Depending on the timer X write
control bit, the latch contents are reloaded to the timer immediately
(write control bit = “0”) or on the next timer underflow (write control
bit = “1”).
Read method
When reading the timer X, read the high-order byte first. This
causes the timer X high- and low-order bytes to be transferred to
temporary registers being assigned to the same addresses as TXH
and TXL. Next, read the low-order byte which is read from the temporary register. This method assures the correct timer value can be
read during the timer count operation.
Timer X count stop control
Regardless of the actual operating mode, timer X can be stopped
by setting the timer X count stop bit (bit 7 of the timer X mode register) to “1”.
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7
0
Timer X mode register (address 001E16)
TXM
Timer X data write control bit
0 : Data is written to latch and timer
1 : Data is written to latch only
Not used (“0” when read, do not write “1”)
Timer X mode bits
b5 b4
0 0: Timer mode
0 1: Bi-phase counter mode
1 0: Event counter mode
1 1: Pulse width measurement mode
CNTR0 polarity selection bit
0 : For event counter mode, rising edge active
For interrupt request, falling edge active
For pulse width measurement mode, measure “H” period
1 : For event counter mode, falling edge active
For interrupt request, rising edge active
For pulse width measurement mode, measure “L” period
Timer X stop control bit
0 : Timer counting
1 : Timer stopped
Fig. 18
Structure of Timer X mode register
Timer Y
Timer Y is a 16 bit timer with a 16-bit reload latch supporting the following operating modes:
(1) Timer mode
(3) Event counter mode
(5) Pulse period measurement mode
(6) H/L pulse width measurement mode
These modes can be selected by the timer Y mode register (TYM).
In the timer, pulse period- and pulse width measurement modes’
the timer’s count source can be selected by the timer Y count
source selection bits. Please refer to Fig. 19.
On read or write access to timer Y, note that the high-order and loworder bytes must be accessed in a specific order.
Write method
When writing to timer Y, write the low-order byte first. The data written is stored in a temporary register which is assigned to the same
20
address as TYL. Next, write the high-order byte. When this is finished, the data is placed in the timer Y high-order reload latch and
the low-order byte is transferred from its temporary register to the
timer Y low-order reload latch.
Read method
When reading the timer Y, read the high-order byte first. This
causes the timer Y high- and low-order bytes to be transferred to
temporary registers being assigned to the same addresses as TYH
and TYL. Next, read the low-order byte which is read from the temporary register. This method assures the correct timer value can be
read during timer count operation.
Timer Y count stop control
Regardless of the actual operating mode, timer Y can be stopped
by setting the timer Y count stop bit (bit 7 of the timer Y mode register) to “1”.
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7
0
Timer Y mode register (address 001F16)
TYM
Timer X count source selection bits
b1 b0
0 0: φ divided by 4
0 1: φ divided by 16
1 0: φ divided by 64
1 1: φ divided by 128
Timer Y count source selection bits
b3 b2
0 0: φ divided by 2
0 1: φ divided by 8
1 0: φ divided by 32
1 1: φ divided by 64
Timer Y operation mode bits
b5 b4
0 0: Timer mode
0 1: Pulse period measurement mode
1 0: Event counter mode
1 1: H/L pulse width measurement mode
CNTR1 polarity selection bit
0 : For event counter mode, rising edge active
For interrupt request, falling edge active
For pulse period measurement mode, refer to falling edges
1 : For event counter mode, falling edge active
For interrupt request, rising edge active
For pulse period measurement mode, refer to rising edges
Timer Y stop control bit
0 : Timer counting
1 : Timer stopped
Fig. 19
Structure of timer Y mode register (φ is internal system clock)
Operating Modes
The count direction is determined by the edge polarity and level
of count source inputs and may change during the count operation. Refer to the table below.
(1) Timer mode
This mode is available with timer X and timer Y.
• Count source
The count source for timer X and Y is the output of the corresponding clock divider. The division ratio can be selected by the
timer Y mode register.
• Operation
Both timers X and Y are down counters. On a timer underflow,
the corresponding timer interrupt request bit will be set to “1”, the
contents of the corresponding timer latches will be reloaded to
the counters and counting continues.
Table 4: Timer X count direction in Bi-phase counter mode
P13/TX0
↑ Edge
↓ Edge
L
(2) Bi-phase counter mode (quadruplicate)
This mode is available with timer X only.
• Count source
The count sources are P14/CNTR0 and the P13/TX0 pins.
• Operation
Timer X will count both rising and falling edges on both input pins
(see above). Refer to Timer X bi-phase counter mode operation
for the timing chart of the bi-phase counter mode.
H
L
H
P14/CNTR0
Count direction
L
Up
H
Down
L
Down
H
↑ Edge
↓ Edge
Up
Down
Up
Up
Down
On a timer over- or underflow, the corresponding interrupt
request bit will be set to “1” and counting continues.
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P13/TX0 input signal
P14/CNTR0 input signal
TX counter
count direction
Fig. 20
down
up
Timer X bi-phase counter mode operation
(3) Event counter mode
•
This mode is available with timer X and timer Y.
• Count source
The count source for timer X is the input signal to the P14/CNTR0
pin and for timer Y the input signal to P15/CNTR1 pin.
• Operation
The timer counts down. On a timer underflow, the corresponding
timer interrupt request bit will be set to “1”, the contents of the
corresponding timer latches will be reloaded to the counters and
counting continues. The active edge used for counting can be
selected by the polarity selection bit of the corresponding pin
P14/CNTR0 or P15/CNTR1. These bits are part of TXM (Structure
of Timer X mode register) and TYM (Structure of timer Y mode
register (f is internal system clock)) registers.
(4) Pulse width measurement mode
This mode is available with timer X only.
• Count source
The count source is the output of timer X clock divider. The division ratio can be selected by the timer Y mode register.
• Operation
The timer counts down while the input signal level on
P14/CNTR0 matches the active polarity selected by the CNTR0
polarity selection bit of TXM (Structure of Timer X mode register). On a timer underflow, the timer X interrupt request bit will be
set to “1”, the contents of the timer latches are reloaded to the
counters and counting continues. When the input level changes
from active polarity (as selected), the CNTR0 interrupt request bit
will be set to “1.” The measurement result may be obtained by
reading timer X during interrupt service.
(5) Pulse period measurement mode
This mode is available with timer Y only.
• Count source
The count source is the output of timer Y clock divider.
22
Operation
The active edge of input signal to be measured can be selected
by CNTR1 polarity selection bit (Fig. 18). When this bit is set to
“0”, the time between two consecutive falling edges of the signal
input to P15/CNTR1 pin will be measured, when the polarity bit is
set to “1”, the time between two consecutive rising edges will be
measured.
The timer counts down. On detection of an active edge of input
signal, the contents of the TY counters will be transferred to temporary registers assigned to the same addresses as TY. At the
same time, the contents of TY latches will be reloaded to the
counters and counting continues. The active edge of input signal
also causes the CNTR1 interrupt request bit to be set to “1”. The
measurement result may be obtained by reading timer Y during
interrupt service.
(6) H/L pulse width measurement mode
This mode is available with timer Y only.
•
Count source
The count source is the output of the timer Y’s clock divider.
•
Operation
This mode measures both the “H” and “L” periods of a signal
input to P15/CNTR1 pin continuously. On detection of any edge
(rising or falling) of input signal to P15/CNTR1 pin, the contents of
timer Y counters are stored to temporary registers which are
assigned to the same addresses as timer Y. At the same time,
the contents of timer Y latches are reloaded to the counters and
counting continues. The detection of an edge causes the
CNTR1 interrupt request bit to be set to “1” as well. The result of
measurement may be obtained by reading timer Y during interrupt service. This read access will address the temporary registers. On a timer underflow, the timer Y interrupt request bit will
be set to “1”, the contents of timer Y latches will be transferred to
the counters and counting continues.
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TIMER 1, TIMER 2, TIMER 3
Timers 1 to 3 are 8-bit timers with 8-bit reload latches and one common pre-divider. Timer 1 can operate in the timer mode only,
φ
1
1/8
1/32
1/128
“00”
T123M67
whereas timers 2 and 3 can be used to generate a PWM output signal timing as well. Timers 1 to 3 are down count timers. See Fig. 21.
T1 latch (8)
“01”
T1 counter (8)
“10”
T1 interrupt
“11”
T2 latch (8)
“1”
“0”
T2 counter (8)
T123M3
“0”
“1”
T2 interrupt
S
T123M1
Q
R
T3 latch (8)
“1”
“0”
T3 counter (8)
T123M4
“0”
Fig. 21
T3 interrupt
S
T123M1
P1D6
T123M1
P16/PWM
“1”
Q
R
T123M0
S
P16 latch
T
Q
Block diagram of timers 1 to 3 (φ is internal system clock)
Timer 1
The count source of timer 1 is the output of timer 123 pre-divider.
The division ratio of the pre-divider can be selected by the predivider division ratio bits of timer 123 mode register (T123M). Refer
to Timer 123 mode register configuration (f is internal system clock).
On a timer 1 underflow, the timer 1 interrupt request bit will be set to
“1”.
Writing to timer 1 initializes the latch and counter.
be selected by the timer count source selection bits of timer 123
mode register (T123M).
Timers 2 and 3
Writing to timer 2 register affects the reload latch only or both of the
reload latch and counter depending on the timer 2 write control bit
of T123M. When the timer write control bit is set to “0”, both latch
and counter will be initialized simultaneously; when set to “1” only
the reload latch will be initialized, on an underflow, the counter will
be set to the modified reload value. Writing to timer 3 initializes
latch and counter both.
The count source of timers 2 and 3 can be either the output of the
timer 123 pre-divider or the timer 1 underflow. The count source can
Timer 2 or 3 underflow causes the timer 2 or 3 interrupt request bit
to be set to “1”.
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7
0
Timer 123 mode register (address 001916)
T123M
PWM polarity selection bit
0 : Start on “H” level output
1 : Start on “L” level output
PWM output enable bit
0 : PWM output disabled
1 : PWM output enabled
Timer 2 write control bit
0 : Latch and counter
1 : Latch only
Timer 2 count source selection bit
0 : Timer 1 underflow
1 : Pre-divider output
Timer 3 count source selection bit
0 : Timer 1 underflow
1 : Pre-divider output
Not used (“0” when read, do not write “1”)
Pre-divider division ratio bits
b7 b6
0 0: φ divided by 1
0 1: φ divided by 8
1 0: φ divided by 32
1 1: φ divided by 128
Fig. 22
Timer 123 mode register configuration (φ is internal system clock)
Operating Modes
(1) Timer Mode
This mode is available with timers 1 to 3.
•
Count source
For timer 1, the count source is the output of the corresponding
pre-divider. For timers 2 and 3, the count source can be separately selected to be either the pre-divider output or timer 1
underflow.
•
Operation
The timer counts down. On a timer underflow, the corresponding
timer interrupt request bit will be set to “1”, the contents of the
corresponding timer latch will be reloaded to the counter and
counting continues.
24
(2) PWM Mode
This mode is available with timer 2 and 3.
• Count source
The count source can be separately selected to be either the
pre-divider output or timer 1 underflow.
•
Operation
When the PWM-mode is enabled, timer 2 starts counting. As
soon as timer 2 underflows, timer 2 stops and timer 3 starts
counting. If bit 0 is set, timer 2 determines the low duration and
the initial output level is low. Timer 3 determines the high duration. If bit 0 is zero timer 2 determines the high duration and the
initial output level is high. In this case timer 3 determines the low
duration.
Note: Be sure to configure the P16/PWM pin as an output port
before using PWM mode.
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SERIAL I/Os
The serial I/O section of 7630 group consists of one clock synchronous and one asynchronous (UART) interface.
Clock Synchronous Serial I/O (SI/O)
speeds. Refer to Block diagram of clock synchronous I/O (f is internal system clock). The operation of the clock synchronous serial I/O
can be configured by the serial I/O control register SIOCON; refer to
Fig. 25.
The clock synchronous interface allows full duplex communication
based on 8 bit word length. The transfer clock can be selected from
an internal or external clock. When an internal clock is selected, a
programmable clock divider allows eight different transmission
φ
SIOCON2, 1, 0
Clock divider
P23/SRDY
SIOCON6
SIOCON4
Sync. circuit
“1”
“0”
P23 latch
P22/SCLK
SIOCON3
SIO counter (3)
“1”
“0”
P22 latch
P21/SOUT
“1”
“0”
SIO interrupt
SIOCON3
“1”
SIO shift register (8)
“0”
P21 latch
P20/SIN
SIOCON3
“1”
“0”
P20 latch
Fig. 23
Block diagram of clock synchronous I/O (φ is internal system clock)
(1) Clock synchronous serial I/O operation
Either an internal or external transfer clock can be selected by bit 6
of SIOCON. The internal clock divider can be programmed by bits 0
to 2 of SIOCON. Bit 3 of SIOCON determines whether the double
function pins P20 to P22 will act as I/O ports or serve as SIO pins.
Bit 4 of SIOCON allows the same selection for pin P23.
When an internal transfer clock is selected, transmission can be
triggered by writing data to the SI/O shift register (SIO, address
001216). After an 8–bit transmission has been completed, the SOUT
pin will change to high impedance and the SIO interrupt request bit
will be set to “1”.
When an external transfer clock is selected, the SIO interrupt
request bit will be set to “1” after 8 cycles but the contents of the
SI/O shift register continue to be shifted while the transfer clock is
being input. Therefore, the clock needs to be controlled externally;
the SOUT pin will not change to high impedance automatically.
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MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
synchronous clock
transfer clock
write signal to SIO
receive enable signal SRDY
Serial Output SOUT
D0
D1
D2
D3
D4
D5
D6
D7
Serial input SIN
D0
D1
D2
D3
D4
D5
D6
D7
SIO interrupt request bit = “1”
Note: When an internal clock is selected, SOUT pin will change to high impedance after 8 bits of data have been transmitted.
Fig. 24
Timing of clock synchronous SI/O function (LSB first selected)
7
0
SIO control register (address 001316)
SIOCON
Clock divider selection bits
b2 b1 b0
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0:
1:
0:
1:
0:
1:
0:
1:
φ divided by 4
φ divided by 8
φ divided by 16
φ divided by 32
φ divided by 64
φ divided by 128
φ divided by 256
φ divided by 512
P20/SIN, P21/SOUT and P22/SCLK function selection bit
0 : I/O port function
1 : SI/O function
P23/SRDY function selection bit
0 : I/O port function
1 : SI/O function
Transmission order selection bit
0 : LSB first
1 : MSB first
Synchronization clock selection bit
0 : use external clock
1 : use internal clock
Not used (“0” when read)
Fig. 25
Structure of serial I/O control register (φ is internal system clock)
Clock Asynchronous Serial I/O (UART)
The UART is a full duplex asynchronous transmit/receive unit. The
built-in clock divider and baud rate generator enable a broad range
of transmission speeds. Please refer to Block diagram of UART.
(1) Description
The transmit and receive shift registers have a buffer (consisting of
high and low order byte) each. Since the shift registers cannot be
26
written to or read from directly, transmit data is written to the transmit buffer and receive data is read from the receive buffer. A transmit or receive operation will be triggered by the transmit enable bit
and receive enable bit of the UART control register UCON (see
Structure of UART control register). The double function terminals
P25/UTXD, P26/URTS and P24/URXD, P27/UCTS will be switched to
serve as UART pins automatically.
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
(2) Baud rate selection
UART status register (USTS, Structure of UART
status register)
The baud rate of transmission and reception is determined by the
setting of the prescaler and the contents of the UART baud rate
generator register. It is calculated by: where p is the division ratio of
The read-only UART status register consists of 7 bits (bit 0 to bit 6)
which indicate the operating status of the UART function and various errors.
φ
b = ----------------------------------16 ⋅ p ⋅ ( n + 1 )
(3) Handshaking signals
the prescaler and n is the content of UART baud rate generator register. The prescalers division ration can be selected by the UART
mode register (see below).
When used as transmitter the UART will recognize the clear-tosend signal via P27/UCTS terminal for handshaking. When used as
receiver it will issue a request-to-send signal through P26/URTS
pin.
UART mode register (UMOD, Structure of UART
mode register)
Clear-to-send input
When used as a transmitter (transmit enable bit set to “1”), the
UART starts transmission after recognizing “L” level on P27/UCTS.
After started the UART will continue to transmit regardless of the
actual level of P27/UCTS or status of the transmit enable bit.
The UART mode register allows to select the transmission and
reception format with the following options:
•
word length: 7, 8 or 9 bits
•
parity: none, odd or even
•
stop bits: 1 or 2
Request-to-send output
The UART controls the P26/URTS output according to the following
conditions.
Table 5: Output control conditions
It allows to select the prescalers division ratio as well.
UART baud rate generator (UBRG)
P26/URTS
Condition
Receive enable bit is set to “1”
This 8 bit register allows to select the baud rate of the UART (see
above). Set this register to the desired value before enabling reception or transmission.
“L”
Reception completed during receive enable
bit set to “1”
Start bit (falling edge) detected
UART control register (UCON, Structure of UART
control register)
Receive enable bit is set to “0” before reception started
“H”
Hardware reset
The UART control register consists of four control bits (bit 0 to bit 3)
which allow to control reception and transmission.
Receive initialization bit is set to “1”
data bus
UART control register
φ
UART status register
transmit buffer (9)
transmit buffer empty flag
UMOD2, 1
1
“00”
1/8
“01”
1/32
“10”
transmit register empty interrupt request
UMOD7, 6
UBRG (8)
transmit buffer empty interrupt request
bit counter
P25/UTXD
transmit shift register (9)
1/256 “11”
UMOD4,3,2
transmission
control circuit
transmit register empty flag
P27/UCTS
reception control
circuit
UMOD7, 6
bit counter
receive shift register (9)
P26/URTS
receive error interrupt request
P24/URXD
receive error flags
receive buffer (9)
receive buffer full interrupt request
receive buffer full flag
data bus
Fig. 26
Block diagram of UART
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MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
7
0
UART mode register
UMOD (address 002016)
Not used (“0” when read, do not write “1”)
clock divider selection bits
b2 b1
0 0 : φ divided by 1
0 1 : φ divided by 8
1 0 : φ divided by 32
1 1 : φ divided by 256
Stop bits selection bit
0 : One stop bit
1 : Two stop bits
Parity selection bit
0 : Even parity
1 : Odd parity
Parity enable bit
0 : Parity disabled
1 : Parity enabled
UART word length selection bits
b7 b6
0 0 : 7 bits
0 1 : 8 bits
1 0 : 9 bits
1 1 : Not used
Fig. 27
Structure of UART mode register
7
0
UART control register
UCON (address 002216)
Transmit enable bit
0 : Transmit disabled (an ongoing transmission will be finished correctly)
1 : Transmit enabled
Receive enable bit
0 : Receive disabled (an ongoing reception will be finished correctly)
1 : Receive enabled
Transmission initialization bit
0 : No action
1 : Clear transmit buffer full flag and transmit shifter full flag, set the
transmit status register bits and stop transmission
Receive initialization bit
0 : No action
1 : Clear receive status flags and the receive enable bit
Not used (“0” when read, do not write “1”)
Fig. 28
28
Structure of UART control register
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
7
0
UART status register (address 002316)
USTS
Transmit register empty flag
0 : Register full
1 : Register empty
Transmit buffer empty flag
0 : Buffer full
1 : Buffer empty
Receive buffer full flag
0 : Buffer full
1 : Buffer empty
Receive parity error flag
0 : No parity error detected
1 : Parity error detected
Receive framing error flag
0 : No framing error detected
1 : Framing error detected
Receive overrun flag
0 : No overrun detected
1 : Overrun detected
Receive error sum flag
0 : No error detected
1 : Error detected
Not used (“0” when read)
Note: this register is read only; writing does not affect its contents.
Fig. 29
Structure of UART status register
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MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
CAN MODULE
The CAN (Controller Area Network) interface of the 7630 group
complies with the 2.0B specification, enabling reception and transmission of frames with either 11- or 29- bit identifier length. Refer to
Fig. 31 for a block diagram of the CAN interface.
The programmer’s interface to the CAN module is formed by three
status/control registers (Fig. 32, Fig. 33, Fig. 34), two bus timing
control registers (Fig. 35 Fig. 36), several registers for acceptance
filtering (Fig. 37), the transmit and receive buffer registers (Fig. 38)
and one dominant level control bit (Fig. 22).
CAN Bus Timing Control
Each bit-time consists of four different segments (see Fig. 30):
• Synchronization segment (SS),
• Propagation time segment (PTS),
• Phase buffer segment 1 (PBS1) and
• Phase buffer segment 2 (PBS2).
Bit-time
SS
Baud Rate Selection
A programmable clock prescaler is used to derive the CAN module’s basic clock from the internal system clock frequency (φ). Bit 0
to bit 3 of the CAN bus timing control register represent the prescaler allowing a division ratio from 1 to 1/16 to be selected. So the
CAN module basic clock frequency fCANB can be calculated as follows:
φ
fCANB = -----------p+1
where p is the value of the prescaler (selectable from 1 to 15). The
effective baud rate of the CAN bus communication depends on the
CAN bus timing control parameters and will be explained below.
PTS
PBS1
PBS2
Sample point
Fig. 30
Bit time of CAN module
The first of these segments is of fixed length (one Time Quantum)
and the latter three can be programmed to be 1 to 8 Time Quanta
by the CAN bus timing control register 1 and 2 (see Fig. 35 and Fig.
36). The whole bit-time has to consist of minimum 8 and maximum
25 Time Quanta. The duration of one Time Quantum is the cycle
time of fCANB. For example, assuming φ = 5 MHz, p = 0, one Time
Quantum will be 200 ns long. This allows the maximum transmission rate of 625 kb/s to be reached (assuming 8 Time Quanta per
bit-time).
data bus
polarity control
register
CAN status/control
registers
bus timing control
register
acceptance mask
register
acceptance code
register
receive buffer 1
acceptance filter
P31/CTX
P32/CRX
receive buffer 2
protocol controller
transmit buffer
wake-up logic
CAN wake-up
data bus
Fig. 31
30
Block diagram of CAN module
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MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
7
0
CAN transmit control register (address 003016)
CTRM
Sleep control bit
0 : CAN module in normal mode
1 : CAN module in sleep mode
Reset/configuration control bit
0 : CAN module in normal mode
1 : CAN module in configuration mode (plus reset at write)
Port double function control bit
0 : P31/CTX serves as I/O port
1 : P31/CTX serves as CTX output port
Transmit request bit
0 : No transmission requested
1 : Transmission requested
(write “0” has no effect)
Not used (no operation, “0” when read)
Transmit buffer control bit
0 : CPU access possible
1 : No CPU access
(write “0” has no effect, while CTRM(3) = 1)
Not used (no operation, “0” when read)
Transmit status bit (read only)
0 : CAN module idle or receiving
1 : CAN module transmitting
Fig. 32
Structure of CAN transmit control register
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MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
7
0
CAN receive control register (address 003D16)
CREC
Receive buffer control bit
0 : Receive buffer empty
1 : Receive buffer full
(write “1” has no effect)
Receive status bit (read only)
0 : CAN module idle or transmitting
1 : CAN module receiving
Not used (do not write “1”, read as “0”)
Auto-receive disable bit
0 : Auto-receive enabled
1 : Auto-receive disabled
Note: Suppresses reception of self initiated/transmitted frames
Not used (do not write “1”, “0” when read)
Fig. 33
Structure of CAN receive control register
7
0
CAN transmit abort register (address 003E16)
CABORT
Transmit Abort control bit
0 : No Transmit Abort Request
1 : Transmit Abort Request
(write “1” has no effect, while CTRM(3) = 0)
Not used (No operation, “0” when read)
Fig. 34
32
Structure of CAN transmit abort register
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
7
0
CAN bus timing control register 1 (address 003116)
CBTCON1
Prescaler division ratio selection bits
b3 b2 b1 b0
0 0 0 0: φ divided by 1
0 0 0 1: φ divided by 2
0 0 1 0: φ divided by 3
…
1 1 1 0: φ divided by 15
1 1 1 1: φ divided by 16
Sampling control bit
0 : One sample per bit
1 : Three sample per bit
Propagation time duration control bits
b7 b6 b5
0 0 0: One Time Quantum
0 0 1: Two Time Quanta
…
1 1 0: Seven Time Quanta
1 1 1 : Eight Time Quanta
Fig. 35
Structure of CAN bus timing control register 1
7
0
CAN bus timing control register 2 (address 003216)
CBTCON2
Phase buffer segment 1 duration control bits
b2 b1 b0
0 0 0: One Time Quantum
0 0 1: Two Time Quanta
…
1 1 0: Seven Time Quanta
1 1 1 : Eight Time Quanta
Phase buffer segment 2 duration control bits
b5 b4 b3
0 0 0: One Time Quantum
0 0 1: Two Time Quanta
…
1 1 0: Seven Time Quanta
1 1 1 : Eight Time Quanta
Synchronization jump width control bits
b7 b6
0
0
1
1
Fig. 36
0:
1:
0:
1:
One Time Quantum
Two Time Quanta
Three Time Quanta
Four Time Quanta
Structure of CAN bus timing control register 2
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MITSUBISHI MICROCOMPUTERS
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Acceptance code
registers:
name 7
CAC0 Not used Not used Not used CSID10
address
0
CSID6
003316
Not used Not used
003416
CSID9
CSID8
CSID1
CSID0
CAC2 Not used Not used Not used Not used CEID 17
CEID16
CEID15
CEID14
003516
CEID7
CEID6
003616
CAC1
CSID5
CSID4
CSID3
CSID2
CAC3
CEID13
CEID12
CEID11
CEID10
CEID9
CEID8
CAC4
CEID5
CEID4
CEID3
CEID2
CEID1
CEID0
CSID7
Not used Not used
003716
Select the bit pattern of identifiers which allows to pass acceptance filtering.
Acceptance mask
registers:
7
CAM0 Not used Not used Not used MSID 10
MSID9
MSID8
CAM1
MSID1
MSID0
CAM2 Not used Not used Not used Not used MEID17
MEID16
MEID15
MEID14
003A16
CAM3
MEID13
MEID12
MEID11
MEID10
MEID9
MEID8
MEID7
MEID6
003B16
CAM4
MEID5
MEID4
MEID3
MEID2
MEID1
MEID0
MSID5
MSID4
MSID3
MSID2
0
MSID6
003816
Not used Not used
003916
MSID7
Not used Not used
003C16
0 : Mask identifier bit (do not care)
1 : Compare identifier bit with acceptance code register bit
(Not used: write to “0”)
Fig. 37
Structure of CAN mask and code registers
name
CTB0, CRB0
CTB1, CRB1
CTB2, CRB2
7
Not used Not used Not used
SID5
SID4
SID3
0
SID9
SID8
SID7
SID6
000016
SID2
SID1
SID0
RTR/SRR
IDE
000116
EID17
EID16
EID15
EID14
000216
Not used Not used Not used Not used
CTB3, CRB3
EID13
EID12
EID11
EID10
EID9
EID8
EID7
EID6
000316
CTB4, CRB4
EID5
EID4
EID3
EID2
EID1
EID0
RTR
r1
000416
r0
DLC3
DLC2
DLC1
DLC0
000516
CTB5, CRB5
Not used Not used Not used
CTB6, CRB6
data byte 0
000616
CTB7, CRB7
data byte 1
000716
CTB8, CRB8
data byte 2
000816
CTB9, CRB9
data byte 3
000916
CTBA, CRBA
data byte 4
000A16
CTBB, CRBB
data byte 5
000B16
CTBC, CRBC
data byte 6
000C16
CTBD, CRBD
data byte 7
000D16
Calculate the actual address as follows:
TxD buffer address = 004016 + offset
RxD buffer address = 005016 +offset
(Not used: write to “0”)
Fig. 38
Note 1:
34
offset
SID10
Structure of CAN transmission and reception buffer registers
All CAN related SFRs must not be written in “CAN sleep” mode.
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
A-D CONVERTER
The A-D converter uses the successive approximation method with
8 bit resolution. The functional blocks of the A-D converter are
described below. Refer to Block diagram of A-D converter.
Comparison Voltage Generator
Channel Selector
The channel selector selects one of ports P00/AN0 to P07/AN7, and
inputs its voltage to the comparator.
A-D conversion register AD
The comparison voltage generator divides the voltage between
AVSS and VREF by 256, and outputs the divided voltage.
The A-D conversion register is a read-only register that stores the
result of an A-D conversion. This register must not be read during
an A-D conversion.
Data bus
b7
b0
A-D control register
3
A-D control circuit
A-D interrupt request
channel selector
P00/AN0
A-D conversion register
Comparator
comparison voltage
generator
P07/AN7
VREF/Input switch bit
VREF
Fig. 39
AVSS
Block diagram of A-D converter
A-D control register (Structure of A-D control register)
The A-D control register controls the A-D conversion process. Bits 0
to 2 select a specific analog input pin. Bit 3 signals the completion
of an A-D conversion. The value of this bit remains “0” during an A-
D conversion, and changes to “1” when an A-D conversion ends.
Writing “0” to this bit starts the A-D conversion. Bit 4 is the VREF/
Input switch bit.
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MITSUBISHI MICROCOMPUTERS
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7
0
A-D control register (address 001516)
ADCON
Analog input pin selection bits
b2 b1 b0
000
001
010
011
100
101
110
111
:
:
:
:
:
:
:
:
P00/AN0
P01/AN1
P02/AN2
P03/AN3
P04/AN4
P05/AN5
P06/AN6
P07/AN7
A-D conversion completion bit
0 : Conversion in progress
1 : Conversion completed
VREF/Input switch bit
0 : Off
1 : On
Not used (“0” when read, do not write “1”)
Fig. 40
Structure of A-D control register
A-D Converter Operation
The comparator and control circuit reference an analog input voltage with the reference voltage, then stores the result in the A-D
conversion register. When an A-D conversion is complete, the control circuit sets the A-D conversion completion bit and the A-D inter-
36
rupt request bit to “1”. The result of A-D conversion can be obtained
from the A-D conversion register, AD (address 001416).
Note that the comparator is linked to a capacitor, so set f(XIN) to 500
kHz or higher during A-D conversion.
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
WATCHDOG TIMER
The watchdog timer consists of two separate counters: one 7-bit
counter (WDH) and one 4-bit counter (WDL). Cascading both
counters or using the high-order counter allows only to select the
time-out from either 524288 or 32768 cycles of the internal clock φ.
Refer to Fig. 41 and Fig. 42. Both counters are addressed by the
same watchdog timer register (WDT). When writing to this register,
both counters will be set to the following default values:
• the high-order counter will be set to address 7F16
• the low-order counter will be set to address F16
regardless of the data written to the WDT register. Reading the
watchdog timer register will return the corresponding control bit status, not the counter contents.
φ
Once the WDT register is written to, the watchdog timer starts
counting down and the watchdog timer interrupt is enabled. Once it
is running, the watchdog timer cannot be disabled or stopped
except by reset. On a watchdog timer underflow, a non-maskable
watchdog timer interrupt will be requested.
To prevent the system being stopped by STP instruction, this
instruction can be disabled by the STP instruction disable bit of
WDT register. Once the STP instruction is disabled, it cannot be
enabled again except by RESET.
“1”
1/256
WDL counter (4) “0”
WDT7
“F16”
WDH counter (7)
WDT interrupt
“7F16”
WDT register (8)
Fig. 41
Block diagram of watchdog timer
7
0
Watchdog timer register (address 002E16)
WDT
Not used (undefined when read)
Stop instruction disable bit
0 : Stop instruction enabled
1 : Execute two NOP instructions instead (once this bit is set to
“1” it can not be cleared to “0” again, except on RESET.)
Upper byte count source selection bit
0 : Underflow of the low order counter
1 : φ divided by 256
Fig. 42
Structure of watchdog timer register (φ is internal clock system)
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MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
RESET CIRCUIT
in the recommended operating condition and then returned to “H”
level.
Refer to Fig. 43 for an example of the reset circuit.
The 7630 group is reset according to the sequence shown in Fig.
44. It starts program execution from the address formed by the contents of the addresses FFFB16 and FFFA16, when the RESET pin is
held at “L” level for more than 2 µs while the power supply voltage is
power on
4.0V
power source voltage
0V
reset input voltage
0.8V
0V
VCC
1
5
M51953AL
4
RESET
0.1µF
3
VSS
7630 group
Fig. 43
Example of reset circuit
XIN
RESET
internal reset
Address
?
Data
?
8192 cycles of
XIN (T1, T2)
Fig. 44
38
?
28 to 34
cycles of XIN
?
?
?
?
?
?
24 cycles of XIN
Reset sequence
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FFFA16
?
FFFB16
ADL
ADL, ADH
ADH
20 cycles of XIN
…
1st op code
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
Register
Address
Register contents
Register
Address
Register contents
CPU mode reg.
000016
4816
Timer XH
001B16
FF16
Interrupt request reg. A
000216
0016
Timer YL
001C16
FF16
Interrupt request reg. B
000316
0016
Timer YH
001D16
FF16
Interrupt request reg. C
000416
0016
Timer X mode reg.
001E16
0016
Interrupt control reg. A
000516
0016
Timer Y mode reg.
001F16
0016
Interrupt control reg. B
000616
0016
UART mode reg.
002016
0010
Interrupt control reg. C
000716
0016
UART control reg.
002216
0016
Port P0 reg.
000816
0016
UART status reg.
002316
0710
Port P0 direction reg.
000916
0016
Port P0 pull-up control reg.
002816
0016
Port P1 reg.
000A16
0016
Port P1 pull-up control reg.
002916
0016
Port P1 direction reg.
000B16
0016
Port P2 pull-up control reg.
002A16
0016
Port P2 reg.
000C16
0016
Port P3 pull-up control reg.
002B16
0016
Port P2 direction reg.
000D16
0016
Port P4 pull-up/down control reg.
002C16
0016
Port P3 reg.
000E16
0016
Interrupt polarity selection reg.
002D16
0016
Port P3 direction reg.
000F16
0016
Watchdog timer reg.
002E16
3F16
Port P4 reg.
001016
0016
Polarity control reg.
002F16
0016
Port P4 direction reg.
001116
0016
CAN transmit control reg.
003016
0216
Serial I/O control reg.
001316
0016
CAN bus timing control reg. 1
003116
0016
A-D control reg.
001516
0816
CAN bus timing control reg. 2
003216
0016
Timer 1
001616
FF16
CAN receive control reg.
003D16
0016
Timer 2
001716
0116
CAN transmit abort reg.
003E16
0016
Timer 3
001816
FF16
Processor status reg.
(PS)
Timer 123 mode reg.
001916
4016
Program counter (high-order byte)
(PCH)
contents of FFFB16
Timer XL
001A16
FF16
Program counter (low-order byte)
(PCL)
contents of FFFA16
0416
Note: The contents of RAM and registers other than the above registers are undefined after reset; thus software initialization is required.
Fig. 45
Internal status of microcomputer after reset
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MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
CLOCK GENERATING CIRCUIT
The 7630 group is equipped with an internal clock generating circuit.
Please refer to Fig. 46 for a circuit example using a ceramic resonator or quartz crystal oscillator. For the capacitor values, refer to the
manufacturers recommended parameters which depend on each
oscillators characteristics. When using an external clock, input it to
the XIN pin and leave XOUT open.
XIN
XOUT
CIN
Fig. 46
Oscillation Control
COUT
Ceramic resonator circuit
.
clock oscillation becomes stable. When using reset, a fixed time-out
will be generated allowing oscillation to stabilize.
Wait mode
The microcomputer enters the wait mode by executing the WIT
instruction. The internal clock ø stops at “H” level while the oscillator
keeps running.
Recovery from wait mode can be done in the same way as from
stop mode. However, the time-out period mentioned above is not
required to return from wait-mode, thus no such time-out mechanism has been implemented.
Note: Set the interrupt enable bit of the interrupt source to be used
to return from stop or wait mode to “1” before executing STP or WIT
instruction.
The 7630 group has two low power modes: the stop and the wait
mode.
Stop mode
The microcomputer enters the stop mode by executing the STP
instruction. The oscillator stops with the internal clock φ at “H” level.
Timers 1 and 2 will be cascaded and initialized by their reload
latches contents. The count source for timer 1 will be set to
f(XIN)/16.
Oscillation is restarted if an external interrupt is accepted or at
reset. When using an external interrupt, the internal clock φ remains
at “H” level until timer 2 underflows allowing a time-out until the
XOUT
1/4
“1”
XIN
“0”
1/2
CPUM6
R
interrupt request
interrupt disable flag
S
RESET
STP
delay
Q
STP
Q
D
S
Q
φ
internal clock
for
peripherals
φ
internal clock
for CPU
T
R
2
R
STP
oscillator countdown
(timer 1 and 2)
Fig. 47
40
D
S
R
WIT
Q
T
Q
S
Block diagram of clock generating circuit
MITSUBISHI
ELECTRIC
P2
Q
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
DATA REQUIRED FOR MASK ORDERS
The following are necessary when ordering a mask ROM production:
1
Mask ROM Order Confirmation Form
2
Mark Specification Form
3
Contents of Mask ROM, in EPROM form (three identical
copies)
The PROM of the blank One Time PROM version is not tested or
screened in the assembly process and following processes. To
ensure proper operation after programming, the procedure shown
in Fig. 48 is recommended to verify programming.
Programming with PROM programmer
PROM PROGRAMMING METHOD
The built-in PROM of the blank One Time PROM version and builtin EPROM version can be read or programmed with a general purpose PROM programmer using a special programming adapter. Set
the address of PROM programmer to the user ROM area.
Screening *(Note)
(150 °C for 40 hours)
For the programming adapter type name, please refer to the following table:
Verification with PROM programmer
Table 6: Programming adapter name
MCU type
Package
Programming adapter type
One Time
PROM
44P6N-A
PCA7430
EPROM
80D0
PCA7431
Functional test in target unit
Note on screening:
The screening temperature is far higher than the storage temperature. Never subject the device to 150 °C exceeding 100 hours.
Fig. 48 Programming and testing of One Time PROM version
MITSUBISHI
ELECTRIC
41
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
Table 7: ABSOLUTE MAXIMUM RATINGS
Symbol
VCC
Parameter
Power source voltage
Input voltage
VI
Output voltage
VO
Ratings
Unit
–0.3 to 7.0
V
–0.3 to VCC + 0.3
V
–0.3 to VCC + 0.3
V
500
mW
Conditions
P00—P07, P11—P17,
P20—P27, P30—P34,
P40—P47, RESET, XIN
P00—P07, P12—P17,
P20—P27, P30—P34,
P40—P47, XOUT
All voltages with respect to VSS
and output transistors are “off”.
Ta = 25 °C
Pd
Power dissipation
Topr
Operating temperature
–40 to 85
°C
Tstg
Storage temperature
–60 to 150
°C
Table 8: RECOMMENDED OPERATING CONDITIONS
(VCC = 4.0 to 5.5 V, VSS = AVSS = 0 V, Ta = – 40 to 85 °C unless otherwise noted)
Limits
Symbol
VCC
VSS
Parameter
Unit
Power source voltage
min.
typ.
max.
4.0
5.0
5.5
0
V
V
VIH
“H” Input voltage
P00—P07, P11—P17, P20—P27,
P30—P34, P40—P47, RESET, XIN
0.8 · VCC
VCC
V
VIL
“L” Input voltage
P00—P07, P11—P17, P20—P27,
P30—P34, P40—P47, RESET, XIN
0
0.2 · VCC
V
∑ IOH (peak)
“H” sum peak output current
P00—P07, P12—P17, P20—P27,
P30—P34, P40—P47
–80
mA
∑ IOH (avg)
∑ IOL (peak)
∑ IOL (avg)
“H” sum average output current
–40
mA
“L” sum peak output current
80
mA
“L” sum average output current
40
mA
IOH (peak)
“H” peak output current
–10
mA
IOH (avg)
“H” average output current
–5
mA
IOL (peak)
“L” peak output current
10
mA
IOL (avg)
“L” average output current
5
mA
IIO
input current at overvoltage condiP11—P17, P20—P27,
tion
P30—P34, P40—P47
(VI > VCC)
1
mA
∑ IIO
total input current at overvoltage
condition
(VI > VCC)
16
mA
P14/CNTR0, P15/CNTR1
(except bi-phase counter mode)
f(XIN)/16
MHz
P13/TX0, P14/CNTR0
(bi-phase counter mode)
f(XIN)/32
MHz
10
MHz
f(CNTR)
f(XIN)
42
Timer input frequency
(based on 50 % duty)
P11—P17, P20—P27,
P30—P34, P40—P47
Clock input oscillation frequency
MITSUBISHI
ELECTRIC
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
Table 9: ELECTRICAL CHARACTERISTICS
(VCC = 4.0 to 5.5 V, VSS = AVSS = 0 V, Ta = – 40 to 85 °C unless otherwise noted)
Limits
Symbol
Parameter
Test conditions
Unit
min.
VOH
“H” output voltage
P00—P07, P12—P17,
P20—P27, P30—P34,
P40—P47
IOH = –5 mA
VOL
“L” output voltage
P00—P07, P12—P17,
P20—P27, P30—P34,
P40—P47
IOL = 5 mA
VT+ – VT–
Hysteresis
P11/INT0, P12/INT1,
P13/TX0, P14/CNTR0,
P15/CNTR1,P20/SIN,
P22/SCLK, P26/URTS,
P27/UCTS, P32/CRX,
RESET
IIH
“H” input current
P00—P07, P11—P17,
P20—P27, P30—P34,
P40—P47, RESET
VI = VCC
IIH
“H” input current
XIN
VI = VCC
IIL
“L” input current
P00—P07, P11—P17,
P20—P27, P30—P34,
P40—P47, RESET
VI = VSS
IIL
“L” input current
XIN
VI = VSS
“H” input current
P32,
P40—P47
VI = VCC
Pull-Down = ’On’
P00—P07, P11—P17,
P20—P27, P30—P34,
P40—P47, RESET
VI = VSS
Pull-Up = ’On’
IIH
IIL
VRAM
“L” input current
RAM hold voltage
typ.
max.
0.8 · VCC
V
2.0
0.5
When clock stopped
MITSUBISHI
ELECTRIC
V
V
5
µA
µA
4
–5
µA
µA
–4
20
200
µA
-200
-20
µA
2.0
V
43
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
Limits
Symbol
Parameter
Test conditions
Unit
min.
ICC
Power source current
typ.
max.
high speed mode,
f(XIN) = 8MHz, VCC = 5V,
output transistors off,
CAN module running,
ADC running
11.0
18.0
mA
high speed mode,
f(XIN) = 8MHz, VCC = 5V,
output transistors off,
CAN module stopped,
ADC running
9.0
16.0
mA
middle speed mode,
f(XIN) = 8MHz, VCC = 5V,
output transistors off,
CAN module running,
ADC running
6.0
11.0
mA
middle speed mode, wait
mode, f(XIN) = 8MHz,
VCC = 5V, output transistors off, CAN module
stopped, ADC stopped
2.0
stop mode, f(XIN) = 0MHz,
VCC = 5V, Ta = 25°C
0.1
stop mode, f(XIN) = 0MHz,
VCC = 5V, Ta = 85°C
Table 10: A-D converter characteristics
(VCC = 4.0 to 5.5 V, VSS = AVSS = 0 V,
Ta = –40 to 85 °C,
mA
1.0
µA
10.0
µA
unless otherwise noted)
Limits
Symbol
Parameter
Test conditions
Unit
min.
—
Resolution
—
Absolute accuracy
tCONV
Conversion time
VREF
Reference input voltage
IREF
Reference input current
RLADDER
Ladder resistor value
IIAN
44
Analog input current
typ.
max.
8
Bit
±1.0
±2.5
LSB
108
tC(XIN)
tC(XIN)
high–speed mode
106
middle–speed mode
424
432
2.0
VCC
V
200
µA
VCC = VREF = 5.12 V
150
35
VI = VSS to VCC
MITSUBISHI
ELECTRIC
0.5
kΩ
5.0
µA
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
(VCC=4.0 to 5.5 V, VSS=AVSS=0 V, Ta=–40 to 85 °C unless otherwise noted)
Table 11: Timing requirements
Limits
Symbol
Parameter
Unit
min.
typ.
max.
2
µs
External clock input cycle time
100
ns
tWH(XIN)
External clock input “H” pulse width
37
ns
tWL(XIN)
External clock input “L” pulse width
37
ns
CNTR0, CNTR1 input cycle time
(except bi-phase counter mode)
1600
ns
CNTR0 input cycle time (bi-phase counter mode)
2000
ns
CNTR0, CNTR1 input “H” pulse width
(except bi-phase counter mode)
800
ns
CNTR0 input “H” pulse width (bi-phase counter mode)
1000
ns
CNTR0, CNTR1 input “L” pulse width
(except bi-phase counter mode)
800
ns
CNTR0 input “L” pulse width (bi-phase counter mode)
1000
ns
tL(CNTR0-TX0)
Lag of CNTR0 and TX0 input edges
(bi-phase counter mode)
500
ns
tC(TX0)
TX0 input cycle time (bi-phase counter mode)
3200
ns
tWH(TX0)
TX0 input “H” pulse width (bi-phase counter mode)
1600
ns
tWL(TX0)
TX0 input “L” pulse width (bi-phase counter mode)
1600
ns
tWH(INT)
INT0, INT1 input “H” pulse width
460
ns
tWL(INT)
INT0, INT1 input “L” pulse width
460
ns
tC(SCLK)
Serial I/O clock input cycle time
8 · tC(XIN)
ns
tWH(SCLK)
Serial I/O clock input “H” pulse width
4 · tC(XIN)
ns
tWL(SCLK)
Serial I/O clock input “L” pulse width
4 · tC(XIN)
ns
tSU(SIN–SCLK)
Serial I/O input setup time
200
ns
tH(SCLK–SIN)
Serial I/O input hold time
150
ns
tW(RESET)
Reset input “L” pulse width
tC(XIN)
tC(CNTR)
tWH(CNTR)
tWL(CNTR)
MITSUBISHI
ELECTRIC
45
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
Table 12: Switching characteristics
(VCC = 4.0 to 5.5 V, VSS = AVSS = 0 V, Ta = –40 to 85 °C, unless otherwise noted)
Limits
Symbol
Parameter
Unit
min.
typ.
max.
tWH(SCLK)
Serial I/O clock output “H” pulse width
0.5 · tC(SCLK) – 50
ns
tWL(SCLK)
Serial I/O clock output “L” pulse width
0.5 · tC(SCLK) – 50
ns
tD(SCLK–SOUT)
Serial I/O output delay time
tV(SCLK–SOUT)
Serial I/O output valid time
tR(SCLK)
Serial I/O clock output rise time
tR(CMOS)
CMOS output rise time
tF(CMOS)
CMOS output fall time
100 pF
CMOS output
46
ns
50
ns
50
ns
10
50
ns
10
50
ns
0
measurement output pin
Fig. 49
50
Circuit for measuring output switching characteristics
MITSUBISHI
ELECTRIC
MITSUBISHI MICROCOMPUTERS
7630 Group
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER
TIMING DIAGRAM
tC(TX0)
tWH(TX0)
tWL(TX0)
0.8·VCC
TX0
0.2·VCC
tC(CNTR)
tWH(CNTR)
tWL(CNTR)
0.8·VCC
CNTR0, CNTR1
0.2·VCC
tWH(INT)
tWL(INT)
0.8·VCC
INT0, INT1
0.2·VCC
tWL(RESET)
RESET
0.2·VCC
tC(XIN)
tWH(XIN)
tWL(XIN)
0.8·VCC
XIN
0.2·VCC
tC(SCLK)
tF
SCLK
tWL(SCLK)
tR
0.8·VCC
0.2·VCC
tSU(SIN-SCLK)
SIN
tWH(SCLK)
tH(SCLK-SIN)
0.8·VCC
0.2·VCC
tD(SCLK-SOUT)
tV(SCLK-SOUT)
SOUT
Fig. 50
Timing diagram
MITSUBISHI
ELECTRIC
47
REVISION
7630 English Data Sheets
REVISION
DATE
Page
New
1.1
MODIFICATIONS
Old
10. 98
“CAN controller” is replaced by “CAN module” in whole
document.
11
11
Schematics (8) and (11) are corrected.
18
18
Replaced: “PUPDj” with “PUP4j”
26
26
Replaced: “UTXD” with “SOUT”
Replaced: “URXD” with “SIN”
38
38
Replaced: “FFFBH” with “FFFB16”
Replaced: “FFFAH” with “FFFA16”
41
(1.2)
13.01.99
Replaced: “44P6N” with “44P6N-A)
43
43
Values changed:Iih(35, 113) to (20, 200) and Iil(-122, -70) to
(-200, -20); typical values are removed.
10
10
Schematic (1) is modified.
35
35
Fig. 39 is modified.
Revision Report M37630 E4/M4
1