FUJITSU MB89PV920

FUJITSU SEMICONDUCTOR
DATA SHEET
DS07-12526-1E
8-bit Proprietary Microcontroller
CMOS
F2MC-8L MB89920 Series
MB89923/925/P928/PV920
■ DESCRIPTION
The MB89920 series is a line of single-chip microcontrollers using the F2MC*-8L CPU core which can operate
at low voltage but at high speed.
The microcontrollers in this series contain peripheral functions such as a PWM timer, an input capture/output
compare control counter, an LCD controller/driver, an A/D converter, and a UART.
The MB89920 series can suit a wide range of applications such as analog input conversion, pulse input
measurement/pulse output control, serial communications control, and display control.
*: F2MC stands for FUJITSU Flexible Microcontroller.
■ FEATURES
• High speed processing at low voltage
Minimum execution time: 0.5 µs/8.0 MHz
• F2MC-8L family CPU core
Instruction set optimized for controllers
Multiplication and division instructions
16-bit arithmetic operations
Test and branch instructions
Bit manipulation instructions, etc.
• 8-bit PWM timer: 2 channels (also usable as a reload timer)
• 16-bit input capture: 2 channels / 16-bit output compare: 2 channels
(Continued)
■ PACKAGE
80-pin Plastic QFP
80-pin Ceramic MQFP
(FPT-80P-M06)
(MQP-80C-P01)
MB89920 Series
(Continued)
• 20-bit time-base counter
• UART: 1 channel (with asynchronous transfer mode and 8-bit synchronous serial mode)
• 8-bit serial interface: 1 channel (LSB first/MSB first selectability)
• 10-bit A/D converter: 8 channels
• LCD controller/driver: 28 segments × 4 commons (max. 112 pixels)
• Low-voltage detection reset
• Watchdog timer reset
• External interrupt: 4 channels
Four channels are independent and capable of wake-up from the low-power consumption mode (with edge
detection function)
• Buzzer output/clock output
• Low-power consumption modes:
Stop mode (The software stops oscillation to minimize the current consumption.)
Sleep mode (The CPU stops to reduce current consumption to approx. 1/3 of normal.)
Hardware standby mode (The pin input stops oscillation.)
2
MB89920 Series
■ PRODUCT LINEUP
Part number
Parameter
Classification
ROM size
RAM size
CPU functions
Ports
Options
20-bit time-base
timer
Real-time I/O
LCD controller/
driver
8-bit PWM timer
UART
8-bit serial I/O
10-bit A/D
converter
Watchdog timer
Low-voltage
detection reset
Hardware standby
Buzzer/clock output
External interrupt
Package
Operating voltage
EPROM for use
MB89923
MB89925
MB89P928
MB89PV920
Mass production products
Piggyback/evaluation
One-time PROM product
(for development)
product (for development)
(mask ROM products)
8 K × 8 bits
16 K × 8 bits
48 K × 8 bits
48 K × 8 bits
(internal mask ROM) (internal mask ROM)
(internal PROM)
(external ROM)
256 × 8 bits
512 × 8 bits
1024 × 8 bits
Number of instructions:
136
Instruction bit length:
8 bits
Instruction length:
1 to 3 bytes
Data bit length:
1, 8, 16 bits
Minimum execution time:
0.5 µs/8 MHz
Interrupt processing time:
4.5 µs/8 MHz
I/O ports (CMOS):
35 (25 ports also serve as peripherals.)
I/O ports (N-ch open-drain):
34 (All also serve as peripherals.)
Total:
69
Set with EPROM programmer
Specify with mask options
None
20 bits (interval time selection: 4.10 ms, 16.38 ms, 65.54 ms, 262 ms/8 MHz)
16-bit timer: operating clock cycle (0.5 µs, 1.0 µs, 2.0 µs, 4.0 µs), overflow interrupt
Input capture: 16 bits × 2 channels, external trigger edge selectability
Output compare: 16 bits × 2 channels
Common output: 4 (selectable from 2 to 4 by software)
Segment output: 28 (can be switched to ports in 4-pin unit by software)
Bias power supply pins: 3
LCD display RAM size: 14 × 8 bits
Dividing resistor for LCD driving: bult-in (external resistor selectability)
8 bits × 2-channel reload timer operation
8 bits × 2-channel PWM operation (4 cycles selectable)
8 bits × 1-channel PPG operation (4 oscillation clocks selectable)
Variable data length (7 or 8 bits), internal baud rate generator, error detection function,
full-duplex with internal double buffer, NRZ transmission formation,
Clock synchronous/asynchronous transfer capable
8 bits, LSB first/MSB first selectability,
One clock selectable from four transfer clocks
(one external shift clock, three internal shift clocks: 1.0 µs, 4.0 µs, 16.0 µs)
10-bit resolution × 8 channels
A/D conversion mode (conversion time: 16.5 µs (33 instruction cycles))
Sense mode (conversion time: 9.0 µs (18 instruction cycles))
Continuous activation by an internal clock capable
Interval time: approx. 130 to 260 ms
Reset activation voltage: 3.0 to 4.3 V
Reset release voltage: 3.1 to 4.5 V
Stop the clock oscillation by pin input
1 channel (output a frequency from 1 KHz, 2 KHz, 4 KHz, and divided clock frequency)
4 channels (rising edge/falling edge selectability)
QFP-80
MQFP-80
2.2 to 6.0 V*
2.7 to 6.0 V*
2.7 to 6.0 V*
MBM27C512-20TV

(LCC package)
* : The minimum operating voltage varies with conditions such as the operating frequencies, functions, and
development tool.
3
MB89920 Series
■ PACKAGE AND CORRESPONDING PRODUCTS
MB89923
MB89925
MB89P928
Package
×
FPT-80P-M06
MQP-80C-P01
: Available
MB89PV920
×
× : Not available
Note: For more information about each package, see section “■ Package Dimensions.”
■ DIFFERENCES AMONG PRODUCTS
1. Memory Size
Before evaluating using the piggyback product, verify its differences from the product that will actually be used.
Take particular care on the following points:
• The stack area, etc., is set at the upper limit of the RAM.
• The external area is used.
2. Current Consumption
• In the case of the MB89PV920, add the current consumed by the EPROM which is connected to the top socket.
• When operated at low speed, the product with an OTPROM (one-time PROM) or an EPROM will consume
more current than the product with a mask ROM.
However, the current consumption in sleep/stop modes is the same. (For more information, see section
“■ Electrical Characteristics.”)
3. Mask Options
Functions that can be selected as options and how to designate these options vary by the product.
Before using options check section “■ Mask Options.”
4
MB89920 Series
■ PIN ASSIGNMENT
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
P71/SEG17
P70/SEG16
P67/SEG15
P66/SEG14
P65/SEG13
P64/SEG12
P63/SEG11
P62/SEG10
P61/SEG9
P60/SEG8
P57/SEG7
P56/SEG6
P55/SEG5
P54/SEG4
P53/SEG3
P52/SEG2
(Top view)
(Lead pitch: 0.80 mm)
(Body size: 20 mm × 14 mm)
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
P51/SEG1
P50/SEG0
P40/COM0
P41/COM1
P42/COM2
P43/COM3
P44/V1
P45/V2
V3
VCC
AVCC
AVR
AVSS
P10/AN0
P11/AN1
P12/AN2
P13/AN3
P14/AN4
P15/AN5
P16/AN6
P17/AN7
P00/INT0
P01/INT1
P02/INT2
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
P32/UCK
P31/UO
P30/UI
P27
P26
P25
P24
P23/RTI1
P22
P21
P20/RTI0
P07
P06
P05
P04
P03/INT3
P72/SEG18
P73/SEG19
P74/SEG20
P75/SEG21
P76/SEG22
P77/SEG23
P80/SEG24
P81/SEG25
P82/SEG26
P83/SEG27
P90/RTO0
P91/RTO1
P92/CLK
P93/PWM0
VSS
MODA
X1
X0
P94/PWM1
HST
RST
P95/SCK
P96/SO
P97/SI
(FPT-80P-M06)
(Only for mass production or one-time PROM products)
5
MB89920 Series
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
P71/SEG17
P70/SEG16
P67/SEG15
P66/SEG14
P65/SEG13
P64/SEG12
P63/SEG11
P62/SEG10
P61/SEG9
P60/SEG8
P57/SEG7
P56/SEG6
P55/SEG5
P54/SEG4
P53/SEG3
P52/SEG2
(Top view)
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
100
99
98
97
96
95
94
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
93
92
91
90
89
88
87
86
85
110
111
112
81
82
83
84
101
102
103
104
105
106
107
108
109
P51/SEG1
P50/SEG0
P40/COM0
P41/COM1
P42/COM2
P43/COM3
P44/V1
P45/V2
V3
V CC
AV CC
AVR
AVSS
P10/AN0
P11/AN1
P12/AN2
P13/AN3
P14/AN4
P15/AN5
P16/AN6
P17/AN7
P00/INT0
P01/INT1
P02/INT2
P32/UCK
P31/UO
P30/UI
P27
P26
P25
P24
P23/RTI1
P22
P21
P20/RTI0
P07
P06
P05
P04
P03/INT3
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
P72/SEG18
P73/SEG19
P74/SEG20
P75/SEG21
P76/SEG22
P77/SEG23
P80/SEG24
P81/SEG25
P82/SEG26
P83/SEG27
P90/RTO0
P91/RTO1
P92/CLK
P93/PWM0
VSS
MODA
X1
X0
P94/PWM1
HST
RST
P95/SCK
P96/SO
P97/SI
(MQP-80C-P01)
• Pin assignment on package top (only for piggyback/evaluation product)
Pin no.
Pin name
Pin no.
Pin name
Pin no.
Pin name
Pin no.
Pin name
81
N.C.
89
AD2
97
N.C.
105
OE/VPP
82
A15
90
AD1
98
O4
106
N.C.
83
A12
91
AD0
99
O5
107
A11
84
AD7
92
N.C.
100
O6
108
A9
85
AD6
93
O1
101
O7
109
A8
86
AD5
94
O2
102
O8
110
A13
87
AD4
95
O3
103
CE
111
A14
88
AD3
96
VSS
104
A10
112
VCC
N.C.: Internally connected. Do not use.
(Only for piggyback/evaluation product)
6
MB89920 Series
■ PIN DESCRIPTION
Pin no.
Pin name
17
X1
18
X0
16
MODA
Circuit
type
Function
A
Clock oscillator pins
B
Operation mode selection input pin
Connect this pin to VSS (GND).
20
HST
B
Hardware standby input pin
21
RST
C
Reset I/O pin
This pin is an N-ch open-drain output type with a pull-up resistor,
and a hysteresis input type.
“L” is output from this pin by an internal reset source. The internal
circuit is initialized by the input of “L”.
11,
12
P90/RTO0,
P91/RTO1
D
General-purpose I/O ports
A pull-up resistor option is provided. Also serve as an output
compare data output.
13
P92/BUZ/CLK
D
General-purpose I/O port
Also serves as a buzzer/clock output.
14
P93/PWM0
D
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as an 8-bit PWM output.
19
P94/PWM1
D
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as an 8-bit PWM output.
22
P95/SCK
E
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as the clock I/O (SCK) for the serial I/O. The SCK
input is a hysteresis input.
The output type can be switched between N-ch open-drain and
CMOS.
23
P96/SO
D
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as the data output (SO) for the serial I/O. The output
type can be switched between N-ch open-drain and CMOS.
24
P97/SI
E
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as the data input (SI) for the serial I/O.
25
P32/UCK
E
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as a UART clock I/O (UCK). The UCK input is
hysteresis input.
The output type can be switched between N-ch open-drain and
CMOS.
26
P31/UO
D
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as a UART data output (UO).
The output type can be switched between N-ch open-drain and
CMOS.
(Continued)
7
MB89920 Series
(Continued)
Pin no.
27
Circuit
type
Function
P30/UI
E
P27 to P24
D
32
P23/RTI1
E
33,
34
P22,
P21
D
35
P20/RTI0
E
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as an input capture data input.
36 to 39
P07 to P04
D
General-purpose I/O ports
A pull-up resistor options is provided.
40 to 43
P03/INT3 to
P00/INT0
E
General-purpose I/O ports
A pull-up resistor options is provided.
Also serve as an external interrupt input (INT0 to INT3).
44 to 51
P17/AN7 to
P10/AN0
G
CMOS I/O ports
Also serve as an A/D converter analog input.
P45/V2,
P44/V1
F
LCD driving power supply pins
These pins can be used as an N-ch open-drain general-purpose
I/O when not used as an LCD driving power supply.
59 to 62
P43/COM3 to
P40/COM0
F
LCD common output pins
These pins can be used as an N-ch open-drain general-purpose
I/O when not used as an LCD common output.
63 to 70
P50/SEG0 to
P57/SEG7
F
LCD segment output pins
These pins can be used as an N-ch open-drain general-purpose
I/O when not used as an LCD segment output.
71 to 78
P60/SEG8 to
P67/SEG15
F
LCD segment output pins
These pins can be used as an N-ch open-drain general-purpose
I/O when not used as an LCD segment output.
79,
80
P70/SEG16,
P71/SEG17
F
LCD segment output pins
These pins can be used as an N-ch open-drain general-purpose
I/O when not used as an LCD segment output.
1 to 6
P72/SEG18 to
P77/SEG23
F
LCD segment output pins
These pins can be used as an N-ch open-drain general-purpose
I/O when not used as an LCD segment output.
7 to 11
P80/SEG24 to
P83/SEG27
F
LCD segment output pins
These pins can be used as an N-ch open-drain general-purpose
I/O when not used as an LCD segment output.
28 to 31
57,
58
8
Pin name
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as a UART data input (UI).
General-purpose I/O ports
A pull-up resistor option is provided.
General-purpose I/O port
A pull-up resistor option is provided.
Also serves as an input capture data input.
General-purpose I/O ports
A pull-up resistor option is provided.
52
AVSS

A/D converter power supply (GND) pin
53
AVR

A/D converter reference power supply pin
54
AVCC

A/D converter power supply pin
55
VCC

Power supply pin
56
V3

LCD driving power supply pin
15
VSS

Power supply (GND) pin
MB89920 Series
• External EPROM pins (the MB89PV920 only)
Pin no.
Pin name
I/O
Function
82
83
84
85
86
87
88
89
90
91
A15
A12
A7
A6
A5
A4
A3
A2
A1
A0
O
Address output pins
93
94
95
O1
O2
O3
I
Data input pins
96
VSS
O
Power supply (GND) pin
98
99
100
101
102
O4
O5
O6
O7
O8
I
Data input pins
103
CE
O
ROM chip enable pin
Outputs “H” during standby.
104
A10
O
Address output pin
105
OE/VPP
O
ROM output enable pin
Outputs “L” at all times.
107
108
109
A11
A9
A8
O
Address output pins
110
A13
O
Address output pin
111
A14
O
Address output pin
112
VCC
O
EPROM power supply pin
81
92
97
106
N.C.
—
Internally connected pins
Be sure to leave them open.
9
MB89920 Series
■ I/O CIRCUIT TYPE
Type
Circuit
Remarks
A
• At an oscillation feedback resistor of approximately
1 MΩ (1 to 8 MHz)
X1
X0
Standby control signal
B
C
• At an output pull-up resistor of approximately 50 KΩ
(5.0 V)
• Hysteresis input
R
P-ch
N-ch
D
• CMOS output
• CMOS input
R
P-ch
P-ch
N-ch
• Pull-up resistor optional
E
• CMOS output
• CMOS input
• Hysteresis input (peripheral input)
R
P-ch
P-ch
N-ch
• Pull-up resistor optional
(Continued)
10
MB89920 Series
(Continued)
Type
Circuit
F
N-ch
Remarks
• N-ch open-drain I/O
• Also serves as LCD controller/driver common/
segment output.
P-ch
N-ch
P-ch
N-ch
G
P-ch
• CMOS I/O
• Analog input
N-ch
Analog input
11
MB89920 Series
■ HANDLING DEVICES
1. Preventing Latchup
Latchup may occur on CMOS ICs if voltage higher than VCC or lower than VSS is applied to input and output pins
other than medium- to high-voltage pins or if higher than the voltage which shows on “1. Absolute Maximum
Ratings” in section “■ Electrical Characteristics” is applied between VCC and VSS.
When latchup occurs, power supply current increases rapidly and might thermally damage elements. When
using, take great care not to exceed the absolute maximum ratings.
Also, take care to prevent the analog power supply (AVCC and AVR) and analog input from exceeding the digital
power supply (VCC) when the analog system power supply is turned on and off.
2. Treatment of Unused Input Pins
Leaving unused input pins open could cause malfunctions. They should be connected to a pull-up or pull-down
resistor.
3. Treatment of Power Supply Pins on Microcontrollers with A/D and D/A Converters
Connect to be AVCC = DAVC = VCC and AVSS = AVR = VSS even if the A/D and D/A converters are not in use.
4. Treatment of N.C. Pins
Be sure to leave (internally connected) N.C. pins open.
5. Power Supply Voltage Fluctuations
Although VCC power supply voltage is assured to operate within the rated range, a rapid fluctuation of the voltage
could cause malfunctions, even if it occurs within the rated range. Stabilizing voltage supplied to the IC is therefore
important. As stabilization guidelines, it is recommended to control power so that VCC ripple fluctuations (P-P
value) will be less than 10% of the standard VCC value at the commercial frequency (50 to 60 Hz) and the transient
fluctuation rate will be less than 0.1 V/ms at the time of a momentary fluctuation such as when power is switched.
6. Precautions when Using an External Clock
Even when an external clock is used, oscillation stabilization time is required for power-on reset (optional) and
wake-up from stop mode.
12
MB89920 Series
■ PROGRAMMING TO THE EPROM ON THE MB89P928
The MB89P928 is an OTPROM version of the MB89920 series.
1. Features
• 48-Kbyte PROM on chip
• Options can be set using the EPROM programmer.
• Equivalency to the MBM27C1001A in EPROM mode (when programmed with the EPROM programmer)
2. Memory Space
Memory space in the EPROM mode is diagrammed below.
Address
Normal operating mode
0000H
EPROM mode
(Corresponding addresses on the EPROM programmer)
0000H
I/O
0080H
0100H
0200H
Vacancy
Register
(Read value undefined)
RAM
0480H
0FE4H
Option area
Not available
1000H
Vacancy
(Read value undefined)
4000H
4000H
Program area
(EPROM)
ROM
FFFFH
FFFFH
Vacancy
(Read value undefined)
1FFFH
13
MB89920 Series
3.Programming to the EPROM
In EPROM mode, the MB89P928 functions equivalent to the MBM27C1001A. This allows the PROM to be
programmed with a general-purpose EPROM programmer (the electronic signature mode cannot be used) by
using the dedicated socket adapter.
• Programming procedure
(1) Set the EPROM programmer to the MBM27C1001A.
(2) Load program data into the EPROM programmer at 0FE4H to FFFFH.
(3) Program with the EPROM programmer.
4. Recommended Screening Conditions
High-temperature aging is recommended as the pre-assembly screening procedure for a product with a blanked
OTPROM microcomputer program.
Program, verify
Aging
+150 °C, 48 Hrs.
Data verification
Assembly
5. Programming Yield
All bits cannot be programmed at Fujitsu shipping test to a blanked OTPROM microcomputer, due to its nature.
For this reason, a programming yield of 100% cannot be assured at all times.
6. EPROM Programmer Socket Adapter
Package
FPT-80P-M06
Compatible socket adapter
ROM-80QF-32DP-8LA
Inquiry: Sun Hayato Co., Ltd.: TEL 81-3-3802-5760
Note: Depending on the EPROM programmer, inserting a capacitor of about 0.1 µF between VPP and VSS or VCC
and VSS can stabilize programming operations.
14
MB89920 Series
7. PROM Option Bit Map
Bit 7
Bit 6
Bit 5
Vacancy
Vacancy
Vacancy
Bit 1
Bit 0
Oscillation
stabilization
time
1: Crystal
0: Ceramic
Reset pin
output
Power-on
reset
Vacancy
Vacancy
Readable
Readable
Readable
1: Yes
0: No
1: Yes
0: No
Readable
Readable
0FE8H
P07
Pull-up
1: No
0: Yes
P06
Pull-up
1: No
0: Yes
P05
Pull-up
1: No
0: Yes
P04
Pull-up
1: No
0: Yes
P03
Pull-up
1: No
0: Yes
P02
Pull-up
1: No
0: Yes
P01
Pull-up
1: No
0: Yes
P00
Pull-up
1: No
0: Yes
0FECH
P27
Pull-up
1: No
0: Yes
P26
Pull-up
1: No
0: Yes
P25
Pull-up
1: No
0: Yes
P24
Pull-up
1: No
0: Yes
P23
Pull-up
1: No
0: Yes
P22
Pull-up
1: No
0: Yes
P21
Pull-up
1: No
0: Yes
P20
Pull-up
1: No
0: Yes
Vacancy
Vacancy
Vacancy
Vacancy
Vacancy
Readable
Readable
Readable
Readable
Readable
P32
Pull-up
1: No
0: Yes
P31
Pull-up
1: No
0: Yes
P30
Pull-up
1: No
0: Yes
P97
Pull-up
1: No
0: Yes
P96
Pull-up
1: No
0: Yes
P95
Pull-up
1: No
0: Yes
P94
Pull-up
1: No
0: Yes
P93
Pull-up
1: No
0: Yes
P92
Pull-up
1: No
0: Yes
P91
Pull-up
1: No
0: Yes
P90
Pull-up
1: No
0: Yes
Vacancy
Vacancy
WDT/lowLow-voltage detection
voltage
voltage
control
1: Register
00: —
01: 3.3 V
0: Option
11: 4.0 V
EPROM 10: 3.6 V
Low-voltage Low-voltage Watchdog
reset
detection
timer (WDT)
1: Yes
0: No
1:
Automatic
0:
Prohibited
1:
Automatic
0:
Prohibited
0FE4H
0FF0H
0FF4H
0FF8H Readable
0FFCH
Readable
Bit 4
Bit 3
Bit 2
Vacancy
Vacancy
Vacancy
Vacancy
Vacancy
Vacancy
Vacancy
Vacancy
Readable
Readable
Readable
Readable
Readable
Readable
Readable
Readable
Notes: • Set each bit to 1 to erase.
• Do not write 0 to the vacant bit.
The read value of the vacant bit is 1, unless 0 is written to it.
• Write the same value as each option register to the 3-byte vacant address that follows above option
registers.
Example: In the case of 0FE4H, write the same value to 0FE5H, 0FE6H and 0FF7H.
• This optional information is taken into the OTPROM while the oscillation is being reset. Therefore, if the
hardware state is initially shifted to standby state after the power supply is turned on, the optional information
will not be valid during the transition (in a state of the initial value 1).
After the hardware standby state is cleared, the oscillation starts and the optional information becomes
valid.
Note that if the hardware is shifted to the standby or stop state in the course of a normal operation
(oscillation), the contents of the optional register are valid since the option data has already been taken
into the OTPROM.
15
MB89920 Series
■ PROGRAMMING TO THE EPROM WITH PIGGYBACK/EVALUATION DEVICE
1. EPROM for Use
MBM27C512-20TV
2. Programming Socket Adapter
To program to the PROM using an EPROM programmer, use the socket adapter (manufacturer: Sun Hayato
Co., Ltd.) listed below.
Package
Adapter socket part number
LCC-32(Rectangle)
ROM-32LC-28DP-YG
LCC-32(Square)
ROM-32LC-28DP-S
Inquiry: Sun Hayato Co., Ltd.: TEL 81-3-3802-5760
3. Memory Space
Memory space in each mode is diagrammed below.
Address
Normal operating mode
Corresponding addresses on the EPROM programmer
0000H
0000H
I/O
0080H
Not available
RAM
0480H
Not available
4000H
4000H
PROM
48 KB
FFFFH
EPROM
48 KB
FFFFH
4. Programming to the EPROM
(1) Set the EPROM programmer to the MBM27C512.
(2) Load program data into the EPROM programmer at 4000H to FFFFH.
(3) Program to 4000H to FFFFH with the EPROM programmer.
16
MB89920 Series
■ BLOCK DIAGRAM
X0
X1
Operating mode
control
Oscillator
Clock control
HST
MODA
Time-base timer
Watchdog timer
CMOS I/O port
Reset circuit
RST
P91/RTO1
P90/RTO0
Output compare
Low-voltage detection
16-bit
free run counter
RAM
F2MC-8L
Input capture
P23/RTI1
P20/RTI0
UART
P32/UCK
P31/UO
P30/UI
Serial I/O
P95/SCK
P96/SO
P97/SI
CPU
P80/SEG24 to
P83/SEG27
P70/SEG16 to
P77/SEG23
P60/SEG8 to
P67/SEG15
P50/SEG0 to
P57/SEG7
4
N-ch open-drain I/O port
8
8
28
8
LCD controller
/driver
V3
P44/V1,
P45/V2
2
2
P40/COM0 to
P43/COM3
4
4
Internal bus
ROM
2-channel
8-bit PWM timer
8-bit timer #2
P94/PWM1
8-bit timer #1
P93/PWM0
AVR
10-bit
A/D converter
8
8
P10/AN0 to
P17/AN7
N-ch open-drain I/O port
P21 to P22
P24 to P27
6
CMOS I/O port
Buzzer/clock
output
4
P00/INT0 to
P03/INT3
P92/CLK
CMOS I/O port
P04 to P07
4
4
External interrupt
CMOS I/O port
17
MB89920 Series
■ CPU CORE
1. Memory Space
The microcontrollers of the MB89920 series offer a memory space of 64 Kbytes for storing all of I/O, data, and
program areas. The I/O area is located at the lowest address. The data area is provided immediately above the
I/O area. The data area can be divided into register, stack, and direct areas according to the application. The
program area is located at exactly the opposite end, that is, near the highest address. Provide the tables of
interrupt reset vectors and vector call instructions toward the highest address within the program area. The
memory space of the MB89920 series is structured as illustrated below.
Memory Space
MB89923
0000H
0080H
0100H
MB89925
0000H
I/O
RAM
0080H
0100H
Register
MB89P928
0000H
I/O
RAM
0080H
0100H
Register
0180H
0200H
MB89PV920
0000H
I/O
RAM
0080H
0100H
Register
I/O
RAM
Register
0200H
0200H
0480H
0480H
0280H
Not available
Not available
Not available
Not available
4000H
4000H
C000H
Program ROM
E000H
Program ROM
ROM
ROM
FFFFH
18
FFFFH
FFFFH
FFFFH
MB89920 Series
2. Registers
The F2MC-8L family has two types of registers; dedicated registers in the CPU and general-purpose registers
in the memory. The following dedicated registers are provided:
Program counter (PC):
A 16-bit register for indicating instruction storage positions
Accumulator (A):
A 16-bit temporary register for storing arithmetic operations, etc. When the
instruction is an 8-bit data processing instruction, the lower byte is used.
Temporary accumulator (T):
A 16-bit register which performs arithmetic operations with the accumulator
When the instruction is an 8-bit data processing instruction, the lower byte is used.
Index register (IX):
A 16-bit register for index modification
Extra pointer (EP):
A 16-bit pointer for indicating a memory address
Stack pointer (SP):
A 16-bit register for indicating a stack area
Program status (PS):
A 16-bit register for storing a register pointer, a condition code
Initial value
16 bits
FFFDH
: Program counter
PC
A
: Accumulator
Undefined
T
: Temporary accumulator
Undefined
IX
: Index register
Undefined
EP
: Extra pointer
Undefined
SP
: Stack pointer
Undefined
PS
: Program status
I-flag = 0, IL1, 0 = 11
Other bits are undefined.
The PS can further be divided into higher 8 bits for use as a register bank pointer (RP) and the lower 8 bits for
use as a condition code register (CCR). (See the diagram below.)
Structure of the Program Status Register
15
PS
14
13
12
11
10
9
8
Vacancy Vacancy Vacancy
RP
RP
7
6
H
I
5
4
IL1, 0
3
2
1
0
N
Z
V
C
CCR
19
MB89920 Series
The RP indicates the address of the register bank currently in use. The relationship between the pointer contents
and the actual address is based on the conversion rule illustrated below.
Rule for Conversion of Actual Addresses of the General-purpose Register Area
RP
Lower OP codes
“0” “0” “0” “0” “0” “0” “0” “1” R4 R3 R2 R1 R0 b2
↓
↓
↓
↓
↓
↓
↓
↓
↓
↓
↓
↓
↓
↓
b1
b0
↓
↓
Generated addresses A15 A14 A13 A12 A11 A10 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0
The CCR consists of bits indicating the results of arithmetic operations and the contents of transfer data and
bits for control of CPU operations at the time of an interrupt.
H-flag: Set when a carry or a borrow from bit 3 to bit 4 occurs as a result of an arithmetic operation. Cleared
otherwise. This flag is for decimal adjustment instructions.
I-flag:
Interrupt is allowed when this flag is set to 1. Interrupt is prohibited when the flag is set to 0. Set to 0
when reset.
IL1, 0:
Indicates the level of the interrupt currently allowed. Processes an interrupt only if its request level is
higher than the value indicated by this bit.
IL1
IL0
0
0
Interrupt level
0
1
1
0
2
1
1
3
1
High-low
High
Low = no interrupt
N-flag: Set if the MSB is set to 1 as the result of an arithmetic operation. Cleared when the bit is set to 0.
Z-flag:
Set when an arithmetic operation results in 0. Cleared otherwise.
V-flag:
Set if the complement on 2 overflows as a result of an arithmetic operation. Reset if the overflow does
not occur.
C-flag: Set when a carry or a borrow from bit 7 occurs as a result of an arithmetic operation. Cleared otherwise.
Set to the shift-out value in the case of a shift instruction.
20
MB89920 Series
The following general-purpose registers are provided:
General-purpose registers: An 8-bit register for storing data
The general-purpose registers are 8 bits and located in the register banks of the memory. One bank contains
eight registers and up to a total of 16 banks can be used on the MB89925. Up to a total of 16 banks can be
used on the MB89923. The bank currently in use is indicated by the register bank pointer (RP).
Note: The number of register banks that can be used varies with the RAM size.
Register Bank Configuration
This address = 0100H + 8 × (RP)
R0
R1
R2
R3
R4
R5
R6
R7
32 banks
Memory area
21
MB89920 Series
■ I/O MAP
Address
Read/write
Register
00H
(R/W)
PDR0
Port 0 data register
01H
(W)
DDR0
Port 0 data direction register
0000 0000B
02H
(R/W)
PDR1
Port 1 data register
XXXX XXXXB
03H
(W)
DDR1
Port 1 data direction register
0000 0000B
04H
Vacancy
05H
Vacancy
06H
Vacancy
07H
Intial value
XXXX XXXXB
Vacancy
08H
(R/W)
STBC
Standby control register
0001 XXXXB
09H
(R/W)
WDTE
Watchdog timer control register
XXXX XXXXB
0AH
(R/W)
TBCR
Time-base timer control register
XXX0 0000B
0BH
(R/W)
LVRC
Low-voltage detection reset control register
0X11 X00XB
0CH
(R/W)
PDR3
Port 3 data/peripheral I/O control register
0000 –XXXB
0DH
(W)
DDR3
Port 3 data direction register
–––– –000B
0EH
(R/W)
PDR4
Port 4 data register
––11 1111B
0FH
(R/W)
PDR5
Port 5 data register
1111 1111B
10H
(R/W)
PDR6
Port 6 data register
1111 1111B
11H
(R/W)
PDR7
Port 7 data register
1111 1111B
12H
(R/W)
PDR8
Port 8 data register
–––– 1111B
13H
(R/W)
PDR9
Port 9 data register
XXXX XXXXB
14H
(W)
DDR9
Port 9 data direction register
0000 0000B
15H
(R/W)
PDR2
Port 2 data register
XXXX XXXXB
16H
(R/W)
DDR2
Port 2 data direction register
0000 0000B
17H
(R/W)
BUZR
Buzzer control register
XXXX 0000B
18H
(R/W)
ADC1
AD converter control register 1
0000 0000B
19H
(R/W)
ADC2
AD converter control register 2
X000 0001B
1AH
(R/W)
ADCH
AD converter data register “H”
–––– ––XXB
1BH
(R/W)
ADCL
AD converter data register “L”
XXXX XXXXB
1CH
(R/W)
SMR
Serial mode register
0000 0000B
1DH
(R/W)
SDR
Serial data register
XXXX XXXXB
(W)
ICR1
Port 1 input control register
1EH
1FH
Vacancy
–: Unused X: Undefined
Note: Do not use vacancies
22
Register description
0000 0000B
(Continued)
MB89920 Series
Address
Read/write
Register
20H
(R/W)
CNTR1
PWM timer control register 1
Register description
0000 0000B
21H
(R/W)
CNTR2
PWM timer control register 2
0000 0000B
22H
(R/W)
CNTR3
PWM timer control register 3
000X 0000B
23H
(W)
COMR2
PWM timer compare register 2
XXXX XXXXB
24H
(W)
COMR1
PWM timer compare register 1
XXXX XXXXB
25H
Vacancy
26H
Vacancy
27H
Vacancy
Initial value
28H
(R/W)
TMCR
Timer control register
29H
(R)
TCHR
Timer count register (H)
00XX 0000B
0000 0000B
2AH
(R)
TCLR
Timer count register (L)
0000 0000B
2BH
(R/W)
OPCR
Output control register
0000 0000B
2CH
(R/W)
CPR0H
Output compare register 0 (H)
0000 0000B
2DH
(R/W)
CPR0L
Output compare register 0 (L)
0000 0000B
2EH
(R/W)
CPR1H
Output compare register 1 (H)
0000 0000B
2FH
(R/W)
CPR1L
Output compare register 1 (L)
0000 0000B
30H
(R/W)
ICCR
Input capture control register
X000 X000B
31H
(R/W)
ICIC
Input capture interrupt control register
X000 0X00B
32H
(R)
ICR0H
Input capture register 0 (H)
XXXX XXXXB
33H
(R)
ICR0L
Input capture register 0 (L)
XXXX XXXXB
34H
(R)
ICR1H
Input capture register 1 (H)
XXXX XXXXB
35H
(R)
ICR1L
Input capture register 1 (L)
XXXX XXXXB
36H
Vacancy
37H
Vacancy
38H
(R/W)
EIC1
External interrupt control register 1
0000 0000B
39H
(R/W)
EIC2
External interrupt control register 2
0000 0000B
3AH
Vacancy
3BH
Vacancy
3CH
Vacancy
3DH
Vacancy
3EH
Vacancy
3FH
Vacancy
–: Unused X: Undefined
(Continued)
Note: Do not use vacancies
23
MB89920 Series
(Continued)
Address
Read/write
Register
40H
(R/W)
USMR
UART mode register
41H
(R/W)
USCR
UART control register
0000 0000B
42H
(R/W)
USTR
UART status register
0000 1XXXB
43H
(R)
(W)
RXDR
TXDR
UART receiver data register
UART transmitter data register
XXXX XXXXB
XXXX XXXXB
44H
45H
Initial value
0000 0000B
Vacancy
(R/W)
RRDR
Baud rate generator/reload data register
46H
Vacancy
47H
Vacancy
48 to 5FH
XXXX XXXXB
Vacancy
60 to 6DH
(R/W)
VRAM
Display data RAM
XXXX XXXXB
70H
(R/W)
LCR1
LCD controller/driver control register 1
0000 0000B
71H
(R/W)
LCR2
LCD controller/driver control register 2
000– ––––B
72H
(R/W)
LCR3
LCD controller/driver control register 3
0000 0000B
73 to 7BH
Vacancy
7CH
(W)
ILR1
Interrupt level setting register 1
1111 1111B
7DH
(W)
ILR2
Interrupt level setting register 2
1111 1111B
7EH
(W)
ILR3
Interrupt level setting register 3
1111 1111B
7FH
–: Unused X: Undefined
Note: Do not use vacancies
24
Register description
Vacancy
MB89920 Series
■ ELECTRICAL CHARACTERISTICS
1. Absolute Maximum Ratings
(VSS = 0.0 V)
Parameter
Symbol
Value
Unit
Remarks
Min.
Max.
VCC
VSS – 0.3
VSS + 7.0
V
AVCC
VSS – 0.3
VCC + 0.3
V
*1
AVR
VSS – 0.3
VSS + 7.0
V
AVR must not exceed AVCC + 0.3
V.
LCD power supply voltage
V1 to V3
VSS – 0.3
VSS + 7.0
V
V1 ≤ V2 ≤ V3 *2
Input voltage
VI1
VSS – 0.3
VCC + 0.3
V
VO1
VSS – 0.3
VCC + 0.3
V
P00 to P07, P10 to P17, P20 to
P27, P30 to P32, P90 to P97
VO2
VSS – 0.3
VSS + 7.0
V
P40 to P45, P50 to P57, P60 to
P67, P70 to P77, P80 to P83
Must not exceed “V3 + 0.3 V”
“L” level maximum output
current
IOL

20
mA
Peak value
“L” level average output current
IOLAV

4
mA
Average value
“L” level total maximum output
current
∑IOL

100
mA
Peak value
“L” level total average output
current
∑IOLAV

40
mA
Average value
“H” level maximum output
current
IOH

–20
mA
Peak value
“H” level average output current
IOHAV

–4
mA
Average value
“H” level total maximum output
current
∑IOH

–50
mA
Peak value
“H” level total average output
current
∑IOHAV

–20
mA
Average value
Power consumption
PD

300
mW
Operating temperature
TA
–40
+85
°C
Storage temperature
Tstg
–55
+150
°C
Power supply voltage
Output voltage
*1: Use AVCC and VCC set at the same voltage.
Take care so that AVCC does not exceed VCC, such as when power is turned on.
*2: VCC must not exceed V3.
Precautions: Permanent device damage may occur if the above “Absolute Maximum Ratings” are exceeded. Functional operation should be restricted to the conditions as detailed in the operational sections of this
data sheet. Exposure to absolute maximum rating conditions for extended periods may affect device
reliability.
25
MB89920 Series
2. Recommended Operating Conditions
(VSS = 0.0 V)
Value
Symbol
Parameter
Power supply voltage
VCC
Unit
Remarks
6.0
V
Normal operation assurance range
6.0
V
MB89PV920/P928
1.5
6.0
V
Retains the RAM state in stop mode
Min.
Max.
2.2*1
2.7*1
A/D converter reference input
voltage
AVR
3.0
AVCC
V
LCD power supply voltage
V1 to V3
VSS
VSS + 6.0
V
Operating temperature
TA
–40
+85
°C
V1 ≤ V2 ≤ V3*2
*1: These values vary with the operating frequency, instruction cycle, and analog assurance range. See Figure 1
and “5. A/D Converter Electrical Characteristics.”
*2: VCC must not exceed V3.
6
Analog accuracy assured in the
AVCC = 3.5 V to 6.0 V range
5
Operating voltage (V)
Operation assurance range
4
3
2
1
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
9.0
10.0
Clock operating frequency (at an instruction cycle of 4/FC) (MHz)
4.0 2.0
0.8
0.5
Minimum execution time (instruction cycle) (µs)
Note: The shaded area is assured only for the MB89923/925.
Figure 1
Operating Voltage vs. Clock Operating Frequency
Figure 1 indicates the operating frequency of the external oscillator at an instruction cycle of 4/FC.
Since the operating voltage range is dependent on the instruction cycle, see minimum execution time if the
operating speed is switched using a gear.
26
MB89920 Series
3. DC Characteristics
(VCC = 5.0 V, VSS = 0.0 V, TA = –40°C to +85°C)
Parameter
Symbol
Pin
Condition
VIH
P00 to P07, P10 to P17,
P20 to P27, P30 to P32,
P40 to P45, P50 to P57,
P60 to P67, P70 to P77,
P80 to P83, P90 to P97
VIHS
Max.
—
0.7 VCC
—
VCC +
0.3
V
RST, MODA, HST
—
0.8 VCC
—
VCC +
0.3
V
VIL
P00 to P07, P10 to P17,
P20 to P27, P30 to P32,
P40 to P45, P50 to P57,
P60 to P67, P70 to P77,
P80 to P83, P90 to P97
—
VSS −
0.3
—
0.3 VCC
V
VILS
RST, MODA, HST
—
VSS −
0.3
—
0.2 VCC
V
VD
P40 to P45, P50 to P57,
P60 to P67, P70 to P77,
P80 to P83*1
—
VSS −
0.3
—
VSS +
6.0
V
VOH1
P00 to P07, P10 to P17,
P30 to P32, P90 to P97
IOH = –2.0 mA
4.0
—
—
V
VOH2
P20 to P27
IOH = –5.0 mA
2.4
—
—
V
VOL1
P00 to P07, P10 to P17,
P30 to P32, P40 to P45,
P50 to P57, P60 to P67,
P70 to P77, P80 to P83,
P90 to P97
IOL = 4.0 mA
—
—
0.4
V
VOL2
P20 to P27
IOL = 5.0 mA
—
—
0.4
V
“L” level input
voltage
“H” level output
voltage
Unit
Typ.
“H” level input
voltage
Open-drain
output
pin application
voltage
Value
Min.
“L” level output
voltage
Remarks
Peripheral input
of the port 0, 2,
3, and 9
Peripheral input
of the port 0, 2,
3, and 9
VOL3
RST
IOL = 4.0 mA
—
—
0.4
V
Input leakage
current
(Hi-z output
leakage
current)
ILI1
P00 to P07, P10 to P17,
P20 to P27, P30 to P32,
P40 to P45, P50 to P57,
P60 to P67, P70 to P77,
P80 to P83, P90 to P97,
MODA
0.45 V < VI <
VCC
—
—
±5
µA
Without pullup resistor
Pull-up
resistance
RPULU
P00 to P07, P20 to P27,
P30 to P32, P90 to P97
VI = 0.0 V
25
50
100
kΩ
Without pullup resistor
(Continued)
27
MB89920 Series
(VCC = 5.0 V, VSS = 0.0 V, TA = –40°C to +85°C)
Parameter
Symbol
Pin
Unit
Remarks
Typ.
Max.
VCC = 5.0 V
—
12
20
mA tinst = 0.5 µs
VCC = 5.0 V
—
3
7
mA
ICCH
TA = +25°C
—
—
1
µA
IA
when A/D
conversion is
activated
—
6
8
mA
when A/D
conversion is
stopped
TA = +25°C
—
—
1
µA
200
300
450
kΩ
ICCS
VCC
AVCC
IAH
LCD divided
resistance
Value
Min.
ICC
Power supply
current*2
Condition
RLCD
Between V3 and VSS
COM0 to 3 output
RVCOM
impedance
COM0 to 3
V1 to V 3 = 5.0 V
—
—
2.5
kΩ
SEG0 to 27
output
impedance
RVSEG
SEG0 to 27
V1 to V 3 = 5.0 V
—
—
15
kΩ
LCD controller/
driver leakage
current
ILCDL
V1 to V3, COM0 to
3,
SEG0 to 27
V1 to V 3 = 5.0 V
—
—
±1
µA
Other than AVCC,
AVSS, VCC, and VSS
f = 1 MHz
—
10
—
pF
Input capacitance CIN
Sleep mode
tinst = 0.5 µs
Stop mode
*1: VD must not exceed V3.
*2: The measurement conditions of power supply current are as follows: the external clock and TA = +25°C.
In the case of the MB89PV920, the current consumed by the connected EPROM and ICE is not included.
Note: For pins which serve as the LCD and ports (P40 to P45, P50 to P57, P60 to P67, P70 to P77, and P80 to
P83), see the port parameter when these pins are used as ports and the LCD parameter when they are used
as LCD pins.
28
MB89920 Series
4. AC Characteristics
(1) Reset Timing
(AVSS = VSS = 0.0 V, TA = –40°C to +85°C)
Symbol
Parameter
RST “L” pulse width
Value
Condition
tZLZH
—
Min.
Max.
48 tHCYL
—
Unit
Remarks
ns
tZLZH
RST
0.2 VCC
0.2 VCC
(2) Power-on Reset
(AVSS = VSS = 0.0 V, TA = –40°C to +85°C)
Parameter
Symbol
Power supply rising time
tR
Power supply cut-off time
tOFF
Condition
—
Value
Unit
Remarks
Min.
Max.
—
50
ms
Power-on reset function only
1
—
ms
Due to repeated operations
Note: Make sure that power supply rises within the selected oscillation stabilization time.
If power supply voltage needs to be varied in the course of operation, a smooth voltage rise is
recommended.
tR
tOFF
2.0 V
VCC
0.2 V
0.2 V
0.2 V
29
MB89920 Series
(3) Clock Timing
(AVSS = VSS = 0.0 V, TA = –40°C to +85°C)
Symbol
Parameter
Clock frequency
Pin
Value
Condition
Min.
Max.
Unit
Remarks
FC
X0, X1
1
8
MHz
Clock cycle time
tXCYL
X0, X1
125
1000
ns
Input clock pulse width
PWH
PWL
X0
20
—
ns
External clock
Input clock rising/falling
time
tCR
tCF
X0
—
10
ns
External clock
—
X0 and X1 Timing and Conditions
tXCYL
PWH
PWL
tCF
tCR
0.8 VCC
0.8 VCC
X0
0.2 VCC
0.2 VCC
0.2 VCC
Clock Conditions
When a crystal
or
ceramic resonator is used
X0
When an external clock is used
X1
X0
FC
C1
X1
Open
C2
(4) Instruction Cycle
Parameter
Symbol
Instruction cycle
tinst
(minimum execution time)
30
Value (typical)
4/FC
Unit
µs
Remarks
(4/FC) tinst = 0.5 µs when operating at
FC = 8 MHz
MB89920 Series
(5) Serial I/O Timing
(AVCC = VCC = +5.0 V±10%, AVSS = VSS= 0.0 V, TA = –40°C to +85°C)
Parameter
Symbol
Pin
Condition
Value
Min.
Max.
Unit
Serial clock cycle time
tSCYC
SCK
2 tinst*
—
µs
SCK ↓ → SO time
tSLOV
SCK, SO
–200
200
ns
Valid SI → SCK ↑
tIVSH
SI, SCK
1/2 tinst*
—
µs
SCK ↑ → valid SI hold time
tSHIX
SCK, SI
1/2 tinst*
—
µs
Serial clock “H” pulse width
tSHSL
SCK
1 tinst*
—
µs
Serial clock “L” pulse width
tSLSH
SCK
1 tinst*
—
µs
Internal shift
clock mode
External shift
clock mode
SCK ↓ → SO time
tSLOV
SCK, SO
0
200
ns
Valid SI → SCK ↑
tIVSH
SI, SCK
1/2 tinst*
—
µs
SCK ↑ → valid SI hold time
tSHIX
SCK, SI
1/2 tinst*
—
µs
Remarks
* : For information on tinst, see “(4) Instruction Cycle.”
Internal Shift Clock Mode
tSCYC
SCK
2.4 V
0.8 V
0.8 V
tSLOV
2.4 V
SO
0.8 V
tIVSH
tSHIX
0.8 VCC
0.8 VCC
0.2 VCC
0.2 VCC
SI
External Shift Clock Mode
tSLSH
tSHSL
SCK
0.8 VCC
0.2 VCC
0.8 VCC
0.2 VCC
tSLOV
2.4 V
SO
0.8 V
tIVSH
tSHIX
0.8 VCC
0.8 VCC
0.2 VCC
0.2 VCC
SI
31
MB89920 Series
(6) Peripheral Input Timing
(VCC = +5.0 V±10%, AVSS = VSS= 0.0 V, TA = –40°C to +85°C)
Symbol
Parameter
Value
Pin
Min.
Max.
Peripheral input “H” pulse width 1
tILIH1
INT0 to INT3, RTI0, 1
2 tinst*
—
—
Peripheral input “L” pulse width 1
tIHIL1
INT0 to INT3, RTI0, 1
2 tinst*
—
—
* : For information on tinst, see “(4) Instruction Cycle.”
tIHIL1
RTI0, 1
INT0 to 3
tILIH1
0.8 VCC
0.2 VCC
32
Unit
0.2 VCC
0.8 V CC
Remarks
MB89920 Series
5. A/D Converter Electrical Characteristics
(AVCC = VCC = +3.5 V to +6.0 V, FC = 8 MHZ, AVSS = VSS = 0.0 V, TA = –40°C to +85°C)
Parameter
Symbol
Pin
Condition
Value
Typ.
Resolution
—
—
10
bit
Linearity error
—
—
±2.0
LSB
—
Differential linearity error
—
Differential total error
Zero transition voltage VOT
AN0 to AN7
Full-scale transition
voltage
AN0 to AN7
VFST
Interchannel disparity
—
AVCC = AVR =
VCC
—
A/D mode conversion time
Analog port input current
VAIN
Analog input voltage
—
Reference voltage
Reference voltage
supply current
AN0 to AN7
IR
At 8-MHZ oscillattion
Max.
Unit
Min.
—
—
±1.5
LSB
—
—
±3.0
LSB
AVSS – 1.5 LSB
AVSS + 0.5 LSB
AVSS + 2.5 LSB
mV
AVR – 3.5 LSB
AVR – 1.5 LSB
AVR + 0.5 LSB
mV
—
—
4
LSB
—
—
16.5
µs
—
—
10
µA
AN0 to AN7
0.0
—
AVR
V
AVR
0.0
—
AVCC
V
—
200

µA
AVR
AVR = 5.0 V
Precautions: • The smaller | AVR – AVSS |, the greater the error would become relatively.
• The output impedance of the external circuit for the analog input must satisfy the following conditions:
Output impedance of the external circuit < Approx. 10 kΩ
If the output impedance of the external circuit is too high, an analog voltage sampling time might be
insufficient (sampling time = 7.5 µs at 8 MHz oscillation).
An analog input equivalent circuit is shown below.
Sample hold circuit
R ≤ 10 kΩ is
recommended.
.
C =. 60 pF
AN
.
R =. 3 kΩ
Comparator
(
)
Analog channel selector
If R > 10 kΩ, it is recommended
to connect an external capacitor
of approx. 0.1 µF.
Close for approx. 15 instruction cycles
after activating A/D conversion.
Microcontroller’s internal circuit
Since the A/D converter contains sample hold circuit, the level of the analog input pin might not stabilize within the
sampling period after A/D activation, resulting in inaccurate A/D conversion values, if the input impedance to the
analog pin is too high. Be sure to maintain an appropriate input impedance to the analog pin.
It is recommended to keep the input impedance to the analog pin not exceed 10 kΩ. If it exceeds 10 kΩ, it is
recommended to connect a capacitor of about 0.1 µF for the analog input pin.
Except for the sampling period after A/D activation, the input leakage current of the analog input pin is less than 10 µA.
33
MB89920 Series
(1) A/D Converter Glossary
• Resolution
Analog changes that are identifiable with the A/D converter.
• Linearity error
The deviation of the straight line connecting the zero transition point (“00 0000 0000” ↔ “00 0000 0001”) with
the full-scale transition point (“11 1111 1111” ↔ “11 1111 1110”) from actual conversion characteristics
• Differential linearity error
The deviation of input voltage needed to change the output code by 1 LSB from the theoretical value
• Total error
The difference between theoretical and actual conversion values, caused by the zero transition error, full-scale
transition error, linearity error, quantization error, and noise.
Theoreticall I/O characteristics
Total error
VFST
3FF
3FF
3FE
3FE
3FD
1.5 LSB
Digital output
Digital output
3FD
004
003
Actual conversion
value
{1 LSB × N + 0.5 LSB}
004
VNT
003
VOT
002
Actual conversion
value
002
1 LSB
Theoretical value
001
001
0.5 LSB
AVSS
AVR
1 LSB =
VFST − VOT
1022
AVSS
AVR
Analog input
Analog input
(V)
Total error of digital output N =
VNT − {1 LSB × N + 0.5 LSB}
1 LSB
(Continued)
34
MB89920 Series
(Continued)
Zero transition error
Full-scale transition error
004
Theoretical value
Actual conversion
value
3FF
Actual conversion
value
Digital output
Digital output
003
002
Theoretical
value
3FE
VFST (Actual
measured value)
3FD
Actual conversion
value
Actual conversion
value
001
3FC
VOT (Actual measured value)
AVSS
3FF
AVR
Analog input
Analog input
Linearity error
Differential linearity error
Theoretical value
Actual conversion
value
N+1
3FE
{1 LSB × N + VOT}
Actual conversion
value
VFST (Actual
measured
VNT value)
004
003
V(N + 1)T
N
N–1
Actual conversion
value
002
Digital output
Digital output
3FD
VNT
Actual conversion
value
Theoretical value
N–2
001
VOT (Actual measured value)
AVSS
AVR
Analog input
Linearity error of digital output N =
AVSS
AVR
Analog input
VNT – {1 LSB × N + VOT}
1 LSB
Differential linearity error of digital output N =
V(N+1)T – VNT
1 LSB
–1
35
MB89920 Series
6. Low-voltage Detection Reset
(AVSS = VSS = 0.0 V, TA = –40°C to +85°C)
Symbol
Parameter
Voltage detected at power supply
voltage drop
Value
Condition
Min.
Max.
Unit
VDL1
3.00
3.60
V
VDL2
3.30
3.90
V
VDL3
3.70
4.30
V
VDH1
3.10
3.80
V
VDH2
3.40
4.10
V
VDH3
3.80
4.50
V
Hysteresis width
∆V
0.10
—
V
Reset ignore time
tL
0.3
—
µs
Reset sense time
tLW
16 tXCYL
—
ns
Reset detection deley time
tD
—
2.0
µs
Voltage regulation (V∆/t∆)
VCR
—
0.10
V/µs
Voltage detected at power supply
voltage rise
Remarks
*1
*1: VDH and VDL can be set for the MB89923 and MB89925 by mask options; for the MB89PV920 and MB89P928
by registers.
Power supply voltage
VCC
VDH*
VDL*
t∆
∆V
V∆
tD
tOSC
tOSC
tD
RUN
RESET
tOSC oscillation stabilization time 219 = 65.5 ms (f = 8 MHz)
Power supply voltage
VCC
over than tLW
less than tL
VDH*
VDL*
t
RUN
RESET
36
Not reset
Reset
t
MB89920 Series
■ INSTRUCTIONS (136 INSTRUCTIONS)
Execution instructions can be divided into the following four groups:
• Transfer
• Arithmetic operation
• Branch
• Others
Table 1 lists symbols used for notation of instructions.
Table 1
Symbol
dir
off
ext
#vct
#d8
#d16
dir: b
rel
@
A
AH
AL
T
TH
TL
IX
EP
PC
SP
PS
dr
CCR
RP
Ri
×
(×)
(( × ))
Instruction Symbols
Meaning
Direct address (8 bits)
Offset (8 bits)
Extended address (16 bits)
Vector table number (3 bits)
Immediate data (8 bits)
Immediate data (16 bits)
Bit direct address (8:3 bits)
Branch relative address (8 bits)
Register indirect (Example: @A, @IX, @EP)
Accumulator A (Whether its length is 8 or 16 bits is determined by the instruction in use.)
Upper 8 bits of accumulator A (8 bits)
Lower 8 bits of accumulator A (8 bits)
Temporary accumulator T (Whether its length is 8 or 16 bits is determined by the instruction in use.)
Upper 8 bits of temporary accumulator T (8 bits)
Lower 8 bits of temporary accumulator T (8 bits)
Index register IX (16 bits)
Extra pointer EP (16 bits)
Program counter PC (16 bits)
Stack pointer SP (16 bits)
Program status PS (16 bits)
Accumulator A or index register IX (16 bits)
Condition code register CCR (8 bits)
Register bank pointer RP (5 bits)
General-purpose register Ri (8 bits, i = 0 to 7)
Indicates that the very × is the immediate data.
(Whether its length is 8 or 16 bits is determined by the instruction in use.)
Indicates that the contents of × is the target of accessing.
(Whether its length is 8 or 16 bits is determined by the instruction in use.)
The address indicated by the contents of × is the target of accessing.
(Whether its length is 8 or 16 bits is determined by the instruction in use.)
Columns indicate the following:
Mnemonic: Assembler notation of an instruction
~:
The number of instructions
#:
The number of bytes
Operation: Operation of an instruction
TL, TH, AH:
A content change when each of the TL, TH, and AH instructions is executed. Symbols in
the column indicate the following:
• “–” indicates no change.
• dH is the 8 upper bits of operation description data.
• AL and AH must become the contents of AL and AH prior to the instruction executed.
• 00 becomes 00.
N, Z, V, C:
An instruction of which the corresponding flag will change. If + is written in this column,
the relevant instruction will change its corresponding flag.
OP code:
Code of an instruction. If an instruction is more than one code, it is written according to
the following rule:
Example: 48 to 4F ← This indicates 48, 49, ... 4F.
37
MB89920 Series
Table 2
Mnemonic
~
#
Operation
TL
TH
AH
NZVC
OP code
MOV dir,A
MOV @IX +off,A
MOV ext,A
MOV @EP,A
MOV Ri,A
MOV A,#d8
MOV A,dir
MOV A,@IX +off
MOV A,ext
MOV A,@A
MOV A,@EP
MOV A,Ri
MOV dir,#d8
MOV @IX +off,#d8
MOV @EP,#d8
MOV Ri,#d8
MOVW dir,A
MOVW @IX +off,A
3
4
4
3
3
2
3
4
4
3
3
3
4
5
4
4
4
5
2
2
3
1
1
2
2
2
3
1
1
1
3
3
2
2
2
2
–
–
–
–
–
AL
AL
AL
AL
AL
AL
AL
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
––––
––––
––––
––––
––––
++––
++––
++––
++––
++––
++––
++––
––––
––––
––––
––––
––––
––––
45
46
61
47
48 to 4F
04
05
06
60
92
07
08 to 0F
85
86
87
88 to 8F
D5
D6
MOVW ext,A
MOVW @EP,A
MOVW EP,A
MOVW A,#d16
MOVW A,dir
MOVW A,@IX +off
5
4
2
3
4
5
3
1
1
3
2
2
–
–
–
AL
AL
AL
–
–
–
AH
AH
AH
–
–
–
dH
dH
dH
––––
––––
––––
++––
++––
++––
D4
D7
E3
E4
C5
C6
MOVW A,ext
MOVW A,@A
MOVW A,@EP
MOVW A,EP
MOVW EP,#d16
MOVW IX,A
MOVW A,IX
MOVW SP,A
MOVW A,SP
MOV @A,T
MOVW @A,T
MOVW IX,#d16
MOVW A,PS
MOVW PS,A
MOVW SP,#d16
SWAP
SETB dir: b
CLRB dir: b
XCH A,T
XCHW A,T
XCHW A,EP
XCHW A,IX
XCHW A,SP
MOVW A,PC
5
4
4
2
3
2
2
2
2
3
4
3
2
2
3
2
4
4
2
3
3
3
3
2
3
1
1
1
3
1
1
1
1
1
1
3
1
1
3
1
2
2
1
1
1
1
1
1
(dir) ← (A)
( (IX) +off ) ← (A)
(ext) ← (A)
( (EP) ) ← (A)
(Ri) ← (A)
(A) ← d8
(A) ← (dir)
(A) ← ( (IX) +off)
(A) ← (ext)
(A) ← ( (A) )
(A) ← ( (EP) )
(A) ← (Ri)
(dir) ← d8
( (IX) +off ) ← d8
( (EP) ) ← d8
(Ri) ← d8
(dir) ← (AH),(dir + 1) ← (AL)
( (IX) +off) ← (AH),
( (IX) +off + 1) ← (AL)
(ext) ← (AH), (ext + 1) ← (AL)
( (EP) ) ← (AH),( (EP) + 1) ← (AL)
(EP) ← (A)
(A) ← d16
(AH) ← (dir), (AL) ← (dir + 1)
(AH) ← ( (IX) +off),
(AL) ← ( (IX) +off + 1)
(AH) ← (ext), (AL) ← (ext + 1)
(AH) ← ( (A) ), (AL) ← ( (A) ) + 1)
(AH) ← ( (EP) ), (AL) ← ( (EP) + 1)
(A) ← (EP)
(EP) ← d16
(IX) ← (A)
(A) ← (IX)
(SP) ← (A)
(A) ← (SP)
( (A) ) ← (T)
( (A) ) ← (TH),( (A) + 1) ← (TL)
(IX) ← d16
(A) ← (PS)
(PS) ← (A)
(SP) ← d16
(AH) ↔ (AL)
(dir): b ← 1
(dir): b ← 0
(AL) ↔ (TL)
(A) ↔ (T)
(A) ↔ (EP)
(A) ↔ (IX)
(A) ↔ (SP)
(A) ← (PC)
AL
AL
AL
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
AL
AL
–
–
–
–
AH
AH
AH
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
AH
–
–
–
–
dH
dH
dH
dH
–
–
dH
–
dH
–
–
–
dH
–
–
AL
–
–
–
dH
dH
dH
dH
dH
++––
++––
++––
––––
––––
––––
––––
––––
––––
––––
––––
––––
––––
++++
––––
––––
––––
––––
––––
––––
––––
––––
––––
––––
C4
93
C7
F3
E7
E2
F2
E1
F1
82
83
E6
70
71
E5
10
A8 to AF
A0 to A7
42
43
F7
F6
F5
F0
Note
38
Transfer Instructions (48 instructions)
During byte transfer to A, T ← A is restricted to low bytes.
Operands in more than one operand instruction must be stored in the order in which their mnemonics
are written. (Reverse arrangement of F2MC-8 family)
MB89920 Series
Table 3
~
#
ADDC A,Ri
ADDC A,#d8
ADDC A,dir
ADDC A,@IX +off
ADDC A,@EP
ADDCW A
ADDC A
SUBC A,Ri
SUBC A,#d8
SUBC A,dir
SUBC A,@IX +off
SUBC A,@EP
SUBCW A
SUBC A
INC Ri
INCW EP
INCW IX
INCW A
DEC Ri
DECW EP
DECW IX
DECW A
MULU A
DIVU A
ANDW A
ORW A
XORW A
CMP A
CMPW A
RORC A
Mnemonic
3
2
3
4
3
3
2
3
2
3
4
3
3
2
4
3
3
3
4
3
3
3
19
21
3
3
3
2
3
2
1
2
2
2
1
1
1
1
2
2
2
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
ROLC A
2
1
CMP A,#d8
CMP A,dir
CMP A,@EP
CMP A,@IX +off
CMP A,Ri
DAA
DAS
XOR A
XOR A,#d8
XOR A,dir
XOR A,@EP
XOR A,@IX +off
XOR A,Ri
AND A
AND A,#d8
AND A,dir
2
3
3
4
3
2
2
2
2
3
3
4
3
2
2
3
2
2
1
2
1
1
1
1
2
2
1
2
1
1
2
2
Arithmetic Operation Instructions (62 instructions)
Operation
TL
TH
AH
NZVC
OP code
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
dL
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
00
–
–
–
–
–
–
–
–
–
–
–
dH
–
–
–
–
–
–
dH
–
–
–
–
dH
–
–
–
dH
dH
00
dH
dH
dH
–
–
–
++++
++++
++++
++++
++++
++++
++++
++++
++++
++++
++++
++++
++++
++++
+++–
––––
––––
++––
+++–
––––
––––
++––
––––
––––
++R–
++R–
++R–
++++
++++
++–+
28 to 2F
24
25
26
27
23
22
38 to 3F
34
35
36
37
33
32
C8 to CF
C3
C2
C0
D8 to DF
D3
D2
D0
01
11
63
73
53
12
13
03
C ← A←
–
–
–
++–+
02
(A) − d8
(A) − (dir)
(A) − ( (EP) )
(A) − ( (IX) +off)
(A) − (Ri)
Decimal adjust for addition
Decimal adjust for subtraction
(A) ← (AL) ∀ (TL)
(A) ← (AL) ∀ d8
(A) ← (AL) ∀ (dir)
(A) ← (AL) ∀ ( (EP) )
(A) ← (AL) ∀ ( (IX) +off)
(A) ← (AL) ∀ (Ri)
(A) ← (AL) ∧ (TL)
(A) ← (AL) ∧ d8
(A) ← (AL) ∧ (dir)
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
++++
++++
++++
++++
++++
++++
++++
++R–
++R–
++R–
++R–
++R–
++R–
++R–
++R–
++R–
14
15
17
16
18 to 1F
84
94
52
54
55
57
56
58 to 5F
62
64
65
(A) ← (A) + (Ri) + C
(A) ← (A) + d8 + C
(A) ← (A) + (dir) + C
(A) ← (A) + ( (IX) +off) + C
(A) ← (A) + ( (EP) ) + C
(A) ← (A) + (T) + C
(AL) ← (AL) + (TL) + C
(A) ← (A) − (Ri) − C
(A) ← (A) − d8 − C
(A) ← (A) − (dir) − C
(A) ← (A) − ( (IX) +off) − C
(A) ← (A) − ( (EP) ) − C
(A) ← (T) − (A) − C
(AL) ← (TL) − (AL) − C
(Ri) ← (Ri) + 1
(EP) ← (EP) + 1
(IX) ← (IX) + 1
(A) ← (A) + 1
(Ri) ← (Ri) − 1
(EP) ← (EP) − 1
(IX) ← (IX) − 1
(A) ← (A) − 1
(A) ← (AL) × (TL)
(A) ← (T) / (AL),MOD → (T)
(A) ← (A) ∧ (T)
(A) ← (A) ∨ (T)
(A) ← (A) ∀ (T)
(TL) − (AL)
(T) − (A)
→ C→A
(Continued)
39
MB89920 Series
(Continued)
Mnemonic
AND A,@EP
AND A,@IX +off
AND A,Ri
OR A
OR A,#d8
OR A,dir
OR A,@EP
OR A,@IX +off
OR A,Ri
CMP dir,#d8
CMP @EP,#d8
CMP @IX +off,#d8
CMP Ri,#d8
INCW SP
DECW SP
~
#
Operation
3
4
3
2
2
3
3
4
3
5
4
5
4
3
3
1
2
1
1
2
2
1
2
1
3
2
3
2
1
1
(A) ← (AL) ∧ ( (EP) )
(A) ← (AL) ∧ ( (IX) +off)
(A) ← (AL) ∧ (Ri)
(A) ← (AL) ∨ (TL)
(A) ← (AL) ∨ d8
(A) ← (AL) ∨ (dir)
(A) ← (AL) ∨ ( (EP) )
(A) ← (AL) ∨ ( (IX) +off)
(A) ← (AL) ∨ (Ri)
(dir) – d8
( (EP) ) – d8
( (IX) + off) – d8
(Ri) – d8
(SP) ← (SP) + 1
(SP) ← (SP) – 1
Table 4
Mnemonic
BZ/BEQ rel
BNZ/BNE rel
BC/BLO rel
BNC/BHS rel
BN rel
BP rel
BLT rel
BGE rel
BBC dir: b,rel
BBS dir: b,rel
JMP @A
JMP ext
CALLV #vct
CALL ext
XCHW A,PC
RET
RETI
~
#
3
3
3
3
3
3
3
3
5
5
2
3
6
6
3
4
6
2
2
2
2
2
2
2
2
3
3
1
3
1
3
1
1
1
Mnemonic
PUSHW A
POPW A
PUSHW IX
POPW IX
NOP
CLRC
SETC
CLRI
SETI
40
~
#
4
4
4
4
1
1
1
1
1
1
1
1
1
1
1
1
1
1
TH
AH
NZVC
OP code
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
++R–
++R–
++R–
++R–
++R–
++R–
++R–
++R–
++R–
++++
++++
++++
++++
––––
––––
67
66
68 to 6F
72
74
75
77
76
78 to 7F
95
97
96
98 to 9F
C1
D1
Branch Instructions (17 instructions)
Operation
If Z = 1 then PC ← PC + rel
If Z = 0 then PC ← PC + rel
If C = 1 then PC ← PC + rel
If C = 0 then PC ← PC + rel
If N = 1 then PC ← PC + rel
If N = 0 then PC ← PC + rel
If V ∀ N = 1 then PC ← PC + rel
If V ∀ N = 0 then PC ← PC + reI
If (dir: b) = 0 then PC ← PC + rel
If (dir: b) = 1 then PC ← PC + rel
(PC) ← (A)
(PC) ← ext
Vector call
Subroutine call
(PC) ← (A),(A) ← (PC) + 1
Return from subrountine
Return form interrupt
Table 5
TL
TL
TH
AH
NZVC
OP code
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
dH
–
–
––––
––––
––––
––––
––––
––––
––––
––––
–+––
–+––
––––
––––
––––
––––
––––
––––
Restore
FD
FC
F9
F8
FB
FA
FF
FE
B0 to B7
B8 to BF
E0
21
E8 to EF
31
F4
20
30
Other Instructions (9 instructions)
Operation
TL
TH
AH
NZVC
OP code
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
dH
–
–
–
–
–
–
–
––––
––––
––––
––––
––––
–––R
–––S
––––
––––
40
50
41
51
00
81
91
80
90
L
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R0
A,R0
A,R0
A,R0
R0,A
A,R0
A,R0
A,R0
R0,#d8
R0,#d8
dir: 0 dir: 0,rel
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R1
A,R1
A,R1
A,R1
R1,A
A,R1
A,R1
A,R1
R1,#d8
R1,#d8
dir: 1 dir: 1,rel
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R2
A,R2
A,R2
A,R2
R2,A
A,R2
A,R2
A,R2
R2,#d8
R2,#d8
dir: 2 dir: 2,rel
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R3
A,R3
A,R3
A,R3
R3,A
A,R3
A,R3
A,R3
R3,#d8
R3,#d8
dir: 3 dir: 3,rel
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R4
A,R4
A,R4
A,R4
R4,A
A,R4
A,R4
A,R4
R4,#d8
R4,#d8
dir: 4 dir: 4,rel
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R5
A,R5
A,R5
A,R5
R5,A
A,R5
A,R5
A,R5
R5,#d8
R5,#d8
dir: 5 dir: 5,rel
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R6
A,R6
A,R6
A,R6
R6,A
A,R6
A,R6
A,R6
R6,#d8
R6,#d8
dir: 6 dir: 6,rel
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
SETB
BBS
INC
A,R7
A,R7
A,R7
A,R7
R7,A
A,R7
A,R7
A,R7
R7,#d8
R7,#d8
dir: 7 dir: 7,rel
9
A
B
C
D
E
F
A
SUBC
A
XCH
A, T
XOR
A
AND
A
OR
A
MOV
MOV
CLRB
BBC
INCW
DECW
MOVW
MOVW
@A,T
A,@A
dir: 2 dir: 2,rel
IX
IX
IX,A
A,IX
XOR
AND
OR
DAA
A,#d8
A,#d8
A,#d8
DAS
R7
R6
R5
R4
R3
R2
R1
R0
DEC
DEC
DEC
DEC
DEC
DEC
DEC
DEC
CALLV
BP
#2
CALLV
BC
#1
CALLV
BZ
#5
rel
CALLV
BNZ
#4
rel
R7
CALLV
BLT
#7
rel
CALLV
BGE
R6
#6
rel
R5
R4
rel
rel
rel
CALLV
BNC
#0
rel
CALLV
BN
R3
#3
R2
R1
R0
CLRB
BBC
MOVW
MOVW
MOVW
XCHW
dir: 4 dir: 4,rel
A,ext
ext,A
A,#d16
A,PC
ADDCW SUBCW XCHW
XORW
ANDW
ORW
MOVW
MOVW
CLRB
BBC
INCW
DECW
MOVW
MOVW
A
A
A, T
A
A
A
@A,T
A,@A
dir: 3 dir: 3,rel
EP
EP
EP,A
A,EP
ADDC
CLRB
BBC
INCW
DECW
MOVW
MOVW
dir: 1 dir: 1,rel
SP
SP
SP,A
A,SP
8
A
A
SETC
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
CLRB
BBC
MOVW
MOVW
MOVW
XCHW
A,@EP
A,@EP
A,@EP
A,@EP
@EP,A
A,@EP
A,@EP
A,@EP @EP,#d8 @EP,#d8
dir: 7 dir: 7,rel
A,@EP
@EP,A EP,#d16
A,EP
CMPW
CMP
JMP
CALL
PUSHW POPW
MOV
MOVW
CLRC
addr16
addr16
IX
IX
ext,A
PS,A
7
F
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
CLRB
BBC
MOVW
MOVW
MOVW
XCHW
A,@IX +d A,@IX +d A,@IX +d A,@IX +d @IX +d,A A,@IX +d A,@IX +d A,@IX +d @IX +d,#d8 @IX +d,#d8
dir: 6
dir: 6,rel A,@IX +d @IX +d,A
IX,#d16
A,IX
E
6
D
MOV
CMP
ADDC
SUBC
MOV
XOR
AND
OR
MOV
CMP
CLRB
BBC
MOVW
MOVW
MOVW
XCHW
A,dir
A,dir
A,dir
A,dir
dir,A
A,dir
A,dir
A,dir
dir,#d8
dir,#d8
dir: 5 dir: 5,rel
A,dir
dir,A SP,#d16
A,SP
C
5
B
CLRB
BBC
INCW
DECW
JMP
MOVW
dir: 0 dir: 0,rel
A
A
@A
A,PC
A
MOV
CMP
ADDC
SUBC
A,#d8
A,#d8
A,#d8
A,#d8
A
A
DIVU
SETI
9
4
8
RORC
7
3
6
ROLC
A
5
PUSHW POPW
MOV
MOVW
CLRI
A
A
A,ext
A,PS
4
2
A
RETI
3
MULU
RET
2
1
SWAP
1
NOP
0
0
H
MB89920 Series
■ INSTRUCTION MAP
41
MB89920 Series
■
MASK OPTIONS
Part number
MB89923
MB89925
MB89P928
MB89PV920
Specifying procedure
Specify when
ordering
masking
Set with EPROM
programmer
Setting not
possible
Can be set per pin
No pull-up resistor
Selectable
Can be set
With power-on
reset
Selectable
Can be set
Crystal oscillator
(32.8 ms/8 MHZ)
No.
1
2
Pull-up resistors
P00 to P07, P20 to P27,
P30 to P32, P90 to P97
Power-on reset
Power-on reset provided
No power-on reset
P00 to P07, P20 to P27,
P30 to P32, P90 to P97
: Selectable by pin
Oscillation stabilization time slection (at 8 HZ)
3
42
Cystal oscillator
(32.8 ms/8MHZ)
Ceramic oscillator
(2.05 ms/8 MHZ)
4
Reset pin output
Reset output provided
No reset output
Selectable
Can be set
With reset output
5
Watchdog timer
Activation prohibited
Automatic activation
Selectable
Can be set
Inactive by default
(Can be activated
by software)
6
Low-voltage detection reset circuit
Activation prohibited
Automatic activation
Selectable
Can be set
Inactive by default
(Can be activated
by software)
7
Low-voltage detection reset output
Output disabled
Output enabled
Selectable
Can be set
Inactive by default
(Can be activated
by software)
8
Low-voltage detection voltage
3.3 V ± 0.3 V
3.6 V ± 0.3 V
4.0 V ± 0.3 V
Selectable
Can be set
Register setting
9
Low-voltage detection reset/watchdog
timer function selection
Register setting valid
Option setting valid
Selectable
Can be set
Fixed to register
setting
MB89920 Series
■ ORDERING INFORMATION
Part number
MB89923PF
MB89925PF
MB89P928PF
MB89PV920CF
Package
Remarks
80-pin Plastic QFP
(FPT-80P-M06)
80-pin Ceramic MQFP
(MQP-80C-P01)
43
MB89920 Series
■ PACKAGE DIMENSIONS
80-pin Plastic QFP
(FPT-80P-M06)
23.90±0.40(.941±.016)
64
20.00±0.20(.787±.008)
3.35(.132)MAX
0.05(.002)MIN
(STAND OFF)
41
40
65
14.00±0.20
(.551±.008)
17.90±0.40
(.705±.016)
12.00(.472)
REF
16.30±0.40
(.642±.016)
INDEX
80
25
"A"
LEAD No.
1
24
0.80(.0315)TYP
0.35±0.10
(.014±.004)
0.16(.006)
0.15±0.05(.006±.002)
M
Details of "A" part
Details of "B" part
0.25(.010)
"B"
0.10(.004)
18.40(.724)REF
22.30±0.40(.878±.016)
C
0.30(.012)
0.18(.007)MAX
0.58(.023)MAX
0 10°
0.80±0.20
(.031±.008)
1994 FUJITSU LIMITED F80010S-3C-2
Dimensions in mm (inches)
44
MB89920 Series
80-pin Ceramic MQFP
(MQP-80C-P01)
18.70(.736)TYP
12.00(.472)TYP
INDEX AREA
16.30±0.33
(.642±.013)
15.58±0.20
(.613±.008)
1.50(.059)TYP
1.00(.040)TYP
1.20 –0.20
+.016
.047 –.008
1.27±0.13
(.050±.005)
22.30±0.33
(.878±.013)
24.70(.972)
TYP
0.30(.012)
TYP
0.80±0.25
(.0315±.010)
0.80±0.25
(.0315±.010)
+0.40
4.50(.177)
TYP
INDEX AREA
18.12±0.20
12.02(.473)
(.713±.008)
TYP
10.16(.400)
14.22(.560)
TYP
TYP
18.40(.724)
REF
INDEX
1.27±0.13
(.050±.005)
6.00(.236)
TYP
0.30(.012)TYP
7.62(.300)TYP
9.48(.373)TYP
11.68(.460)TYP
0.40±0.10
(.016±.004)
1.50(.059)
TYP
1.00(.040)
TYP
0.40±0.10
(.016±.004)
+0.40
1.20 –0.20
+.016
.047 –.008
0.15±0.05 8.70(.343)
(.006±.002) MAX
C
1994 FUJITSU LIMITED M80001SC-4-2
Dimensions in mm (inches)
45
MB89920 Series
FUJITSU LIMITED
For further information please contact:
Japan
FUJITSU LIMITED
Corporate Global Business Support Division
Electronic Devices
KAWASAKI PLANT, 4-1-1, Kamikodanaka,
Nakahara-ku, Kawasaki-shi,
Kanagawa 211-8588, Japan
Tel: +81-44-754-3763
Fax: +81-44-754-3329
http://www.fujitsu.co.jp/
North and South America
FUJITSU MICROELECTRONICS, INC.
3545 North First Street,
San Jose, CA 95134-1804, U.S.A.
Tel: +1-408-922-9000
Fax: +1-408-922-9179
Customer Response Center
Mon. - Fri.: 7 am - 5 pm (PST)
Tel: +1-800-866-8608
Fax: +1-408-922-9179
http://www.fujitsumicro.com/
Europe
FUJITSU MICROELECTRONICS EUROPE GmbH
Am Siebenstein 6-10,
D-63303 Dreieich-Buchschlag,
Germany
Tel: +49-6103-690-0
Fax: +49-6103-690-122
http://www.fujitsu-fme.com/
Asia Pacific
FUJITSU MICROELECTRONICS ASIA PTE. LTD.
#05-08, 151 Lorong Chuan,
New Tech Park,
Singapore 556741
Tel: +65-281-0770
Fax: +65-281-0220
http://www.fmap.com.sg/
Korea
FUJITSU MICROELECTRONICS KOREA LTD.
1702 KOSMO TOWER, 1002 Daechi-Dong,
Kangnam-Gu,Seoul 135-280
Korea
Tel: +82-2-3484-7100
Fax: +82-2-3484-7111
F0005
 FUJITSU LIMITED Printed in Japan
All Rights Reserved.
The contents of this document are subject to change without notice.
Customers are advised to consult with FUJITSU sales
representatives before ordering.
The information and circuit diagrams in this document are
presented as examples of semiconductor device applications, and
are not intended to be incorporated in devices for actual use. Also,
FUJITSU is unable to assume responsibility for infringement of
any patent rights or other rights of third parties arising from the use
of this information or circuit diagrams.
The contents of this document may not be reproduced or copied
without the permission of FUJITSU LIMITED.
FUJITSU semiconductor devices are intended for use in standard
applications (computers, office automation and other office
equipments, industrial, communications, and measurement
equipments, personal or household devices, etc.).
CAUTION:
Customers considering the use of our products in special
applications where failure or abnormal operation may directly
affect human lives or cause physical injury or property damage, or
where extremely high levels of reliability are demanded (such as
aerospace systems, atomic energy controls, sea floor repeaters,
vehicle operating controls, medical devices for life support, etc.)
are requested to consult with FUJITSU sales representatives before
such use. The company will not be responsible for damages arising
from such use without prior approval.
Any semiconductor devices have inherently a certain rate of failure.
You must protect against injury, damage or loss from such failures
by incorporating safety design measures into your facility and
equipment such as redundancy, fire protection, and prevention of
over-current levels and other abnormal operating conditions.
If any products described in this document represent goods or
technologies subject to certain restrictions on export under the
Foreign Exchange and Foreign Trade Control Law of Japan, the
prior authorization by Japanese government should be required for
export of those products from Japan.