Fujitsu MB90497GPFM 16-bit proprietary microcontroller cmo Datasheet

FUJITSU SEMICONDUCTOR
DATA SHEET
DS07-13713-3E
16-bit Proprietary Microcontroller
CMOS
F2MC-16LX MB90495G Series
MB90497G/F497G/F498G/V495G
■ DESCRIPTION
The MB90495G Series is a general-purpose, high-performance 16-bit microcontroller. It was designed for devices
like consumer electronics, which require high-speed, real-time process control. This series features an on-chip
full-CAN interface.
In addition to being backwards compatible with the F2MC* family architecture, the instruction set has been expanded to add support for high-level language instructions, expanded addressing mode, and enhanced multiply/
divide and bit processing instructions. A 32-bit accumulator is also provided, making it possible to process long
word (32-bit) data.
The MB90495G Series peripheral resources include on chip 8/10-bit A/D converter, UART (SCI) 0/1, 8/16-bit
PPG timer, 16-bit I/O timer (16-bit free-run timer, input capture 0, 1, 2, 3 (ICU) ) , and CAN controller.
* : F2MC is abbreviation for Fujitsu Flexible Microcontroller. F2MC is a registered trademark of Fujitsu Limited.
■ FEATURES
• Models that support +125 °C
• Clock
•Built-in PLL clock multiplier circuit
•Choose 1/2 oscillation clock or ×1 to ×4 multiplied oscillation clock (for a 4-MHz oscillation clock, 4 to 16 MHz)
machine (PLL) clock
(Continued)
■ PACKAGES
64-pin plastic QFP
64-pin plastic LQFP
(FPT-64P-M06)
(FPT-64P-M09)
MB90495G Series
(Continued)
•Select subclock behavior (8.192 kHz)
•Minimum instruction execution time : 62.5 ns (operating with 4-MHz oscillation clock and × 4 PLL clock)
• 16-MByte CPU memory space
•24-bit internal addressing
•External access possible through selection of 8/16-bit bus width (external bus mode)
• Optimum instruction set for controller applications
•Wealth of data types (Bit, Byte, Word, Long Word)
•Wealth of addressing modes (23 different modes)
•Enhanced signed multiply-divide instructions and RETI instruction functions
•Enhanced high-precision arithmetic employing 32-bit accumulator
• Instruction set supports high-level programming language (C) and multitasking
•Employs system stack pointer
•Enhanced indirect instructions with all pointer types
•Barrel shift instructions
• Improved execution speed
•4-byte instruction queue
• Powerful interrupt feature
•Powerful 8-level, 34-condition interrupt feature
• CPU-independent automated data forwarding
•Extended intelligent I/O service feature (EI2OS) : maximum 16 channels
• Low-power consumption (Standby) Mode
•Sleep mode (CPU operation clock stopped)
•Time-base timer mode (oscillation clock and subclock, time-base timer and watch timer only operational)
•Watch mode (subclock and watch timer only operational)
•Stop mode (oscillation clock and subclock stopped)
•CPU intermittent operation mode
• Process
•CMOS technology
• I/O Ports
•Generic I/O ports (CMOS output) : 49
• Timer
•Time-base timer, watch timer, watchdog timer : 1 channel
•8/16-bit PPG timer : four 8-bit channels, or two 16-bit channels
•16-bit reload timer : 2 channels
•16-bit I/O timer
•16-bit free-run timer : 1 channel
•16-bit input capture (ICU) : 4 channels
Generates interrupt requests by latching onto the count value of the 16-bit free-run timer with pin input
edge detection
(Continued)
2
MB90495G Series
(Continued)
• CAN Controller : 1 channel
•CAN specifications conform to versions 2.0A and 2.0B
•8 on-chip message buffers
•Forwarding rate 10 Kbps to 1 Mbps (with 16-MHz machine clock)
• UART0 (SCI) /UART1 (SCI) : 2 channels
•All with full duplex double buffer
•Use clock-asynchronous or clock-synchronous serial forwarding
• DTP/external interrupt : 8 channels
•A module for launching extended intelligent I/O service (EI2OS) and generating external interrupts through
external output
• Delayed interrupt generation module
•Generates interrupt requests for switching tasks
• 8/10-bit A/D converter : 8 channels
•Switch between 8-bit and 10-bit resolution
•Launch through external trigger input
•Conversion time : 6.13 µs (with 16-MHz machine clock, including sampling time)
• Program batch function
•2-address pointer ROM correction
• Clock output function
3
MB90495G Series
■ PRODUCT LINEUP
Part Number
Paarmeter
Feature Classification
ROM Size
MB90F497G
MB90497G
MB90F498G
MB90V495G
FLASH ROM
Mask ROM
FLASH ROM
Product Evaluated
128 Kbytes

64 Kbytes
RAM Size
2 Kbytes
Process
6 Kbytes
CMOS
Package
LQFP64 (width 0.65 mm) , QFP64 (width 1.0 mm)
Operating Power
4.5 V to 5.5 V

Emulator power supply*
Number of instructions
Instruction bit length
Instruction length
Data bit length
CPU Functions
PGA256
None
: 351
: 8-bit, 16-bit
: 1 to 7 bytes
: 1 bit, 8-bit, 16-bit
Minimum execution time : 62.5 ns (with 16-MHz machine clock)
Interrupt processing time : minimum 1.5 µs (with 16-MHz machine clock)
Low-power consumption
(Standby) Mode
Sleep mode/watch mode/time-base timer mode/stop mode / CPU intermittent
mode
I/O Ports
General-purpose I/O ports (CMOS output) : 49
Time-base timer
18-bit free-run counter
Interrupt interval : 1.024 ms, 4.096 ms, 16.834 ms, 131.072 ms
(with 4-MHz oscillation clock)
Watchdog timer
Reset generation intervals : 3.58 ms, 14.33 ms, 57.23 ms, 458.75 ms
(with 4-MHz oscillation clock)
16-bit
I/O Timer
16-bit
Number of channels : 1
free-run timer Interrupts from overflow generation
Input capture
Number of channels : 4
Maintenance of free-run timer value through pin input (rising, falling or both edges)
16-bit reload timer
Number of channels : 2
16-bit reload timer operation
Count clock interval : 0.25 µs, 0.5 µs, 2.0 µs
(with 16-MHz machine clock)
External event count enabled
Watch timer
15-bit free-run counter
Interrupt intervals : 31.25 ms, 62.5 ms, 12 ms, 250 ms, 500 ms, 1.0 s, 2.0 s
(with 8.192-kHz subclock)
8/16-bit PPG timer
Number of channels : 2 (two 8-bit channels can be used)
Two 8-bit or one 16-bit channel PPG operation possible
Free interval, free duty pulse output possible
Count clock : 62.5 ns to 1 µs (with 16-MHz machine clock)
* : The S2 dipswitch setting when using the MB2145-507 emulation baud. For details, see the MB2145-507
hardware manual (2.7 Emulator Power Pin) .
(Continued)
4
MB90495G Series
(Continued)
Part Number
Parameter
MB90F497G
MB90497G
MB90F498G
MB90V495G
Delayed interrupt generation
module
Module for delayed interrupt generation switching tasks
Used in real-time OS
DTP/external interrupt circuit
Number of inputs : 8
Starting by rising edge, falling edge, “H” level input, or “L” level input, external
interrupts or extended intelligent I/O service (EI2OS) can be used
8/10-bit A/D converter
Number of channels : 8
Resolution : set 10-bit or 8-bit
Conversion time : 6.13 µs (with 16-MHz machine clock, including sampling time)
Continuous conversion of multiple linked channels possible
(up to 8 channels can be set)
One-shot conversion mode : converts selected channel only once
Continuous conversion mode : converts selected channel continuously
Stop conversion mode : converts selected channel and suspends operation
repeatedly
UART0 (SCI)
Number of channels : 1
Clock-synchronous forwarding : 62.5 Kbps to 2 Mbps
Clock-asynchronous forwarding : 1,202 bps to 62,500 bps
Transmission can be performed by two-way serial transmission or by master/
slave connection
UART1 (SCI)
Number of channels : 1
Clock-synchronous forwarding : 62.5 Kbps to 2 Mbps
Clock-asynchronous forwarding : 9,615 bps to 500 Kbps
Transmission can be performed by two-way serial transmission or by master/
slave connection
CAN
Compliant with CAN specification versions 2.0A and 2.0B
Send/receive message buffers : 8
Forwarding bit rate : 10 Kbps to 1 Mbps (with 16-MHz machine clock)
■ PACKAGES AND CORRESPONDING PRODUCTS
Package
MB90F497G
MB90497G
MB90F498G
FPT-64P-M06
FPT-64P-M09
: available × : not available
Note : See “Package Dimensions” for details.
■ PRODUCT COMPARISON
Memory Size
When evaluating with evaluation chips and other means, take careful note of the different between the evaluation
chip and the chip actually used. Take particular note of the following.
• While the MB90V495G does not feature an on-chip ROM, the dedicated development tool can be used to
achieve operation equivalent to a product with built-in ROM. Therefore, the ROM size is configured by the
development tool.
• On the MB90V495G, the FF4000H to FFFFFFH image is only visible in the 00 bank, and the FE0000H to
FF3FFFH is only visible in the FE and FF banks (configurable on development tool) .
• On the MB90F497G/F498G/497G, the FF4000H to FFFFFFH image is visible in the 00 bank, and the FF0000H
to FF3FFFH is visible only in the FF bank.
5
P44/RX
P61/INT1
P62/INT2
P50/AN0
P51/AN1
P52/AN2
P53/AN3
P54/AN4
P55/AN5
P56/AN6
P57/AN7
AVCC
AVR
AVSS
P60/INT0
X0A
X1A
P63/INT3
MD0
(FPT-64P-M06)
6
19
P31/SCK0/RD
P32/SIN0/WRL
P33/WRH
P34/HRQ
P35/HAK
VCC
C
P36/FRCK/RDY
P37/ADTG/CLK
P40/SIN1
P41/SCK1
P42/SOT1
P43/TX
10
1
33
42
51
P30/SOT0/ALE
VSS
P27/INT7/A23
P26/INT6/A22
P25/INT5/A21
P24/INT4/A20
P23/TOT1/A19
P22/TIN1/A18
P21/TOT0/A17
P20/TIN0/A16
P17/PPG3/AD15
P16/PPG2/AD14
P15/PPG1/AD13
P14/PPG0/AD12
P13/IN3/AD11
P12/IN2/AD10
P11/IN1/AD09
P10/IN0/AD08
P07/AD07
MB90495G Series
■ PIN ASSIGNMENTS
• FPT-64P-M06
(TOP VIEW)
52
32
58
26
64
20
P06/AD06
P05/AD05
P04/AD04
P03/AD03
P02/AD02
P01/AD01
P00/AD00
VSS
X1
X0
MD2
MD1
RST
16
8
1
VSS
P30/SOT0/ALE
P31/SCK0/RD
P32/SIN0/WRL
P33/WRH
P34/HRQ
P35/HAK
VCC
C
P36/FRCK/RDY
P37/ADTG/CLK
P40/SIN1
P41/SCK1
P42/SOT1
P43/TX
P44/RX
P61/INT1
P62/INT2
P50/AN0
P51/AN1
P52/AN2
P53/AN3
P54/AN4
P55/AN5
P56/AN6
P57/AN7
AVCC
AVR
AVSS
P60/INT0
X0A
X1A
33
40
48
P27/INT7/A23
P26/INT6/A22
P25/INT5/A21
P24/INT4/A20
P23/TOT1/A19
P22/TIN1/A18
P21/TOT0/A17
P20/TIN0/A16
P17/PPG3/AD15
P16/PPG2/AD14
P15/PPG1/AD13
P14/PPG0/AD12
P13/IN3/AD11
P12/IN2/AD10
P11/IN1/AD09
P10/IN0/AD08
MB90495G Series
• FPT-64P-M09
(TOP VIEW)
49
32
57
24
64
17
P07/AD07
P06/AD06
P05/AD05
P04/AD04
P03/AD03
P02/AD02
P01/AD01
P00/AD00
VSS
X1
X0
MD2
MD1
RST
MD0
P63/INT3
(FPT-64P-M09)
7
MB90495G Series
■ PIN DESCRIPTION
Pin No.
M06
M09
2
1
3
2
Pin Name
P61
INT1
P62
INT2
Circuit
Type
D
D
P50 to P57
4 to 11 3 to 10
Description
General-purpose I/O port
Functions as external interrupt input pin. Set this to input port.
General-purpose I/O port
Functions as external interrupt input pin. Set this to input port.
General-purpose I/O port
AN0 to
AN7
E
Functions as analog input port of A/D converter. This is enabled if analog
input configuration is permitted.
12
11
AVCC

VCC power input pin of A/D converter.
13
12
AVR

Reference voltage (+) input pin for the A/D converter.This voltage must
not exceed VCC and AVCC. Reference voltage (−) is fixed to AVSS.
14
13
AVSS

VSS power input pin of A/D converter.
15
14
16
15
X0A
A
Low-speed oscillation pin.
Perform pull-down processing if not connected to an oscillator.
17
16
X1A
A
Low-speed oscillation pin.
Set to open if not connected to an oscillator.
18
17
19
18
MD0
C
Input pin for specifying operation mode.
20
19
RST
B
External reset input pin.
21
20
MD1
C
Input pin for specifying operation mode.
22
21
MD2
F
Input pin for specifying operation mode.
23
22
X0
A
High-speed oscillation pin.
24
23
X1
A
High-speed oscillation pin.
25
24
VSS

Power supply (0 V) input pin.
26 to
33
25 to
32
P60
INT0
P63
INT3
D
D
P00 to P07
AD00 to
AD07
D
P10 to P13
34 to
37
33 to
36
IN0 to IN3
AD08 to
AD11
General-purpose I/O port
Functions as external interrupt input pin. Set this to input port.
General-purpose I/O port
Functions as external interrupt input pin. Set this to input port.
General-purpose I/O port
Only enabled in single-chip mode.
I/O pin for the lower 8-bit of the external address data bus.
Only enabled during external bus mode.
General-purpose I/O port. Only enabled in single-chip mode.
D
Functions as trigger input pin for input capture channels 0 to 3. Set this to
input port.
I/O pin for upper 4-bit of external address data bus.
Only enabled during external bus mode.
(Continued)
8
MB90495G Series
(Continued)
Pin No.
M06
M09
Pin Name
Circuit
Type
General-purpose I/O port.
Only enabled in single-chip mode.
P14 to P17
38 to
41
37 to
40
PPG0 to
PPG3
D
AD12 to
AD15
43
44
45
41
42
43
44
TIN0
Functions as output pin of PPG timer 01, 23. Only valid if output configuration is enabled.
I/O pin for upper 4-bit of external address data bus.
Only enabled during external bus mode.
General-purpose I/O port.
When the bits of high address control register (HACR) are set to “1” in external bus mode, these pins function as general purpose I/O ports.
P20
42
Description
D
Functions as event input pin of TIN0 reload timer 0.
Set this to input port.
A16
Output pin of external address bus (A16) .
Only valid when the bits of high address control register (HACR) are set
to “0” in external bus mode.
P21
General-purpose I/O port.
When the bits of high address control register (HACR) are set to “1” in external bus mode, these pins function as general purpose I/O ports.
TOT0
D
Functions as event output pin of TOT0 reload timer 0.
Only valid if output configuration enabled.
A17
Output pin of external address bus (A17) .
Only valid when the bits of high address control register (HACR) are set
to “0” in external bus mode.
P22
General-purpose I/O port.
When the bits of high address control register (HACR) are set to “1” in external bus mode, these pins function as general purpose I/O ports.
TIN1
D
Functions as event input pin of TIN1 reload timer 1.
Set this to input port.
A18
Output pin of external address bus (A18) .
Only valid when the bits of high address control register (HACR) are set
to “0” in external bus mode.
P23
General-purpose I/O port.
When the bits of high address control register (HACR) are set to “1” in external bus mode, these pins function as general purpose I/O ports.
TOT1
A19
D
Functions as event output pin for TOT1 reload timer 1.
Only valid if output configuration enabled.
Output pin for external address bus (A19) .
Only valid when the bits of high address control register (HACR) are set
to “0” in external bus mode.
(Continued)
9
MB90495G Series
(Continued)
Pin No.
M06
M09
Pin Name
Circuit
Type
General-purpose I/O port.
When the bits of high address control register (HACR) are set to “1” in external bus mode, these pins function as general purpose I/O ports.
P24 to P27
46 to
49
45 to
48
INT4 to INT7
D
49
VSS

52
53
54
50
51
52
53
SOT0
D
54
Address latch authorization output pin.
Only enabled during external bus mode.
P31
General-purpose I/O port.
Only enabled in single-chip mode.
SCK0
D
10
55
57
56
58
57
UART0 serial clock I/O pin.
Only valid if UART0 serial clock I/O configuration is enabled.
RD
Lead strobe output pin.
Only enabled during external bus mode.
P32
General-purpose I/O port.
SIN0
D
UART0 serial data input pin.
Set this to input port.
WRL
Write strobe output pin for lower 8-bit of data bus.
Only valid if WRL pin output is enabled, in external bus mode.
P33
General-purpose I/O port.
WRH
D
HRQ
Write strobe output pin for upper 8-bit of data bus.
Only valid if external bus mode/16-bit bus mode/WRH pin output enabled.
General-purpose I/O port.
D
P35
56
UART0 serial data output pin.
Only valid if UART0 serial data output configuration is enabled.
ALE
P34
55
Power supply (0 V) input pin.
General-purpose I/O port.
Only enabled in single-chip mode.
P30
51
Functions as external interrupt input pin. Set this to input port.
Output pin for external address bus (A20 to A23) .
Only valid when the bits of high address control register (HACR) are set
to “0” in external bus mode.
A20 to A23
50
Description
Hold request input pin.
Only valid if hold input is enabled, in external bus mode.
General-purpose I/O port.
D
Hold addressing output pin.
Only valid if hold input is enabled, in external bus mode.
VCC

Power supply (5 V) input pin.
C

Capacity pin for power stabilization.
Please connect to an approximately 0.1 µF ceramic capacitor.
(Continued)
HAK
MB90495G Series
(Continued)
Pin No.
M06
M09
Pin Name
Circuit
Type
P36
59
60
58
59
61
60
62
61
FRCK
General-purpose I/O port.
D
External ready input pin.
Only valid if external ready input is enabled, in external bus mode.
P37
General-purpose I/O port.
ADTG
D
64
63
External clock output pin.
Only valid if external clock output is enabled, in external bus mode.
P40
General-purpose I/O port.
SIN1
D
SCK1
SOT1
TX
RX
UART1 serial clock I/O pin.
Only valid if UART1 clock I/O configuration is enabled.
General-purpose I/O port.
D
UART1 serial data output pin.
Only valid if UART1 serial data output configuration is enabled.
General-purpose I/O port.
D
P44
64
UART1 serial data input pin.
Set this to input port.
General-purpose I/O port.
D
P43
1
Functions as A/D converter external trigger input pin. Set this to input port.
CLK
P42
62
Functions as an external clock input pin for a FRCK 16-bit free-run timer.
Set this to input port.
RDY
P41
63
Description
CAN transmission output pin.
Only valid if output configuration enabled.
General-purpose I/O port.
D
CAN reception input pin.
Set this to input port.
11
MB90495G Series
■ I/O CIRCUIT TYPE
Type
Circuit
Remarks
X1
Clock input
X1A
A
• High speed oscillation feedback
resistor : 1 MΩ approx.
• Low speed oscillation feedback
resistor : 10 MΩ approx.
X0
X0A
Standby control signal
• Hysteresis input with pull-up
• Pull-up Resistor : 50 kΩ approx.
VCC
B
R
R
Hysteresis input
• Hysteresis input
R
C
Hysteresis input
VCC
Pch
D
R
Nch
VSS
Digital output
• CMOS hysteresis input
• CMOS level output
• Standby control available
Digital output
Hysteresis input
IOL = 4 mA
Standby control
VCC
Pch
Nch
E
IOL = 4 mA
R
Digital output
•
•
•
•
CMOS hysteresis input
CMOS level output
Doubles as analog input pin
Standby control available
Digital output
VSS
Hysteresis input
Standby control
Analog input
(Continued)
12
MB90495G Series
(Continued)
Type
Circuit
Remarks
R
Hysteresis input
F
• Hysteresis input with pull-down
• Pull-down Resistor : 50 kΩ approx.
(except FLASH device)
R
VSS
13
MB90495G Series
■ HANDLING DEVICES
• Make sure you do not exceed the maximum rated values (in order to prevent latch-up) .
• CMOS IC chips may suffer latch-up if a voltage higher than VCC or lower than VSS is applied to an input or
output pin with other than mid or high current resistance; or voltage exceeding the rating is applied across VCC
and VSS.
• Latch-ups can dramatically increase the power supply current, causing thermal breakdown of the device.
Make sure that you do not exceed the maximum rated value of your device, in order to prevent a latch-up.
• When turning the analog power supply on or off, make sure that the analog power voltage (AVCC, AVR) and
analog input voltages do not exceed the digital voltage (VCC) .
• Handling Unused Pins
Leaving unused input pins open may cause malfunctions and latch-ups, permanently damaging the device.
Prevent this by connecting it to a pull-up or pull-down resistor of no less than 2 kΩ. Leave unused output pins
open in output mode, or if in input mode, handle them in the same as input pins.
• Notes on Using External Clock
When using the external clock, drive pin X0 only, and leave pin X1 unconnected. See below for an example of
external clock use.
Example External Clock Use
X0
Open
X1
MB90495G Series
• Notes on Not Using Subclock
If you do not connect pins X0A and X1A to an oscillator, use pull-down handling on the X0A pin, and leave the
X1A pin open.
• Power Supply Pins
• If your product has multiple VCC or VSS pins, pins of the same potential are internally connected in the device
in order to avoid abnormal operation, including latch-up. However, you should make sure to connect the pins’
external power and ground lines, in order to lower unneeded emissions, prevent abnormal operation of strobe
signals due to a rise in ground levels, and maintain total output current within rated levels.
• Take care to connect the VCC and VSS pins of MB90495G Series devices to power lines via the lowest possible
impedance.
• It is recommended that you connect a bypass capacitor of approximately 0.1 µF between VCC and VSS near
MB90495G Series device pins.
• Crystal Oscillator Circuit
• Noise in the vicinity of X0 and X1 pins could cause abnormal operations in MB90495G Series devices. Make
sure to provide bypass capacitors via the shortest possible distance from X0 and X1 pins, crystal oscillators
(or ceramic resonators) , and ground lines. In addition, design your printed circuit boards so as to keep X0
and X1 wiring from crossing other wiring, if at all possible.
• It is strongly recommended that you provide printed circuit board artwork surrounding X0 and X1 pins within
a grand area, as this should stabilize operation.
14
MB90495G Series
• A/D Converter Power-up and Analog Input Initiation Sequence
• Make sure to power up the A/D converter and analog input (pins AN0 to AN7) after turning on digital power
(VCC) .
• Turn off digital power after turning off the A/D converter power supply and analog inputs. In this case, make
sure that the voltage of AVR does not exceed AVCC (it is permissible to turn off analog and digital power
simultaneously) .
• Connecting Unused A/D Converter Pins
If you are not using the A/D converter, set unused pins to AVCC = AVR = VCC, AVSS = VSS.
• Notes for Powering Up
Ensure that the voltage step-up time (between 0.2 V and 2.7 V) at power-up is no less than 50 µs, in order to
prevent malfunction in the built-in step-down circuit.
• Initialization
The device contains built-in registers which are only initialized by a power-on reset. Cycle the power supply to
initialize these registers.
• Stabilizing the Power Supply
Make sure that the VCC power supply voltage is stable. Even at the rated operating VCC power supply voltage,
large, sudden changes in the voltage could cause malfunctions. As a standard for stable power supply, keep
VCC ripples (peak-to-peak value) at commercial power frequencies (50 Hz to 60 Hz) to no more than 10% of the
power supply voltage, and momentary surges caused by switching the power supply and other events to more
than 0.1 V/ms.
• If Output from Ports 0/1 Becomes Undefined
After power is turned on, if the RST pin is set to “H” during step-down circuit stabilization standby (during poweron reset) , ports 0 and 1 output will be undefined. If the RST pin is set to “L”, ports 0 and 1 will go into a high
impedance state. Take careful note of the timing of events outlined in figures 1 and 2.
15
MB90495G Series
• Figure 1 - Timing Chart of Undefined Output from Ports 0/1 (with RST pin set to “H”)
Time in standby for oscillation to stabilize*2
Time in standby for stepdown circuit to stabilize*1
VCC (power supply pin)
PONR (power-on reset) signal
RST (external asynchronous reset) signal
RST (internal reset) signal
Oscillation clock signal
KA (internal operating clock A) signal
KB (internal operating clock B) signal
PORT (port output) signal
Time of undefined output
*1 : Step-down circuit stabilization standby time : 217/oscillation clock frequency
(with 16-MHz oscillation clock frequency, about 8.19 ms)
*2 : Oscillation stabilization standby time : 218/oscillation clock frequency
(with 16-MHz oscillation clock frequency, about 16.36 ms)
• Figure 2 - Timing Chart of High Impedance State for Ports 0/1 (when RST pin is “L”)
Time in standby for oscillation to stabilize*2
Step-down circuit
stabilization standby time*1
VCC (power supply pin)
PONR (power-on reset) signal
RST (external asynchronous reset) signal
RST (internal reset) signal
Oscillation clock signal
KA (internal operation clock A) signal
KB (internal operating clock B) signal
PORT (port output) signal
High impedance
*1 : Step-down circuit stabilization standby time : 217/oscillation clock frequency
(with 16-MHz oscillation clock frequency, about 8.19 ms)
*2 : Oscillation stabilization standby time : 218/oscillation clock frequency
(with 16-MHz oscillation clock frequency, about 16.38 ms)
16
MB90495G Series
• Caution on Operations during PLL Clock Mode
If the PLL clock mode is selected in the microcontroller, it may attempt to continue the operation using the freerunning frequency of the automatic oscillating circuit in the PLL circuitry even if the oscillator is out of place or
the clock input is stopped. Performance of this operation, however, cannot be guaranteed.
• Support for +125 °C
If used exceeding TA = +105 °C, be sure to contact us for reliability limitations.
17
MB90495G Series
■ BLOCK DIAGRAM
X0, X1
RST
X0A, X1A
Clock
control circuit
CPU
F2MC-16LX
Core
Watch timer
16 bit
free-run timer
RAM
Input
capture
(4 ch)
ROM/FLASH
Prescaler
SOT1
SCK1
SIN1
Internal data bus
Time-base timer
16-bit
PPG timer
(2 ch)
CAN
FRCK
IN0 to IN3
PPG0 to PPG3
RX
TX
UART1
DTP/external
interrupt circuit
INT0 to INT7
16 bits
reload timer
(2 ch)
TIN0, TIN1
TOT0, TOT1
External bus
AD00 to AD15
A16 to A23
ALE
RD
WRL
WRH
HRQ
HAK
RDY
CLK
Prescaler
SOT0
SCK0
SIN0
UART0
AVCC
AVSS
AN0 to AN7
AVR
ADTG
18
8/10 bit
A/D converter
(8 ch)
MB90495G Series
■ MEMORY MAP
The memory access modes of the MB90495G Series can be set to single chip mode, internal ROM - external
bus mode, and external ROM - external bus mode.
1. Memory Allocation of the MB90495G
The MB90495G Series has 24-bit internal address bus and 24-bit external address bus output, enabling it to
access up to 16 Mbytes of external access memory. The enable/disable time of the ROM mirror function is shown
graphically in the memory map.
2. Memory Map
Single chip mode
(ROM mirror function available)
Internal ROM
External bus mode
External ROM
External bus mode
Periphery
Periphery
Periphery
RAM space
Register
RAM space
Register
RAM space
Register
Extention
IO space
ROM space
(image of
bank FF)
Extention
IO space
ROM space
(image of
bank FF)
Extention
IO space
ROM space
ROM space
000000H
0000C0H
000100H
Address #1
002000H
003800H
003900H
Address #2
010000H
Address #3
FFFFFFH
Internal access memory
External access memory
Access prohibited
Product
Address #1*
Address #2
Address #3*
MB90V495G
001900H
004000H
(FC0000H)
MB90F497G
000900H
004000H
FF0000H
MB90497G
000900H
004000H
FF0000H
MB90F498G
000900H
004000H
FE0000H
* : Addresses #1 and #3 are product-specific.
Note : When the internal ROM is operational, the ROM data in the upper address of bank 00 of the F2MC-16LX is
visible in an image. This is called the ROM mirror function, and takes advantage of the small C compiler model.
With the F2MC-16LX, the lower 16-bit address of bank FF and the lower 16-bit address of bank 00 are set
identical to one another. This allows the ROM-internal table to be referenced without specifying a far pointer.
For example, say the address “00C000H” is accessed. In actuality, the “FFC000H ” address inside ROM will
be accessed. However, as the ROM space in bank FF exceeds 48 Kbytes, the entire space cannot be viewed
on bank 00’s image. And so, since “FF4000H” to “FFFFFFH” ROM data will be visible on the “004000H” to
“00FFFFH” image, save the ROM data table in the “FF4000H” to “FFFFFFH” space.
19
MB90495G Series
■ I/O MAP
Address
Register
Abbreviation
000000H
PDR0
000001H
Register Name
Access
Resource Name
Initial Value
Port 0 data register
R/W
Port 0
XXXXXXXXB
PDR1
Port 1 data register
R/W
Port 1
XXXXXXXXB
000002H
PDR2
Port 2 data register
R/W
Port 2
XXXXXXXXB
000003H
PDR3
Port 3 data register
R/W
Port 3
XXXXXXXXB
000004H
PDR4
Port 4 data register
R/W
Port 4
XXXXXXXXB
000005H
PDR5
Port 5 data register
R/W
Port 5
XXXXXXXXB
000006H
PDR6
Port 6 data register
R/W
Port 6
XXXXXXXXB
000007H
to
00000FH
(system-reserved area) *
000010H
DDR0
Port 0 direction register
R/W
Port 0
0 0 0 0 0 0 0 0B
000011H
DDR1
Port 1 direction register
R/W
Port 1
0 0 0 0 0 0 0 0B
000012H
DDR2
Port 2 direction register
R/W
Port 2
0 0 0 0 0 0 0 0B
000013H
DDR3
Port 3 direction register
R/W
Port 3
0 0 0 0 0 0 0 0B
000014H
DDR4
Port 4 direction register
R/W
Port 4
XXX 0 0 0 0 0B
000015H
DDR5
Port 5 direction register
R/W
Port 5
0 0 0 0 0 0 0 0B
000016H
DDR6
Port 6 direction register
R/W
Port 6
XXXX 0 0 0 0B
8/10-bit
A/D converter
1 1 1 1 1 1 1 1B
000017H
to
00001AH
00001BH
(system-reserved area) *
ADER
Analog input enable register
00001CH
to
00001FH
R/W
(system-reserved area) *
000020H
SMR0
Serial mode register 0
R/W
0 0 0 0 0 0 0 0B
000021H
SCR0
Serial control register 0
R/W
0 0 0 0 0 1 0 0B
000022H
SIDR0/
SODR0
Serial input data register 0/
Serial output data register 0
R/W
Serial status register 0
R/W
Communication prescaler control
register 0
R/W
0 XXX 1 1 1 1B
XXXXXXXXB
UART0
000023H
SSR0
000024H
CDCR0
000025H
SES0
Serial edge selection register 0
R/W
XXXXXXX 0B
000026H
SMR1
Serial mode register 1
R/W
0 0 0 0 0 0 0 0B
000027H
SCR1
Serial control register 1
R/W
000028H
SIDR1/
SODR1
Serial input data register 1/
Serial output data register 1
R/W
UART1
0 0 0 0 1 X 0 0B
0 0 0 0 0 1 0 0B
XXXXXXXXB
(Continued)
20
MB90495G Series
(Continued)
Address
Register
Abbreviation
000029H
SSR1
Register Name
Serial status register 1
00002AH
00002BH
Access
Resource Name
Initial Value
R/W
UART1
0 0 0 0 1 0 0 0B
UART1
0 XXX 0 0 0 0B
(system-reserved area) *
CDCR1
Communication prescaler control
register 1
00002CH
to
00002FH
R/W
(system-reserved area) *
000030H
ENIR
DTP/external interrupt enable register
R/W
000031H
EIRR
DTP/external interrupt condition
register
R/W
ELVR
Detection level configuration register
ADCS
A/D control status register
000032H
000033H
000034H
000035H
000036H
000037H
ADCR
000038H
to
00003FH
000040H
R/W
0 0 0 0 0 0 0 0B
R/W
PPGC0
PPG0 operation mode control register
PPG01
PPG0/1 count clock selection register
R/W
000043H
PPGC2
PPG2 operation mode control register
0 X 0 0 0 0 0 1B
0 0 0 0 0 0 XXB
R/W
PPGC3
PPG3 operation mode control register
R/W
000046H
PPG23
PPG2/3 count clock selection register
R/W
000047H
to
00004FH
0 X 0 0 0 XX 1B
8/16-bit
PPG timer 2/3
0 X 0 0 0 0 0 1B
0 0 0 0 0 0 XXB
(system-reserved area) *
IPCP0
Input capture data register 0
R
IPCP1
Input capture data register 1
R
000054H
ICS01
000055H
ICS23
000057H
0 X 0 0 0 XX 1B
8/16-bit
PPG timer 0/1
(system-reserved area) *
000045H
000056H
XXXXXXXXB
0 0 1 0 1 XXXB
R/W
000042H
000053H
0 0 0 0 0 0 0 0B
(system-reserved area) *
R/W
000052H
8/10-bit
A/D converter
R/W
PPG1 operation mode control register
000051H
0 0 0 0 0 0 0 0B
R/W
PPGC1
000050H
XXXXXXXXB
0 0 0 0 0 0 0 0B
000041H
000044H
DTP/external
interrupt
R/W
R
A/D data register
0 0 0 0 0 0 0 0B
TCDT
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
16-bit I/O timer
Input capture control status register
R/W
Timer counter data register
R/W
XXXXXXXXB
0 0 0 0 0 0 0 0B
0 0 0 0 0 0 0 0B
0 0 0 0 0 0 0 0B
0 0 0 0 0 0 0 0B
(Continued)
21
MB90495G Series
(Continued)
Address
000058H
000059H
00005AH
00005BH
00005CH
00005DH
Register
Abbreviation
Register Name
Access
TCCS
Timer counter control status register
R/W
IPCP2
Input capture data register 2
R
IPCP3
Input capture data register 3
R
00005EH
to
000065H
000066H
000067H
000068H
000069H
R/W
TMCSR0
Timer control status register
TMCSR1
ROMM
ROM mirror function selection register
BVALR
TREQR
TCANR
TCR
RCR
XXXXXXXXB
R/W
16-bit reload timer 0
16-bit reload timer 1
0 0 0 0 0 0 0 0B
XXXX0 0 0 0B
0 0 0 0 0 0 0 0B
XXXX0 0 0 0B
W
ROM mirror function
selection module
XXXXXXX 1B
Message buffer valid register
R/W
CAN controller
0 0 0 0 0 0 0 0B
Send request register
R/W
CAN controller
0 0 0 0 0 0 0 0B
Send cancel register
W
CAN controller
0 0 0 0 0 0 0 0B
Send complete register
R/W
CAN controller
0 0 0 0 0 0 0 0B
Reception complete register
R/W
CAN controller
0 0 0 0 0 0 0 0B
CAN controller
0 0 0 0 0 0 0 0B
CAN controller
0 0 0 0 0 0 0 0B
CAN controller
0 0 0 0 0 0 0 0B
(system-reserved area) *
RRTRR
Reception RTR register
R/W
(system-reserved area) *
ROVRR
00008DH
00008EH
XXXXXXXXB
(system-reserved area) *
00008BH
00008CH
XXXXXXXXB
(system-reserved area) *
000089H
00008AH
XXXXXXXXB
(system-reserved area) *
000087H
000088H
16-bit I/O timer
(system-reserved area) *
000085H
000086H
0 XXXXXXXB
(system-reserved area) *
000083H
000084H
0 0 0 0 0 0 0 0B
(system-reserved area) *
000081H
000082H
R/W
R/W
000070H
to
00007FH
000080H
Initial Value
(system-reserved area) *
00006AH
to
00006EH
00006FH
Resource Name
Reception overrun register
R/W
(system-reserved area) *
RIER
Reception complete interrupt enable
register
R/W
(Continued)
22
MB90495G Series
(Continued)
Address
Register
Abbreviation
00008FH
to
00009DH
Register Name
Access
Resource Name
Initial Value
(system-reserved area) *
Address detection control register
R/W
ROM correction
function
0 0 0 0 0 0 0 0B
Delayed interrupt request generate/
cancel register
R/W
Delayed interrupt
generation module
XXXXXXX 0B
LPMCR
Low power consumption mode control
register
R/W
CKSCR
Clock selection register
R/W
00009EH
PACSR
00009FH
DIRR
0000A0H
0000A1H
0000A2H
to
0000A4H
Low-power
0 0 0 1 1 0 0 0B
consumption modes
Clock
1 1 1 1 1 1 0 0B
(system-reserved area) *
0000A5H
ARSR
Auto ready function selection register
W
0000A6H
HACR
High address control register
W
0 0 1 1 XX 0 0B
0 0 0 0 0 0 0 0B
External access
ECSR
Bus control signal selection register
0000A8H
WDTC
Watchdog timer control register
R/W
Watchdog timer
XXXXX 1 1 1B
0000A9H
TBTC
Time-base timer control register
R/W
Time-base timer
1 XX 0 0 1 0 0B
0000AAH
WTC
Watch timer control register
R/W
Watch timer
1 0 0 0 1 0 0 0B
512-Kbit
flash memory
0 0 0 X 0 0 0 0B
0000ABH
to
0000ADH
0000AEH
W
0 0 0 0 0 0 0 XB
or
0 0 0 0 1 0 0 XB
0000A7H
(system-reserved area) *
FMCS
0000AFH
Flash memory control status register
R/W
(system-reserved area) *
0000B0H
ICR00
Interrupt control register 00
R/W
0 0 0 0 0 1 1 1B
0000B1H
ICR01
Interrupt control register 01
R/W
0 0 0 0 0 1 1 1B
0000B2H
ICR02
Interrupt control register 02
R/W
0 0 0 0 0 1 1 1B
0000B3H
ICR03
Interrupt control register 03
R/W
0 0 0 0 0 1 1 1B
0000B4H
ICR04
Interrupt control register 04
R/W
0 0 0 0 0 1 1 1B
0000B5H
ICR05
Interrupt control register 05
R/W
0000B6H
ICR06
Interrupt control register 06
R/W
0 0 0 0 0 1 1 1B
0000B7H
ICR07
Interrupt control register 07
R/W
0 0 0 0 0 1 1 1B
0000B8H
ICR08
Interrupt control register 08
R/W
0 0 0 0 0 1 1 1B
0000B9H
ICR09
Interrupt control register 09
R/W
0 0 0 0 0 1 1 1B
0000BAH
ICR10
Interrupt control register 10
R/W
0 0 0 0 0 1 1 1B
(Continued)
Interrupt controller
0 0 0 0 0 1 1 1B
23
MB90495G Series
(Continued)
Address
Register
Abbreviation
0000BBH
ICR11
Interrupt control register 11
R/W
0 0 0 0 0 1 1 1B
0000BCH
ICR12
Interrupt control register 12
R/W
0 0 0 0 0 1 1 1B
0000BDH
ICR13
Interrupt control register 13
R/W
0000BEH
ICR14
Interrupt control register 14
R/W
0 0 0 0 0 1 1 1B
0000BFH
ICR15
Interrupt control register 15
R/W
0 0 0 0 0 1 1 1B
Register Name
0000C0H
to
0000FFH
Access
Resource Name
Interrupt controller
Initial Value
0 0 0 0 0 1 1 1B
(system-reserved area) *
Detection address configuration
register 0 (lower)
R/W
XXXXXXXXB
Detection address configuration
register 0 (mid)
R/W
XXXXXXXXB
001FF2H
Detection address configuration
register 0 (upper)
R/W
001FF3H
Detection address configuration
register 1 (lower)
R/W
Detection address configuration
register 1 (mid)
R/W
XXXXXXXXB
Detection address configuration
register 1 (upper)
R/W
XXXXXXXXB
TMR0/
TMRLR0
16-bit timer register 0/
16-bit reload register 0
R/W
16-bit reload timer 0
TMR1/
TMRLR1
16-bit timer register 1/
16-bit reload register 1
R/W
16-bit reload timer 1
001FF0H
001FF1H
001FF4H
PADR0
PADR1
001FF5H
003900H
003901H
003902H
003903H
ROM correction
function
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
003904H
to
00390FH
003910H
PRLL0
PPG0 reload register L
R/W
XXXXXXXXB
003911H
PRLH0
PPG0 reload register H
R/W
XXXXXXXXB
003912H
PRLL1
PPG1 reload register L
R/W
XXXXXXXXB
003913H
PRLH1
PPG1 reload register H
R/W
003914H
PRLL2
PPG2 reload register L
R/W
003915H
PRLH2
PPG2 reload register H
R/W
XXXXXXXXB
003916H
PRLL3
PPG3 reload register L
R/W
XXXXXXXXB
003917H
PRLH3
PPG3 reload register H
R/W
XXXXXXXXB
003918H
to
003BFFH
003C00H
to
003C0FH
(system-reserved area) *
8/16-bit PPG timer
XXXXXXXXB
XXXXXXXXB
(system-reserved area) *
RAM (general-purpose RAM)
(Continued)
24
MB90495G Series
(Continued)
Address
Register
Abbreviation
003C10H
to
003C13H
IDR0
ID register 0
R/W
XXXXXXXXB
to
XXXXXXXXB
003C14H
to
003C17H
IDR1
ID register 1
R/W
XXXXXXXXB
to
XXXXXXXXB
003C18H
to
003C1BH
IDR2
ID register 2
R/W
XXXXXXXXB
to
XXXXXXXXB
003C1CH
to
003C1FH
IDR3
ID register 3
R/W
XXXXXXXXB
to
XXXXXXXXB
003C20H
to
003C23H
IDR4
ID register 4
R/W
XXXXXXXXB
to
XXXXXXXXB
003C24H
to
003C27H
IDR5
ID register 5
R/W
XXXXXXXXB
to
XXXXXXXXB
003C28H
to
003C2BH
IDR6
ID register 6
R/W
XXXXXXXXB
to
XXXXXXXXB
003C2CH
to
003C2FH
IDR7
ID register 7
R/W
003C30H
003C31H
DLCR0
DLC register 0
R/W
XXXXXXXXB
XXXXXXXXB
003C32H
003C33H
DLCR1
DLC register 1
R/W
XXXXXXXXB
XXXXXXXXB
003C34H
003C35H
DLCR2
DLC register 2
R/W
XXXXXXXXB
XXXXXXXXB
003C36H
003C37H
DLCR3
DLC register 3
R/W
XXXXXXXXB
XXXXXXXXB
003C38H
003C39H
DLCR4
DLC register 4
R/W
XXXXXXXXB
XXXXXXXXB
003C3AH
003C3BH
DLCR5
DLC register 5
R/W
XXXXXXXXB
XXXXXXXXB
003C3CH
003C3DH
DLCR6
DLC register 6
R/W
XXXXXXXXB
XXXXXXXXB
003C3EH
003C3FH
DLCR7
DLC register 7
R/W
XXXXXXXXB
XXXXXXXXB
003C40H
to
003C47H
DTR0
Data register 0
R/W
Register Name
Access
Resource Name
CAN controller
Initial Value
XXXXXXXXB
to
XXXXXXXXB
XXXXXXXXB
to
XXXXXXXXB
(Continued)
25
MB90495G Series
(Continued)
Address
Register
Abbreviation
003C48H
to
003C4FH
DTR1
Data register 1
R/W
XXXXXXXXB
to
XXXXXXXXB
003C50H
to
003C57H
DTR2
Data register 2
R/W
XXXXXXXXB
to
XXXXXXXXB
003C58H
to
003C5FH
DTR3
Data register 3
R/W
XXXXXXXXB
to
XXXXXXXXB
003C60H
to
003C67H
DTR4
Data register 4
R/W
003C68H
to
003C6FH
DTR5
Data register 5
R/W
XXXXXXXXB
to
XXXXXXXXB
003C70H
to
003C77H
DTR6
Data register 6
R/W
XXXXXXXXB
to
XXXXXXXXB
003C78H
to
003C7FH
DTR7
Data register 7
R/W
XXXXXXXXB
to
XXXXXXXXB
Register Name
003C80H
to
003CFFH
Access
CSR
Control status register
R/W
003D02H
LEIR
Display last event register
R/W
003D03H
RTEC
003D06H
003D07H
BTR
Bit timing register
R/W
003D08H
IDER
IDE register
R/W
Receive/transmit error counter
003D09H
CAN controller
0 XXXX 0 0 1B
0 0 XXX 0 0 0B
0 0 0 XX 0 0 0B
0 0 0 0 0 0 0 0B
0 0 0 0 0 0 0 0B
R
CAN controller
1 1 1 1 1 1 1 1B
X 1 1 1 1 1 1 1B
XXXXXXXXB
(system-reserved area) *
TRTRR
003D0BH
Transmit RTR register
R/W
CAN controller
0 0 0 0 0 0 0 0B
CAN controller
XXXXXXXXB
CAN controller
0 0 0 0 0 0 0 0B
(system-reserved area) *
RFWTR
003D0DH
003D0EH
XXXXXXXXB
to
XXXXXXXXB
(system-reserved area) *
003D04H
003D05H
003D0CH
CAN controller
Initial Value
(system-reserved area) *
003D00H
003D01H
003D0AH
Resource Name
Remote frame reception standby
register
R/W
(system-reserved area) *
TIER
Transmit complete interrupt enable
register
R/W
(Continued)
26
MB90495G Series
(Continued)
Address
Register
Abbreviation
Register Name
003D0FH
003D10H
003D11H
Access
Resource Name
Initial Value
CAN controller
XXXXXXXXB
XXXXXXXXB
(system-reserved area) *
AMSR
Acceptance mask selection register
003D12H
003D13H
R/W
(system-reserved area) *
003D14H
to
003D17H
AMR0
003D18H
to
003D1BH
AMR1
Acceptance mask register 0
R/W
CAN controller
Acceptance mask register 1
003D1CH
to
003FFFH
R/W
XXXXXXXXB
to
XXXXXXXXB
XXXXXXXXB
to
XXXXXXXXB
(system-reserved area) *
Explanation of reset values
0 : The reset value of this bit is 0.
1 : The reset value of this bit is 1.
X : The reset value of this bit is undefined.
* : System-reserved area contains system-internal addresses, and cannot be used.
27
MB90495G Series
■ INTERRUPT CONDITIONS AND INTERRUPT VECTOR/REGISTER
Interrupt Condition
EI2OS
Compatible
Interrupt Vector
Number
Interrupt Register
Address
ICR
Address
Priority
*3
Reset
×
#08
08H
FFFFDCH


Highest
INT 9 instruction
×
#09
09H
FFFFD8H


↑
Exception processing
×
#10
0AH
FFFFD4H


Can controller reception complete (RX)
×
#11
0BH
FFFFD0H
Can controller reception complete (TX)
/Node status transition (NS)
×
#12
0CH
FFFFCCH
Reserved
×
#13
0DH
FFFFC8H
Reserved
×
#14
0EH
FFFFC4H
#15
0FH
FFFFC0H
#16
10H
FFFFBCH
16-bit reload timer 0
#17
11H
FFFFB8H
8/10-bit A/D converter
#18
12H
FFFFB4H
16-bit free-run timer overflow
#19
13H
FFFFB0H
External interrupt (INT2/INT3)
#20
14H
FFFFACH
External interrupt (INT0/INT1)
Time-base timer
×
Reserved
×
#21
15H
FFFFA8H
PPG timer ch0, ch1 underflow
×
#22
16H
FFFFA4H
Input capture 0 load
#23
17H
FFFFA0H
External interrupt (INT4/INT5)
#24
18H
FFFF9CH
Input capture 1 load
#25
19H
FFFF98H
#26
1AH
FFFF94H
External interrupt (INT6/INT7)
#27
1BH
FFFF90H
Watch timer
#28
1CH
FFFF8CH
PPG timer ch2, ch3 underflow
×
Reserved
×
#29
1DH
FFFF88H
Input capture 2 load
Input capture 3 load
×
#30
1EH
FFFF84H
Reserved
×
#31
1FH
FFFF80H
Reserved
×
#32
20H
FFFF7CH
Reserved
×
#33
21H
FFFF78H
Reserved
×
#34
22H
FFFF74H
Reserved
×
#35
23H
FFFF70H
16-bit reload timer 1
#36
24H
FFFF6CH
UART1 reception complete
#37
25H
FFFF68H
UART1 transmission complete
#38
26H
FFFF64H
ICR00 0000B0H (*1)
ICR01
0000B1H
ICR02 0000B2H (*1)
ICR03 0000B3H (*1)
ICR04 0000B4H (*1)
ICR05 0000B5H (*2)
ICR06 0000B6H (*1)
ICR07 0000B7H (*1)
ICR08 0000B8H (*1)
ICR09 0000B9H (*1)
ICR10 0000BAH (*1)
ICR11 0000BBH (*1)
ICR12 0000BCH (*1)
ICR13 0000BDH (*1)
(Continued)
28
MB90495G Series
(Continued)
Interrupt Condition
EI2OS
Compatible
Interrupt Vector
Number
Address
UART0 reception complete
#39
27H
FFFF60H
UART0 transmission complete
#40
28H
FFFF5CH
Flash memory
×
#41
29H
FFFF58H
Delayed interrupt generation module
×
#42
2AH
FFFF54H
Interrupt Register
ICR
Address
Priority
*3
ICR14 0000BEH (*1)
ICR15 0000BFH (*1)
↓
Lowest
: Available
× : Not available
: Available, EI2OS halt function supplied
: Available for interrupt conditions not shared by ICR
*1 : • The interrupt level is the same for peripheral devices sharing the ICR register.
• Peripheral devices that share the ICR register and use the extended intelligent I/O service only utilize one set.
• If one side of a peripheral device sharing the ICR register is set to extended intelligent I/O service, the other
side cannot use interrupts.
*2 : Only the 16-bit reload timer is compatible with EI2OS. Since PPG does not support EI2OS, if you use EI2OS
with the 16-bit reload timer, prohibit interrupts by PPG.
*3 : Priority if two or more interrupts with the same level are generated simultaneously.
29
MB90495G Series
■ PERIPHERAL RESOURCES
1. I/O Port
(1) Overview
General-purpose (parallel) I/O ports can be used as the I/O ports. The MB90495G Series has 7 ports (49) .
Each port doubles as a peripheral device I/O pin.
• I/O Port Features
I/O ports output data to I/O pins and load signals input to them, by means of the port data register (PDR) .
Additionally, the port direction register (DDR) sets the I/O direction of the I/O pins at the bit level. Below is a
description of each pin’s function, and the peripheral device that shares it.
• Port 0 : general-purpose I/O port/doubles as external address data bus pin
• Port 1 : general-purpose I/O port/doubles as PPG timer output, input capture input, and external address data
bus pin
• Port 2 : general-purpose I/O port/doubles as reload timer I/O, external interrupt input pin, and external address
bus pin
• Port 3 : general-purpose I/O port/doubles as UART0 I/O, free-run timer, and A/D converter startup trigger pin
• Port 4 : general-purpose I/O port/doubles as UART1 I/O, and CAN controller transmit/receive pin
• Port 5 : general-purpose I/O port/doubles as analog input pin
• Port 6 : general-purpose I/O port/doubles as external interrupt input pin
30
MB90495G Series
• Pin Block Diagram for Port 0 (single chip mode)
PDR (port data register)
Internal data bus
PDR read
Output latch
Pch
PDR write
Pin
DDR (port direction register)
Direction
latch
Nch
DDR write
Standby control (SPL = 1)
DDR read
Standby control : control stop mode (SPL = 1) , time-base timer mode (SPL = 1) and watch mode (SPL = 1)
• Port 0 register (single chip mode)
• The port 0 register contains the port 0 data register (PDR0) and the port 0 direction register (DDR0) .
• The bits making up the register are in a one-to-one relation to the port 0 pin.
Compatibility between port 0 register and pin
Port Name
Related register bit and corresponding pin
Port 0
PDR0, DDR0
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
Corresponding pin
P07
P06
P05
P04
P03
P02
P01
P00
31
MB90495G Series
• Block Diagram for Pins of Ports 1, 2, 3 and 4 (single-chip mode)
Peripheral device
input
Peripheral device
output
Port data register (PDR)
Peripheral device
output enabled
Internal data bus
PDR read
Output
latch
Pch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL = 1)
DDR read
Standby control : control stop mode (SPL = 1) , time-base timer mode (SPL = 1) and watch mode (SPL = 1)
• Port 1 register (single-chip mode)
• The port1 register contains the port 1 data register (PDR1) and the port 1 direction register (DDR1) .
• The bits making up the register are in a one-to-one relationship with the port 1 pins.
Port 1 Register and Corresponding Pins
Port Name
Related register bit and corresponding pin
Port 1
32
PDR1, DDR1
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
Corresponding pin
P17
P16
P15
P14
P13
P12
P11
P10
MB90495G Series
• Port 2 register
• The port2 register contains the port 2 data register (PDR2) , the port 2 direction register (DDR2) and the high
address control register (HACR).
• The high address control register (HACR) enables or disables the output of external addresses (A16 to A23).
When the register enables the output of the external addresses, the port can not be used as a peripheral
device and a general-purpose I/O port.
• The bits making up the register are in a one-to-one relationship with the port 2 pins.
Port 2 Register and Corresponding Pins
Port Name
Related register bit and corresponding pin
Port 2
PDR2, DDR2,
HACR
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
Corresponding pin
P27
P26
P25
P24
P23
P22
P21
P20
• Port 3 register
• The port3 register contains the port 3 data register (PDR3) and the port 3 direction register (DDR3) .
• The bus control signal selection register (ECSR) enables or disables the input and output of external bus
control signals (WRL / WRH, HRQ / HAK, RDY, CLK). When the register enables the input and output of the
external bus control signals, the port can not be used as a peripheral device and a general-purpose I/O port.
• The bits making up the register are in a one-to-one relationship with the port 3 pins.
Port 3 Register and Corresponding Pins
Port Name
Related register bit and corresponding pin
Port 3
PDR3, DDR3
bit7
bit6
ECSR
CKE
RYE
Corresponding pin
P37
P36
bit5
bit4
bit3
HDE
P35
bit2
bit1

WRE
P34
P33
bit0
P32
P31
P30
• Port 4 register
• The port4 register contains the port 4 data register (PDR4) and the port 4 direction register (DDR4) .
• The bits making up the register are in a one-to-one relationship with the port 4 pins.
Port 4 Register and Corresponding Pins
Port Name
Related register bit and corresponding pin
Port 4
PDR4, DDR4



bit4
bit3
bit2
bit1
bit0
Corresponding pin



P44
P43
P42
P41
P40
33
MB90495G Series
• Block Diagram of Port 5 Pins
Analog input
ADER
Internal data bus
Port data register (PDR)
PDR read
Output latch
Pch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL = 1)
DDR read
Standby control : control stop mode (SPL = 1) , time-base timer mode (SPL = 1) , and watch mode (SPL = 1)
• Port 5 register
• The port 5 register contains the port 5 data register (PDR5) , the port 5 direction register (DDR5) and the
analog input enable register (ADER) .
• The analog data enable register (ADER) enables or disables the input of analog signals by the analog input pin.
• The bits making up the register are in a one-to-one correspondence with the pins of port 5.
Port 5 Register and Corresponding Pins
Port Name
Related register bit and corresponding pin
PDR5, DDR5
Port 5
ADER
Corresponding pin
34
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
ADE7
ADE6
ADE5
ADE4
ADE3
ADE2
ADE1
ADE0
P57
P56
P55
P54
P53
P52
P51
P50
MB90495G Series
• Block Diagram of Port 6 Pins
Peripheral device input
Port data register (PDR)
Internal data bus
PDR read
Output latch
Pch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL = 1)
DDR read
Standby control : control stop mode (SPL = 1) , time-base timer mode (SPL = 1) , and watch mode (SPL = 1)
• Port 6 register
• The port 6 register contains the port 6 data register (PDR6) and the port 6 direction register (DDR6) .
• The bits making up the register are in a one-to-one relationship with the port 6 pins.
Port 6 Register and Corresponding Pins
Port Name
Related register bit and corresponding pin
Port 6
PDR6, DDR6
Corresponding pin
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0




P63
P62
P61
P60
35
MB90495G Series
2. Time-base Timer
The time-base timer is an 18-bit free-run counter (time-base counter) for counting up in synchronization with the
main clock (1/2 main oscillation clock) .
• Four interval times are available, and interrupt requests can be generated for each interval time.
• The time-base timer also has a function for supplying timers for oscillation stabilize standby time and operating
clocks for peripheral devices.
• Interval timer feature
• When the time-base timer counter reaches the interval set by the interval time selection bits (TBTC : TBC1,
TBC0) , it generates an overflow (TBTC : TBOF = 1) and interrupt request.
• If the interrupts due to overflow generation are enabled (TBTC : TBIE = 1) , when an overflow is generated
(TBTC : TBOF = 1) , an interrupt is generated.
• Select from the following 4 time-base timer intervals :
Time-base timer interval times
Count Clock
Interval Time
212/HCLK (approx. 1.0 ms)
214/HCLK (approx. 4.1 ms)
2/HCLK (0.5 µs)
216/HCLK (approx. 16.4 ms)
219/HCLK (approx. 131.1 ms)
HCLK : oscillation clock
The number in parentheses ( ) for 4-MHz oscillation clock operation
• Time-base Timer Block Diagram
To PPG timer
To watchdog timer
Time-base timer counter
21/HCLK
× 21 × 22 × 23
× 28 × 29 × 210 × 211 × 212 × 213 × 214 × 215 × 216 × 217 × 218
OF
OF
OF
OF
Power-on Reset
Stop Mode
CKSCR : MCS = 1 → 0*1
CKSCR : SCS = 0 → 1*2
To clock controller
oscillation stabilize
standby time selector
Clear counter
circuit
Interval
Timer selector
Clear TBOF
Time-base timer control register
(TBTC)
Reserved

Set TBOF

TBIE TBOF TBR TBC1 TBC0
Time-base timer interrupt signal
OF
HCLK
*1
*2
: overflow
: oscillation clock
: Switch machine clock from main clock to PLL clock
: Switch machine clock from subclock to main clock
See below for the actual interrupt request number of the time-base timer :
Interrupt request number : #16 (10H)
36
MB90495G Series
3. Watchdog Timer
The watchdog timer is a 2-bit timer used as a count clock for the timer-based or watch timer.
If the counter is not cleared within the interval time, it resets the CPU.
• Watchdog Timer Function
• The watchdog timer is a timer counter used to deal with runaway programs. Once the watchdog timer is
launched, it is necessary to keep clearing its counter within the specified interval. If the specified interval
passes without the watchdog timer counter being cleared, the CPU will be reset. This feature is called the
watchdog timer.
• The watchdog timer interval traces back to the clock interval input as the count clock. A watchdog reset is
generated for the smallest to largest times.
• The clock source output destination is set by the watchdog clock selection bit of the watch timer control register
(WTC : WDCS) .
• The watchdog timer interval is set time-base timer output selection bit/watch timer output selection bit of the
watchdog timer control register (WDTC : WT1, WT0) .
Watchdog Timer Intervals
Minimum
Maximum
Clock Interval
Minimum
Maximum
Clock Interval
Approx. 3.58 ms
Approx. 4.61 ms
214 ± 211
/HCLK
Approx. 0.457 s
Approx. 0.576 s
212 ± 29
/SCLK
Approx. 14.33 ms
Approx. 18.3 ms
216 ± 213
/HCLK
Approx. 3.584 s
Approx. 4.608 s
215 ± 212
/SCLK
Approx. 57.23 ms
Approx. 73.73 ms
218 ± 215
/HCLK
Approx. 7.168 s
Approx. 9.216 s
216 ± 213
/SCLK
221 ± 218
Approx. 14.336 s Approx. 18.432 s
/HCLK
HCLK : oscillation clock (4 MHz) ; SCLK : Subclock (8.192 kHz)
Approx. 458.75 ms Approx. 589.82 ms
217 ± 214
/SCLK
Notes: • If the count clock of the watchdog timer is set to time-base timer output (overflow signal) , then clearing the
time-base timer could make it take longer to reset the watchdog.
• If you are using a subclock as the machine clock, make sure to select watch timer output by setting the
watchdog timer clock source selection bit (WDCS) of the watch timer control register (WTC) to 0.
37
MB90495G Series
• Watchdog Timer Block Diagram
Watchdog timer control register (WDTC)
PONR

Watchdog timer
Watch timer control register (WTC)
WRST ERST SRST WTE
WT1
WT0
WDCS
2
Launch
Reset generation
Go to sleep mode
Go to time-base
timer mode
Counter
clearcontrol
circuit
Counter
clock
selector
Go to watch mode
Go to stop mode
2-bit
counter
Watchdog
reset
generation circuit
To internal reset
generation circuit
Clear
4
4
(Time-base timer counter)
Main clock
(1/2 HCLK)
× 21 × 22
× 28 × 29 × 210 × 211 × 212 × 213 × 214 × 215 × 216 × 217 × 218
(Clock counter)
Subclock
SCLK
× 21 × 22
HCLK : Oscillation clock
SCLK : Subclock
38
× 25 × 26 × 27 × 28 × 29 × 210 × 211 × 212 × 213 × 214 × 215
MB90495G Series
4. 16-bit I/O Timer
The 16-bit I/O timer is a complex module comprising one 16-bit free-run timer, and two input capture units (4
input pins) . Clock interval input signals and pulse widths can be measured based on the 16-bit free-run timer.
• 16-bit I/O Timer Configuration
The 16-bit I/O timer is made up of the following modules :
• One 16-bit free-run timer
• Two input capture units (each unit having 2 input pins)
• 16-bit I/O Timer Function
(1) 16-bit free-run timer function
The 16-bit free-run timer consists of a 16-bit up counter, a time counter control status register, and prescaler.
The 16-bit up counter counts up in synchronization with a fraction of the machine clock.
• The count clock can be set to one of eight fractions of the machine clock. The external clock signals input to
the 16-bit free-run timer clock input pin (FRCK) can be used as the count clock.
• Interrupts can be generated in response to counter value overflows.
• Interrupts launch the extended intelligent I/O service (EI2OS) .
• The count value of the 16-bit free-run timer can be cleared to “0000H” by either a reset, or software clear via
the timer count clear bit (TCCS : CLR) .
• The count value of the 16-bit free-run timer is output to the input capture, and used as the base time for capture
operation.
(2) Input Capture Function
When the input capture detects that an external signal edge has been input to an input pin, it stores the count
value of the 16-bit free-run timer in the input capture data register, for the point at which the edge was detected.
The input capture consists of an input capture register corresponding to four I/O pins, an input capture control
status register, and an edge detection circuit.
• When an edge is detected, either rising, falling, or both can be selected.
• An interrupt request can be generated to the CPU when an input signal edge is detected.
• Interrupts launch the extended intelligent I/O service (EI2OS) .
• Since the input capture has four pairs of input pins and input capture data registers, it can measure up to 4
phenomena.
• Block Diagram of 16-bit I/O Timer
Internal data bus
Input capture
Dedicated
bus
16-bit
free-run timer
16-bit free-run timer: The counter value of the 16-bit free-run timer is used as the base time of the input capture.
Input capture: Input capture detects rising, falling and both edges for external signals input to input pins, and stores
the counter value of the 16-bit free-run timer. Interrupts can be generated in response to input signal
edge detection.
39
MB90495G Series
• Block Diagram of 16-bit Free-run Timer
Output count value
to input capture
Timer counter data register (TCDT)
16-bit free-run timer
FRCK
φ
OF
CLK
STOP
Internal data bus
Pin
CLR
Prescaler
2
Timer counter control
status register
(TCCS)
IVF
IVFE STOP
Re- CLR CLK2 CLK1 CLK0
served
Free-run timer
interrupt request
φ
OF
: Machine clock
: overflow
Note: The 16-bit I/O timer contains one 16-bit free-run timer.
The interrupt request number of the 16-bit free-run timer is as follows :
Interrupt request number : 19 (13H)
Prescaler: Takes a fraction of the machine clock, and supplies a count clock to the 16-bit up-counter. One of
four machine clock fractions can be selected by setting the timer counter control status register
(TCCS) .
Timer Counter Register (TCDT) :
This is a 16-bit up-counter. It is possible to read the current counter value of the 16-bit free-run timer
by reading this counter. The counter can be set to an arbitrary value by writing to it while stopped.
Timer Counter Control Status Register (TCCS) :
TCCS selects the divide ratio of a machine clock, executes software clear of counter values. and
enables or disables counter operation. Also TCCS confirms and clears an overflow generation flag,
and enables or disables interruption.
40
MB90495G Series
• Input Capture Block Diagram
16-bit free-run timer
Edge detection circuit
IN3
Pin
Input capture data register 3 (IPCP3)
IN2
Pin
Input capture data register 2 (IPCP2)
2
2
Input capture
interrupt request
Input capture
control status register
(ICS01)
Internal data bus
Input capture
control status register ICP1 ICP0 ICE1 ICE0 EG11EG10EG01EG00
(ICS23)
ICP1 ICP0 ICE1 ICE0 EG11EG10EG01EG00
2
2
IN1
Pin
Input capture data register 1 (IPCP1)
IN0
Pin
Input capture data register 0 (IPCP0)
Edge detection circuit
41
MB90495G Series
5. 16-bit Reload Timer
The functions of the 16-bit reload timer are as follows :
• Choose one of three internal clocks or an external event clock as the count clock.
• Choose a software or external launch trigger.
• An interrupt can be sent to the CPU in response to an underflow generated by the 16-bit timer register. Interrupts
can be used to utilize the timer as an interval timer.
• When an underflow is generated by the 16-bit timer register (TMR) , select one-shot mode, where TMR counter
operation is halted, or reload mode, where the 16-bit reload register value is reloaded, and TMR count operation
continues.
• Supports extended intelligent I/O service (EI2OS) .
• The MB90495G Series features two on-chip 16-bit reload timer channels.
• 16-bit Reload Timer Operation Mode
Count Clock
Launch Trigger
Operation in Case of Underflow
Internal clock mode
Software trigger
External trigger
One-shot mode
Reload mode
Event count mode
Software trigger
One-shot mode
Reload mode
• Internal Clock Mode
• Set the count clock selection bits of the timer control status register (TMCSR : CSL1, CSL0) to “00B”, “01B” or
“10B” to set the 16-bit reload timer to internal clock mode.
• In internal clock mode, the timer counts down in synchronization with the internal clock.
• Set the count clock selection bits of the timer control status register (TMCSR : CSL1, CSL0) to select one of
three count clock intervals.
• Select software-triggered or externally triggered (edge detection) launch.
42
MB90495G Series
• 16-bit Reload Timer Block Diagram
Internal data bus
TMRLR
16-bit reload register
Reload signal
Reload
control circuit
TMR
UF
16-bit timer register
CLK
Count clock generation circuit
Machine
clock
φ
Prescaler
Gate
input
3
Valid clock
determination
circuit
Wait signal
Output to on-chip
peripheral functions
Clear
Internal
clock
CLK
Clock
selector
I/O control
circuit
Pin
TIN
External
clock
3
2
Select function



Output control circuit
Output signal
generation
circuit
Pin
EN
TOT
Select
signal
Operation
control circuit
 CSL1 CSL0 MOD2 MOD1 MOD0 OUTE OUTL RELD INTE UF CNTE TRG
Timer control status register (TMCSR)
Output interrupt request
43
MB90495G Series
6. Watch Timer
The watch timer is a 15-bit free-run counter that counts up in synchronization with the subclock.
• Eight different intervals can be selected, and interrupt requests generated for each interval time.
• Supplies a timer for subclock oscillation stabilization standby, and an operational clock for the watchdog timer.
• The subclock is always the count clock, regardless of the clock selection register (CKSCR) setting.
• Interval timer feature
• When the interval time set by the interval time selection bits (WTC : WTC2 to WTC0) is reached, the clock
timer generates an overflow in the bits corresponding to the interval time of the watch timer counter, and sets
the overflow flag bit (WTC : WTOF = 1) .
• Interrupts arising from overflows are enabled (WTC : WTIE = 1) , an interrupt request is generated when the
overflow flag bit is set (WTC : WTOF = 1) .
• Select from one of the following 8 watch timer intervals :
Clock Timer Interval Times
Subclock Frequency
Interval Time
8
2 /SCLK (31.25 ms)
29/SCLK (62.5 ms)
210/SCLK (125 ms)
SCLK (122 µs)
211/SCLK (250 ms)
212/SCLK (500 ms)
213/SCLK (1.0 s)
214/SCLK (2.0 s)
215/SCLK (4.0 s)
SCLK : Subclock frequency
Figures in parentheses ( ) are a sample calculation with the subclock running at 8.192 kHz.
44
MB90495G Series
• Watch Timer Block Diagram
To watchdog timer
Watch timer counter
SCLK
× 21 × 22 × 23 × 24 × 25 × 26 × 27 × 28 × 29 × 210 × 211 × 212 × 213 × 214 × 215
OF
OF
OF
OF
OF
OF
OF
OF
Power-on reset
Go to hardware standby
Counter
clear circuit
To subclock oscillation
stabilization standby time
Go to stop mode
Interval
timer selector
Watch timer interrupt
WDCS SCE WTIE WTOF WTR WTC2 WTC1 WTC0
Watch timer control register (WTC)
OF : Overflow
SCLK : Subclock
Notes: The actual interrupt request number generated by the watch timer is as follows :
Interrupt request number : #28 (1CH)
Watch timer counter: 15-bit up counter using the subclock (SCLK) as its count clock.
Counter clear circuit: This circuit clears the watch timer counter.
45
MB90495G Series
7. 8/16-Bit PPG
The 8/16-bit PPG timer is a 2-channel reload timer module (PPG0, PPG1) capable of arbitrary synchronization
and pulse output of duty ratio. Combining the 2 channel module can yield the following behavior :
• 8-bit PPG output, 2-channel independent operation mode
• 16-bit PPG output operation mode
• 8 + 8-bit PPG output operation mode
The MB90495G Series features two on-chip, 8/16-bit PPG timers. This section describes the functions of PPG0/
1. PPG2/3 has the same functions as PPG0/1.
• 8/16-bit PPG Timer Functions
The 8/16-bit PPG timer is made up of four 8-bit reload registers (PRLH0/PRLL0, PRLH1/PRLL1) , and two PPG
down counters (PNT0, PCNT1) .
• Since you can set each output pulse to “H” or “L” width independently, the interval and duty ratio of each
pulse can be set to an arbitrary value.
• Select one of 6 internal clocks as the count clock.
• Interrupt requests can be generated for each interval time, allowing the timer to be used as an interval timer.
• The use of an external circuit allows the timer to be used as a D/A converter.
46
MB90495G Series
• Block Diagram of 8/16-Bit PPG Timer 0
"H" level side data bus
"L" level side data bus
PPG0
reload
register
PPG0 operation mode control register
(PPGC0)
PRLL0
("L" level side)
PRLH0
("H" level side)
PEN0

PE0
PIE0 PUF0


Output
interrupt
request*
R
PPG0 temporary
buffer 0 (PRLBH0)
S
Q
2
Operation mode
control signal
Select signal
Reload register
L/H selector
Initial
count value
Reserved
Reload
PPG0 underflow
PPG1 underflow
(to PPG1)
Clear
Pulse selector
PPG0 down counter
(PCNT0)
Underflow
CLK
Invert
PPG0
output latch
Pin
PPG0
PPG output control circuit
Time-base timer output
(512/HCLK)
Peripheral clock (1/φ)
Peripheral clock (2/φ)
Peripheral clock (4/φ)
Peripheral clock (8/φ)
Peripheral clock (16/φ)
Count
clock
selector
3
Select signal
PCS2 PCS1 PCS0 PCM2 PCM1 PCM0


PPG0/1 count clock selection register (PPG01)

Reserved
HCLK
φ
*
: Undefined
: Reserved bit
: Oscillation clock frequency
: Machine clock frequency
: Interrupt output from 8/16-bit PPG timer 0 is merged with interrupt request output from PPG
timer 1 into a single interrupt via an OR circuit.
47
MB90495G Series
• Block Diagram of 8/16-Bit PPG Timer1
"H" level side data bus
"L" level side data bus
PPG1 operation mode control register
(PPGC1)
PPG1 reload
register
PRLL1
("L" side)
PRLH1
("H" side)

PEN1
PE10 PIE1 PUF1 MD1
MD0 Reserved
2
Operation
mode control signal
Output
interrupt
request*
R
PPG1 temporary
buffer (PRLBH1)
S
Reload selector
L/H selector
Q
Select signal
Initial count value
Reload
PPG1 down counter
(PCNT1)
Clear
Underflow
Invert
PPG1
output latch
Pin
PPG1
PPG1 underflow
(to PPG0)
CLK
PPG output control circuit
MD0
PPG0 underflow
(from PPG0) Time-base timer output
(512/HCLK)
Peripheral clock (1/φ)
Peripheral clock (2/φ)
Peripheral clock (4/φ)
Peripheral clock (8/φ)
Peripheral clock (16/φ)
Counter
clock
selector
3
Select signal
PCS2 PCS1 PCS0 PCM2 PCM1 PCM0


PPG0/1 count clock selection register (PPG01)

Reserved
HCLK
φ
*
48
: Undefined
: Reserved bit
: Oscillation clock frequency
: Machine clock frequency
: Interrupt output from 8/16-bit PPG timer 1 is merged with interrupt request output from
PPG timer 0 into a single interrupt via an OR circuit.
MB90495G Series
8. Delayed Interrupt Generation Module
The delayed interrupt generation module generates interrupts for switching tasks.
This module can be used to generate hardware interrupts from the software.
• Overview of the Delayed Interrupt Generation Module
Use the delayed interrupt generation module to generate or cancel hardware interrupts from the software.
Overview of the Delayed Interrupt Generation Module
Functions and Control
When the R0 bit of the delayed interrupt request generation/cancel register is
set to 1 (DIRR : R0 = 1) : Generate interrupt request
When the R0 bit of the delayed interrupt request generation/cancel register is
set to 0 (DIRR : R0 = 0) : Cancel interrupt request
Interrupt Condition
Interrupt number
#42 (2AH)
Interrupt control
There is no enable setting from the register
Interrupt flag
Stored in bit DIRR : R0
2
EI OS
Does not support extended intelligent I/O service
• Delayed Interrupt/Generation Module Block Diagram
Internal data bus







Delayed interrupt request generation/cancel register
(DIRR)
R0
S Interrupt
R request latch
Interrupt
request signal
 : Undefined
Interrupt request latch:This latch stores the delayed interrupt request generation/cancel register setting
(generates/cancels delayed interrupt requests) .
Delayed interrupt request generation/cancel register (DIRR) :
Generates or cancels delayed interrupt requests.
• Interrupt number
Below is the interrupt number used by the delayed interrupt generation module.
Interrupt number : #42 (2AH)
49
MB90495G Series
9. DTP/External Interrupts
The DTP/external interrupt transmits interrupt requests or data transfer requests generated by peripheral devices
to the CPU, generates external interrupt request, and starts the extended intelligent I/O service (EI2OS) .
• DTP/External Interrupt Functions
Outputs interrupt requests from external peripheral devices to the CPU using the same procedure as for peripheral functions, and generates external interrupts, or starts the extended intelligent I/O service (EI2OS) .
If the interrupt control register is configured to prohibit the extended intelligent I/O service (EI2OS) (ICR : ISE =
0) , then the external interrupt feature becomes valid, and the process branches into interrupt processing.
If the EI2OS is enabled (ICR : ISE = 1) , then the DTP function becomes valid, and the EI2OS automatically
transmits data, and after transmitting data a specified number of times, branches into interrupt processing.
Overview of DTP/External Interrupts
External interrupt
Input pins
Interrupt condition
Interrupt numbers
Interrupt control
Interrupt flag
Process selection
Processing
50
DTP functions
8 (INT0 to INT7)
Each pin sets individually in the detection level configuration register (ELVR)
“H” / “L” level/rising edge/falling edge input “H” / “L” level input
#15 (0FH) , #20 (14H) , #24 (18H) , #27 (1BH)
The DTP/external interrupt enable register (ENIR) enables or prohibits interrupt request
output
Interrupt conditions stored by DTP/external interrupt condition register (EIRR)
Set EI2OS to prohibited (ICR : ISE = 0)
Set EI2OS to enabled (ICR : ISE = 1)
Branch to external interrupt process
After the EI2OS conducts automated data
forwarding the specified number of times,
branches to interrupt processing.
MB90495G Series
• DTP/External Interrupt Block Diagram
Detection level configuration register (ELVR)
LB7 LA7 LB6 LA6 LB5 LA5 LB4 LA4
Pin
INT7
Pin
Internal data bus
INT6
Pin
INT5
Pin
INT4
Level/
edge
selector
Level/
edge
selector
Level/
edge
selector
Level/
edge
selector
LB3 LA3 LB2 LA2 LB1 LA1 LB0 LA0
Pin
INT3
Pin
INT2
Pin
INT1
Pin
INT0
Level/
edge
selector
Level/
edge
selector
Level/
edge
selector
Level/
edge
selector
DTP/external interrupt
input detection circuit
ER7 ER6 ER5 ER4 ER3 ER2 ER1 ER0
DTP/external interrupt condition
register (EIRR)
Interrupt request
signal
Interrupt request
signal
EN7 EN6 EN5 EN4 EN3 EN2 EN1 EN0
DTP/external interrupt enable
register (ENIR)
51
MB90495G Series
10. 8/10-bit A/D Converter
The 8/10-bit A/D converter converts analog voltage to 8 or 10-bit digital values, by means of RC successive
approximation conversion.
• The input signal can be selected from an 8-channel analog input pin set.
• Select a software trigger, internal timer output, or external trigger as the start trigger.
• Functions of the 8/10 A/D Converter
Converts analog voltage (input voltage) input to the analog input pins to 8-bit or 10-bit digital values. (A/D
conversion)
The 8/10-bit A/D converter has the following features :
• Single-channel A/D conversion time is a minimum of 6.12 µs, including sampling time.*
• Single-channel sampling time is a minimum of 2.0 µs.*
• RC-type successive approximation with sampling and hold circuits is used for conversion.
• Select 8 or 10-bit resolution.
• Analog input pins can use up to 8 channels.
• A/D conversion results are stored in the A/D data register, allowing them to be used to generate interrupts.
• Interrupt requests launch the EI2OS. Use the EI2OS to prevent dropped data even with continuous A/D conversion.
• Select software, internal timer output, or external trigger (falling edge) as the start trigger.
* : With machine clock operating at 16 MHz
• Conversion Modes of the 8/10-bit A/D Converter
Conversion Mode
52
Description
Single conversion mode
Conducts A/D conversion for each channel in turn, from the start channel to the end
channel. When A/D conversion of the end channel is completed, the A/D conversion
function halts.
Continuous conversion
mode
Conducts A/D conversion for each channel in turn, from the start channel to the end
channel. When A/D conversion of the end channel is completed, the function returns
to the start channel and continues A/D conversion.
Stop conversion mode
Suspends each channel and conducts A/D conversion, one at a time. When A/D
conversion of the end channel is completed, the function returns to the start channel
and repeats the A/D conversion and channel stop.
MB90495G Series
• 8/10-bit A/D Converter Block Diagram
Output interrupt request
A/D control
status register
ReBUSY INT INTE PAUS STS1 STS0 STAT served MD1 MD0 ANS2 ANS1 ANS0 ANE2 ANE1 ANE0
(ADCS)
2
2
Launch
Selector
Decoder
Internal data bus
ADTG
TO
6
φ
Comparator
AN7
AN6
AN5
AN4
AN3
AN2
AN1
AN0
Sample and
hold circuit
Control circuit
Analog
channel
selector
AVR
AVCC
AVSS
D/A converter
2
2
A/D data register
S10 ST1 ST0 CT1 CT0 
(ADCR)
TO

Reserved
φ
D9
D8
D7
D6 D5
D4
D3
D2
D1
D0
: Internal timer output
: Undefined
: Make sure this is always set to “01”
: Machine clock
53
MB90495G Series
11. UART0/1
The UART is a general-purpose serial data communications interface for synchronous or asynchronous communication with external devices.
• The UART has a clock-synchronous/clock-asynchronous two-way communications feature .
• Also supplies a master/slave communications feature (multi-processor mode) . (It can be used only master
side.)
• Interrupts can be generated upon send complete, receive complete, or reception error detection.
• Supports extended intelligent I/O service (EI2OS) .
• UART0/1 Functions
Functions
Data Buffer
Transfer mode
Full-duplex double buffer
• Clock-synchronous (no start, stop, or parity bit)
• Clock-asynchronous (start-stop synchronization)
Baud Rate
• Select from 8 dedicated baud rate generators
• External clock input possible
• Clock supplied from internal timer (16-bit reload timer) available
Data length
• 7-bit (asynchronous normal mode only)
• 8-bit
Signal method
Non Return to Zero (NRZ)
Reception Error Detection
• Framing error
• Overrun error
• Parity error (not available in operation mode 1 (multi processor mode) )
Interrupt Requests
• Receive interrupt (reception complete, reception error detected)
• Send interrupt (send complete)
• Both send and receive support extended intelligent I/O service (EI2OS)
Master/Slave Communications
Function
(In multiprocessor mode)
1-to-n (master to slave) communication available (can only be used as master)
Note : During clock-synchronous forwarding, just the data is forwarded, with no stop or start bit appended.
54
MB90495G Series
• UART0 Block Diagram
Control bus
Reception
interrupt
request output
Dedicated baud rate
generator
16-bit reload timer0
Send clock
Clock
selector
Reception clock
Pin
SCK0
Send interrupt
request output
Send
control circuit
Reception
control circuit
Start bit
detection circuit
Send start
circuit
Reception
bit counter
Send bit
counter
Reception
parity counter
Send parity
counter
Pin
SOT0
Reception
shift register
Pin
Send
shift register
SIN0
Reception status
determination circuit
Serial input
data register0
Reception
end
Send start
Serial output
data register0
EI2OS
receive error
generation signal
(to CPU)
Internal data bus
Communications
prescaler
control
register
Serial
edge
selection
register
NEG
MD
DIV3
DIV2
DIV1
DIV0
Serial
mode
register0
MD1
MD0
CS2
CS1
CS0
SCKE
SOE
Serial
control
register0
PEN
P
SBL
CL
A/D
REC
RXE
TXE
Serial
status
register0
PE
ORE
FRE
RDRF
TDRE
RIE
TIE
55
MB90495G Series
• UART1 Block Diagram
Control bus
Reception
interrupt
request output
Dedicated baud rate
generator
16-bit reload timer1
Send clock
Clock
selector
Reception clock
Pin
SCK1
Send interrupt
request output
Send
control circuit
Reception
control circuit
Start bit
detection circuit
Send start
circuit
Reception
bit counter
Send bit
counter
Reception
parity counter
Send parity
counter
Pin
SOT1
Reception
shift register
Pin
Send
shift register
SIN1
Reception status
determination circuit
Serial input
data register1
Reception
end
Send start
Serial output
data register1
EI2OS
receive error
generation signal
(to CPU)
Internal data bus
Communications
prescaler
control
register
56
MD
DIV2
DIV1
DIV0
Serial
mode
register1
MD1
MD0
CS2
CS1
CS0
RST
SCKE
SOE
Serial
control
register1
PEN
P
SBL
CL
A/D
REC
RXE
TXE
Serial
status
register1
PE
ORE
FRE
RDRF
TDRE
BDS
RIE
TIE
MB90495G Series
12. CAN Controller
CAN (Controller Area Network) is a serial communications protocol conforming to CAN version 2.0 A and B.
Sending and receiving is available in standard and extended frame format.
•
•
•
•
•
Can Controller Features
The CAN controller format conforms to CAN versions 2.0 A and B.
Sending and receiving is available in standard and extended frame format.
Supports automated data frame formatting through remote frame reception.
Baud rate : 10 Kbps to 1 Mbps. When using at 1 Mbps, the machine clock must be operated at 8 MHz or more.
Data Transmission Baud Rates
Machine clock
Baud rate (Max)
16 MHz
1 Mbps
12 MHz
1 Mbps
8 MHz
1 Mbps
4 MHz
500 Kbps
2 MHz
250 Kbps
Supplies 8 send/receive message buffers.
Sending and receiving available in standard frame format (ID 11-bit) , and extended frame format (ID 29-bit) .
Message data can be set to 0 to 8 bytes.
Possible to configure a multi-level message buffer.
The CAN controller has two built-in acceptance masks, each of which can be set to a different mask for reception
message IDs.
• The two acceptance masks can receive in standard or extended frame format.
• Configure four types of partial masks with full-bit compare, full-bit mask, and acceptance mask register 0/1.
•
•
•
•
•
57
MB90495G Series
• CAN Controller Block Diagram
EI2OS -16LX Bus
CPU
operation
clock
PSC
TS1
BTR
TS2
RSJ
TOE
TS
RS
CSR HALT
NIE
NT
NS1,0
Operation clock (TQ)
Bit timing
generation circuit
Prescaler
(1:1 to 1:64)
Node status
transition interrupt
generation circuit
TREQR
Error
control
circuit
Clear send
buffer
Send buffer
determination
circuit
Idle/
interrupt/
suspend/
send/
receive/
error/
overload
Bus status
determination circuit
Node status
transition
interrupt signal
RTEC
BVALR
Sink segment
Timer segment 1
Timer segment 2
Send
buffer
Send/receive
sequence
Error
frame
generation
circuit
Acceptance
Data
filter control
counter
circuit
Send ReID
DLC ception selection
DLC
Overload
frame
generation
circuit
Arbitration lost
Bit error/
Staff error/
CRC error/
Frame error/
ACK error
Send buffer
TCANR
Output
driver
Pin TX
Input
latch
Pin RX
TRTRR
Send shift
register
RFWTR
TCR
Set/clear send buffer
Send complete interrupt
generation circuit
Set reception buffer
Send
complete
interrupt
signal
RRTRR
Reception complete
interrupt generation circuit
Reception buffer
Set/clear send buffer
Reception
complete
interrupt
signal
ROVRR
Set reception
Select ID
buffer
TIER
RCR
RIER
Send DLC
Staffing
ACK
CRC
generation generation
circuit
circuit
CRC error
Receive
CRC generation
DLC
circuit/error check
Reception
shift register
Staff
error
Destaffing/
staffing error
check
AMSR
AMR0
AMR1
IDR0 to IDR7
DLCR0 to
DLCR7
DTR0 to DTR7
RAM
IDER
LEIR
58
0
1
Acceptance
filter
Reception buffer
determination
circuit
Arbitration
lost
Bit error
Reception buffer
RAM address
generation circuit
Reception buffer/
Send buffer/
Receive DLC/Send DLC/
Select ID
Arbitration check
Bit error check
ACK error
Acknowledgement
error check
Frame
error
Form error check
MB90495G Series
13. ROM Correction Function
In the case that the address of the instruction after the one that a program is currently processing matches the
address configured in the detection address configuration register, the program forces the next instruction to be
processed into an INT9 instruction, and branches to the interrupt process program. Since processing can be
conducted using INT9 interrupts, programs can be repaired using batch processing.
• Overview of the ROM Correction Function
• The address of the instruction after the one that a program is currently processing is always stored in an
address latch via the internal data bus. ROM correction constantly compares the address stored in the address
latch with the one configured in the detection address configuration register. If the two compared addresses
match, the CPU forcibly changes this instruction into an INT9 instruction, and executes an interrupt processing
program.
• There are two detection address configuration registers : PADR0 and PADR1. Each register provides an
interrupt enable bit. This allows you to individually configure each register to enable/prohibit the generation of
interrupts when the address stored in the address latch matches the one configured in the detection address
configuration register.
• ROM Correction Block Diagram
Comparator
Internal data bus
Address latch
PADR0 (24 bit)
Detection address configuration register 0
PADR1 (24 bit)
INT9 instruction
(INT9 interrupt generation)
Detection address configuration register 1
PACSR
Reserved
Reserved
Reserved
Reserved
AD1E
Reserved
AD0E
Reserved
Address detection control register (PACSR)
Reserved : Make sure this is always set to “01”
• Address latch
Stores value of address output to internal data bus.
• Address detection control register (PACSR)
Set this register to enable/prohibit interrupt output when an address match is detected.
• Detection address configuration register (PADR0, PADR1)
Configure an address with which to compare the address latch value.
59
MB90495G Series
14. ROM Mirror Function Selection Module
The ROM mirror function selection module configures ROM-internal data arrayed inside bank FF to be readable
by accessing bank 00.
• ROM Mirror Function Selection Module Block Diagram
ROM mirror function selection register (ROMM)
Reserved Reserved Reserved Reserved Reserved Reserved Reserved
Address
Internal data bus
Address area
Bank FF
Bank 00
Data
ROM
• Accessing Bank FF through ROM Mirror Function
004000H
Bank 00
ROM mirror area
00FFFFH
FC0000H
FE0000H
MB90V495G
FEFFFFH
FF0000H
MB90F498G
FF4000H
FFFFFFH
60
Bank FF
(Area corresponding
to ROM mirror)
MB90F497G
MB90497G
MI
MB90495G Series
15. 512-K/1-M bit Flash Memory
• Overview
There are three methods available for writing/deleting data to/from flash memory :
1. Parallel writer
2. Serial dedicated writer
3. Program runtime write/delete
• Overview of 512-K/1-M bit flash memory
512-Kbit flash memory is arrayed in bank FFH on the CPU memory map, 1-Mbit flash memory is arrayed in bank
FEH to FFH on the CPU memory map. The flash memory interface circuit provides read and program access
from the CPU.
Since instructions from the CPU are carried out via the flash memory interface circuit, flash memory can be
overwritten at the implementation level. This allows you to efficiently improve programs and data.
• Features of 512-K/1-M bit Flash Memory
• 512-Kbit flash memory : 64 KWords × 8-bit/32 KWords × 16-bit (16 Kbyte + 8 Kbyte + 8 Kbyte + 32 Kbyte)
sector architecture
• 1-Mbit flash memory : 128 KWords × 8-bit/64 KWords × 16-bit (16 Kbyte + 8 Kbyte + 8 Kbyte + 32 Kbyte +
64 Kbyte) sector architecture
• Auto program algorithm (Embedded AlgorithmTM : same as MBM29LV200)
• On-chip delete suspend/delete resume functions
• Data polling, write/delete completion detection through toggle bit
• Write/delete completion detection from CPU overwrite
• Sector-specific deletion available (sectors can be combined as desired)
• Write/delete iterations (minimum) : 10,000
Embedded AlgorithmTM is a trademark of Advanced Micro Device.
Notes : There is no function to read the manufacture or device code.
These codes also cannot be accessed through commands.
• Flash memory write/delete
• It is not possible to simultaneously write to and read from flash memory.
• When writing to or deleting from flash memory, first copy the program residing in flash memory into RAM,
then execute the program copied into RAM. This will allow you to write to flash memory.
61
MB90495G Series
• List of Flash Memory Registers and Reset Values
Flash memory control
status register (FMCS)
bit
7
6
5
4
3
2
1
0
0
0
0
X
0
0
0
0
× : Undefined
• Sector Architecture of 512-K/1-M bit Flash memory
• Sector architecture
512-Kbit flash memory : When accessing from the CPU, SA0 to SA3 are arrayed in the Bank FF register.
1-Mbit flash memory : When accessing from the CPU, SA0 is arrayed in the Bank FE register, SA1 to SA4
are arrayed in the Bank FF register.
Sector Architecture of 512-K/1-M bit Flash Memory
512-Kbit
Flash Memory
CPU Addresses
Writer Address*
FF0000H
70000H
FF7FFFH
77FFFH
FF8000H
78000H
FF9FFFH
79FFFH
FFA000H
7A000H
FFBFFFH
7BFFFH
FFC000H
7C000H
FFFFFFH
7FFFFH
CPU Addresses
Writer Address*
FE0000H
60000H
FEFFFFH
6FFFFH
FF0000H
70000H
FF7FFFH
77FFFH
FF8000H
78000H
FF9FFFH
79FFFH
FFA000H
7A000H
FFBFFFH
7BFFFH
FFC000H
7C000H
FFFFFFH
7FFFFH
SA0 (32 Kbytes)
SA1 (8 Kbytes)
SA2 (8 Kbytes)
SA3 (16 Kbytes)
1-Mbit
Flash Memory
SA0 (64 Kbytes)
SA1 (32 Kbytes)
SA2 (8 Kbytes)
SA3 (8 Kbytes)
SA4 (16 Kbytes)
* : If a parallel write is writing data to Flash memory, the write address corresponds to the CPU address.
If a general-purpose writer is used to write/delete, this address is written to/over.
62
MB90495G Series
■ ELECTRICAL CHARACTERISTICS
1. Absolute Maximum Ratings
Parameter
(VSS = AVSS = 0 V)
Symbol
Rating
Unit
Remarks
Min
Max
VCC
VSS − 0.3
VSS + 6.0
V
AVCC
VSS − 0.3
VSS + 6.0
V
VCC = AVCC
*1
AVR
VSS − 0.3
VSS + 6.0
V
AVCC ≥ AVR
*1
Input voltage
VI
VSS − 0.3
VSS + 6.0
V
*2
Output voltage
VO
VSS − 0.3
VSS + 6.0
V
*2
ICLAMP
− 2.0
+ 2.0
mA
*6
Σ| ICLAMP |

20
mA
*6
IOL

15
mA
*3
“L” level average output current
IOLAV

4
mA
*4
“L” level maximum total output current
ΣIOL

100
mA
ΣIOLAV

50
mA
*5
IOH

−15
mA
*3
“H” level average output current
IOHAV

−4
mA
*4
“H” level maximum total output current
ΣIOH

−100
mA
ΣIOHAV

−50
mA
Power consumption
PD

315
mW
Operating temperature
TA
−40
+105
°C
−40
+125
°C
Storage temperature
Tstg
−55
+150
°C
Power supply voltage
Maximum clamp current
Total maximum clamp current
“L” level maximum output current
“L” level average total output current
“H” level maximum output current
“H” level average total output current
*5
*7
*1 : AVCC and AVR shall never exceed VCC. Also, AVR shall never exceed AVCC.
*2 : VI and VO shall never exceed VCC + 0.3 V. However, if the maximum current to/from an input is limited by some
means with external components, the ICLAMP rating supersedes the VI rating.
*3 : The rating for the maximum output current is the peak value of one of the corresponding pins.
*4 : The standard for computing average output current is the average current output from one of the corresponding
pins over a period of 100 ms (the average value is taken by multiplying operating current by operational rate) .
*5 : The standard for computing average total output current is the average current output from all of the corresponding pins over a period of 100 ms (the average value is taken by multiplying operating current by operational
rate) .
*6 : • Applicable to pins: P00 to P07, P10 to P17, P20 to P27, P30 to P37, P40 to P44, P50 to P57, P60 to P63
• Use within recommended operating conditions.
• Use at DC voltage (current)
• The +B signal should always be applied a limiting resistance placed between the +B signal and the
microcontroller.
• The value of the limiting resistance should be set so that when the +B signal is applied the input current to
the microcontroller pin does not exceed rated values, either instantaneously or for prolonged periods.
• Note that when the microcontroller drive current is low, such as in the power saving modes, the +B input
potential may pass through the protective diode and increase the potential at the VCC pin, and this may affect
other devices.
(Continued)
63
MB90495G Series
(Continued)
• Note that if a +B signal is input when the microcontroller power supply is off (not fixed at 0 V) , the power
supply is provided from the pins, so that incomplete operation may result.
• Note that if the +B input is applied during power-on, the power supply is provided from the pins and the resulting
supply voltage may not be sufficient to operate the power-on reset.
• Care must be taken not to leave the +B input pin open.
• Note that analog system input/output pins other than the A/D input pins (LCD drive pins, comparator input
pins, etc.) cannot accept +B signal input.
• Sample recommended circuits:
Protective diode
VCC
P-ch
Limiting
resistance
+B input (0 V to 16 V)
N-ch
R
*7 : If used exceeding TA = +105 °C, be sure to contact us for reliability limitations.
WARNING: Semiconductor devices can be permanently damaged by application of stress (voltage, current,
temperature, etc.) in excess of absolute maximum ratings. Do not exceed these ratings.
64
MB90495G Series
2. Recommended Operating Conditions
Parameter
Power supply voltage
Symbol
VCC,
AVCC
Smoothing capacitor
CS
Operating temperature
TA
(VSS = AVSS = 0.0 V)
Value
Unit
Remarks
Min
Typ
Max
4.5
5.0
5.5
V
During normal operation,
TA = −40 °C to +105 °C
4.75
5.0
5.25
V
During normal operation,
+105 °C < TA ≤ +125 °C
3.0

5.5
V
Maintaining stop operation state
0.022
0.1
1.0
µF
*1
−40

+105
°C
−40

+125
°C
*2
*1 : Use a ceramic capacitor, or one with approximately the same frequency characteristics. The bypass capacitor
of the VCC pin should have a greater capacity than CS.
See the figure below for details about connecting a smooth capacitor to the CS.
*2 : If used exceeding TA = +105 °C, be sure to contact us for reliability limitations.
• C Pin Connection Diagram
C
CS
WARNING: The recommended operating conditions are required in order to ensure the normal operation of the
semiconductor device. All of the device’s electrical characteristics are warranted when the device is
operated within these ranges.
Always use semiconductor devices within their recommended operating condition ranges. Operation
outside these ranges may adversely affect reliability and could result in device failure.
No warranty is made with respect to uses, operating conditions, or combinations not represented on
the data sheet. Users considering application outside the listed conditions are advised to contact their
FUJITSU representatives beforehand.
65
MB90495G Series
3. DC Characteristics
Parameter
“H” level
input
voltage
“L” level
input
voltage
“H” level
output voltage
“L” level
output voltage
Input leakage
current
Symbol
VIHS
Pin Name
CMOS
hysteresis
input pin
VIHM MD input pin
(VCC = 5.0 V ± 5%, VSS = AVSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V ± 10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Condition
Value
Unit
Min
Typ
Max

0.8 VCC

VCC + 0.3
V

VCC − 0.3

VCC + 0.3
V
Remarks
VILS
CMOS
hysteresis
input pin

VSS − 0.3

0.2 VCC
V
VILM
MD input pin

VSS − 0.3

VSS + 0.3
V
VOH
All output
pins
VCC = 4.5 V,
IOH = −4.0 mA
VCC − 0.5


V
TA = −40 °C to +105 °C
VCC = 4.75 V
VCC − 0.5


V
+105 °C < TA ≤ +125 °C
VCC = 4.5 V,
IOL = 4.0 mA


0.4
V
TA = −40 °C to +105 °C
VCC = 4.75 V


0.4
V
+105 °C < TA ≤ +125 °C
VCC = 5.5 V,
VSS < VI < VCC
−5

5
µA TA = −40 °C to +105 °C
VCC = 5.25 V,
VSS < VI < VCC
−5

5
µA +105 °C < TA ≤ +125 °C
VCC = 5.0 V
Internal 16-MHz
operation,
Normal mode

30
40
MB90497G
mA MB90F497G
MB90F498G
VCC = 5.0 V
Internal 16-MHz
operation,
Flash memory
write mode

45
50
mA
MB90F497G
MB90F498G
VCC = 5.0 V
Internal 16-MHz
operation,
Flash memory
delete mode

45
50
mA
MB90F497G
MB90F498G
VCC = 5.0 V
Internal 16-MHz
operation,
Sleep mode

11
18
MB90497G
mA MB90F497G
MB90F498G
VOL
IIL
All output
pins
All output
pins
ICC
Power
supply
current*
VCC
ICCS
(Continued)
66
MB90495G Series
(Continued)
Parameter
Power
supply
current*
Power
supply
current*
(VCC = 5.0 V ± 5%, VSS = AVSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V ± 10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
SymPin Name
bol
Condition
Value
Unit
Typ
Max

0.6
1.2
MB90497G
mA MB90F497G
MB90F498G

30
50
µA MB90497G

300
500
µA
ICCLS
VCC = 5.0 V
Internal 8-kHz operation,
Subclock sleep mode
TA = + 25 °C

10
30
MB90497G
µA MB90F497G
MB90F498G
ICCT
VCC = 5.0 V
Internal 8-kHz operation,
Clock mode
TA = + 25 °C

8
25
MB90497G
µA MB90F497G
MB90F498G
VCC = 5.0 V
Stop mode, TA = + 25 °C

5
20
MB90497G
µA MB90F497G
MB90F498G
ICTS
VCC = 5.0 V
Internal 2-MHz operation,
Timer mode
ICCL
VCC = 5.0 V
Internal 8-kHz operation,
Subclock operation mode
TA = + 25 °C
VCC
ICCH
VCC
Input
Capacity
CIN
Other than
AVCC,
AVSS,
AVR, C,
VCC, or VSS


5
15
pF
Pull up
Resistor
RUP
RST

25
50
100
kΩ
RDOWN MD2

25
50
100
kΩ
Pull down
Resistor
Remarks
Min
MB90F497G
MB90F498G
* : This is when using the external clock as the power supply current test condition.
67
MB90495G Series
4. AC Characteristics
(1) Clock Timing
(VCC = 5.0 V ± 5%, VSS = AVSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V ± 10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Parameter
Clock frequency
Clock Cycle Time
Input clock pulse width
Input clock rising/falling
time
Internal operation clock
frequency
Internal operation clock
cycle time
Symbol
Pin Name
fC
Value
Unit
Remarks
Min
Typ
Max
X0, X1
3

16
MHz
fCL
X0A, X1A

32.768

kHz
tHCYL
X0, X1
62.5

333
ns
tLCYL
X0A, X1A

30.5

µs
PWH, PWL
X0
10


ns
PWLH, PWLL
X0A

15.2

µs
tCR, tCF
X0


5
ns
fCP

1.5

16
MHz
When oscillation circuit used
fLCP


8.192

kHz
When subclock used
tCP

62.5

666
ns
When using oscillation circuit
tLCP


122.1

µs
When subclock used
Duty ratio should be around
30 % to 70 %
When external clock used
• X0/X1 Clock Timing
tHCYL
0.8 VCC
X0
0.2 VCC
PWH
PWL
tCF
tCR
tLCYL
0.8 VCC
X0A
0.2 VCC
PWLH
PWLL
tCF
68
tCR
MB90495G Series
• PLL guaranteed operation range
Relationship between internal operating clock frequency and power supply voltage
Power supply voltage VCC (V)
MB90F497G/MB90F498G/MB90497G guaranteed operation range (TA = −40°C to +105°C)
MB90F497G/MB90F498G/MB90497G guaranteed operation range
( = +105°C < TA ≤ +125°C)
5.5
5.25
4.75
4.5
PLL guaranteed operation range
3.3
3.0
1.5
3
8
12
16
Internal clock fCP (MHz)
Relationship between external clock frequency and internal operation clock frequency
×4
Internal clock fCP (MHz)
16
×3
×2
×1
12
9
8
×1/2
(no multiplication)
4
3
4
8
16
External clock fC (MHz)
AC characteristics are specified by the following reference voltage values.
• Input Signal Waveform
Hysteresis Input Pin
• Output Signal Waveform
Output Pin
0.8 VCC
2.4 V
0.2 VCC
0.8 V
69
MB90495G Series
(2) Clock Output Timing
Parameter
(VCC = 5.0 V ± 5%, VSS = AVSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V ± 10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Symbol
Cycle time
tCYC
CLK ↑ → CLK ↓
tCHCL
Pin Name
Condition
CLK

Value
Unit
Min
Max
62.5

ns
20

ns
Remarks
tCYC
tCHCL
2.4 V
CLK
2.4 V
0.8 V
(3) Reset Input Timing
Parameter
Reset input time
Symbol
tRSTL
Value
Pin
Condition
Name
RST

Min
Max
16 tCP

Oscillator oscillation time*
+ 16 tCP

Unit
Remarks
ns
Normal mode
ms
Stop mode,
Watch mode,
Subclock mode,
Subsleep mode
* : Oscillator oscillation time is the time to reach 90% amplitude. For a crystal oscillator, this is a few to several
dozen ms; for a FAR/ceramic oscillator, this is several hundred µs to a few ms, and for an external clock this is 0 ms.
• Stop mode, Watch mode, Subclock mode, Subsleep mode
tRSTL
RST
0.2 VCC
X0
Internal operation
clock
0.2 VCC
90% of
amplitude
Oscillator
oscillation time
16 tCP
Oscillation stabilize standby time
Instruction execution
Internal reset
70
MB90495G Series
(4) Power-on Reset
(VCC = 5.0 V ± 5%, VSS = AVSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V ± 10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Parameter
Symbol
Pin
Name
Power supply rising time
tR
VCC
Power supply cutoff time
tOFF
VCC
Condition

Value
Unit
Min
Max
0.05
30
ms
1

ms
Remarks
Due to repeated operations
tR
VCC
2.7 V
0.2 V
0.2 V
0.2 V
tOFF
Sudden changes in the power supply voltage may cause a power-on reset. To change the power
supply voltage while the device is in operation, it is recommended that you raise the voltage at a
steady rate, in order to suppress fluctuations (see figure below). In this case, perform this operation
when the PLL clock is not being used. If, however, the voltage falling speed is no more than 1 V/s,
it is permissible to perform this operation while using the PLL clock.
VCC
3V
VSS
It is recommended that you keep the rising
speed to no more than 50 mV/ms.
RAM data hold period
71
MB90495G Series
(5) Bus Read Timing
Parameter
72
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Symbol
Pin Name
ALE pulse width
tLHLL
Valid address → ALE ↓ time
Value
Unit
Min
Max
ALE
tCP/2 − 20

ns
tAVLL
ALE, A23 to A16,
AD15 to AD00
tCP/2 − 20

ns
ALE ↓ → address valid time
tLLAX
ALE, AD15 to
AD00
tCP/2 − 15

ns
Valid address → RD ↓ time
tAVRL
A23 to A16,
AD15 to AD00, RD
tCP − 15

ns
Valid address → Valid data input
tAVDV
A23 to A16,
AD15 to AD00

5 tCP/2 − 60
ns
RD pulse width
tRLRH
RD
3 tCP/2 − 20

ns
RD ↓ → valid data input
tRLDV
RD, AD15 to AD00

3 tCP/2 − 60
ns
RD ↑ → data hold time
tRHDX
RD, AD15 to AD00
0

ns
RD ↓ → ALE ↑ time
tRHLH
RD, ALE
tCP/2 − 15

ns
RD ↑ → address valid time
tRHAX
RD, A23 to A16
tCP/2 − 10

ns
Valid address → CLK ↑ time
tAVCH
A23 to A16,
AD15 to AD00,
CLK
tCP/2 − 20

ns
RD ↓ → CLK ↑ time
tRLCH
RD, CLK
tCP/2 − 20

ns
ALE ↓ → RD ↓ time
tLLRL
ALE, RD
tCP/2 − 15

ns
Remarks
MB90495G Series
• Bus read timing
tAVCH
tRLCH
2.4 V
2.4 V
CLK
tAVLL
ALE
tLLAX
tRHLH
2.4 V
2.4 V
2.4 V
tLHLL
0.8 V
tAVRL
tRLRH
2.4 V
RD
0.8 V
tLLRL
tRHAX
2.4 V
2.4 V
A23 to A16
0.8 V
0.8 V
tRLDV
tAVDV
AD15 to AD00
2.4 V
tRHDX
2.4 V
0.8 VCC
Address
0.8 V
0.8 VCC
Read data
0.8 V
0.2 VCC
0.2 VCC
73
MB90495G Series
(6) Bus Write Timing
Parameter
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Symbol
Pin Name
Valid Address → WR ↓ time
tAVWL
WR pulse width
tWLWH
Valid data output → WR ↑ time
Value
Unit
Min
Max
A23 to A16,
AD15 to AD00, WR
tCP − 15

ns
WR
3 tCP/2 − 20

ns
tDVWH
AD15 to AD00, WR 3 tCP/2 − 20

ns
WR ↑ → data hold time
tWHDX
AD15 to AD00, WR
20

ns
WR ↑ → address valid time
tWHAX
A23 to A16, WR
tCP/2 − 10

ns
WR ↑ → ALE ↑ time
tWHLH
WR, ALE
tCP/2 − 15

ns
WR ↑ → CLK ↑ time
tWLCH
WR, CLK
tCP/2 − 20

ns
Remarks
tWLCH
2.4 V
CLK
tWHLH
2.4 V
ALE
tAVWL
tWLWH
2.4 V
WR (WRL, WRH)
0.8 V
tWHAX
2.4 V
2.4 V
0.8 V
0.8 V
A23 to A16
tDVWH
AD15 to AD00
2.4 V
Address
0.8 V
74
2.4 V
tWHDX
2.4 V
Write data
0.8 V
0.8 V
MB90495G Series
(7) Ready Input Timing
Parameter
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Symbol
Pin Name
RDY setup time
tRYHS
RDY hold time
tRYHH
Value
Unit
Min
Max
RDY
45

ns
RDY
0

ns
Remarks
Note : Use the automatic ready function if the setup time for the falling edge of the RDY signal is not sufficient.
• Ready Input timing
2.4 V
CLK
ALE
RD/WR
tRYHS
tRYHH
0.8 VCC
RDY
Unweighted
RDY
Weighted
(1 cycle)
0.8 VCC
0.2 VCC
(8) Hold Timing
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Parameter
Symbol Pin Name
Value
Min
Max
Unit
Pin in floating status → HAK ↓ time
tXHAL
HAK
30
tCP
ns
HAK ↑ → pin valid time
tHAHV
HAK
tCP
2 tCP
ns
Remarks
Note : It will take at least 1 cycle from the time the HRQ pin is loaded until the HAK changes.
• Hold Timing
2.4 V
HAK
0.8 V
tXHAL
Each pin
tHAHV
2.4 V
0.8 V
2.4 V
High-Z
0.8 V
75
MB90495G Series
(9) UART Timing
Parameter
(VCC = 5.0 V±5%, VSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Symbol
Pin Name
Condition
Serial clock cycle time
tSCYC
SCK1
SCK ↓ → SOT delay time
tSLOV
Valid SIN → SCK ↑
tIVSH
SCK ↑ → valid SIN hold time
tSHIX
Serial clock “H” pulse width
tSHSL
Serial clock “L” pulse width
tSLSH
SCK ↓ → SOT delay time
tSLOV
Valid SIN → SCK ↑
tIVSH
Eternal shift clock
SCK1, SOT1 mode outputpin :
CL = 80 pF + 1 TTL
SCK1, SIN1
SCK ↑ → valid SIN hold time
tSHIX
SCK1, SIN1
Value
Max
8 tCP*

ns
−80
80
ns
100

ns
60

ns
SCK1
4 tCP

ns
SCK1
4 tCP

ns

150
ns
60

ns
60

ns
SCK1, SOT1 Internal shift clock
mode output pin :
SCK1, SIN1 CL = 80 pF + 1 TTL
SCK1, SIN1
* : See “ (1) Clock Timing” for details about tCP (internal operating clock cycle time) .
Notes : • AC ratings are for CLK synchronous mode.
• CL is the load capacitor value connected to pins while testing.
76
Unit
Min
Remarks
MB90495G Series
• Internal shift clock mode
tSCYC
2.4 V
SCK
0.8 V
0.8 V
tSLOV
2.4 V
SOT
0.8 V
tIVSH
SIN
tSHIX
0.8 VCC
0.8 VCC
0.2 VCC
0.2 VCC
• External shift clock mode
tSLSH
SCK
0.2 VCC
tSHSL
0.8 VCC
0.8 VCC
0.2 VCC
tSLOV
2.4 V
SOT
0.8 V
tIVSH
SIN
tSHIX
0.8 VCC
0.8 VCC
0.2 VCC
0.2 VCC
77
MB90495G Series
(10) Timer Input Timing
(VCC = 5.0 V±5%, VSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Parameter
Input pulse width
Symbol
Pin Name
tTIWH
TIN0, TIN1, FRCK
tTIWL
IN0 to IN3, FRCK
Value
Condition

Min
Max
4 tCP

Unit
Remarks
ns
• Timer Input Timing
0.8 VCC
TIN0, TIN1,
IN0 to IN3,
FRCK
0.8 VCC
0.2 VCC
tTIWH
tTIWL
(11) Timer Output Timing
Parameter
0.2 VCC
(VCC = 5.0 V±5%, VSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Symbol
Pin Name
Condition
tTO
TOT0, TOT1,
PPG0 to PPG3

CLK ↑ → TOUT change time
Value
Min
Max
30

Unit Remarks
ns
• Timer Output Timing
2.4 V
CLK
2.4 V
TOT0, TOT1,
PPG0 to PPG3
0.8 V
tTO
(12) Trigger Input Timing
Parameter
Input pulse width
(VCC = 5.0 V±5%, VSS = 0.0 V, TA = −40 °C to +125 °C)
(VCC = 5.0 V±10%, VSS = 0.0 V, TA = −40 °C to +105 °C)
Symbol
Pin Name
Condition
tTRGH
tTRGL
INT0 to INT7,
ADTG

Value
Unit
Remarks

ns
Normal mode

µs
Stop mode
Min
Max
5 tCP
1
• Trigger Input Timing
INT0 to INT7,
ADTG
0.8 VCC
0.8 VCC
0.2 VCC
tTRGH
78
0.2 VCC
tTRGL
MB90495G Series
5. A/D Converter
(VCC = AVCC = 5.0 V±5%, VSS = AVSS = 0.0 V, 3.0 V ≤ AVR − AVSS, TA = −40 °C to +125 °C)
(VCC = AVCC = 5.0 V±10%, VSS = AVSS = 0.0 V, 3.0 V ≤ AVR − AVSS, TA = −40 °C to +105 °C)
Parameter
Value
Symbol
Pin Name
Resolution



Total error



Nonlinearity error


Differential linearity error

Zero transition voltage
Full-scale transition voltage
Min
Typ
Max
Unit
10
bit

±5.0
LSB


±2.5
LSB



±1.9
LSB
VOT
AN0 to AN7
AVSS −
3.5 LSB
AVSS +
0.5 LSB
AVSS +
4.5 LSB
V
VFST
AN0 to AN7
AVR −
6.5 LSB
AVR −
1.5 LSB
AVR +
1.5 LSB
V
Conversion time


66 tCP


ns
Sampling period


32 tCP


ns
Analog port input current
IAIN
AN0 to AN7


10
µA
Analog input voltage
VAIN
AN0 to AN7
AVSS

AVR
V

AVR
AVSS + 3.0

AVCC
V
IA
AVCC

2
7
mA
IAH
AVCC


5
µA
Reference voltage
Power supply current
Reference voltage supply
current
IR
AVR

0.9
1.3
mA
IRH
AVR


5
µA
Inter-channel variation

AN0 to AN7


4
LSB
Remarks
1 LSB =
AVR / 1024
Machine clock
of 16 MHz
*
*
* : Current (VCC = AVCC = AVR = 5.0 V) when A/D converter is not operating and CPU is halted.
79
MB90495G Series
6. A/D Converter Glossary
Resolution
Linearity error
: Analog changes that are identifiable with the A/D converter
: 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 1110” ←→ “11 1111 1111” ) from actual conversion characteristics.
Differential linearity error : The deviation of input voltage needed to change the output code by 1 LSB from the
ideal value.
Total error
: The difference between the actual value and the theoretical value, which includes
zero-transition error/full-scale transition error, linearity error, and differential linearity error.
Total error
3FF
3FE
Actual conversion
characteristics
1.5 LSB
Digital output
3FD
{1 LSB × (N − 1) + 0.5 LSB}
004
VNT
(actual measurement)
003
Actual conversion
characteristics
Ideal characteristics
002
001
0.5 LSB
AVSS
AVR
Analog input
VNT − {1 LSB × (N − 1) + 0.5 LSB}
1 LSB
AVR − AVSS
[V]
1024
Total error of digital output N =
1 LSB = (ideal value)
[LSB]
VOT (ideal value) = AVSS + 0.5 LSB [V]
VFST (ideal value) = AVR − 1.5 LSB [V]
VNT : The voltage to transition digital output from N − 1 to N.
(Continued)
80
MB90495G Series
(Continued)
Differential linearity error
Linearity error
Ideal
characteristics
3FF
Actual conversion
characteristics
{1 LSB × (N − 1)
+ VOT }
Digital output
3FD
N+1
VFST
(actual
measurement)
VNT
(actual
measurement)
004
Actual conversion
characteristics
003
Digital output
3FE
Actual conversion
characteristics
N
V (N + 1) T
(actual
measurement)
VNT (actual measurement)
N−1
002
Ideal characteristics
Actual conversion
characteristics
N−2
001
VOT (actual measurement)
AVSS
AVR
AVSS
AVR
Analog input
Analog input
Linearity error of digital output N =
Differential linearity error of digital output N =
1 LSB =
VNT − {1 LSB × (N − 1) + VOT}
1 LSB
V (N + 1) T − VNT
1 LSB
VFST − VOT
1022
[LSB]
− 1 LSB [LSB]
[V]
VOT : Voltage for transition from digital output 000H to 001H.
VFST : Voltage for transition from digital output 3FEH to 3FFH.
7. Notes on Using A/D Converter
Select the output impedance value for the external circuit of analog input according to the following conditions :
External circuit output impedance values of about 5 kΩ or lower are recommended.
If external capacitors are used, a capacitance of several thousand times the internal capacitor value is recommended in order to minimize the effect of voltage distribution between the external and internal capacitor.
If the output impedance of the external circuit is too high, the sampling time for analog voltages may not be
sufficient (sampling period = 2.00 µs @ machine clock of 16 MHz) .
• Model Analog Input Circuit
Comparator
Analog input
R
C
MB90F497G, MB90F498G, MB90V495G R 3.2 kΩ, C 30 pF
MB90497G
R 2.6 kΩ, C 28 pF
Note : The figures given here are the suggested values.
• About Error
The smaller the absolute value of | AVR - AVSS |, the greater the relative error.
81
MB90495G Series
8. Flash Memory Program/Erase Characteristics
Parameter
Condition
Sector erase time
Chip erare time
TA = + 25 °C
VCC = 5.0 V
Word (16-bit width)
programming time
Erase/Program cycle
82

Value
Unit
Remarks
15
s
Excludes 00H programming prior
erasure
5

s
Excludes 00H programming prior
erasure

16
3,600
µs
Excludes system-level overhead
10,000


cycle
Min
Typ
Max

1

MB90495G Series
■ EXAMPLE CHARACTERISTICS
• MB90F497G/F498G
ICC − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
45
40
f = 16 MHz
35
ICC (mA)
30
f = 10 MHz
25
f = 8 MHz
20
15
f = 4 MHz
10
f = 2 MHz
5
0
3.0
4.0
5.0
VCC (V)
6.0
7.0
ICCS − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
16
14
12
f = 16 MHz
ICCS (mA)
10
8
f = 10 MHz
f = 8 MHz
6
4
f = 4 MHz
2
0
3.0
f = 2 MHz
4.0
5.0
VCC (V)
6.0
7.0
(Continued)
83
MB90495G Series
(Continued)
ICCL − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
180
160
140
ICCL (µA)
120
f = 8 kHz
100
80
60
40
20
0
3.0
4.0
5.0
VCC (V)
6.0
7.0
ICCLS − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
10
9
8
ICCLS (µA)
7
f = 8 kHz
6
5
4
3
2
1
0
3.0
4.0
5.0
VCC (V)
6.0
7.0
(Continued)
84
MB90495G Series
(Continued)
ICCT − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
7
6
f = 8 kHz
ICCT (µA)
5
4
3
2
1
0
3.0
4.0
5.0
VCC (V)
6.0
VOL − IOL
TA = 25 °C, VCC = 4.5 V
1000
1000
900
900
800
800
700
700
600
600
VOL (V)
VCC - VOH (mV)
(VCC − VOH) − IOH
TA = 25 °C, VCC = 4.5 V
500
500
400
400
300
300
200
200
100
100
0
7.0
0
0
1
2
3
4
5 6 7
IOH (mA)
8
9 10 11 12
0
1
2
3
4
5 6 7
IOL (mA)
8
9 10 11 12
85
MB90495G Series
• MB90497G
ICC − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
45
40
35
f = 16 MHz
ICC (mA)
30
25
f = 10 MHz
20
f = 8 MHz
15
10
f = 4 MHz
5
f = 2 MHz
0
3.0
4.0
5.0
VCC (V)
6.0
7.0
ICCS − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
16
14
f = 16 MHz
12
ICCS (mA)
10
f = 10 MHz
8
f = 8 MHz
6
4
f = 4 MHz
2
0
3.0
f = 2 MHz
4.0
5.0
VCC (V)
6.0
7.0
(Continued)
86
MB90495G Series
(Continued)
ICCL − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
25
ICCL (µA)
20
f = 8 kHz
15
10
5
0
3.0
4.0
5.0
VCC (V)
6.0
7.0
ICCLS − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
10
9
f = 8 kHz
8
ICCLS (µA)
7
6
5
4
3
2
1
0
3.0
4.0
5.0
VCC (V)
6.0
7.0
(Continued)
87
MB90495G Series
(Continued)
ICCT − VCC
TA = 25 °C, external clock operation
f = internal operation frequency
7
f = 8 kHz
6
ICCT (µA)
5
4
3
2
1
0
3.0
4.0
5.0
VCC (V)
6.0
1000
1000
900
900
800
800
700
700
600
600
500
500
400
400
300
300
200
200
100
100
0
0
0
88
VOL − IOL
TA = 25 °C, VCC = 4.5 V
VOL (V)
VCC - VOH (mV)
(VCC − VOH) − IOH
TA = 25 °C, VCC = 4.5 V
7.0
1
2
3
4
5 6 7
IOH (mA)
8
9 10 11 12
0
1
2
3
4
5 6 7
IOL (mA)
8
9 10 11 12
MB90495G Series
■ ORDERING INFORMATION
Part Number
Package
MB90F497GPF
MB90497GPF
MB90F498GPF
64-pin plastic QFP
(FPT-64P-M06)
MB90F497GPFM
MB90497GPFM
MB90F498GPFM
64-pin plastic LQFP
(FPT-64P-M09)
Remarks
89
MB90495G Series
■ PACKAGE DIMENSIONS
Note 1) * : These dimensions do not include resin protrusion.
Note 2) Pins width and pins thickness include plating thickness.
Note 3) Pins width do not include tie bar cutting remainder.
64-pin plastic QFP
(FPT-64P-M06)
24.70±0.40(.972±.016)
* 20.00±0.20(.787±.008)
51
0.17±0.06
(.007±.002)
33
52
32
18.70±0.40
(.736±.016)
*14.00±0.20
(.551±.008)
INDEX
Details of "A" part
+0.35
3.00 –0.20
+.014
.118 –.008
64
(Mounting height)
20
0~8˚
1
19
1.00(.039)
0.42±0.08
(.017±.003)
0.20(.008)
+0.15
M
0.25 –0.20
1.20±0.20
(.047±.008)
+.006
.010 –.008
(Stand off)
"A"
0.10(.004)
C
2003 FUJITSU LIMITED F64013S-c-5-5
Dimensions in mm (inches)
Note : The values in parentheses are reference values.
(Continued)
90
MB90495G Series
(Continued)
64-pin plastic LQFP
(FPT-64P-M09)
Note 1) * : These dimensions do not include resin protrusion.
Note 2) Pins width and pins thickness include plating thickness.
Note 3) Pins width do not include tie bar cutting remainder.
14.00±0.20(.551±.008)SQ
* 12.00±0.10(.472±.004)SQ
48
0.145±0.055
(.0057±.0022)
33
49
32
0.10(.004)
Details of "A" part
+0.20
1.50 –0.10
+.008
.059 –.004
(Mounting height)
0.25(.010)
INDEX
0~8˚
64
17
1
0.65(.026)
C
"A"
16
0.32±0.05
(.013±.002)
0.13(.005)
0.50±0.20
(.020±.008)
0.60±0.15
(.024±.006)
0.10±0.10
(.004±.004)
(Stand off)
M
2003 FUJITSU LIMITED F64018S-c-3-5
Dimensions in mm (inches)
Note : The values in parentheses are reference values.
91
MB90495G Series
FUJITSU LIMITED
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Customers are advised to consult with FUJITSU sales
representatives before ordering.
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circuit examples, in this document are presented solely for the
purpose of reference to show examples of operations and uses of
Fujitsu semiconductor device; Fujitsu does not warrant proper
operation of the device with respect to use based on such
information. When you develop equipment incorporating the
device based on such information, you must assume any
responsibility arising out of such use of the information. Fujitsu
assumes no liability for any damages whatsoever arising out of
the use of the information.
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function and schematic diagrams, shall not be construed as license
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and manufactured as contemplated for general use, including
without limitation, ordinary industrial use, general office use,
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and manufactured as contemplated (1) for use accompanying fatal
risks or dangers that, unless extremely high safety is secured, could
have a serious effect to the public, and could lead directly to death,
personal injury, severe physical damage or other loss (i.e., nuclear
reaction control in nuclear facility, aircraft flight control, air traffic
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Please note that Fujitsu will not be liable against you and/or any
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F0306
 FUJITSU LIMITED Printed in Japan
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