FUJITSU MB90F387S

FUJITSU SEMICONDUCTOR
DATA SHEET
DS07-13717-3E
16-bit Proprietary Microcontroller
CMOS
F2MC-16LX MB90385 Series
MB90387/387S/F387/F387S/MB90V495G
■ DESCRIPTION
MB90385 series devices are general-purpose high-performance 16-bit micro controllers designed for process
control of consumer products, which require high-speed real-time processing. The devices of this series have the
built-in full-CAN interface.
The system, inheriting the architecture of F2MC* family, employs additional instruction ready for high-level languages, expanded addressing mode, enhanced multiply-divide instructions, and enriched bit-processing instructions. Furthermore, employment of 32-bit accumulator achieves processing of long-word data (32 bits).
The peripheral resources of MB90385 series include the following:
8/10-bit A/D converter, UART (SCI), 8/16-bit PPG timer, 16-bit input-output timer (16-bit free-run timer, input
capture 0, 1, 2, 3 (ICU)), and CAN controller.
*: “F2MC”, an abbreviation for FUJITSU Flexible Microcontroller, is a registered trademark of FUJITSU Ltd.
■ FEATURES
• Clock
• Built-in PLL clock frequency multiplication circuit
• Selection of machine clocks (PLL clocks) is allowed among frequency division by two on oscillation clock, and
multiplication of 1 to 4 times of oscillation clock (for 4-MHz oscillation clock, 4 MHz to 16 MHz).
• Operation by sub-clock (8.192 kHz) is allowed.
• Minimum execution time of instruction: 62.5 ns (when operating with 4-MHz oscillation clock, and 4-time multiplied PLL clock).
(Continued)
■ PACKAGE
48-pin plastic-LQFP
(FPT-48P-M26)
MB90385 Series
• 16 Mbyte CPU memory space
• 24-bit internal addressing
• Instruction system best suited to controller
• Wide choice of data types (bit, byte, word, and long word)
• Wide choice of addressing modes (23 types)
• Enhanced multiply-divide instructions and RETI instructions
• Enhanced high-precision computing with 32-bit accumulator
• Instruction system compatible with high-level language (C language) and multitask
• Employing system stack pointer
• Enhanced various pointer indirect instructions
• Barrel shift instructions
• Increased processing speed
• 4-byte instruction queue
• Powerful interrupt function with 8 levels and 34 factors
• Automatic data transfer function independent of CPU
• Expanded intelligent I/O service function (EI2 OS): Maximum of 16 channels
• Low power consumption (standby) mode
• Sleep mode (a mode that halts CPU operating clock)
• Time-base timer mode (a mode that operates oscillation clock, sub clock, time-base timer and clock timer only)
• Clock mode (a mode that operates sub clock and clock timer only)
• Stop mode (a mode that stops oscillation clock and sub clock)
• CPU blocking operation mode
• Process
• CMOS technology
• I/O port
• General-purpose input/output port (CMOS output) :
MB90387, MB90F387
: 34 ports (including 4 high-current output ports)
MB90387S, MB90F387S : 36 ports (including 4 high-current output ports)
• Timer
• Time-base timer, clock timer, watchdog timer: 1 channel
• 8/16-bit PPG timer: 8-bit x 4 channels, or 16-bit x 2 channels
• 16-bit reload timer: 2 channels
• 16-bit input/output timer
- 16-bit free run timer: 1 channel
- 16-bit input capture: (ICU): 4 channels
Interrupt request is issued upon latching a count value of 16-bit free run timer by detection of an edge on pin
input.
• CAN controller: 1 channel
• Compliant with Ver2.0A and Ver2.0B CAN specifications
• 8 built-in message buffers
• Transmission rate of 10 Kbps to 1 Mbps (by 16 MHz machine clock)
• CAN wake-up
• UART (SCI): 1 channel
• Equipped with full-duplex double buffer
• Clock-asynchronous or clock-synchronous serial transmission is available.
(Continued)
2
MB90385 Series
(Continued)
• DTP/External interrupt: 4 channels, CAN wakeup: 1channel
• Module for activation of expanded intelligent I/O service (EI2OS), and generation of external interrupt.
• Delay interrupt generator module
• Generates interrupt request for task switching.
• 8/10-bit A/D converter: 8 channels
• Resolution is selectable between 8-bit and 10-bit.
• Activation by external trigger input is allowed.
• Conversion time: 6.125 µs (at 16-MHz machine clock, including sampling time)
• Program patch function
• Address matching detection for 2 address pointers.
3
MB90385 Series
■ PRODUCT LINEUP
Part Number
Parameter
Classification
MB90F387/S
MB90387/S
MB90V495G
Flash ROM
Mask ROM
Evaluation product
ROM capacity
64 Kbytes

RAM capacity
2 Kbytes
6 Kbytes
Process
CMOS
Package
Operating power supply voltage
Special power supply for
emulator*1
LQFP-48 (0.50 mm width)
PGA256
3.5 V to 5.5 V
4.5 V to 5.5 V

None
Number of basic instructions
Instruction bit length
Instruction length
Data bit length
CPU functions
: 351 instructions
: 8 bits and 16 bits
: 1 byte to 7 bytes
: 1 bit, 8 bits, 16 bits
Minimum instruction execution time : 62.5 ns (at 16-MHz machine clock)
Interrupt processing time : 1.5 µs at minimum (at 16-MHz machine clock)
Low power consumption
(standby) mode
Sleep mode/Clock mode/Time-base timer mode/
Stop mode/CPU intermittent
I/O port
General-purpose input/output ports (CMOS output) : 34 ports (36 ports*2)
including 4 high-current output ports (P14 to P17)
Time-base timer
18-bit free-run counter
Interrupt cycle : 1.024 ms, 4.096 ms, 16.834 ms, 131.072 ms
(with oscillation clock frequency at 4 MHz)
Watchdog timer
Reset generation cycle: 3.58 ms, 14.33 ms, 57.23 ms, 458.75 ms
(with oscillation clock frequency at 4 MHz)
16-bit input/
output timer
16-bit free-run
timer
Number of channels: 1
Interrupt upon occurrence of overflow
Input capture
Number of channels: 4
Retaining free-run timer value set by pin input (rising edge, falling edge, and
both edges)
16-bit reload timer
Number of channels: 2
16-bit reload timer operation
Count clock cycle: 0.25 µs, 0.5 µs, 2.0 µs
(at 16-MHz machine clock frequency)
External event count is allowed.
Clock timer
15-bit free-run counter
Interrupt cycle: 31.25 ms, 62.5 ms, 12 ms, 250 ms, 500 ms, 1.0 s, 2.0 s
(with 8.192 kHz sub clock)
8/16-bit PPG timer
Number of channels: 2 (four 8-bit channels are available also.)
PPG operation is allowed with four 8-bit channels or one 16-bit channel.
Outputting pulse wave of arbitrary cycle or arbitrary duty is allowed.
Count clock: 62.5 ns to 1 µs
(with 16 MHz machine clock)
(Continued)
4
MB90385 Series
(Continued)
Part Number
MB90F387/S
Parameter
MB90387/S
MB90V495G
Delay interrupt generator
module
Interrupt generator module for task switching. Used for realtime OS.
DTP/External interrupt
Number of inputs: 4
Activated by rising edge, falling edge, “H” level or “L” level input.
External interrupt or expanded intelligent I/O service (EI2OS) is available.
8/10-bit A/D converter
Number of channels: 8
Resolution: Selectable 10-bit or 8-bit.
Conversion time: 6.125 µs (at 16-MHz machine clock, including sampling time)
Sequential conversion of two or more successive channels is allowed. (Setting
a maximum of 8 channels is allowed.)
Single conversion mode
: Selected channel is converted only once.
Sequential conversion mode: Selected channel is converted repetitively.
Halt conversion mode
: Conversion of selected channel is stopped and
activated alternately.
UART(SCI)
Number of channels: 1
Clock-synchronous transfer: 62.5 Kbps to 2 Mbps
Clock-asynchronous transfer: 9,615 bps to 500 Kbps
Communication is allowed by bi-directional serial communication function and
master/slave type connection.
CAN
Compliant with Ver 2.0A and Ver 2.0B CAN specifications.
8 built-in message buffers.
Transmission rate of 10 Kbps to 1 Mbps (by 16 MHz machine clock)
CAN wake-up
*1 : Settings of DIP switch S2 for using emulation pod MB2145-507. For details, see MB2145-507 Hardware Manual
(2.7 Power Pin solely for Emulator).
*2 : MB90387S, MB90F387S
■ PACKAGES AND PRODUCT MODELS
Package
MB90F387/S
MB90387/S
FPT-48P-M26
: Yes × : No
Note : Refer to
PACKAGE DIMENSION for details of the package.
■ PRODUCT COMPARISON
Memory space
When testing with test product for evaluation, check the differences between the product and a product to be
used actually. Pay attention to the following points:
• The MB90V495G has no built-in ROM. However, a special-purpose development tool allows the operations
as those of one with built-in ROM. ROM capacity depends on settings on a development tool.
• On MB90V495G, an image from FF4000H to FFFFFFH is viewed on 00 bank and an image of FE0000H to
FF3FFFH is viewed only on FE bank and FF bank. (Modified on settings of a development tool.)
• On MB90F387/S/387/S, an image from FF4000H to FFFFFFH is viewed on 00 bank and an image of FE0000H
to FF3FFFH is viewed only on FF bank.
5
MB90385 Series
■ PIN ASSIGNMENT
1
2
3
4
5
6
7
8
9
10
11
12
36
35
34
33
32
31
30
29
28
27
26
25
P21/TOT0
P22/TIN1
P23/TOT1
P24/INT4
P25/INT5
P26/INT6
P27/INT7
MD2
MD1
MD0
RST
VCC
AVCC
AVR
P50/AN0
P51/AN1
P52/AN2
P53/AN3
P54/AN4
P55/AN5
P56/AN6
P57/AN7
P37/ADTG
P20/TIN0
13
14
15
16
17
18
19
20
21
22
23
24
48
47
46
45
44
43
42
41
40
39
38
37
AVSS
X1A/P36*
X0A/P35*
P33
P32
P31
P30
P44/RX
P43/TX
P42/SOT1
P41/SCK1
P40/SIN1
(TOP VIEW)
(FPT-48P-M26)
* : MB90387, MB90F387 : X1A, X0A
MB90387S, MB90F387S: P36, P35
6
P17/PPG3
P16/PPG2
P15/PPG1
P14/PPG0
P13/IN3
P12/IN2
P11/IN1
P10/IN0
X1
X0
C
VSS
MB90385 Series
■ PIN DESCRIPTION
Pin No.
Pin name
Circuit
type
1
AVcc

Vcc power input pin for A/D converter.
2
AVR

Power (Vref+) input pin for A/D converter. Use as input for Vcc or lower.
P50 to P57
3 to 10
AN0 to AN7
General-purpose input/output ports.
E
P37
11
ADTG
TIN0
TOT0
D
TIN1
16 to 19
TOT1
P24 to P27
INT4 to INT7
Function as an event output pin for reload timer 0. Valid only when output
setting is “enabled.”
General-purpose input/output ports.
D
P23
15
Function as an event input pin for reload timer 0. Use the pin by setting as
input port.
General-purpose input/output ports.
D
P22
14
Function as an external trigger input pin for A/D converter. Use the pin by
setting as input port.
General-purpose input/output ports.
P21
13
Functions as analog input pin for A/D converter. Valid when analog
input setting is “enabled.”
General-purpose input/output ports.
D
P20
12
Function
Function as an event input pin for reload timer 1. Use the pin by setting as
input port.
General-purpose input/output ports.
D
D
Function as an event output pin for reload timer 1. Valid only when output
setting is “enabled.”
General-purpose input/output ports.
Functions as external interrupt input pin. Use the pin by setting as input port.
20
MD2
F
Input pin for specifying operation mode. Connect directly to Vss.
21
MD1
C
Input pin for specifying operation mode. Connect directly to Vcc.
22
MD0
C
Input pin for specifying operation mode. Connect directly to Vcc.
23
RST
B
External reset input pin.
24
Vcc

Power source (5 V) input pin.
25
Vss

Power source (0 V) input pin.
26
C

Capacitor pin for stabilizing power source. Connect a ceramic capacitor of
approximately 0.1 µF.
27
X0
A
Pin for high-rate oscillation.
28
X1
A
Pin for high-rate oscillation.
P10 to P13
29 to 32
IN0 to IN3
General-purpose input/output ports.
D
Functions as trigger input pins of input capture channels 0 to 3. Use the
pins by setting as input ports.
(Continued)
7
MB90385 Series
(Continued)
Pin No.
Pin name
Circuit
type
P14 to P17
33 to 36
37
PPG0 to PPG3
P40
SIN1
General-purpose input/output ports. High-current output ports.
G
D
P41
38
SCK1
SOT1
D
TX
D
42 to 45
46
47
48
RX
P30 to P33
X0A*
P35*
X1A*
P36*
AVss
D
Serial clock input pin for UART. Valid only when serial clock input/output
setting on UART is “enabled.”
Serial data input pin for UART. Valid only when serial data input/output setting on UART is “enabled.”
Transmission output pin for CAN. Valid only when output setting is
“enabled.”
General-purpose input/output port.
D
Transmission output pin for CAN. Valid only when output setting is
“enabled.”
D
General-purpose input/output ports.
A
A

* : MB90387, MB90F387 : X1A, X0A
MB90387S, MB90F387S: P36, P35
8
Serial data input pin for UART. Use the pin by setting as input port.
General-purpose input/output port.
P44
41
General-purpose input/output port.
General-purpose input/output port.
P43
40
Functions as output pin of PPG timers 01 and 23. Valid when output
setting is “enabled.”
General-purpose input/output port.
P42
39
Function
Pin for low-rate oscillation.
General-purpose input/output port.
Pin for low-rate oscillation.
General-purpose input/output port.
Vss power source input pin for A/D converter.
MB90385 Series
■ I/O CIRCUIT TYPE
Type
Circuit
Remarks
X1
A
Clock input
X1A
X0
X0A
Standby control signal
• Hysteresis input with pull-up
resistor.
• Pull-up resistor, approx.50 kΩ
Vcc
B
• High-rate oscillation feedback
resistor, approx.1 MΩ
• Low-rate oscillation feedback
resistor, approx.10 MΩ
R
R
Hysteresis input
• Hysteresis input
C
R
Hysteresis input
• CMOS hysteresis input
• CMOS level output
• Standby control provided
Vcc
Pch
D
R
Nch
Vss
Digital output
Digital output
Hysteresis input
Standby control
Vcc
Pch
E
R
Nch
Vss
Digital output
•
•
•
•
CMOS hysteresis input
CMOS level output
Shared for analog input pin
Standby control provided
Digital output
Hysteresis input
Standby control
Analog input
(Continued)
9
MB90385 Series
(Continued)
Type
Circuit
Remarks
R
Hysteresis input
F
• Hysteresis input with pull-down
resistor
• Pull-down resistor, approx. 50 kΩ
• FLASH product is not provided with
pull-down resistor.
R
Vss
Vcc
Pch
High-current output
High-current output
G
R
Nch
Vss
Hysteresis input
Standby control
10
• CMOS hysteresis input
• CMOS level output (high-current
output)
• Standby control provided
MB90385 Series
■ HANDLING DEVICES
• Do Not Exceed Maximum Rating (preventing “latch up”)
• On a CMOS IC, latch-up may occur when applying a voltage higher than Vcc or a voltage lower than Vss to
input or output pin, which has no middle or high withstand voltage. Latch-up may also occur when a voltage
exceeding maximum rating is applied across Vcc and Vss.
• Latch-up causes drastic increase of power current, which may lead to destruction of elements by heat. Extreme
caution must be taken not to exceed maximum rating.
• When turning on and off analog power source, take extra care not to apply an analog power voltages (AVcc
and AVR) and analog input voltage that are higher than digital power voltage (Vcc).
• Handling Unused Pins
• Leaving unused input pins open may cause permanent destruction by malfunction or latch-up. Apply pull-up
or pull-down process to the unused pins using resistors of 2 kΩ or higher. Leave unused input pins open under
output status, or process as input pins if they are under input status.
• Using External Clock
• When using an external clock, drive only X0 pin and leave X1 pin open. An example of using an external clock
is shown below.
• Using external clock
X0
Open
X1
MB90385 series
• Notes When Using No Sub Clock
• If an oscillator is not connected to X0A and X1A pin, apply pull-down resistor to X0A pin and leave X1A pin open.
• About Power Supply Pins
• If two or more Vcc and Vss exist, the pins that should be at the same potential are connected to each other
inside the device. For reducing unwanted emissions and preventing malfunction of strobe signals caused by
increase of ground level, however, be sure to connect the Vcc and Vss pins to the power source and the ground
externally.
• Pay attention to connect a power supply to Vcc and Vss of MB90385 series device in a lowest-possible
impedance.
• Near pins of MB90385 series device, connecting a bypass capacitor is recommended at 0.1 µF across Vcc
and Vss.
• Crystal Oscillator Circuit
• Noises around X0 and X1 pins cause malfunctions on a MB90385 series device. Design a print circuit so that
X0 and X1 pins, an crystal oscillator (or a ceramic oscillator), and bypass capacitor to the ground become as
close as possible to each other. Furthermore, avoid wires to X0 and X1 pins crossing each other as much as
possible.
• Print circuit designing that surrounds X0 and X1 pins with grounding wires, which ensures stable operation,
is strongly recommended.
• Caution on Operations during PLL Clock Mode
• If the PLL clock mode is selected, the microcontroller attempt to be working with the self-oscillating circuit even
when there is no external oscillator or external clock input is stopped. Performance of this operation, however,
cannot be guaranteed.
11
MB90385 Series
• Sequence of Turning on Power of A/D Converter and Applying Analog Input
• Be sure to turn on digital power (Vcc) before applying signals to the A/D converter and applying analog input
signals (AN0 to AN7 pins).
• Be sure to turn off the power of A/D converter and analog input before turning off the digital power source.
• Be sure not to apply AVR exceeding AVcc when turning on and off. (No problems occur if analog and digital
power is turned on and off simultaneously.)
• Handling Pins When A/D Converter is Not Used
• If the A/D converter is not used, connect the pins under the following conditions: “AVcc=AVR=Vcc,” and
“AVss=Vss”
• Note on Turning on Power
• For preventing malfunctions on built-in step-down circuit, maintain a minimum of 50 µs of voltage rising time
(between 0.2 V and 2.7V) when turning on the power.
• Stabilization of supply voltage
• A sudden change in the supply voltage may cause the device to malfunction even within the specified VCC
supply voltage operating range. Therefore, the VCC supply voltage should be stabilized.
For reference, the supply voltage should be controlled so that VCC ripple variations (peak-to-peak values) at
commercial frequencies (50 Hz to 60 Hz) fall below 10% of the standard VCC supply voltage and the coefficient
of fluctuation does not exceed 0.1 V/ms at instantaneous power switching.
12
MB90385 Series
■ BLOCK DIAGRAM
X0,X1
RST
X0A,X1A
Clock
control circuit
CPU
F2MC-16LX core
Clock timer
Time-base timer
16-bit
free-run timer
RAM
Input
capture
(4ch)
Prescaler
SOT1
SCK1
SIN1
UART1
Internal data bus
ROM/FLASH
16-bit
PPG timer
(2ch)
CAN
DTP/External
interrupt
IN0 to IN3
PPG0 to PPG3
RX
TX
INT4 to INT7
AVcc
AVss
AN0 to AN7
AVR
8/10-bit A/D
converter (8ch)
16-bit
reload timer
(2ch)
TIN0,TIN1
TOT0,TOT1
ADTG
13
MB90385 Series
■ MEMORY MAP
MB90385 series allows specifying a memory access mode “single chip mode.”
1. Memory allocation of MB90385
MB90385 series model has 24-bit wide internal address bus and up to 24-bit bus of external address bus.
A maximum of 16 Mbyte memory space of external access memory is accessible.
2. Memory map
(with ROM mirroring
function enabled)
000000H
0000C0H
000100H
Address #1
003800H
004000H
Peripheral
RAM area
Register
Extension IO
area
ROM area
(FF bank image)
010000H
FE0000H
ROM area*
FF0000H
FFFFFFH
ROM area
Model
Address #1
MB90V495G
001900 H
MB90F387/S
000900 H
MB90387/S
000900 H
: Internal access memory
: Access disallowed
* : On MB90387/S or MB90F387/S, to read “FE0000H” to “FEFFFFH” is to read out
“FF0000H” to “FFFFFFH”.
Note : When internal ROM is operating, F2MC-16LX allows viewing ROM data image on FF bank at upper-level of
00 bank. This function is called “mirroring ROM,” which allows effective use of C compiler small model.
F2MC-16LX assigns the same low order 16-bit address to FF bank and 00 bank, which allows referencing
table in ROM without specifying “far” using pointer.
For example, when accessing to “00C000H”, ROM data at “FFC000H” is accessed actually. However, because
ROM area of FF bank exceeds 48 Kbytes, viewing all areas is not possible on 00 bank image. Because ROM
data of “FF4000H” to “FFFFFFH” is viewed on “004000H” to “00FFFFH” image, store a ROM data table in area
“FF4000H” to “FFFFFFH.”
14
MB90385 Series
■ I/O MAP
Register
Address abbreviation
Read/
Write
Register
000000H
Resource
Initial value
(Reserved area) *
000001H
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
to
000010H
(Reserved area) *
000011H
DDR1
Port 1 direction data register
R/W
Port 1
00000000B
000012H
DDR2
Port 2 direction data register
R/W
Port 2
00000000B
000013H
DDR3
Port 3 direction data register
R/W
Port 3
000X0000B
000014H
DDR4
Port 4 direction data register
R/W
Port 4
XXX00000B
000015H
DDR5
Port 5 direction data register
R/W
Port 5
00000000B
8/10-bit
A/D converter
11111111B
000016H
to
00001AH
00001BH
(Reserved area) *
ADER
Analog input permission register
00001CH
to
000025H
R/W
(Reserved area) *
000026H
SMR1
Serial mode register 1
R/W
000027H
SCR1
Serial control register 1
R/W, W
000028H
SIDR1/
SODR1
000029H
SSR1
00002AH
00002BH
Serial input data register 1/ Serial
output data register 1
Serial status data register 1
R, W
R, R/W
CDCR1
Communication prescaler control
register 1
R/W
XXXXXXXXB
00001000B
UART1
0XXX0000B
(Reserved area) *
000030H
ENIR
DTP/External interrupt permission
register
R/W
000031H
EIRR
DTP/External interrupt permission
register
R/W
ELVR
Detection level setting register
000033H
00000100B
UART1
(Reserved area) *
00002CH
to
00002FH
000032H
00000000B
00000000B
DTP/External
interrupt
XXXXXXXXB
R/W
00000000B
R/W
00000000B
(Continued)
15
MB90385 Series
Register
Address abbreviation
000034H
000035H
000036H
000037H
ADCS
ADCR
Read/
Write
Register
R/W
A/D control status register
R/W, W
W, R
A/D data register
000038H
to
00003FH
PPG0 operation mode control
register
R/W, W
000041H
PPGC1
PPG1 operation mode control
register
R/W, W
000042H
PPG01
PPG0/1 count clock selection
register
R/W
000043H
PPGC2
PPG2 operation mode control
register
R/W, W
000045H
PPGC3
PPG3 operation mode control
register
R/W, W
000046H
PPG23
PPG2/3 count clock selection
register
R/W
000047H
to
00004FH
000053H
IPCP0
Input capture data register 0
R
IPCP1
Input capture data register 1
R
ICS01
000055H
ICS23
000057H
000058H
Input capture control status register
R/W
TCDT
Timer counter data register
R/W
TCCS
Timer counter control status register
R/W
000059H
00005AH
00005BH
00005CH
00005DH
XXXXXXXXB
00101XXXB
0X000XX1B
8/16-bit
PPG timer 0/1
0X000001B
000000XXB
0X000XX1B
8/16-bit
PPG timer 2/3
0X000001B
000000XXB
(Reserved area) *
000054H
000056H
00000000B
(Reserved area) *
000044H
000052H
8/10-bit
A/D converter
(Reserved area) *
PPGC0
000051H
Initial value
00000000B
R
000040H
000050H
Resource
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
16-bit input/output
timer
00000000B
00000000B
00000000B
00000000B
00000000B
(Reserved area) *
IPCP2
Input capture data register 2
XXXXXXXXB
R
16-bit input/output
timer
IPCP3
Input capture data register 3
R
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
(Continued)
16
MB90385 Series
Register
Address abbreviation
00005EH
to
000065H
000066H
000067H
000068H
000069H
R/W
TMCSR0
R/W
ROMM
ROM mirroring function selection
register
BVALR
Message buffer enabling register
TREQR
Send request register
TCANR
00000000B
XXXX0000B
ROM mirroring
function selection
module
XXXXXXX1B
R/W
CAN controller
00000000B
CAN controller
00000000B
W
CAN controller
00000000B
CAN controller
00000000B
CAN controller
00000000B
CAN controller
00000000B
CAN controller
00000000B
CAN controller
00000000B
(Reserved area) *
TCR
Send completion register
R/W
(Reserved area) *
RCR
Receive completion register
R/W
(Reserved area) *
RRTRR
Receive RTR register
R/W
(Reserved area) *
ROVRR
00008DH
00008EH
W
R/W
Send cancel register
00008BH
00008CH
XXXX0000B
(Reserved area) *
000089H
00008AH
16-bit reload timer 1
00000000B
(Reserved area) *
000087H
000088H
16-bit reload timer 0
(Reserved area) *
000085H
000086H
Initial value
(Reserved area) *
000083H
000084H
R/W
TMCSR1
000081H
000082H
R/W
Timer control status register
000070H
to
00007FH
000080H
Resource
(Reserved area) *
00006AH
to
00006EH
00006FH
Read/
Write
Register
Receive overrun register
R/W
(Reserved area) *
RIER
00008FH
to
00009DH
Receive completion interrupt
permission register
R/W
(Reserved area) *
00009EH
PACSR
Address detection control register
R/W
Address matching
detection function
00000000B
00009FH
DIRR
Delay interrupt request generation/
release register
R/W
Delay interrupt
generation module
XXXXXXX0B
(Continued)
17
MB90385 Series
Register
Address abbreviation
Register
Read/
Write
Resource
Initial value
0000A0H
LPMCR
Lower power consumption mode
control register
W,R/W
Lower power
consumption mode
00011000B
0000A1H
CKSCR
Clock selection register
R,R/W
Clock
11111100B
0000A2H
to
0000A7H
(Reserved area) *
0000A8H
WDTC
Watchdog timer control register
R,W
Watchdog timer
XXXXX111B
0000A9H
TBTC
Time-base timer control register
R/W,W
Time-base timer
1XX00100B
0000AAH
WTC
Clock timer control register
R,R/W
Clock timer
1X001000B
512k-bit flash
memory
000X0000B
0000ABH
to
0000ADH
0000AEH
(Reserved area) *
FMCS
Flash memory control status
register
0000AFH
R,W,R/W
(Reserved area) *
0000B0H
ICR00
Interrupt control register 00
00000111B
0000B1H
ICR01
Interrupt control register 01
00000111B
0000B2H
ICR02
Interrupt control register 02
00000111B
0000B3H
ICR03
Interrupt control register 03
00000111B
0000B4H
ICR04
Interrupt control register 04
00000111B
0000B5H
ICR05
Interrupt control register 05
00000111B
0000B6H
ICR06
Interrupt control register 06
00000111B
0000B7H
ICR07
Interrupt control register 07
0000B8H
ICR08
Interrupt control register 08
0000B9H
ICR09
Interrupt control register 09
00000111B
0000BAH
ICR10
Interrupt control register 10
00000111B
0000BBH
ICR11
Interrupt control register 11
00000111B
0000BCH
ICR12
Interrupt control register 12
00000111B
0000BDH
ICR13
Interrupt control register 13
00000111B
0000BEH
ICR14
Interrupt control register 14
00000111B
0000BFH
ICR15
Interrupt control register 15
00000111B
0000C0H
to
0000FFH
R/W
Interrupt controller
00000111B
00000111B
(Reserved area) *
(Continued)
18
MB90385 Series
Register
Address abbreviation
PADR0
Detection address setting register 0
(middle-order)
001FF2H
Detection address setting register 0
(high-order)
001FF3H
Detection address setting register 1
(low-order)
001FF4H
PADR1
003901H
003902H
003903H
Detection address setting register 1
(middle-order)
XXXXXXXXB
R/W
Address matching
detection function
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
R/W
XXXXXXXXB
TMR0/
TMRLR0
16-bit timer register 0/16-bit reload
register
R,W
16-bit reload timer 0
TMR1/
TMRLR1
16-bit timer register 1/16-bit reload
register
R,W
16-bit reload timer 1
003904H
to
00390FH
Initial value
XXXXXXXXB
Detection address setting register 1
(high-order)
001FF5H
003900H
Resource
Detection address setting register 0
(low-order)
001FF0H
001FF1H
Read/
Write
Register
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
XXXXXXXXB
(Reserved area) *
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
8/16-bit PPG timer
003918H
to
00392FH
(Reserved area) *
003930H
to
003BFFH
(Reserved area) *
003C00H
to
003C0FH
RAM (General-purpose RAM)
XXXXXXXXB
XXXXXXXXB
(Continued)
19
MB90385 Series
Register
Address abbreviation
Register
Read/
Write
Resource
Initial value
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
CAN controller
003C28H
to
003C2BH
IDR6
ID register 6
R/W
XXXXXXXXB
to
XXXXXXXXB
003C2CH
to
003C2FH
IDR7
ID register 7
R/W
XXXXXXXXB
to
XXXXXXXXB
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
(Continued)
20
MB90385 Series
Read/
Write
Address
Register
abbreviation
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
XXXXXXXXB
to
XXXXXXXXB
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
003C60H
to
003C67H
DTR4
Data register 4
R/W
XXXXXXXXB
to
XXXXXXXXB
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
003C80H
to
003CFFH
CAN controller
Initial value
XXXXXXXXB
to
XXXXXXXXB
(Reserved area) *
003D00H
003D01H
CSR
Control status register
003D02H
LEIR
Last event display register
003D03H
R/W, R
CAN controller
R/W
0XXXX001B
00XXX000B
000XX000B
(Reserved area) *
003D04H
003D05H
RTEC
003D06H
003D07H
BTR
Bit timing register
R/W
003D08H
IDER
IDE register
R/W
Send/receive error counter
003D09H
003D0AH
Resource
00000000B
00000000B
R
CAN controller
11111111B
X1111111B
XXXXXXXXB
(Reserved area) *
TRTRR
Send RTR register
R/W
CAN controller
00000000B
(Continued)
21
MB90385 Series
(Continued)
Register
Address abbreviation
003D0BH
003D0CH
RFWTR
Remote frame receive wait register
Initial value
R/W
CAN controller
XXXXXXXXB
CAN controller
00000000B
CAN controller
XXXXXXXXB
XXXXXXXXB
(Reserved area) *
TIER
Send completion interrupt
permission register
003D0FH
003D10H
003D11H
Resource
(Reserved area) *
003D0DH
003D0EH
Read/
Write
Register
R/W
(Reserved area) *
AMSR
Acceptance mask selection register
003D12H
003D13H
R/W
(Reserved area) *
003D14H
to
003D17H
AMR0
003D18H
to
003D1BH
AMR1
Acceptance mask register 0
R/W
CAN controller
Acceptance mask register 1
R/W
003D1CH
to
003DFFH
(Reserved area) *
003E00H
to
003EFFH
(Reserved area) *
003FF0H
to
003FFFH
(Reserved area) *
XXXXXXXXB
to
XXXXXXXXB
XXXXXXXXB
to
XXXXXXXXB
Initial values :
0 : Initial value of this bit is “0.”
1 : Initial value of this bit is “1.”
X : Initial value of this bit is undefined.
* : “Reserved area” should not be written anything. Result of reading from “Reserved area” is undefined.
22
MB90385 Series
■ INTERRUPT SOURCES, INTERRUPT VECTORS, AND INTERRUPT CONTROL REGISTERS
Interrupt source
EI2OS
readiness
Interrupt vector
Number
Interrupt control register
Address
ICR
Address
Priority*3
Reset
×
#08
08H
FFFFDCH


High
INT 9 instruction
×
#09
09H
FFFFD8H


↑
Exceptional treatment
×
#10
0AH
FFFFD4H


CAN controller reception
completed (RX)
×
#11
0BH
FFFFD0H
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
CAN controller transmission
completed (TX) / Node status
transition (NS)
×
#12
0CH
FFFFCCH
Reserved
×
#13
0DH
FFFFC8H
Reserved
×
#14
0EH
FFFFC4H
CAN wakeup
∆
#15
0FH
FFFFC0H
Time-base timer
×
#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
Reserved
×
#20
14H
FFFFACH
Reserved
×
#21
15H
FFFFA8H
PPG timer ch0, ch1 underflow
×
#22
16H
FFFFA4H
Input capture 0-input
∆
#23
17H
FFFFA0H
External interrupt (INT4/INT5)
∆
#24
18H
FFFF9CH
Input capture 1-input
∆
#25
19H
FFFF98H
PPG timer ch2, ch3 underflow
×
#26
1AH
FFFF94H
External interrupt (INT6/INT7)
∆
#27
1BH
FFFF90H
Clock timer
∆
#28
1CH
FFFF8CH
Reserved
×
#29
1DH
FFFF88H
Input capture 2-input
Input capture 3-input
×
#30
1EH
FFFF84H
Reserved
×
#31
1FH
FFFF80H
Reserved
×
#32
20H
FFFF7CH
Reserved
×
#33
21H
FFFF78H
Reserved
×
#34
22H
FFFF74H
Reserved
×
#35
23H
FFFF70H
#36
24H
FFFF6CH
16-bit reload timer 1
↓
Low
(Continued)
23
MB90385 Series
(Continued)
Interrupt source
EI2OS
readiness
UART1 reception completed
Interrupt vector
Number
Address
#37
25H
FFFF68H
UART1 transmission completed
∆
#38
26H
FFFF64H
Reserved
×
#39
27H
FFFF60H
Reserved
×
#40
28H
FFFF5CH
Flash memory
×
#41
29H
FFFF58H
Delay interrupt generation
module
×
#42
2AH
FFFF54H
Interrupt control register
ICR
Address
ICR13
0000BDH*1
ICR14
0000BEH*1
ICR15
0000BFH*1
Priority*3
High
↑
↓
Low
: Available
× : Unavailable
: Available El2OS function is provided.
∆ : Available when a cause of interrupt sharing a same ICR is not used.
*1 : • Peripheral functions sharing an ICR register have the same interrupt level.
• If peripheral functions share an ICR register, only one function is available when using expanded intelligent
I/O service.
• If peripheral functions share an ICR register, a function using expanded intelligent I/O service does not allow
interrupt by another function.
*2 : Only 16-bit reload timer is ready for EI2OS. Because PPG is not ready for EI2OS, disable PPG interrupt when
using EI2OS with 16-bit reload timer.
*3 : Priority when two or more interrupts of a same level occur simultaneously.
24
MB90385 Series
■ PERIPHERAL RESOURCES
1. I/O Ports
The I/O ports are used as general-purpose input/output ports (parallel I/O ports). The MB60385 series model
is provided with 5 ports (34 inputs). The ports function as input/output pins for peripheral functions also.
• I/O port functions
An I/O port, using port data resister (PDR), outputs the output data to I/O pin and input a signal input to I/O port.
The port direction register (DDR) specifies direction of input/output of I/O pins on a bit-by-bit basis.
The following summarizes functions of the ports and sharing peripheral functions :
• Port 1 : General-purpose input/output port, used also for PPG timer output and input capture inputs.
• Port 2 : General-purpose input/output port, used also for reload timer input/output and external interrupt input.
• Port 3 : General-purpose input/output port, used also for A/D converter activation trigger pin.
• Port 4 : General-purpose input/output port, used also for UART input/output and CAN controller send/receive
pin.
• Port 5 : General-purpose input/output port, used also analog input pin.
• Port 1 pins block diagram (single-chip mode)
Peripheral
function input
Peripheral
function output
Peripheral function
output permission
Port data register (PDR)
PDR read
Internal data bus
Pch
Output latch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL=1)
DDR read
Standby control : Control among Stop mode (SPL=1), Time-base timer mode (SPL=1), and clock mode
(SPL=1).
• Port 1 registers (single-chip mode)
• Port 1 registers include port 1 data register (PDR1) and port 1 direction register (DDR1).
• The bits configuring the register correspond to port 1 pins on a one-to-one basis.
Relation between port 1 registers and pins
Port name
Bits of register and corresponding pins
Port 1
PDR1, DDR1
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
Corresponding pins
P17
P16
P15
P14
P13
P12
P11
P10
25
MB90385 Series
• Port 2 pins block diagram (general-purpose input/output port)
Peripheral
function input
Peripheral
function output
Peripheral function
output permission
Port data register (PDR)
PDR read
Internal data bus
Output latch
Pch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL=1)
DDR read
Standby control : Control among Stop mode (SPL=1), Time-base timer mode (SPL=1), and clock mode
(SPL=1).
• Port 2 registers
• Port 2 registers include port 2 data register (PDR2) and port 2 direction register (DDR2).
• The bits configuring the register correspond to port 2 pins on a one-to-one basis.
Relation between port 2 registers and pins
Port name
Bits of register and corresponding pins
Port 2
26
PDR2,DDR2
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
Corresponding pins
P27
P26
P25
P24
P23
P22
P21
P20
MB90385 Series
• Port 3 pins block diagram (general-purpose input/output port)
Peripheral
function input
Peripheral
function output
Peripheral function
output permission
Port data register (PDR)
PDR read
Internal data bus
Pch
Output latch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL=1)
DDR read
Standby control : Control among Stop mode (SPL=1), Time-base timer mode (SPL=1), and clock mode
(SPL=1).
• Port 3 registers
• Port 3 registers include port 3 data register (PDR3) and port 3 direction register (DDR3).
• The bits configuring the register correspond to port 3 pins on a one-to-one basis.
Relation between port 3 registers and pins
Port name
Bits of register and corresponding pins
Port 3
PDR3, DDR3
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
Corresponding pins
P37
P36*
P35*

P33
P32
P31
P30
* : P35 and P36 do not exist on MB90387and MB90F387.
27
MB90385 Series
• Port 4 pins block diagram
Peripheral
function input
Peripheral
function output
Peripheral function
output permission
Port data register (PDR)
PDR read
Internal data bus
Pch
Output latch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL=1)
DDR read
Standby control : Control among Stop mode (SPL=1), Time-base timer mode (SPL=1), and clock mode
(SPL=1).
• Port 4 registers
• Port 4 registers include port 4 data register (PDR4) and port 4 direction register (DDR4).
• The bits configuring the register correspond to port 4 pins on a one-to-one basis.
Relation between port 4 registers and pins
Port name
Bits of register and corresponding pins
Port 4
28
PDR4, DDR4



bit4
bit3
bit2
bit1
bit0
Corresponding pins



P44
P43
P42
P41
P40
MB90385 Series
• Port 5 pins block diagram
Analog input
ADER
Port data register (PDR)
PDR read
Internal data bus
Output latch
Pch
PDR write
Pin
Port direction register (DDR)
Direction
latch
Nch
DDR write
Standby control (SPL=1)
DDR read
Standby control: Control among Stop mode (SPL=1), Time-base timer mode (SPL=1), and clock mode
(SPL=1).
• Port 5 registers
• Port 5 registers include port 5 data register (PDR5), port 5 direction register (DDR5), and analog input permission register (ADER).
• Analog input permission register (ADER) allows or disallows input of analog signal to the analog input pin.
• The bits configuring the register correspond to port 5 pins on a one-to-one basis.
Relation between port 5 registers and pins
Port name
Bits of register and corresponding pins
PDR5, DDR5
Port 5
ADER
Corresponding pins
bit7
bit6
bit5
bit4
bit3
bit2
bit1
bit0
ADE7
ADE6
ADE5
ADE4
ADE3
ADE2
ADE1
ADE0
P57
P56
P55
P54
P53
P52
P51
P50
29
MB90385 Series
2. Time-Base Timer
The time-base time is an 18-bit free-run counter (time-base timer counter) that counts up in synchronization with
the main clock (dividing main oscillation clock by 2).
• Four choices of interval time are selectable, and generation of interrupt request is allowed for each interval time.
• Provides operation clock signal to oscillation stabilizing wait timer and peripheral functions.
• Interval timer function
• When the counter of time-base timer reaches an interval time specified by interval time selection bit
(TBTC:TBC1, TBC0), an overflow (carrying-over) occurs (TBTC: TBOF=1) and interrupt request is generated.
• If an interrupt by overflow is permitted (TBTC: TBIE=1), an interrupt is generated when overflow occurs (TBTC:
TBOF=1).
• The following four interval time settings are selectable :
Interval time of time-base timer
Count clock
Interval time
212/HCLK (Approx. 1.0 ms)
2/HCLK (0.5 µs)
214/HCLK (Approx. 4.1 ms)
216/HCLK (Approx. 16.4 ms)
219/HCLK (Approx. 131.1 ms)
HCLK: Oscillation clock
Values in parentheses “( )” are those under operation of 4-MHz oscillation clock.
30
MB90385 Series
• Time-base timer block diagram
To watchdog
timer
To PPG timer
Time-base timer counter
21/HCLK
21
22
23 · · ·
···
28
29
210
211
212
213
OF
OF
214
215
216
217
218
OF
OF
Power-on reset
Stop mode
CKSCR : MCS = 1
CKSCR : SCS = 0
0
1
1
To clock controller
oscillation stabilizing
wait time selector
Counterclear circuit
Interval timer
selector
2
TBOF clear TBOF set
Time-base timer control register
(TBTC)
Reserved
TBIE TBOF TBR TBC1 TBC0
Time-base timer interrupt signal
OF : Overflow
HCLK : Oscillation clock
*1 : Switch machine clock from main clock to PLL clock.
*2 : Switch machine clock from sub clock to main clock.
Actual interrupt request number of time-base timer is as follows:
Interrupt request number: #16 (10H)
31
MB90385 Series
3. Watchdog Timer
The watchdog timer is a 2-bit counter that uses time-base timer or clock timer as count clock. If the counter is
not cleared within an interval time, CPU is reset.
•Watchdog timer functions
• The watchdog timer is a timer counter that prevents runaway of a program. Once a watchdog timer is activated,
the counter of watchdog timer must always be cleared within a specified time of interval. If specified interval
time elapses without clearing the counter of a watchdog timer, CPU resetting occurs. This is the function of a
watchdog timer.
• The interval time of a watchdog timer is determined by a clock cycle, which is input as a count clock. Watchdog
resetting occurs between a minimum time and a maximum time specified.
• The output target of a clock source is specified by the watchdog clock selection bit (WTC: WDCS) in the clock
timer control register.
• Interval time of a watchdog timer is specified by the time-base timer output selection bit/clock timer output
selection bit (WDTC: WT1, WT0) in the watchdog timer control register.
Interval timer of watchdog timer
Min
Max
Clock cycle
Min
Max
Clock cycle
Approx. 4.61 ms
2 ±2
/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
14
Approx. 3.58 ms
Approx.
458.75 ms
Approx.
589.82 ms
11
221±218
/HCLK
Approx.
14.336 s
Approx.
18.432 s
217±214
/SCLK
HCLK: Oscillation clock ( 4 MHz) , CSCLK: Sub clock (8.192 kHz)
Notes: • If the time-base timer is cleared when watchdog timer count clock is used as time base timer output
(carry-over signal), watchdog reset time may become longer.
• When using the sub clock as machine clock, be sure to specify watchdog timer clock source selection bit
(WDCS) in clock timer control register (WTC) at “0,” selecting output of clock timer.
32
MB90385 Series
• Watchdog timer block diagram
Clock timer control register (WTC)
Watchdog timer control register(WDTC)
WRST ERST SRST WTE WT1 WT0
PONR
Watchdog timer
WDCS
2
Activate
Reset occurs
Shift to sleep mode
Shift to time-base
timer mode
Shift to clock mode
Shift to stop mode
Counter
clear control
circuit
Watchdog
reset
generation
circuit
2-bit
counter
Count clock
selector
Internal reset
generation
circuit
Clear
4
4
Time-base timer counter
Main clock
(dividing HCLK by 2)
21
22
28
29
210
25
26
27
211 212
213
214
215
216
217
218
28
210
211
212 213
214
215
Clock counter
Sub clock
SCLK
21
22
29
HCLK: Oscillation clock
SCLK: Sub clock
33
MB90385 Series
4. 16-bit Input/Output Timer
The 16-bit input/output timer is a compound module composed of 16-bit free-run timer, (1 unit) and input capture
(2 units, 4 input pins). The timer, using the 16-bit free-run timer as a basis, enables measurement of clock cycle
of an input signal and its pulse width.
• Configuration of 16-bit input/output timer
The 16-bit input/output timer is composed of the following modules:
• 16-bit free-run timer (1 unit)
• Input capture (2 units, 2 input pins per unit)
• Functions of 16-bit input/output timer
(1) Functions of 16-bit free-run timer
The 16-bit free-run timer is composed of 16-bit up counter, timer counter control status register, and prescaler.
The 16-bit up counter increments in synchronization with dividing ratio of machine clock.
• Count clock is set among four types of machine clock dividing rates.
• Generation of interrupt is allowed by counter value overflow.
• Activation of expanded intelligent I/O service (EI2OS) is allowed by interrupt generation.
• Counter value of 16-bit free-run timer is cleared to “0000H” by either resetting or software-clearing with timer
count clear bit (TCCS: CLR).
• Counter value of 16-bit free-run timer is output to input capture, which is available as base time for capture
operation.
(2) Functions of input capture
The input capture, upon detecting an edge of a signal input to the input pin from external device, stores a counter
value of 16-bit free-run timer at the time of detection into the input capture data register. The function includes
the input capture data registers corresponding to four input pins, input capture control status register, and edge
detection circuit.
• Rising edge, falling edge, and both edges are selectable for detection.
• Generating interrupt on CPU is allowed by detecting an edge of input signal.
• Expanded intelligent I/O service (EI2OS) is activated by interrupt generation.
• The four input capture input pins and input capture data registers allows monitoring of a maximum of four events.
34
MB90385 Series
• 16-bit input/output timer block diagram
Internal data bus
Input capture
Specialpurpose bus
16-bit free-run
timer
• 16-bit free-run timer
Counter value of 16-bit free-run timer is used as reference time (base time) of input capture.
• Input capture
Input capture detects rising edge, falling edge or both edges and retains a counter value of 16-bit free-run timer.
Detection of edge on input signal is allowed to generate interrupt.
• 16-bit free-run timer block diagram
Timer counter data register
(TCDT)
Output counter value
to input capture
16-bit free-run timer
OF
CLK
STOP
CLR
Internal data bus
Prescaler
2
Timer counter
control status register
(TCCS)
IVF
IVFE STOP
φ : Machine clock
OF : Overflow
Reserved
CLR CLK2 CLK1 CLK0
Free-run timer
interrupt request
35
MB90385 Series
• Detailed pin assignment on block diagram
The 16-bit input/output timer includes a 16-bit free-run timer. Interrupt request number of the 16-bit free-run
timer is as follows:
Interrupt request number: 19 (13H)
• Prescaler
The prescaler divides a machine clock and provides a counter clock to the 16-bit up counter. Dividing ratio of
the machine clock is specified by timer counter control status register (TCCS) among four values.
• Timer counter data register (TCDT)
The timer counter data register is a 16-bit up counter. A current counter value of the 16-bit free-run timer is read.
Writing a value during halt of the counter allows setting an arbitrary counter value.
36
MB90385 Series
•Input capture block diagram
16-bit free-run timer
Edge detection
circuit
IN3
Input capture data register 3 (IPCP3)
Pin
IN2
Input capture data register 2 (IPCP2)
Pin
2
2
Input capture control
status register
(ICS23)
ICP1 ICP0 ICE1 ICE0 EG11 EG10 EG01 EG00
Internal data bus
Input capture
interrupt request
Input capture control
ICP1 ICP0 ICE1 ICE0 EG11 EG10 EG01 EG00
status register
(ICS01)
2
2
IN1
Pin
Input capture data register 1 (IPCP1)
IN0
Input capture data register 0 (IPCP0)
Pin
Edge detection
circuit
37
MB90385 Series
5. 16-bit Reload Timer
The 16-bit reload timer has the following functions:
• Count clock is selectable among 3 internal clocks and external event clock.
• Activation trigger is selectable between software trigger and external trigger.
• Generation of CPU interrupt is allowed upon occurrence of underflow on 16-bit timer register. Available as an
interval timer using the interrupt function.
• When underflow of 16-bit timer register (TMR) occurs, one of two reload modes is selectable between oneshot mode that halts counting operation of TMR, and reload mode that reloads 16-bit reload register value to
TMR, continuing TMR counting operation.
• The 16-bit reload timer is ready for expanded intelligent I/O service (EI2OS).
• MB90385 series device has 2 channels of built-in 16-bit reload timer.
• Operation mode of 16-bit reload timer
Count clock
Activation trigger
Operation upon 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
• The 16-bit reload timer is set to internal clock mode, by setting count clock selection bit (TMCSR: CSL1, CSL0)
to “00B”, “01B”, “10B”.
• In the internal clock mode, the counter decrements in synchronization with the internal clock.
• Three types of count clock cycles are selectable by count clock selection bit (TMCSR: CSL1, CSL0) in timer
control status register.
• Edge detection of software trigger or external trigger is specified as an activation trigger.
38
MB90385 Series
• 16-bit reload timer block diagram
Internal data bus
TMRLR
16-bit reload register
Reload signal
TMR
Reload
control
circuit
16-bit timer register UF
Count clock generation
circuit
Machine
clock
φ
Prescaler 3
CLK
Gate
input
Valid
clock
decision
circuit
Clear
Pin
TIN
Internal
clock
Input
control
circuit
CLK
Clock
selector
External clock
3
2
Select
signal
Select function
Wait signal
Output to internal
peripheral
functions
Output control
circuit
Output signal
generation
circuit
Pin
TOT
EN
Operation control
circuit generation
circuit
CSL1 CSL0 MOD2 MOD1 MOD0 OUTE OUTL RELD INTE UF CNTE TRG
Timer control status register (TMCSR)
Interrupt request
output
39
MB90385 Series
6. Clock Timer Outline
The clock timer is a 15-bit free-run counter that increments in synchronization with sub clock.
• Interval time is selectable among 7 choices, and generation of interrupt request is allowed for each interval.
• Provides operation clock to the subclock oscillation stabilizing wait timer and watchdog timer.
• Always uses subclock as a count clock regardless of settings of clock selection register (CKSCR).
• Interval timer function
• In the clock timer, a bit corresponding to the interval time overflows (carry-over) when an interval time, which
is specified by interval time selection bit, is reached. Then overflow flag bit is set (WTC: WTOF=1).
• If an interrupt by overflow is permitted (WTC: WTIE=1), an interrupt request is generated upon setting an
overflow flag bit.
• Interval time of clock timer is selectable among the following seven choices :
• Interval time of clock timer
Sub clock cycle
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)
SCLK: Sub clock frequency
Values in parentheses “( )” are calculation when operating with 8.192 kHz clock.
40
MB90385 Series
• Clock timer block diagram
To watchdog
timer
Clock timer counter
SCLK
21
22
23
24
25
26
27
28
29
210
211
212
213
214
215
OF OF OF
OF
Power-on reset
Shift to hardware standby
Shift to stop mode
OF
Counter
clear
circuit
Interval timer
selector
OF
OF
OF
To sub clock oscillation
stabilizing wait time
Clock time interrupt
OF : Overflow
SCLK : Sub clock
WDCS SCE WTIE WTOF WTR WTC2 WTC1 WTC0
Clock timer control register (WTC)
Actual interrupt request number of clock timer is as follows :
Interrupt request number : #28 (1CH)
• Clock timer counter
A 15-bit up counter that uses sub clock (SCLK) as a count clock.
• Counter clear circuit
A circuit that clears the clock timer counter.
41
MB90385 Series
7. 8/16-bit PPG Timer Outline
The 8/16-bit PPG timer is a 2-channel reload timer module (PPG0 and PPG1) that allows outputting pulses of
arbitrary cycle and duty cycle. Combination of the two channels allows selection among the following operations:
• 8-bit PPG output 2-channel independent operation mode
• 16-bit PPG output operation mode
• 8-bit and 8-bit PPG output operation mode
MB90385 series device has two 8/16-bit built-in PPG timers. This section describes functions of PPG0/1. PPG2/
3 have the same functions as those of PPG0/1.
• Functions of 8/-16-bit PPG timer
The 8/-16-bit PPG timer is composed of four 8-bit reload register (PRLH0/PRLL0, PRLH1/PRLL1) and two PPG
down counters (PCNT0, PCNT1).
• Widths of “H” and “L” in output pulse are specifiable independently. Cycle and duty factor of output pulse is
specifiable arbitrarily.
• Count clock is selectable among 6 internal clocks.
• The timer is usable as an interval timer, by generating interrupt requests for each interval.
• The time is usable as a D/A converter, with an external circuit.
42
MB90385 Series
• 8/16-bit PPG timer 0 block diagram
“H” level side data bus
“L” level side data bus
PPG0 reload
register
PPLH0
(“H” level side)
PPG0 operation mode control
register (PPGC0)
PPLL0
(“L” level side)
PEN0
Reserved
PE0 PIE0 PUF0
PPG0 temporary
buffer 0(PRLBH0)
Interrupt
request output*
R
S
Count start
value
Reload
PPG0 down counter
(PCNT0)
2
Select
signal
Reload register
L/H selector
Q
Clear
Pulse selector
Operation mode
control signal
PPG1 underflow
PPG0 underflow
(To PPG1)
Underflow
CLK
Reversed
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)
−
: Undefined
Reserved : Reserved bit
HCLK
: Oscillation clock frequency
φ
: Machine clock frequency
*
: Interrupt output of 8/16-bit PPG timer 0 is incorporated into one by the OR circuit against
interrupt output of 8/16-bit PPG timer 1.
43
MB90385 Series
• 8/16-bit PPG timer 1 block diagram
“H” level side data bus
“L” level side data bus
PPG1 reload
register
PPG1 operation mode control
register (PPGC1)
PRLL1
PRLH1
Operation (“H” level side) (“L” level side)
mode
control
signal
RePE1 PIE1 PUF1 MD1 MD0 served
PEN1
2
PPG1 temporary
buffer 0(PRLBH1)
R
S
Reload selector
L/H selector
Count start
value
Q
Select signal
Reload
PPG1 down
counter (PCNT1)
PPG1 underflow
(To PPG0)
Interrupt
request output*
Clear
Underflow
PPG1
Re- output latch
versed
CLK
PPG output control circuit
Pin
PPG1
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)
Count clock
selector
3
Select signal
PCS2 PCS1 PCS0 PCM2 PCM1 PCM0
PPG0/1 count clock selection register (PPG01)
−
: Undefined
Reserved : Reserved bit
HCLK
: Oscillation clock frequency
φ
: Machine clock frequency
*
: Interrupt output of 8/16-bit PPG timer 1 is incorporated into one by the OR circuit against
interrupt output of 8/16-bit PPG timer 0.
44
MB90385 Series
8. Delay Interrupt Generation Module Outline
The delay interrupt generation module is a module that generates interrupts for switching tasks. Generation of
a hardware interrupt request is performed by software.
• Delay interrupt generation module outline
Using the delay interrupt generation module, hardware interrupt request is generated and released by software.
Delay interrupt generation module outline
Function and control
Cause of interrupt
Set “1” in R0 bit of delay interrupt request generation/release register (DIRR: R0=1),
generating an interrupt request.
Set “0” in R0 bit of delay interrupt request generation/release register (DIRR: R0=0),
releasing an interrupt request.
Interrupt number
#42 (2AH)
Interrupt control
No setting of permission register is provided.
Interrupt flag
Retained in DIRR: R0 bit
2
EI OS
Not ready for expanded intelligent I/O service.
• Delay interrupt generation module block diagram
Internal data bus
R0
Delay interrupt request generation/release
register (DIRR)
S Interrupt request
R Latch
Interrupt
request signal
− : Not defined
• Interrupt request latch
A latch that retains settings on delay interrupt request generation/release register (generation or release of delay
interrupt request).
• Delay interrupt request generation/release register (DIRR)
Generates or releases delay interrupt request.
• Interrupt number
An interrupt number used in delay interrupt generation module is as follows:
Interrupt number: #42 (2AH)
45
MB90385 Series
9. DTP/External Interrupt and CAN Wakeup Outline
DTP/external interrupt transfers an interrupt request generated by an external peripheral device or a data transmission request to CPU, generating external interrupt request and activating expanded intelligent I/O service.
Input RX of CAN controller is used as external interrupt input.
• DTP/external interrupt and CAN wakeup function
An interrupt request input from external peripheral device to external input pins (INT7 to INT4) and RX pin, just
as interrupt request of peripheral device, generates an interrupt request. The interrupt request generates an
external interrupt and activates expanded intelligent I/O service (EI2OS).
If the expanded intelligent I/O service (EI2OS) has been disabled by interrupt control register (ICR: ISE=0),
external interrupt function is enabled and branches to interrupt processing.
If the EI2OS has been enabled, (ICR: ISE=1), DTP function is enabled and automatic data transmission is
performed by EI2OS. After performing specified number of data transmission processes, the process branches
to interrupt processing.
DTP/external interrupt and CAN wakeup outline
External interrupt
Input pin
DTP function
5 pins (RX, and INT4 to INT7)
Specify for each pin with detection level setting register (ELVR).
Interrupt cause
Input of “H” level/“L” level/rising edge/falling
Input of “H” level/ “L” level
edge.
Interrupt number
#15 (0FH) , #24 (18H) , #27 (1BH)
Interrupt control
Enabling or disabling output of interrupt request, using DTP/external interrupt permission
register (ENIR).
Interrupt flag
Retaining interrupt cause with DTP/external interrupt cause register (EIRR).
Process selection
Disable EI2OS (ICR: ISE=0)
Enable EI2OS (ICR: ISE=1)
Branch to external interrupt process
After automatic data transmission by EI2OS for
specified number of times, branch to interrupt
process.
Process
46
MB90385 Series
• DTP/External interrupt/CAN wakeup block diagram
Detection level setting register (ELVR)
LB7 LA7 LB6 LA6 LB5 LA5 LB4 LA4
Pin
Re- Re- Re- Re- Re- Reserved served served served served served
LB0 LA0
Level/edge
selector
INT7
Pin
Level/edge
selector
INT6
Internal data bus
Pin
Level/edge
selector
INT5
Pin
Level/edge
selector
Pin
INT4
Level/edge
selector
RX
DTP/external interrupt input
detection circuit
Re-
Re-
Re-
ER7 ER6 ER5 ER4 served served served ER0
Interrupt
request signal
DTP/external interrupt
cause register (EIRR)
Interrupt
request signal
Re- Re- Re- EN0
EN7 EN6 EN5 EN4 served
served served
DTP/external interrupt
permission register (ENIR)
47
MB90385 Series
10. 8/10-bit A/D Converter
The 8/10-bit A/D converter converts an analog input voltage into 8-bit or 10/bit digital value, using the RC-type
successive approximation conversion method.
• Input signal is selected among 8 channels of analog input pins.
• Activation trigger is selected among software trigger, internal timer output, and external trigger.
• Functions of 8/10-bit A/D converter
The 8/10-bit A/D converter converts an analog voltage (input voltage) input to analog input pin into an 8-bit or
10-bit digital value (A/D conversion).
The 8/10-bit A/D converter has the following functions:
• A/D conversion takes a minimum of 6.12 µs* for 1 channel, including sampling time. (A/D conversion)
• Sampling of one channel takes a minimum of 2.0 µs*.
• RC-type successive approximation conversion method, with sample & hold circuit is used for conversion.
• Resolution of either 8 bits or 10 bits is specifiable.
• A maximum of 8 channels of analog input pins are allowed for use.
• Generation of interrupt request is allowed, by storing A/D conversion result in A/D data register.
• Activation of EI2OS is allowed upon occurrence of an interrupt request. With use of EI2OS, data loss is avoided
even if A/D conversion is performed successively.
• An activation trigger is selectable among software trigger, internal timer output, and external trigger (fall edge).
*: When operating with 16-MHz machine clock
• 8/10-bit A/D converter conversion mode
Conversion mode
48
Description
Singular conversion
mode
The A/D conversion is performed form a start channel to an end channel sequentially.
Upon completion of A/D conversion on an end channel, A/D conversion function stops.
Sequential conversion
mode
The A/D conversion is performed form a start channel to an end channel sequentially.
Upon completion of A/D conversion on an end channel, A/D conversion function resumes from the start channel.
Pausing conversion
mode
The A/D conversion is performed by pausing at each channel. Upon completion of A/D
conversion on an end channel, A/D conversion and pause functions resume from the
start channel.
MB90385 Series
• 8/10-bit A/D converter block diagram
A/D control
status register
(ADCS)
Interrupt request output
BUSY INT INTE PAUS STS1 STS0 STRT
Reserved
MD1 MD0 ANS2 ANS1 ANS0 ANE2 ANE1 ANE0
2
ADTG
TO
2
Activation
selector
Decoder
Sample&
hold circuit
Internal data bus
AN7
AN6
AN5
AN4
AN3
AN2
AN1
AN0
6
Comparator
Control circuit
Analog
channel
selector
AVR
AVcc
AVss
D/A converter
2
2
A/D data
register
(ADCR)
S10 ST1 ST0 CT1 CT0
TO
:
−
:
Reserved :
φ
:
D9 D8 D7 D6 D5 D4 D3 D2 D1 D0
Internal timer output
Not defined
Be sure to set to “0”
Machine clock
49
MB90385 Series
11. UART Outline
UART is a general-purpose serial data communication interface for synchronous and asynchronous communication using external devices.
• Provided with bi-directional communication function for both clock-synchronous and clock-asynchronous
modes.
• Provided with master/slave communication function (multi-processor mode). (Only master side is available.)
• Interrupt request is generated upon completion of reception, completion of transmission and detection of
reception error.
• Ready for expanded intelligent service, EI2OS.
UART functions
Description
Data buffer
Full-duplex double buffer
Clock synchronous (No start/stop bit, no parity bit)
Clock asynchronous (start-stop synchronous)
Transmission mode
Built-in special-purpose baud-rate generator. Setting is selectable
among 8 values.
Input of external values is allowed.
Use of clock from external timer (16-bit reload timer 0) is allowed.
Baud rate
7 bits (only asynchronous normal mode)
8 bits
Data length
Signaling system
Non Return to Zero (NRZ) system
Framing error
Overrun error
Parity error (not detectable in operation mode 1 (multi-processor
mode))
Reception error detection
Receive interrupt (reception completed, reception error detected)
Transmission interrupt (transmission completed)
Ready for expanded intelligent I/O service (EI2OS) in both transmission and reception
Interrupt request
Master/slave communication function
(asynchronous, multi-processor mode)
Communication between 1 (master) and n (slaves) are available
(usable as master only).
Note : Start/stop bit is not added upon clock-synchronous transmission. Data only is transmitted.
UART operation modes
Operation mode
Data length
With parity
Without parity
Synchronization
0
Asynchronous mode
(normal mode)
1
Multi processor mode
8+1*1

Asynchronous
2
Synchronous mode
8

Synchronous
7-bit or 8-bit
Asynchronous
Stop bit length
1- bit or 2-bit *2
No
 : Disallowed
*1 : “+1” is an address/data selection bit used for communication control (bit 11 of SCR1 register: A/D).
*2 : Only 1 bit is detected as a stop bit on data reception.
50
MB90385 Series
• UART block diagram
Control bus
Special-purpose
baud-rate
generator
16-bit reload
timer
Pin
Reception interrupt
request output
Transmission
clock
Clock Reception
Reception
selector
clock
control
circuit
SCK1
Transmission interrupt
request output
Transmission
control
circuit
Transmission
start circuit
Start bit
detection circuit
Reception bit
counter
Transmission
bit counter
Reception
parity counter
Transmission
parity counter
Pin
SOT1
Shift register for
transmission
Shift register for
reception
Pin
SIN1
Reception status
decision circuit
Reception
Serial input data comregister 1
pleted
Serial output data
register 1
Start
transmission
Reception error
occurrence
signal for EI2OS
(to CPU)
Internal data bus
Communication
prescaler
control
register
MD
DIV2
DIV1
DIV0
Serial
mode
register
1
MD1
MD0
CS2
CS1
CS0
RST
SCKE
SOE
Serial
control
register
1
PEN
P
SBL
CL
A/D
REC
RXE
TXE
Serial
status
register
1
PE
ORE
FRE
RDRF
TDRE
BDS
RIE
TIE
51
MB90385 Series
12. CAN Controller
The Controller Area Network (CAN) is a serial communication protocol compliant with CANVer2.0A and Ver2.0B.
The protocol allows data transmission and reception in both standard frame format and expanded frame format.
• Features of CAN controller
• CAN controller format is compliant with CANVer2.0A and Ver2.0B.
• The protocol allows data transmission and reception in standard frame format and expanded frame format.
• Automatic transmission of data frame by remote frame reception is allowed.
• Baud rate ranges from 10 Kbps to 1 Mbps (with 16-MHz machine clock).
Data transmission baud rate
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
Provided with 8 transmission/reception message buffers.
Transmission/reception is allowed at ID11bit in standard format, and at ID29bit in expanded frame format.
Specifying 0 byte to 8 bytes is allowed in message data.
Multi-level message buffer configuration is allowed.
CAN controller has two built-in acceptance masks. Mask settings are independently allowed for the two acceptance masks on reception IDs.
• The two acceptance masks allow reception in standard frame format and expanded frame format.
• For types of masking, all-bit comparison, all-bit masking, and partial masking with acceptance mask register
0/1, are specifiable.
52
MB90385 Series
• CAN controller block diagram
F2MC-16LX bus
CPU
operation
clock
PSC
TS1
BTR
TS2
RSJ
TOE
TS
RS
CSR HALT
NIE
NT
NS1,0
Bit timing
generation circuit
Prescaler
(dividing by 1 to 64)
Node status
transition interrupt
generation circuit
TREQR
Error
control
circuit
Clear transmission
buffer
Transmission
buffer
decision circuit
Transmission
buffer
Transmission/
reception
sequence
Error frame
generation
circuit
Overload
frame
generation
circuit
Data Acceptance
counter filter control
circuit
Trans- Recep- ID
mission tion selection
DLC DLC
Transmission
buffer
Idle, interrupt, suspend,
transmit, receive, error,
and overload
Bus
status
decision
circuit
Node status
transition
interrupt signal
RTEC
BVALR
Operation clock (TQ)
Sync segment
Time segment 1
Time segment 2
Arbitration
lost
Bit error, stuff error,
CRC error, frame
error, ACK error
TCANR
Output
driver
Pin TX
Input
latch
Pin RX
TRTRR
TCR
TIER
RCR
RIER
Set and clear
transmission buffer
Transmission
completion interrupt
generation circuit
Transmission
completion
interrupt
signal
Set reception buffer
Reception completion
interrupt generation
circuit
Reception
completion
interrupt
signal
RRTRR
Set and clear reception
buffer and transmission buffer
ROVRR
Set reception
ID selection
buffer
AMR1
IDR0 to 7
DLCR0 to 7
DTR0 to 7
RAM
CRC
ACK
generation generation
circuit
Transmission
circuit
DLC
CRC error
Reception
CRC generation circuit/
DLC
error check
Reception
shift register
0
1
Acceptance
filter
RAM address
generation circuit
Stuffing
error
Destuffing/stuffing
error check
Arbitration
check
Arbitration lost
AMSR
AMR0
Stuffing
Transmission
shift register
RFWTR
Bit error
check
Bit error
Reception
buffer
decision circuit
ACK error
Acknowledgment
error check
Reception buffer
Form error
Form error
check
Reception buffer, transmission buffer,
reception DLC, transmission DLC, ID selection
IDER
LEIR
53
MB90385 Series
13. Address Matching Detection Function Outline
The address matching detection function checks if an address of an instruction to be processed next to a currentlyprocessed instruction is identical with an address specified in the detection address register. If the addresses
match with each other, an instruction to be processed next in program is forcibly replaced with INT9 instruction,
and process branches to the interrupt process program. Using INT9 interrupt, this function is available for
correcting program by batch processing.
• Address matching detection function outline
• An address of an instruction to be processed next to a currently-processed instruction of the program is always
retained in an address latch via internal data bus. By the address matching detection function, the address
value retained in the address latch is always compared with an address specified in detection address setting
register. If the compared address values match with each other, an instruction to be processed next by CPU
is forcibly replaced with INT9 instruction, and an interrupt process program is executed.
• Two detection address setting registers are provided (PADR0 and PADR1), and each register is provided with
interrupt permission bit. Generation of interrupt, which is caused by address matching between the address
retained in address latch and the address specified in address setting register, is permitted and prohibited on
a register-by-register basis.
• Address matching detection function block diagram
Address latch
24bit
Detection address setting register 0
PADR1
24bit
Comparator
Internal data bus
PADR0
INT9 instruction
(generate INT9 interrupt)
Detection address setting register 1
PACSR
Reserved Reserved Reserved Reserved
AD1E Reserved AD0E Reserved
Address detection control register (PACSR)
Reserved: Be sure to set to “0.”
• Address latch
Retains address value output to internal data bus.
• Address detection control register (PACSR)
Specifies if interrupt is permitted or prohibited when addresses match with each other.
• Detection address setting (PADR0, PADR1)
Specifies addresses to be compared with values in address latch.
54
MB90385 Series
14. ROM Mirror Function Selection Module Outline
The ROM mirror function selection module sets the data in ROM assigned to FF bank so that the data is read
by access to 00 bank.
• ROM mirror function selection module block diagram
ROM mirror function selection register
(ROMM)
Reserved Reserved Reserved Reserved Reserved Reserved Reserved
MI
Address
Internal data bus
Address area
FF bank
00 bank
Data
ROM
• FF bank access by ROM mirror function
004000 H
00 bank
ROM mirror area
00FFFFH
FBFFFF H
FC0000H
FEFFFF H
MB90V495G
FF0000 H
FF4000 H
FFFFFFH
FF bank (ROM
mirror applicable
area)
MB90F387
MB90387
55
MB90385 Series
15. 512 Kbit Flash Memory Outline
The following three methods are provided for data writing and deleting on flash memory:
1. Parallel writer
2. Serial special-purpose writer
3. Writing/deleting by program execution
This section describes “3. Writing/deleting by program execution.”
• 512 Kbit flash memory outline
The 512K-bit flash memory is allocated on FFH bank of CPU memory map. Using the function of flash memory
interface circuit, the memory allows read access and program access from CPU.
Writing/deleting on flash memory is performed by instruction from CPU via flash memory interface. Because
rewriting is allowed on mounted memory, modifying program and data is performed efficiently.
• Features of 512 Kbit flash memory
• 128 K words x 8 bits/64 K words x 16 bits (16 K + 8 K + 8 K + 32 K) sector configuration
• Automatic program algorithm (Embedded AlgorithmTM* : Similar to MBM29LV200.)
• Built-in deletion pause/deletion resume function
• Detection of completed writing/deleting by data polling and toggle bits.
• Detection of completed writing/deleting by CPU interrupt.
• Deletion is allowed on a sector-by-sector basis (sectors are combined freely).
• Number of writing/deleting operations (minimum): 10,000 times
• Sector protection
• Expanded sector protection
• Temporaly sector unprotection
* : Embedded AlgorithmTM is a registered trademark of Advanced Micro Devices.
Note : A function of reading manufacture code and device code is not provided. These codes are not accessible
by command either.
• Flash memory writing/deleting
• Writing and reading data is not allowed simultaneously on the flash memory.
• Data writing and deleting on the flash memory is performed by the processes as follows: Make a copy of
program on flash memory onto RAM. Then, execute the program copied on the RAM.
• List of registers and reset values in flash memory
Flash memory control status register (FMCS)
× : Undefined
56
bit
7
6
5
4
3
2
1
0
0
0
0
X
0
0
0
0
MB90385 Series
• Sector configuration
For access from CPU, SA0 to SA3 are allocated in FF bank register.
• Sector configuration of 512 Kbit flash memory
Flash memory
CPU address
Writer address*
FF0000H
70000H
FF7FFF H
77FFFH
FF8000H
78000H
FF9FFF H
79FFFH
FFA000H
7A000H
FFBFFF H
7BFFF H
FFC000 H
7C000H
FFFFFF H
7FFFFH
SA0 (32 Kbytes)
SA1 (8 Kbytes)
SA2 (8 Kbytes)
SA3 (16 Kbytes)
* : “Writer address” is an address equivalent to CPU address, which is used
when data is written on flash memory, using parallel writer. When writing/
deleting data with general-purpose writer, the writer address is used for
writing and deleting.
57
MB90385 Series
■ ELECTRIC CHARACTERISTICS
1. Absolute Maximum Rating
(VSS = AVSS = 0 V)
Parameter
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
∑ | ICLAMP |

20
mA
*6
IOL1

15
mA
Normal output*3
IOL2

40
mA
High-current output*3
IOLAV1

4
mA
Normal output*4
IOLAV2

30
mA
High-current output*4
∑IOL1

125
mA
Normal output
∑IOL2

160
mA
High-current output
∑IOLAV1

40
mA
Normal output*5
∑IOLAV2

40
mA
High-current output*5
IOH1

−15
mA
Normal output*3
IOH2

−40
mA
High-current output*3
IOHAV1

−4
mA
Normal output*4
IOHAV2

−30
mA
High-current output*4
∑IOH1

−125
mA
Normal output
∑IOH2

−160
mA
High-current output
∑IOHAV1

−40
mA
Normal output*5
∑IOHAV2

−40
mA
High-current output*5
Power consumption
PD

245
mW
Operating temperature
TA
−40
+105
°C
Tstg
−55
+150
°C
Power supply voltage
Maximum clamp current
Total maximum clamp current
“L” level maximum output current
“L” level average output current
“L” level maximum total output current
“L” level average total output current
“H” level maximum output current
“H” level average output current
“H” level maximum total output current
“H” level average total output current
Storage temperature
*1 : AVcc and AVR should not exceed Vcc.
*2 : VI and VO should not exceed Vcc + 0.3 V.
*3 : A peak value of an applicable one pin is specified as a maximum output current.
*4 : An average current value of an applicable one pin within 100 ms is specified as an average output current.
(Average value is found by multiplying operating current by operating rate.)
*5 : An average current value of all pins within 100 ms is specified as an average total output current. (Average
value is found by multiplying operating current by operating rate.)
(Continued)
58
MB90385 Series
(Continued)
*6 : • Applicable to pins: P10 to P17, P20 to P27, P30 to P33, P35*, P36*, P37, P40 to P44, P50 to P57
*: P35 and P36 are MB90387S and MB90F387S only.
• 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.
• 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:
• Input/Output Equivalent circuits
Protective diode
VCC
P-ch
Limiting
resistance
+B input (0 V to 16 V)
N-ch
R
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.
59
MB90385 Series
2. Recommended Operating Conditions
Parameter
(VSS = AVSS = 0.0V)
Value
Symbol
Unit
Remarks
Min
Typ
Max
3.5
5.0
5.5
V
Under normal operation
3.0

5.5
V
Retain status of stop
operation
AVCC
4.0

5.5
V
*2
Smoothing capacitor
CS
0.1

1.0
µF
*1
Operating temperature
TA
−40

+105
°C
Power supply voltage
VCC
*1 : Use a ceramic capacitor, or a capacitor of similar frequency characteristics. On the Vcc pin, use a bypass
capacitor that has a larger capacity than that of Cs.
Refer to the following figure for connection of smoothing capacitor Cs.
*2 : AVcc is a voltage at which accuracy is guaranteed. AVcc should not exceed Vcc.
• 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.
60
MB90385 Series
3. DC Characteristics
Parame- Sym
ter
bol
“H” level
input
voltage
“L” level
input
voltage
“H” level
output
voltage
“L” level
output
voltage
Input
leak
current
Pin name
(VCC = 5.0 V±10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Value
Remarks
Conditions
Unit
Min
Typ
Max
CMOS
VIHS hysteresis input
pin
—
0.8 VCC
—
VCC + 0.3
V
VIHM MD input pin
—
VCC − 0.3
—
VCC + 0.3
V
—
VSS − 0.3
—
0.2 VCC
V
—
VSS − 0.3
—
VSS + 0.3
V
VCC = 4.5 V,
IOH = −4.0 mA
VCC – 0.5
—
—
V
VCC = 4.5 V,
IOH = −14.0 mA
VCC – 0.5
—
—
V
VCC = 4.5 V,
IOL = 4.0 mA
—
—
0.4
V
VCC = 4.5 V,
IOL = 20.0 mA
—
—
0.4
V
VCC = 5.5 V,
VSS < VI < VCC
–5
—
+5
µA
VCC = 5.0 V,
Internally operating at
16 MHz, normal operation.
—
25
30
mA
VCC = 5.0 V,
Internally operating at
16 MHz, writing on flash
memory.
—
45
50
mA MB90F387/S
VCC = 5.0 V,
Internally operating at
16 MHz, deleting on flash
memory.
—
45
50
mA MB90F387/S
ICCS
VCC = 5.0 V,
Internally operating at
16 MHz, sleeping.
—
8
12
mA
0.75
1.0
ICTS
VCC = 5.0 V,
Internally operating at
2 MHz, transition from
main clock mode, in timebase timer mode.
VILS
CMOS
hysteresis input
pin
VILM MD input pin
VOH1
Pins other than
P14 to P17
VOH2 P14 to P17
VOL1
Pins other than
P14 to P17
VOL2 P14 to P17
IIL
All input pins
ICC
Power
supply
current*
VCC
—
MB90F387/S
mA
0.2
0.35
MB90387/S
(Continued)
61
MB90385 Series
(Continued)
Parameter
Symbol
Pin name
VCC = 5.0 V,
Internally operating at
8 kHz, subclock operation,
TA = + 25°C
—
0.3
1.2
mA MB90F387/S
—
40
100
µA
VCC = 5.0 V,
Internally operating at
8 kHz, subclock,
sleep mode,
TA = + 25°C
—
10
30
µA
ICCT
VCC = 5.0 V,
Internally operating at
8 kHz, clock mode,
TA = + 25°C
—
8
25
µA
ICCH
Stopping,
TA = + 25°C
—
5
20
µA
ICCL
Power
supply
current*
Input
capacity
Pull-up
resistor
Pull-down
resistor
(VCC = 5.0 V±10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Rating
Conditions
Unit
Remarks
Min
Typ
Max
ICCLS
VCC
CIN
Other than
AVCC, AVSS,
AVR, C, VCC,
VSS

—
5
15
pF
RUP
RST

25
50
100
kΩ
RDOWN MD2

25
50
100
kΩ
* : Test conditions of power supply current are based on a device using external clock.
62
MB90387/S
FLASH product is
not provided with
pull-down resistor.
MB90385 Series
4. AC Characteristics
(1) Clock timing
Parameter
Symbol
(VCC = 5.0 V±10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Value
Pin name
Unit
Remarks
Min
Typ
Max
fC
Clock frequency
Clock cycle time
Input clock pulse width
Input clock rise time and fall
time
Internal operation clock
frequency
Internal operation clock cycle
time
X0, X1
When crystal or ceramic
resonator is used*2
3
—
8
MHz
3
—
16
MHz External clock *1, *2
fCL
X0A, X1A
—
32.768
—
kHz
tHCYL
X0, X1
125
—
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 main clock is used
fLCP
—
—
8.192
—
kHz
When sub clock is used
tCP
—
62.5
—
666
ns
When main clock is used
tLCP
—
—
122.1
—
µs
When sub clock is used
Set duty factor at 30% to
70% as a guideline.
When external clock is
used
*1 : Internal operation clock frequency should not exceed 16 MHz.
*2 : When selecting the PLL clock, the range of clock frequency is limitted. Use this product within range as mentioned
in “Relation among external clock frequency and internal clock frequency”.
• 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
tCR
63
MB90385 Series
• PLL operation guarantee range
Relation between internal operation clock
frequency and power supply voltage
Operation guarantee range of MB90F387/S and MB90387/S
Power voltage VCC (V)
5.5
A/D converter
accuracy
guarantee range
4.0
3.5
3.0
PLL operation guarantee range
1.5
3 4
8
12
16
Internal clock fCP (MHz)
Relation among external clock frequency and internal clock frequency
Multiply
by 4
Multiply Multiply
by 3
by 2
Multiply by 1
Internal clock fCP (MHz)
16
12
x1/2
(no multiplication)
9
8
4
3
4
8
16
External clock fC (MHz)*
* : fc is 8 MHz at maximum when crystal or ceramic resonator circuit is used.
Rating values of alternating current is defined by the measurement reference voltage values shown below:
• Input signal waveform
• Output signal waveform
Hysteresis input pin
64
Output pin
0.8 VCC
2.4 V
0.2 VCC
0.8 V
MB90385 Series
(2) Reset input timing
Parameter
Symbol
Reset input time
tRSTL
Value
Pin
name
RST
Min
Max
16 tCP*3

Unit
Remarks
ns
Normal operation
Oscillation time of oscillator*1
+ 100 µs + 16 tCP*3


In sub clock*2, sub
sleep*2, watch*2 and
stop mode
100

µs
In timebase timer
*1 : Oscillation time of oscillator is time that the amplitude reached the 90%. In the crystal oscillator, the oscillation
time is between several ms to tens of ms. In FAR/ceramic oscillator, the oscillation time is between hundreds
of µs to several ms. In the external clock, the oscillation time is 0 ms.
*2 : Except for MB90F387S and MB90387S.
*3 : Refer to "(1) Clock timing" ratings for tCP (internal operation clock cycle time).
• In sub clock, sub sleep, watch and stop mode
tRSTL
RST
0.2 VCC
0.2 VCC
90% of
amplitude
X0
Internal operation
clock
100 s
+ 16 tCP
Oscillation
time of
oscillator
Wait time for stabilizing
oscillation
Execute instruction
Internal reset
65
MB90385 Series
(3) Power-on reset
Parameter
(VCC = 5.0 V ± 10%, VSS = AVSS = 0.0 V, TA = −40 °C to +105 °C)
Value
Symbol Pin name Conditions
Unit
Remarks
Min
Max
Power supply rise time
tR
VCC
Power supply shutdown
time
tOFF
VCC

0.05
30
ms
1

ms
Repeated operation
tR
VCC
2.7 V
0.2 V
0.2 V
0.2 V
tOFF
Sudden change of power supply voltage may activate the power-on reset function. When
changing power supply voltages during operation, raise the power smoothly by suppressing
variation of voltages as shown below. When raising the power, do not use PLL clock. However, if voltage drop is 1V/s or less, use of PLL clock is allowed during operation.
VCC
3.0 V
VSS
66
Limiting the slope of rising within
50 mV/ms is recommended.
RAM data hold period
MB90385 Series
(4) UART timing
Parameter
(VCC = 4.5 V to 5.5 V, VSS = 0.0 V, TA = −40 °C to +105 °C)
Value
Symbol Pin name
Conditions
Unit Remarks
Min
Max
8 tCP *

ns
−80
+80
ns
100

ns
SCK1,
SIN1
60

ns
tSHSL
SCK1
4 tCP *

ns
Serial clock “L” pulse width
tSLSH
SCK1
4 tCP *

ns
SCK ↓ → SOT delay time
tSLOV
SCK1,
SOT1

150
ns
Valid SIN → SCK ↑
tIVSH
SCK1,
SIN1
60

ns
SCK ↑ → valid SIN hold time
tSHIX
SCK1,
SIN1
60

ns
Serial clock cycle time
tSCYC
SCK1
SCK ↓ → SOT delay time
tSLOV
SCK1,
SOT1
Valid SIN → SCK ↑
tIVSH
SCK1,
SIN1
SCK ↑ → valid SIN hold time
tSHIX
Serial clock “H” pulse width
Internal shift clock
mode output pin is :
CL = 80 pF+1TTL.
External shift clock
mode output pin is :
CL = 80 pF+1TTL.
* : Refer to "(1) Clock timing" ratings for tCP (internal operation clock cycle time).
Notes: • AC rating in CLK synchronous mode.
• CL is a load capacitance value on pins for testing.
67
MB90385 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
68
tSHIX
0.8 VCC
0.8 VCC
0.2 VCC
0.2 VCC
MB90385 Series
(5) Timer input timing
Parameter
(VCC = 4.5 V to 5.5 V, VSS = 0.0 V, TA = −40 °C to +105 °C)
Value
Conditions
Unit Remarks
Min
Max
Symbol
Pin name
tTIWH
TIN0, TIN1
tTIWL
IN0 to IN3
Input pulse width

4 tCP *

ns
* : Refer to "(1) Clock timing" ratings for tCP (internal operation clock cycle time).
• Timer input timing
0.8 VCC
0.8 VCC
TIN0, TIN1,
IN0 to IN3
0.2 VCC
tTIWH
tTIWL
(6) Trigger input timing
Parameter
(VCC = 4.5 V to 5.5 V, VSS = 0.0 V, TA = −40 °C to +105 °C)
Value
Conditions
Unit Remarks
Min
Max
Symbol
Pin name
tTRGH
tTRGL
INT4 to INT7,
ADTG
Input pulse width
0.2 VCC

5 tCP *

ns
* : Refer to "(1) Clock timing" ratings for tCP (internal operation clock cycle time).
• Trigger input timing
INT4 to INT7,
ADTG
0.8 VCC
0.8 VCC
0.2 VCC
tTRGH
0.2 VCC
tTRGL
69
MB90385 Series
5. A/D converter
Parameter
(VCC = AVCC = 5.0 V ± 10%, VSS = AVSS = 0.0 V, 3.0 V ≤ AVR − AVSS, TA = −40 °C to +105 °C)
Value
Pin
Symbol
Conditions
Unit
Remarks
name
Min
Max
Resolution




10
bit
Total error




± 3.0
LSB
Nonlinear error




± 2.5
LSB
Differential linear error




± 1.9
LSB
Zero transition voltage
VOT
AN0 to
AN7
AVSS − 1.5
LSB
AVSS + 0.5 AVSS + 2.5
LSB
LSB
V
VFST
AN0 to
AN7
AVR − 3.5
LSB
AVR − 1.5
LSB
AVR + 0.5
LSB
V
66 tCP *1


ns
With 16 MHz
machine clock
5.5 V ≥ AVCC ≥ 4.5 V
88 tCP *1


ns
With 16 MHz
machine clock
4.5 V > AVCC ≥ 4.0 V
32 tCP *1


ns
With 16 MHz
machine clock
5.5 V ≥ AVCC ≥ 4.5 V
128 tCP *1


ns
With 16 MHz
machine clock
4.5 V > AVCC ≥ 4.0 V
Full-scale transition
voltage
Compare time
Sampling time


1 LSB = AVR/1024


Analog port input
current
IAIN
AN0 to
AN7


10
µA
Analog input voltage
VAIN
AN0 to
AN7
AVSS

AVR
V

AVR
AVSS + 2.7

AVCC
V
IA
AVCC

3.5
7.5
mA
IAH
AVCC


5
µA
IR
AVR

165
250
µA
IRH
AVR


5
µA

AN0 to
AN7


4
LSB
Reference voltage
Power supply current
Reference voltage
supplying current
Variation among
channels
*2
*2
*1 : Refer to "(1) Clock timing" ratings for tCP (internal operation clock cycle time).
*2 : If A/D converter is not operating, a current when CPU is stopped is applicable (Vcc=AVcc=AVR=5.0 V).
70
MB90385 Series
6. Definition of A/D Converter Terms
Resolution
Linear error
Differential linear
error
Total error
: Analog variation that is recognized by an A/D converter.
: Deviation between a line across zero-transition line (“00 0000 00 0 0” ←→“00 0000 0001”)
and full-scale transition line (“11 1111 11 1 0” ←→ “11 1111 1111”) and actual conversion
characteristics.
: Deviation of input voltage, which is required for changing output code by 1 LSB, from an
ideal value.
: Difference between an actual value and an ideal value. A total error includes zero transition
error, full-scale transition error, and linear error.
Total error
3FF
3FE
Actual conversion
characteristics
1.5 LSB
Digital output
3FD
{1 LSB × (N − 1) + 0.5 LSB}
004
VNT
(Actually-measured value)
003
Actual conversion
characteristics
Ideal characteristics
002
001
0.5 LSB
AVss
Total error of digital output “N” =
1 LSB = (Ideal value)
Analog input
AVR
VNT − {1 LSB × (N − 1) + 0.5 LSB}
1 LSB
AVR − AVSS
1024
[LSB]
[V]
VOT (Ideal value) = AVSS + 0.5 LSB [V]
VFST (Ideal value) = AVR − 1.5 LSB [V]
VNT : A voltage at which digital output transits from (N-1) to N.
(Continued)
71
MB90385 Series
(Continued)
Differential linear error
Linear error
3FF
Digital output
3FD
004
003
N+1
VFST (actual
measurement
value)
Digital output
3FE
Ideal characteristics
Actual conversion
characteristics
{1 LSB × (N − 1)
+ VOT }
VNT (actual
measurement value)
Actual conversion
characteristics
Actual conversion
characteristics
N
002
Ideal characteristics
N−2
001
V (N + 1) T
(actual measurement
value)
N−1
VNT
(actual measurement value)
Actual conversion
characteristics
VOT (actual measurement value)
AVss
AVR
Analog input
Linear error of digital output N =
Differential linear error of digital output N =
1 LSB =
AVss
VNT − {1 LSB × (N − 1) + VOT}
1 LSB
V (N + 1) T − VNT
1 LSB
VFST − VOT
1022
−1LSB [LSB]
[V]
VOT : Voltage at which digital output transits from “000H” to “001H.”
VFST : Voltage at which digital output transits from “3FEH” to “3FFH.”
72
Analog input
[LSB]
AVR
MB90385 Series
7. Notes on A/D Converter Section
Use the device with external circuits of the following output impedance for analog inputs:
Recommended output impedance of external circuits are: Approx. 3.9 kΩ or lower (4.5 V ≤ AVcc ≤ 5.5 V)
(sampling period=2.00 µs at 16-MHz machine clock), Approx. 11 kΩ or lower (4.0 V ≤ AVcc < 4.5 V) (sampling
period=8.0 µs at 16-MHz machine clock).
If an external capacitor is used, in consideration of the effect by tap capacitance caused by external capacitors
and on-chip capacitors, capacitance of the external one is recommended to be several thousand times as high
as internal capacitor.
If output impedance of an external circuit is too high, a sampling period for an analog voltage may be insufficient.
• Analog input circuit model
R
Analog input
Comparator
C
MB90F387/S, MB90387/S
4.5 V ≤ AVCC ≤ 5.5 V
R =: 2.35 kΩ, C =: 36.4 pF
4.0 V ≤ AVCC < 4.5 V
R =: 16.4 kΩ, C =: 36.4 pF
Note : Use the values in the figure only as a guideline.
• About errors
As [AVR-AVss] become smaller, values of relative errors grow larger.
8. Flash Memory Program/Erase Characteristics
Parameter
Conditions
Sector eraset time
Chip erase time
TA = + 25 °C
VCC = 5.0 V
Word (16 bit width)
programming time
Value
Unit
Remarks
15
s
Excludes 00H programming
prior to erasure
4

s
Excludes 00H programming
prior to erasure

16
3,600
µs
Except for the over head
time of the system
Min
Typ
Max

1

Program/Erase cycle

10,000


cycle
Flash Data Retention
Time
Average
TA = + 85 °C
20


Year
*
* : This value comes from the technology qualification (using Arrhenius equation to translate high temperature
measurements into normalized value at + 85 °C) .
73
MB90385 Series
■ EXAMPLE CHARACTERISTICS
• MB90F387
ICC − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
30
25
f = 16 MHz
ICC (mA)
20
f = 10 MHz
15
f = 8 MHz
10
f = 4 MHz
5
f = 2 MHz
0
2.5
3.5
4.5
VCC (V)
5.5
6.5
ICCS − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
10
ICCS (mA)
8
f = 16 MHz
6
f = 10 MHz
4
f = 8 MHz
2
f = 4 MHz
f = 2 MHz
0
2.5
3.5
4.5
VCC (V)
5.5
6.5
ICCL − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
350
300
f = 8 kHz
ICCL ( A)
250
200
150
100
50
0
3
4
5
VCC (V)
6
7
(Continued)
74
MB90385 Series
ICCLS − VCC
ICCLS ( A)
TA = +25 °C, In external clock operation
f = Internal operating frequency
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
f = 8 kHz
3
4
5
VCC (V)
6
7
ICCT − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
10
9
8
f = 8 kHz
ICCT ( A)
7
6
5
4
3
2
1
0
4
3
5
6
7
VCC (V)
ICCH − VCC
Stopping, TA = +25 °C
30
ICCH ( A)
25
20
15
10
5
0
2
3
4
5
6
7
VCC (V)
(Continued)
75
MB90385 Series
(Continued)
(VCC - VOH) − IOH
TA = +25 °C, VCC = 4.5 V
1000
900
VCC VOH (mV)
800
700
600
500
400
300
200
100
0
0
1
2
3
4
5
6
7
8
9
10
IOH (mA)
VOL − IOL
TA = +25 °C, VCC = 4.5 V
1000
900
800
VOL (mV)
700
600
500
400
300
200
100
0
0
2
4
6
8
10
IOL (mA)
H level input voltage/ L level input voltage
VIN − VCC
TA = +25 °C
5
VIN (V)
4
VIH
3
VIL
2
1
0
2.5
3
3.5
4
4.5
VCC (V)
76
5
5.5
6
MB90385 Series
• MB90387
ICC − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
25
f = 16 MHz
15
f = 10 MHz
10
f = 8 MHz
5
f = 4 MHz
f = 2 MHz
0
3
2.5
3.5
4
4.5
5
5.5
6
6.5
7
VCC (V)
ICCS − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
9
8
f = 16 MHz
ICCS (mA)
7
6
f = 10 MHz
5
f = 8 MHz
4
3
f = 4 MHz
2
f = 2 MHz
1
0
2.5
3.5
4.5
VCC (V)
5.5
6.5
ICCL − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
100
90
80
70
ICCL ( A)
ICC (mA)
20
60
f = 8 kHz
50
40
30
20
10
0
3
4
5
6
7
VCC (V)
(Continued)
77
MB90385 Series
ICCLS − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
10
9
ICCLS ( A)
8
f = 8 kHz
7
6
5
4
3
2
1
0
4
3
5
VCC (V)
6
7
ICCT − VCC
TA = +25 °C, In external clock operation
f = Internal operating frequency
10
9
8
ICCT ( A)
7
f = 8 kHz
6
5
4
3
2
1
0
4
3
5
VCC (V)
6
7
ICCH − VCC
Stopping, TA = +25 °C
30
25
ICCH ( A)
20
15
10
5
0
2
3
4
5
6
7
VCC (V)
(Continued)
78
MB90385 Series
(Continued)
(VCC - VOH) − IOH
TA = +25 °C, VCC = 4.5 V
1000
900
VCC
VOH (mV)
800
700
600
500
400
300
200
100
0
0
2
1
3
4
5
6
IOH (mA)
7
8
VOL − IOL
9
10
TA = +25 °C, VCC = 4.5 V
1000
900
800
VOL (mV)
700
600
500
400
300
200
100
0
0
1
2
3
4
5
6
IOL (mA)
7
8
9
10
H level input voltage/ L level input voltage
VIN − VCC
TA = +25 °C
5
4
VIN (V)
VIH
3
VIL
2
1
0
2.5
3
3.5
4
4.5
VCC (V)
5
5.5
6
79
MB90385 Series
■ ORDERING INFORMATION
Part number
MB90F387PMT
MB90387PMT
MB90F387SPMT
MB90387SPMT
80
Package
48-pin plastic LQFP
(FPT-48P-M26)
Remarks
MB90385 Series
■ PACKAGE DIMENTION
Note 1) * : These dimensions include resin protrusion.
Note 2) Pins width and pins thickness include plating thickness.
Note 3) Pins width do not include tie bar cutting remainder.
48-pin plastic LQFP
(FPT-48P-M26)
9.00±0.20(.354±.008)SQ
+0.40
+.016
* 7.00 –0.10 .276 –.004 SQ
36
0.145±0.055
(.006±.002)
25
37
24
0.08(.003)
Details of "A" part
+0.20
1.50 –0.10
+.008
48
13
"A"
0˚~8˚
LEAD No.
1
0.50(.020)
(Mounting height)
.059 –.004
INDEX
0.10±0.10
(.004±.004)
(Stand off)
12
0.20±0.05
(.008±.002)
0.08(.003)
0.25(.010)
M
0.60±0.15
(.024±.006)
C
2003 FUJITSU LIMITED F48040S-c-2-2
Dimensions in mm (inches)
Note : The values in parentheses are reference values.
81
MB90385 Series
FUJITSU LIMITED
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The contents of this document are subject to change without notice.
Customers are advised to consult with FUJITSU sales
representatives before ordering.
The information, such as descriptions of function and application
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
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assumes no liability for any damages whatsoever arising out of
the use of the information.
Any information in this document, including descriptions of
function and schematic diagrams, shall not be construed as license
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from the use of information contained herein.
The products described in this document are designed, developed
and manufactured as contemplated for general use, including
without limitation, ordinary industrial use, general office use,
personal use, and household use, but are not designed, developed
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
control, mass transport control, medical life support system, missile
launch control in weapon system), or (2) for use requiring
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satellite).
Please note that Fujitsu will not be liable against you and/or any
third party for any claims or damages arising in connection with
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must protect against injury, damage or loss from such failures by
incorporating safety design measures into your facility and
equipment such as redundancy, fire protection, and prevention of
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If any products described in this document represent goods or
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F0405
 FUJITSU LIMITED Printed in Japan