DS704-00003-2v1-E

The following document contains information on Cypress products.
F2MC-16FX MB96650 Series
16-bit Proprietary Microcontroller
MB96F653R/A, MB96F655R/A
MB96F656R, MB96F657R
Data Sheet (Full Production)
Publication Number MB96650_DS704-00003
CONFIDENTIAL
Revision 2.1
Issue Date January 31, 2014
D a t a S h e e t
2
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
F2MC-16FX MB96650 Series
16-bit Proprietary Microcontroller
MB96F653R/A, MB96F655R/A
MB96F656R, MB96F657R
Data Sheet (Full Production)
 DESCRIPTION
MB96650 series is based on Spansion’s advanced F2MC-16FX architecture (16-bit with instruction pipeline
for RISC-like performance). The CPU uses the same instruction set as the established F2MC-16LX family
thus allowing for easy migration of F2MC-16LX Software to the new F2MC-16FX products.
F2MC-16FX product improvements compared to the previous generation include significantly improved
performance - even at the same operation frequency, reduced power consumption and faster start-up time.
For high processing speed at optimized power consumption an internal PLL can be selected to supply the
CPU with up to 32MHz operation frequency from an external 4MHz to 8MHz resonator. The result is a
minimum instruction cycle time of 31.2ns going together with excellent EMI behavior. The emitted power
is minimized by the on-chip voltage regulator that reduces the internal CPU voltage. A flexible clock tree
allows selecting suitable operation frequencies for peripheral resources independent of the CPU speed.
Spansion provides information facilitating product development via the following website.
The website contains information useful for customers.
http://www.spansion.com/Support/microcontrollers/Pages/default.aspx
Publication Number MB96650_DS704-00003
Revision 2.1
Issue Date January 31, 2014
This document states the current technical specifications regarding the Spansion product(s) described herein. Spansion Inc. deems the products to have been in sufficient
production volume such that subsequent versions of this document are not expected to change. However, typographical or specification corrections, or modifications to the
valid combinations offered may occur.
CONFIDENTIAL
D a t a S h e e t
 FEATURES
 Technology
0.18m CMOS
 CPU
 F2MC-16FX CPU
 Optimized instruction set for controller applications
(bit, byte, word and long-word data types, 23 different addressing modes, barrel shift, variety of pointers)
 8-byte instruction queue
 Signed multiply (16-bit  16-bit) and divide (32-bit/16-bit) instructions available
 System clock
 On-chip PLL clock multiplier (1 to 8, 1 when PLL stop)
 4MHz to 8MHz crystal oscillator
(maximum frequency when using ceramic resonator depends on Q-factor)
 Up to 8MHz external clock for devices with fast clock input feature
 32.768kHz subsystem quartz clock
 100kHz/2MHz internal RC clock for quick and safe startup, clock stop detection function, watchdog
 Clock source selectable from mainclock oscillator, subclock oscillator and on-chip RC oscillator,
independently for CPU and 2 clock domains of peripherals
 The subclock oscillator is enabled by the Boot ROM program controlled by a configuration marker after a
Power or External reset
 Low Power Consumption - 13 operating modes (different Run, Sleep, Timer, Stop modes)
 On-chip voltage regulator
Internal voltage regulator supports a wide MCU supply voltage range (Min=2.7V), offering low power
consumption
 Low voltage detection function
Reset is generated when supply voltage falls below programmable reference voltage
 Code Security
Protects Flash Memory content from unintended read-out
 DMA
Automatic transfer function independent of CPU, can be assigned freely to resources
 Interrupts
 Fast Interrupt processing
 8 programmable priority levels
 Non-Maskable Interrupt (NMI)
 CAN
 Supports CAN protocol version 2.0 part A and B
 ISO16845 certified
 Bit rates up to 1Mbps
 32 message objects
 Each message object has its own identifier mask
 Programmable FIFO mode (concatenation of message objects)
 Maskable interrupt
 Disabled Automatic Retransmission mode for Time Triggered CAN applications
 Programmable loop-back mode for self-test operation
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MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
 USART
 Full duplex USARTs (SCI/LIN)
 Wide range of baud rate settings using a dedicated reload timer
 Special synchronous options for adapting to different synchronous serial protocols
 LIN functionality working either as master or slave LIN device
 Extended support for LIN-Protocol to reduce interrupt load
 I2C
 Up to 400kbps
 Master and Slave functionality, 7-bit and 10-bit addressing
 A/D converter
 SAR-type
 8/10-bit resolution
 Signals interrupt on conversion end, single conversion mode, continuous conversion mode,
stop conversion mode, activation by software, external trigger, reload timers and PPGs
 Range Comparator Function
 Scan Disable Function
 Source Clock Timers
Three independent clock timers (23-bit RC clock timer, 23-bit Main clock timer, 17-bit Sub clock timer)
 Hardware Watchdog Timer
 Hardware watchdog timer is active after reset
 Window function of Watchdog Timer is used to select the lower window limit of the watchdog interval
 Reload Timers
 16-bit wide
 Prescaler with 1/21, 1/22, 1/23, 1/24, 1/25, 1/26 of peripheral clock frequency
 Event count function
 Free-Running Timers
 Signals an interrupt on overflow, supports timer clear upon match with Output Compare (0, 4)
 Prescaler with 1, 1/21, 1/22, 1/23, 1/24, 1/25, 1/26, 1/27, 1/28 of peripheral clock frequency
 Input Capture Units
 16-bit wide
 Signals an interrupt upon external event
 Rising edge, Falling edge or Both (rising & falling) edges sensitive
 Output Compare Units
 16-bit wide
 Signals an interrupt when a match with Free-running Timer occurs
 A pair of compare registers can be used to generate an output signal
 Programmable Pulse Generator
 16-bit down counter, cycle and duty setting registers
 Can be used as 2  8-bit PPG
 Interrupt at trigger, counter borrow and/or duty match
 PWM operation and one-shot operation
 Internal prescaler allows 1, 1/4, 1/16, 1/64 of peripheral clock as counter clock or of selected Reload timer
underflow as clock input
 Can be triggered by software or reload timer
 Can trigger ADC conversion
 Timing point capture
 Start delay
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
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D a t a S h e e t
 Quadrature Position/Revolution Counter (QPRC)
 Up/down count mode, Phase difference count mode, Count mode with direction
 16-bit position counter
 16-bit revolution counter
 Two 16-bit compare registers with interrupt
 Detection edge of the three external event input pins AIN, BIN and ZIN is configurable
 Real Time Clock
 Operational on main oscillation (4MHz), sub oscillation (32kHz) or RC oscillation (100kHz/2MHz)
 Capable to correct oscillation deviation of Sub clock or RC oscillator clock (clock calibration)
 Read/write accessible second/minute/hour registers
 Can signal interrupts every half second/second/minute/hour/day
 Internal clock divider and prescaler provide exact 1s clock
 External Interrupts
 Edge or Level sensitive
 Interrupt mask bit per channel
 Each available CAN channel RX has an external interrupt for wake-up
 Selected USART channels SIN have an external interrupt for wake-up
 Non Maskable Interrupt
 Disabled after reset, can be enabled by Boot-ROM depending on ROM configuration block
 Once enabled, can not be disabled other than by reset
 High or Low level sensitive
 Pin shared with external interrupt 0
 I/O Ports
 Most of the external pins can be used as general purpose I/O
 All push-pull outputs (except when used as I2C SDA/SCL line)
 Bit-wise programmable as input/output or peripheral signal
 Bit-wise programmable input enable
 One input level per GPIO-pin (either Automotive or CMOS hysteresis)
 Bit-wise programmable pull-up resistor
 Built-in On Chip Debugger (OCD)
 One-wire debug tool interface
 Break function:
- Hardware break: 6 points (shared with code event)
- Software break: 4096 points
 Event function
- Code event: 6 points (shared with hardware break)
- Data event: 6 points
- Event sequencer: 2 levels + reset
 Execution time measurement function
 Trace function: 42 branches
 Security function
 Flash Memory
 Dual operation flash allowing reading of one Flash bank while programming or erasing the other bank
 Command sequencer for automatic execution of programming algorithm and for supporting DMA for
programming of the Flash Memory
 Supports automatic programming, Embedded Algorithm
 Write/Erase/Erase-Suspend/Resume commands
 A flag indicating completion of the automatic algorithm
 Erase can be performed on each sector individually
 Sector protection
 Flash Security feature to protect the content of the Flash
 Low voltage detection during Flash erase or write
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CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
 PRODUCT LINEUP
Features
Product Type
Subclock
Dual Operation Flash Memory
64.5KB + 32KB
128.5KB + 32KB
256.5KB + 32KB
384.5KB + 32KB
MB96650
RAM
10KB
16KB
24KB
28KB
Package
DMA
USART
with automatic LIN-Header
transmission/reception
with 16 byte RX- and
TX-FIFO
I 2C
8/10-bit A/D Converter
with Data Buffer
with Range Comparator
with Scan Disable
with ADC Pulse Detection
16-bit Reload Timer (RLT)
16-bit Free-Running Timer (FRT)
16-bit Input Capture Unit (ICU)
16-bit Output Compare Unit (OCU)
8/16-bit Programmable Pulse Generator
(PPG)
with Timing point capture
with Start delay
with Ramp
Quadrature Position/Revolution Counter
(QPRC)
CAN Interface
External Interrupts (INT)
Non-Maskable Interrupt (NMI)
Real Time Clock (RTC)
I/O Ports
Clock Calibration Unit (CAL)
Clock Output Function
Low Voltage Detection Function
Flash Memory Product
Subclock can be set by software
MB96F653R, MB96F653A
MB96F655R, MB96F655A
MB96F656R
MB96F657R
LQFP-120
FPT-120P-M21
4ch
6ch
Yes (only 1ch)
Remark
Product Options
R: MCU with CAN
A: MCU without CAN
LIN-USART 0 to 2/4/5/7
LIN-USART 0
No
2ch
29ch
No
Yes
Yes
No
5ch
3ch
7ch
(1 channel for LIN-USART)
7ch
16ch (16-bit) / 32ch (8-bit)
I2C 0/1
AN 0 to 28
RLT 0 to 3/6
FRT 0 to 2
ICU 0/1/4 to 7/9
ICU 9 for LIN-USART
OCU 0 to 4/6/7
(OCU 4 for FRT clear)
PPG 0 to 15
Yes
Yes
No
2ch
1ch
16ch
1ch
1ch
99 (Dual clock mode)
101 (Single clock mode)
1ch
2ch
Yes
QPRC 0/1
CAN 0
32 Message Buffers
INT 0 to 15
Low voltage detection
function can be
disabled by software
Hardware Watchdog Timer
Yes
On-chip RC-oscillator
Yes
On-chip Debugger
Yes
Note: All signals of the peripheral function in each product cannot be allocated by limiting the pins of package.
It is necessary to use the port relocate function of the general I/O port according to your function use.
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
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D a t a S h e e t
 BLOCK DIAGRAM
NMI
CKOT0, CKOT0_R, CKOT1, CKOT1_R
CKOTX0, CKOTX1, CKOTX1_R
X0, X1
X0A, X1A
RSTX
MD
Interrupt
Controller
Flash
Memory A
DEBUG I/F
16FX
CPU
OCD
Clock &
Mode Controller
16FX Core Bus (CLKB)
Peripheral
Bus Bridge
Watchdog
2
IC
2ch
AVcc
AVss
AVRH
AVRL
AN0 to AN28
ADTG
8/10-bit ADC
29ch
TIN0 to TIN3
TIN1_R, TIN2_R
TOT0 to TOT3
TOT1_R, TOT2_R
16-bit Reload
Timer
0/1/2/3/6
5ch
FRCK0, FRCK0_R
IN0, IN0_R, IN1, IN1_R
I/O Timer 0
FRT0
ICU 0/1
OCU 0/1/2/3
OUT0 to OUT3
OUT0_R to OUT3_R
FRCK1
IN6, IN7
IN4_R to IN7_R
OUT6, OUT7
I/O Timer 1
FRT1
ICU 4/5/6/7
OCU 4/6/7
Peripheral
Bus Bridge
Peripheral Bus 2 (CLKP2)
SDA0, SDA1
SCL0, SCL1
RAM
CAN
Interface
1ch
USART
6ch
Peripheral Bus 1 (CLKP1)
DMA
Controller
Boot ROM
Voltage
Regulator
RX0
Vcc
Vss
C
TX0
SIN0 to SIN2, SIN4, SIN5, SIN7, SIN5_R, SIN7_R
SOT0 to SOT2, SOT4, SOT5, SOT7, SOT5_R, SOT7_R
SCK0 to SCK2, SCK4, SCK5, SCK7, SCK5_R, SCK7_R
TTG0 to TTG7, TTG12 to TTG15
PPG
16ch (16-bit)/
32ch (8-bit)
PPG0 to PPG7, PPG12 to PPG15
PPG0_R to PPG5_R, PPG8_R to PPG13_R
PPG0_B to PPG15_B
AIN0, AIN1
QPRC
2ch
BIN0, BIN1
ZIN0, ZIN1
FRCK2
INT0 to INT15
INT1_R to INT7_R
6
CONFIDENTIAL
I/O Timer 2
FRT2
ICU 9
External
Interrupt
16ch
Real Time
Clock
WOT, WOT_R
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
 PIN ASSIGNMENT
Vcc
P00_2 / INT5_R
P00_1 / INT4_R
P00_0 / INT3_R / FRCK2
P12_7 / INT1_R
P12_6 / TOT2_R / PPG3_B
P12_5 / TIN2_R / PPG2_B
P12_4 / OUT3_R
P12_3 / OUT2_R
P12_2 / TOT1_R / PPG1_B
P12_1 / TIN1_R / PPG0_B
P12_0 / IN1_R / BIN1
P11_7 / IN0_R / AIN1
P11_6 / FRCK0_R / ZIN1
P11_5 / PPG4_R
P11_4 / PPG3_R
P11_3 / PPG2_R
P11_2 / PPG1_R
P11_1 / PPG0_R
P11_0
RSTX
P04_1 / X1A*3
P04_0 / X0A*3
Vss
X1
X0
MD
P17_0
DEBUG I/F
Vss
(Top view)
90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
60
91
59
92
58
93
57
94
56
95
55
96
54
97
53
98
52
99
51
100
50
101
49
102
48
103
47
104
46
105
45
106
44
107
43
108
42
109
41
110
40
111
39
112
38
113
37
114
36
115
35
116
34
117
33
118
32
119
31
120
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30
LQFP - 120
Vcc
P10_3 / PPG7
P10_2 / SCK2 / PPG6*1
P10_1 / SOT2 / TOT3
P10_0 / SIN2 / TIN3 / AN28 / INT11*1
P09_7 / PPG15
P17_2 / PPG13_R
P17_1 / PPG12_R
P09_6 / PPG14
P09_5 / PPG13
P09_4 / PPG12
P09_3 / AN27 / PPG11_R
P09_2 / AN26 / PPG10_R
P09_1 / AN25 / PPG9_R
P09_0 / AN24 / PPG8_R
P08_7 / AN23 / PPG7_B
P08_6 / AN22 / PPG6_B
P08_5 / AN21 / OUT7
P04_7 / SCL1*2
P04_6 / SDA1*2
P08_4 / AN20 / OUT6
P08_3 / AN19
P08_2 / AN18
P08_1 / AN17
P08_0 / AN16
P05_7 / AN15 / TOT2
P05_6 / AN14 / TIN2
P05_5 / AN13
P05_4 / AN12 / INT2_R / WOT_R
Vss
Vss
C
P03_7 / INT1 / SIN1*1
P13_0 / INT2 / SOT1
P13_1 / INT3 / SCK1*1
P13_2 / PPG0 / TIN0 / FRCK1
P13_3 / PPG1 / TOT0 / WOT
P13_4 / SIN0 / INT6*1
P13_5 / SOT0 / ADTG / INT7
P13_6 / SCK0 / CKOTX0*1
P13_7 / PPG2 / CKOT0
P04_4 / PPG3 / SDA0*2
P04_5 / PPG4 / SCL0*2
P06_0 / AN0 / SCK5*1
P06_1 / AN1 / SOT5
P06_2 / AN2 / INT5 / SIN5*1
P06_3 / AN3 / FRCK0
P06_4 / AN4 / IN0 / TTG0 / TTG4
P06_5 / AN5 / IN1 / TTG1 / TTG5
P06_6 / AN6 / TIN1 / IN4_R
P06_7 / AN7 / TOT1 / IN5_R
AVcc
AVRH
AVRL
AVss
P05_0 / AN8
P05_1 / AN9
P05_2 / AN10 / OUT2
P05_3 / AN11 / OUT3
Vcc
Vss
P00_3 / INT6_R / PPG8_B
P00_4 / INT7_R / PPG9_B
P00_5 / IN6 / TTG2 / TTG6 / PPG10_B
P00_6 / IN7 / TTG3 / TTG7 / PPG11_B
P00_7 / INT14
P01_0 / SCK7*1
P01_1 / CKOT1 / OUT0 / SOT7
P01_2 / CKOTX1 / OUT1 / INT15 / SIN7*1
P01_3 / PPG5
P01_4 / SIN4 / INT8*1
P01_5 / SOT4
P01_6 / SCK4 / TTG12*1
P01_7 / CKOTX1_R / INT9 / TTG13 / ZIN0 / SCK7_R*1
P02_0 / CKOT1_R / INT10 / TTG14 / AIN0 / SOT7_R
P02_1 / IN6_R / TTG15
P02_2 / IN7_R / CKOT0_R / INT12 / BIN0 / SIN7_R*1
P02_3 / PPG12_B
P02_4 / PPG13_B
P02_5 / OUT0_R / INT13 / SIN5_R*1
P02_6 / OUT1_R
P02_7 / PPG5_R
P03_0 / PPG4_B
P03_1 / PPG5_B
P03_2 / PPG14_B / SOT5_R
P03_3 / PPG15_B / SCK5_R*1
P03_4 / RX0 / INT4*1
P03_5 / TX0
P03_6 / INT0 / NMI
Vcc
(FPT-120P-M21)
*1: CMOS input level only
2
*2: CMOS input level only for I C
*3: Please set ROM Configuration Block (RCB) to use the subclock.
Other than those above, general-purpose pins have only Automotive input level.
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
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D a t a S h e e t
 PIN DESCRIPTION
Pin name
Feature
Description
ADTG
AINn
ANn
AVcc
ADC
QPRC
ADC
Supply
AVRH
AVRL
AVss
BINn
C
CKOTn
ADC
ADC
Supply
QPRC
Voltage regulator
Clock Output function
A/D converter high reference voltage input pin
A/D converter low reference voltage input pin
Analog circuits power supply pin
Quadrature Position/Revolution Counter Unit n input pin
Internally regulated power supply stabilization capacitor pin
Clock Output function n output pin
CKOTn_R
CKOTXn
CKOTXn_R
DEBUG I/F
FRCKn
FRCKn_R
Clock Output function
Clock Output function
Clock Output function
OCD
Free-Running Timer
Free-Running Timer
Relocated Clock Output function n output pin
Clock Output function n inverted output pin
Relocated Clock Output function n inverted output pin
On Chip Debugger input/output pin
Free-Running Timer n input pin
Relocated Free-Running Timer n input pin
INn
INn_R
INTn
INTn_R
MD
NMI
ICU
ICU
External Interrupt
External Interrupt
Core
External Interrupt
OUTn
OUTn_R
Pnn_m
PPGn
OCU
OCU
GPIO
PPG
PPGn_R
PPG
A/D converter trigger input pin
Quadrature Position/Revolution Counter Unit n input pin
A/D converter channel n input pin
Analog circuits power supply pin
Input Capture Unit n input pin
Relocated Input Capture Unit n input pin
External Interrupt n input pin
Relocated External Interrupt n input pin
Input pin for specifying the operating mode
Non-Maskable Interrupt input pin
Output Compare Unit n waveform output pin
Relocated Output Compare Unit n waveform output pin
General purpose I/O pin
Programmable Pulse Generator n output pin (16bit/8bit)
Relocated Programmable Pulse Generator n output pin
(16bit/8bit)
Programmable Pulse Generator n output pin (16bit/8bit)
PPGn_B
PPG
RSTX
RXn
SCKn
SCKn_R
SCLn
SDAn
Core
CAN
USART
USART
I2C
I2C
SINn
SINn_R
SOTn
SOTn_R
TINn
USART
USART
USART
USART
Reload Timer
USART n serial data input pin
Relocated USART n serial data input pin
USART n serial data output pin
Relocated USART n serial data output pin
Reload Timer n event input pin
TINn_R
TOTn
Reload Timer
Reload Timer
Relocated Reload Timer n event input pin
Reload Timer n output pin
TOTn_R
TTGn
Reload Timer
PPG
Relocated Reload Timer n output pin
Programmable Pulse Generator n trigger input pin
TXn
CAN
8
CONFIDENTIAL
Reset input pin
CAN interface n RX input pin
USART n serial clock input/output pin
Relocated USART n serial clock input/output pin
I2C interface n clock I/O input/output pin
I2C interface n serial data I/O input/output pin
CAN interface n TX output pin
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
Pin name
Feature
Vcc
Supply
Power supply pin
Vss
WOT
Supply
RTC
Power supply pin
Real Time clock output pin
WOT_R
RTC
Relocated Real Time clock output pin
X0
X0A
Clock
Clock
Oscillator input pin
Subclock Oscillator input pin
X1
X1A
Clock
Clock
Oscillator output pin
Subclock Oscillator output pin
ZINn
QPRC
Quadrature Position/Revolution Counter Unit n input pin
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
Description
9
D a t a S h e e t
 PIN CIRCUIT TYPE
Pin no.
I/O circuit type*
Pin name
1
Supply
Vss
2
F
C
3
M
P03_7 / INT1 / SIN1
4
H
P13_0 / INT2 / SOT1
5
M
P13_1 / INT3 / SCK1
6
H
P13_2 / PPG0 / TIN0 / FRCK1
7
H
P13_3 / PPG1 / TOT0 / WOT
8
M
P13_4 / SIN0 / INT6
9
H
P13_5 / SOT0 / ADTG / INT7
10
M
P13_6 / SCK0 / CKOTX0
11
H
P13_7 / PPG2 / CKOT0
12
N
P04_4 / PPG3 / SDA0
13
N
P04_5 / PPG4 / SCL0
14
I
P06_0 / AN0 / SCK5
15
K
P06_1 / AN1 / SOT5
16
I
P06_2 / AN2 / INT5 / SIN5
17
K
P06_3 / AN3 / FRCK0
18
K
P06_4 / AN4 / IN0 / TTG0 / TTG4
19
K
P06_5 / AN5 / IN1 / TTG1 / TTG5
20
K
P06_6 / AN6 / TIN1 / IN4_R
21
K
P06_7 / AN7 / TOT1 / IN5_R
22
Supply
AVcc
23
G
AVRH
24
G
AVRL
25
Supply
AVss
26
K
P05_0 / AN8
27
K
P05_1 / AN9
28
K
P05_2 / AN10 / OUT2
29
K
P05_3 / AN11 / OUT3
30
Supply
Vcc
31
Supply
Vss
32
K
P05_4 / AN12 / INT2_R / WOT_R
33
K
P05_5 / AN13
34
K
P05_6 / AN14 / TIN2
35
K
P05_7 / AN15 / TOT2
36
K
P08_0 / AN16
37
K
P08_1 / AN17
38
K
P08_2 / AN18
39
K
P08_3 / AN19
40
K
P08_4 / AN20 / OUT6
10
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
Pin no.
I/O circuit type*
Pin name
41
N
P04_6 / SDA1
42
N
P04_7 / SCL1
43
K
P08_5 / AN21 / OUT7
44
K
P08_6 / AN22 / PPG6_B
45
K
P08_7 / AN23 / PPG7_B
46
K
P09_0 / AN24 / PPG8_R
47
K
P09_1 / AN25 / PPG9_R
48
K
P09_2 / AN26 / PPG10_R
49
K
P09_3 / AN27 / PPG11_R
50
H
P09_4 / PPG12
51
H
P09_5 / PPG13
52
H
P09_6 / PPG14
53
H
P17_1 / PPG12_R
54
H
P17_2 / PPG13_R
55
H
P09_7 / PPG15
56
I
P10_0 / SIN2 / TIN3 / AN28 / INT11
57
H
P10_1 / SOT2 / TOT3
58
M
P10_2 / SCK2 / PPG6
59
H
P10_3 / PPG7
60
Supply
Vcc
61
Supply
Vss
62
O
DEBUG I/F
63
H
P17_0
64
C
MD
65
A
X0
66
A
X1
67
Supply
Vss
68
B
P04_0 / X0A
69
B
P04_1 / X1A
70
C
RSTX
71
H
P11_0
72
H
P11_1 / PPG0_R
73
H
P11_2 / PPG1_R
74
H
P11_3 / PPG2_R
75
H
P11_4 / PPG3_R
76
H
P11_5 / PPG4_R
77
H
P11_6 / FRCK0_R / ZIN1
78
H
P11_7 / IN0_R / AIN1
79
H
P12_0 / IN1_R / BIN1
80
H
P12_1 / TIN1_R / PPG0_B
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
11
D a t a S h e e t
Pin no.
I/O circuit type*
Pin name
81
H
P12_2 / TOT1_R / PPG1_B
82
H
P12_3 / OUT2_R
83
H
P12_4 / OUT3_R
84
H
P12_5 / TIN2_R / PPG2_B
85
H
P12_6 / TOT2_R / PPG3_B
86
H
P12_7 / INT1_R
87
H
P00_0 / INT3_R / FRCK2
88
H
P00_1 / INT4_R
89
H
P00_2 / INT5_R
90
Supply
Vcc
91
Supply
Vss
92
H
P00_3 / INT6_R / PPG8_B
93
H
P00_4 / INT7_R / PPG9_B
94
H
P00_5 / IN6 / TTG2 / TTG6 / PPG10_B
95
H
P00_6 / IN7 / TTG3 / TTG7 / PPG11_B
96
H
P00_7 / INT14
97
M
P01_0 / SCK7
98
H
P01_1 / CKOT1 / OUT0 / SOT7
99
M
P01_2 / CKOTX1 / OUT1 / INT15 / SIN7
100
H
P01_3 / PPG5
101
M
P01_4 / SIN4 / INT8
102
H
P01_5 / SOT4
103
M
P01_6 / SCK4 / TTG12
104
M
P01_7 / CKOTX1_R / INT9 / TTG13 / ZIN0 / SCK7_R
105
H
P02_0 / CKOT1_R / INT10 / TTG14 / AIN0 / SOT7_R
106
H
P02_1 / IN6_R / TTG15
107
M
P02_2 / IN7_R / CKOT0_R / INT12 / BIN0 / SIN7_R
108
H
P02_3 / PPG12_B
109
H
P02_4 / PPG13_B
110
M
P02_5 / OUT0_R / INT13 / SIN5_R
111
H
P02_6 / OUT1_R
112
H
P02_7 / PPG5_R
113
H
P03_0 / PPG4_B
114
H
P03_1 / PPG5_B
115
H
P03_2 / PPG14_B / SOT5_R
116
M
P03_3 / PPG15_B / SCK5_R
117
M
P03_4 / RX0 / INT4
118
H
P03_5 / TX0
119
H
P03_6 / INT0 / NMI
120
Supply
Vcc
■ I/O CIRCUIT TYPE” for details on the I/O circuit types.
*: See “
12
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
 I/O CIRCUIT TYPE
Type
Circuit
Remarks
A
X1
R
0
1
FCI
X0
X out
High-speed oscillation circuit:
 Programmable between
oscillation mode (external
crystal or resonator connected
to X0/X1 pins) and Fast
external Clock Input (FCI)
mode (external clock
connected to X0 pin)
 Feedback resistor = approx.
1.0M
 The amplitude: 1.8V±0.15V
to operate by the internal
supply voltage
FCI or Osc disable
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
13
D a t a S h e e t
Type
Circuit
Remarks
B
Pull-up control
P-ch
Standby
control
for input
shutdown
P-ch
Pout
N-ch
Nout
R
Low-speed oscillation circuit
shared with GPIO functionality:
 Feedback resistor = approx.
5.0M
 GPIO functionality selectable
(CMOS level output (IOL =
4mA, IOH = -4mA),
Automotive input with input
shutdown function and
programmable pull-up
resistor)
Automotive input
X1A
R
X out
0
1
FCI
X0A
FCI or Osc disable
Pull-up control
P-ch
Standby
control
for input
shutdown
C
14
CONFIDENTIAL
P-ch
Pout
N-ch
Nout
R
Automotive input
CMOS hysteresis input pin
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
Type
Circuit
Remarks
F
Power supply input protection
circuit
P-ch
N-ch
 A/D converter ref+ (AVRH)/
ref- (AVRL) power supply
input pin with protection
circuit
 Without protection circuit
against VCC for pins
AVRH/AVRL
G
P-ch
N-ch
H
Pull-up control
P-ch
P-ch
Pout
N-ch
Nout
 CMOS level output
(IOL = 4mA, IOH = -4mA)
 Automotive input with input
shutdown function
 Programmable pull-up
resistor
R
Standby control
for input shutdown
Automotive input
I
Pull-up control
P-ch
P-ch
Pout
N-ch
Nout
 CMOS level output
(IOL = 4mA, IOH = -4mA)
 CMOS hysteresis input with
input shutdown function
 Programmable pull-up
resistor
 Analog input
R
Hysteresis input
Standby control
for input shutdown
Analog input
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
15
D a t a S h e e t
Type
Circuit
Remarks
K
Pull-up control
P-ch
P-ch
Pout
N-ch
Nout
 CMOS level output
(IOL = 4mA, IOH = -4mA)
 Automotive input with input
shutdown function
 Programmable pull-up
resistor
 Analog input
R
Automotive input
Standby control
for input shutdown
Analog input
M
Pull-up control
P-ch
P-ch
Pout
N-ch
Nout
R
 CMOS level output
(IOL = 4mA, IOH = -4mA)
 CMOS hysteresis input with
input shutdown function
 Programmable pull-up
resistor
Hysteresis input
Standby control
for input shutdown
N
Pull-up control
P-ch
R
P-ch
Pout
N-ch
Nout*
 CMOS level output
(IOL = 3mA, IOH = -3mA)
 CMOS hysteresis input with
input shutdown function
 Programmable pull-up
resistor
*: N-channel transistor has slew
rate control according to I2C
spec, irrespective of usage.
Hysteresis input
Standby control
for input shutdown
16
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
Type
Circuit
Remarks
 Open-drain I/O
 Output 25mA, Vcc = 2.7V
 TTL input
O
N-ch
Nout
R
Standby control
for input shutdown
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
TTL input
17
D a t a S h e e t
 MEMORY MAP
FF:FFFFH
USER ROM*1
DE:0000H
DD:FFFFH
Reserved
10:0000H
0F:C000H
Boot-ROM
Peripheral
0E:9000H
Reserved
01:0000H
00:8000H
RAMSTART0*2
ROM/RAM
MIRROR
Internal RAM
bank0
Reserved
00:0C00H
00:0380H
Peripheral
00:0180H
GPR*3
00:0100H
DMA
00:00F0H
Reserved
00:0000H
Peripheral
*1: For details about USER ROM area, see “USER ROM MEMORY MAP FOR FLASH DEVICES”
on the following pages.
*2: For RAMSTART addresses, see the table on the next page.
*3: Unused GPR banks can be used as RAM area.
GPR: General-Purpose Register
The DMA area is only available if the device contains the corresponding resource.
The available RAM and ROM area depends on the device.
18
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
 RAMSTART ADDRESSES
Devices
Bank 0
RAM size
RAMSTART0
MB96F653
10KB
00:5A00H
MB96F655
16KB
00:4200H
MB96F656
24KB
00:2200H
MB96F657
28KB
00:1200H
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
19
D a t a S h e e t
 USER ROM MEMORY MAP FOR FLASH DEVICES
CPU mode
address
FF:FFFFH
Flash memory
mode address
3F:FFFFH
FF:0000H
3F:0000H
FE:FFFFH
3E:FFFFH
FE:0000H
3E:0000H
FD:FFFFH
3D:FFFFH
FD:0000H
3D:0000H
FC:FFFFH
3C:FFFFH
FC:0000H
3C:0000H
FB:FFFFH
3B:FFFFH
FB:0000H
3B:0000H
FA:FFFFH
3A:FFFFH
FA:0000H
3A:0000H
MB96F653
MB96F655
MB96F656
Flash size
Flash size
Flash size
MB96F657
Flash size
64.5KB + 32KB
128.5KB + 32KB
256.5KB + 32KB
384.5KB + 32KB
SA39 - 64KB
SA39 - 64KB
SA39 - 64KB
SA39 - 64KB
SA38 - 64KB
SA38 - 64KB
SA38 - 64KB
SA37 - 64KB
SA37 - 64KB
SA36 - 64KB
SA36 - 64KB
Bank A of Flash A
SA35 - 64KB
SA34 - 64KB
F9:FFFFH
Reserved
Reserved
Reserved
Reserved
DF:A000H
DF:9FFFH
1F:9FFFH
DF:8000H
1F:8000H
DF:7FFFH
1F:7FFFH
DF:6000H
1F:6000H
DF:5FFFH
1F:5FFFH
DF:4000H
1F:4000H
DF:3FFFH
1F:3FFFH
DF:2000H
1F:2000H
DF:1FFFH
1F:1FFFH
DF:0000H
1F:0000H
DE:FFFFH
DE:0000H
SA4 - 8KB
SA4 - 8KB
SA4 - 8KB
SA3 - 8KB
SA3 - 8KB
SA3 - 8KB
SA3 - 8KB
SA2 - 8KB
SA2 - 8KB
SA2 - 8KB
SA2 - 8KB
SA1 - 8KB
SA1 - 8KB
SA1 - 8KB
SA1 - 8KB
SAS - 512B*
SAS - 512B*
SAS - 512B*
SAS - 512B*
Reserved
Reserved
Reserved
Reserved
SA4 - 8KB
Bank B of Flash A
Bank A of Flash A
*: Physical address area of SAS-512B is from DF:0000H to DF:01FFH.
Others (from DF:0200H to DF:1FFFH) is mirror area of SAS-512B.
Sector SAS contains the ROM configuration block RCBA at CPU address DF:0000 H -DF:01FFH.
2
SAS can not be used for E PROM emulation.
20
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
 SERIAL PROGRAMMING COMMUNICATION INTERFACE
USART pins for Flash serial programming (MD = 0, DEBUG I/F = 0, Serial Communication mode)
MB96650
Pin Number
USART Number
8
9
SIN0
USART0
SOT0
10
SCK0
3
SIN1
4
USART1
SOT1
5
SCK1
56
SIN2
57
USART2
SOT2
58
SCK2
101
SIN4
102
USART4
103
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
Normal Function
SOT4
SCK4
21
D a t a S h e e t
 INTERRUPT VECTOR TABLE
Vector
number
Offset in
vector table
Vector name
Cleared by
DMA
Index in
ICR to
program
Description
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
3FCH
3F8H
3F4H
3F0H
3ECH
3E8H
3E4H
3E0H
3DCH
3D8H
3D4H
3D0H
3CCH
3C8H
3C4H
3C0H
3BCH
3B8H
3B4H
3B0H
3ACH
3A8H
3A4H
3A0H
39CH
398H
394H
390H
38CH
388H
384H
380H
37CH
378H
374H
370H
36CH
368H
364H
360H
35CH
CALLV0
CALLV1
CALLV2
CALLV3
CALLV4
CALLV5
CALLV6
CALLV7
RESET
INT9
EXCEPTION
NMI
DLY
RC_TIMER
MC_TIMER
SC_TIMER
LVDI
EXTINT0
EXTINT1
EXTINT2
EXTINT3
EXTINT4
EXTINT5
EXTINT6
EXTINT7
EXTINT8
EXTINT9
EXTINT10
EXTINT11
EXTINT12
EXTINT13
EXTINT14
EXTINT15
CAN0
PPG0
PPG1
PPG2
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
No
Yes
Yes
Yes
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
CALLV instruction
CALLV instruction
CALLV instruction
CALLV instruction
CALLV instruction
CALLV instruction
CALLV instruction
CALLV instruction
Reset vector
INT9 instruction
Undefined instruction execution
Non-Maskable Interrupt
Delayed Interrupt
RC Clock Timer
Main Clock Timer
Sub Clock Timer
Low Voltage Detector
External Interrupt 0
External Interrupt 1
External Interrupt 2
External Interrupt 3
External Interrupt 4
External Interrupt 5
External Interrupt 6
External Interrupt 7
External Interrupt 8
External Interrupt 9
External Interrupt 10
External Interrupt 11
External Interrupt 12
External Interrupt 13
External Interrupt 14
External Interrupt 15
CAN Controller 0
Reserved
Reserved
Reserved
Reserved
Programmable Pulse Generator 0
Programmable Pulse Generator 1
Programmable Pulse Generator 2
22
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
Vector
number
Offset in
vector table
Vector name
Cleared by
DMA
Index in
ICR to
program
Description
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
358H
354H
350H
34CH
348H
344H
340H
33CH
338H
334H
330H
32CH
328H
324H
320H
31CH
318H
314H
310H
30CH
308H
304H
300H
2FCH
2F8H
2F4H
2F0H
2ECH
2E8H
2E4H
2E0H
2DCH
2D8H
2D4H
2D0H
2CCH
2C8H
2C4H
2C0H
2BCH
PPG3
PPG4
PPG5
PPG6
PPG7
PPG8
PPG9
PPG10
PPG11
PPG12
PPG13
PPG14
PPG15
RLT0
RLT1
RLT2
RLT3
RLT6
ICU0
ICU1
ICU4
ICU5
ICU6
ICU7
ICU9
OCU0
OCU1
OCU2
OCU3
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Programmable Pulse Generator 3
Programmable Pulse Generator 4
Programmable Pulse Generator 5
Programmable Pulse Generator 6
Programmable Pulse Generator 7
Programmable Pulse Generator 8
Programmable Pulse Generator 9
Programmable Pulse Generator 10
Programmable Pulse Generator 11
Programmable Pulse Generator 12
Programmable Pulse Generator 13
Programmable Pulse Generator 14
Programmable Pulse Generator 15
Reserved
Reserved
Reserved
Reserved
Reload Timer 0
Reload Timer 1
Reload Timer 2
Reload Timer 3
Reserved
Reserved
Reload Timer 6
Input Capture Unit 0
Input Capture Unit 1
Reserved
Reserved
Input Capture Unit 4
Input Capture Unit 5
Input Capture Unit 6
Input Capture Unit 7
Reserved
Input Capture Unit 9
Reserved
Reserved
Output Compare Unit 0
Output Compare Unit 1
Output Compare Unit 2
Output Compare Unit 3
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
23
D a t a S h e e t
Vector
number
Offset in
vector table
Vector name
Cleared by
DMA
Index in
ICR to
program
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
2B8H
2B4H
2B0H
2ACH
2A8H
2A4H
2A0H
29CH
298H
294H
290H
28CH
288H
284H
280H
27CH
278H
274H
270H
26CH
268H
264H
260H
25CH
258H
254H
250H
24CH
248H
244H
240H
23CH
238H
234H
230H
22CH
228H
224H
220H
21CH
OCU4
OCU6
OCU7
FRT0
FRT1
FRT2
RTC0
CAL0
IIC0
IIC1
ADC0
LINR0
LINT0
LINR1
LINT1
LINR2
LINT2
LINR4
LINT4
LINR5
LINT5
LINR7
LINT7
-
Yes
Yes
Yes
Yes
Yes
Yes
No
No
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
-
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
24
CONFIDENTIAL
Description
Output Compare Unit 4
Reserved
Output Compare Unit 6
Output Compare Unit 7
Reserved
Reserved
Reserved
Reserved
Free-Running Timer 0
Free-Running Timer 1
Free-Running Timer 2
Reserved
Real Time Clock
Clock Calibration Unit
Reserved
I2C interface 0
I2C interface 1
A/D Converter 0
Reserved
Reserved
LIN USART 0 RX
LIN USART 0 TX
LIN USART 1 RX
LIN USART 1 TX
LIN USART 2 RX
LIN USART 2 TX
Reserved
Reserved
LIN USART 4 RX
LIN USART 4 TX
LIN USART 5 RX
LIN USART 5 TX
Reserved
Reserved
LIN USART 7 RX
LIN USART 7 TX
Reserved
Reserved
Reserved
Reserved
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
Vector
number
Offset in
vector table
Vector name
Cleared by
DMA
Index in
ICR to
program
Description
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
218H
214H
210H
20CH
208H
204H
200H
1FCH
1F8H
1F4H
1F0H
1ECH
1E8H
1E4H
1E0H
1DCH
1D8H
1D4H
1D0H
1CCH
1C8H
1C4H
1C0H
FLASHA
QPRC0
QPRC1
ADCRC0
-
Yes
Yes
Yes
No
-
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Flash memory A interrupt
Reserved
Reserved
Reserved
Quad Position/Revolution counter 0
Quad Position/Revolution counter 1
A/D Converter 0 - Range Comparator
Reserved
Reserved
Reserved
Reserved
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
25
D a t a S h e e t
 HANDLING PRECAUTIONS
Any semiconductor devices have inherently a certain rate of failure. The possibility of failure is greatly
affected by the conditions in which they are used (circuit conditions, environmental conditions, etc.). This
page describes precautions that must be observed to minimize the chance of failure and to obtain higher
reliability from your Spansion semiconductor devices.
1. Precautions for Product Design
This section describes precautions when designing electronic equipment using semiconductor devices.
 Absolute Maximum Ratings
Semiconductor devices can be permanently damaged by application of stress (voltage, current, temperature,
etc.) in excess of certain established limits, called absolute maximum ratings. Do not exceed these ratings.
 Recommended Operating Conditions
Recommended operating conditions are normal operating ranges for the semiconductor device. All the
device's electrical characteristics are warranted when operated within these ranges.
Always use semiconductor devices within the recommended operating conditions. 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 sales
representative beforehand.
 Processing and Protection of Pins
These precautions must be followed when handling the pins which connect semiconductor devices to power
supply and input/output functions.
(1) Preventing Over-Voltage and Over-Current Conditions
Exposure to voltage or current levels in excess of maximum ratings at any pin is likely to cause
deterioration within the device, and in extreme cases leads to permanent damage of the device. Try to
prevent such overvoltage or over-current conditions at the design stage.
(2) Protection of Output Pins
Shorting of output pins to supply pins or other output pins, or connection to large capacitance can
cause large current flows. Such conditions if present for extended periods of time can damage the
device.
Therefore, avoid this type of connection.
(3) Handling of Unused Input Pins
Unconnected input pins with very high impedance levels can adversely affect stability of operation.
Such pins should be connected through an appropriate resistance to a power supply pin or ground pin.
 Latch-up
Semiconductor devices are constructed by the formation of P-type and N-type areas on a substrate. When
subjected to abnormally high voltages, internal parasitic PNPN junctions (called thyristor structures) may
be formed, causing large current levels in excess of several hundred mA to flow continuously at the power
supply pin. This condition is called latch-up.
CAUTION: The occurrence of latch-up not only causes loss of reliability in the semiconductor device, but
can cause injury or damage from high heat, smoke or flame. To prevent this from happening, do the
following:
(1) Be sure that voltages applied to pins do not exceed the absolute maximum ratings. This should
include attention to abnormal noise, surge levels, etc.
(2) Be sure that abnormal current flows do not occur during the power-on sequence.
Code: DS00-00004-3E
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 Observance of Safety Regulations and Standards
Most countries in the world have established standards and regulations regarding safety, protection from
electromagnetic interference, etc. Customers are requested to observe applicable regulations and standards
in the design of products.
 Fail-Safe Design
Any semiconductor devices have inherently a certain rate of failure. You must protect against injury,
damage or loss from such failures by incorporating safety design measures into your facility and equipment
such as redundancy, fire protection, and prevention of over-current levels and other abnormal operating
conditions.
 Precautions Related to Usage of Devices
Spansion semiconductor devices are intended for use in standard applications (computers, office automation
and other office equipment, industrial, communications, and measurement equipment, personal or
household devices, etc.).
CAUTION: Customers considering the use of our products in special applications where failure or
abnormal operation may directly affect human lives or cause physical injury or property damage, or where
extremely high levels of reliability are demanded (such as aerospace systems, atomic energy controls, sea
floor repeaters, vehicle operating controls, medical devices for life support, etc.) are requested to consult
with sales representatives before such use. The company will not be responsible for damages arising from
such use without prior approval.
2. Precautions for Package Mounting
Package mounting may be either lead insertion type or surface mount type. In either case, for heat
resistance during soldering, you should only mount under Spansion's recommended conditions. For detailed
information about mount conditions, contact your sales representative.
 Lead Insertion Type
Mounting of lead insertion type packages onto printed circuit boards may be done by two methods: direct
soldering on the board, or mounting by using a socket.
Direct mounting onto boards normally involves processes for inserting leads into through-holes on the
board and using the flow soldering (wave soldering) method of applying liquid solder. In this case, the
soldering process usually causes leads to be subjected to thermal stress in excess of the absolute ratings for
storage temperature. Mounting processes should conform to Spansion recommended mounting conditions.
If socket mounting is used, differences in surface treatment of the socket contacts and IC lead surfaces can
lead to contact deterioration after long periods. For this reason it is recommended that the surface treatment
of socket contacts and IC leads be verified before mounting.
 Surface Mount Type
Surface mount packaging has longer and thinner leads than lead-insertion packaging, and therefore leads
are more easily deformed or bent. The use of packages with higher pin counts and narrower pin pitch results
in increased susceptibility to open connections caused by deformed pins, or shorting due to solder bridges.
You must use appropriate mounting techniques. Spansion recommends the solder reflow method, and has
established a ranking of mounting conditions for each product. Users are advised to mount packages in
accordance with Spansion ranking of recommended conditions.
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 Lead-Free Packaging
CAUTION: When ball grid array (BGA) packages with Sn-Ag-Cu balls are mounted using Sn-Pb eutectic
soldering, junction strength may be reduced under some conditions of use.
 Storage of Semiconductor Devices
Because plastic chip packages are formed from plastic resins, exposure to natural environmental conditions
will cause absorption of moisture. During mounting, the application of heat to a package that has absorbed
moisture can cause surfaces to peel, reducing moisture resistance and causing packages to crack. To prevent,
do the following:
(1) Avoid exposure to rapid temperature changes, which cause moisture to condense inside the product.
Store products in locations where temperature changes are slight.
(2) Use dry boxes for product storage. Products should be stored below 70% relative humidity, and at
temperatures between 5°C and 30°C.
When you open Dry Package that recommends humidity 40% to 70% relative humidity.
(3) When necessary, Spansion packages semiconductor devices in highly moisture-resistant aluminum
laminate bags, with a silica gel desiccant. Devices should be sealed in their aluminum laminate bags
for storage.
(4) Avoid storing packages where they are exposed to corrosive gases or high levels of dust.
 Baking
Packages that have absorbed moisture may be de-moisturized by baking (heat drying). Follow the Spansion
recommended conditions for baking.
Condition: 125°C/24 h
 Static Electricity
Because semiconductor devices are particularly susceptible to damage by static electricity, you must take
the following precautions:
(1) Maintain relative humidity in the working environment between 40% and 70%. Use of an apparatus
for ion generation may be needed to remove electricity.
(2) Electrically ground all conveyors, solder vessels, soldering irons and peripheral equipment.
(3) Eliminate static body electricity by the use of rings or bracelets connected to ground through high
resistance (on the level of 1 MΩ).
Wearing of conductive clothing and shoes, use of conductive floor mats and other measures to
minimize shock loads is recommended.
(4) Ground all fixtures and instruments, or protect with anti-static measures.
(5) Avoid the use of styrofoam or other highly static-prone materials for storage of completed board
assemblies.
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3. Precautions for Use Environment
Reliability of semiconductor devices depends on ambient temperature and other conditions as described
above.
For reliable performance, do the following:
(1) Humidity
Prolonged use in high humidity can lead to leakage in devices as well as printed circuit boards. If high
humidity levels are anticipated, consider anti-humidity processing.
(2) Discharge of Static Electricity
When high-voltage charges exist close to semiconductor devices, discharges can cause abnormal
operation. In such cases, use anti-static measures or processing to prevent discharges.
(3) Corrosive Gases, Dust, or Oil
Exposure to corrosive gases or contact with dust or oil may lead to chemical reactions that will
adversely affect the device. If you use devices in such conditions, consider ways to prevent such
exposure or to protect the devices.
(4) Radiation, Including Cosmic Radiation
Most devices are not designed for environments involving exposure to radiation or cosmic radiation.
Users should provide shielding as appropriate.
(5) Smoke, Flame
CAUTION: Plastic molded devices are flammable, and therefore should not be used near combustible
substances. If devices begin to smoke or burn, there is danger of the release of toxic gases.
Customers considering the use of Spansion products in other special environmental conditions should
consult with sales representatives.
Please check the latest handling precautions at the following URL.
http://www.spansion.com/fjdocuments/fj/datasheet/e-ds/DS00-00004.pdf
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 HANDLING DEVICES
Special care is required for the following when handling the device:
• Latch-up prevention
• Unused pins handling
• External clock usage
• Notes on PLL clock mode operation
• Power supply pins (Vcc/Vss)
• Crystal oscillator and ceramic resonator circuit
• Turn on sequence of power supply to A/D converter and analog inputs
• Pin handling when not using the A/D converter
• Notes on Power-on
• Stabilization of power supply voltage
• Serial communication
• Mode Pin (MD)
1. Latch-up prevention
CMOS IC chips may suffer latch-up under the following conditions:
- A voltage higher than VCC or lower than VSS is applied to an input or output pin.
- A voltage higher than the rated voltage is applied between Vcc pins and Vss pins.
- The AVCC power supply is applied before the VCC voltage.
Latch-up may increase the power supply current dramatically, causing thermal damages to the device.
For the same reason, extra care is required to not let the analog power-supply voltage (AVCC, AVRH) exceed
the digital power-supply voltage.
2. Unused pins handling
Unused input pins can be left open when the input is disabled (corresponding bit of Port Input Enable register
PIER = 0).
Leaving unused input pins open when the input is enabled may result in misbehavior and possible permanent
damage of the device. To prevent latch-up, they must therefore be pulled up or pulled down through resistors
which should be more than 2k.
Unused bidirectional pins can be set either to the output state and be then left open, or to the input state with
either input disabled or external pull-up/pull-down resistor as described above.
3. External clock usage
The permitted frequency range of an external clock depends on the oscillator type and configuration.
See AC Characteristics for detailed modes and frequency limits. Single and opposite phase external clocks must
be connected as follows:
(1) Single phase external clock for Main oscillator
When using a single phase external clock for the Main oscillator, X0 pin must be driven and X1 pin left open.
And supply 1.8V power to the external clock.
X0
X1
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(2) Single phase external clock for Sub oscillator
When using a single phase external clock for the Sub oscillator, “External clock mode” must be selected and
X0A/P04_0 pin must be driven. X1A/P04_1 pin can be configured as GPIO.
(3) Opposite phase external clock
When using an opposite phase external clock, X1 (X1A) pins must be supplied with a clock signal which has
the opposite phase to the X0 (X0A) pins. Supply level on X0 and X1 pins must be 1.8V.
X0
X1
4. Notes on PLL clock mode operation
If the microcontroller is operated with PLL clock mode and no external oscillator is operating or no external
clock is supplied, the microcontroller attempts to work with the free oscillating PLL. Performance of this
operation, however, cannot be guaranteed.
5. Power supply pins (Vcc/Vss)
It is required that all VCC-level as well as all VSS-level power supply pins are at the same potential. If there is
more than one VCC or VSS level, the device may operate incorrectly or be damaged even within the guaranteed
operating range.
Vcc and Vss pins must be connected to the device from the power supply with lowest possible impedance.
The smoothing capacitor at Vcc pin must use the one of a capacity value that is larger than Cs.
Besides this, as a measure against power supply noise, it is required to connect a bypass capacitor of about 0.1F
between Vcc and Vss pins as close as possible to Vcc and Vss pins.
6. Crystal oscillator and ceramic resonator circuit
Noise at X0, X1 pins or X0A, X1A pins might cause abnormal operation. It is required to provide bypass
capacitors with shortest possible distance to X0, X1 pins and X0A, X1A pins, crystal oscillator (or ceramic
resonator) and ground lines, and, to the utmost effort, that the lines of oscillation circuit do not cross the lines of
other circuits.
It is highly recommended to provide a printed circuit board art work surrounding X0, X1 pins and X0A, X1A
pins with a ground area for stabilizing the operation.
It is highly recommended to evaluate the quartz/MCU or resonator/MCU system at the quartz or resonator
manufacturer, especially when using low-Q resonators at higher frequencies.
7. Turn on sequence of power supply to A/D converter and analog inputs
It is required to turn the A/D converter power supply (AV CC, AVRH, AVRL) and analog inputs (ANn) on after
turning the digital power supply (VCC) on.
It is also required to turn the digital power off after turning the A/D converter supply and analog inputs off. In
this case, AVRH must not exceed AVCC . Input voltage for ports shared with analog input ports also must not
exceed AVCC (turning the analog and digital power supplies simultaneously on or off is acceptable).
8. Pin handling when not using the A/D converter
If the A/D converter is not used, the power supply pins for A/D converter should be connected such as AV CC =
VCC, AVSS = AVRH =AVRL = VSS.
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9. Notes on Power-on
To prevent malfunction of the internal voltage regulator, supply voltage profile while turning the power supply
on should be slower than 50s from 0.2V to 2.7V.
10. Stabilization of power supply voltage
If the power supply voltage varies acutely even within the operation safety range of the VCC power supply
voltage, a malfunction may occur. The VCC power supply voltage must therefore be stabilized. As stabilization
guidelines, the power supply voltage must be stabilized in such a way that VCC ripple fluctuations (peak to peak
value) in the commercial frequencies (50Hz to 60Hz) fall within 10% of the standard VCC power supply voltage
and the transient fluctuation rate becomes 0.1V/s or less in instantaneous fluctuation for power supply
switching.
11. Serial communication
There is a possibility to receive wrong data due to noise or other causes on the serial communication.
Therefore, design a printed circuit board so as to avoid noise.
Consider receiving of wrong data when designing the system. For example apply a checksum and retransmit
the data if an error occurs.
12. Mode Pin (MD)
Connect the mode pin directly to Vcc or Vss pin. To prevent the device unintentionally entering test mode due to
noise, lay out the printed circuit board so as to minimize the distance from the mode pin to Vcc or Vss pin and
provide a low-impedance connection.
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 ELECTRICAL CHARACTERISTICS
1.
Absolute Maximum Ratings
Parameter
Power supply
voltage*1
Analog power
supply voltage*1
Analog reference
voltage*1
Rating
Min
Max
Symbol
Condition
VCC
-
VSS - 0.3
VSS + 6.0
V
AVCC
-
VSS - 0.3
VSS + 6.0
V
AVRH,
AVRL
-
VSS - 0.3
VSS + 6.0
Unit
V
Remarks
VCC = AVCC*2
AVCC≥ AVRH,
AVCC ≥ AVRL,
AVRH > AVRL,
AVRL ≥ AVSS
VI ≤ VCC + 0.3V*3
VO ≤ VCC + 0.3V*3
Applicable to general
purpose I/O pins *4
Applicable to general
purpose I/O pins *4
Input voltage*1
VI
VSS - 0.3
VSS + 6.0
V
Output voltage*1
VO
VSS - 0.3
VSS + 6.0
V
Maximum Clamp
ICLAMP
-4.0
+4.0
mA
Current
Total Maximum
Σ|ICLAMP|
33
mA
Clamp Current
"L" level maximum
IOL
15
mA
output current
"L" level average
IOLAV
4
mA
output current
"L" level maximum
overall output
ΣIOL
82
mA
current
"L" level average
overall output
ΣIOLAV
41
mA
current
"H" level maximum
IOH
-15
mA
output current
"H" level average
IOHAV
-4
mA
output current
"H" level maximum
overall output
-82
mA
ΣIOH
current
"H" level average
overall output
-41
mA
ΣIOHAV
current
Power
PD
TA= +125°C
446*6
mW
consumption*5
Operating ambient
TA
-40
+125*7
°C
temperature
Storage temperature
TSTG
-55
+150
°C
*1: This parameter is based on VSS = AVSS = 0V.
*2: AVCC and VCC must be set to the same voltage. It is required that AVCC does not exceed VCC and that the
voltage at the analog inputs does not exceed AVCC when the power is switched on.
*3: VI and VO should not exceed VCC + 0.3V. VI should also not exceed the specified ratings. However if the
maximum current to/from an input is limited by some means with external components, the ICLAMP rating
supersedes the VI rating. Input/Output voltages of standard ports depend on VCC.
*4: • Applicable to all general purpose I/O pins (Pnn_m).
• 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.
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D a t a S h e e t
• 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 0V), 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 reset.
• The DEBUG I/F pin has only a protective diode against VSS. Hence it is only permitted to input a negative
clamping current (4mA). For protection against positive input voltages, use an external clamping diode
which limits the input voltage to maximum 6.0V.
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• Sample recommended circuits:
Protective diode
VCC
Limiting
resistance
P-ch
+B input (0V to 16V)
N-ch
R
*5: The maximum permitted power dissipation depends on the ambient temperature, the air flow velocity and the
thermal conductance of the package on the PCB.
The actual power dissipation depends on the customer application and can be calculated as follows:
PD = PIO + PINT
PIO = Σ (VOL  IOL + VOH  IOH) (I/O load power dissipation, sum is performed on all I/O ports)
PINT = VCC  (ICC + IA) (internal power dissipation)
ICC is the total core current consumption into VCC as described in the “DC characteristics” and depends on the
selected operation mode and clock frequency and the usage of functions like Flash programming.
IA is the analog current consumption into AVCC.
*6: Worst case value for a package mounted on single layer PCB at specified T A without air flow.
*7: Write/erase to a large sector in flash memory is warranted with TA ≤ + 105°C.
<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.
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D a t a S h e e t
2.
Recommended Operating Conditions
(VSS = AVSS = 0V)
Parameter
Power supply
voltage
Smoothing
capacitor at C pin
Min
Value
Typ
Max
VCC, AVCC
2.7
2.0
-
5.5
5.5
V
V
CS
0.5
1.0 to 3.9
4.7
F
Symbol
Unit
Remarks
Maintains RAM data in stop mode
1.0F (Allowance within ± 50%)
3.9µF (Allowance within ± 20%)
Please use the ceramic capacitor or the
capacitor of the frequency response of
this level.
The smoothing capacitor at VCC must
use the one of a capacity value that is
larger than 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 representatives beforehand.
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3.
DC Characteristics
(1) Current Rating
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Pin
name
Conditions
PLL Run mode with
CLKS1/2 = CLKB =
CLKP1/2 = 32MHz
ICCPLL
Flash 0 wait
(CLKRC and CLKSC
stopped)
Main Run mode with
CLKS1/2 = CLKB =
CLKP1/2 = 4MHz
ICCMAIN
Flash 0 wait
(CLKPLL, CLKSC and
CLKRC stopped)
Power supply
current in Run
modes*1
RC Run mode with
CLKS1/2 = CLKB =
CLKP1/2 = CLKRC =
2MHz
ICCRCH
Vcc
Min
Value
Typ Max
Unit
Remarks
-
27
-
mA
TA = +25°C
-
-
37
mA
TA = +105°C
-
-
38.5
mA
TA = +125°C
-
3.5
-
mA
TA = +25°C
-
-
8
mA
TA = +105°C
-
-
9.5
mA
TA = +125°C
-
1.8
-
mA
TA = +25°C
-
-
6
mA
TA = +105°C
-
-
7.5
mA
TA = +125°C
-
0.16
-
mA
TA = +25°C
-
-
3.5
mA
TA = +105°C
-
-
5
mA
TA = +125°C
-
0.1
-
mA
TA = +25°C
-
-
3.3
mA
TA = +105°C
-
-
4.8
mA
TA = +125°C
Flash 0 wait
(CLKMC, CLKPLL and
CLKSC stopped)
RC Run mode with
CLKS1/2 = CLKB =
CLKP1/2 = CLKRC =
100kHz
ICCRCL
Flash 0 wait
(CLKMC, CLKPLL and
CLKSC stopped)
Sub Run mode with
CLKS1/2 = CLKB =
CLKP1/2 = 32kHz
ICCSUB
Flash 0 wait
(CLKMC, CLKPLL and
CLKRC stopped)
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D a t a S h e e t
Parameter
Symbol
Pin
name
ICCSPLL
ICCSMAIN
Power supply
current in
Sleep modes*1
ICCSRCH
ICCSRCL
ICCSSUB
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CONFIDENTIAL
Vcc
Conditions
Min
Value
Typ Max
Unit
Remarks
PLL Sleep mode with
CLKS1/2 = CLKP1/2 =
32MHz
(CLKRC and CLKSC
stopped)
-
8.5
-
mA
TA = +25°C
-
-
14
mA
TA = +105°C
-
-
15.5
mA
TA = +125°C
Main Sleep mode with
CLKS1/2 = CLKP1/2 =
4MHz,
SMCR:LPMSS = 0
(CLKPLL, CLKRC
and CLKSC stopped)
-
1
-
mA
TA = +25°C
-
-
4.5
mA
TA = +105°C
-
-
6
mA
TA = +125°C
RC Sleep mode with
CLKS1/2 = CLKP1/2 =
CLKRC = 2MHz,
SMCR:LPMSS = 0
(CLKMC, CLKPLL
and CLKSC stopped)
-
0.6
-
mA
TA = +25°C
-
-
3.8
mA
TA = +105°C
-
-
5.3
mA
TA = +125°C
RC Sleep mode with
CLKS1/2 = CLKP1/2 =
CLKRC = 100kHz
(CLKMC, CLKPLL
and CLKSC stopped)
-
0.07
-
mA
TA = +25°C
-
-
2.8
mA
TA = +105°C
-
-
4.3
mA
TA = +125°C
Sub Sleep mode with
CLKS1/2 = CLKP1/2 =
32kHz,
(CLKMC, CLKPLL
and CLKRC stopped)
-
0.04
-
mA
TA = +25°C
-
-
2.5
mA
TA = +105°C
-
-
4
mA
TA = +125°C
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D a t a S h e e t
Parameter Symbol
Pin
name
ICCTMAIN
ICCTRCH
ICCTRCL
ICCTSUB
Vcc
Value
Typ Max
Unit
Remarks
1800
2250
A
TA = +25°C
-
-
3220
A
TA = +105°C
-
-
4205
A
TA = +125°C
Main Timer mode with
CLKMC = 4MHz,
SMCR:LPMSS = 0
(CLKPLL, CLKRC and
CLKSC stopped)
RC Timer mode with
CLKRC = 2MHz,
SMCR:LPMSS = 0
(CLKPLL, CLKMC and
CLKSC stopped)
-
285
330
A
TA = +25°C
-
-
1195
A
TA = +105°C
-
-
2165
A
TA = +125°C
-
160
215
A
TA = +25°C
-
-
1095
A
TA = +105°C
-
-
2075
A
TA = +125°C
RC Timer mode with
CLKRC = 100kHz
(CLKPLL, CLKMC and
CLKSC stopped)
-
35
75
A
TA = +25°C
-
-
905
A
TA = +105°C
-
-
1880
A
TA = +125°C
Sub Timer mode with
CLKSC = 32kHz
(CLKMC, CLKPLL and
CLKRC stopped)
-
25
65
A
TA = +25°C
-
-
885
A
TA = +105°C
-
-
1850
A
TA = +125°C
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Min
-
PLL Timer mode with
CLKPLL = 32MHz (CLKRC
and CLKSC stopped)
ICCTPLL
Power
supply
current in
Timer
modes*2
Conditions
39
D a t a S h e e t
Parameter
Power supply
current in Stop
mode*3
Flash Power
Down current
Power supply
current
for active Low
Voltage
detector*4
Flash Write/
Erase current*5
Symbol
Pin
name
ICCH
Conditions
-
ICCFLASHPD
-
Min
Value
Typ Max
Unit
Remarks
-
20
60
A
TA = +25°C
-
-
880
A
TA = +105°C
-
-
1845
A TA = +125°C
-
36
70
-
5
-
A TA = +25°C
-
-
12.5
A TA = +125°C
-
12.5
-
mA TA = +25°C
-
-
20
mA TA = +125°C
A
Vcc
ICCLVD
ICCFLASH
Low voltage
detector enabled
-
*1: The power supply current is measured with a 4MHz external clock connected to the Main oscillator and
a 32kHz external clock connected to the Sub oscillator. See chapter “Standby mode and voltage regulator
control circuit” of the Hardware Manual for further details about voltage regulator control. Current for "On
Chip Debugger" part is not included. Power supply current in Run mode does not include Flash Write / Erase
current.
*2: The power supply current in Timer mode is the value when Flash is in Power-down / reset mode.
When Flash is not in Power-down / reset mode, ICCFLASHPD must be added to the Power supply current.
The power supply current is measured with a 4MHz external clock connected to the Main oscillator and a
32kHz external clock connected to the Sub oscillator. The current for "On Chip Debugger" part is not
included.
*3: The power supply current in Stop mode is the value when Flash is in Power-down / reset mode.
When Flash is not in Power-down / reset mode, ICCFLASHPD must be added to the Power supply current.
*4: When low voltage detector is enabled, ICCLVD must be added to Power supply current.
*5: When Flash Write / Erase program is executed, ICCFLASH must be added to Power supply current.
40
CONFIDENTIAL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
(2) Pin Characteristics
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Pin
Parameter Symbol
name
VIH
"H" level
input
voltage
"L" level
input
voltage
Conditions
-
Port inputs
Pnn_m
External clock in
"Fast Clock Input mode"
External clock in
"Oscillation mode"
VIHX0S
X0
VIHX0AS
X0A
VIHR
RSTX
-
VIHM
MD
-
VIHD
DEBUG
I/F
-
VIL
Port
inputs
Pnn_m
External clock in "Fast
Clock Input mode"
External clock in
"Oscillation mode"
VILX0S
X0
VILX0AS
X0A
VILR
RSTX
-
VILM
MD
-
VILD
DEBUG
I/F
-
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
Value
Unit
Min Typ Max
VCC
 0.7
VCC
 0.8
VD
 0.8
VCC
 0.8
VCC
 0.8
VCC
- 0.3
2.0
VSS
- 0.3
VSS
- 0.3
VSS
VSS
- 0.3
VSS
- 0.3
VSS
- 0.3
VSS
- 0.3
-
VCC
+ 0.3
VCC
+ 0.3
VD
VCC
+ 0.3
VCC
+ 0.3
VCC
+ 0.3
VCC
+ 0.3
VCC
 0.3
VCC
 0.5
VD
 0.2
VCC
 0.2
VCC
 0.2
VSS
+ 0.3
0.8
V
V
V
Remarks
CMOS Hysteresis
input
AUTOMOTIVE
Hysteresis input
VD=1.8V±0.15V
V
V
V
V
V
V
V
CMOS Hysteresis
input
CMOS Hysteresis
input
TTL Input
CMOS Hysteresis
input
AUTOMOTIVE
Hysteresis input
VD=1.8V±0.15V
V
V
V
V
CMOS Hysteresis
input
CMOS Hysteresis
input
TTL Input
41
D a t a S h e e t
Parameter Symbol
VOH4
4mA
type
VOH3
3mA
type
VOL4
4mA
type
"H" level
output
voltage
"L" level
output
voltage
Pin
name
VOL3
VOLD
3mA
type
DEBUG
I/F
Conditions
4.5V ≤ VCC ≤ 5.5V
IOH = -4mA
2.7V ≤ VCC < 4.5V
IOH = -1.5mA
4.5V ≤ VCC ≤ 5.5V
IOH = -3mA
2.7V ≤ VCC < 4.5V
IOH = -1.5mA
4.5V ≤ VCC ≤ 5.5V
IOL = +4mA
2.7V ≤ VCC < 4.5V
IOL = +1.7mA
2.7V ≤ VCC < 5.5V
IOL = +3mA
VCC = 2.7V
IOL = +25mA
VSS < VI < VCC
AVSS, AVRL < VI <
AVCC, AVRH
Min
Value
Typ Max
Unit
VCC
- 0.5
-
VCC
V
VCC
- 0.5
-
VCC
V
-
-
0.4
V
-
-
0.4
V
0
-
0.25
V
-1
-
+1
A
Input leak
current
IIL
Pnn_m
Pull-up
resistance
value
RPU
Pnn_m
VCC = 5.0V ±10%
25
50
100
k
CIN
Other than
C,
Vcc,
Vss,
AVcc,
AVss,
AVRH,
AVRL
-
-
5
15
pF
Input
capacitance
42
CONFIDENTIAL
Remarks
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
4.
AC Characteristics
(1) Main Clock Input Characteristics
(VCC = AVCC = 2.7V to 5.5V, VD=1.8V±0.15V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Input frequency
Input frequency
Symbol
Pin
name
fC
fFCI
X0,
X1
Min
Value
Typ
Max
4
-
8
MHz
-
-
8
MHz
4
-
8
MHz
-
-
8
MHz
4
-
8
MHz
Unit
X0
Input clock cycle
tCYLH
-
125
-
-
ns
Input clock pulse
width
PWH,
PWL
-
55
-
-
ns
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
Remarks
When using a crystal
oscillator, PLL off
When using an opposite
phase external
clock, PLL off
When using a crystal
oscillator or opposite
phase external clock,
PLL on
When using a single
phase external
clock in “Fast Clock
Input mode”, PLL off
When using a single
phase external
clock in “Fast Clock
Input mode”, PLL on
43
D a t a S h e e t
(2) Sub Clock Input Characteristics
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Min
Value
Typ
Max
-
-
32.768
-
kHz
-
-
-
100
kHz
X0A
-
-
-
50
kHz
Pin
Conditions
name
X0A,
X1A
Input frequency
fCL
Unit
Input clock cycle
tCYLL
-
-
10
-
-
s
Input clock pulse
width
-
-
PWH/tCYLL,
PWL/tCYLL
30
-
70
%
44
CONFIDENTIAL
Remarks
When using an
oscillation circuit
When using an
opposite phase
external clock
When using a
single phase
external clock
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
(3) Built-in RC Oscillation Characteristics
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Clock frequency
Min
Value
Typ
Max
50
100
200
kHz
1
2
4
MHz
80
160
320
s
64
128
256
s
Unit
fRC
RC clock stabilization
time
tRCSTAB
Remarks
When using slow frequency of
RC oscillator
When using fast frequency of
RC oscillator
When using slow frequency of
RC oscillator
(16 RC clock cycles)
When using fast frequency of
RC oscillator
(256 RC clock cycles)
(4) Internal Clock Timing
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Value
Min
Max
Unit
Internal System clock frequency
(CLKS1 and CLKS2)
fCLKS1, fCLKS2
-
54
MHz
Internal CPU clock frequency (CLKB),
Internal peripheral clock frequency (CLKP1)
fCLKB, fCLKP1
-
32
MHz
Internal peripheral clock frequency (CLKP2)
fCLKP2
-
32
MHz
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
45
D a t a S h e e t
(5) Operating Conditions of PLL
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Value
Min Typ Max
Unit
PLL oscillation stabilization wait time
tLOCK
1
-
4
ms
PLL input clock frequency
fPLLI
4
-
8
MHz
PLL oscillation clock frequency
fCLKVCO
56
-
108
MHz
PLL phase jitter
tPSKEW
-5
-
+5
ns
Remarks
For CLKMC = 4MHz
Permitted VCO output
frequency of PLL
(CLKVCO)
For CLKMC (PLL input
clock) ≥ 4MHz
(6) Reset Input
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Pin name
tRSTL
RSTX
Value
Reset input time
Rejection of reset input time
Unit
Min
Max
10
-
s
1
-
s
tRSTL
RSTX
0.2VCC
46
CONFIDENTIAL
0.2VCC
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
(7) Power-on Reset Timing
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Power on rise time
Power off time
Symbol
Pin name
tR
tOFF
Vcc
Vcc
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
Min
Value
Typ
Max
0.05
1
-
30
-
Unit
ms
ms
47
D a t a S h e e t
(8) USART Timing
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C, CL=50pF)
Parameter
Symbol
4.5V  VCC 5.5V
Pin
Conditions
Min
Max
name
Serial clock cycle time
tSCYC
SCKn
SCKn,
SOTn
SCKn,
Internal shift
SOTn
clock mode
SCKn,
SINn
SCKn,
SINn
SCK   SOT delay time
tSLOVI
SOT  SCK  delay time
tOVSHI
SIN  SCK  setup time
tIVSHI
SCK   SIN hold time
tSHIXI
Serial clock "L" pulse width
tSLSH
SCKn
Serial clock "H" pulse width
tSHSL
SCKn
2.7V  VCC  4.5V
Min
Max
Unit
4tCLKP1
-
4tCLKP1
-
ns
- 20
+ 20
- 30
+ 30
ns
-
ns
-
ns
-
ns
-
ns
-
ns
NtCLKP1
– 20*
tCLKP1
+ 45
0
-
tCLKP1
+ 10
tCLKP1
+ 10
-
NtCLKP1
– 30*
tCLKP1
+ 55
0
tCLKP1
+ 10
tCLKP1
+ 10
SCKn,
2tCLKP1
2tCLKP1
ns
SOTn External shift
+ 45
+ 55
SCKn, clock mode
tCLKP1/2
tCLKP1/2
SIN  SCK  setup time
tIVSHE
ns
SINn
+ 10
+ 10
SCKn,
tCLKP1
tCLKP1
tSHIXE
ns
SCK   SIN hold time
SINn
+ 10
+ 10
SCK fall time
tF
SCKn
ns
20
20
SCK rise time
tR
SCKn
ns
20
20
Notes:  AC characteristic in CLK synchronized mode.
 CL is the load capacity value of pins when testing.
 Depending on the used machine clock frequency, the maximum possible baud rate can be limited by
some parameters. These parameters are shown in “MB96600 series HARDWARE MANUAL”.
 tCLKP1 indicates the peripheral clock 1 (CLKP1), Unit: ns
 These characteristics only guarantee the same relocate port number.
 For example, the combination of SCKn and SOTn_R is not guaranteed.
SCK   SOT delay time
tSLOVE
*: Parameter N depends on tSCYC and can be calculated as follows:
 If tSCYC = 2  k  tCLKP1, then N = k, where k is an integer > 2
 If tSCYC = (2  k + 1)  tCLKP1, then N = k + 1, where k is an integer > 1
Examples:
48
CONFIDENTIAL
tSCYC
N
4  tCLKP1
2
5  tCLKP1, 6  tCLKP1
3
7  tCLKP1, 8  tCLKP1
4
...
...
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
tSCYC
VOH
SCK
VOL
VOL
tOVSHI
tSLOVI
VOH
SOT
VOL
tIVSHI
SIN
tSHIXI
VIH
VIH
VIL
VIL
Internal shift clock mode
SCK
tSHSL
tSLSH
VIH
VIH
VIL
tF
SOT
VIL
VIH
tR
tSLOVE
VOH
VOL
SIN
tIVSHE
VIH
VIL
tSHIXE
VIH
VIL
External shift clock mode
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
49
D a t a S h e e t
(9) External Input Timing
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Value
Min
Max
Pin name
Unit
Pnn_m
General Purpose I/O
A/D Converter trigger
input
Reload Timer
PPG trigger input
ADTG
Input pulse width
TINn, TINn_R
TTGn
FRCKn,
FRCKn_R
INn, INn_R
AINn,
BINn,
ZINn
INTn, INTn_R
tINH,
tINL
2tCLKP1 +200
(tCLKP1=
1/fCLKP1)*
Remarks
-
ns
Free-Running Timer
input clock
Input Capture
Quadrature
Position/Revolution
Counter
External Interrupt
Non-Maskable
NMI
Interrupt
*: tCLKP1 indicates the peripheral clock1 (CLKP1) cycle time except stop when in stop mode.
200
tINH
External input timing
VIH
CONFIDENTIAL
ns
tINL
VIH
VIL
50
-
VIL
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
2
(10) I C Timing
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Symbol
Conditions
High-speed
mode*4
Min
Max
Typical mode
Min
Max
Unit
SCL clock frequency
fSCL
0
100
0
400
kHz
(Repeated) START condition
hold time
tHDSTA
4.0
0.6
s
SDA   SCL 
SCL clock "L" width
tLOW
4.7
1.3
s
SCL clock "H" width
tHIGH
4.0
0.6
s
(Repeated) START condition
setup time
tSUSTA
4.7
0.6
s
CL = 50pF,
SCL   SDA 
R = (Vp/IOL)*1
Data hold time
tHDDAT
0
3.45*2
0
0.9*3
s
SCL   SDA  
Data setup time
tSUDAT
250
100
ns
SDA    SCL 
STOP condition setup time
tSUSTO
4.0
0.6
s
SCL   SDA 
Bus free time between
"STOP condition" and
tBUS
4.7
1.3
s
"START condition"
Pulse width of spikes which
(1-1.5)
(1-1.5)
will be suppressed by input
tSP
0
0
ns
tCLKP1*5
tCLKP1*5
noise filter
*1: R and CL represent the pull-up resistance and load capacitance of the SCL and SDA lines, respectively.
Vp indicates the power supply voltage of the pull-up resistance and IOL indicates VOL guaranteed current.
*2: The maximum tHDDAT only has to be met if the device does not extend the "L" width (t LOW) of the SCL signal.
*3: A high-speed mode I2C bus device can be used on a standard mode I2C bus system as long as the device
satisfies the requirement of "tSUDAT ≥ 250ns".
*4: For use at over 100kHz, set the peripheral clock1 (CLKP1) to at least 6MHz.
*5: tCLKP1 indicates the peripheral clock1 (CLKP1) cycle time.
SDA
tSUDAT
tSUSTA
tBUS
tLOW
SCL
tHDSTA
tHDDAT
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
tHIGH
tHDSTA
tSP
tSUSTO
51
D a t a S h e e t
5.
A/D Converter
(1) Electrical Characteristics for the A/D Converter
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Min
Value
Typ
Max
-
-
-
10
bit
-
-
- 3.0
-
+ 3.0
LSB
-
-
- 2.5
-
+ 2.5
LSB
-
-
- 1.9
-
+ 1.9
LSB
VOT
ANn
Typ - 20
Typ + 20
mV
VFST
ANn
Typ - 20
Typ + 20
mV
Compare time*
-
-
Sampling time*
-
-
5.0
8.0
3.1
s
s
s
s
mA
Symbol
Pin
name
Resolution
-
Total error
Nonlinearity error
Parameter
Differential
Nonlinearity error
Zero transition
voltage
Full scale transition
voltage
Power supply
current
Reference power
supply current
(between AVRH
and AVRL)
Analog input
capacity
Analog impedance
Analog port input
current (during
conversion)
Analog input
voltage
Reference voltage
range
IA
IAH
IR
CONFIDENTIAL
Remarks
1.0
2.2
0.5
1.2
-
AVRL
+ 0.5LSB
AVRH
- 1.5LSB
2.0
-
-
3.3
A
-
520
810
A A/D Converter active
-
-
1.0
A
AVRH
IRH
4.5V ≤ ΑVCC ≤ 5.5V
2.7V ≤ ΑVCC  4.5V
4.5V ≤ ΑVCC ≤ 5.5V
2.7V ≤ ΑVCC  4.5V
A/D Converter active
A/D Converter not
operated
A/D Converter not
operated
CVIN
ANn
-
-
15.9
pF
RVIN
ANn
-
-
2050
3600


4.5V ≤ AVCC ≤ 5.5V
2.7V ≤ AVCC < 4.5V
IAIN
ANn
- 0.3
-
+ 0.3
A
AVSS , AVRL VAIN 
AVCC, AVRH
VAIN
ANn
AVRL
-
AVRH
V
-
AVRH
AVCC
- 0.1
-
AVCC
V
-
AVRL
AVSS
-
AVSS
+ 0.1
V
ANn
-
-
4.0
LSB
Variation between
channels
*: Time for each channel.
52
AVCC
Unit
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
(2) Accuracy and Setting of the A/D Converter Sampling Time
If the external impedance is too high or the sampling time too short, the analog voltage charged to the
internal sample and hold capacitor is insufficient, adversely affecting the A/D conversion precision.
To satisfy the A/D conversion precision, a sufficient sampling time must be selected. The required sampling
time (Tsamp) depends on the external driving impedance R ext, the board capacitance of the A/D converter
input pin Cext and the AVCC voltage level. The following replacement model can be used for the calculation:
MCU
Rext
Analog
input
RVIN
Source
Comparator
Cext
CVIN
Sampling switch
(During sampling:ON)
Rext: External driving impedance
Cext: Capacitance of PCB at A/D converter input
CVIN: Analog input capacity (I/O, analog switch and ADC are contained)
RVIN: Analog input impedance (I/O, analog switch and ADC are contained)
The following approximation formula for the replacement model above can be used:
Tsamp = 7.62  (Rext  Cext + (Rext + RVIN)  CVIN)
 Do not select a sampling time below the absolute minimum permitted value.
(0.5s for 4.5V ≤ AVCC ≤ 5.5V, 1.2s for 2.7V ≤ AVCC < 4.5V)
 If the sampling time cannot be sufficient, connect a capacitor of about 0.1F to the analog input pin.
 A big external driving impedance also adversely affects the A/D conversion precision due to the pin
input leakage current IIL (static current before the sampling switch) or the analog input leakage
current IAIN (total leakage current of pin input and comparator during sampling). The effect of the
pin input leakage current IIL cannot be compensated by an external capacitor.
 The accuracy gets worse as |AVRH - AVRL| becomes smaller.
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
53
D a t a S h e e t
(3) Definition of A/D Converter Terms
 Resolution
 Nonlinearity error
: Analog variation that is recognized by an A/D converter.
: Deviation of the actual conversion characteristics from a straight line that connects
the zero transition point (0b0000000000 ←→ 0b0000000001) to the full-scale
transition point (0b1111111110 ←→ 0b1111111111).
 Differential nonlinearity error : Deviation from the ideal value of the input voltage that is required to
change the output code by 1LSB.
Total error
: Difference between the actual value and the theoretical value. The total error
includes zero transition error, full-scale transition error and nonlinearity error.
 Zero transition voltage: Input voltage which results in the minimum conversion value.
 Full scale transition voltage: Input voltage which results in the maximum conversion value.
Nonlinearity error of digital output N =
VNT - {1LSB  (N - 1) + VOT}
1LSB
Differential nonlinearity error of digital output N =
1LSB =
N
VOT
VFST
VNT
54
CONFIDENTIAL
:
:
:
:
V(N + 1) T - VNT
1LSB
[LSB]
- 1 [LSB]
VFST - VOT
1022
A/D converter digital output value.
Voltage at which the digital output changes from 0x000 to 0x001.
Voltage at which the digital output changes from 0x3FE to 0x3FF.
Voltage at which the digital output changes from 0x(N − 1) to 0xN.
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
1LSB (Ideal value) =
AVRH - AVRL
1024
Total error of digital output N =
[V]
VNT - {1LSB  (N - 1) + 0.5LSB}
1LSB
N
: A/D converter digital output value.
VNT : Voltage at which the digital output changes from 0x(N + 1) to 0xN.
VOT (Ideal value) = AVRL + 0.5LSB[V]
VFST (Ideal value) = AVRH - 1.5LSB[V]
January 31, 2014, MB96650_DS704-00003-2v1-E
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D a t a S h e e t
6.
Low Voltage Detection Function Characteristics
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Min
Value
Typ
Max
CILCR:LVL = 0000B
CILCR:LVL = 0001B
CILCR:LVL = 0010B
CILCR:LVL = 0011B
CILCR:LVL = 0100B
CILCR:LVL = 0111B
CILCR:LVL = 1001B
2.70
2.79
2.98
3.26
3.45
3.73
3.91
2.90
3.00
3.20
3.50
3.70
4.00
4.20
3.10
3.21
3.42
3.74
3.95
4.27
4.49
V
V
V
V
V
V
V
dV/dt
-
- 0.004
-
+ 0.004
V/s
Hysteresis width
VHYS
CILCR:LVHYS=0
CILCR:LVHYS=1
80
100
50
120
mV
mV
Stabilization time
TLVDSTAB
-
-
-
75
s
Parameter
Symbol
Conditions
Detected voltage*1
VDL0
VDL1
VDL2
VDL3
VDL4
VDL5
VDL6
Power supply voltage
change rate*2
Unit
Detection delay time
td
30
s
*1: If the power supply voltage fluctuates within the time less than the detection delay time (td), there is a
possibility that the low voltage detection will occur or stop after the power supply voltage passes the
detection range.
*2: In order to perform the low voltage detection at the detection voltage (V DLX), be sure to suppress fluctuation
of the power supply voltage within the limits of the change ration of power supply voltage.
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D a t a S h e e t
Voltage
Vcc
dV
Detected Voltage
dt
VDLX max
VDLX min
Time
RCR:LVDE
···Low voltage detection
function enable
January 31, 2014, MB96650_DS704-00003-2v1-E
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Low voltage detection
function disable
Stabilization time
TLVDSTAB
Low voltage detection
function enable···
57
D a t a S h e e t
7.
Flash Memory Write/Erase Characteristics
(VCC = AVCC = 2.7V to 5.5V, VSS = AVSS = 0V, TA = - 40°C to + 125°C)
Parameter
Sector erase time
Word (16-bit)
write time
Conditions
Value
Min Typ Max
Unit
Large Sector
TA ≤ + 105°C
-
1.6
7.5
s
Small Sector
-
-
0.4
2.1
s
Security Sector
-
-
0.31
1.65
s
-
25
400
s
-
-
25
400
s
TA ≤ + 105°C
-
Large Sector
TA ≤ + 105°C
Small Sector
Chip erase time
11.51 55.05
s
Remarks
Includes write time
prior to internal erase.
Not including
system-level overhead
time.
Includes write time
prior to internal erase.
Note: While the Flash memory is written or erased, shutdown of the external power (VCC) is prohibited. In the
application system where the external power (VCC) might be shut down while writing or erasing, be sure
to turn the power off by using a low voltage detection function.
To put it concrete, change the external power in the range of change ration of power supply voltage
(-0.004V/s to +0.004V/s) after the external power falls below the detection voltage (V DLX)*1.
Write/Erase cycles and data hold time
Write/Erase cycles
(cycle)
Data hold time
(year)
1,000
10,000
100,000
20 *2
10 *2
5 *2
*1: See "6. Low Voltage Detection Function Characteristics".
*2: This value comes from the technology qualification (using Arrhenius equation to translate high temperature
measurements into normalized value at + 85C).
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 EXAMPLE CHARACTERISTICS
This characteristic is an actual value of the arbitrary sample. It is not the guaranteed value.
 MB96F657
Run Mode
(VCC = 5.5V)
100.00
PLL clock (32MHz)
10.00
ICC [mA]
Main osc. (4MHz)
1.00
RC clock (2MHz)
RC clock (100kHz)
0.10
Sub osc. (32kHz)
0.01
-50
0
50
100
150
TA [ºC]
Sleep Mode
(VCC = 5.5V)
100.000
PLL clock (32MHz)
ICC [mA]
10.000
Main osc. (4MHz)
1.000
RC clock (2MHz)
0.100
RC clock (100kHz)
0.010
Sub osc. (32kHz)
0.001
-50
0
50
100
150
TA [ºC]
January 31, 2014, MB96650_DS704-00003-2v1-E
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59
D a t a S h e e t
 MB96F657
Timer Mode
(VCC = 5.5V)
10.000
PLL clock (32MHz)
ICC [mA]
1.000
Main osc. (4MHz)
0.100
RC clock (2MHz)
RC clock (100kHz)
0.010
Sub osc. (32kHz)
0.001
-50
0
50
100
150
TA [ºC]
Stop Mode
(VCC = 5.5V)
1.000
ICC [mA]
0.100
0.010
0.001
-50
0
50
100
150
TA [ºC]
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D a t a S h e e t
 Used setting
Mode
Run mode
Sleep mode
Selected Source
Clock
PLL
Main osc.
RC clock fast
RC clock slow
Sub osc.
PLL
Main osc.
RC clock fast
RC clock slow
Sub osc.
Timer mode
PLL
Main osc.
RC clock fast
RC clock slow
Sub osc.
Stop mode
stopped
January 31, 2014, MB96650_DS704-00003-2v1-E
CONFIDENTIAL
Clock/Regulator and FLASH Settings
CLKS1 = CLKS2 = CLKB = CLKP1 = CLKP2 = 32MHz
CLKS1 = CLKS2 = CLKB = CLKP1 = CLKP2 = 4MHz
CLKS1 = CLKS2 = CLKB = CLKP1 = CLKP2 = 2MHz
CLKS1 = CLKS2 = CLKB = CLKP1 = CLKP2 = 100kHz
CLKS1 = CLKS2 = CLKB = CLKP1 = CLKP2 = 32kHz
CLKS1 = CLKS2 = CLKP1 = CLKP2 = 32MHz
Regulator in High Power Mode,
(CLKB is stopped in this mode)
CLKS1 = CLKS2 = CLKP1 = CLKP2 = 4MHz
Regulator in High Power Mode,
(CLKB is stopped in this mode)
CLKS1 = CLKS2 = CLKP1 = CLKP2 = 2MHz
Regulator in High Power Mode,
(CLKB is stopped in this mode)
CLKS1 = CLKS2 = CLKP1 = CLKP2 = 100kHz
Regulator in Low Power Mode,
(CLKB is stopped in this mode)
CLKS1 = CLKS2 = CLKP1 = CLKP2 = 32kHz
Regulator in Low Power Mode,
(CLKB is stopped in this mode)
CLKMC = 4MHz, CLKPLL = 32MHz
(System clocks are stopped in this mode)
Regulator in High Power Mode,
FLASH in Power-down / reset mode
CLKMC = 4MHz
(System clocks are stopped in this mode)
Regulator in High Power Mode,
FLASH in Power-down / reset mode
CLKMC = 2MHz
(System clocks are stopped in this mode)
Regulator in High Power Mode,
FLASH in Power-down / reset mode
CLKMC = 100kHz
(System clocks are stopped in this mode)
Regulator in Low Power Mode,
FLASH in Power-down / reset mode
CLKMC = 32 kHz
(System clocks are stopped in this mode)
Regulator in Low Power Mode,
FLASH in Power-down / reset mode
(All clocks are stopped in this mode)
Regulator in Low Power Mode,
FLASH in Power-down / reset mode
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D a t a S h e e t
 ORDERING INFORMATION
MCU with CAN controller
Part number
Flash memory
MB96F653RBPMC-GSE1
Flash A
(96.5KB)
MB96F653RBPMC-GSE2
MB96F655RBPMC-GSE1
Flash A
(160.5KB)
MB96F655RBPMC-GSE2
MB96F656RBPMC-GSE1
Flash A
(288.5KB)
MB96F656RBPMC-GSE2
MB96F657RBPMC-GSE1
Flash A
(416.5KB)
MB96F657RBPMC-GSE2
*: For details about package, see "PACKAGE DIMENSION".
Package*
120-pin plastic LQFP
(FPT-120P-M21)
120-pin plastic LQFP
(FPT-120P-M21)
120-pin plastic LQFP
(FPT-120P-M21)
120-pin plastic LQFP
(FPT-120P-M21)
MCU without CAN controller
Part number
Flash memory
MB96F653ABPMC-GSE1
Flash A
(96.5KB)
MB96F653ABPMC-GSE2
MB96F655ABPMC-GSE1
Flash A
(160.5KB)
MB96F655ABPMC-GSE2
*: For details about package, see "PACKAGE DIMENSION".
62
CONFIDENTIAL
Package*
120-pin plastic LQFP
(FPT-120P-M21)
120-pin plastic LQFP
(FPT-120P-M21)
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
 PACKAGE DIMENSION
120-pin plastic LQFP
Lead pitch
0.50 mm
Package width ×
package length
16.0 × 16.0 mm
Lead shape
Gullwing
Sealing method
Plastic mold
Mounting height
1.70 mm MAX
Weight
0.88 g
Code
(Reference)
P-LFQFP120-16×16-0.50
(FPT-120P-M21)
120-pin plastic LQFP
(FPT-120P-M21)
Note 1) * : These dimensions do not include resin protrusion.
Resin protrusion is +0.25(.010) MAX(each side).
Note 2) Pins width and pins thickness include plating thickness.
Note 3) Pins width do not include tie bar cutting remainder.
18.00±0.20(.709±.008)SQ
* 16.00
+0.40
–0.10
.630
+.016
–.004
SQ
90
61
91
60
0.08(.003)
Details of "A" part
1.50
.059
+0.20
–0.10
+.008
–.004
(Mounting height)
INDEX
0~8°
120
LEAD No.
31
1
30
0.50(.020)
C
"A"
0.22±0.05
(.009±.002)
0.08(.003) M
0.145
.006
2002-2010 FUJITSU SEMICONDUCTOR LIMITED F120033S-c-4-7
+0.05
–0.03
+.002
–.001
0.60±0.15
(.024±.006)
0.10±0.05
(.004±.002)
(Stand off)
0.25(.010)
Dimensions in mm (inches).
Note: The values in parentheses are reference values.
Please check the latest package dimension at the following URL.
http://edevice.fujitsu.com/package/en-search/
January 31, 2014, MB96650_DS704-00003-2v1-E
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 Major Changes
Page
Revision 1.0
Revision 2.0
39
Revision 2.1
-
64
CONFIDENTIAL
Section
ELECTRICAL CHARACTERISTICS
3. DC Characteristics
(1) Current Rating
-
Change Results
Initial release
Changed the Value of “Power supply current in Timer modes”
ICCTPLL
Typ: 2485μA → 1800μA (TA = +25°C)
Max: 2715μA → 2250μA (TA = +25°C)
Max: 4095μA → 3220μA (TA = +105°C)
Max: 5065μA → 4205μA (TA = +125°C)
Company name and layout design change
MB96650_DS704-00003-2v1-E, January 31, 2014
D a t a S h e e t
January 31, 2014, MB96650_DS704-00003-2v1-E
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65
D a t a S h e e t
Colophon
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 any use that includes 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 any use
where chance of failure is intolerable (i.e., submersible repeater and artificial satellite). Please note that Spansion will not
be liable to you and/or any third party for any claims or damages arising in connection with above-mentioned uses of the
products. Any semiconductor devices have an inherent chance of failure. You must protect against injury, damage or loss
from such failures by incorporating safety design measures into your facility and equipment such as redundancy, fire
protection, and prevention of over-current levels and other abnormal operating conditions. If any products described in
this document represent goods or technologies subject to certain restrictions on export under the Foreign Exchange and
Foreign Trade Law of Japan, the US Export Administration Regulations or the applicable laws of any other country, the
prior authorization by the respective government entity will be required for export of those products.
Trademarks and Notice
The contents of this document are subject to change without notice. This document may contain information on a
Spansion product under development by Spansion. Spansion reserves the right to change or discontinue work on any
product without notice. The information in this document is provided as is without warranty or guarantee of any kind as to
its accuracy, completeness, operability, fitness for particular purpose, merchantability, non-infringement of third-party
rights, or any other warranty, express, implied, or statutory. Spansion assumes no liability for any damages of any kind
arising out of the use of the information in this document.
Copyright © 2013-2014 Spansion Inc. All rights reserved. Spansion®, the Spansion logo, MirrorBit®, MirrorBit®
EclipseTM, ORNANDTM and combinations thereof, are trademarks and registered trademarks of Spansion LLC in the
United States and other countries. Other names used are for informational purposes only and may be trademarks of their
respective owners.
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