Mitsubishi M37736EHBXXXGP Datasheet

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

DESCRIPTION

The M37736EHBXXXGP is a single-chip microcomputer using the
7700 Family core. This single-chip microcomputer has a CPU and a
bus interface unit. The CPU is a 16-bit parallel processor that can be
an 8-bit parallel processor, and the bus interface unit enhances the
memory access efficiency to execute instructions fast. This
microcomputer also includes a 32 kHz oscillation circuit, in addition
to the PROM, RAM, multiple-function timers, serial I/O, A-D converter,
and others.
In the M37736EHBXXXGP, as the multiplex method of the external
bus, either of 2 types can be selected.
The M37736EHBXXXGP has the same function as the
M37736MHBXXXGP except that the built-in ROM is PROM. (Refer
to the basic function blocks description.) For program development,
the M37736EHBGS with erasable ROM that is housed in a windowed
ceramic LCC is also provided.

FEATURES

●Number of basic instructions .................................................. 103

●Memory size PROM .............................................124 Kbytes

RAM................................................ 3968 bytes

●Instruction execution time

The fastest instruction at 25 MHz frequency ...................... 160 ns

M37736EHBGS

PROM VERSION OF M37736MHBXXXGP

●Single power supply ...................................................... 5 V ± 10%

●Low power dissipation (at 25 MHz frequency)

............................................47.5 mW (Typ.)

●Interrupts ............................................................ 19 types, 7 levels

●Multiple-function 16-bit timer ................................................. 5 + 3

●Serial I/O (UART or clock synchronous) ..................................... 3

●10-bit A-D converter ............................................ 8-channel inputs

●12-bit watchdog timer

●Programmable input/output, output

(ports P0, P1, P2, P3, P4, P5, P6, P7, P8, P9, P10)..........................84

●Clock generating circuit ........................................ 2 circuits built-in

APPLICATION

Control devices for general commercial equipment such as office
automation, office equipment, and others.
Control devices for general industrial equipment such as
communication equipment, and others.
Note. Do not use the windowed EPROM version for mass production,

because it is a tool for program development (for evaluation).

PIN CONFIGURATION (TOP VIEW)

2

2

2

1

2

D

D

D

X

X

X

/R

/T

/CTS

/CLK

/T

2

7

0

1

3

↔ P9

→ P9

↔ P8

↔ P9

↔ P9

8079787776

/CLK1 ↔

/CLK0 ↔

V

CC
CC

V

REF

→

AV

SS

V

SS
CIN

COUT

TRG

4

/AN4 ↔

3

/AN3 ↔

2

/AN2 ↔

1

/AN1 ↔

0

/AN0 ↔

81
82
83
84

↔

85
86
87
88
89
90
91
92
93

↔

94

↔

95

↔

96
97
98
99
100

123456789

↔

↔

IN

SUB

/f

/TB1

6

IN

P6

/TB2

7

P6

↔

IN

/TB0

5

P6

↔

2

/INT

4

P6

↔

1

/INT

3

P6

P86/RXD1 ↔
P8

4

/CTS1/RTS1 ↔

P8

P8

P8

2/RXD0

/CLKS0 ↔

P8

0

P8

/CTS0/RTS0/CLKS1 ↔

AV

P7

7

/AN7/X

P7

6

/AN6/X

P7

5

/AN5/AD

P7
P7
P7
P7
P7

5

3/TXD0

1

4

→ P9

→ P95→ P96→ P97↔ P0

7574737271

↔

↔

↔

↔

0

IN

IN

OUT

/INT

2

/TA4

/TA3

1

7

/TA4

P6

0

P5

P6

P6

0

0

1

2

3

4

/CS

/CS

/CS

/CS

/CS

0

/A

0

/RSMP

1

2

3

4

5

/A

/A

/A

/A

/A

1

2

3

4

5

↔ P0

↔ P0

↔ P0

↔ P0

↔ P0

70696867666564636261605958575655545352

16

/A

6

/A

6

↔ P0

17

/A

7

/A

7

↔ P0

8

/D

8

/A

0

↔ P1

9

/D

9

/A

1

↔ P1

10

/D

10

/A

2

↔ P1

11

/D

11

/A

3

↔ P1

12

/D

12

/A

4

↔ P1

13

/D

13

/A

5

↔ P1

14

/D

14

/A

6

↔ P1

15

/D

15

/A

7

↔ P1

/D

0

/A

16

/A

0

↔ P2

M37736EHBXXXGP

10

↔

OUT

/TA3

6

P5

11

↔

IN

/TA2

5

P5

1213141516

↔

↔

↔

↔

IN

IN

OUT

OUT

/TA1

/TA0

3

1

/TA2

/TA1

4

2

P5

P5

P5

P5

↔

OUT

/TA0

0

P5

171819

↔

↔

3

2

/KI

/KI

7

6

P10

P10

2021222324

↔

↔

↔

1

0

3

/KI

/KI

5

4

P10

P10

P10

↔

2

P10

↔

1

P10

↔

0

P10

25

↔

7

P4

26

↔

6

P4

1

2

/D

/D

1

2

/A

/A

17

18

/A

/A

1

2

↔ P2

↔ P2

272829

↔

↔

5

4

P4

P4

3

4

/D

/D

3

4

/A

/A

19

20

/A

/A

3

4

↔ P2

↔ P2

51

↔ P25/A21/A5/D

50

↔ P26/A22/A6/D

49

↔ P27/A23/A7/D

48

↔ P30/R/W/WEL

47

↔ P3

46

↔ P3

45

↔ P3

44

→ EVL0

43
42

→ EVL1
V

41
40

V

39

→ E/RDE

38

→ X
← X

37

← RESET

36

← BSEL

35

← CNV

34
33

← BYTE

32

↔ P4

31

↔ P4

30

↔

↔

3

f1

/

2

P4

P4

5
6
7

1

/BHE/WEH

2

/ALE

3

/HLDA

CC
SS

OUT
IN

SS

0

/HOLD

1

/RDY

Outline 100P6S-A

1



























































































































































































Clock input

X

IN

Clock output

X

OUT

Clock Generating Circuit

Timer TA4(16)

RAM

3968 bytes

PROM

124 Kbytes

Timer TA3(16)

Timer TA2(16)

Timer TA1(16)

P8(8)

Input/Output

port P8

P7(8)

Input/Output

port P7

X

CIN

X

COUT

P6(8)

Input/Output

port P6

P5(8)

Input/Output

port P5

P4(8)

Input/Output

port P4

P3(4)

Input/Output

port P3

P2(8)

Input/Output

port P2

P1(8)

Input/Output

port P1

P0(8)

Input/Output

port P0

Timer TA0(16)

Watchdog Timer

Timer TB2(16)

Timer TB1(16)

Timer TB0(16)

UART2(9)

UART1(9)

UART0(9) A-D Converter(10)

Instruction Register(8)

Data Buffer DBH(8)

Data Buffer DB

L

(8)

Processor Status Register PS(11)

Direct Page Register DPR(16)

Stack Pointer S(16)

Index Register Y(16)

Index Register X(16)

Accumulator B(16)

Arithmetic Logic

Unit(16)

Accumulator A(16)

Instruction Queue Buffer Q0(8)

Instruction Queue Buffer Q

1

(8)

Incrementer(24)

Program Address Register PA(24)

Data Address Register DA(24)

Instruction Queue Buffer Q

2

(8)

Program Counter PC(16)

Incrementer/Decrementer(24)

Program Bank Register PG(8)

Data Bank Register DT((8)

Input Buffer Register IB(16)

Address Bus

Data Bus(Even)

Data Bus(Odd)

X

CINXCOUT

Enable output

E

Reset input

RESET

(0V)

V

SS

(0V)

AV

SS

CNV

SS

AV

CC

Reference

voltage input

V

REF

Bus method

selection input

BSEL

External data bus width

selection input

BYTE

V

CC



P9(8)

Output

port P9



P10(8)

Input/Output

port P10

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

PROM VERSION OF M37736MHBXXXGP

M37736EHBGS

2

M37736EHBXXXGP BLOCK DIAGRAM

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

M67736EHBGS

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

FUNCTIONS OF M37736EHBXXXGP

Number of basic instructions 103
Instruction execution time 160 ns (the fastest instruction at external clock 25 MHz frequency)

Memory size

Input/Output ports
Output port P9 8-bit ✕ 1

Multi-function timers
Serial I/O (UART or clock synchronous serial I/O) ✕ 3

A-D converter 10-bit ✕ 1 (8 channels)
Watchdog timer 12-bit ✕ 1

Interrupts

Clock generating circuit
Supply voltage 5 V ± 10%

Power dissipation 47.5 mW (at external clock 25 MHz frequency)
Input/Output characteristic

Memory expansion

Operating temperature range –20 to 85 °C
Device structure CMOS high-performance silicon gate process

Package

Parameter Functions

PROM 124 Kbytes
RAM 3968 bytes
P0 – P2, P4 – P8, P10 8-bit ✕ 9
P3 4-bit ✕ 1

TA0, TA1, TA2, TA3, TA4 16-bit ✕ 5
TB0, TB1, TB2 16-bit ✕ 3

3 external types, 16 internal types
Each interrupt can be set to the priority level (0 – 7.)
2 circuits built-in (externally connected to a ceramic resonator or a

quartz-crystal oscillator)

Input/Output voltage 5 V
Output current 5 mA

M37736EHBXXXGP
M37736EHBGS

External bus mode A; maximum 16 Mbytes,
External bus mode B; maximum 1 Mbytes

100-pin plastic molded QFP (100P6S-A)
100-pin ceramic LCC (with a window) (100D0)

PROM VERSION OF M37736MHBXXXGP

3

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

PIN DESCRIPTION

Pin Name Input/Output Functions
Vcc, Power source Apply 5 V ± 10% to Vcc and 0 V to Vss.
Vss
CNVss CNVss input Input This pin controls the processor mode. Connect to Vss for the single-chip mode and the memory

_____

RESET Reset input Input When “L” level is applied to this pin, the microcomputer enters the reset state.

XIN Clock input Input
X

OUT Clock output Output

_

E Enable output Output This pin functions as the enable signal output pin which indicates the access status in the internal

BYTE

External data

Input In the memory expansion mode or the microprocessor mode, this pin determines whether the
bus width
selection input

BSEL Input In the memory expansion mode or the microprocessor mode, this pin determines the external bus

Bus method
select input

AVcc, Analog power Power source input pin for the A-D converter. Externally connect AVcc to Vcc and AVss to Vss.
AVss source input

REF Reference Input This is reference voltage input pin for the A-D converter.

V

voltage input

0 – P07 I/O port P0 I/O In the single-chip mode, port P0 becomes an 8-bit I/O port. An I/O direction register is available so

P0

0 – P17 I/O port P1 I/O In the single-chip mode, these pins have the same functions as port P0. When the BYTE pin is set

P1

0 – P27 I/O port P2 I/O In the single-chip mode, these pins have the same functions as port P0. In the memory expansion

P2

0 – P33 I/O port P3 I/O In the single-chip mode, these pins have the same function as port P0. In the memory expansion

P3

0 – P47 I/O port P4 I/O In the single-chip mode, these pins have the same functions as port P0. In the memory expansion

P4

0 – P57 I/O port P5 I/O In addition to having the same functions as port P0 in the single-chip mode, these pins also

P5

0 – P67 I/O port P6 I/O In addition to having the same functions as port P0 in the single-chip mode, these pins also

P6

0 – P77 I/O port P7 I/O In addition to having the same functions as port P0 in the single-chip mode, these pins function as

P7

0 – P87 I/O port P8 I/O In addition to having the same functions as port P0 in the single-chip mode, these pins also

P8

0 – P97

P9
P100 – P107
EVL0, EVL1

Output port P9

Output Port P9 is an 8-bit I/O port. These ports are floating when reset. When writting to the port latch,

I/O port P10 I/O In addition to having the same functions as port P0 in the single-chip mode, P104 – P107 also

––

Output These pins should be left open.

expansion mode, and to Vcc for the microprocessor mode.

These are pins of main-clock generating circuit. Connect a ceramic resonator or a quartz­crystal oscillator between X

IN and XOUT. When an external clock is used, the clock source should

be connected to the XIN pin, and the XOUT pin should be left open.
bus. In the external bus mode B and the memory expansion mode or the microprocessor mode,

this pin output signal RDE.

___

external data bus has an 8-bit width or a 16-bit width. The data bus has a 16-bit width when “L”
signal is input and an 8-bit width when “H” signal is input.

mode. The bus mode becomes the external bus mode A when “H” signal is input, and the external
bus mode B when “L” signal is input.

that each pin can be programmed for input or output. These ports are in the input mode when
reset.

In the memory expansion mode or the microprocessor mode, these pins output address (A
at the external bus mode A, and these pins output signals CS0 – CS4 and RSMP, and addresses
(A16, A17) at the external bus mode B.

to “L” in the memory expansion mode or the microprocessor mode and external data bus has a
16-bit width, high-order data (D8 – D15) is input/output or an address (A8 – A15) is output. When
the BYTE pin is “H” and an external data bus has an 8-bit width, only address (A8 – A15) is output.

mode or the microprocessor mode, low-order data (D
output. When using the external bus mode A, the address is A
bus mode B, the address is A0 – A7.

___ ____

mode or the microprocessor mode, R/W, BHE, ALE, and HLDA signals are output at the external
bus mode A, and WEL, WEH, ALE, and HLDA signals are output at the external bus mode B.

___ ___ ____

__

mode or the microprocessor mode, P40, P41 and P42 become HOLD and RDY input pins, and a

φ1 output pin, respectively. Functions of the other pins are the same as in the single-chip

clock
mode. However, in the memory expansion mode, P42 can be selected as an I/O port.

function as I/O pins for timers A0 to A3.
function as I/O pins for timer A4, input pins for external interrupt input (INT0 – INT2) and input pins

for timers B0 to B2. P67 also functions as sub-clock φSUB output pin.
input pins for A-D converter. Additionally, P7

and the input pin (X

CIN) of the sub-clock (32 kHz) oscillation circuit, respectively. When P76 and

P77 are used as the XCOUT and XCIN pins, connect a resonator or an oscillator between the both.
function as I/O pins for UART 0 and UART 1.
these ports become the output mode. P90 – P93 also function as I/O port for UART 2.
function as input pins for key input interrupt input (KI0 – KI3).

PROM VERSION OF M37736MHBXXXGP

0 – D7) is input/output or an address is

6 and P77 have the function as the output pin (XCOUT)

__ __

M37736EHBGS

___ ___

16 – A23. When using the external

____ ___

____

___ ___

0 – A7)

4

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

M67736EHBGS

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

BASIC FUNCTION BLOCKS

The M37736EHBXXXGP has the same function as the M37736MHB
XXXGP except that the built-in ROM is PROM. Refer to the section
on the M37736MHBXXXGP.

PIN DESCRIPTION (EPROM MODE)

Pin
VCC, VSS
CNVSS
BYTE

_____

RESET

XIN
XOUT

_

E

AVCC, AVSS
VREF
P00 – P07
P10 – P17
P20 – P27
P30
P31 – P33
P40 – P47
P50 – P57

P60 – P67
P70 – P77
P80 – P87
P90 – P97

P100 – P107
BSEL
EVL0, EVL1

Power supply
V
VPP input
Reset input
Clock input
Clock output
Enable output
Analog supply input
Reference voltage input
Address input (A0 – A7)
Address input (A8 – A15)
Data I/O (D0 – D7)
Address input (A16)
Input port P3
Input port P4
Control signal input

Input port P6
Input port P7
Input port P8
Input port P9
Input port P10

PP input

Name

_____
_____

Input/Output

Input
Input
Input

Input
Output
Output

Input

Input

Input

I/O
Input
Input
Input
Input

Input
Input

Input
Input
Input
Input

Output

Supply 5V±10% to VCC and 0V to VSS.
Connect to VPP when programming or verifing.
Connect to VPP when programming or verifing.
Connect to VSS.
Connect a ceramic resonator between XIN and XOUT.

Keep open.
Connect AVCC to VCC and AVSS to VSS.
Connect to VSS.
Port P0 functions as the lower 8 bits address input (A0 – A7).
Port P1 functions as the higher 8 bits address input (A8 – A15).
Port P2 functions as the 8 bits data input/output (D0 – D7).
P30 functions as the most significant bit address input (A16).
Connect to VSS.
Connect to VSS.
P50, P51, and P52 function as PGM, OE, and CE input pins respectively.

Connect P5
Connect to VSS.
Connect to VSS.
Connect to VSS.
Connect to V
Connect to V
Connect to V
Keep open.

3, P54, P55, and P56 to VCC. Connect P57 to VSS.

SS.
SS.
CC.

PROM VERSION OF M37736MHBXXXGP

Functions

_____ ___ ___

5

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

PROM VERSION OF M37736MHBXXXGP

M37736EHBGS

EPROM MODE

The M37736EHBXXXGP features an EPROM mode in addition to
its normal modes. When the RESET signal level is “L”, the chip
automatically enters the EPROM mode. Table 1 list the
correspondence between pins and Figure 1 shows the pin
connections in the EPROM mode.
The EPROM mode is the 1M mode for the EPROM that is equivalent
to the M5M27C101K.
When in the EPROM mode, ports P0, P1, P2, P3
CNV

SS, and BYTE are used for the EPROM (equivalent to the

M5M27C101K).
When in this mode, the built-in PROM can be programmed or read
from using these pins in the same way as with the M5M27C101K.

V

CC

_____

6

P8

5

P8

4

P8
P83 ↔

2

P8

1

P8

0

P8

CC

V

CC

AV

REF

V

AVSS

SS

V

7

P7

6

P7

5

P7

4

P7

3

P7

2

P7

1

P7
P7

0

↔
↔
↔

↔
↔
↔

→

↔
↔
↔
↔
↔
↔
↔
↔

7

↔ P8

80

81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100

1

↔

7

P6

0, P50, P51, P52,

2

1

0

↔ P9

79

2345678

↔

6

P6

78

↔ P9

↔

5

P6

↔ P9

77

↔

4

P6

3

→ P9

76

↔

3

P6

4

→ P9

75

↔

2

P6

5

→ P9

74

↔

1

P6

0

4

3

2

1

0

7

6

↔ P0

↔ P0

↔ P0

↔ P0

↔ P0

→ P9

→ P9

73

72

67

68

69

70

71

M37736EHBGP

9

101112131415161718192021222324252526282930

↔

↔

↔

↔

↔

↔

0

7

P6

P5

↔

6

5

4

3

2

P5

P5

P5

P5

P5

This chip does not have Device Identifier Mode, so that set the
corresponding program algorithm. The program area should specify
address 01000

16 – 1FFFF16.

Connect the clock which is either ceramic resonator or external clock
to X

IN pin and XOUT pin.

Table 1 Pin function in EPROM mode

D

5

D

6

D

7

A

16




∗



V

PP

M5M27C101K

5

↔ P0

66

↔

1

P5

65

6

↔ P0

↔

0

P5

Address input

10

A9A8A7A6A5A4A3A2A1A

2

1

0

7

↔ P1

↔ P1

↔ P1

↔ P0

61

62

63

64

↔

↔

↔

↔

7

6

5

4

P10

P10

P10

P10

VCC
VPP
VSS

Data I/O

___

CE

___

OE

_____

PGM

14

A

6

5

4

3

↔ P1

↔ P1

↔ P1

↔ P1

57

58

59

60

↔

↔

↔

↔

3

2

1

0

P10

P10

P10

P10

M37736EHBXXXGP

CNVSS, BYTE

Ports P0, P1, P30

0

0

↔ P2

55

↔

6

P4

1

↔ P2

54

↔

5

P4

D4D3D2D1D

4

2

↔ P23↔ P2

↔

52

51

53

50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31

↔

↔

↔ P2

4

3

2

P4

P4

P4

A15A13A12A11A

7

↔ P1

56

↔

7

P4

VCC

VSS

Port P2

P52
P51
P50

↔ P2

5

↔ P2

6

↔ P2

7

↔ P3

0

↔ P3

1

↔ P3

2
3

↔ P3
→ EVL0
→ EVL1

V

CC

V

SS

→ E
→ X

OUT
IN

← X
← RESET
← BSEL
CNV
← BYTE
↔ P4

0

↔ P4

1

SS

VCC
VPP
VSS

A0 – A16

D0 – D7

___

CE

___

OE

_____

PGM

V

SS

Fig. 1 Pin connection in EPROM mode

6

GM

CE

OE

P

Outline 100P6S-A

∗ : Connect to ceramic oscillation circuit.

: It is used in the EPROM mode.

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

M67736EHBGS

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

PROM VERSION OF M37736MHBXXXGP

FUNCTION IN EPROM MODE
1M mode (equivalent to the M5M27C101K)

Reading

To read the EPROM, set the CE and OE pins to a “L” level. Input the
address of the data (A
to the I/O pins D

__ __

the CE or OE pins are in the “H” state.

0 – D7. The data I/O pins will be floating when either

___ ___

0 – A16) to be read, and the data will be output

Programming

Programming must be performed in 8 bits by a byte program. To
program to the EPROM, set the CE pin to a “L” level and the OE pin to
a “H” level. The CPU will enter the programming mode when 12.5 V
is applied to the V
with pins A
– D7. Set the PGM pin to a “L” level to being programming.

PP pin. The address to be programmed to is selected

0 – A16, and the data to be programmed is input to pins D0

_____

___ ___

Erasing

To erase data on this chip, use an ultraviolet light source with a 2537
Angstrom wave length. The minimum radiation power necessary for
erasing is 15 J/cm

2

.

Programming operation

To program the M37733EHBXXXFP, first set VCC = 6 V, VPP = 12.5
V, and set the address to 01000
pulse, check that the data can be read, and if it cannot be read OK,
repeat the procedure, applying a 0.2 ms programming pulse and
checking that the data can be read until it can be read OK. Record
the accumulated number of pulse applied (X) before the data can be
read OK, and then write the data again, applying a further once this
number of pulses (0.2 ✕ X ms).
When this series of programming operations is complete, increment
the address, and continue to repeat the procedure above until the
last address has been reached.
Finally, when all addresses have been programmed, read with V
V

PP = 5 V (or VCC = VPP = 5.5 V).

Table 2. I/O signal in each mode

___CE___OE_____

Pin

Mode
Read-out
Output
Disable
Programming
Programming
Verify
Program Disable

VIL

VIL
VIH
VIL

VIL
VIH

Note 1 : An X indicates either V

16. Apply a 0.2 ms programming

PGM VPP VCC Data I/O

VIL

X

5 V

5 V

VIH

X

5 V

5 V

X

X

5 V

5 V

VIH

VIL

12.5 V

6 V

VIL

VIH

12.5 V

6 V

VIH

VIH

12.5 V

6 V

IL or VIH.

CC =

Output
Floating
Floating

Input

Output
Floating

Programming operation (equivalent to the M5M27C101K)

AC ELECTRICAL CHARACTERISTICS (Ta = 25 ± 5 °C, VCC = 6 V ± 0.25 V, VPP = 12.5 ± 0.3 V, unless otherwise noted)

Symbol Parameter Test conditions

tAS
tOES
tDS
tAH
tDH
tDFP
tVCS
tVPS
tPW
tOPW
tCES
tOE

Address setup time

___

OE setup time

Data setup time
Address hold time
Data hold time
Output enable to output float delay
VCC setup time
VPP setup time

_____

PGM pulse width

_____

PGM over program pulse width

___

CE setup time

Data valid from OE

__

Min.

0.19

0.19

Limits

Typ.
2
2
2
0
2
0
2
2

0.2

2

Max.

130

0.21

5.25

150

Unit

µs
µs
µs
µs
µs
ns
µs

µs
ms
ms

µs

ns

7

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

AC waveforms

V

ADDRESS

DATA

PP

V

VCC

CE

PGM

OE

VIL

VIH/VOH

VIL/VOL

VPP

VCC

VCC +1

V

VIH

VIL

VIH

VIL

VIH

VIL

IH

CC

tAS

tVPS

tVCS

tCES

PROGRAM VERIFY

DATA SET

DATA OUTPUT VALID

tDH tDS

tOES tOE

tPW

tOPW

PROM VERSION OF M37736MHBXXXGP

M37736EHBGS

tAH

tDFP

Programming algorithm flow chart

INCREMENT ADDR

START

ADDR=FIRST LOCATION

V

CC

PP

=12.5 V

V

X=0

PROGRAM ONE PULSE OF 0.2 ms

X=X+1

X=25?

NO

FAIL

NO

VERIFY

BYTE

PROGRAM PULSE OF

0.2X ms DURATION

LAST ADDR?

V

CC=VPP

VERIFY

ALL BYTE

DEVICE PASSED

Test conditions for A.C. characteristics

Input voltage : V

IL = 0.45 V, VIH = 2.4 V

Input rise and fall times (10 % – 90 %) : ≤ 20 ns
Reference voltage at timing measurement : Input, Output
“L” = 0.8 V, “H” = 2 V

=6.0 V

YES

PASS

=*5.0 V

PASS

YES

FAIL

VERIFY

BYTE

DEVICE
FAILED

PASS

FAIL

DEVICE

FAILED

*4.5 V ≤ VCC = VPP ≤ 5.5 V

8

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

M37736EHBGS

PROM VERSION OF M37736MHBXXXGP

SAFETY INSTRUCTIONS

(1)Sunlight and fluorescent lamp contain light that can erase written

information. When using in read mode, be sure to cover the
transparent glass portion with a seal or other materials (ceramic
package product).

(2)Mitsubishi Electric corp. provides the seal for covering the

transparent glass. Take care that the seal does not touch the read
pins (ceramic package product).

(3)Clean the transparent glass before erasing. Fingers’ fat and paste

disturb the passage of ultraviolet rays and may affect badly the
erasure capability (ceramic package product).

(4) A high voltage is used for programming. Take care that over-

voltage is not applied. Take care especially at power on.

(5) The programmable M37736EHBGP that is shipped in blank is

also provided. For the M37736EHBGP, Mitsubishi Electric corp.
does not perform PROM programming test and screening following
the assembly processes. To improve reliability after programming,
performing programming and test according to the flow below
before use is recommended.

Programming with PROM programmer

Screening

(Leave at 150 °C for 40 hours)

(Caution)

ADDRESSING MODES

The M37736EHBXXXGP has 28 powerful addressing modes. Refer
to the “7700 Family Software Manual” for the details.

MACHINE INSTRUCTION LIST

The M37736EHBXXXGP has 103 machine instructions. Refer to the
“7700 Family Software Manual” for the details.

DATA REQUIRED FOR PROM ORDERING

Please send the following data for writing to PROM.
(1) M37736EHBXXXGP writing to PROM order confirmation form
(2) 100P6S mark specification form
(3) ROM data (EPROM 3 sets)

Verify test with PROM programmer

Function check in target device

Caution : Never expose to 150 °C exceeding 100 hours.

9

MITSUBISHI MICROCOMPUTERS

M37736EHBXXXGP

PRELIMINARY

Notice: This is not a final specification.

Some parametric limits are subject to change.

ABSOLUTE MAXIMUM RATINGS

Symbol Parameter Conditions Ratings Unit
Vcc Power source voltage –0.3 to +7 V
AVcc Analog power source voltage –0.3 to +7 V
VI

Input voltage RESET, CNVss, BYTE –0.3 to +12(Note) V
Input voltage P0

VI

Output voltage

VO

Pd Power dissipation Ta = 25 °C 300 mW
Topr Operating temperature –20 to +85 °C

stg Storage temperature –40 to +150 °C

T

Note. When the EPROM is programmed, input voltage of pins CNVss and BYTE is 13 V respectively.

_____

0 – P07, P10 – P17, P20 – P27,
0 – P33, P40 – P47, P50 – P57,

P3

0 – P67, P70 – P77, P80 – P87,

P6

0 – P92, P100 – P107,

P9
VREF, XIN, BSEL
P00 – P07, P10 – P17, P20 – P27,

0 – P33, P40 – P47, P50 – P57,

P3

0 – P67, P70 – P77, P80 – P87,

P6
P90 – P97, P100 – P107, XOUT, E

_

PROM VERSION OF M37736MHBXXXGP

M37736EHBGS

–0.3 to Vcc + 0.3 V

–0.3 to Vcc + 0.3 V

RECOMMENDED OPERATING CONDITIONS (Vcc = 5 V ± 10%, Ta = –20 to +85 °C, unless otherwise noted)

Symbol Parameter

IN) : Operating 4.5 5.0 5.5

Vcc Power source voltage

f(X
f(XIN) : Stopped, f(XCIN) = 32.768 kHz 2.7 5.5

Min. Typ. Max.

AVcc Analog power source voltage Vcc V
Vss Power source voltage 0V
AVss Analog power source voltage 0 V

High-level input voltage P0

IH

V

P70 – P77, P80 – P87, P90 – P92, P100 – P107, XIN, RESET,

0 – P07, P30 – P33, P40 – P47, P50 – P57, P60 – P67,

_____

0.8 Vcc

CNVss, BYTE, BSEL, XCIN (Note 3)

VIH
VIH

VIL

High-level input voltage P10 – P17, P20 – P27 (in single-chip mode)
High-level input voltage P1

0 – P17, P20 – P27

(in memory expansion mode and microprocessor mode)

Low-level input voltage P0

0 – P07, P30 – P33, P40 – P47, P50 – P57, P60 – P67,

P70 – P77, P80 – P87, P90 – P92, P100 – P107, XIN, RESET,

_____

0.8 Vcc

0.5 Vcc

0

CNVss, BYTE, BSEL, XCIN (Note 3)

VIL
VIL

IOH(peak)

Low-level input voltage P10 – P17, P20 – P27 (in single-chip mode)
Low-level input voltage P1

0 – P17, P20 – P27

(in memory expansion mode and microprocessor mode)

High-level peak output current P0

0 – P07, P10 – P17, P20 – P27, P30 – P33,
0 – P47, P50 – P57, P60 – P67, P70 – P77,

P4

0
0

P80 – P87, P90 – P97, P100 – P107

High-level average output current P00 – P07, P10 – P17, P20 – P27, P30 – P33,

IOH(avg)

P4

0 – P47, P50 – P57, P60 – P67, P70 – P77,

P80 – P87, P90 – P97, P100 – P107

Low-level peak output current P00 – P07, P10 – P17, P20 – P27, P30 – P33,

IOL(peak)

0 – P43, P54 – P57, P60 – P67, P70 – P77,

P4
P80 – P87, P90 – P97, P104 – P107

IOL(peak)

Low-level peak output current P44 – P47, P100 – P103
Low-level average output current P00 – P07, P10 – P17, P20 – P27, P30 – P33,

IOL(avg)

0 – P43, P54 – P57, P60 – P67, P70 – P77,

P4

P80 – P87, P90 – P97, P104 – P107
IOL(avg) Low-level average output current P44 – P47, P100 – P103 15 mA
f(XIN) Main-clock oscillation frequency (Note 4) 25 MHz
f(X

CIN) Sub-clock oscillation frequency 32.768 50 kHz

Notes 1. Average output current is the average value of a 100 ms interval.

2. The sum of I

the sum of I
the sum of I
the sum of I

3. Limits V

4. The maximum value of f(X

OL(peak) for ports P0, P1, P2, P3, P8, and P9 must be 80 mA or less,
OH(peak) for ports P0, P1, P2, P3, P8, and P9 must be 80 mA or less,
OL(peak) for ports P4, P5, P6, P7, and P10 must be 100 mA or less, and
OH(peak) for ports P4, P5, P6, P7, and P10 must be 80 mA or less.

IH and VIL for XCIN are applied when the sub clock external input selection bit = “1”.

IN) = 12.5 MHz when the main clock division selection bit = “1”.

Limits

Vcc
Vcc

Vcc

0.2Vcc

0.2Vcc

0.16Vcc

–10

–5

10

20

5

Unit

V

V
V

V

V

V
V

mA

mA

mA

mA

mA

10