NEC UPD75P108BGF-3BE

DATA SHEET
MOS INTEGRATED CIRCUIT
µPD75P108B
4-BIT SINGLE-CHIP MICROCOMPUTER
DESCRIPTION
The µPD75P108B is a version of the µPD75108 in which the on-chip mask ROM is replaced by one-time
PROM which can be written to once only, or EPROM which is capable of program write, erasure and rewrite.
Also, since the µPD75P108B is capable of program write by a user, it can easily be exchanged with the mask
version, allowing evaluation at low voltage.
Detailed functional descriptions are shown in the following User’s Manual. Be sure to read for designations.
µPD751×× Series User’s Manual : IEM-922
FEATURES
• Version with on-chip PROM, allowing low-voltage operation VDD = 2.7 to 6.0 V
• µPD75108 compatible
• Memory capacity
• Program memory (PROM) : 8064 × 8 bits
: 512 × 4 bits
• Data memory (RAM)
• Correspondence to QTOP™ microcomputer
ORDERING INFORMATION
Ordering Code
µ PD75P108BCW
µ PD75P108BDW
µ PD75P108BGF-3BE
Note
Package
On-Chip ROM
64-pin plastic shrink DIP (750 mil)
64-pin ceramic shrink DIP (with window)
One-time PROM
EPROM
64-pin plastic QFP (14 × 20 mm, 1.0 mm pitch)
One-time PROM
★
There is no on-chip pull-up resistor function by means of a mask option.
QUALITY GRADE
Standard
Please refer to “Quality grade on NEC Semiconductor Devices” (Document number IEI-1209) published by
NEC Corporation to know the specification of quality grade on the devices and its recommended applications.
In this ducument, common parts of one-time PROM products and EPROM products are represented as
PROM.
The information in this document is subject to change without notice.
Document No. IC-2580C
(O. D. No.
IC-7987C)
Date Published December 1993 P
Printed in Japan
The mark ★ shows major revised points.
© NEC Corporation 1989
µPD75P108B
PIN CONFIGURATION (TOP VIEW)
64-pin plastic shrink DIP (750 mil)
64-pin ceramic shrink DIP
(with window)
2
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
µPD75P108BCW
µPD75P108BDW
P13/INT3
P12/INT2
P11/INT1
P10/INT0
PTH03
PTH02
PTH01
PTH00
TI0
TI1
P23
P22/PCL
P21/PTO1
P20/PTO0
P03/SI
P02/SO
P01/SCK
P00/INT4
P123
P122
P121
P120
P133
P132
P131
P130
P143
P142
P141
P140
V PP
V DD
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
V SS
P90
P91
P92
P93
P80
P81
P82
P83
P70
P71
P72
P73
P60
P61
P62
P63
X1
X2
RESET
P50
P51
P52
P53
P40
P41
P42
P43
P30/MD0
P31/MD1
P32/MD2
P33/MD3
µPD75P108B
P42
P43
P30/MD0
P31/MD1
P32/MD2
P33/MD3
V DD
V PP
P140
P141
P142
P143
P130
64-pin plastic QFP (14 × 20 mm, 1.0 mm pitch)
64 636261605958575655545352
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
µPD75P108BGF-3BE
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
P131
P132
P133
P120
P121
P122
P123
P00/INT4
P01/SCK
P02/SO
P03/SI
P20/PTO0
P21/PTO1
P22/PCL
P23
T11
T10
PTH00
PTH01
m
P81
P80
P93
P92
P91
P90
V SS
P13/INT3
P12/INT2
P11/INT1
P10/INT0
PTH03
PTH02
P41
P40
P53
P52
P51
P50
RESET
X2
X1
P63
P62
P61
P60
P73
P72
P71
P70
P83
P82
3
µPD75P108B
OVERVIEW OF FUNCTIONS
Description
Item
Basic instructions
43
Minimum instruction
execution time
0.95 µs, 1.91 µs, 15.3 µs (4.19 MHz operation)
3-stage switching capability
ROM
8064 × 8
RAM
512 × 4
Internal memory
General register
4-bits × 8 × 4 banks (memory mapping)
Accumulator
3 types of accumulators corresponding to bit length of manipulated data
• 1-bit accumulator (CY),
4-bit accumulator (A),
8-bit accumulator (XA)
Input/output port
Total 58
• CMOS input pins
• CMOS input/output pins (LED direct drive capability)
• Middle-high voltage N-ch open-drain input/output pins
(LED direct drive capability)
• Comparator input pins (4-bit precision)
Timer/counter
• 8-bit timer/event counter × 2
• 8-bit basic interval timer (watchdog timer applicable)
8-bit serial interface
• Two transfer modes
• Serial transmity receive mode
• Serial receive mode
• LSB-first/MSB-first switchable
Vectored interrupt
External : 3, internal : 4
Test input
External : 2
Standby
• STOP/HALT mode
Instruction set
★
4
•
•
•
•
: 10
: 32
: 12
: 4
Various bit manipulation instructions (set, reset, test, boolean operation)
8-bit data transfer, comparison, operation, increment/decrement instructions
1-byte relative branch instruction
GETI instruction that can implement arbitrary 2-byte/3-byte instructions with 1
byte
Others
• Bit manipulation memory (bit sequential buffer : 16 bits) on-chip
Package
• 64-pin plastic shrink DIP (750 mil)
• 64-pin ceramic shrink DIP (with window)
• 64-pin plastic QFP (14 × 20mm, 1.0 mm pitch)
INTBT
SP(8)
PROGRAM
COUNTER (13)
ALU
TIMER/EVENT
COUNTER
#0
TI0
PTO0/P20
PORT 0
4
P00-P03
PORT 1
4
P10-P13
PORT 2
4
P20-P23
PORT 3
4
P30-P33
/MD0-MD3
PORT 4
4
P40-P43
PORT 5
4
P50-P53
PORT 6
4
P60-P63
PORT 7
4
P70-P73
PORT 8
4
P80-P83
PORT 9
4
P90-P93
PORT 12
4
P120-P123
PORT 13
4
P130-P133
PORT 14
4
P140-P143
BLOCK DIAGRAM
BIT SEQ.
BUFFER
(16)
BASIC
INTERVAL
TIMER
CY
BANK
INTT0
TIMER/EVENT
COUNTER
#1
TI1
PTO1/P21
INTT1
SI/P03
SERIAL
INTERFACE
SO/P02
SCK/P01
GENERAL REG.
ROM
PROGRAM
MEMORY
8064 × 8 BITS
DECODE
AND
CONTROL
RAM DATA
MEMORY
512 × 4 BITS
INTSIO
INT0/P10
INT1/P11
INT2/P12
INT3/P13
INT4/P00
PTH00-PTH03
INTERRUPT
CONTROL
fXX / 2
4
PROGRAMMABLE
THRESHOLD
PORT #0
CLOCK
OUTPUT
CONTROL
CLOCK
GENERATOR
X1
X2
STAND BY
CONTROL
CPU CLOCK
Φ
VPP VDD
VSS RESET
5
µPD75P108B
PCL/P22
CLOCK
DIVIDER
N
µPD75P108B
CONTENTS
1.
★
PIN FUNCTIONS ....................................................................................................................................
7
1.1
1.2
1.3
1.4
PORT PINS .....................................................................................................................................................
OTHER PINS ...................................................................................................................................................
PIN INPUT/OUTPUT CIRCUITS ...................................................................................................................
RECOMMENDED CONNECTION OF UNUSED PINS .................................................................................
7
8
9
11
1.5
CAUTION ON USING P00/INT4 PIN AND RESET PIN ..............................................................................
12
2.
DIFFERENCES BETWEEN µPD75P108B AND µPD75P116 ................................................................. 12
3.
DIFFERENCES BETWEEN MASK VERSION (µPD75108) AND PROM VERSION (µPD75P108B) .. 13
4.
PROM (PROGRAM MEMORY) WRITE AND VERIFY .......................................................................... 14
★
4.1
PROGRAM MEMORY WRITE/VERIFY OPERATING MODES ...................................................................
14
4.2
4.3
4.4
4.5
PROGRAM MEMORY WRITE PROCEDURE ................................................................................................
PROGRAM MEMORY READ PROCEDURE .................................................................................................
ERASUER METHOD ( µPD75P108BDW only) ..............................................................................................
SCREENING OF ONE-TIME PROM PRODUCTS .........................................................................................
15
16
17
17
5.
ELECTRICAL SPECIFICATIONS ............................................................................................................ 18
6.
CHARACTERISTIC CURVE (REFERENCE VALUE) .............................................................................. 30
7.
RECOMMENDED SOLDERING CONDITIONS ..................................................................................... 36
8.
PACKAGE INFORMATION .................................................................................................................... 37
APPENDIX A. DEVELOPMENT TOOLS ...................................................................................................... 39
★
APPENDIX B. RELATED DOCUMENTATIONS .......................................................................................... 40
APPENDIX C. FONCTIONAL DIFFERENCE AMONG µPD751×× SERIES ................................................ 42
6
µPD75P108B
1. PIN FUNCTIONS
1.1
PORT PINS
Pin Name
Input/Output
DualFunction Pin
P00
Input
INT4
P01
Input/output
SCK
P02
Input/output
SO
P03
Input
SI
Function
8-bit I/O
After Reset
I/O Circuit
Type *1
B
F
4-bit input port (PORT 0).
Input
E
B
×
P10
INT0
P11
INT1
Input
B
Input
E
Programmable 4-bit input/output port (PORT 3).
MD0 to MD3 Input/output can be specified bit-wise.
*2
Input
E
INT2
P13
INT3
P20
PTO0
P21
PTO1
Input/output
P22
PCL
P23
—
4-bit input/output port (PORT 2).
×
*2
P30 to P33
Input/output
P40 to P43
Input/output
—
4-bit input/output port (PORT 4).
Data input/output pin for program memory
(PROM) write/verify (low-order 4 bits).
*2
Input
E
P50 to P53
Input/output
—
4-bit input/output port (PORT 5).
Data input/output pin for program memory
(PROM) write/verify (high-order 4 bits).
*2
Input
E
P60 to P63
Input/output
Programmable 4-bit input/output port (PORT 6).
Input/output can be specified bit-wise.
*2
Input
E
—
P70 to P73
Input/output
—
4-bit input/output port (PORT 7).
*2
Input
E
P80 to P83
Input/output
—
4-bit input/output port (PORT 8).
*2
Input
E
—
4-bit input/output port (PORT 9).
*2
Input
E
Input
M-A
Input
M-A
Input
M-A
P90 to P93
*
4-bit input port (PORT 1).
Input
P12
Input/output
P120-P123
Input/output
—
N-ch open-drain 4-bit input/output port (PORT
12).
+12 V withstand voltage.
*2
P130-P133
Input/output
—
N-ch open-drain 4-bit input/output port (PORT
13).
+12 V withstand voltage.
*2
P140-P143
Input/output
—
N-ch open-drain 4-bit input/output port (PORT
14).
+12 V withstand voltage.
*2
1.
2.
—
indicates Schmitt-triggered input.
LED direct drive capability
7
µPD75P108B
1.2
OTHER PINS
Pin Name
Input/Output
DualFunction Pin
PTH00 to PTH03
Input
—
Variable threshold voltage 4-bit analog input port.
N
Input
—
External event pulse input to timer/event counter.
Or edge detection vectored interrupt input pin, or 1-bit input
is also possible.
B
TI0
TI1
Input/output
I/O Circuit
Type *1
Timer/event counter output pin.
Input
E
P21
PTO1
SCK
Input/output
P01
Serial clock input/output pin.
Input
F
SO
Input/output
P02
Serial data output pin.
Input
E
SI
Input
P03
Serial data input pin.
Input
B
INT4
Input
P00
Edge detection vector interrupt input pin (detection of both
rising and falling edges).
B
Edge detection vector interrupt input pin (detection edge
selectable).
B
Edge detection testable input pin (rising edge detection)
B
P10
INT0
Input
P11
INT1
P12
INT2
Input
P13
INT3
PCL
Input/output
X1, X2
RESET
Input
MD0 to MD3
Input/output
P22
Clock output pin
—
System clock oscillation crystal/ceramic connection pin.
When an external clock is used, the clock is input to X1 and
the inverted clock is input to X2.
—
System reset input pin (low-level active).
P30 to P33
Mode selection pin for program memory (PROM) write/
verify.
VDD
—
Positive power supply pin. Applies +6 V for write/verify.
VSS
—
GND potential pin.
—
Program voltage impression pin for program memory (PROM)
write/verify.
Connected to VDD in normal operation.
Applies +12.5 V for PROM write/verify.
VPP *2
8
After Reset
P20
PTO0
*
Function
1.
2.
indicates Schmitt-triggered input.
The device will not operate correctly unless VPP is connected to VDD in normal use.
Input
E
B
Input
E
µPD75P108B
1.3 PIN INPUT/OUTPUT CIRCUITS
The input/output circuits of each pin of the µPD75P108B are shown by in abbreviated form.
(1) Type A (for Type E)
VDD
P-ch
IN
N-ch
CMOS standard input buffer
(2) Type B
IN
Schmitt-triggered input with hysteresis characteristic
(3) Type D (for Type E, F)
VDD
data
P-ch
OUT
output
disable
N-ch
Push-pull output that can be made high-impedance output (P-ch and N-ch OFF)
9
µPD75P108B
(4) Type E
data
IN/OUT
Type D
output
disable
Type A
This is an input/output circuit made up of a Type D push-pull output and Type A input buffer.
(5) Type F
data
IN/OUT
Type D
output
disable
Type B
This is an input/output circuit made up of a Type D push-pull output and Type B Schmitt-triggered input.
(6) Type M-A
IN/OUT
data
output
disable
N-ch
(+12 V
Withstand
Voltage)
Middle-High Voltage Input Buffer
(+12 V Withstand Voltage)
10
µPD75P108B
(7) Type N
Comparator
IN
+
–
VREF (Threshold Voltage)
1.4
RECOMMENDED CONNECTION OF UNUSED PINS
Recommended Connection
Pin
PTH00 to PTH03
TI0
Connect to VSS or VDD.
TI1
P00
Connect to VSS.
P01 to P03
Connect to VSS or VDD.
P10 to P13
Connect to VSS.
P20 to P23
P30 to P33
P40 to P43
P50 to P53
Input status
: Connect to VSS or VDD.
Output status
: Leave open.
P60 to P63
P70 to P73
P80 to P83
P90 to P93
P120 to P123
P130 to P133
P140 to P143
RESET
Connect to VDD.
11
µPD75P108B
1.5 CAUTION ON USING P00/INT4 PIN AND RESET PIN
The P00/INT4 and RESET pins have a test mode setting function (for IC test) which tests internal operations of
pin of the µPD75P108B in addition to those functions given in 1.1 and 1.2.
The test mode is set when voltage greater than VDD is applied to either pin. Therefore, even during normal
operation, the test mode is engaged when noise greater than VDD is added, thus causing interference with normal
operation.
For example, this problem may occure if the P00/INT4 and RESET pins wiring is too long, causing line noise.
To avoid this, try to suppress line noise in wiring. If line noise is still high, try elimminating the noise using the
exterior add-on components shown in the Figures below.
●
CONNECT A DIODE WITH LOW VF BETWEEN
THE VDD AND THE PIN.
●
CONNECT A CONDENSER BETWEEN
THE VDD AND THE PIN.
VDD
★
VDD
VDD
VDD
P00/INT4, RESET
P00/INT4, RESET
2. DIFFERENCES BETWEEN µPD75P108B AND µPD75P116
In addition to the µ PD75P108B, the µPD75P116 is available as µPD751×× series on-chip PROM device.
µPD75P108B
µPD75P116
8064 × 8 bits
16256 × 8 bits
2.7 to 6.0 V
5 V ±10%
12.5 V
12.5 V
–40 to +85 °C
–40 to +85 °C
Supply current TYP. value during operation
4 mA
5 mA
Supply current TYP. value in STOP mode
0.1 µA
0.5 µA
No
No
Parameter
PROM capacity
Operating voltage range
Write voltage
Operating temperature range
Power-on reset function
Package
12
• 64-pin plastic shrink DIP
• 64-pin ceramic shrink DIP (with window)
• 64-pin plastic QFP
(14 × 20 mm, 1.0 mm pitch)
• 64-pin plastic shrink DIP
• 64-pin plastic QFP
(14 × 20 mm, 1.0 mm pitch)
µPD75P108B
3. DIFFERENCES BETWEEN MASK VERSION (µPD75108) AND PROM VERSION (µPD75P108B)
Parameter
µPD75P108B
(PROM product)
µPD75108
(Mask ROM product)
• 0000H to 1F7FH
• 8064 × 8 bits
Program memory
Pull-up resistor of ports 12,13 and 14
★
No
Mask option
No
Mask option
Power-on reset circuit
Power-on reset
Power-on Flag
2.7 to 6.0 V
Operating voltage range
SDIP (Nos. 33 to 36)
QFP (Nos. 39 to 62)
P33/MD3 to P30/MD0
P33 to P30
VPP
NC
Pin connection
SDIP (No. 31)
QFP (No. 57)
Electrical specification
Different consumption current, etc.
Refer to the parameter for each data sheet for details.
Other
Different noise resistance, noise radiation, etc., due to
difference in the size of circuits and mask layout
Note
The PROM and ROM products differ in noise resistance and noise radiation. If you are considering
replacement of the PROM product by the ROM product in the transition from preproduction to volume
production, this should be evaluated thoroughly with the mask ROM CS product (not ES product).
13
µPD75P108B
4. PROM (PROGRAM MEMORY) WRITE AND VERIFY
The ROM built into the µPD75P108B is a 8064 × 8-bit PROM. The pins shown in the table below are used to
write/verify this PROM. There is no address input; instead, a method to update the address by the clock input
from the X1 pin is adopted.
Function
Pin Name
VPP
Voltage applecation pin for program memory write/verify
(normally VDD potential).
X1, X2
Address update clock inputs for program memory write/
verify. Inverse of X1 pin signal is input to X2 pin.
MD0 to MD3
Operating mode selection pin for program memory write/
verify.
P40 to P43 (low-order 4 bits) 8-bit data input/output pins for progrm memory write/
P50 to P53 (high-order 4 bits) verify.
Supply voltage application pin.
Applies 2.7 to 6.0 V in normal operation, and 6 V for
program memory write/verify.
VDD
Note
4.1
Pins not used in a program memory write/verify operation should be connected to VSS with a pulldown resistor.
PROGRAM MEMORY WRITE/VERIFY OPERATING MODES
The µPD75P108B assumes the program memory write/verify mode is +6 V and +12.5 V are applied respectively to the VDD and VPP pins. The table below shows the operating modes available by the MD0 to MD3 pin
setting in this mode.
Operating Mode Setting
Operating Mode
VPP
+12.5 V
VDD
MD0
MD1
MD2
MD3
H
L
H
L
Program memory address zero-clear
L
H
H
H
Write mode
L
L
H
H
Verify mode
H
×
H
H
Program inhibit mode
+6 V
× : L or H
14
µPD75P108B
4.2 PROGRAM MEMORY WRITE PROCEDURE
The program memory writing procedure is shown below. High-speed write is possible.
(1) Pull down a pin which is not used to VSS via the resistor. A low-level signal is input to the X1 pin.
(2) Supply +5 V to the VDD and VPP pins.
(3)
(4)
(5)
(6)
10 µs wait.
The program memory address 0 clear mode.
Supply +6 V and +12.5 V respectively to VDD and VPP.
The program inhibit mode.
(7)
(8)
(9)
(10)
Write data in the 1-ms write mode.
The program inhibit mode.
The verify mode. If written, proceed to (10); if not written, repeat (7) to (9).
(Number of times written in (7) to (9): X) x 1-ms additional write.
(11)
(12)
(13)
(14)
The program inhibit mode.
Update (+1) the program memory address by inputting 4 pulses to the X1 pin.
Repeat (7) to (12) up to the last address.
The program memory address 0 clear mode.
(15) Change the VDD and VPP pins voltage to +5 V.
(16) Power off.
The diagram below shows the procedure of the above (2) to (12).
Repeated X Times
Write
Verify
Additional
Write
Address
Increment
VPP
VPP
VDD
VDD + 1
VDD
VDD
X1
P40-P43
P50-P53
Data Input
Data Output
Data Input
MD0
MD1
MD2
MD3
15
µPD75P108B
4.3 PROGRAM MEMORY READ PROCEDURE
The µPD75P108B can read the content of the program memory in the following procedure.
(1) Pull down a pin which is not used to VSS via the resistor. A low-level signal is input to the X1 pin.
(2) Supply +5 V to the VDD and VPP pins.
10 µs wait.
The program memory address 0 clear mode.
Supply +6 V and +12.5 V respectively to VDD and VPP.
The program inhibit mode.
(3)
(4)
(5)
(6)
(7) The verify mode. If clock pulses are input to the X1 pin, data is output sequentially 1 address at a time at
the period of inputting 4 pulses.
(8) The program inhibit mode.
(9) The program memory address 0 clear mode.
(10) Change the VDD and VPP pins voltage to +5 V.
(11) Power off.
The diagram below shows the procedure of the above (2) to (9).
VPP
VPP
VDD
VDD + 1
VDD
VDD
X1
P40-P43
P50-P53
Data Output
MD0
MD1
MD2
MD3
16
"L"
Data Output
µPD75P108B
4.4 ERASURE METHOD ( µPD75P108BDW only)
The data contents programmed in the µPD75P108BDW can be erased by exposure to ultra-violet rays via the
upper window.
The wavelength of erasable UVR is approx. 250 nm. The irradiation amount required for complete erasure is
15Ws/cm 2 (UVR intensity × erasure time).
Erasure requires approx. 15 to 20 minutes if a commercially available UVR lamp (wavelength 254 nm, intensity
12 mW/cm2).
Note 1. If exposed directly to sunshine or a fluorescent light for a long period, the contents may be erased. For
protection of the contents, mask the upper window with the lightshield cover film. Use the lightshield
cover film provided by NEC for UV EPROM products.
Note 2. When performing erasure, ensure that the distance between the UV lamp and the µPD75P108BDW is 2.5
cm or less.
Remarks
The erasure time may be increased due to deterioration of the UV lamp, dirt or stains on the package
window surface.
4.5 SCREENING OF ONE-TIME PROM PRODUCTS
Due to the nature of their construction, it is not possible for NEC to fully test one-time PROM products
(µPD75P108BCW, µPD75P108BGF-3BE) before shipment. It is therefore recommended that screening which performs PROM verification be carried out after high-temperature storage under the conditions shown below once the
necessary data has been written to the device.
Storage Temperature
Storage Time
125 °C
24 hours
NEC offers a fee-paying service under the QTOP microcomputer name which covers one-time PROM writing,
marking, screening and verification. Please contact our salesman for details.
17
★
µPD75P108B
5. ELECTRICAL SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS (Ta = 25 °C)
PARAMETER
SYMBOL
Supply voltage
RATING
UNIT
–0.3 to + 7.0
V
–0.3 to 13.5
V
–0.3 to VDD + 0.3
V
–0.3 to +13
V
–0.3 to VDD + 0.3
V
1 pin
–15
mA
Total pins
–30
mA
Peak value
30
mA
Effective value
15
mA
Ports 0, 2 to 4,
12 to 14 total
Peak value
100
mA
Effective value
60
mA
Ports 5 to 9
total
Peak value
100
mA
Effective value
60
mA
VDD
Supply voltage
Input voltage
TEST CONDITIONS
VPP
VI1
VI2 *1
Output voltage
VO
Output current high
IOH
Except ports 12 to 14
Ports 12 to 14
1 pin
Output current low
*
IOL*2
Operating
temperature
Topt
–40 to +85
°C
Storage
temperature
Tstg
–65 to +150
°C
1.
The power supply impedance (pull-up resistor) should be 50 kΩ or more when the voltage exceeding
2.
10 V applied to ports 12, 13 and 14.
Effective value should be calculated as follows: [Effective value] = [Peak value] ×
√duty
OPERATING VOLTAGES (Ta = –40 to +85 °C)
MIN.
MAX.
UNIT
CPU *1
*2
6.0
V
Programmable threshold port
(comparator input)
4.5
6.0
V
Other hardware *1
2.7
6.0
V
PARAMETER
*
18
1.
2.
TEST CONDITIONS
Excluding system clock oscillation circuit and programmable threshold ports.
The operating voltage range varies depending on the CPU clock cycle time.
See "AC characteristics".
µPD75P108B
CAPACITANCE (Ta = 25 °C, VDD = 0 V)
PARAMETER
Input capacitance
Output capacitance
I/O capacitance
SYMBOL
CIN
COUT
TEST CONDITIONS
MIN.
TYP.
f = 1 MHz
Unmeasured pins returned to
0 V.
CIO
MAX.
UNIT
15
pF
15
pF
15
pF
MAX.
UNIT
±100
mV
COMPARATOR CHARACTERISTICS (Ta = –40 to +85 °C, VDD = 4.5 to 6.0 V)
PARAMETER
SYMBOL
Comparison accuracy
VACOMP
TEST CONDITIONS
MIN.
TYP.
Threshold voltage
VTH
0
VDD
V
PTH input voltage
VIPTH
0
VDD
V
Comparator circuit
current consumption
PTHM7 set to "1"
1
mA
19
µPD75P108B
SYSTEM CLOCK OSCILLATION CIRCUIT CHARACTERISTICS (Ta = –40 to +85 °C, VDD = 2.7 to 6.0 V)
RESONATOR
RECOMMENDED
CIRCUIT
X2
★
Ceramic
resonator
Crystal
resonator
TEST CONDITIONS
MIN.
Oscillator
frequency (fXX) *1
VDD = Oscillation voltage
VDD = range
2.0
Oscillation
stabilization time *2
After VDD reaches oscillator voltage range MIN.
X1 V SS
Oscillator
frequency (fXX) *1
X1
*
1.
2.
3.
★
2.0
4.19
C1
C2
Oscillation
stabilization time *2
External
clock
TYP.
MAX.
UNIT
*3
5.0
MHz
4
ms
*3
5.0
MHz
10
ms
30
ms
C1
C2
X2
★
X1 V SS
PARAMETER
X2
µPD74HCU04
VDD = 4.5 to 6.0 V
X1 input
frequency (fX) *1
2.0
5.0
MHz
X1 input
high/low level width
(tXH , tXL )
100
250
ns
Indicates only oscillation circuit characteristics.
Refer to “AC Characteristics” for instruction execution time.
Time required to stabilize oscillation after VDD impression or STOP mode release.
When using a value of fx such that 4.19MHz<fxx≤5.0MHz, if the maximum speed mode:Φ=fx/4 is set as the
CPU clock frequency, 1 machine cycle becomes less than 0.95µs, with the result that the specified MIN
value of 0.95 cannot be observed.
★
Note
When the system clock oscillator is used, the following points should be noted concerning wiring in the
section enclosed by dots, in order to prevent the effects of wiring capacitance, etc.
• Keep the wiring as short as possible.
• Do not cross any other signal lines, and keep clear of lines in which a high fluctuating current
flows.
• Ensure that oscillator capacitor connection points are always at the same potential as VSS. Do not
ground in a ground pattern in which a high current flows.
• Do not take a signal from the oscillator.
20
µPD75P108B
RECOMMENDED CERAMIC RESONATOR
MANUFACTURER
Murata Mfg. Co.,
Ltd.
PART NAME
EXTERNAL CAPACITANCE OSCILLATION VOLTAGE RANGE
C1 (pF)
C2 (pF)
MIN. (V)
MAX. (V)
CSAx.xxMG
2.00 to 5.00
30
30
CSTx.xxMG
2.00 to 5.00
30
30
CSTx.xxMGW
2.45 to 5.00
30
30
2.0 to 2.5
100
100
2.6 to 6.0
33
33
3.00 to 4.19
27
27
Kyocera Corporation KBR-x.xMS
Toko, Inc.
FREQUENCY (MHz)
CRHFx.xx
2.7
6.0
2.7
6.0
3.0
6.0
RECOMMENDED CRYSTAL RESONATOR
MANUFACTURER
Kinseki, Ltd.
PART NAME
HC-49/U
FREQUENCY (MHz)
2.00 to 5.00
EXTERNAL CAPACITANCE OSCILLATION VOLTAGE RANGE
C1 (pF)
C2 (pF)
MIN. (V)
MAX. (V)
22
22
2.7
6.0
21
µPD75P108B
DC CHARACTERISTICS (Ta = –40 to +85 °C, VDD = 2.7 to 6.0 V)
PARAMETER
Input voltage high
Input voltage low
Output voltage high
Output voltage low
SYMBOL
TEST CONDITIONS
UNIT
0.7VDD
0.8V DD
0.7VDD
VDD
VDD
12
V
V
V
VIH4
X1, X2
VDD–0.5
VDD
V
VIL1
Other than below
0
0.3VDD
V
VIL2
Ports 0 & 1, TI0 & 1, RESET
0
0.2VDD
V
VIH3
X1, X2
0
0.4
V
VOH
VOL
VDD = 4.5 to 6.0 V,
IOH = –1 mA
VDD–1.0
V
IOH = –100 µA
VDD–0.5
V
VDD =
Ports 0, 2, to 9, I OL = 15 mA
0.35
2.0
V
4.5 to 6.0 V
Ports 12 to 14, I OL = 10 mA
0.35
2.0
V
VDD = 4.5 to 6.0 V,
IOL = 1.6 mA
0.4
V
IOL = 400 µA
0.5
V
3
µA
X1, X2
20
µA
Ports 12 to 14
20
µA
Except X1 & X2
–3
µA
X1, X2
–20
µA
Other than below
VIN = VDD
ILIH2
VIN = 12 V
Input leakage
current low
ILIL1
Output leakage
current high
ILOH1
VOUT = VDD
Other than below
3
µA
ILOH2
VOUT = 12 V
Ports 12 to 14
20
µA
ILOL
VOUT = 0 V
–3
µA
Output leakage
current low
VIN = 0 V
ILIL2
IDD1
Power supply
current *1
IDD2
IDD3
22
MAX.
Other than below
Ports 0 & 1, TI0 & 1, RESET
Ports 12 to 14
ILIH3
*
TYP.
VIH1
VIH2
VIH3
ILIH1
Input leakage
current high
MIN.
4.19 MHz
Crystal oscillation
C1 = C2 = 22 pF
VDD = 5 V ± 10 % *2
4
10
mA
VDD = 3 V ± 10 % *3
1
2.5
mA
VDD = 5 V ± 10 %
600
1800
µA
VDD = 3 V ± 10 %
200
600
µA
0.1
10
µA
HALT
mode
STOP mode, VDD = 3 V ± 10 %
1.
Not including current flowing in comparator.
2.
3.
When processor clock control register (PCC) is set to 0011 and CPU is operating in high-speed mode.
When PCC is set to 0000 and CPU is operating in low-speed mode.
µPD75P108B
AC CHARACTERISTICS (Ta = –40 to +85 °C, VDD = 2.7 to 6.0 V)
PARAMETER
SYMBOL
CPU clock cycle time*
(minimum instruction
execution time = 1 machine cycle)
TEST CONDITIONS
MIN.
VDD = 4.5 to 6.0 V
TI0, TI1 input high/lowlevel width
MAX.
UNIT
0.95
32
µs
3.8
32
µs
0
1
MHz
0
275
kHz
fTI
tTIH,
0.48
µs
1.8
µs
Input
0.8
µs
Output
0.95
µs
Input
3.2
µs
Output
3.8
µs
Input
0.4
µs
tKCY/2–50
ns
1.6
µs
tKCY/2–150
ns
VDD = 4.5 to 6.0 V
tTIL
VDD = 4.5 to 6.0 V
SCK cycle time
tKCY
VDD = 4.5 to 6.0 V
SCK high/low-level width
★
tCY
VDD = 4.5 to 6.0 V
TI0, TI1 input frequency
TYP.
tKH,
Output
tKL
Input
Output
SI setup time (to SCK↑)
tSIK
100
ns
SI hold time (from SCK↑)
tKSI
400
ns
SO output delay time
from SCK↓
tKSO
VDD = 4.5 to 6.0 V
tINTH,
INT0 to INT4 high/lowlevel width
tINTL
RESET low level width
tRSL
tCY
VS.
300
ns
1000
ns
5
µs
5
µs
VDD
★
40
The cycle time of the CPU
clock (Φ) is determined by
the oscillator frequency of
32
7
6
the connected resonator
and the processor clock
control register (PCC). The
graph on the right shows
cycle time tCY characteristics against supply voltage
VDD when system clock is
operated.
5
Operation
Guaranteed
Range
4
tCY [µs]
*
3
2
1
0.5
0
1
2
3
4
5
6
VDD [V]
23
µPD75P108B
AC Timing Test Point (Excluding ports 0 & 1, TI0, TI1, X1, X2, RESET)
0.7 VDD
0.3 VDD
0.7 VDD
0.3 VDD
Test Points
Clock Timing
1/fX
tXL
tXH
VDD - 0.5
0.4
X1 Input
TI0, TI1 Input Timing
1/fTI
tTIL
TI0, TI1
24
tTIH
0.8 VDD
0.2 VDD
µPD75P108B
Serial Transfer Timing
tKCY
tKL
tKH
0.8 VDD
0.2 VDD
SCK
tSIK
tKSI
0.8 VDD
Input Data
SI
0.2 VDD
tKSO
SO
Output Data
Interrupt Input Timing
tINTL
tINTH
0.8 VDD
INT0-INT4
0.2 VDD
RESET Input Timing
tRSL
RESET
0.2 VDD
25
µPD75P108B
DATA MEMORY STOP MODE LOW SUPPLY VOLTAGE DATA RETENTION CHARACTERISTICS (Ta = –40 to
+85 °C)
PARAMETER
SYMBOL
Data retention supply voltage
VDDDR
Data retention power supply current *1
IDDDR
Release signal set time
tSREL
Oscillation stabilization wait time
tWAIT
*
1.
2.
3.
TEST CONDITIONS
MIN.
TYP.
2.0
VDDDR = 2.0 V
0.1
0
217/f x
*3
Release by RESET
Release by interrupt request
MAX.
UNIT
6.0
V
10
µA
µs
ms
ms
Does not include current flowing in the comparator.
The oscillator stabilization wait time is the time during which CPU operation is halted to prevent
unstable operation when oscillation begins.
Depends on the setting of the basic interval timer mode register (BTM) (table below).
BTM3 BTM2 BTM1 BTM0
WAIT Time (Figure in Parentheses is for fXX = 4.19 MHz)
–
0
0
0
220/fXX (Approx. 250 ms)
–
0
1
1
217/fXX (Approx. 31.3 ms)
–
1
0
1
215/fXX (Approx. 7.82 ms)
–
1
1
1
213/fXX (Approx. 1.95 ms)
Data Retention Timing (STOP Mode Release by RESET)
Internal RESET Operation
HALT Mode
Operating Mode
STOP Mode
Data Retention Mode
VDD
tSREL
VDDDR
STOP Instruction Execution
RESET
tWAIT
Data Retention Timing (Standby Release Signal: STOP Mode Release by Interrupt Signal)
HALT Mode
Operating Mode
STOP Mode
Data Retention Mode
VDD
VDDDR
tSREL
STOP Instruction Execution
Standby Release Signal
(Interrupt Request)
tWAIT
26
µPD75P108B
DC PROGRAMMING CHARACTERISTICS (Ta = 25 °C, VDD = 6.0 ±0.25 V, VPP = 12.5 ±0.3 V, VSS = 0 V)
PARAMETER
SYMBOL
TEST CONDITIONS
MIN.
TYP.
MAX.
UNIT
VIH1
Except X1 & X2
0.7V DD
VDD
V
VIH2
X1, X2
VDD–0.5
VDD
V
VIL1
Except X1 & X2
0
0.3VDD
V
VIL2
X1, X2
0
0.4
V
10
µA
Input voltage high
Input voltage low
Input leakage current
ILI
Output voltage high
VOH
IOH = –1 mA
Output voltage low
VOL
IOL = 1.6 mA
VDD supply current
IDD
VPP supply current
IPP
Note 1.
2.
VIN = VIL or VIH
V
VDD–1.0
MD0 = VIL, MD1 = VIH
0.4
V
30
mA
30
mA
Ensure that VPP does not reach +13.5 V or above including overshot.
Ensure that VDD is applied before VPP and cut off after VPP.
27
µPD75P108B
AC PROGRAMMING CHARACTERISTICS (Ta = 25 °C, VDD = 6.0 ±0.25 V, VPP = 12.5 ±0.3 V, VSS = 0 V)
PARAMETER
★
★
Address setup time *2 (to MD0↓)
tAS
tAS
2
µs
MD1 setup time (to MD0↓)
tM1S
tOES
2
µs
Data setup time (to MD0↓)
tDS
tDS
2
µs
Address hold time *2 (from MD0↑)
tAH
tAH
2
µs
Data hold time (from MD0↑)
tDH
tDH
2
µs
Data output float delay time from MD0↑
tDF
tDF
0
VPP setup time (to MD3↑)
tVPS
tVPS
2
µs
VDD setup time (to MD3↑)
tVDS
tVCS
2
µs
Initial program pulse width
tPW
tPW
0.95
Additional program pulse width
tOPW
tOPW
0.95
MD0 setup time (to MD1↑)
tMOS
tCES
2
Data output delay time from MD0↓
tDV
tDV
MD1 hold time (from MD0↑)
tM1H
tOEH
MD1 recovery time (from MD0↓)
tM1R
tOR
Program counter reset time
tPCR
MIN.
MD0 = MD1 = VIL
MAX.
130
1.0
UNIT
ns
1.05
ms
21.0
ms
µs
1
µs
2
µs
2
µs
—
10
µs
tXH, tXL
—
0.125
µs
X1 input frequency
fX
—
Initial mode setting time
tI
—
2
µs
MD3 setup time (to MD1↑)
tM3S
—
2
µs
MD3 hold time (from MD1↓)
tM3H
—
2
µs
MD3 setup time (to MD0↓)
tM3SR
—
In program memory read
2
µs
Address *2 data output delay time
tDAD
tACC
In program memory read
Address *2 data output hold time
tHAD
tOH
In program memory read
0
MD3 hold time (from MD0↑)
tM3HR
—
In program memory read
2
Data output float delay time from MD3↓
tDFR
—
In program memory read
*
28
TYP.
*1
X1 input high-/low-level width
★
TEST CONDITIONS
SYMBOL
tM1H + tM1R ≥ 50 µs
4.19
MHz
2
µs
130
ns
µs
2
µs
1.
Corresponding to µPD27C256A symbol.
2.
Internal address signal is incremented by 1 on rise of 4th X1 input, and is not connected to a pin.
µPD75P108B
Program Memory Write Timing
tVPS
VPP
VPP
VDD
tVDS
VDD + 1
VDD
VDD
tXH
X1
Data Output
tXL
P40-P43
P50-P53
Data Input
Data Input
tDS
t1
tDV
tOH
tDF
Data Input
tDH
tAH
tDS
tAS
MD0
tM1R
tPW
tOPW
tMOS
MD1
tPCR
tMIS
tM1H
MD2
tM3H
tM3S
MD3
Program Memory Read Timing
tVPS
VPP
VPP
VDD
tVDS
tXH
VDD + 1
VDD
VDD
X1
tXL
tDAD
tHAD
P40-P43
P50-P53
t1
Data Output
Data Output
tDFR
tDV
tM3HR
MD0
MD1
tPCR
MD2
tM3SR
MD3
29
µPD75P108B
6. CHARACTERISTIC CURVE (REFERENCE VALUE)
IDD vs VDD (Crystal Oscillation)
(Ta = 25 °C)
10000
High-Speed Mode
Middle-Speed Mode
Low-Speed Mode
HALT Mode
Power Supply Current IDD (µ A)
1000
X1
100
X2
Crystal
4.19 MHz
22 pF
22 pF
10
0
1
2
3
4
5
Power Supply Voltage VDD (V)
30
6
7
µPD75P108B
IDD vs VDD (Ceramic Oscillation)
(Ta = 25 °C)
10000
High-Speed Mode
Middle-Speed Mode
Low-Speed Mode
1000
Power Supply Current IDD (µ A)
HALT Mode
X1
100
X2
Ceramic Resonator
4.19 MHz
30 pF
30 pF
10
0
1
2
3
4
5
6
7
Power Supply Voltage VDD (V)
31
µPD75P108B
IDD vs VDD (Crystal Oscillation)
(Ta = 25 °C)
10000
High-Speed Mode
Middle-Speed Mode
Low-Speed Mode
1000
Power Supply Current IDD (µ A)
HALT Mode
X1
100
X2
Crystal
2.00 MHz
22 pF
22 pF
10
0
1
2
3
4
5
Power Supply Voltage VDD (V)
32
6
7
µPD75P108B
IDD vs Ta (Crystal Oscillation)
(VDD = 5V)
10000
High-Speed Mode
Middle-Speed Mode
Low-Speed Mode
Power Supply Current IDD (µ A)
1000
HALT Mode
X1
100
X2
Crystal
4.19 MHz
22 pF
22 pF
10
–40
0
40
80 85
Ambient Temperature Ta (°C)
33
µPD75P108B
IDD vs fX (External Clock)
IDD vs fX (External Clock)
(VDD = 5 V, Ta = 25 °C)
(VDD = 3 V, Ta = 25 °C)
X1
X2
X1
1.5
X2
Middle-Speed Mode
µPD74HCU04
1.0
µPD74HCU04
3
Low-Speed
Mode
0.5
Power Supply Current IDD (mA)
Power Supply Current IDD (mA)
High-Speed Mode
Middle-Speed
Mode
2
Low-Speed Mode
1
HALT Mode
HALT Mode
0
0
2
3
4
X1 Input Frequency fx (MHz)
34
5
0
2
3
4
X1 Input Frequency fx (MHz)
5
µPD75P108B
VOL vs IOL (Ports 12, 13 and 14)
VOL vs IOL (Ports 0 and 2 to 9)
VDD = 5 V
30
VDD = 6 V
VDD = 4 V
VDD = 3 V
20
VDD = 2.7 V
10
0
1
2
3
Low-Level Output Voltage VOL (V)
(Ta = 25 °C)
Low-Level Output Current IOL (mA)
Low-Level Output Current IOL (mA)
(Ta = 25 °C)
VDD = 5 V
30
VDD = 6 V
VDD = 4 V
VDD = 3 V
20
VDD = 2.7 V
10
0
1
2
3
Low-Level Output Voltage VOL (V)
VDD – VOH vs IOH
(Ta = 25 °C)
VDD = 5 V
IOH (mA)
15
VDD = 6 V
VDD = 4 V
VDD = 3 V
10
VDD = 2.7 V
5
0
1
2
3
VDD–VOH (V)
35
µPD75P108B
★
7. RECOMMENDED SOLDERING CONDITIONS
The µPD75P108B should be mounted under the conditions recommended in the table below.
For details of recommended soldering conditions for the surface mounting type, refer to the information
document “Surface Mount Technology Manual” (IEI-1207)
For soldering methods and conditions other than those recommended below, contact our salesman.
Table 7-1 Surface Mount Type Soldering Conditions
µPD75P108BGF-3BE : 64-pin plastic QFP (14 × 20 mm, 1.0 mm pitch)
Soldering Method
*
Soldering Conditions
Recommended
Condition Symbol
Infrared reflow
Package peak temperature: 230°C, Duration: 30 sec. max.
(at 210°C or above), Number of times: Once
Time limit: 2 days* (thereafter 16 hours prebaking required
at 125°C)
VPS
Package peak temperature: 215°C, Duration: 40 sec. max.
(at 200°C or above), Number of times: 0nce
Time limit: 2 days* (thereafter 16 hours prebaking required
at 125°C)
Wave soldering
Solder bath temperature: 260°C max., Duration: 10 sec. max
Number of times: Once
Preheating temperature: 120°C max. (package surface
temperature),
Time limit: 2days* (thereafter 16 hours prebaking required
at 125°C)
WS60-162-1
Pin part heating
Pin part temperature: 300°C max., Duration 3 sec. max.
(per device lead)
Pin part heating
IR30-162-1
VP15-162-1
For the storage period after dry-pack decapsulation, storage conditions are max. 25°C, 65% 1H.
Note
Use of more than one soldering method should be avoided (except in the case of pin part heating).
Table 7-2 Insertion Type Soldering Conditions
µPD75P108BCW : 64-pin plastic shrink DIP (750 mil)
µPD75P108BDW : 64-pin ceramic shrink DIP (with window)
Soldering Method
Soldering Conditions
Wave Soldering (lead part only)
Solder bath temperature: 260°C max., Duration: 10sec. max.
Pin part heating
Pin part temperature: 260°C max., Duration: 10sec. max.
Note
Ensure that the application of (wave soldering) is limited to the lead part and no solder touches
the main unit directly.
For Your Information
Products to improve the recommended soldering conditions are available.
(Improvements: Extension of the infrared reflow peak temperature to 235°C, doubled frequency, increased
life, etc.)
For further details, consult our sales personnel.
36
µPD75P108B
8. PACKAGE INFORMATION
64 PIN PLASTIC SHRINK DIP (750 mil)
64
33
1
32
A
K
H
G
J
I
L
F
D
N
M
NOTE
M
B
C
ITEM MILLIMETERS
R
INCHES
1) Each lead centerline is located within 0.17 mm (0.007 inch) of
its true position (T.P.) at maximum material condition.
A
58.68 MAX.
2.311 MAX.
B
1.78 MAX.
0.070 MAX.
2) Item "K" to center of leads when formed parallel.
C
1.778 (T.P.)
0.070 (T.P.)
D
0.50±0.10
0.020 +0.004
–0.005
F
0.9 MIN.
0.035 MIN.
G
3.2±0.3
0.126±0.012
H
0.51 MIN.
0.020 MIN.
I
4.31 MAX.
0.170 MAX.
J
5.08 MAX.
0.200 MAX.
K
19.05 (T.P.)
0.750 (T.P.)
L
17.0
0.669
M
0.25 +0.10
–0.05
0.010 +0.004
–0.003
N
0.17
0.007
R
0~15°
0~15°
P64C-70-750A,C-1
37
µPD75P108B
64 PIN CERAMIC SHRINK DIP (SEAM WELD) (750 mil)
64
33
1
32
A
K
J
I
G
H
L
C
F
D
N
R
M
B
M
NOTES
1) Each lead centerline is located within 0.25 mm (0.01 inch) of
its true position (T.P.) at maximum material condition.
2) ltem "K" to center of leads when formed parallel.
ITEM MILLIMETERS
INCHES
A
58.68 MAX.
2.310 MAX.
B
1.78 MAX.
0.070 MAX.
C
1.778 (T.P.)
0.070 (T.P.)
D
0.46±0.05
0.018±0.002
F
0.8 MIN.
0.031 MIN.
G
3.5±0.3
0.138±0.012
H
1.0 MIN.
0.039 MIN.
I
2.62
0.103
J
5.08 MAX.
0.200 MAX.
K
19.05 (T.P.)
0.750 (T.P.)
L
18.8
0.740
M
0.25±0.05
0.010 +0.002
–0.003
N
R
0.25
0~15°
0.01
0~15°
P64D-70-750A-1
38
µPD75P108B
64 PIN PLASTIC QFP (14×20)
A
B
detail of lead end
33
32
51
52
C
D
S
R
Q
64
1
20
19
F
G
H
I
M
J
K
M
P
N
L
NOTE
Each lead centerline is located within 0.20 mm (0.008 inch) of
its true position (T.P.) at maximum material condition.
ITEM
MILLIMETERS
INCHES
A
23.6±0.4
0.929±0.016
B
20.0±0.2
0.795 +0.008
–0.009
C
14.0±0.2
0.551+0.009
–0.008
D
17.6±0.4
0.693±0.016
F
1.0
0.039
G
1.0
0.039
H
0.40±0.10
0.016 +0.004
–0.005
0.008
I
0.20
J
1.0 (T.P.)
0.039 (T.P)
K
1.8±0.2
0.071 +0.008
–0.009
L
0.8±0.2
0.031 +0.009
–0.008
M
0.15 +0.10
–0.05
0.006 +0.004
–0.003
N
P
Q
R
S
0.10
0.004
2.7
0.106
0.1±0.1
0.004±0.004
5°±5°
5°±5°
3.0 MAX.
0.119 MAX.
P64GF-100-3B8,3BE,3BR-2
39
µPD75P108B
APPENDIX A. DEVELOPMENT TOOLS
Hardware
The following development tools are available for system development using the µPD75P108B.
40
In-circuit emulator for 75X series
IE-75000-R-EM *2
Emulation board for IE-75000-R and IE-75001-R
EP-75108CW-R
Emulation probe for µPD75P108BCW
EP-75108GF-R
Emulation probe for µPD75P108BGF
A 64-pin conversion socket EV-9200G-64 is provided.
EV-9200G-64
PG-1500
PROM programmar
PA-75P108CW
This is a PROM programmar adopter for µPD75P108BCW and connects to PG-1500.
PA-75P116GF
This is a PROM programmar adopter for µPD75P108BGF and connects to PG-1500.
IE control program
Software
*
IE-75000-R *1
IE-75001-R
PG-1500 controller
RA75X relocatable assembler
Host machine
PC-9800 series (MS-DOS™ Ver.3.30 to Ver.5.00A *3)
PC/AT™ series (PC-DOS™ Ver.3.10)
1
Maintenance product
2
3
This is not incorporated in the IE-75001-R.
A task swap function is not provided with Ver.5.00/5.00A; however, a task swap function cannot be used
with this software.
µPD75P108B
APPENDIX B. RELATED DOCUMENTATIONS
List of Device-Related Documentations
Document Name
Document No.
User's Manual
IEM-922
Instruction Using Table
IEM-902
(I) Introductory Volume
Application Note
IEM-980
(II) Remote-Controlled Reception Volume
IEM-5003
(III) Bar-Code Reade-Volume
IEM-5065
(IV) IC Control for MSK Transmission/Reception Volume
75X Series Selection Guide
IEA-694
IF-151
List of Development Tool Related Documentations
Software
Hardware
Document Name
Document No.
IE-75000-R/IE-75001-R User's Manual
EEU-846
IE-75000-R-EM User's Manual
EEU-673
EP-75108CW-R User's Manual
EEU-696
EP-75108GF-R User's Manual
EEU-695
PG-1500 User's Manual
EEU-651
Operation Volume
EEU-731
Language Volume
EEU-730
RA75X Assembler Package User's Manual
PG-1500 Controller User's Manual
EEU-704
Other Documentations
Document Name
Document No.
Package Manual
IEI-635
Surface Mount Technology Manual
IEI-1207
Quality Grade on NEC Semiconductor Devices
IEI-1209
NEC Semiconductor Device Reliability Quality Control
IEM-5068
Static Discharge (ESD) Test
MEM-539
Semiconductor Device Quality Guarantee Guide
MEI-603
Microcomputer Related Product Guide Other Manufacturer Volume
MEI-604
Note
The above related documentations may be changed without notice. Be sure to use the latest
documentations for designations.
41
µPD75P108B
[MEMO]
42
µPD75P108B
APPENDIX C. FONCTIONAL DIFFERENCES AMONG µPD751×× SERIES
Product Name
Item
µPD75104/106/108/112/116
µPD75104A/108A
µPD75108F/112F/116F
4K/6K/8K/12K/16K
(Mask ROM)
320/320/512/512/512
4K/8K
(Mask ROM)
320/512
8K/12K/16K
(Mask ROM)
512
ROM (byte)
RAM (× 4 bits)
Instruction set
75X High-End
I/O Port
Total
CMOS input
10
CMOS input/output
32 (LED can be driver
directly)
N-ch open-drain
output
Withstand Voltage
10
32 (LED can be driver
directly)
32 (Pull-up resistor mask option
: 24, LED can be driverndirectly)
12 (LED can be driven directly)
+12 V
Pull-up resistor
+10 V
Can be incorporated by mask option
4 (4-bit accuracy)
Analog input
Power-on reset circuit
Power-on flag
Incorporated (mask option)
No
Operating voltage
2.7 to 6.0 V
2.7 to 5.0 V (Ta = –40 to +50°C)
2.8 to 5.0 V
Operating temperature
rang
–40 to 85C°
–40 to +60 °C
0.95 µs (Operation at 4.5 to 6.0 V)
3.8 µs (Operation at 2.7 V)
0.95 µs
(Operation at 4.5 to 5.0 V)
1.91 µs (Operation at 2.7 V)
Minimum instruction
excution time
Package *3
*
58
10 (Pull resistor mask option
: 4)
• 64-pin plastic shrink DIP
• 64-pin plastic QFP (GF-3BE)
• 64-pin plastic QFP (GC-AB8)
• 64-pin plastic QFP (G-22)
: µPD75108A only
• 64-pin plastic QFP
(GF-3BE)
1.
Under development
2.
3.
Can be used as 75X High-End by 16K-byte mode/24K-byte mode switching function
There are four kinds of plastic QFP.
•GC-AB8 ........14 × 14 × 2.55 mm, 0.8 mm pitch
•GF-3BE ........14 × 20 × 2.7 mm, 1.0 mm pitch
•G-22 ............. 14 × 14 × 1.5 mm, 0.8 mm pitch
•GK-8A8 ........12 × 12 × 1.4 mm, 0.65 mm pitch
43
µPD75P108B
µPD75116H/117H
16K/24K
(Mask ROM)
768
75X High-End/expanded
High-End
µPD75P108B
µPD75P116
µPD75P117H
512
24K
(One-time PROM)
768
75X High-End
75X expanded High-End *2
8K
(One-time PROM, EPROM)
8K
(One-time PROM)
58
10
32 (LED can be driver
directly : 8)
32 (LED can be driver directly)
32 (LED can be driver
directly : 8)
12
12 (LED can be driver directly)
12
+6 V
+12 V
+6 V
Can be incorporated by
mask option
No
4 (4-bit accuracy)
No
1.8 to 5.0 V
–40 to +60 °C
No
5 V ±10%
2.7 to 6.0 V
–40 to +85 °C
0.95 µs (Operation at 2.7 V)
1.91 µs (Operation at 1.8 V)
0.95 µs
(Operation at 4.5 to 6.0 V)
3.8 µs (Operation at 2.7 V)
0.95 µs
(Operation at 4.75 to 5.5 V)
• 64-pin plastic QFP (GC-AB8)
• 64-pin plastic QFP (GK-8A8)
• 64-pin plastic shrink DIP
• 64-pin ceramic shrink DIP
(with window)
• 64-pin plastic QFP (GF-3BE)
• 64-pin plastic shrink DIP
• 64-pin plastic QFP (GF-3BE)
44
1.8 to 5.0 V
–40 to +60 °C
0.95 µs (Operation at 2.7 V)
1.91 µs (Operation at 1.8 V)
• 64-pin plastic QFP
(GC-AB8)
• 64-pin plastic QFP
(GK-8A8) *1
µPD75P108B
[MEMO]
45
µPD75P108B
[MEMO]
No part of this document may be copied or reproduced in any form or by any means without the prior written
consent of NEC Corporation. NEC Corporation assumes no responsibility for any errors which may appear in this
document.
NEC Corporation does not assume any liability for infringement of patents, copyrights or other intellectual
property rights of third parties by or arising from use of a device described herein or any other liability arising
from use of such device. No license, either express, implied or otherwise, is granted under any patents, copyrights
or other intellectual property rights of NEC Corporation or others.
The devices listed in this document are not suitable for use in aerospace equipment, submarine cables, nuclear
reactor control systems and life support systems. If customers intend to use NEC devices for above applications
or they intend to use "Standard" quality grade NEC devices for applications not intended by NEC, please contact
our sales people in advance.
Application examples recommended by NEC Corporation
Standard : Computer, Office equipment, Communication equipment, Test and Measurement equipment,
Machine tools, Industrial robots, Audio and Visual equipment, Other consumer products, etc.
Special
: Automotive and Transportation equipment, Traffic control systems, Antidisaster systems,
Anticrime systems, etc.
M4 92.6
QTOP is a trademark of NEC Corporation.
MS-DOS is a trademark of MicroSoft Corporation.
PC/AT, PC DOS is a trademark of IBM Corporation.