NEC Personal Computer PD75P308 User Manual

DATA SHEET  
MOS INTEGRATED CIRCUIT  
µPD75P308  
4-BIT SINGLE-CHIP MICROCOMPUTER  
DESCRIPTION  
The µPD75P308 is a model of the µPD75308 equipped with a one-time PROM or EPROM instead of an  
internal mask ROM.  
Two types are available as the µPD75P308. The one-time PROM type is ideal for production of a small  
quantity of many different types of application systems as data can only be written once to the one-time  
PROM of this type. Programs can be written and rewritten to the built-in EPROM type making it ideal  
for system evaluation.  
Detailed functions are described in the followig user's manual. Be sure to read it for designing.  
µPD75308 User's Manual: IEM-5016  
FEATURES  
µPD75308 compatible  
Memory capacity  
• Program memory (PROM): 8064 x 8 bits  
• Data memory (RAM): 512 x 4 bits  
Can be connected to a pull-up resistor through software: Ports 0-3, 6, 7  
Open-drain input/output: Ports 4 and 5  
Single power source: 5V ± 5%  
ORDERING INFORMATION  
Part Number  
Package  
Internal ROM  
µPD75P308GF-3B9  
µPD75P308K  
80-pin plastic QFP (14 x 20 mm)  
One-time PROM  
EPROM  
80-pin ceramic WQFN (LCC w/window)  
QUALITY GRADE  
Part Number  
Package  
Quality Grade  
µPD75P308GF-001-3B9  
µPD75P308K  
80-pin plastic QFP (14 x 20 mm)  
Standard  
Standard  
80-pin Ceramic WQFN (LCC w/window)  
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.  
The function common to the one-time PROM and EPROM types of product is referred to as PROM throughout this document.  
The information in this document is subject to change without notice.  
Document No. IC-2472B  
(O. D. No. IC-7208C)  
Date Published November 1993 P  
Printed in Japan  
The mark shows major revised points.  
NEC Corporation 1989  
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BASIC  
4
4
4
4
4
4
4
4
PORT0  
P00-P03  
P10-P13  
P20-P23  
INTERVAL  
TIMER  
PORT1  
PORT2  
INTBT  
PROGRAM  
SP(8)  
COUNTER(13)  
CY  
ALU  
TI0/P13  
TIMER/EVENT  
COUNTER  
#0  
PTO0/P20  
BANK  
P30-P33  
/MD0-MD3  
INTT0  
PORT3  
PORT4  
WATCH  
TIMER  
P40-P43  
P50-P53  
BUZ/P23  
PROGRAM  
MEMORY  
(PROM)  
PORT5  
PORT6  
PORT7  
GENERAL REG.  
fLCD  
INTW  
P60-P63  
P70-P73  
DECODE  
AND  
SI/SBI/P03  
SO/SB0/P02  
SCK/P01  
SERIAL  
DATA  
MEMORY  
(RAM)  
INTERFACE  
CONTROL  
8064 x 8 BITS  
INTCSI  
512 x 4 BITS  
24  
8
S0-S23  
INT0/P10  
S24/BP0  
-S31/BP7  
INT1/P11  
INT2/P12  
INT4/P00  
INTERRUPT  
CONTROL  
LCD  
COM0-COM3  
VLCO -VLC2  
4
3
CONTROLLER  
/DRIVER  
8
KR0/P60-  
KR3/P63,  
KR4/P70-  
KR7/P73  
N
fX/2  
SYSTEM CLOCK  
GENERATOR  
CLOCK  
µ
CPU  
STAND BY  
CONTROL  
CLOCK  
DIVIDER  
fLCD  
OUTPUT  
BIT SEQ.  
BUFFER(16)  
CLOCK  
BIAS  
CONTROL  
MAIN  
SUB  
LCDCL/P30  
SYNC/P30  
PCL/P22  
VSS  
RESET  
VPP VDD  
X2  
XT2 X1  
XT1  
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µPD75P308  
CONTENTS  
1. PIN FUNCTIONS ................................................................................................................................. 5  
1.1  
1.2  
1.3  
1.4  
PORT PINS ................................................................................................................................................. 5  
NON PORT PINS ....................................................................................................................................... 6  
PIN INPUT/OUTPUT CIRCUITS ................................................................................................................ 7  
NOTES ON USING P00/INT4 AND RESET PINS..................................................................................... 9  
2. DIFFERENCES BETWEEN µPD75P308 AND µPD75308.................................................................. 10  
3. WRITING AND VERIFYING PROM (PROGRAM MEMORY) ........................................................... 11  
3.1  
3.2  
3.3  
3.4  
OPERATION MODES FOR WRITING/VERIFYING PROGRAM MEMORY ............................................ 11  
PROGRAM MEMORY WRITE PROCEDURE .......................................................................................... 12  
PROGRAM MEMORY READ PROCEDURE ............................................................................................ 13  
ERASURE (µPD75P308K ONLY) ............................................................................................................. 14  
4. ELECTRICAL SPECIFICATIONS........................................................................................................ 15  
5. PACKAGE DRAWINGS ......................................................................................................................28  
6. RECOMMENDED SOLDERING CONDITIONS................................................................................. 30  
APPENDIX A. DEVELOPMENT TOOLS ................................................................................................. 31  
APPENDIX B. RELATED DOCUMENTS ................................................................................................ 32  
4
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µPD75P308  
1. PIN FUNCTIONS  
1.1 PORT PINS  
Input/  
Output  
Also Served  
As  
Pin Name Input/Output  
Function  
8-Bit I/O  
X
When Reset  
Circuit  
TYPE*1  
B
P00  
P01  
P02  
P03  
P10  
P11  
P12  
P13  
Input  
INT4  
SCK  
4-bit input port (PORT0)  
Pull-up resistors can be specified in 3-bit  
units for the P01 to P03 pins by software.  
Input/Output  
Input/Output  
Input/Output  
F -A  
F -B  
M -C  
Input  
Input  
SO/SB0  
SI/SBI  
INT0  
INT1  
INT2  
TI0  
With noise elimination function  
4-bit input port (PORT1)  
Internal pull-up resistors can be  
specified in 4-bit units by software.  
X
B -C  
E-B  
E-B  
Input  
P20  
P21  
PTO0  
4-bit input/output port (PORT2)  
Internal pull-up resistors can be  
specified in 4-bit units by software.  
Input/Output  
X
X
Input  
Input  
P22  
P23  
PCL  
BUZ  
Programmable 4-bit input/output port  
(PORT3)  
P30*2  
P31*2  
P32*2  
P33*2  
LCDCL MD0  
SYNC  
MD1  
This port can be specified for input/output  
in bit units.  
Input/Output  
MD2  
Internal pull-up resistors can be  
specified in 4-bit units by software.  
MD3  
N-ch open-drain 4-bit input/output port  
(PORT4)  
P40-43*2 Input/Output  
Data input/output pin for writing and  
verifying of program memory (PROM)  
(lower 4 bits)  
High impedance  
High impedance  
M-A  
M-A  
N-ch open-drain 4-bit input/output port  
(PORT5)  
P50-P53*2 Input/Output  
P60  
Data input/output pin for writing and  
verifying of program memory (PROM)  
(upper 4 bits)  
KR0  
KR1  
KR2  
KR3  
KR4  
KR5  
KR6  
KR7  
S24  
S25  
S26  
S27  
S28  
S29  
S30  
S31  
Programmable 4-bit input/output port  
(PORT6)  
P61  
This port can be specified for input/output  
in bit units.  
Input/Output  
P62  
Input  
Input  
F -A  
F -A  
Internal pull-up resistors can be specified  
in 4-bit units by software.  
P63  
P70  
4-bit input/output port (PORT7)  
Internal pull-up resistors can be  
specified in 4-bit units by software.  
P71  
Input/Output  
P72  
P73  
BP0  
BP1  
Output  
BP2  
BP3  
BP4  
BP5  
1-bit output port (BIT PORT)  
Shared with a segment output pin.  
G-C  
X
*3  
Output  
BP6  
BP7  
*1: Circles indicate schmitt trigger inputs.  
2: Can directly drive LED.  
3: For BP0-7, VLC1 indicated below are selected as the input source.  
However, the output level is changed depending on BP0-7 and the VLC1 external circuits.  
5
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µPD75P308  
1.2 NON PORT PINS  
Input/  
Output  
Circuit  
TYPE*1  
Also Served  
As  
Pin Name Input/Output  
Function  
When Reset  
Timer/event counter external event pulse input  
Timer/event counter output  
Clock output  
B -C  
TI0  
PTO0  
PCL  
Input  
Output  
P13  
P20  
P22  
E-B  
Input  
Input  
Input/Output  
E-B  
Fixed frequency output (for buzzer or for trimming  
the system clock)  
BUZ  
SCK  
Input/Output  
Input/Output  
P23  
P01  
P02  
Input  
E-B  
F -A  
F -B  
Serial clock input/output  
Input  
Input  
Serial data output  
SO/SB0 Input/Output  
SI/SB1 Input/Output  
Serial bus input/output  
Serial data input  
P03  
P00  
Input  
M -C  
Serial bus input/output  
Edge detection vector interrupt input (either rising  
or falling edge detection is effective)  
INT4  
Input  
B
Edge detection vector interrupt input (detection  
edge can be selected)  
INT0  
INT1  
INT2  
P10  
P11  
B -C  
Input  
Input  
B -C  
F -A  
F -A  
G-A  
Edge detection testable input (rising edge detection)  
Testable input/output(parallel falling edge detection)  
Testable input/output(parallel falling edge detection)  
Segment signal output  
Input  
Input  
*3  
P12  
KR0-KR3 Input/Output  
KR4-KR7 Input/Output  
P60-P63  
P70-P73  
S0-S23  
Output  
Output  
G-C  
Segment signal output  
*3  
S24-S31  
BP0-7  
COM0-  
COM3  
Common signal output  
LCD drive power  
*3  
G-B  
Output  
VLC0-VLC2  
High-impedance  
Input  
BIAS  
External dividing resistor disconnect output  
Externally expanded driver clock output  
Externally expanded driver sync clock output  
LCDCL*2 Input/Output  
SYNC*2 Input/Output  
P30  
P31  
E-B  
E-B  
Input  
To connect the crystal/ceramic oscillator to the main  
system clock generator.  
X1, X2  
XT1  
Input  
Input  
When inputting the external clock, input the external  
clock to pin X1, and the reverse phase of the  
external clock to pin X2.  
To connect the crystal oscillator to the subsystem  
clock generator.  
When the external clock is used, in XT1 inputs the  
external clock. In this case, pin XT2 must be left  
open.  
XT2  
Pin XT1 can be used as a 1-bit input (test) pin.  
B
RESET  
Input  
System reset input (low level active)  
To select mode when writing/verifying of program  
memory (PROM)  
Input  
MD0-MD3 Input/Output  
P30-P33  
E-B  
Program voltage application when writing and  
verifying of program memory (PROM)  
Connect to VDD during the normal operation  
VPP  
Apply +12.5V when writing/verifying EPROM  
Positive power supply  
VDD  
VSS  
GND  
*1: Circles indicate schmitt trigger inputs.  
2: These pins are provided for future system expansion. At present, these pins are used only as pins P30 and P31.  
3: For these display output, VLCX indicated below are selected as the input source.  
S0 to S31: VLC1, COM0 to COM2: VLC2, COM3: VLC0  
However, display output level varies depending on the particular display output and VLCX external circuit.  
6
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µPD75P308  
1.3 PIN INPUT/OUTPUT CIRCUITS  
The following shows a simplified input/output circuit diagram for each pin of the µPD75P308.  
TYPE A (for TYPE E–B)  
TYPE D (for TYPE E–B, F-A)  
VDD  
data  
P–ch  
N–ch  
P–ch  
N–ch  
OUT  
IN  
output  
disable  
Push–pull output that can be set in a output  
high–impedance state (both P–ch and N–ch are off)  
Input buffer of CMOS standard  
TYPE B  
TYPE E–B  
VDD  
P.U.R.  
P.U.R.  
P–ch  
enable  
IN  
data  
IN/OUT  
Type D  
output  
disable  
Type A  
Schmitt trigger input with hysteresis characteristics  
TYPE B–C  
P.U.R. : Pull–Up Resistor  
VDD  
TYPE E–E  
P.U.R.  
VDD  
P.U.R.  
P–ch  
enable  
P.U.R.  
data  
P.U.R.  
enable  
IN/OUT  
Type D  
P–ch  
output  
disable  
IN  
Type A  
Type B  
P.U.R. : Pull  
–Up Resistor  
Schmitt trigger input with hysteresis characteristics  
P.U.R. : Pull–Up Resistor  
7
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µPD75P308  
TYPE G–B  
TYPE F–A  
VDD  
VLC0  
P-ch  
P.U.R.  
enable  
P–ch  
VLC1  
data  
P-ch N-ch  
N-ch P-ch  
IN/OUT  
Type D  
output  
disable  
OUT  
COM  
data  
Type B  
VLC2  
P.U.R. : Pull–Up Resistor  
N-ch  
TYPE F–B  
TYPE GC  
VDD  
P.U.R.  
VDD  
P-ch  
P.U.R.  
enable  
P–ch  
output  
VLC0  
VDD  
disable  
(P)  
VLC1  
P-ch  
IN/OUT  
P-ch  
OUT  
N-ch  
data  
output  
disable  
SEG  
data/Bit Port data  
N-ch  
output  
disable  
(N)  
VLC2  
N-ch  
P.U.R. : Pull–Up Resistor  
TYPE G–A  
TYPE M–A  
VLC0  
IN/OUT  
P-ch  
data  
VLC1  
N-ch  
P-ch  
output  
disable  
SEG  
data  
OUT  
N-ch  
VLC2  
N-ch  
Middle voltage input buffer  
8
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µPD75P308  
TYPE M-C  
VDD  
P.U.R.  
P.U.R.  
enable  
P–ch  
IN/OUT  
data  
N-ch  
output  
disable  
P.U.R. : Pull–Up Resistor  
1.4 NOTES ON USING P00/INT4 AND RESET PINS  
In addition to the functions shown in sections 1.1 and 1.2, the P00/INT4 and RESET pins also have a function  
to set a test mode (for IC testing) in which the internal operations of the µPD75P308 are tested.  
When a voltage higher than VDD is applied to either of these pins, the test mode is set. This means that, even  
during ordinary operation, the µPD75P308 may be set in the test mode if a noise exceeding VDD is applied.  
For example, if the wiring length of the P00/INT4 or RESET pin is too long, noise superimposed on the wiring  
line of the pin may cause the above problem.  
Therefore, keep the wiring length of these pins as short as possible to suppress the noise; otherwise, take noise  
preventive measures as shown below by using external components.  
Connect capacitor between VDD  
and P00/INT4, RESET pin  
Connect diode with low VF between VDD  
and P00/INT4, RESET pin  
V
DD  
V
DD  
Diode with  
low VF  
V
DD  
V
DD  
P00/INT4, RESET  
P00/INT4, RESET  
9
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µPD75P308  
2. DIFFERENCES BETWEEN µPD75P308 AND µPD75308  
The µPD75P308 is a model of the µPD75308 and is equipped with a PROM instead of a mask ROM.  
Programs can be rewritten to the PROM of the µPD75P308. Table 2-1 shows the differences between the  
µPD75P308 and µPD75308. You should fully consider these differences when you debug or produce your  
application system on an experimental basis by using the PROM model, and then proceed to mass-produce  
the system by using the mask ROM model.  
For the details of the CPU and the internal hardware, refer to µPD75308 User's Manual (IEM-5016).  
Table 2-1 Differences between µPD75P308 and µPD75308  
Item  
µPD75P308K  
• EPROM  
µPD75P308GF  
µPD75308GF  
• Mask ROM  
• PROM (one-time model)  
• 0000H-1F7FH  
• 0000H-1F7FH  
• 8064 x 8 bits  
• 0000H-1F7FH  
• 8064 x 8 bits  
Program Memory  
• 8064 x 8 bits  
Pull-up Resistor  
Ports 4, 5  
Not provided  
Mask option  
Dividing Resistor for LCD  
Driving Power Supply  
Not provided  
Mask option  
Pins 50-53  
P30/MD0-P33/MD3  
VPP  
P30-P33  
NC  
Pin Connection  
Pin 57  
Current dissipations and operating temperature ranges differ between µPD75P308 and  
Electrical Specifications  
µPD75308. For detail, refer to the specification documents of each mode.  
Operating Voltage Range  
Package  
5V±5%  
2.7-6.0V  
80-pin ceramic WQFN  
(LCC w/window)  
80-pin plastic QFP (14 x 20 mm)  
Noise immunity and noise radiation differ because circuit scale and mask layout are  
different.  
Others  
Note: The noise immunity and noise radiation differ between the PROM and mask ROM models. To replace  
the PROM model with the mask ROM model in the course of experimental production to mass  
production, evaluate your system by using the CS mode (not ES model) of the mask ROM model.  
10  
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µPD75P308  
3. WRITING AND VERIFYING PROM (PROGRAM MEMORY)  
The program memory of the µPD75P308 is a PROM of 8064 x 8 bits. To write data to or verify the contents  
of this PROM, the pins listed in the table below are used. Note that no address input pins are provided  
because the address is updated by the clock input through the X1 pin.  
Pin Name  
Function  
VPP  
Applies voltage when program memory is written/verified (normally, at VDD potential)  
These pins input clock that updates address when program memory is written/verified. To X2 pin,  
input signal 180º out of phase in respect to signal to X1 pin.  
X1, X2  
MD0-MD3  
These pins select operation mode when program memory is written/verified.  
These pins input/output 8-bit data when program memory is written/verified.  
P40-P43 (Lower 4)  
P50-P53 (Upper 4)  
Power supply voltage application pin.  
VDD  
Apply 5V ± 5% to this pin during normal operation and 6V when program memory is written/verified.  
Note 1: Always cover the erasure window of the µPD75P308K with a light-opaque film except when the  
contents of the program memory are erased.  
2: The one-time PROM model µPD75P308GF is not equipped with a window and therefore, the  
contents of the program memory of this model cannot be erased by exposing it to ultraviolet rays.  
3.1 OPERATION MODES FOR WRITING/VERIFYING PROGRAM MEMORY  
When +6V is applied to the VDD pin of the µPD75P308 with +12.5V applied to the VPP pin, the µPD75P308  
is set in the program memory write/verify mode. In this mode, the following operation modes can be set  
by using the MD0-MD3 pins. At this time, pull down the levels of all the other pins to VSS.  
Operating Mode Specification  
Operating Mode  
VPP  
VDD  
MD0  
MD1  
MD2  
MD3  
H
L
L
H
L
H
L
Program memory address 0 clear mode  
Write mode  
H
H
+12.5 V  
+6 V  
L
H
H
Verify mode  
H
x
H
H
Program inhibit mode  
x: L or H  
11  
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µPD75P308  
3.2 PROGRAM MEMORY WRITE PROCEDURE  
The program memory write procedure is as follows. High-speed program memory write is possible.  
(1) Ground the unused pins through pull-down resistors. The X1 pin must be low.  
(2) Supply 5 V to the VDD and VPP pins.  
(3) Wait for 10 microseconds.  
(4) Set program memory address 0 clear mode.  
(5) Supply 6 V to the VDD pin and 12.5 V to the VPP pin.  
(6) Set program inhibit mode.  
(7) Write data in 1-millisecond write mode.  
(8) Set program inhibit mode.  
(9) Set verify mode. If data has been written connectly, proceed to step (10). If data has not yet been  
written, repeat steps (7) to (9).  
(10) Write additional data for (the number of times data was written (X) in steps (7) to (9)) times  
1 milliseconds.  
(11) Set program inhibit mode.  
(12) Supply a pulse to the X1 pin four times to update the program memory address by 1.  
(13) Repeat steps (7) to (12) to the last address.  
(14) Set program memory address 0 clear mode.  
(15) Change the voltages of VDD and VPP pins to 5 V.  
(16) Turn off the power supply.  
Steps (2) to (12) are illustrated below.  
X-time repetition  
Additional  
data write  
Address  
increment  
Write  
Verify  
VPP  
VPP  
VDD  
VDD+1  
VDD  
VDD  
X1  
P40-P43  
P50-P53  
Data  
output  
Data input  
Data input  
MD0  
(P30)  
MD1  
(P31)  
MD2  
(P32)  
MD3  
(P33)  
12  
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µPD75P308  
3.3 PROGRAM MEMORY READ PROCEDURE  
The contents of the program memory can be read in the following procedure.  
(1) Ground the unused pins through pull-down resistors. The X1 pin must be low.  
(2) Supply 5 V to the VDD and VPP pins.  
(3) Wait for 10 microseconds.  
(4) Set program memory address 0 clear mode.  
(5) Supply 6 V to the VDD pin and 12.5 V to the VPP pin.  
(6) Set program inhibit mode.  
(7) Set verify mode. Data of each address is sequentially output each time a clock pulse is input to the  
X1 pin four times.  
(8) Set program inhibit mode.  
(9) Set program memory address 0 clear mode.  
(10) Change the voltages of VDD and VPP pins to 5 V.  
(11) Turn off the power supply.  
Steps (2) to (9) are illustrated below.  
VPP  
VPP  
VDD  
VDD+1  
VDD  
VDD  
X1  
P40-P43  
P50-P53  
Data output  
Data output  
MD0  
(P30)  
MD1  
(P31)  
MD2  
(P32)  
MD3  
(P33)  
13  
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µPD75P308  
3.4 ERASURE (µPD75P308K ONLY)  
The contents of the data programmed to the µPD75P308 can be erased by exposing the window of the  
program memory to ultraviolet rays.  
The wavelength of the ultraviolet rays used to erase the contents is about 250 nm, and the quantity of the  
ultraviolet rays necessary for complete erasure is 15 W.s/cm2 (= ultraviolet ray intensity x erasure time).  
When a commercially available ultraviolet ray lamp (wavelength: 254 nm, intensity: 12 mW/cm2) is used,  
about 15 to 20 minutes is required.  
Note 1: The contents of the program memory may be erased when the µPD75P308 is exposed for a long  
time to direct sunlight or the light of fluorescent lamps. To protect the contents from being  
erased, mask the window of the program memory with the light-opaque film supplied as an  
accessory with the UV EPROM products.  
2: To erase the memory contents, the distance between the ultraviolet ray lamp and theµPD75P308  
should be 2.5 cm or less.  
Remarks:  
The time required for erasure changes depending on the degradation of the ultraviolet ray  
lamp and the surface condition (dirt) of the window of the program memory.  
14  
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µPD75P308  
4. ELECTRICAL SPECIFICATIONS  
ABSOLUTE MAXIMUM RATINGS (Ta = 25°C)  
Parameter  
Supply Voltage  
Supply Voltage  
Symbol  
VDD  
Conditions  
Rating  
Unit  
V
-0.3 to +7.0  
VPP  
-0.3 to +13.5  
V
VI1  
Other than ports 4 or 5  
-0.3 to VDD+0.3  
V
Input Voltage  
*1  
VI2  
Ports 4 and 5  
Open-drain  
-0.3 to +11  
V
Output Voltage  
VO  
-0.3 to VDD+0.3  
V
1 Pin  
-15  
mA  
mA  
mA  
mA  
mA  
mA  
mA  
mA  
°C  
High-Level Output Current  
IOH  
All pins  
-30  
Peak value  
30  
15  
One pin  
Effective value  
Peak value  
100  
*2  
Low-Level Output Current  
Total of ports 0, 2, 3, 5  
Total of ports 4, 6, 7  
IOH  
Effective value  
Peak value  
60  
100  
Effective value  
60  
Operating Temperature  
Storage Temperature  
Topt  
Tstg  
-10 to +70  
-65 to +150  
°C  
*1:  
2:  
The impedance of the power source (pull-up resistor) must be 50 Kminimum when a voltage higher  
than 10V is applied to ports 4 and 5.  
Effective value = Peak value x Duty  
15  
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µPD75P308  
MAIN SYSTEM CLOCK OSCILLATOR CIRCUIT CHARACTERISTICS  
(Ta = -10 to +70°C, VDD = 5 to ±5 V)  
Recommended  
Oscillator  
Ceramic*3  
Item  
Conditions  
MIN.  
1.0  
TYP. MAX.  
Unit  
MHz  
ms  
Constants  
Oscillation  
frequency (fXX)*1  
Oscillation stabilization After VDD came to MIN.  
5.0*4  
4
X1 X2  
C1  
C1  
C2  
C2  
time*2  
of oscillation voltage range  
VDD  
X2  
Crystal  
Oscilaltion  
1.0  
4.19  
5.0*4  
10  
MHz  
ms  
X1  
X1  
frequency (fXX)*1  
Oscillation stabilization  
time*2  
VDD  
X2  
External Clock  
X1 input frequency  
(fX)*1  
1.0  
5.0*4  
500  
MHz  
ns  
X1 input high-, low-level  
widths (tXH, tXL)  
100  
µ
PD74HCU04  
*1: The oscillation frequency and X1 input frequency are indicated only to express the characteristics of the  
oscillator circuit.  
For instruction execution time, refer to AC Characteristics.  
2: Time required for oscillation to stabilize after VDD reaches the minimum value of the oscillation voltage  
range or the STOP mode has been released.  
3: The oscillators below are recommended.  
4: When the oscillation frequency is 4.19 MHz < fx 5.0 MHz, do not select PCC = 0011 as the instruction  
execution time: otherwise, one machine cycle is set to less than 0.95 µs, falling short of the rated  
minimum value of 0.95 µs.  
Caution: When using the oscillation circuit of the main system clock, wire the portion enclosed in dotted  
line in the figures as follows to avoid adverse influences on the wiring capacity:  
Keep the wiring length as short as possible.  
Do not cross the wiring over the other signal lines. Do not route the wiring in the vicinity of  
lines through which a high alternating current flows.  
Always keep the ground point of the capacitor of the oscillator circuit at the same potential  
as VDD. Do not connect the power source pattern through which a high current flows.  
Do not extract signals from the oscillation circuit.  
RECOMMENDED OSCILLATION CIRCUIT CONSTANTS  
MAIN SYSTEM CLOCK: CERAMIC OSCILLATOR (Ta = -10 to +70°C)  
Oscillation  
Voltage Range [V]  
External Capacitance [pF]  
Manufac-  
turer  
Product Name  
C1  
C2  
MIN.  
4.75  
4.75  
4.75  
4.75  
MAX.  
5.25  
5.25  
5.25  
5.25  
Murata  
Mfg.  
Co., Ltd.  
CSA 2.00MG  
CSA 4.19MG  
CSA 4.19MGU  
CST 4.19MG  
30  
30  
30  
30  
30  
30  
30 pF (internal)  
30 pF (internal)  
16  
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µPD75P308  
SUBSYSTEM CLOCK OSCILLATOR CIRCUIT CHARACTERISTICS  
(Ta = -10 to +70°C, VDD = 5 V ±5%)  
Recommended  
Oscillator  
Crystal  
Item  
Oscillation  
Conditions  
MIN.  
32  
TYP. MAX.  
Unit  
kHz  
Constants  
XT1  
XT2  
32.768  
1.0  
35  
frequency (fXT)  
R
Oscillation stabilization  
time*  
C3  
C4  
2
s
VDD  
External Clock  
XT1 input frequency  
(fXT)  
32  
5
100  
15  
kHz  
µs  
XT1  
XT2  
Open  
XT1 input high-, low-level  
widths (tXTH, tXTL)  
*: Time required for oscillation to stabilize after VDD reaches the minimum value of the oscillation voltage  
range.  
Caution: When using the oscillation circuit of the subsystem clock, wire the portion enclosed in dotted line  
in the figures as follows to avoid adverse influences on the wiring capacity:  
Keep the wiring length as short as possible.  
Do not cross the wiring over the other signal lines. Do not route the wiring in the vicinity of  
lines through which a high alternating current flows.  
Always keep the ground point of the capacitor of the oscillator circuit at the same potential  
as VDD. Do not connect the power source pattern through which a high current flows.  
Do not extract signals from the oscillation circuit.  
The amplification factor of the subsystem clock oscillation circuit is designed to be low to reduce the  
current dissipation and therefore, the subsystem clock oscillation circuit is influenced by noise more  
easily than the main system clock oscillation circuit. When using the subsystem clock, therefore,  
exercise utmost care in wiring the circuit.  
CAPACITANCE (Ta = 25°C, VDD = 0 V)  
Parameter  
Input Capacitance  
Output Capacitance  
Symbol  
Conditions  
MIN.  
TYP. MAX. Unit  
CIN  
f = 1 MHz  
Pins other than thosemeasured are at 0 V  
15  
15  
pF  
pF  
COUT  
CIO  
Input/Output  
Capacitance  
15  
pF  
17  
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µPD75P308  
DC CHARACTERISTICS (Ta = -10 to +70°C, VDD = 5V ±5%)  
Parameter  
Symbol  
Conditions  
MIN. TYP. MAX. Unit  
Ports 2, 3  
Ports 0, 1, 6, 7, RESET  
High-Level Input Voltage  
0.7 VDD  
0.8 VDD  
0.7 VDD  
VDD-0.5  
0
VDD  
VDD  
V
V
V
V
V
V
V
VIH1  
VIH2  
VIH3  
VIH4  
VIL1  
VIL2  
VIL3  
Ports 4, 5  
Open-drain  
10  
X1, X2, XT1  
VDD  
Ports 2, 3, 4, 5  
Ports 0, 1, 6, 7, RESET  
X1, X2, XT1  
Ports 0, 2, 3, IOH = -1mA  
6, 7  
Low-Level Input Voltage  
High-Level Output Voltage  
Low-Level Output Voltage  
0.3 VDD  
0.2 VDD  
0.4  
0
0
VDD-1.0  
V
VOH1  
VOH2  
VOL1  
BIAS  
BP0-7  
IOH = -100µA*1  
VDD-2.0  
V
V
Ports 0, 2, 3, Ports 3, 4, 5  
0.4  
2.0  
6, 7  
IOL = 15mA  
IOL = 1.6mA  
0.4  
V
V
SB0, 1  
Open-drain  
VOL2  
0.2VDD  
Pull-up R 1kΩ  
VOL3  
ILIH1  
ILIH2  
ILIH3  
ILIL1  
BP0-7  
IOL = 100µA*1  
Other than below  
X1, X2, XT1  
1.0  
3
V
High-Level Input Leakage Current  
µA  
µA  
µA  
µA  
µA  
µA  
µA  
µA  
VIN = VDD  
20  
20  
-3  
VIN = 10V  
VIN = 0V  
Ports 4, 5  
Low-Level Input Leakage Current  
High-Level Output Leakage Current  
Other than below  
X1, X2, XT1  
ILIL2  
-20  
3
ILOH1  
ILOH2  
ILOL  
VOUT = VDD  
VOUT = 10V  
VOUT = 0V  
Other than below  
Ports 4.5  
20  
-3  
Low-Level Output Leakage Current  
Internal Pull-Up Resistor  
Ports 0, 1, 2, 3, 6, 7  
(except P00) VIN = 0V  
RLI  
15  
40  
80  
KΩ  
VLCD  
LCD Drive Voltage  
2.5  
VDD  
V
2
2
3
*
VLCD0 = VLCD  
LCD Output Voltage Deviation  
(Common)  
I0 = ±5 µA  
VODC  
VODS  
0
0
±0.2V  
V
V
2
VLCD1 = VLCD x —  
3
1
*
*
VLCD2 = VLCD x —  
LCD Output Voltage Deviation  
(Segment)  
2.7 V VLCD 3VDD  
±0.2V  
I0 = ±1 µA  
4.19MHz crystal *4  
oscillator  
6
*
Supply Current  
IDD1  
IDD2  
5
15  
mA  
HALT mode  
HALT mode  
500  
350  
35  
1500  
1000  
100  
µA  
C1 = C2 = 22pF  
5
32 kHz  
*
IDD3  
IDD4  
µA  
crystal oscillator  
XT1 = 0V  
0.5  
20  
µA  
STOP mode  
* 1: When using two of BP0-BP3 and two of BP4-BP7 for output at the same time.  
2: "Voltage deviation" means the difference between the ideal segment or common output value  
(VLCDn: = 0, 1, 2) and output voltage.  
3: Currents for the built-in pull-up resistor are not included.  
4: Including when the subsystem clock is operated.  
5: When operated with the subsystem clock by setting the system clock control register (SCC) to  
1001 to stop the main system clock operation.  
6: When operand in the high-speed mode with the processor clock control register (PCC) set to 0011.  
18  
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µPD75P308  
AC CHARACTERISTICS (Ta = -10 to + 70°C, VDD = 5V ±5%)  
Operation Other Than Serial Transfer  
Parameter  
CPU Clock Cycle Time*1  
(Minimum Instruction  
Execution Time  
Symbol  
Conditions  
MIN.  
0.95  
TYP.  
122  
MAX.  
64  
Unit  
w/main system clock  
µs  
tCY  
w/subsystem clock  
114  
125  
1
µs  
= 1 Machine Cycle)  
TI0 Input Frequency  
TI0 Input High-, Low-Level  
Widths  
fTI  
0
MHz  
tTIH, tTIL  
0.48  
µs  
tINTH,  
tINTL  
tRSL  
InterruptInputHigh-,Low-Level  
Widths  
*2  
10  
10  
µs  
µs  
µs  
INT0  
KR0-7, INT1, 2, 4  
RESET Low-Level Width  
t
cy vs VDD  
(with main system clock)  
70  
* 1: The CPU clock (Φ) cycle time is determined  
bytheoscillationfrequencyoftheconnected  
oscillator, system clock control register  
(SCC), and processor clock control register  
(PCC).  
64  
60  
6
5
The figure on the right is cycle time tCY vs.  
supply voltage VDD characteristics at the  
main system clock.  
4
3
µ
2: 2tCY or 128/fXX depending on the setting of  
the interrupt mode register (IM0).  
2
1
0.5  
0
1
2
3
4
5
6
DD  
Supply voltage V [V]  
19  
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µPD75P308  
SERIAL TRANSFER OPERATION  
TWO-LINE AND THREE-LINE SERIAL I/O MODES (SCK: internal clock output)  
Parameter  
SCK Cycle Time  
SCK High-, Low-Level Widths  
Symbol  
Conditions  
MIN.  
1600  
TYP.  
MAX.  
Unit  
ns  
Output  
tKCY1  
tKH1, tKL1  
tSIK1  
Output tKCY1/2-50  
ns  
SI Set-Up Time (vs. SCK  
)
150  
400  
ns  
ns  
SI Hold Time (vs. SCK  
)
tKSI1  
↓ →  
RL = 1k, CL = 100pF*  
250  
ns  
SCK  
SO Output  
tKSO1  
Delay Time  
*: RL and CL are load resistance and load capacitance of the SO output line.  
TWO-LINE AND THREE-LINE SERIAL I/O MODES (SCK: external clock input)  
Parameter  
SCK Cycle Time  
SCK High-, Low-Level Widths  
Symbol  
Conditions  
MIN.  
800  
400  
100  
400  
TYP.  
MAX.  
Unit  
ns  
Input  
Input  
tKCY2  
tKH2, tKL2  
tSIK2  
ns  
SI Set-Up Time (vs. SCK  
)
ns  
SI Hold Time (vs. SCK  
)
ns  
tKSI2  
↓ →  
RL = 1k, CL = 100pF*  
300  
ns  
SCK  
SO Output  
tKSO2  
Delay Time  
*: RL and CL are load resistance and load capacitance of the SO output line.  
20  
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µPD75P308  
SBI MODE (SCK: internal clock output (master))  
Parameter  
SCK Cycle Time  
Symbol  
Conditions  
MIN.  
1600  
TYP.  
MAX.  
Unit  
ns  
tKCY3  
tKL3  
tKCY/2  
SCK High-, Low-Level  
Widths  
ns  
tKH3  
tSIK3  
tKSI3  
-50  
SB0, 1 Set-Up Time (vs. SCK  
)
)
150  
ns  
ns  
SB0, 1 Hold Time (vs. SCK  
tKCY/2  
↓ →  
Delay Time  
SCK  
SB0, 1 Output  
tKSO3  
0
250  
ns  
RL = 1k, CL = 100pF*  
tKSB  
tSBK  
SCK↑ → SB0, 1↓  
tKCY  
tKCY  
tKCY  
tKCY  
ns  
ns  
ns  
ns  
↓ →  
SCK  
SB0, 1  
SB0, 1 Low-Level Width  
SB0, 1 High-Level Width  
tSBL  
tSBH  
*: RL and CL are load resistance and load capacitance of the SO output line.  
SBI MODE (SCK: external clock output (master))  
Parameter  
SCK Cycle Time  
Symbol  
Conditions  
MIN.  
1600  
TYP.  
MAX.  
Unit  
ns  
tKCY4  
tKL4  
SCK High-, Low-Level  
Widths  
400  
ns  
tKH4  
tSIK4  
tKSI4  
SB0, 1 Set-Up Time (vs. SCK  
)
)
100  
tKCY/2  
0
ns  
ns  
ns  
SB0, 1 Hold Time (vs. SCK  
↓ →  
SCK  
Delay Time  
↑ →  
SB0, 1 Output  
300  
tKSO4  
RL = 1k, CL = 100pF*  
tKSB  
tSBK  
SCK  
SB0, 1  
SB0, 1↓  
↓ →  
tKCY  
tKCY  
tKCY  
tKCY  
ns  
ns  
ns  
ns  
SCK  
SB0, 1 Low-Level Width  
SB0, 1 High-Level Width  
tSBL  
tSBH  
*: RL and CL are load resistance and load capacitance of the SO output line.  
21  
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µPD75P308  
AC TIMING TEST POINT (excluding X1 and XT1 inputs)  
0.8 VDD  
0.8 VDD  
0.2 VDD  
Test points  
0.2 VDD  
CLOCK TIMING  
1/fX  
tXL  
tXH  
X1 input  
VDD –0.5V  
0.4 V  
1/fXT  
tXTL  
tXTH  
XT1 input  
VDD –0.5V  
0.4 V  
TI0 TIMING  
1/fTI  
tTIL  
tTIH  
TI0  
22  
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µPD75P308  
SERIAL TRANSFER TIMING  
THREE-LINE SERIAL I/O MODE:  
tKCY1  
tKL1  
tKH1  
SCK  
tSIK1  
tKSI1  
SI  
Input data  
tKSO1  
Output data  
SO  
TWO-LINE SERIAL I/O MODE:  
tKCY  
tKH  
tKL  
SCK  
tKSO  
tSIK  
tKSI  
SB0,1  
23  
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µPD75P308  
SERIAL TRANSFER TIMING  
BUS RELEASE SIGNAL TRANSFER  
KCY3,4  
t
tKL3,4  
tKH3,4  
SCK  
tSIK3,4  
tKSB  
tSBL  
tSBH  
tSBK  
tKSI3,4  
SB0,1  
tKSO3,4  
COMMAND SIGNAL TRANSFER  
tKCY3,4  
tKL3,4  
tKH3,4  
SCK  
tSIK3,4  
tKSB  
tSBK  
tKSI3,4  
SB0,1  
tKSO3,4  
INTERRUPT INPUT TIMING  
tINTL  
tINTH  
INT0, 1, 2, 4  
KR0-7  
RESET INPUT TIMING  
tRSL  
RESET  
24  
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µPD75P308  
LOW-VOLTAGE DATA RETENTION CHARACTERISTICS OF DATA MEMORY IN STOP MODE  
(Ta = -10 to +70°C)  
Parameter  
Symbol  
Conditions  
MIN.  
2.0  
TYP.  
MAX.  
6.0  
Unit  
V
Data Retention Supply  
Voltage  
VDDDR  
Data Retention Supply  
Current*1  
IDDDR  
VDDDR = 2.0V  
0.1  
10  
µA  
0
µs  
tSREL  
tWAIT  
Release Signal Set Time  
Oscillation Stabilization  
Wait Time*2  
217/fX  
ms  
ms  
Released by RESET  
3
*
Released by interrupt  
*1: Does not include current folowing through internal pull-up resistor  
2: The oscillation stabilization wait time is the time during which the CPU is stopped to prevent unstable  
operation when oscillation is started.  
3: Depends on the setting of the basic interval timer mode register (BTM) as follows:  
BTM3  
BTM2  
BTM1  
BTM0  
WAIT time ( ): fX = 4.19 MHz  
220/fX (approx. 250 ms)  
217/fX (approx. 31.3 ms)  
215/fX (approx. 7.82 ms)  
213/fX (approx. 1.95 ms)  
0
0
1
1
0
1
0
1
DATA RETENTION TIMING (releasing STOP mode by RESET)  
Internal reset operation  
HALT mode  
STOP mode  
Operation  
mode  
Data retention mode  
VDD  
VDDDR  
tSREL  
STOP instruction  
execution  
RESET  
tWAIT  
DATA RETENTION TIMING (standby release signal: releasing STOP mode by interrupt)  
HALT mode  
STOP mode  
Data retention mode  
Operation  
mode  
VDD  
VDDDR  
tSREL  
STOP instruction execution  
Standby release signal  
(interrupt request)  
tWAIT  
25  
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µPD75P308  
DC PROGRAMMING CHARACTERISTICS (Ta = 25 ±5°C, VDD = 6.0±0.25V, VPP = 12.5±0.3V, VSS = 0V)  
Parameter  
Symbol  
Conditions  
Other than X1 or X2  
MIN.  
0.7 VDD  
VDD –0.5  
0
TYP.  
MAX.  
VDD  
Unit  
V
VIH1  
VIH2  
VIL1  
VIL2  
ILI  
High-Level Input Voltage  
X1 and X2  
VDD  
V
Other than X1 or X2  
X1 and X2  
0.3 VDD  
0.4  
V
Low-Level Input Voltage  
0
V
Input Leakage Current  
High-Level Output Voltage  
Low-Level Output Voltage  
VDD Supply Current  
VIN = VIL or VIH  
IOH = –1 mA  
10  
µA  
V
VDD –1.0  
VOH  
VOL  
IDD  
IOL = 1.6 mA  
0.4  
30  
30  
V
mA  
mA  
VPP Supply Current  
MD0 = VIL, MD1 = VIH  
IPP  
Notes 1: VPP must not exceed +13.5 V, including the overshoot.  
2: Apply VDD before VPP and disconnect it after VPP.  
AC PROGRAMMING CHARACTERISTICS (Ta = 25±5°C, VDD = 6.0±0.25V, VPP = 12.5±0.3V, VSS = 0V)  
1
Parameter  
Symbol  
*
Conditions  
MIN. TYP. MAX. Unit  
Address Set-Up Time*2 (vs.MD0)  
MD1 Set-Up Time (vs. MD0)  
Data Set-Up Time (vs. MD0)  
Address Hold Time*2 (vs.MD0)  
Data Hold Time (vs. MD0)  
tAS  
tM1S  
tDS  
tAS  
tOES  
tDS  
tAH  
tDH  
tDF  
tVPS  
tVCS  
tPW  
tOPW  
tCES  
tDV  
tOEH  
tOR  
2
2
µs  
µs  
µs  
µs  
µs  
ns  
µs  
µs  
ms  
ms  
µs  
µs  
µs  
µs  
µs  
µs  
2
2
tAH  
2
tDH  
0
130  
MD0 Data Output Float Delay Time  
VPP Set-Up Time (vs. MD3)  
VDD Set-Up Time (vs. MD3)  
Initial Program Pulse Width  
Additional Program Pulse Width  
MD0 Set-Up Time (vs. MD1)  
MD0 Data Output Delay Time  
MD1 Hold Time (vs. MD0)  
tDF  
2
tVPS  
tVDS  
tPW  
2
0.95  
0.95  
2
1.0  
1.05  
21.0  
tOPW  
tMOS  
tDV  
1
MD0 = MD1 = VIL  
2
2
tM1H  
tM1R  
tPCR  
tXH,tXL  
fX  
tM1H + tM1R 50 µs  
MD1 Recovery Time (vs. MD0)  
Program Counter Reset Time  
X1 Input High-/Low- Level Width  
X1 Input Frequency  
10  
0.125  
4.19 MHz  
2
2
2
2
µs  
µs  
µs  
µs  
Initial Mode Set Time  
tI  
MD3 Set-Up Time (vs. MD1)  
MD3 Hold Time (vs. MD1)  
tM3S  
tM3H  
tM3SR  
tDAD  
tHAD  
tM3HR  
tDFR  
When data is read from program memory  
When data is read from program memory  
When data is read from program memory  
When data is read from program memory  
When data is read from program memory  
MD3 Set-Up Time (vs. MD0)  
Address*2 Data Output Delay Time  
Address*2 Data Output Hold Time  
MD3 Hold Time (vs. MD0)  
2
µs  
ns  
µs  
µs  
tACC  
tOH  
0
2
130  
2
MD3 Data Output Float Delay Time  
*1: These symbols are the corresponding µPD27C256 symbols.  
2: The internal address signal is incremented by 1 at the fourth rising edge of X1 input. The internal  
address is not connected to any pin.  
26  
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µPD75P308  
PROGRAM MEMORY WRITE TIMING  
tVPS  
VPP  
VPP  
VDD  
tVDS  
VDD+1  
VDD  
VDD  
tXH  
X1  
tXL  
P40-P43  
P50-P53  
Data  
Data input  
Data input  
Data input  
output  
tDS  
tDH  
tAH  
tI  
tOH  
tDV  
tDF  
tDS  
tAS  
MD0  
MD1  
tMOS  
tPW  
tM1R  
tOPW  
tPCR  
tM1S  
tM1H  
MD2  
MD3  
tM3H  
tM3S  
PROGRAM MEMORY READ TIMING  
tVPS  
VPP  
VDD  
VPP  
tVDS  
VDD+1  
VDD  
VDD  
tXH  
X1  
tXL  
tDAD  
tHAD  
P40-P43  
P50-P53  
Data output  
Data output  
tDV  
tDFR  
t
I
tM3HR  
MD0  
MD1  
MD2  
tPCR  
tM3SR  
MD3  
27  
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µPD75P308  
5. PACKAGE DRAWINGS  
80 PIN PLASTIC QFP (14×20)  
A
B
41  
40  
64  
65  
detail of lead end  
25  
24  
80  
1
G
H
M
N
I
J
K
L
P80GF-80-3B9-2  
NOTE  
ITEM  
MILLIMETERS  
INCHES  
Each lead centerline is located within 0.15  
mm (0.006 inch) of its true position (T.P.) at  
maximum material condition.  
±
±
A
B
C
D
F
23.6 0.4  
0.929 0.016  
+0.009  
±
20.0 0.2  
0.795  
–0.008  
+0.009  
±
14.0 0.2  
0.551  
–0.008  
±
±
0.693 0.016  
17.6 0.4  
1.0  
0.8  
0.039  
G
H
I
0.031  
+0.004  
±
0.35 0.10  
0.014  
–0.005  
0.15  
0.006  
J
0.8 (T.P.)  
0.031 (T.P.)  
+0.008  
±
K
L
1.8 0.2  
0.071  
–0.009  
+0.009  
±
0.031  
0.8 0.2  
–0.008  
+0.10  
+0.004  
0.15  
M
N
P
Q
S
0.006  
–0.05  
–0.003  
0.15  
2.7  
0.006  
0.106  
±
±
0.1 0.1  
0.004 0.004  
3.0 MAX.  
0.119 MAX.  
28  
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µPD75P308  
80 PIN CERAMIC WQFN  
A
B
Q
K
T
80  
1
M
I
H
U
J
R
X80KW-80A-1  
NOTE  
ITEM  
A
MILLIMETERS  
INCHES  
Each lead centerline is located within 0.08  
mm (0.003 inch) of its true position (T.P.) at  
maximum material condition.  
+0.017  
±
20.0 0.4  
0.787  
–0.016  
B
19.0  
13.2  
0.748  
0.520  
C
±
±
D
E
14.2 0.4  
0.559 0.016  
0.065  
1.64  
F
2.14  
0.084  
G
H
I
4.064 MAX.  
0.160 MAX.  
±
±
0.51 0.10  
0.020 0.004  
0.08  
0.003  
J
0.8 (T.P.)  
0.031 (T.P.)  
+0.009  
±
K
1.0 0.2  
0.039  
–0.008  
Q
R
C 0.5  
0.8  
C 0.020  
0.031  
S
1.1  
0.043  
T
R 3.0  
12.0  
R 0.118  
U
W
0.472  
+0.008  
±
0.75 0.2  
0.030  
–0.009  
29  
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µPD75P308  
6. RECOMMENDED SOLDERING CONDITIONS  
It is recommended that µPD75P308 be soldered under the following conditions.  
For details on the recommended soldering conditions, refer to Information Document "Semiconductor  
Devices Mounting Manual" (IEI-616).  
The soldering methods and conditions are not listed here, consult NEC.  
Table 6-1 Soldering Conditions  
µPD75P308GF-3B9: 80-pin plastic QFP (14 x 20 mm)  
Symbol for Recommended  
Soldering Method  
Wave Soldering  
Soldering Conditions  
Condition  
Soldering bath temperature: 260°C max.,  
time: 10 seconds max., number of times: 1,  
pre-heating temperature: 120°C max. (package surface  
temperature), maximum number of days: 2 days*,  
(beyond this period, 16 hours of pre-baking is required  
at 125°C).  
WS60-162-1  
Infrared Reflow  
Package peak temperature: 230°C,  
IR30-162-1  
VP15-162-1  
time: 30 seconds max. (210°C min.),  
number of times: 1, maximum number of days: 2 days*  
(beyond this period, 16 hours of pre-baking is required  
at 125°C)  
VPS  
Package peak temperature: 215°C,  
time: 40 seconds max. (200°C min.),  
number of times: 1, maximum number of days: 2 days*  
(beyond this period, 16 hours of pre-baking is required  
at 125°C)  
Pin Partial Heating  
Pin temperature: 300°C max.,  
time: 3 seconds max. (per side)  
*: Number of days after unpacking the dry pack. Storage conditions are 25°C and 65%RH max.  
Caution: Do not use two or more soldering methods in combination (except the pin partial heating  
method).  
Notice  
A model that can be soldered under the more stringent conditions (infrared reflow peak  
temperature: 235°C, number of times: 2, and an extended number of days) is also available.  
For details, consult NEC.  
30  
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µPD75P308  
APPENDIX A. DEVELOPMENT TOOLS  
The following development support tools are readily available to support development of systems using  
µPD75P308:  
PROM writing tools  
Hardare  
IE-75000-R*1  
In-circuit emulator for 75K series  
IE-75001-R  
IE-75000-R-EM*2  
Emulation board for IE-75000-R and IE-75001-R  
EP-75308GF-R  
Emulation prove for µPD75P308GF, provided with 80-pin conversion socket,  
EV-9200G-80  
EV-9200G-80.  
PG-1500  
PROM programmer  
PA-75P308GF  
PROM programmer adapter solely used for µPD75P308GF. It is connected to  
PG-1500.  
PA-75P308K  
PROM programmer adapter solely used for µPD75P308K. It is connected to  
PG-1500.  
Software  
IE Control Program  
PG-1500 Controller  
RA75X Relocatable  
Assembler  
Host machine  
PC-9800 series (MS-DOSTM Ver.3.30 to Ver.5.00A*3)  
IBM PC/ATTM (PC DOSTM Ver.3.1)  
*1: Maintenance product  
2: Not provided with IE-75001-R  
3: Ver.5.00/5.00A has a task swap function, but this function cannot be used with this software.  
Remarks: For development tools from other companies, refer to 75X Series Selection Guide (IF-151).  
31  
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µPD75P308  
APPENDIX B. RELATED DOCUMENTS  
32  
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µPD75P308  
GENERAL NOTES ON CMOS DEVICES  
1
STATIC ELECTRICITY (ALL MOS DEVICES)  
Exercise care so that MOS devices are not adversely influenced by static electricity while being  
handled.  
The insulation of the gates of the MOS device may be destroyed by a strong static charge.  
Therefore, when transporting or storing the MOS device, use a conductive tray, magazine case,  
or conductive buffer materials, or the metal case NEC uses for packaging and shipment, and use  
grounding when assembling the MOS device system. Do not leave the MOS device on a plastic  
plate and do not touch the pins of the device.  
Handle boards on which MOS devices are mounted similarly .  
2
PROCESSING OF UNUSED PINS (CMOS DEVICES ONLY)  
Fix the input level of CMOS devices.  
Unlike bipolar or NMOS devices, if a CMOS device is operated with nothing connected to its  
input pin, intermediate level input may be generated due to noise, and an inrush current may flow  
through the device, causing the device to malfunction. Therefore, fix the input level of the device  
by using a pull-down or pull-up resistor. If there is a possibility that an unused pin serves as an  
output pin (whose timing is not specified), each pin should be connected to VDD or GND through  
a resistor.  
Refer to “Processing of Unused Pins” in the documents of each devices.  
3
STATUS BEFORE INITIALIZATION (ALL MOS DEVICES)  
The initial status of MOS devices is undefined upon power application.  
Since the characteristics of an MOS device are determined by the quantity of injection at the  
molecular level, the initial status of the device is not controlled during the production process. The  
output status of pins, I/O setting, and register contents upon power application are not guaranteed.  
However, the items defined for reset operation and mode setting are subject to guarantee after  
the respective operations have been executed.  
When using a device with a reset function, be sure to reset the device after power application.  
33  
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µPD75P308  
[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 uses 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 the applications not  
intended by NEC, please contact our sales people in advance.  
Application examples recommended by NEC Corporation  
Standard: Computer, Officeequipment, Communicationequipment, TestandMeasurementequipment,  
Machine tools, Industrial robots, Audio and Visual equipment, Other consumer products,etc.  
Special: Automotive and Transportation equipment, Traffic control systems, Antidisaster systems,  
Anticrime system, etc.  
M4 92.6  
MS-DOS is a trademark of Microsoft Corporation.  
PC DOS and PC/AT are trademarks of IBM Corporation.  
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