ETC UPD17P709A

DATA SHEET
MOS INTEGRATED CIRCUIT
µPD17P709A
4-BIT SINGLE-CHIP MICROCONTROLLER
WITH DEDICATED HARDWARE FOR DIGITAL TUNING SYSTEM
DESCRIPTION
The µPD17P709A is produced by replacing the on-chip mask ROM of the µPD17704A, 17705A, 17707A, 17708A,
and 17709A with a one-time PROM.
The µPD17P709A allows programs to be written once, so the µPD17P709A is suitable for preproduction in
µPD17704A, 17705A, 17707A, 17708A, or 17709A system development or low-volume production.
When reading this document, also refer to the publications on the µPD17704A, 17705A, 17707A, 17708A,
or 17709A.
The electrical characteristics (including power supply current) and PLL analog characteristics of the
µPD17P709A differ from those of the µPD17704A, 17705A, 17707A, 17708A, and 17709A. In high-volume
application set production, be sure to carefully check these differences.
FEATURES
• Compatible with the µPD17704A, 17705A, 17707A, 17708A, and 17709A
• On-chip one-time PROM: 32 KB (16384 × 16 bits)
• Supply voltage: VDD = 5 V ±10%
ORDERING INFORMATION
Part Number
Package
µPD17P709AGC-3B9
80-pin plastic QFP (14 × 14)
The information in this document is subject to change without notice. Before using this document, please
confirm that this is the latest version.
Not all devices/types available in every country. Please check with local NEC representative for
availability and additional information.
Document No. U15723EJ1V0DS00 (1st edition)
Date Published October 2001 N CP(K)
Printed in Japan
©
2001
µPD17P709A
FUNCTIONAL OUTLINE
(1/2)
Part Number
µ PD17704A
µ PD17705A µ PD17707A µ PD17708A µ PD17709A µ PD17P709A
Program memory (ROM)
8192 × 16 bits
(mask ROM)
12288 × 16 bits
(mask ROM)
General-purpose data memory (RAM)
672 × 4 bits
Instruction execution time
1.78 µ s (with f X = 4.5 MHz crystal oscillator)
General-purpose ports
• I/O ports:
• Input ports:
Item
• Output ports:
16384 × 16 bits
(mask ROM)
1120 × 4 bits
16384 × 16 bits
(one-time PROM)
1176 × 4 bits
46
12
4
Stack levels
• Address stack: 15 levels
• Interrupt stack: 4 levels
• DBF stack:
4 levels (can be manipulated via software)
Interrupts
• External: 6 sources (falling edge of CE pin, INT0 to INT4)
• Internal: 6 sources (timers 0 to 3, serial interfaces 0 and 1)
Timer
5
•
•
•
•
channels
Basic timer (clock: 10, 20, 50, 100 Hz):
8-bit timer with gate counter (clock: 1 k, 2 k, 10 k, 100 kHz):
8-bit timer (clock: 1 kHz, 2 kHz, 10 kHz, 100 kHz):
8-bit timer multiplexed with PWM (clock: 440 Hz, 4.4 kHz):
1
1
2
1
channel
channel
channels
channel
A/D converter
8 bits × 6 channels (hardware mode and software mode selectable)
D/A converter (PWM)
3 channels (8-bit or 9-bit resolution selectable by software)
Output frequency: 4.4 kHz, 440 Hz (with 8-bit PWM selected)
2.2 kHz, 220 Hz (with 9-bit PWM selected)
Serial interface
2 units (3 channels)
• 3-wire serial I/O:
2 channels
• 2-wire serial I/O/I 2 C bus: 1 channel
PLL
Division mode
• Direct division mode (VCOL pin (MF mode):
• Pulse swallow mode (VCOL pin (HF mode):
0.5 to 3 MHz)
10 to 40 MHz)
(VCOH pin (VHF mode): 60 to 130 MHz)
2
Reference frequency
13 types selectable (1, 1.25, 2.5, 3, 5, 6.25, 9, 10, 12.5, 18, 20, 25, 50 kHz)
Charge pump
Two error-out output pins (EO0, EO1)
Phase comparator
Unlock status detectable by program
Intermediate frequency counter
• Intermediate frequency (IF) measurement
P1C0/FMIFC pin : 10 to 11 MHz in FMIF mode
0.4 to 0.5 MHz in AMIF mode
P1C1/AMIFC pin: 0.4 to 0.5 MHz in AMIF mode
• External gate width measurement
P2A1/FCG1, P2A0/FCG0 pin
BEEP output
2 pins
Output frequency: 1 kHz, 3 kHz, 4 kHz, 6.7 kHz (BEEP0 pin)
67 Hz, 200 Hz, 3 kHz, 4 kHz (BEEP1 pin)
Data Sheet U15723EJ1V0DS
µPD17P709A
(2/2)
Part Number
Item
µ PD17704A
µ PD17705A µ PD17707A µ PD17708A µ PD17709A µ PD17P709A
Reset
• Power-on reset (on power application)
• Reset by RESET pin
• Watchdog timer reset
Can be set only once on power application: 65536 instructions, 131072
instructions, or no-use
selectable
• Stack pointer overflow/underflow reset
Can be set only once on power application: interrupt stack or address stack
selectable
• CE reset (CE pin low → high level)
CE reset delay timing can be set.
• Power failure detection function
Standby
• Clock stop mode (STOP)
• Halt mode (HALT)
Supply voltage
• PLL operation: VDD = 4.5 to 5.5 V
• CPU operation: V DD = 3.5 to 5.5 V
Package
80-pin plastic QFP (14 × 14)
Data Sheet U15723EJ1V0DS
3
µPD17P709A
PIN CONFIGURATION (TOP VIEW)
80-pin plastic QFP (14 × 14)
µ PD17P709AGC-3B9
P0C1
P0C0
P0A3/SDA
P0A2/SCL
P0A1/SCK0
P0A0/SO0
P0B3/SI0
P0B2/SCK1
P0B1/SO1
P0B0/SI1
P2D2
P2D1
P2D0
REG
GND0
XIN
XOUT
CE
VDD0
RESET
(1) Normal operation mode
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
INT2
1
60
P0C2
P1A3/INT4
2
59
P0C3
P1A2/INT3
3
58
P2C0
P1A1
4
57
P2C1
P1A0/TM0G
5
56
P2C2
P3A3
6
55
P2C3
P3A2
7
54
P3D0
P3A1
8
53
P3D1
P3A0
9
52
P3D2
P3B3
10
51
P3D3
P3B2
11
50
P3C0
P3B1
12
49
P3C1
P3B0
13
48
P3C2
P2A2
14
47
P3C3
P2A1/FCG1
15
46
P2B0
P2A0/FCG0
16
45
P2B1
P1B3
17
44
P2B2
P1B2/PWM2
18
43
P2B3
P1B1/PWM1
19
42
INT0
P1B0/PWM0
20
41
INT1
Data Sheet U15723EJ1V0DS
P1D0/BEEP0
P1D2
P1D1/BEEP1
P1D3
TEST
EO1
EO0
GND1
VCOL
VCOH
VDD1
P1C0/FMIFC
P1C1/AMIFC
P1C2/AD4
P1C3/AD5
P0D0/AD0
P0D1/AD1
P0D2/AD2
GND2
4
P0D3/AD3
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
µPD17P709A
(L)
Note
REG
GND0
(OPEN)
CLK
(L)
VDD0
(H)
(2) PROM programming mode
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
(L)
(OPEN)
1
60
2
59
3
58
D0
4
57
D1
5
56
D2
6
55
D3
7
54
D4
8
53
D5
9
52
D6
10
51
D7
11
50
12
49
13
48
14
47
15
46
16
45
17
44
18
43
19
42
20
(L)
(L)
41
(L)
VPP
(OPEN)
GND1
(L)
MD0
VDD1
MD1
MD2
MD3
(L)
GND2
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
Note Connect to the same potential as VDD .
Caution
The items in parentheses indicate the processing of pins not used in the PROM programming
mode.
L:
Independently connect to GND via a resistor (470 Ω)
H:
Independently connect each pin to VDD via a resistor (470 Ω)
OPEN: Leave open.
Data Sheet U15723EJ1V0DS
5
µPD17P709A
PIN NAMES
AD0 to AD5:
6
A/D converter input
P2B0 to P2B3: Port 2B
AMIFC:
AM frequency counter input
P2C0 to P2C3: Port 2C
BEEP0, BEEP1:
BEEP output
P2D0 to P2D2: Port 2D
CE:
Chip enable
P3A0 to P3A3: Port 3A
CLK:
Address update clock input
P3B0 to P3B3: Port 3B
D0 to D7:
Data I/O
P3C0 to P3C3: Port 3C
EO0, EO1:
Error-out output
P3D0 to P3D3: Port 3D
FCG0, FGC1:
Frequency counter gate input
REG:
CPU regulator
FMIFC:
FM frequency counter input
RESET:
Reset input
GND0 to GND2:
Ground 0 to 2
SCK0, SCK1:
3-wire serial clock I/O
INT0 to INT4:
External interrupt input
SCL:
2-wire serial clock I/O
MD0 to MD3:
Operation mode selection
SDA:
2-wire serial data I/O
PWM0 to PWM2: D/A converter output
SI0, SI1:
3-wire serial data input
P0A0 to P0A3:
Port 0A
SO0, SO1:
3-wire serial data output
P0B0 to P0B3:
Port 0B
TEST:
Test input
P0C0 to P0C3:
Port 0C
TM0G:
Timer 0 gate input
P0D0 to P0D3:
Port 0D
VCOH:
Local oscillation high input
P1A0 to P1A3:
Port 1A
VCOL:
Local oscillation low input
P1B0 to P1B3:
Port 1B
V DD0, V DD1:
Power supply
P1C0 to P1C3:
Port 1C
V PP:
Program voltage application
P1D0 to P1D3:
Port 1D
X IN, X OUT:
Main clock oscillation
P2A0 to P2A2:
Port 2A
Data Sheet U15723EJ1V0DS
µPD17P709A
BLOCK DIAGRAM
P0A0 to P0A3
4
P0B0 to P0B3
4
P0C0 to P0C3
4
P0D0 to P0D3
4
P1A0 to P1A3
4
VCOH
PLL
SO0/P0A0
RAM
1776 × 4 bits
SCK0/P0A1
Serial
interface 0
SYSREG
4
P1C0 (MD0)
to P1C3 (MD3)
4
P1D0 to P1D3
4
EO0
EO1
RF
P1B0 to P1B3
VCOL
SCL/P0A2
SDA/P0A3
SI0/P0B3
SCK1/P0B2
Ports
P2A0 to P2A2
3
P2B0 to P2B3
4
P2C0 (D0)
to P2C3 (D3)
4
P2D0 to P2D2
3
Serial
interface 1
SO1/P0B1
SI1/P0B0
ALU
BEEP
BEEP0/P1D0
BEEP1/P1D1
P3A0 to P3A3
4
P3B0 to P3B3
4
P3C0 to P3C3
4
P3D0 (D4)
to P3D3 (D7)
4
Instruction
decoder
INT0
INT1
Interrupt
control
INT2
INT3/P1A2
INT4/P1A3
One-time PROM
16384 × 16 bits
FCG0/P2A0
Frequency
counter
FCG1/P2A1
FMIFC/P1C0
AMIFC/P1C1
AD0/P0D0
AD1/P0D1
AD2/P0D2
AD3/P0D3
A/D
converter
8-bit
timer 0
gate
counter
Program counter
TM0G/P1A0
AD4/P1C2
AD5/P1C3
8-bit
timer 1
Stack
PWM0/P1B0
PWM1/P1B1
D/A
converter
8-bit
timer 2
PWM2/P1B2
8-bit
timer 3
CPU
Peripheral
OSC
XIN
XOUT
CE
Basic
timer
Reset
RESET
VDD0, VDD1
GND0 to GND2
VCPU
Remark
Regulator
REG
Pins in parentheses are used in PROM programming mode.
Data Sheet U15723EJ1V0DS
7
µPD17P709A
CONTENTS
1. PIN FUNCTIONS ..............................................................................................................................
1.1
Pin Function List ..................................................................................................................
1.2
PROM Programming Mode .................................................................................................
1.3
Equivalent Circuits of Pins .................................................................................................
1.4
Connections of Unused Pins ..............................................................................................
1.5
Cautions on Using CE, INT0 to INT4, and RESET Pins
(Only in Normal Operation Mode) ......................................................................................
1.6
Cautions on Using TEST Pin (Only in Normal Operation Mode) .....................................
9
9
13
14
19
2. ONE-TIME PROM (PROGRAM MEMORY) WRITE, READ, AND VERIFY ....................................
2.1
Operation Modes for Program Memory Write, Read and Verify ......................................
2.2
Program Memory Write Procedure ....................................................................................
2.3
Program Memory Read Procedure .....................................................................................
22
23
24
25
21
21
3. ELECTRICAL SPECIFICATIONS ......................................................................................................... 26
4. PACKAGE DRAWING ..........................................................................................................................31
5. RECOMMENDED SOLDERING CONDITIONS ................................................................................... 32
APPENDIX DEVELOPMENT TOOLS ...................................................................................................... 33
8
Data Sheet U15723EJ1V0DS
µPD17P709A
1. PIN FUNCTIONS
1.1 Pin Function List
Pin No.
Symbol
Function
Output Form
1
41
42
INT2
INT1
INT0
Edge-detectable vectored interrupt input pins. Rising or falling edge can be
specified.
–
2
3
4
5
P1A3/INT4
P1A2/INT3
P1A1
P1A0/TM0G
Port 1A multiplexed with external interrupt request signal input and event
signal input pins.
• P1A3 to P1A0
• 4-bit input port
• INT4, INT3
• Edge-detectable vectored interrupt
• TM0G
• Input for gate of 8-bit timer 0
–
After reset
6
|
9
P3A3
|
P3A0
Power-on reset
WDT&SP reset
Input
(P1A3 to P1A0)
Input
(P1A3 to P1A0)
With clock stopped
CE reset
Retained
Retained
4-bit I/O port.
Input or output can be specified in 4-bit units.
After reset
Power-on reset
Input
WDT&SP reset
Input
CMOS
push-pull
With clock stopped
CE reset
Retained
Retained
10
P3B3
4-bit I/O port.
CMOS
|
13
|
P3B0
Input or output can be specified in 4-bit units.
push-pull
After reset
Power-on reset
Input
14
15
16
P2A2
P2A1/FCG1
P2A0/FCG0
WDT&SP reset
Input
With clock stopped
CE reset
Retained
Retained
Port 2A multiplexed with external gate counter input pins.
• P2A2 to P2A0
• 3-bit I/O port
• Input or output can be specified in 1-bit units.
• FCG1, FCG0
• Input for external gate counter
After reset
Power-on reset
WDT&SP reset
Input
(P2A2 to P2A0)
Input
(P2A2 to P2A0)
CMOS
push-pull
With clock stopped
CE reset
Retained
(P2A2 to P2A0)
Data Sheet U15723EJ1V0DS
Retained
(P2A2 to P2A0)
9
µPD17P709A
Pin No.
Symbol
17
18
|
20
P1B3
P1B2/PWM2
|
P1B0/PWM0
Function
Output Form
Port 1B multiplexed with D/A converter output pins.
• P1B3 to P1B0
• 4-bit output port
• PWM2 to P2M0
• 8- or 9-bit D/A converter output
After reset
Power-on reset
WDT&SP reset
Outputs low level
Outputs low level
(P1B3 to P1B0)
(P1B3 to P1B0)
N-ch
open-drain
(12 V
withstanding
voltage)
With clock stopped
CE reset
Retained
Retained
(P1B3 to P1B0)
21
33
75
GND2
GND1
GND0
Ground
–
22
|
25
P0D3/AD3
|
P0D0/AD0
Port 0D multiplexed with A/D converter input pins
• P0D3 to P0D0
• 4-bit input port
• Pull-down resistors can be connected in 1-bit units.
• AD3 to AD0
• Analog input of A/D converter with 8-bit resolution
–
After reset
26
27
28
29
P1C3/AD5
P1C2/AD4
P1C1/AMIFC
P1C0/FMIFC
Power-on reset
WDT&SP reset
Input with pull-down
resistor
(P0D3 to P0D0)
Input with pull-down
resistor
(P0D3 to P0D0)
With clock stopped
CE reset
Retained
Retained
Port 1C multiplexed with A/D converter input and IF counter input pins.
• P1C3 to P1C0
• 4-bit input port
• AD5, AD4
• Analog input to A/D converter with 8-bit resolution
• FMIFC, AMIFC
• Input to frequency counter
After reset
10
Power-on reset
WDT&SP reset
Input
(P1C3 to P1C0)
Input
(P1C3 to P1C0)
With clock stopped
CE reset
• P1C3/AD5,
P1C2/AD4
Retained
• P1C1/AMIFC,
P1C0/FMIFC
Input
(P1C1, P1C0)
Data Sheet U15723EJ1V0DS
• P1C3/AD5,
P1C2/AD4
Retained
• P1C1/AMIFC,
P1C0/FMIFC
Input
(P1C1, P1C0)
–
µPD17P709A
Pin No.
Symbol
Function
Output Form
30
79
V DD 1
V DD 0
Power supply. Supply the same voltage to these
• With CPU and peripheral function operating:
• With CPU operating:
• With clock stopped:
pins.
4.5 to 5.5 V
3.5 to 5.5 V
2.2 to 5.5 V
31
32
VCOH
VCOL
PLL local oscillation (VCO) frequency input.
• VCOH
• Active with VHF mode selected by program; otherwise, pulled down.
• VCOL
• Active with HF or MW mode selected by program; otherwise, pulled down.
–
–
Because the input of these pins goes into an AC amplifier, cut the DC
component of the input signal with a capacitor.
34
35
EO0
EO1
Output from charge pump of PLL frequency synthesizer. Outputs the divided
frequency of local oscillation and the result of comparison of the phase
difference of the reference frequency.
After reset
CMOS
3-state
With clock stopped
Power-on reset
WDT&SP reset
CE reset
High-impedance
output
High-impedance
output
High-impendance
output
36
TEST
Test input pin.
Be sure to connect this pin to GND.
37
38
39
40
P1D3
P1D2
P1D1/BEEP1
P1D0/BEEP0
Port 1D and BEEP output.
• P1D3 to P1D0
• 4-bit I/O port
• Input or output can be specified in 1-bit units.
• BEEP1, BEEP0
High-impedance
output
–
CMOS
push-pull
• BEEP output
After reset
Power-on reset
43
|
46
P2B3
|
P2B0
Input
Retained
Retained
(P1D3 to P1D0)
(P1D3 to P1D0)
(P1D3 to P1D0)
(P1D3 to P1D0)
4-bit I/O port.
Input or output can be specified in 1-bit units.
After reset
Input
P3C3
|
P3C0
CE reset
Input
Power-on reset
47
|
50
WDT&SP reset
With clock stopped
WDT&SP reset
Input
CMOS
push-pull
With clock stopped
CE reset
Retained
Retained
4-bit I/O port.
Input or output can be specified in 4-bit units.
After reset
Power-on reset
Input
WDT&SP reset
Input
CMOS
push-pull
With clock stopped
CE reset
Retained
Data Sheet U15723EJ1V0DS
Retained
11
µPD17P709A
Pin No.
51
|
54
Symbol
P3D3
|
P3D0
Function
4-bit I/O port.
Input or output can be specified in 4-bit units.
Input
P2C3
|
P2C0
65
66
67
68
69
70
P0A1/SCK0
P0A0/SO0
P0B3/SI0
P0B2/SCK1
P0B1/SO1
P0B0/SI1
WDT&SP reset
Input
CE reset
Retained
P2D2
|
P2D0
WDT&SP reset
Input
CMOS
push-pull
CE reset
Retained
Retained
Ports P0A and P0B are multiplexed with I/O of serial interface.
• P0A3 to P0A0
• 4-bit I/O port
• Input or output can be specified in 1-bit units.
• P0B3 to P0B0
• 4-bit I/O port
• Input or output can be specified in 1-bit units.
• SDA, SCL
• Serial data and serial clock I/O of serial interface 0 in 2-wire serial I/O or
I 2 C bus mode
• SCK0, SO0, SI0
• Serial clock I/O, serial data output, and serial data input of serial interface
0 in 3-wire serial I/O mode
• SCK1, SO1, SI1
• Serial clock I/O, serial data output, serial data input of serial interface 1
in 3-wire serial I/O mode
WDT&SP reset
CE reset
Input
P0A3 to P0A0,
P0B3 to P0B0
Input
P0A3 to P0A0,
P0B3 to P0B0
Retained
P0A3 to P0A0,
P0B3 to P0B0
After reset
Input
Input
CMOS
push-pull
Retained
P0A3 to P0A0,
P0B3 to P0B0
3-bit I/O port.
Input or output can be specified in 1-bit units.
WDT&SP reset
N-ch
open-drain
With clock stopped
Power-on reset
Power-on reset
12
Retained
With clock stopped
After reset
71
|
73
CMOS
push-pull
With clock stopped
After reset
Input
P0A3/DSA
P0A2/SCL
Retained
4-bit I/O port.
Input or output can be specified in 4-bit units.
Power-on reset
63
64
Retained
After reset
Input
P0C3
|
P0C0
Input
CE reset
4-bit I/O port.
Input or output can be specified in 4-bit units.
Power-on reset
59
|
62
WDT&SP reset
CMOS
push-pull
With clock stopped
After reset
Power-on reset
55
|
58
Output Form
CMOS
push-pull
With clock stopped
CE reset
Retained
Data Sheet U15723EJ1V0DS
Retained
µPD17P709A
Pin No.
Symbol
Function
Output Form
74
REG
CPU regulator.
Connect this pin to GND via 0.1 µ F capacitor.
–
76
77
X OUT
X IN
Ground pins of crystal resonator.
–
78
CE
Device operation selection, CE reset, and interrupt signal input pin.
• Device operation selection
When CE is high, the PLL frequency synthesizer can operate.
When CE is low, the PLL frequency synthesizer is automatically disabled
internally.
• CE reset
When CE goes high, the device is reset at the rising edge of the internal
basic timer setting pulse. This pin also has a reset timing delay function.
• Interrupt
–
A vectored interrupt occurs at the falling edge of this pin.
80
RESET
Reset input
–
1.2 PROM Programming Mode
Pin No.
Symbol
26
|
MD3
|
29
MD0
21
33
GND2
GND1
75
GND0
36
Function
Output Form
Input for operating mode selection for program memory write, read, or
verify.
–
Ground
–
V PP
Pin to which program voltage is applied during program memory write, read,
or verify. +12.5 V is applied.
–
30
V DD 1
Power supply pins. +6 V is applied during program memory write, read, or
–
79
V DD 0
verify.
51
D7
8-bit data I/O for program memory write, read, or verify
|
58
|
D0
77
CLK
Clock input for address updating during program memory write, read, or
CMOS push-pull
–
verify
Remark
The pins other than those listed above are not used in PROM programming mode. For the handling
of the unused pins, see PIN CONFIGURATION (2) PROM programming mode.
Data Sheet U15723EJ1V0DS
13
µPD17P709A
1.3 Equivalent Circuits of Pins
(1) P0A (P0A1/SCK0, P0A0/SO0)
P0B (P0B3/SI0, P0B2/SCK1, P0B1/SO1, P0B0/SI1)
P0C (P0C3, P0C2, P0C1, P0C0)
P1D (P1D3, P1D2, P1D1/BEEP1, P1D0/BEEP0)
P2A (P2A2, P2A1/FCG1, P2A0/FCG0)
P2B (P2B3, P2B2, P2B1, P2B0)
(I/O)
P2C (P2C3, P2C2, P2C1, P2C0)
P2D (P2D2, P2D1, P2D0)
P3A (P3A3, P3A2, P3A1, P3A0)
P3B (P3B3, P3B2, P3B1, P3B0)
P3C (P3C3, P3C2, P3C1, P3C0)
P3D (P3D3, P3D2, P3D1, P3D0)
VDD
CKSTOPNote
VDD
Note This is an internal signal that is output when the clock stop instruction is executed. Its circuit is
designed not to increase the current consumption due to noise even if it is floated.
14
Data Sheet U15723EJ1V0DS
µPD17P709A
(2) P0A (P0A3/SDA, P0A2/SCL) (I/O)
VDD
CKSTOPNote
Note This is an internal signal that is output when the clock stop instruction is executed. Its circuit is
designed not to increase the current consumption due to noise even if it is floated.
(3) P1B (P1B3, P1B2/PWM2, P1B1/PWM1, P1B0/PWM0) (output)
(4) P0D (P0D3/AD3, P0D2/AD2, P0D1/AD1, P0D0/AD0) (input)
A/D converter
VDD
CKSTOPNote
P0DPLD flag
High on-resistance
Note This is an internal signal that is output when the clock stop instruction is executed. Its circuit is
designed not to increase the current consumption due to noise even if it is floated.
Data Sheet U15723EJ1V0DS
15
µPD17P709A
(5) P1A (P1A1) (input)
VDD
(6) P1C (P1C3/AD5, P1C2/AD4) (input)
VDD
A/D converter
(7) P1C (P1C1/AMIFC, P1C0/FMIFC) (input)
VDD
General-purpose port
VDD
High on-resistance
VDD
Frequency counter
16
Data Sheet U15723EJ1V0DS
µPD17P709A
(8) CE
RESET
INT0, INT1, INT2
(Schmitt-triggered input)
P1A (P1A3/INT4, P1A2/INT3, P1A0/TM0G)
VDD
(9) X OUT (output), X IN (input)
VDD
High on-resistance
VDD
XIN
Internal clock
High onresistance
XOUT
(10) EO1, EO0 (output)
VDD
DWN
UP
Data Sheet U15723EJ1V0DS
17
µPD17P709A
(11) VCOH, VCOL (input)
VDD
High on-resistance
VDD
High onresistance
18
Data Sheet U15723EJ1V0DS
µPD17P709A
1.4 Connections of Unused Pins
It is recommended to connect unused pins as follows.
Table 1-1. Connections of Unused Pins
(1/2)
Pin Name
Port pin
P0D3/AD3 to P0D0/AD0
I/O Mode
Recommended Connection
Independently connect to GND via a resistorNote 1 .
Input
P1C3/AD5
P1C2/AD4
P1C1/AMIFC Note 2
Set to port mode and individually connect to V DD or GND
P1C0/FMIFC Note 2
via a resistor Note 1 .
P1A3/INT4
Independently connect to GND via a resistor Note 1 .
P1A2/INT3
P1A1
P1A0/TM0G
P1B3
N-ch open-drain
P1B2/PWM2 to P1B0/PWM0
output
P0A3/SDA
I/O Note 3
P0A2/SCL
Set to low-level output by software and leave open.
Set to general-purpose input port mode by software and
independently connect to V DD or GND via a resistor Note 1 .
P0A1/SCK0
P0A0/SO0
P0B3/SI0
P0B2/SCK1
P0B1/SO1
P0B0/SI1
P0C3 to P0C0
P1D3
P1D2
P1D1/BEEP1
P1D0/BEEP0
P2A2
P2A1/FCG1
P2A0/FCG0
P2B3 to P2B0
P2C3 to P2C0
P2D2 to P2D0
Notes 1. If a pin is externally pulled up (connected to V DD via a resistor) or pulled down (connected to GND
via a resistor) with a high resistance, the pin almost enters a high-impedance state, increasing the
current (through-current) consumption of the port. Generally, the resistance of a pull-up or pulldown resistor is several 10 kΩ, although it depends on the application circuit.
2. Do not set these pins as AMIFC and FMIFC pins; otherwise, the current consumption will increase.
3. The I/O ports are set in the general-purpose input port mode at power-on reset, when reset by the
RESET pin, or when reset by an overflow or underflow of the watchdog timer or the stack.
Data Sheet U15723EJ1V0DS
19
µPD17P709A
Table 1-1. Connections of Unused Pins
(2/2)
Pin Name
Port pin
P3A3 to P3A0
I/O Mode
I/O Note 2
Recommended Connection
Set in general-purpose input port mode by software and
independently connect to V DD or GND via a resistor Note 1 .
P3B3 to P3B0
P3C3 to P3C0
P3D3 to P3D0
Non-port
pins
CE
Input
Connect to V DD via a resistor Note 1.
EO1
Output
Leave open.
INT0 to INT2
Input
Independently connect to GND via a resistorNote 1 .
RESET
Input
Connect to V DD via a resistor Note 1.
EO0
TEST
VCOH
–
Input
Directly connect to GND.
Disable PLL via software and leave open.
VCOL
Notes 1. If a pin is externally pulled up (connected to V DD via a resistor) or pulled down (connected to GND
via a resistor) with a high resistance, the pin almost enters a high-impedance state, increasing the
current (through-current) consumption of the port. Generally, the resistance of a pull-up or pulldown resistor is several 10 kΩ, although it depends on the application circuit.
2. The I/O ports are set in the general-purpose input port mode at power-on reset, when reset by the
RESET pin, or when reset by an overflow or underflow of the watchdog timer or the stack.
20
Data Sheet U15723EJ1V0DS
µPD17P709A
1.5 Cautions on Using CE, INT0 to INT4, and RESET Pins (Only in Normal Operation Mode)
The CE, INT0 to INT4, and RESET pins have a function to set a test mode in which the internal operations
of the µ PD17P709A are tested (IC test), in addition to the functions listed in 1.1 Pin Function List.
When a voltage exceeding V DD is applied to any of these pins, the device is set in the test mode. If a noise
exceeding V DD is superimposed during normal operation, therefore, the test mode is set by mistake, affecting
the normal operation.
Especially if the wiring length of pins is too long, noise is superimposed on these pins. In consequence, the
above problem occurs.
Therefore, keep the wiring length as short as possible to prevent noise from being superimposed.
If
superimposition of noise is unavoidable, connect an external component as illustrated below to suppress the
noise.
•
Connect a diode with a low V F
• Connect a capacitor between the pin and
between the pin and V DD.
V DD.
VDD
Diode with
low VF
VDD
VDD
VDD
CE, INT0 to INT4, RESET
CE, INT0 to INT4, RESET
1.6 Cautions on Using TEST Pin (Only in Normal Operation Mode)
When V DD is applied to the TEST pin, the device is set in the test mode or program memory write/verify mode.
Therefore, be sure to keep the wiring length of this pin as short as possible, and directly connect it to the GND
pin.
If the wiring length between the TEST pin and GND pin is too long, or if external noise is superimposed on
the TEST pin, generating a potential difference between the TEST pin and GND pin, your program may not run
normally.
GND TEST
Short
Data Sheet U15723EJ1V0DS
21
µPD17P709A
2. ONE-TIME PROM (PROGRAM MEMORY) WRITE, READ, AND VERIFY
The µ PD17P709A includes a 16,384 × 16-bit one-time PROM program memory. In normal operation, this
PROM is accessed in 16-bit word units. During program memory write, read, and verify, the PROM is accessed
in 8-bit word units. The higher 8 bits of a 16-bit word are located at an even-numbered address, and the lower
8 bits are located at an odd-numbered address.
The pins used for the write, read, and verify operations of this one-time PROM are listed in Table 2-1.
Clock input from the CLK pin, instead of address input, is used for updating addresses.
Table 2-1. Pins Used for Program Memory Write, Read, and Verify
Pin Name
Function
V PP
Program voltage application (+12.5 V)
CLK
Address update clock input
MD0 to MD3
Operation mode selection
D0 to D7
8-bit data I/O
V DD0, V DD1
Supply voltage application (+6 V)
The specified PROM programmer and a dedicated programmer adapter are used for writing to the on-chip
PROM.
The following PROM programmers and programmer adapters are usable.
PROM Programmer
PG-1500
Programmer Adapter
PA17P709GC
+
PA-17KDZ
(adapter for PG-1500)
Third-party PROM programmers are also available, such as the AF-9703, AF-9704, AF-9705, and AF-9706
(manufactured by Ando Electric Co., Ltd.)
22
Data Sheet U15723EJ1V0DS
µPD17P709A
Figure 2-1. PA-17P709GC and PA-17KDZ
PA-17P709GC
PA-17KDZ
To PG-1500
2.1 Operation Modes for Program Memory Write, Read, and Verify
When +6 V is applied to the VDD pin and +12.5 V to the VPP pin, the µPD17P709A enters the program memory write,
read, and verify mode.
The following operation modes can be set by setting pins MD0 to MD3 as shown below.
Pins not listed in Table 2-2 should be connected to GND via a pull-down resistor (470 Ω) (refer to PIN
CONFIGURATION (2) PROM programming mode).
Table 2-2. Operation Mode Setting for Program Memory Write, Read, and Verify
Operation Mode Setting
VPP
+12.5 V
Remark
Operation Mode
VDD
MD0
MD1
MD2
MD3
+6 V
H
L
H
L
Program memory address 0-clear mode
L
H
H
H
Write mode
L
L
H
H
Write/verify mode
H
×
H
H
Program inhibit mode
×: L or H
Data Sheet U15723EJ1V0DS
23
µPD17P709A
2.2 Program Memory Write Procedure
Program memory can be written at high speed using the following procedure.
(1)
Pull down unused pins to GND via a resistor. Set the CLK pin to low.
(2)
Supply 5 V to the V DD pin. Set the V PP pin to low.
(3)
Wait for 10 µ s and then supply 5 V to the V PP pin.
(4)
Set the mode setting pin to program memory address 0-clear mode.
(5)
Supply +6 V to the V DD pin and +12.5 V to the V PP pin.
(6)
Set the program inhibit mode.
(7)
Write data in the 1 ms write mode.
(8)
Set the program inhibit mode.
(9)
Set the verify mode. If the data is correct, go to step (10). If not, repeat steps (7) to (9).
(10) (X: Number of write operations from steps (7) to (9)) × 1 ms additional write.
(11) Set the program inhibit mode.
(12) Input four pulses to the CLK pin to increment the program memory address by one.
(13) Repeat steps (7) to (12) until the end address is reached.
(14) Set the program memory address 0-clear mode.
(15) Change the V DD and V PP pins to 5 V.
(16) Turn off the power.
The following figure shows steps (2) to (12).
X repetitions
Reset
Verify
Write
VDD
VPP
Additional write
Address
increment
VDD + 1
VDD
GND
VPP
VDD
GND
CLK
D0 to D7
Hi - Z
Data input
Hi - Z
Data output
MD0
MD1
MD2
MD3
24
Data Sheet U15723EJ1V0DS
Hi - Z
Data input
Hi - Z
µPD17P709A
2.3 Program Memory Read Procedure
(1)
Pull down unused pins to GND via a resistor. Set the CLK pin to low.
(2)
Supply 5 V to the V DD pin. Set the V PP pin to low.
(3)
Wait for 10 µ s and then supply 5 V to the VPP pin.
(4)
Set the mode setting pin to program memory address 0-clear mode.
(5)
Supply +6 V to the V DD pin and +12.5 V to the V PP pin.
(6)
Set the program inhibit mode.
(7)
Set the verify mode. Addresses are incremented by one for each 4-pulse cycle input to the CLK pin.
(8)
Set the program inhibit mode.
(9)
Set the program memory address 0-clear mode.
(10) Change the V DD and V PP pins to 5 V.
(11) Turn off the power.
The following figure shows steps (2) to (9).
Reset
VDD
VPP
VDD + 1
VDD
GND
VPP
VDD
GND
CLK
D0 to D7
Hi - Z
Data output
Data output
Hi - Z
MD0
MD1
“L”
MD2
MD3
Data Sheet U15723EJ1V0DS
25
µPD17P709A
3. ELECTRICAL SPECIFICATIONS
Absolute Maximum Ratings (TA = 25°C)
Parameter
Symbol
Conditions
Ratings
Unit
Supply voltage
VDD
–0.3 to +6.0
V
PROM program voltage
VPP
–0.3 to +13.5
V
Other than CE, INT0 to INT4, and RESET pins
–0.3 to VDD + 0.3
V
CE, INT0 to INT4, and RESET pins
–0.3 to VDD + 0.6
V
–0.3 to VDD + 0.3
V
Input voltage
VI
Output voltage
VO
Except P1B0 to P1B3
Output current, high
IOH
Per pin
–8.0
mA
Total of P2A0 to P2A2, P3A0 to P3A3,
and P3B0 to P3B3
–15.0
mA
Total of P0A0 to P0A3, P0B0 to P0B3, P0C0 to P0C3,
P1D0 to P1D3, P2B0 to P2B3, P2C0 to P2C3,
P2D0 to P2D2, P3C0 to P3C3, and P3D0 to P3D3
–25.0
mA
Per pin for P1B0 to P1B3
12.0
mA
Per pin for P1B0 to P1B3
8.0
mA
Total of P2A0 to P2A2, P3A0 to P3A3,
and P3B0 to P3B3
15.0
mA
Total of P0A0 to P0A3, P0B0 to P0B3, P0C0 to P0C3,
P1D0 to P1D3, P2B0 to P2B3, P2C0 to P2C3,
P2D0 to P2D2, P3C0 to P3C3, and P3D0 to P3D3
25.0
mA
Total of P1B0 to P1B3 pins
25.0
mA
P1B0 to P1B3
14.0
V
Output current, low
Output voltage
IOL
VBDS
Total power dissipation
Pt
200
mW
Operating ambient
temperature
TA
–40 to +85
°C
Storage temperature
Tstg
–55 to +125
°C
Caution Product quality may suffer if the absolute maximum rating is exceeded even momentarily for any
parameter. That is, the absolute maximum ratings are rated values at which the product is on
the verge of suffering physical damage, and therefore the product must be used under conditions
that ensure that the absolute maximum ratings are not exceeded.
Recommended Operating Range (TA = –40 to +85°C)
Parameter
Supply voltage
Symbol
Conditions
MIN.
TYP.
MAX.
Unit
VDD1
When CPU and PLL are operating
4.5
5.0
5.5
V
VDD2
When CPU and PLL are stopped
3.5
5.0
5.5
V
MIN.
TYP.
MAX.
Unit
12
V
Recommended Output Withstanding Voltage (TA = –40 to +85°C)
Parameter
Output withstanding
voltage
26
Symbol
VBDS
Conditions
P1B0 to P1B3
Data Sheet U15723EJ1V0DS
µPD17P709A
DC Characteristics (TA = –40 to +85°C, VDD = 3.5 to 5.5 V)
Parameter
Supply current
Data retention voltage
Symbol
Conditions
MIN.
TYP.
MAX.
Unit
IDD1
When CPU is operating and PLL is stopped with
sine wave input to XIN pin.
(fIN = 4.5 MHz ±1%, VIN = VDD)
1.5
3.0
mA
IDD2
When CPU and PLL are stopped with sine-wave
input to XIN pin.
(fIN = 4.5 MHz ±1%, VIN = VDD)
With HALT instruction
0.7
1.5
mA
VDDR1
Crystal oscillation
3.5
5.5
V
VDDR2
Crystal oscillation Power failure detection by timer FF
2.2
5.5
V
VDDR3
stopped
2.0
5.5
V
IDDR1
Crystal oscillation VDD = 5 V, TA = 25°C
2.0
4.0
µA
IDDR2
stopped
2.0
30.0
µA
VIH1
P0A0, P0B1, P0C0 to P0C3, P1A0, P1A1, P1C0 to
P1C3, P1D0 to P1D3, P2A2, P2B0 to P2B3,
P2C0 to P2C3, P2D0 to P2D2, P3A0 to P3A3,
P3B0 to P3B3, P3C0 to P3C3, P3D0 to P3D3
0.7VDD
VDD
V
VIH2
P0A1 to P0A3, P0B0, P0B2, P0B3, P2A0, P2A1, CE,
INT0 to INT4, RESET
0.8VDD
VDD
V
VIH3
P0D0 to P0D3
0.55VDD
VDD
V
VIL1
P0A0, P0B1, P0C0 to P0C3, P1A0, P1A1, P1C0 to
P1C3, P1D0 to P1D3, P2A2, P2B0 to P2B3,
P2C0 to P2C3, P2D0 to P2D2, P3A0 to P3A3,
P3B0 to P3B3, P3C0 to P3C3, P3D0 to P3D3
0
0.3VDD
V
VIL2
P0A1 to P0A3, P0B0, P0B2, P0B3, P2A0, P2A1, CE,
INT0 to INT4, RESET
0
0.2VDD
V
VIL3
P0D0 to P0D3
0
0.15VDD
V
IOH1
P0A0 to P0A3, P0B0 to P0B3, P0C0 to P0C3,
P1D0 to P1D3, P2A0 to P2A2, P2B0 to P2B3,
P2C0 to P2C3, P2D0 to P2D2, P3A0 to P3A3,
P3B0 to P3B3, P3C0 to P3C3, P3D0 to P3D3
VOH = VDD – 1 V
–1.0
mA
IOH2
EO0, EO1
VDD = 4.5 to 5.5 V, VOH = VDD – 1 V
–3.0
mA
IOL1
P0A0 to P0A3, P0B0 to P0B3, P0C0 to P0C3,
P1D0 to P1D3, P2A0 to P2A2, P2B0 to P2B3,
P2C0 to P2C3, P2D0 to P2D2, P3A0 to PA3A,
P3B0 to P3B3, P3C0 to P3C3, P3D0 to P3D3
VOL = 1 V
1.0
mA
IOL2
EO0, EO1
VDD = 4.5 to 5.5 V, VOL = 1 V
3.0
mA
IOL3
P1B0 to P1B3
VOL = 1 V
7.0
mA
Input current, high
IIH
P0D0 to P0D3 pulled down
VIN = VDD
5.0
Output off leakage
ILO1
P1B0 to P1B3
current
ILO2
EO0, EO1
Input leakage current,
high
ILIH
Input pin
Input leakage current, low
ILIL
Input pin
Data retention current
Input voltage, high
Input voltage, low
Output current, high
Output current, low
Data memory retained
150
µA
1.0
µA
±1.0
µA
VIN = VDD
1.0
µA
VIN = 0 V
–1.0
µA
VIN = 12 V
VIN = VDD, VIN = 0 V
Data Sheet U15723EJ1V0DS
27
µPD17P709A
AC Characteristics (TA = –40 to +85°C, VDD = 5 V ±10%)
Parameter
Symbol
Operating frequency
fIN1
fIN2
Conditions
MIN.
TYP.
MAX.
Unit
VCOL pin,
Sine-wave input VIN = 0.15Vp-p
0.8
3
MHz
MF mode
Sine-wave input VIN = 0.1Vp-p
0.5
3
MHz
10
40
MHz
VCOL pin, HF mode, sine-wave input
VIN = 0.1Vp-pNote
fIN3
VCOH pin, VHF mode, sine-wave input
VIN = 0.1Vp-pNote
60
130
MHz
fIN4
AMIFC pin, sine-wave input
0.4
0.5
MHz
VIN = 0.15Vp-p
fIN5
FMIFC pin, FMIF count mode, sine-wave input
VIN = 0.20Vp-p
10
11
MHz
fIN6
FMIFC pin, AMIF count mode, sine-wave input
VIN = 0.15Vp-p
0.4
0.5
MHz
SIO0 input frequency
fIN7
External clock
1
MHz
SIO1 input frequency
fIN8
External clock
0.7
MHz
Note
The condition of sine-wave input VIN = 0.1Vp-p is the rated value when the µPD17P709A is operating alone.
Where influence of noise must be taken into consideration, operation under input amplitude conditions of
VIN = 0.15Vp-p is recommended.
A/D Converter Characteristics (TA = –40 to +85°C, VDD = 5 V ±10%)
Parameter
Symbol
Conditions
A/D conversion total error
8 bits
A/D conversion total error
8 bits
MIN.
TYP.
MAX.
Unit
±3.0
LSB
±2.5
LSB
TYP.
MAX.
Unit
6.0
12.0
mA
TA = 0 to 85°C
Reference Characteristics (TA = +25°C, VDD = 5.0 V)
Parameter
Symbol
Supply current
IDD3
Conditions
MIN.
When CPU and PLL are operating with sine-wave
input to VCOH pin
(fIN = 130 MHz, VIN = 0.3Vp-p)
DC Programming Characteristics (TA = 25°C, VDD = 6.0 ±0.25 V, VPP = 12.5 ±0.5 V)
Parameter
Symbol
Input voltage, high
Conditions
VDD
V
V
Pins other than CLK
0
0.2VDD
V
VIL2
CLK
0
0.4
V
Input leakage current
ILI
VIN = VIL or VIH
10
µA
Output voltage, high
VOH
IOH = –1 mA
Output voltage, low
VOL
IOL = 1 mA
VDD supply current
IDD
VPP supply current
IPP
28
VIL1
Unit
VDD
2.
CLK
MAX.
0.7VDD
Cautions 1.
Pins other than CLK
TYP.
VDD – 0.5
Input voltage, low
VIH1
VIH2
MIN.
VDD – 1.0
MD0 = VIL, MD1 = VIH
Ensure that VPP does not exceed +13.5 V including overshoot.
VDD must be applied before VPP, and cut after VPP.
Data Sheet U15723EJ1V0DS
V
1.0
V
30
mA
30
mA
µPD17P709A
AC Programming Characteristics (TA = 25°C, VDD = 6.0 ±0.25 V, VPP = 12.5 ±0.5 V)
Parameter
Symbol
Conditions
MIN.
TYP.
MAX.
Unit
Address setup timeNote (to MD0↓)
tAS
2
µs
MD1 setup time (to MD0↓)
tM1S
2
µs
Data setup time (to MD0↓)
tDS
2
µs
tAH
2
µs
Data hold time (from MD0↑)
tDH
2
µs
Delay time from MD0↑ to data output float
tDF
0
VPP setup time (to MD3↑)
tVPS
2
µs
VDD setup time (to MD3↑)
tVDS
2
µs
Initial program pulse width
tPW
0.95
Additional program pulse width
tOPW
0.95
MD0 setup time (to MD1↑)
tM0S
2
Delay time from MD0↓ to data output
tDV
MD0 = MD1 = VIL
MD1 hold time (from MD0↑)
tM1H
tM1H + tM1R ≥ 50 µs
MD1 recovery time (from MD0↓)
Note
Address hold time
(from MD0↑)
130
1.0
ns
1.05
ms
21.0
ms
µs
1
µs
2
µs
tM1R
2
µs
Program counter reset time
tPCR
10
µs
CLK input high-/low-level widths
tXH, tXL
0.125
µs
CLK 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
Program memory read
Delay time from addressNote to data output
tDAD
Program memory read
Hold time from addressNote to data output
tHAD
Program memory read
0
MD3 hold time (from MD0↑)
tM3HR
Program memory read
2
Delay time from MD3↓ to data output float
tDFR
Program memory read
Reset setup time
tRES
Note
4.19
µs
2
2
µs
130
ns
µs
2
10
MHz
µs
µs
The internal address signal is incremented by 1 on the 3rd fall of a four-clock input (CLK) cycle, and is not
connected to a pin.
Data Sheet U15723EJ1V0DS
29
µPD17P709A
Program Memory Write Timing
tRES
tVPS
VPP
VPP
VDD
GND
VDD + 1
VDD
tVDS
VDD
tXH
GND
CLK
tXL
Data input
D0-D7
tDS
tI
Data output
tDH
tDV
tDF
Data input
Data input
tDH
tAH
tDS
tAS
MD0
tPW
tM0S
tM1R
tOPW
MD1
tPCR
tM1S
tM1H
MD2
tM3H
tM3S
MD3
Remark The dashed line indicates high-impedance.
Program Memory Read Timing
tRES
tVPS
VPP
VPP
VDD
GND
VDD + 1
tVDS
VDD
VDD
tXH
GND
CLK
tDAD
tHAD
tXL
Hi-Z
D0-D7
Hi-Z
Data output
Data output
tDFR
tDV
tI
tM3HR
MD0
MD1
L
tPCR
MD2
tM3SR
MD3
30
Data Sheet U15723EJ1V0DS
µPD17P709A
4. PACKAGE DRAWING
80-PIN PLASTIC QFP (14x14)
A
B
41
40
60
61
detail of lead end
S
C D
Q
R
21
20
80
1
F
G
J
H
I
M
K
P
S
N
S
L
M
NOTE
ITEM
Each lead centerline is located within 0.13 mm of
its true position (T.P.) at maximum material condition.
MILLIMETERS
A
17.2±0.4
B
14.0±0.2
C
14.0±0.2
D
17.2±0.4
F
0.825
G
0.825
H
I
0.30±0.10
0.13
J
0.65 (T.P.)
K
1.6±0.2
0.8±0.2
L
M
0.15 +0.10
−0.05
N
0.10
P
2.7±0.1
Q
0.1±0.1
R
5°±5°
S
3.0 MAX.
S80GC-65-3B9-6
Data Sheet U15723EJ1V0DS
31
µPD17P709A
5. RECOMMENDED SOLDERING CONDITIONS
The µPD17P709A should be soldered and mounted under the following recommended conditions.
For details of the recommended soldering conditions, refer to the document Semiconductor Device Mounting
Technology Manual (C10535E).
For soldering methods and conditions other than those recommended below, contact an NEC sales representative.
Table 5-1. Surface Mounting Type Soldering Conditions
µPD17P709AGC-3B9: 80-pin plastic QFP (14 × 14)
Soldering Method
Soldering Conditions
Recommended
Condition
Symbol
Infrared reflow
Package peak temperature: 235°C, Time: 30 seconds MAX. (at 210°C or higher.),
Count: Three times or less
IR35-00-3
VPS
Package peak temperature: 215°C, Time: 40 seconds MAX. (at 200°C or higher.),
Count: Three times or less
VP15-00-3
Wave soldering
Solder bath temperature: 260°C MAX., Time: 10 seconds MAX., Count: Once,
Preheating temperature: 120°C MAX. (package surface temperature)
WS60-00-1
Partial heating
Pin temperature: 300°C MAX., Time: 3 seconds MAX. (per pin row)
Caution Do not use different soldering methods together (except for partial heating).
32
Data Sheet U15723EJ1V0DS
—
µPD17P709A
APPENDIX DEVELOPMENT TOOLS
The following development tools are available for development of programs for the µPD17P709A.
Hardware
Name
Outline
In-circuit emulator
(IE-17K-ETNote 1)
IE-17K-ET is an in-circuit emulator that can be used with any model in the 17K Series.
IE-17K-ET is connected to a host machine, which is PC-9800 series or IBM PC/ATTM, with RS-232C.
By using these in-circuit emulators with a system evaluation board (SE board) corresponding to each
model, these emulators operate as emulators specific to a model. When man-machine interface
software SIMPLEHOSTTM is used, a more sophisticated debugging environment can be created.
SE board
(SE-17709)
SE-17709 is an SE board for the µPD17709A Subseries. This board can be used alone to evaluate
a system, or in combination with an in-circuit emulator for debugging.
Emulation probe
(EP-17K80GC)
EP-17K80GC is an emulation probe for the µPD17P709AGC. By using this probe with EV-9200GC80Note 2, the SE board and target system are connected.
Conversion socket
(EV-9200GC-80Note 2)
EV-9200GC-80 is a conversion socket for 80-pin plastic QFP (14 × 14). It is used to connect the EP17K80GC and target system.
PROM programmer
(PG-1500)
PG-1500 is a PROM programmer supporting µPD17P709A. It can program the µPD17P709A when
connected with the PG-1500 adapter PA-17KDZ and programmer adapter PA-17P709GC.
Programmer adapter
(PA-17P709GC)
PA-17P709GC is an adapter to program the µPD17P709A. It is used with PG-1500.
Notes 1. External power supply type
2. One EV-9200GC-80 is supplied with the EP-17K80GC. Five EV-9200GC-80 are also available as a set.
Remark Third-party PROM programmers AF-9703, AF-9704, AF-9705, and AF-9706 are available from Ando
Electric Co., Ltd. Use these programmers with programmer adapter PA-17P709GC. For details, consult
Ando Electric Co., Ltd. (TEL: +8-44-549-7300).
Software
Name
17K Series
assembler
(RA17K)
Device file
(AS17704)
Outline
Host Machine
RA17K is an assembler that can be
commonly used with 17K Series.
To develop programs for the
µPD17P709A, this RA17K and a
device file (AS17704) are used in
combination.
AS17704 is a device file for the
µPD17P709A.
It is used with the assembler common
to the 17K Series (RA17K).
SIMPLEHOST is man-machine
Support
interface software that runs on
software
Windows when a program is
(SIMPLEHOST) developed by using an in-circuit
emulator and personal computer.
OS
Media
Parts Number
PC-9800 series Japanese WindowsTM 3.5” 2HD
µSAA13RA17K
IBM PC/AT
Japanese Windows 3.5” 2HC
µSAB13RA17K
compatibles
English Windows
µSBB13RA17K
PC-9800 series Japanese Windows 3.5” 2HD
µSAA13AS17704
IBM PC/AT
Japanese Windows 3.5” 2HC
µSAB13AS17704
compatibles
English Windows
µSBB13AS17704
PC-9800 series Japanese Windows 3.5” 2HD
µSAA13ID17K
IBM PC/AT
Japanese Windows 3.5” 2HC
µSAB13ID17K
compatibles
English Windows
µSBB13ID17K
Data Sheet U15723EJ1V0DS
33
µPD17P709A
NOTES FOR CMOS DEVICES
1
PRECAUTION AGAINST ESD FOR SEMICONDUCTORS
Note:
Strong electric field, when exposed to a MOS device, can cause destruction of the gate oxide and
ultimately degrade the device operation. Steps must be taken to stop generation of static electricity
as much as possible, and quickly dissipate it once, when it has occurred. Environmental control
must be adequate. When it is dry, humidifier should be used. It is recommended to avoid using
insulators that easily build static electricity. Semiconductor devices must be stored and transported
in an anti-static container, static shielding bag or conductive material. All test and measurement
tools including work bench and floor should be grounded. The operator should be grounded using
wrist strap. Semiconductor devices must not be touched with bare hands. Similar precautions need
to be taken for PW boards with semiconductor devices on it.
2
HANDLING OF UNUSED INPUT PINS FOR CMOS
Note:
No connection for CMOS device inputs can be cause of malfunction. If no connection is provided
to the input pins, it is possible that an internal input level may be generated due to noise, etc., hence
causing malfunction. CMOS devices behave differently than Bipolar or NMOS devices. Input levels
of CMOS devices must be fixed high or low by using a pull-up or pull-down circuitry. Each unused
pin should be connected to V DD or GND with a resistor, if it is considered to have a possibility of
being an output pin. All handling related to the unused pins must be judged device by device and
related specifications governing the devices.
3
STATUS BEFORE INITIALIZATION OF MOS DEVICES
Note:
Power-on does not necessarily define initial status of MOS device. Production process of MOS
does not define the initial operation status of the device. Immediately after the power source is
turned ON, the devices with reset function have not yet been initialized. Hence, power-on does
not guarantee out-pin levels, I/O settings or contents of registers. Device is not initialized until the
reset signal is received. Reset operation must be executed immediately after power-on for devices
having reset function.
34
Data Sheet U15723EJ1V0DS
µPD17P709A
Regional Information
Some information contained in this document may vary from country to country. Before using any NEC
product in your application, pIease contact the NEC office in your country to obtain a list of authorized
representatives and distributors. They will verify:
•
Device availability
•
Ordering information
•
Product release schedule
•
Availability of related technical literature
•
Development environment specifications (for example, specifications for third-party tools and
components, host computers, power plugs, AC supply voltages, and so forth)
•
Network requirements
In addition, trademarks, registered trademarks, export restrictions, and other legal issues may also vary
from country to country.
NEC Electronics Inc. (U.S.)
NEC Electronics (Germany) GmbH
NEC Electronics Hong Kong Ltd.
Santa Clara, California
Tel: 408-588-6000
800-366-9782
Fax: 408-588-6130
800-729-9288
Benelux Office
Eindhoven, The Netherlands
Tel: 040-2445845
Fax: 040-2444580
Hong Kong
Tel: 2886-9318
Fax: 2886-9022/9044
NEC Electronics Hong Kong Ltd.
Velizy-Villacoublay, France
Tel: 01-3067-5800
Fax: 01-3067-5899
Seoul Branch
Seoul, Korea
Tel: 02-528-0303
Fax: 02-528-4411
NEC Electronics (France) S.A.
NEC Electronics Singapore Pte. Ltd.
Milton Keynes, UK
Tel: 01908-691-133
Fax: 01908-670-290
Madrid Office
Madrid, Spain
Tel: 091-504-2787
Fax: 091-504-2860
Novena Square, Singapore
Tel: 253-8311
Fax: 250-3583
NEC Electronics Italiana s.r.l.
NEC Electronics (Germany) GmbH
Milano, Italy
Tel: 02-66 75 41
Fax: 02-66 75 42 99
Scandinavia Office
Taeby, Sweden
Tel: 08-63 80 820
Fax: 08-63 80 388
NEC Electronics (France) S.A.
NEC Electronics (Germany) GmbH
Duesseldorf, Germany
Tel: 0211-65 03 02
Fax: 0211-65 03 490
NEC Electronics (UK) Ltd.
NEC Electronics Taiwan Ltd.
Taipei, Taiwan
Tel: 02-2719-2377
Fax: 02-2719-5951
NEC do Brasil S.A.
Electron Devices Division
Guarulhos-SP, Brasil
Tel: 11-6462-6810
Fax: 11-6462-6829
J01.2
Data Sheet U15723EJ1V0DS
35
µPD17P709A
Purchase of NEC I2C components conveys a license under the Philips I2C Patent Rights to use these
components in an I2C system, provided that the system conforms to the I2C Standard Specification as defined
by Philips.
SIMPLEHOST is a trademark of NEC Corporation.
Windows is either a registered trademark or trademark of Microsoft Corporation in the United States and/
or other countries.
PC/AT is a trademark of International Business Machines Corporation.
The export of this product from Japan is regulated by the Japanese government. To export this product may be prohibited
without governmental license, the need for which must be judged by the customer. The export or re-export of this product
from a country other than Japan may also be prohibited without a license from that country. Please call an NEC sales
representative.
• The information in this document is current as of September, 2001. The information is subject to
change without notice. For actual design-in, refer to the latest publications of NEC's data sheets or
data books, etc., for the most up-to-date specifications of NEC semiconductor products. Not all
products and/or types are available in every country. Please check with an NEC sales representative
for availability and additional information.
• No part of this document may be copied or reproduced in any form or by any means without prior
written consent of NEC. NEC assumes no responsibility for any errors that may appear in this document.
• NEC does not assume any liability for infringement of patents, copyrights or other intellectual property rights of
third parties by or arising from the use of NEC semiconductor products listed in this document or any other
liability arising from the use of such products. No license, express, implied or otherwise, is granted under any
patents, copyrights or other intellectual property rights of NEC or others.
• Descriptions of circuits, software and other related information in this document are provided for illustrative
purposes in semiconductor product operation and application examples. The incorporation of these
circuits, software and information in the design of customer's equipment shall be done under the full
responsibility of customer. NEC assumes no responsibility for any losses incurred by customers or third
parties arising from the use of these circuits, software and information.
• While NEC endeavours to enhance the quality, reliability and safety of NEC semiconductor products, customers
agree and acknowledge that the possibility of defects thereof cannot be eliminated entirely. To minimize
risks of damage to property or injury (including death) to persons arising from defects in NEC
semiconductor products, customers must incorporate sufficient safety measures in their design, such as
redundancy, fire-containment, and anti-failure features.
• NEC semiconductor products are classified into the following three quality grades:
"Standard", "Special" and "Specific". The "Specific" quality grade applies only to semiconductor products
developed based on a customer-designated "quality assurance program" for a specific application. The
recommended applications of a semiconductor product depend on its quality grade, as indicated below.
Customers must check the quality grade of each semiconductor product before using it in a particular
application.
"Standard": Computers, office equipment, communications equipment, test and measurement equipment, audio
and visual equipment, home electronic appliances, machine tools, personal electronic equipment
and industrial robots
"Special": Transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster
systems, anti-crime systems, safety equipment and medical equipment (not specifically designed
for life support)
"Specific": Aircraft, aerospace equipment, submersible repeaters, nuclear reactor control systems, life
support systems and medical equipment for life support, etc.
The quality grade of NEC semiconductor products is "Standard" unless otherwise expressly specified in NEC's
data sheets or data books, etc. If customers wish to use NEC semiconductor products in applications not
intended by NEC, they must contact an NEC sales representative in advance to determine NEC's willingness
to support a given application.
(Note)
(1) "NEC" as used in this statement means NEC Corporation and also includes its majority-owned subsidiaries.
(2) "NEC semiconductor products" means any semiconductor product developed or manufactured by or for
NEC (as defined above).
2
M8E 00. 4