DATA SHEET MOS INTEGRATED CIRCUIT µPD17P719 4-BIT SINGLE-CHIP MICROCONTROLLER WITH BUILT-IN HARDWARE DEDICATED TO DIGITAL TUNING SYSTEMS The µPD17P719 is produced by replacing the built-in masked ROM of the µPD17717, µPD17718, and µPD17719 with a one-time PROM. The µPD17P719 allows programs to be written once, so that the µPD17P719 is suitable for preproduction in µPD17717, µPD17718, or µPD17719 system development or low-volume production. When reading this document, also refer to the publications on the µPD17717, µPD17718, or µPD17719. The electrical characteristics (including power supply currents) and PLL analog characteristics of the µPD17P719 differ from those of the µPD17717, µPD17718, and µPD17719. In high-volume application set production, carefully check those differences. FEATURES • Compatible with the µPD17717, µPD17718, and µPD17719 • Built-in one-time PROM : 32K bytes (16384 × 16 bits) • Supply voltage : PLL operation : VDD = 4.5 to 5.5 V CPU operation : VDD = 3.5 to 5.5 V ORDERING INFORMATION Part number Package µPD17P719GC-3B9 80-pin plastic QFP (14 × 14 mm, 0.65-mm pitch) The information in this document is subject to change without notice. Document No. U12112EJ1V0DS00 (1st edition) Date Published February 1997 J Printed in Japan © 1997 µPD17P719 FUNCTION OVERVIEW (1/2) Product µPD17717 Program memory (ROM) 12288 × 16 bits (masked ROM) General-purpose data memory (RAM) 1120 × 4 bits Item µPD17P719 µPD17719 µPD17718 16384 × 16 bits (masked ROM) 16384 × 16 bits (one-time PROM) 1776 × 4 bits Instruction execution time 1.78 µs (with fX = 4.5-MHz crystal) General-purpose ports • I/O ports : 46 • Input ports : 12 • Output ports : 4 Stack level • Address stack : 15 levels • Interrupt stack : 4 levels • DBF stack : 4 levels (operated by software) Interrupt • External : 6 (CE rising edge and INT0 to INT4) • Internal : 6 (timers 0 to 3, serial interfaces 0 and 1) Timers 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 k, 2 k, 10 k, 100 kHz) 8-bit timer, also used for PWM (clock: 440 Hz, 4.4 kHz) : : : : 1 1 2 1 channel channel channels channel A/D converter 8 bits × 6 channels (Hardware or software mode can be selected.) D/A converter (PWM) 3 channels (8-bit or 9-bit resolution, selected by software.) Output frequency : 4.4 kHz, 440 Hz (8-bit PWM) 2.2 kHz, 220 Hz (9-bit PWM) Serial interface 2 systems (4 channels) • Selectable for 3-wire serial I/O method, SBI method, 2-wire serial I/O method, or I2C bus methodNote. • Selectable for 3-wire serial I/O method or UART method. PLL Frequency division system • Direct frequency division system (VCOL pin (MF mode) : 0.5 to 3 MHz) • Pulse swallow system (VCOL pin (HF mode) : 10 to 40 MHz) (VCOH pin (VHF mode) : 60 to 130 MHz) Reference frequency Can be set to one of 13 frequencies (1, 1.25, 2.5, 3, 5, 6.25, 9, 10, 12.5, 18, 20, 25, or 50 kHz). Charge pump 2 error output pins (EO0 and EO1) Phase comparator Unlock detection is enabled by software. 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 and P2A0/FCG0 pins Note When ordering a mask, please consult our sales office if the I2C bus method is used (or when the serial interface is accomplished by the program not by the peripheral hardware). 2 µPD17P719 (2/2) Item Product µPD17717 µPD17718 µPD17719 µPD17P719 BEEP output 2 Output frequency : 1 kHz, 3 kHz, 4 kHz, 6.7 kHz (BEEP0 pin) 67 Hz, 200 Hz, 3 kHz, 4 kHz (BEEP1 pin) Reset • Power-on reset (when the power is turned on) • Reset using the RESET pin • Watchdog timer reset Can be set only once at power-on: 65,536 instructions, 131,072 instructions, or non-use can be selected. • Stack pointer overflow/underflow reset Can be set only once at power-on: the interrupt stack or address stack can be selected. • CE reset (CE pin: low → high) A 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 : VDD = 3.5 to 5.5 V Package 80-pin plastic QFP (14 × 14 mm, 0.65-mm pitch) 3 µPD17P719 PIN CONFIGURATION (TOP VIEW) 80-pin plastic QFP (14 × 14 mm, 0.65-mm pitch) µPD17P719GC-3B9 P0C1 P0C0 P0A3/SDA P0A2/SCL P0A1/SCK2 P0A0/SO2 P0B3/SI2 P0B2/SCK3/ASCK P0B1/SO3/TxD P0B0/SI3/RxD P2D2/SCK P2D1/SB1 P2D0/SB0 REG GND0 XOUT XIN 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 P1D0/BEEP0 P1D1/BEEP1 P1D2 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 µPD17P719 (L) REGNote 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 41 (L) (L) (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 parentheses above indicate the handling of the pins not used in PROM programming mode. L : Connect each pin to GND through a resistor (470 ohms). H : Connect each pin to VDD through a resistor (470 ohms). OPEN : Leave each pin open. 5 µPD17P719 PIN NAMES AD0-AD5 6 : A/D converter inputs P2C0-P2C3 : Port 2C AMIFC : AM frequency counter input P2D0-P2D2 : Port 2D ASCK : UART serial clock I/O P3A0-P3A3 : Port 3A BEEP0, BEEP1 : Beep outputs P3B0-P3B3 : Port 3B CE : Chip enable P3C0-P3C3 : Port 3C CLK : Address update clock input P3D0-P3D3 : Port 3D D0-D7 : Data I/O REG : CPU regulator EO0, EO1 : Error outputs RESET : Reset input FCG0, FCG1 : Frequency counter gate inputs RxD : UART serial data input FMIFC : FM frequency counter input SB0, SB1 : SBI serial data I/O GND0-GND2 : Ground 0 to 2 SCK : SBI serial clock I/O INT0-INT4 : External interrupt inputs SCK2, SCK3 : 3-wire serial clock I/O MD0-MD3 : Operating mode selection SCL PWM0-PWM2 : D/A converter outputs SDA : 2-wire serial data I/O P0A0-P0A3 : Port 0A SI2, SI3 : 3-wire serial data input P0B0-P0B3 : Port 0B SO2, SO3 : 3-wire serial data output P0C0-P0C3 : Port 0C TEST : Test input P0D0-P0D3 : Port 0D TM0G : Timer 0 gate input P1A0-P1A3 : Port 1A TxD : UART serial data output P1B0-P1B3 : Port 1B VCOH : Local oscillation high input P1C0-P1C3 : Port 1C VCOL : Local oscillation low input P1D0-P1D3 : Port 1D VDD0, VDD1 : Power supply P2A0-P2A2 : Port 2A VPP : Program voltage application P2B0-P2B3 : Port 2B XIN, XOUT : Main clock oscillation : 2-wire serial clock I/O µPD17P719 BLOCK DIAGRAM P0A0-P0A3 4 P0B0-P0B3 4 VCOH PLL RF P0C0-P0C3 4 P0D0-P0D3 4 P1A0-P1A3 4 P1B0-P1B3 4 VCOL EO0 EO1 SO2/P0A0 RAM 1776 × 4 bits SCK2/P0A1 SCL/P0A2 Serial interface 2 SYSREG SDA/P0A3 SI2/P0B3 SB0/P2D0 P1C0(MD0)P1C3(MD3) 4 P1D0-P1D3 4 P2A0-P2A2 3 SB1/P2D1 ALU P2B0-P2B3 4 P2C0(D0)-P2C3(D3) 4 P2D0-P2D2 3 P3A0-P3A3 4 P3B0-P3B3 4 P3C0-P3C3 4 P3D0(D4)-P3D3(D7) 4 SCK/P2D2 Ports Serial interface 3 Instruction decoder SCK3/P0B2/ASCK SO3/P0B1/TxD SI3/P0B0/RxD BEEP BEEP0/P1D0 BEEP1/P1D1 INT0 One-time PROM 16384 × 16 bits Interrupt control INT1 INT2 INT3/P1A2 INT4/P1A3 AD0/P0D0 AD1/P0D1 AD2/P0D2 AD3/P0D3 FCG0/P2A0 Program counter Frequency counter FMIFC/P1C0 AMIFC/P1C1 Stack 8-bit timer 0 Gate counter A/D converter AD4/P1C2 AD5/P1C3 PWM0/P1B0 PWM1/P1B1 PWM2/P1B2 FCG1/P2A1 TM0G/P1A0 8-bit timer 1 D/A converter 8-bit timer 2 8-bit timer 3 CPU Peripheral OSC Basic timer Reset GND0-GND2 VCPU XIN(CLK) XOUT Regurator CE RESET VDD0,VDD1 REG Remark Pins enclosed in parentheses are used in PROM programming mode. 7 µPD17P719 CONTENTS 1. PIN FUNCTIONS ......................................................................................................................... 9 1.1 NORMAL OPERATION MODE ....................................................................................................... 9 1.2 PROM PROGRAMMING MODE ..................................................................................................... 13 1.3 EQUIVALENT CIRCUIT OF PINS .................................................................................................. 14 1.4 HANDLING UNUSED PINS ............................................................................................................ 19 1.5 NOTES ON USE OF THE CE, INT0-INT4, AND RESET PINS (ONLY IN NORMAL OPERATION MODE) ....................................................................................................................... 21 NOTES ON USE OF THE TEST PIN (ONLY IN NORMAL OPERATION MODE) ...................... 21 ONE-TIME PROM (PROGRAM MEMORY) WRITE, READ, AND VERIFICATION ................ 22 2.1 OPERATING MODES FOR PROGRAM MEMORY WRITE, READ, AND VERIFICATION ........ 23 2.2 PROGRAM MEMORY WRITE PROCEDURE ............................................................................... 24 2.3 PROGRAM MEMORY READ PROCEDURE ................................................................................. 25 3. ELECTRICAL CHARACTERISTICS .......................................................................................... 26 4. PACKAGE DRAWING ................................................................................................................ 31 5. RECOMMENDED SOLDERING CONDITIONS ....................................................................... 32 APPENDIX DEVELOPMENT TOOLS .............................................................................................. 33 1.6 2. 8 µPD17P719 1. PIN FUNCTIONS 1.1 NORMAL OPERATION MODE Pin No. Symbol 1 41 42 INT2 INT1 INT0 2 3 4 5 P1A3/INT4 P1A2/INT3 P1A1 P1A0/TM0G Function Output format Input for edge-detected vectored. Either a rising edge or falling edge can be selected. - Input for port 1A, external interrupt request signal, and event signal - • • • P1A3-P1A0 • 4-bit input port INT4, INT3 • Edge-detected vectored interrupt TM0G • Gate input for 8-bit timer 0 When reset 6 to 9 10 to 13 14 15 16 P3A3 to P3A0 P3B3 to P3B0 P2A2 P2A1/FCG1 P2A0/FCG0 Power-on reset WDT&SP reset Input (P1A3-P1A0) Input (P1A3-P1A0) CE reset Held When the clock is stopped Held CMOS push-pull 4-bit I/O port. Input/output can be specified in 4-bit units. When reset Power-on reset WDT&SP reset Input Input CE reset Held When the clock is stopped Held CMOS push-pull 4-bit I/O port. Input/output can be specified in 4-bit units. When reset Power-on reset WDT&SP reset Input Input CE reset Held When the clock is stopped Held CMOS push-pull Input for port 2A and external gate counter • P2A2-P2A0 • 3-bit I/O port • Input/output can be specified bit by bit. • FCG1, FCG0 • External gate counter input When reset Power-on reset WDT&SP reset Input (P2A2-P2A0) Input (P2A2-P2A0) CE reset Held (P2A2-P2A0) When the clock is stopped Held (P2A2-P2A0) 9 µPD17P719 Pin No. 17 18 to 20 Symbol P1B3 P1B2/PWM2 to P1B0/PWM0 Function Output format Output for port 1B and D/A converter • P1B3-P1B0 • 4-bit output port • PWM2-PWM0 • 8-bit or 9-bit D/A converter output N-ch open-drain (12-V withstand voltage) When reset Power-on reset Low-level output (P1B3-P1B0) 21 33 75 GND2 22 to 25 P0D3/AD3 to P0D0/AD0 WDT&SP reset Low-level output (P1B3-P1B0) CE reset Held Held (P1B3-P1B0) Ground - Input for port 0D and A/D converter • P0D3-P0D0 • 4-bit input port • A pull-down resistor can be set bit by bit. - GND1 GND0 • AD3-AD0 • Analog input for 8-bit-resolution A/D converter When reset Power-on reset WDT&SP reset Input with pulldown resistors (P0D3-P0D0) Input with pulldown resistors (P0D3-P0D0) CE reset Held 26 P1C3/AD5 Input for port 1C, A/D converter, and IF counter 27 P1C2/AD4 • 28 P1C1/AMIFC 29 P1C0/FMIFC • • When the clock is stopped Held - P1C3-P1C0 • 4-bit input port AD5, AD4 • Analog input for 8-bit-resolution A/D converter FMIFC, AMIFC • Frequency counter input When reset Power-on reset Input (P1C3-P1C0) 10 When the clock is stopped WDT&SP reset CE reset When the clock is stopped Input (P1C3-P1C0) • P1C3/AD5, P1C2/AD4 Held • P1C1/AMIFC, P1C0/FMIFC Input (P1C1, P1C0) • P1C3/AD5, P1C2/AD4 Held • P1C1/AMIFC, P1C0/FMIFC Input (P1C1, P1C0) µPD17P719 Pin No. Symbol Function Output format 30 79 VDD1 VDD0 Power supply. Apply the same voltage to the VDD1 and VDD0 pins. • When the CPU and peripheral functions are operating: 4.5 to 5.5 V • When only the CPU is operating: 3.5 to 5.5 V • When the clock is stopped: 2.2 to 5.5 V - 31 32 VCOH VCOL Input for PLL local oscillation (VCO) frequency • VCOH • Active when VHF mode is selected by software. Otherwise, pulled down. • VCOL • Active when HF or MW mode is selected by software. Otherwise, pulled down. - Inputs to these pins are to be AC-amplified. Cut, therefore, the DC components in the input signals by using capacitors. 34 35 EO0 EO1 Output from the charge pump of the PLL frequency synthesizer. The result of phase comparison between the divided local oscillation frequency and reference frequency is output. When reset Power-on reset CE reset WDT&SP reset CMOS tristate When the clock is stopped High-impedance High-impedance High-impedance High-impedance output output output output - 36 TEST Test input pin. Be sure to connect it to GND. 37 38 39 40 P1D3 P1D2 P1D1/BEEP1 P1D0/BEEP0 Output for port 1D and BEEP • P1D3-P1D0 • 4-bit I/O port • Input/output can be specified bit by bit. • BEEP1, BEEP0 • BEEP output When reset 43 to 46 47 to 50 P2B3 to P2B0 P3C3 to P3C0 Power-on reset WDT&SP reset Input (P1D3-P1D0) Input (P1D3-P1D0) CE reset Held (P1D3-P1D0) CMOS push-pull When the clock is stopped Held (P1D3-P1D0) CMOS push-pull 4-bit I/O port. Input/output can be specified bit by bit. When reset Power-on reset WDT&SP reset Input Input CE reset Held When the clock is stopped Held CMOS push-pull 4-bit I/O port. Input/output can be specified in 4-bit units. When reset Power-on reset WDT&SP reset Input Input CE reset Held When the clock is stopped Held 11 µPD17P719 Pin No. 51 to 54 55 to 58 59 to 62 Symbol P3D3 to P3D0 P2C3 to P2C0 P0C3 to P0C0 Function Output format 4-bit I/O port. Input/output can be specified in 4-bit units. When reset Power-on reset WDT&SP reset Input Input CE reset Held P0A3/SDA P0A2/SCL 65 P0A1/SCK2 66 P0A0/SO2 67 P0B3/SI2 68 P0B2/SCK3/ ASCK 69 P0B1/SO3/TxD 70 P0B0/SI3/RxD 71 P2D2/SCK 72 P2D1/SB1 73 P2D0/SB0 Held CMOS push-pull When reset Power-on reset WDT&SP reset Input Input CE reset Held When the clock is stopped Held CMOS push-pull 4-bit I/O port. Input/output can be specified bit by bit. Power-on reset WDT&SP reset Input Input CE reset Held When the clock is stopped Held Input/output for P0A, P0B, P2D, and serial interface • P0A3-P0A0 • 4-bit I/O port • Input/output can be specified bit by bit. • P0B3-P0B0 • 4-bit I/O port • Input/output can be specified bit by bit. • P2D2-P2D0 • 3-bit I/O port • Input/output can be specified bit by bit. • SDA, SCL • Serial data and serial clock I/O when the 2-wire serial I/O or I2C bus of serial interface 2 is selected. • SCK2, SO2, SI2 • Serial clock I/O, serial data output, and serial data input when the 3-wire serial I/O of serial interface 2 is selected. • SCK3, SO3, SI3 • Serial clock I/O, serial data output, and serial data input when the 3-wire serial I/O of serial interface 3 is selected. • ASCK, TxD, RxD • Serial clock I/O, serial data output, and serial data input when the UART of serial interface 3 is selected. • SCK, SB1, SB0 • Serial clock and serial data I/O when the SBI of serial interface 2 is selected. When reset Power-on reset Input P0A3-P0A0, P0B3-P0B0, P2D2-P2D0 12 When the clock is stopped 4-bit I/O port. Input/output can be specified bit by bit. When reset 63 64 CMOS push-pull WDT&SP reset Input P0A3-P0A0, P0B3-P0B0, P2D2-P2D0 CE reset Held P0A3-P0A0, P0B3-P0B0, P2D2-P2D0 When the clock is stopped Held P0A3-P0A0, P0B3-P0B0, P2D2-P2D0 N-ch open-drain CMOS push-pull N-ch open-drain µPD17P719 Pin No. 1.2 Symbol Function Output format 74 REG CPU regulator. Use 0.1-µF capacitor to connect it to GND. - 76 77 XOUT XIN A crystal is connected to these pins. - 78 CE Input for device operation selection, CE reset, and interrupt signals • Device operation selection When CE is high, the PLL frequency synthesizer can be operated. When CE is low, the PLL frequency synthesizer is automatically disabled by the device. • CE reset Setting CE from low to high resets the device upon the detection of a rising edge of the internal basic timer setting pulse. A reset timing delay can also be specified. • Interrupt A vectored interrupt occurs upon the detection of a falling edge of the input signal. - 80 RESET Reset input - PROM PROGRAMMING MODE Pin No. Function Symbol Output format 26 to 29 MD3 to MD0 Input for operating mode selection for program memory write, read, or verification - 21 33 75 GND2 GND1 GND0 Ground - 36 VPP Pin to which program voltage is applied during program memory write, read, or verification. +12.5 V is applied. - 30 79 VDD1 VDD0 Power supply pins. +6 V is applied during program memory write, read, or verification. - 51 to 58 D7 to D0 8-bit data I/O for program memory write, read, or verification 77 CLK Clock input for address updating during program memory write, read, or verification CMOS push-pull - 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. 13 µPD17P719 1.3 EQUIVALENT CIRCUIT OF PINS (1) P0A (P0A1/SCK2, P0A0/SO2) P0B (P0B3/SI2, P0B2/SCK3/ASCK, P0B1/SO3/TxD, P0B0/SI3/RxD) 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/SCK) P3A (P3A3, P3A2, P3A1, P3A0) P3B (P3B3, P3B2, P3B1, P3B0) P3C (P3C3, P3C2, P3C1, P3C0) P3D (P3D3, P3D2, P3D1, P3D0) VDD CKSTOPNote VDD Note In this circuit, a current drained by noise does not increase even if the circuit is in the floating state, because of the internal signal being output when the clock stop instruction is executed. 14 µPD17P719 (2) P0A (P0A3/SDA, P0A2/SCL) P2D (P2D1/SB1, P2D0/SB0) (I/O) VDD CKSTOPNote Note In this circuit, a current drained by noise does not increase even if the circuit is in the floating state, because of the internal signal being output when the clock stop instruction is executed. (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-state resistor Note In this circuit, a current drained by noise does not increase even if the circuit is in the floating state, because of the internal signal being output when the clock stop instruction is executed. 15 µPD17P719 (5) P1A (P1A1) (Input) VDD CKSTOPNote Note In this circuit, a current drained by noise does not increase even if the circuit is in the floating state, because of the internal signal being output when the clock stop instruction is executed. (6) P1C (P1C3/AD5, P1C2/AD4) (Input) VDD A/D converter CKSTOPNote Note In this circuit, a current drained by noise does not increase even if the circuit is in the floating state, because of the internal signal being output when the clock stop instruction is executed. 16 µPD17P719 (7) P1C (P1C1/AMIFC, P1C0/FMIFC) (Input) VDD General-purpose port CKSTOPNote High on-state resistor VDD VDD Frequency counter Note In this circuit, a current drained by noise does not increase even if the circuit is in the floating state, because of the internal signal being output when the clock stop instruction is executed. (8) CE RESET INT0, INT1, INT2 (Schmitt-triggered input) P1A (P1A3/INT4, P1A2/INT3, P1A0/TM0G) VDD 17 µPD17P719 (9) XOUT (Output), XIN (Input) High on-state resistor VDD VDD XIN Internal clock High on-state resistor XOUT (10) EO1, EO0 (Output) VDD DWN UP (11) VCOH, VCOL (Input) VDD High on-state resistor 18 High on-state resistor VDD µPD17P719 1.4 HANDLING UNUSED PINS The unused pins should be handled as indicated in Table 1-1. Table 1-1 Pin P0D3/AD3-P0D0/AD0 I/O format Input P1C3/AD5 P1C2/AD4 P1C1/AMIFCNote 2 P1C0/FMIFCNote 2 (1/2) Recommended handling Connect each pin to GND through a resistor.Note 1 Specify as a port and connect each pin to VDD or GND through a resistor.Note 1 Connect each pin to GND through a resistor.Note 1 P1A3/INT4 P1A2/INT3 P1A1 P1A0/TM0G Port pins Handling Unused Pins P1B3 P1B2/PWM2-P1B0/PWM0 N-ch open-drain output Specify low output, in the software, and leave open. P0A3/SDA P0A2/SCL P0A1/SCK2 P0A0/SO2 I/ONote 3 Specify as a general-purpose input port, in the software, and connect each pin to VDD or GND through a resistor.Note 1 P0B3/SI2 P0B2/SCK3/ASCK P0B1/SO3/TxD P0B0/SI3/RxD P0C3-P0C0 P1D3 P1D2 P1D1/BEEP1 P1D0/BEEP0 P2A2 P2A1/FCG1 P2A0/FCG0 P2B3-P2B0 P2C3-P2C0 Notes 1. When making an external connection to VDD with a pull-up resistor, or to GND with a pull-down resistor, note the following: If the resistance of the pull-up or pull-down resistor is too high, the pin approaches the high impedance state, thus increasing the through current drawn by the port. In general, pull-up and pull-down resistors should have a resistance of between 20 and 50 kilohms, depending on the application circuit. 2. Do not specify AMIFC or FMIFC. If AMIFC or FMIFC is specified, current drain increases. 3. I/O ports become general-purpose input ports upon power-on reset, reset by the RESET pin, watchdog timer reset, or stack overflow/underflow reset. 19 µPD17P719 Table 1-1 Port pins Pin Handling Unused Pins I/O format Recommended handling I/ONote 2 Specify as a general-purpose input port, in the software, and connect each pin to VDD or GND through a resistor.Note 1 CE Input Connect to VDD through a resistor.Note 1 EO1 EO0 Output Leave each pin open. INT0-INT2 Input Connect each pin to GND through a resistor.Note 1 RESET Input Connect to VDD through a resistor.Note 1 P2D2/SCK P2D1/SB1 P2D0/SB0 (2/2) P3A3-P3A0 P3B3-P3B0 P3C3-P3C0 Other than port pins P3D3-P3D0 - TEST Input VCOH VCOL Connect directly to GND. Disable PLL, in the program, and leave each pin open. Notes 1. When making an external connection to VDD with a pull-up resistor, or to GND with a pull-down resistor, note the following: If the resistance of the pull-up or pull-down resistor is too high, the pin approaches the high impedance state, thus increasing the through current drawn by the port. In general, pull-up and pull-down resistors should have a resistance of between 20 and 50 kilohms, depending on the application circuit. 2. I/O ports become general-purpose input ports upon power-on reset, reset by the RESET pin, watchdog timer reset, or stack overflow/underflow reset. 20 µPD17P719 1.5 NOTES ON USE OF THE CE, INT0-INT4, AND RESET PINS (ONLY IN NORMAL OPERATION MODE) The CE, INT0-INT4, and RESET pins can be used as the test mode selection pin for testing the internal operation of the µPD17P719 (IC test), besides the usage shown in Section 1.1. Applying a voltage exceeding VDD to the CE, INT0-INT4, or RESET pin causes the µPD17P719 to enter test mode. When noise exceeding VDD comes in during normal operation, the device may not operate normally. For example, if the wiring from the CE, INT0-INT4, or RESET pin is too long, noise may be induced on the wiring, causing this mode switching. When installing the wiring, lay the wiring in such a way that noise is suppressed as much as possible. If noise yet arises, use an external part to suppress it as shown below. • Connect a diode with low VF between the pin • Connect a capacitor between the pin and VDD. and VDD. VDD VDD Diode with low VF VDD VDD CE, INT0-INT4, RESET CE, INT0-INT4, RESET 1.6 NOTES ON USE OF THE TEST PIN (ONLY IN NORMAL OPERATION MODE) Applying VDD to the TEST pin causes the µPD17P719 to enter test mode or program memory write/verify mode. Keep the wiring as short as possible and connect the TEST pin directly to the GND pin. When the wiring between the TEST pin and GND pin is too long or external noise enters the TEST pin, a voltage difference may occur between the TEST pin and GND pin. When this happens, your program may malfunction. GND TEST Keep the wiring as short as possible. 21 µPD17P719 2. ONE-TIME PROM (PROGRAM MEMORY) WRITE, READ, AND VERIFICATION The program memory built into the µPD17P719 is a one-time PROM (16384 × 16 bits) that is electrically writable. In normal operation, this PROM is accessed on a 16-bit word basis. During program memory write, read, and verification, the PROM is accessed on an 8-bit word basis. The higher 8 bits of a 16-bit word are located at an evennumbered address, and the lower 8 bits are located at an odd-numbered address. For PROM write, read, and verification, PROM programming mode must be specified, and the pins listed in Table 2-1 are used. In this case, address input is not used. Instead, clock input on the CLK pin is used to update addresses. Table 2-1 Pins Used for Program Memory Write, Read, and Verification Function Pin VPP Used to apply the program voltage (+12.5 V) CLK Used to apply an address update clock MD0-MD3 Used to select an operating mode D0-D7 Used to input/output 8-bit data VDD0, VDD1 Used to apply the power supply voltage (+6 V) For writing to the built-in PROM, a specified PROM programmer and dedicated programmer adapter are to be used. The following PROM programmers and programmer adapters are usable: PROM programmer PG-1500 + PA-17KDZ (adapter for PG-1500) Programmer adapter PA-17P709GC Third-party PROM programmers are also available: For example, AF-9703, AF-9704, AF-9705, and AF-9706 (manufactured by Ando Electric Co., Ltd.) 22 µPD17P719 Fig. 2-1 PA17P709GC and PA-17KDZ PA-17P709GC PA-17KDZ To PG-1500 2.1 OPERATING MODES FOR PROGRAM MEMORY WRITE, READ, AND VERIFICATION The µPD17P719 is placed in program memory write, read, and verify mode when +6 V is applied to the VDD pin, and +12.5 V to the VPP pin. In this mode, one of the operating modes indicated in Table 2-2 is set, depending on the setting of the MD0 to MD3 pins. The input pins that are not used for program memory write, read, and verification are connected to GND through a pull-down resistor (470 ohms). (See PIN CONFIGURATION, (2) PROM programming mode.) Table 2-2 Operating Modes for Program Memory Write, Read, and Verication Operating mode specification VPP VDD +12.5 V +6 V Operating mode MD0 MD1 MD2 MD3 H L H L Program memory address zero-clear mode L H H H Write mode L L H H Read/verify mode H X H H Program inhibit mode Remark X: L or H 23 µPD17P719 2.2 PROGRAM MEMORY WRITE PROCEDURE The program memory write procedure is described below. The procedure allows high-speed write operation. (1) Connect the unused pins to GND through pull-down resistors. The CLK pin must be low. (2) Apply 5 V to the VDD pin. The VPP pin must be low. (3) Apply 5 V to the VPP pin after waiting 10 µs. (4) Specify program memory address zero-clear mode, using the mode setting pins. (5) Apply 6 V to VDD, and 12.5 V to VPP. (6) Program inhibit mode (7) Write data in 1-ms write mode. (8) Program inhibit mode (9) Verify mode. When data has been written normally, proceed to step (10). When data has not been written normally, repeat steps (7) to (9). (10) Perform an additional write operation ((X: Number of write operations performed in steps (7) to (9)) × 1 ms). (11) Program inhibit mode (12) Apply four pulses to the CLK pin to increment the program memory address by 1. (13) Repeat steps (7) to (12) until the last address is reached. (14) Program memory address zero-clear mode (15) Change the voltage applied to the VDD and VPP pins to 5 V. (16) Turn off the power. Steps (2) to (12) are illustrated below. Repeat X times Reset Write Additional write Verify Address increment VDD + 1 VDD VDD VPP GND VPP VDD GND CLK D0-D7 MD0 MD1 MD2 MD3 24 Hi-Z Data input Hi-Z Data output Hi-Z Data input Hi-Z µPD17P719 2.3 PROGRAM MEMORY READ PROCEDURE (1) Connect the unused pins to GND through pull-down resistors. The CLK pin must be low. (2) Apply 5 V to the VDD pin. The VPP pin must be low. (3) Apply 5 V to the VPP pin after waiting 10 µs. (4) Specify program memory address zero-clear mode, using the mode setting pins. (5) Apply 6 V to VDD, and 12.5 V to VPP. (6) Program inhibit mode (7) Verify mode. When a clock pulse signal is applied to the CLK pin, data is output for each address every four clock pulses. (8) Program inhibit mode (9) Program memory address zero-clear mode (10) Change the voltage applied to the VDD and VPP pins to 5 V. (11) Turn off the power. Steps (2) to (9) are illustrated below. Reset VDD + 1 VDD VDD GND VPP VPP VDD GND CLK Hi-Z Hi-Z Data output D0-D7 Data output MD0 MD1 “L” MD2 MD3 25 µPD17P719 3. ELECTRICAL CHARACTERISTICS ABSOLUTE MAXIMUM RATINGS (TA = 25 °C) Parameter Symbol Condition Rating Unit Supply voltage VDD -0.3 to +6.0 V PROM program voltage VPP -0.3 to +13.5 V Input voltage VI At other than CE, INT0-INT4, and RESET pins -0.3 to VDD + 0.3 V CE, INT0-INT4, and RESET pins -0.3 to VDD + 0.6 V -0.3 to VDD + 0.3 V Output voltage VO At other than P1B0-P1B3 High output current IOH At one pin -8.0 mA Total for P2A0-P2A2, P3A0-P3A3, and P3B0-P3B3 -15.0 mA Total for P0A0, P0A1, P0B0-P0B3, P0C0-P0C3, P1D0-P1D3, P2B0-P2B3, P2C0-P2C3, -25.0 mA At one pin of P1B0-P1B3 12.0 mA At one pin of other than P1B0-P1B3 8.0 mA Total for P2A0-P2A2, P3A0-P3A3, and P3B0-P3B3 15.0 mA Total for P0A0-P0A3, P0B0-P0B3, P0C0-P0C3, P1D0-P1D3, P2B0-P2B3, P2C0-P2C3, P2D0-P2D2, P3C0-P3C3, and P3D0-P3D3 25.0 mA Total for P1B0-P1B3 25.0 mA P1B0-P1B3 14.0 V P2D2, P3C0-P3C3, and P3D0-P3D3 Low output current IOL Output withstand voltage VBDS Total loss Pt 200 mW Operating ambient temperature TA -40 to +85 °C Storage temperature Tstg -55 to +125 °C Caution Absolute maximum ratings are rated values beyond which physical damage will be caused to the product; if the rated value of any of the parameters in the above table is exceeded, even momentarily, the quality of the product may deteriorate. Always use the product within its rated values. RECOMMENDED OPERATING RANGES (TA = -40 to +85 °C) Parameter Supply voltage Symbol Condition Min. Typ. Max. Unit VDD1 While the CPU and PLL are operating 4.5 5.0 5.5 V VDD2 While the CPU is operating but the PLL is halted 3.5 5.0 5.5 V Min. Typ. Max. Unit 12 V RECOMMENDED OUTPUT WITHSTAND VOLTAGE (TA = -40 to +85 °C) Parameter Output withstand voltage 26 Symbol VBDS Condition P1B0-P1B3 µPD17P719 DC CHARACTERISTICS (TA = -40 to +85 °C, VDD = 3.5 to 5.5 V) Parameter Supply current Data hold voltage Symbol Condition Typ. Max. Unit IDD1 The CPU is operating but the PLL is halted, with a sinusoidal wave applied to the XIN pin. (fIN = 4.5 MHz ±1%, VIN = VDD) 1.5 3.0 mA IDD2 The CPU and PLL are halted, with a sinusoidal wave applied to the XIN pin. (fIN = 4.5 MHz ±1%, VIN = VDD) The HALT instruction is used. 0.7 1.5 mA VDDR1 The crystal oscillator is operating. 3.5 5.5 V VDDR2 The crystal oscillator is halted. The timer flip-flop is used for detecting power failure. 2.2 5.5 V Data memory contents are held. 2.0 5.5 V 2.0 4.0 µA 2.0 30.0 µA VDDR3 Data hold current Min. IDDR1 IDDR2 The crystal oscillator is halted. VDD = 5 V, TA = 25 °C VIH1 P0A0, P0B1, P0C0-P0C3, P1A0, P1A1, P1C0-P1C3, P1D0-P1D3, P2A2, P2B0-P2B3, P2C0-P2C3, P3A0-P3A3, P3B0-P3B3, P3C0-P3C3, P3D0-P3D3 0.7VDD VDD V VIH2 P0A1-P0A3, P0B0, P0B2, P0B3, P2A0, P2A1, P2D0-P2D2, CE, INT0-INT4, RESET 0.8VDD VDD V VIH3 P0D0-P0D3 0.55VDD VDD V VIL1 P0A0, P0B1, P0C0-P0C3, P1A0, P1A1, P1C0-P1C3, P1D0-P1D3, P2A2, P2B0-P2B3, P2C0-P2C3, P3A0-P3A3, P3B0-P3B3, P3C0-P3C3, P3D0-P3D3 0 0.3VDD V VIL2 P0A1-P0A3, P0B0, P0B2, P0B3, P2A0, P2A1, P2D0-P2D2, CE, INT0-INT4, RESET 0 0.2VDD V VIL3 P0D0-P0D3 0 0.15VDD V IOH1 P0A0, P0A1, P0B0-P0B3, P0C0-P0C3, P1D0-P1D3, P2A0-P2A2, P2B0-P2B3, P2C0-P2C3, P2D2, P3A0-P3A3, P3B0-P3B3, P3C0-P3C3, P3D0-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-P0A3, P0B0-P0B3, P0C0-P0C3, P1D0-P1D3, P2A0-P2A2, P2B0-P2B3, P2C0-P2C3, P2D0-P2D2, P3A0-P3A3, P3B0-P3B3, P3C0-P3C3, P3D0-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-P1B3 VOL = 1 V 7.0 mA High input current IIH P0D0-P0D3 are pulled down. VIN = VDD 5.0 Output-off leakage current ILO1 P1B0-P1B3 ILO2 EO0, EO1 High input leakage current ILIH Low input leakage current ILIL High input voltage Low input voltage High output current Low output current 150 µA VIN = 12 V 1.0 µA VIN = VDD, VIN = 0 V ±1.0 µA Input pin VIN = VDD 1.0 µA Input pin VIN = 0 V -1.0 µA 27 µPD17P719 AC CHARACTERISTICS (TA = -40 to +85 °C, VDD = 5 V ±10%) Parameter Operating frequency Symbol fIN1 Min. Condition Typ. Max. Unit VCOL pin in MF mode Sinusoidal wave applied to the VIN pin = 0.15Vp-p 0.8 3 MHz Sinusoidal wave applied to the VIN pin = 0.20Vp-p 0.5 3 MHz fIN2 VCOL pin in HF mode, with a sinusoidal wave applied to the VIN pin = 0.1Vp-pNote 10 40 MHz fIN3 VCOH pin in VHF mode, with a sinusoidal wave applied to the VIN pin = 0.1Vp-pNote 60 130 MHz fIN4 AMIFC pin, with a sinusoidal wave applied to the VIN pin = 0.15Vp-p 0.4 0.5 MHz fIN5 FMIFC pin in FMIF count mode, with a sinusoidal wave applied to the VIN pin = 0.20Vp-p 10 11 MHz fIN6 FMIFC pin in AMIF count mode, with a sinusoidal wave applied to the VIN pin = 0.15Vp-p 0.4 0.5 MHz SIO2 input frequency fIN7 External clock 1 MHz SIO3 input frequency fIN8 External clock 0.7 MHz Note The condition of sinusoidal wave input VIN = 0.1Vp-p is the rated value when the µPD17P719 alone is operating. Where influence of noise must be taken into consideration, operation under input amplitude condition of VIN = 0.15Vp-p is recommended. A/D CONVERTER CHARACTERISTICS (TA = -40 to +85 °C, VDD = 5 V ±10%) Parameter Condition Symbol Total error in A/D conversion 8 bits Total error in A/D conversion 8 bits Min. Max. Unit ±3.0 LSB ±2.5 LSB Typ. Max. Unit 6.0 12.0 mA Typ. TA = 0 to 85 °C REFERENCE CHARACTERISTICS (TA = +25 °C, VDD = 5.0 V) Parameter Supply current 28 Symbol IDD3 Condition The CPU and PLL are operating, with a sinusoidal wave applied to the VCOH pin. (fIN = 130 MHz, VIN = 0.3Vp-p) Min. µPD17P719 DC PROGRAMMING CHARACTERISTICS (TA = 25 ±5 °C, VDD = 6.0 ±0.25 V, VPP = 12.5 ±0.3 V) Symbol Parameter Condition Typ. Max. Unit 0.7VDD VDD V VDD - 0.5 VDD V Min. VIH1 Other than CLK VIH2 CLK VIL1 Other than CLK 0 0.3VDD V VIL2 CLK 0 0.4 V Input leakage current ILI VIN = VIL or VIH 10 µA Output high voltage VOH IOH = -1 mA Output low voltage VOL IOL = 1.6 mA VDD supply current IDD VPP supply current IPP Input high voltage Input low voltage VDD - 1.0 V MD0 = VIL, MD1 = VIH 0.4 V 30 mA 30 mA Cautions 1. VPP must be under +13.5 V including overshoot. 2. VDD must be applied before VPP on and must be off after VPP off. AC PROGRAMMING CHARACTERISTICS (TA = 25 ±5 °C, VDD = 6.0 ±0.25 V, VPP = 12.5 ±0.3 V) Parameter Symbol Note 1 Condition Min. Typ. Max. Unit Address setup timeNote 2 (referred to MD0↓) tAS tAS 2 µs MD1 setup time (referred to MD0↓) tM1S tOES 2 µs Data setup time (referred to MD0↓) tDS tDS 2 µs Address hold timeNote 2 (referred to MD0↑) tAH tAH 2 µs Data hold time (referred to MD0↑) tDH tDH 2 Data output float delay from MD0↑ tDF tDF 0 VPP setup time (referred to MD3↑) tVPS tVPS 2 µs VDD setup time (referred to MD3↑) tVDS tVCS 2 µs Initial program pulse width tPW tPW 0.95 Additional program pulse width tOPW tOPW 0.95 MD0 setup time (referred to MD1↑) tM0S tCES Data output delay from MD0↓ tDV tDV MD0 = MD1 = VIL MD1 hold time (referred to MD0↑) tM1H tOEH tM1H + tM1R ≥ 50 µs MD1 recovery time (referred to MD0↓) tM1R tOR Program counter reset time tPCR CLK input high, low level range tXH,tXL CLK input frequency fX - Initial mode set time tI - 2 µs MD3 setup time (referred to MD1↑) tM3S - 2 µs MD3 hold time (referred to MD1↓) tM3H - 2 µs MD3 setup time (referred to MD0↓) tM3SR Data output delay from address incrementNote 2 tDAD tACC tHAD 1.0 ns 1.05 ms 21.0 ms µs 2 1 µs 2 µs 2 µs - 10 µs - 0.125 µs - 4.19 When reading program memory tOH 0 tM3HR - 2 Data output float delay from MD3↓ tDFR - Reset setup time tRES - MHz µs 2 MD3 hold time (referred to MD0↑) Data output hold time from address incrementNote 2 µs 130 2 µs 130 ns µs 2 10 µs µs Notes 1. Symbols used for the µPD27C256 (The µPD27C256 is used only for maintenance.) 2. The internal address signal is incremented by 1 on the falling edge of the third clock (CLK) pulse, with four CLK pulses treated as one cycle. Internal addresses are not connected to pins. 29 µPD17P719 Write program memory timing tRES tVPS VPP VPP VDD tVDS GND VDD + 1 VDD VDD tXH GND CLK tXL Data output Data input D0-D7 tDS tI tDH tDV Data input Data input tDF tDH tAH tDS tAS MD0 tPW tM1R tOPW tM0S MD1 tM1S tPCR tM1H MD2 tM3H tM3S MD3 Remark The dashed line indicates high-impedance. Read program memory timing tRES tVPS VPP VPP VDD GND tVDS VDD + 1 VDD VDD GND tXH CLK tDAD tHAD tXL Hi-Z Hi-Z D0-D7 Data output tDV tI tM3HR MD0 MD1 L tPCR MD2 tM3SR MD3 30 Data output tDFR µPD17P719 4. PACKAGE DRAWING 80 PIN PLASTIC QFP (14×14) A B 60 61 41 40 detail of lead end C D S R Q 21 20 80 1 F J G I H M K P M N L NOTE Each lead centerline is located within 0.13 mm (0.005 inch) of its true position (T.P.) at maximum material condition. ITEM MILLIMETERS INCHES A 17.2±0.4 0.677±0.016 B 14.0±0.2 0.551 +0.009 –0.008 C 14.0±0.2 0.551 +0.009 –0.008 D 17.2±0.4 0.677±0.016 F 0.825 0.032 G 0.825 0.032 H 0.30±0.10 0.012 +0.004 –0.005 I 0.13 0.005 J 0.65 (T.P.) 0.026 (T.P.) K 1.6±0.2 L 0.8±0.2 0.063±0.008 0.031 +0.009 –0.008 M 0.15 +0.10 –0.05 0.006 +0.004 –0.003 N 0.10 0.004 P 2.7 0.106 Q 0.1±0.1 0.004±0.004 R 5°±5° 5°±5° S 3.0 MAX. 0.119 MAX. S80GC-65-3B9-4 31 µPD17P719 5. RECOMMENDED SOLDERING CONDITIONS The conditions listed below shall be met when soldering the µPD17P719. For details of the recommended soldering conditions, refer to our document SMD Surface Mount Technology Manual (C10535E). Please consult with our sales offices in case any other soldering process is used, or in case soldering is done under different conditions. Table 5-1 Soldering Conditions for Surface-Mount Devices µPD17P719GC-3B9: 80-pin plastic QFP (14 × 14 mm, 0.65-mm pitch) Soldering process Soldering conditions Recommended conditions Infrared ray reflow Peak package's surface temperature: 235 °C Reflow time: 30 seconds or less (at 210 °C or more) Maximum allowable number of reflow processes: 3 IR35-00-3 VPS Peak package's surface temperature: 215 °C Reflow time: 40 seconds or less (at 200 °C or more) Maximum allowable number of reflow processes: 3 VP15-00-3 Wave soldering Solder temperature: 260 °C or less WS60-00-1 Flow time: 10 seconds or less Number of flow processes: 1 Preheating temperature: 120 °C max. (measured on the package surface) Partial heating method Terminal temperature: 300 °C or less Heat time: 3 seconds or less (for one side of a device) - Caution Do not apply more than a single process at once, except for “Partial heating method.” 32 µPD17P719 APPENDIX DEVELOPMENT TOOLS The following support tools are available for developing programs for the µPD17P719. Hardware Name Description In-circuit emulator IE-17K IE-17K-ETNote 1 EMU-17KNote 2 The IE-17K, IE-17K-ET, and EMU-17K are in-circuit emulators applicable to the 17K series. The IE-17K and IE-17K-ET are connected to the host machine (PC-9800 series or IBM PC/ ATTM) through the RS-232C interface. The EMU-17K is inserted into the extension slot of the host machine (PC-9800 series). Use the system evaluation board (SE board) corresponding to each product together with one of these in-circuit emulators. SIMPLEHOSTTM, a man machine interface, implements an advanced debug environment. The EMU-17K also enables user to check the contents of the data memory in real time. SE board (SE-17709) The SE-17709 is an SE board for the µPD17719 sub-series. It is used alone for evaluating the system. It is also used for debugging, in combination with an in-circuit emulator. Emulation probe (EP-17K80GC) The EP-17K80GC is an emulation probe for the µPD17P719GC. When used with the EV9200GC-80Note 3, this emulation probe connects the SE board to the target system. Conversion socket (EV-9200GC-80Note 3) The EV-9200GC-80 is a conversion socket for the 80-pin plastic QFP (14 × 14 mm). It is used to connect the EP-17K80GC to the target system. PROM Programmer (PG-1500) The PG-1500 is a PROM programmer for the µPD17P719. Use this PROM programmer with the PA-17KDZ (adapter for the PG-1500) and PA17P709GC programmer adapter, to program the µPD17P719. Programmer adapter (PA-17P709GC) The PA-17P709GC is a socket unit for the µPD17P719. It is used with the PG-1500. Notes 1. Low-end model, operating on an external power supply 2. The EMU-17K is a product of Naito Densei Machida Seisakusho Co., Ltd.. Contact Naito Densei Machida Seisakusho Co., Ltd. (Kawasaki, 044-822-3813) for details. 3. The EP-17K80GC is supplied together with one EV-9200GC-80. A set of five EV-9200GC-80s is also available. Remark Third-party PROM programmers are also available: For example, AF-9703, AF-9704, AF-9705, and AF9706 (manufactured by Ando Electric Co., Ltd.). These PROM programmers can be used with the PA17P709GC programmer adapter. For details, contact Ando Electric Co., Ltd. (Tokyo, 03-3733-1151). 33 µPD17P719 Software Description Name 17K series assembler (AS17K) AS17K is an assembler applicable to the 17K series. In developing µPD17P719 programs, AS17K is used in combination with a device file (AS17707). Host machine Distribution media OS 5.25-inch, µS5A10AS17K 2HD PC-9800 MS-DOSTM series 3.5-inch, 2HD IBM PC/AT AS17707 has a device file for the µPD17P719 . It is used together with the assembler (AS17K), which is applicable to the 17K series. 3.5-inch, 2HD SIMPLEHOST, running under WindowsTM, provides a man machine interface in developing programs by using a personal computer and incircuit emulator. PC-9800 MS-DOS series Windows PC DOS µS7B13AS17707 5.25-inch, µS5A10IE17K 2HD 3.5-inch, 2HD IBM PC/AT µS5A13AS17707 5.25-inch, µS7B10AS17707 2HC PC DOS 3.5-inch, 2HC Support software (SIMPLEHOST) µS7B13AS17K 5.25-inch, µS5A10AS17707 2HD PC-9800 MS-DOS series IBM PC/AT µS5A13AS17K 5.25-inch, µS7B10AS17K 2HC PC DOSTM 3.5-inch, 2HC Device file (AS17707) Part number µS5A13IE17K 5.25-inch, µS7B10IE17K 2HC 3.5-inch, 2HC µS7B13IE17K Remark The following table lists the versions of the operating systems described in the above table. OS Versions MS-DOS Ver. 3.30 to Ver.5.00ANote PC DOS Ver. 3.1 to Ver. 5.0Note Windows Ver. 3.0 to Ver. 3.1 Note MS-DOS versions 5.00 and 5.00A and PC DOS Ver. 5.0 are provided with a task swap function. This function, however, cannot be used in these software packages. 34 µPD17P719 [MEMO] 35 µPD17P719 [MEMO] 36 µPD17P719 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 device 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 VDD 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. 37 µPD17P719 [MEMO] Caution This product contains an I2C bus interface circuit. When using the I2C bus interface, notify its use to NEC when ordering custom code. NEC can guarantee the following only when the customer informs NEC of the use of the interface: 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. 38 µPD17P719 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: 800-366-9782 Fax: 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. NEC Electronics (Germany) GmbH Duesseldorf, Germany Tel: 0211-65 03 02 Fax: 0211-65 03 490 Velizy-Villacoublay, France Tel: 01-30-67 58 00 Fax: 01-30-67 58 99 Seoul Branch Seoul, Korea Tel: 02-528-0303 Fax: 02-528-4411 NEC Electronics (France) S.A. NEC Electronics Singapore Pte. Ltd. Spain Office Madrid, Spain Tel: 01-504-2787 Fax: 01-504-2860 United Square, Singapore 1130 Tel: 253-8311 Fax: 250-3583 NEC Electronics (France) S.A. NEC Electronics (UK) Ltd. Milton Keynes, UK Tel: 01908-691-133 Fax: 01908-670-290 NEC Electronics Italiana s.r.1. Milano, Italy Tel: 02-66 75 41 Fax: 02-66 75 42 99 NEC Electronics Taiwan Ltd. NEC Electronics (Germany) GmbH Scandinavia Office Taeby, Sweden Tel: 08-63 80 820 Fax: 08-63 80 388 Taipei, Taiwan Tel: 02-719-2377 Fax: 02-719-5951 NEC do Brasil S.A. Sao Paulo-SP, Brasil Tel: 011-889-1680 Fax: 011-889-1689 J96. 8 39 µPD17P719 SIMPLEHOST is a trademark of NEC Corporation. MS-DOS and Windows are trademarks of Microsoft Corporation. PC/AT and PC DOS are trademarks of IBM 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. 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. While NEC Corporation has been making continuous effort to enhance the reliability of its semiconductor devices, the possibility of defects cannot be eliminated entirely. To minimize risks of damage or injury to persons or property arising from a defect in an NEC semiconductor device, customers must incorporate sufficient safety measures in its design, such as redundancy, fire-containment, and anti-failure features. NEC devices are classified into the following three quality grades: "Standard", "Special", and "Specific". The Specific quality grade applies only to devices developed based on a customer designated "quality assurance program" for a specific application. The recommended applications of a device depend on its quality grade, as indicated below. Customers must check the quality grade of each device 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: Aircrafts, aerospace equipment, submersible repeaters, nuclear reactor control systems, life support systems or medical equipment for life support, etc. The quality grade of NEC devices is "Standard" unless otherwise specified in NEC's Data Sheets or Data Books. If customers intend to use NEC devices for applications other than those specified for Standard quality grade, they should contact an NEC sales representative in advance. Anti-radioactive design is not implemented in this product. M4 96. 5