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| DATA SHEET MOS INTEGRATED CIRCUIT PD75208 4-BIT SINGLE-CHIP MICROCOMPUTER DESCRIPTION The PD75208 is a microcomputer with a CPU capable of 1-, 4-, and 8-bit-wise data processing, a ROM, a RAM, I/O ports, a fluorescent display tube controller/driver, a watch timer, a timer/pulse generator capable of outputting 14-bit PWM, a serial interface and a vectored interrupt function integrated on a single-chip. It uses the VCR, ECR and CD fluorescent display tubes as display devices and is most suitable for applications requiring the timer/watch function and high-speed interrupt servicing. It can help to provide the unit with many functions and to decrease performance costs. With the PD75208, the PD75P216A, 75P218 one-time PROM products are available for system development evaluation or small production. The following manual provides detailed description of the functions of the PD75208. Be sure to read this manual when you design an application system. PD75216A User's Manual: IEM-988 5 FEATURES * Architecture equal to that of an 8-bit microcomputer * High-speed operation : Minimum instruction execution time : 0.95 s (when operated at 4.19 MHz) * Instruction execution time variable function realizing a wide range of operating voltages * * * * On-chip large-capacity program memory : 8K bytes Watch operation with an ultra low current consumption : 5A TYP. (at the 3 V operation) On-chip programmable fluorescent display tube controller/driver Timer function : 4 ch * 14-bit PWM output capability with the voltage synthesizer type electronic tuner * Buzzer output capability * Interrupt function with importance attached to applications * For power-off detection * For remote controlled reception * Product with an on-chip PROM : PD75P216A, PD75P218 (on-chip EPROM : WQFN package) 5 5 ORDERING INFORMATION Ordering Code Package 64-pin plastic shrink DIP (750 mil) 64-pin plastic QFP (14 x 20 mm) Quality Grade Standard Standard PD75208CW-xxx PD75208GF-xxx-3BE Please refer to "Quality grade on NEC Semiconductor Devices" (Document number IEI-1209) published by NEC Corporation to know the specification of quality grade on the devices and its recommended applications. The information in this document is subject to change without notice. Document No. IC-1884A (O. D. No. IC-7048C) Date Published August 1993 P Printed in Japan The mark 5 shows major revised points. (c) NEC Corporation 1991 PD75208 5 LIST OF FUNCTIONS Item Instruction execution time Function * 0.95, 1.91, 15.3 s (Main system clock : 4.19 MHz operation) * 122 s (Subsystem clock : 32.768 kHz operation) 8064 x 8 bits 497 x 4 bits * 4-bit manipulation : 8 x 4 banks * 8-bit manipulation : 4 x 4 banks 33 8 20 CMOS input pin CMOS input/output pins * Direct LED drive capability : 8 * On-chip pull-down resistor by mask option capability : 4 * Direct LED drive capability : 4 * PWM/pulse output : 1 * On-chip pull-down resistor by mask option capability : 4 On-chip memory ROM RAM General register Input/output port FIP (R) dual-function pin included FIP dedicated pin excluded FIP controller/driver Timer Serial interface Vectored interrupt Test input System clock oscillator Standby function Mask option Operating temperature range Operating voltage Package 2 * * * * * 5 CMOS output pin No. of segments : 9 to 12 segments No. of digits : 9 to 16 digits Dimmer function : 8 levels On-chip pull-down resistor by mask option capability Key scan interrupt generation * * * * Timer/pulse generator : 14-bit PWM output enabled Watch timer : Buzzer output enabled Timer/event counter Basic interval timer : Watchdog timer application capability 4 channels * MSB start/LSB start switchable * Serial bus configuration capability External : 3, Internal : 5 External : 1, Internal : 1 * Ceramic/crystal oscillator for main system clock oscillation : 4.194304 MHz standard * Crystal oscillator for subsystem clock oscillation : 32.768 kHz standard STOP/HALT mode * Power-on reset, power-on flag * High withstand voltage port : Pull-down resistor or open-drain output * Port 6 : Pull-down resistor -40 to +85 C 2.7 to 6.0 V (standby data hold : 2.0 to 6.0 V) * 64-pin plastic shrink DIP (750 mil) * 64-pin plastic QFP (14 x 20 mm) PD75208 CONTENTS 1. 2. 3. PIN CONFIGURATION (TOP VIEW) ....................................................................................... 5 BLOCK DIAGRAM .................................................................................................................... 6 PIN FUNCTIONS ...................................................................................................................... 7 3.1 3.2 3.3 3.4 3.5 3.6 PORT PINS .................................................................................................................................... 7 NON-PORT PINS .......................................................................................................................... 8 PIN INPUT/OUTPUT CIRCUIT LIST ............................................................................................ 9 UNUSED PINS TREATMENT .................................................................................................... 10 P00/INT4 PIN AND RESET PIN OPERATING PRECAUTIONS ............................................... 11 XT1, XT2 AND P50 PIN OPERATING PRECAUTIONS ........................................................... 11 4. 5. ARCHITECTURE AND MEMORY MAP OF THE PD75208 ............................................... 12 PERIPHERAL HARDWARE FUNCTIONS .............................................................................. 14 5.1 5.2 5.3 5.4 5.5 5.6 5.7 5.8 5.9 PORTS .......................................................................................................................................... 14 CLOCK GENERATOR .................................................................................................................. 15 BASIC INTERVAL TIMER ........................................................................................................... 16 WATCH TIMER .......................................................................................................................... 17 TIMER/EVENT COUNTER ......................................................................................................... 18 TIMER/PULSE GENERATOR ..................................................................................................... 19 SERIAL INTERFACE ................................................................................................................... 20 FIP CONTROLLER/DRIVER ........................................................................................................ 22 POWER-ON FLAG (MASK OPTION) ......................................................................................... 23 6. 7. 8. 9. INTERRUPT FUNCTIONS ...................................................................................................... 23 STANDBY FUNCTIONS ......................................................................................................... 25 RESET FUNCTIONS ............................................................................................................... 25 INSTRUCTION SET ................................................................................................................ 26 10. MASK OPTION SELECTION .................................................................................................. 35 11. APPLICATION BLOCK DIAGRAM ......................................................................................... 36 11.1 11.2 11.3 VCR TIMER TUNER .................................................................................................................... 36 COMPACT DISK PLAYER .......................................................................................................... 37 ECR ............................................................................................................................................... 37 3 PD75208 12. ELECTRICAL SPECIFICATIONS ............................................................................................ 38 13. CHARACTERISTIC CURVES .................................................................................................. 50 14. PACKAGE INFORMATION .................................................................................................... 54 15. RECOMMENDED SOLDERING CONDITIONS ..................................................................... 57 APPENDIX A DEVELOPMENT TOOLS .................................................................................... 58 APPENDIX B RELATED DOCUMENT ....................................................................................... 59 4 PD75208 1. PIN CONFIGURATION (TOP VIEW) S3 S2 S1 S0 P00/INT4 P01/SCK P02/SO P03/SI P10/INT0 P11/INT1 P12/INT2 P13/TI0 P20 P21 P22 P23/BUZ P30 P31 P32 P33 P60 P61 P62 P63 P40 P41 P42 P43 PPO X1 X2 VSS 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 VDD S4 S5 S6 S7 S8 S9 VPRE VLOAD T15/S10 T14/S11 T13/PH0 T12/PH1 T11/PH2 T10/PH3 T9 T8 T7 T6 T5 T4 T3 T2 T1 T0 RESET P53 P52 P51 P50 XT2 XT1 P12/INT2 P11/INT1 P10/INT0 P23/BUZ P13/TI0 P41 P42 P43 PPO X1 X2 VSS XT1 XT2 P50 P51 P52 P53 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 52 32 53 54 55 56 57 58 59 60 61 62 63 64 1 2 3 4 5 6 7 8 31 30 29 28 27 26 25 24 23 22 21 20 9 10 11 12 13 14 15 16 17 18 19 P02/SO P03/SI PD75208CW-x x x P40 P63 P62 P61 P60 P33 P32 P31 P30 P22 P21 P20 P01/SCK P00/INT4 S0 S1 S2 S3 VDD S4 S5 S6 S7 S8 S9 PD75208GF-x x x-3BE RESET T0 T1 T2 T3 T4 T5 T6 T7 T8 T9 T10/PH3 T11/PH2 T12/PH1 T13/PH0 T14/S11 T15/S10 VLOAD VPRE 5 INT0/P10 INT1/P11 INT2/P12 INTERRUPT CONTROL INTW WATCH TIMER fX/2 N CLOCK DIVIDER SYSTEM CLOCK GENERATOR SUB MAIN STAND BY CONTROL CPU CLOCK INT4/P00 6 PORT0 BASIC INTERVAL TIMER INTBT TI0/P13 TIMER/EVENT COUNTER #0 INTT0 TIMER/PULSE GENERATOR PPO INTTPG SI/P03 SO/P02 SCK/P01 INTSIO 4 FIP CONTROLLER/ DRIVER SERIAL INTERFACE ROM PROGRAM MEMORY 8064 x 8 BITS PORT6 DECODE AND CONTROL RAM DATA MEMORY 497 x 4 BITS 4 P60-P63 PROGRAM COUNTER(13) ALU CY SP(8) PORT2 BANK 4 P20-P23 4 P00-P03 PORT1 4 P10-P13 PORT3 4 P30-P33 PORT4 GENERAL REG. 4 P40-P43 PORT5 4 P50-P53 10 T0-T9 T10/PH3- T13/PH0 2 10 S0-S9 VPRE VLOAD INTKS PORTH BUZ/P23 XT1 XT2 X1 X2 VDD VSS RESET 4 PH0-PH3 T14/S11,T15/ S10 2. BLOCK DIAGRAM PD75208 PD75208 3. PIN FUNCTIONS 3.1 PORT PINS Pin Name P00 P01 P02 P03 P10 P11 P12 P13 P20 P21 P22 P23 P30-P33 I/O Input Input/output Input/output Input Input DualFunction Pin INT4 SCK SO SI INT0 INT1 INT2 TI0 Function 4-bit input port (PORT0). 8-Bit I/O Input / Output After Reset Circuit Type *1 Input B F G B x Noise removing function available Noise removing function available 4-bit input port (PORT1). Input B Input/ output --- --- --- BUZ 4-bit input/output port (PORT2). x Input E Input/ output Input/ output Input/ output Input/ output --- Programmable 4-bit input/ output port (PORT3). Input/output specifiable in 1-bit units. 4-bit input/output port (PORT4). LED direct drive capability. 4-bit input/output port (PORT5). LED direct drive capability. Programmable 4-bit input/output port (PORT6). Input/output specifiable in 1-bit units. On-chip pull-down resistor available (mask option). Suitable for key input. Input E P40 to P43 --- q Input E P50 to P53 --- Input E P60 to P63 --- x Input V PH0 PH1 PH2 PH3 Output T13 T12 T11 T10 4-bit P-ch open-drain, high-dielectric, high-current output port (PORTH). LED direct drive capability. On-chip pull-down resistor available (mask option). x Low level (with an onchip pulldown resistor) or high impedance. I * Schmitt trigger inputs are circled. 7 PD75208 3.2 NON-PORT PINS DualFunction Pin --- FIP controller/ driver output pins. Pull-down resistor can be incorporated in bit units (mask option). Input / Output Circuit Type * I Pin Name T0 to T9 I/O Output Function Digit output high-voltage high-current output. Digit/segment output dual-function high-voltage high-current output. Extra pins can be used as PORTH. Digit/segment output dual-function high-voltage high-current output. Static output also possible. Segment output high voltage output. Static output also possible. Segment high-voltage output. After Reset Low level (with an onchip pulldown resistor ) or high impedance (without a pull-down resistor) T10 to T13 PH3 to PH0 T14/S11, T15/S10 --- S9 S0 to S8 PPO Output --- Timer/pulse generator pulse output. High impedance D TI0 SCK SO SI INT4 Input Input/output Input/output Input Input P13 P01 P02 P03 P00 External event pulse input for timer/event counter. Serial clock input/output. Serial data output pin or serial data input/output. Serial data input or normal input. Edge-detected vectored interrupt input (rising and falling edge detection). Edge-detected vectored interrupt input with noise eliminate function (detection edge selection possible). Edge-detected testable input (rising edge detection). Fixed frequency output (for buzzer or system clock trimming). Crystal/ceramic connect pin for main system clock oscillation. External clock input to X1 and its inverted clock input to X2. Crystal connect pin for subsystem clock oscillation. External clock input to XT1 and XT2 open. System reset input (low level active). Input Input Input Input B F G B B INT0 INT1 INT2 BUZ Input P10 P11 B Input Input/output P12 P23 B E X1, X2 Input --- XT1 XT2 RESET VPRE VLOAD VDD VSS Input --- Input --- B I I --- --- --- --- FIP controller/driver output buffer power supply. FIP controller/driver pull-down resistor connect pin. Positive power supply. GND potential. * Schmitt trigger inputs are circled. 8 PD75208 3.3 PIN INPUT/OUTPUT CIRCUIT LIST TYPE A TYPE F VDD data output disable Type D IN/OUT P-ch IN N-ch Type B CMOS-Specified Input Buffer TYPE B Input/Output Circuit Consisting of Type D Push-Pull Output and Type B Schmitt Trigger Input TYPE G VDD P-ch output disable data P-ch IN/OUT N-ch Type B IN Schmitt Trigger Input Having Hysteresis Characteristics TYPE D VDD data data P-ch OUT output disable Type D IN/OUT Input/Output Circuit Capable of Switching between Push-Pull Output and N-ch Open-Drain Output (with P-ch OFF). TYPE V output disable N-ch Type A Pull-down Resistor (Mask Option) Push-Pull Output which can be Set to Output High Impedance (with Both P-ch and N-ch Set to OFF) TYPE E TYPE I data output disable Type D VDD IN/OUT data P-ch VDD P-ch OUT N-ch Type A Pull-down Resistor (Mask Option) VLOAD VPRE Input/Output Circuit Consisting of Type D Push-Pull Output and Type A Input Buffer 9 PD75208 3.4 UNUSED PINS TREATMENT Pin P00/INT4 P01/SCK P02/SO P03/SI P10/INT0 to P12/INT2 P13/TI0 P20 to P22 P23/BUZ P30 to P33 P40 to P43 P50 to P53 P60 to P63 PPO S0 to S9 T15/S10 to T14/S11 T0 to T9 T10/PH3 to T13/PH0 XT1 XT2 RESET when there is an onchip power-on reset circuit VLOAD when there is no onchip load resistor Leave open Connect to VSS Connect to VSS Recommended Connection Connect to VSS or VDD Input state : Connect to VSS or VDD Output state : Leave open Connect to VSS or VDD Leave open Connect to VDD Connect to VSS or VDD 10 PD75208 3.5 P00/INT4 PIN AND RESET PIN OPERATING PRECAUTIONS P00/INT4 and RESET pins have the function (especially for IC test) to test UPD75208 internal operations in addition to the functions described in sections 3.1 and 3.2. The test mode is set when a voltage larger than VDD is applied to one of these pins. If noise larger than VDD is applied in normal operation, the test mode may be set thereby adversely affecting normal operation. Since there is a display output pin having a high-voltage amplitude (35 V) next to the P00/INT4 and RESET pins, if cables for the related signals are routed in parallel, wiring noise larger than VDD may be applied to the P00/INT4 and RESET pins causing errors. Thus, carry out wiring so that wiring noise can be minimized, If noise still cannot be suppressed, take the measure against noise using the following external components. * Connect diode with small VF (0.3 V or less) between the pins and VDD VDD * Connect a capacitor between the pins and VDD. VDD VDD VDD P00/INT4, RESET P00/INT4, RESET 3.6 XT1, XT2 AND P50 PIN OPERATING PRECAUTIONS When selecting the 32.768 kHz subsystem clock connected to the XT1 and XT2 pins as the watch timer source clock, the signal to be input or output to the P50 pin next to the XT2 pin must be a signal required to be switched between high and low the minimum number of times (once/second or less). If the P50 pin signal is switched frequently between high and low, a spike is generated in the XT2 pin because of capacitance coupling of the P50 and XT2 pins and the correct watch functions cannot be achieved (the watch becomes fast). If it is necessary to allow the P50 pin signal to switch between high and low, mount an external capacitor to the P50 pin as shown below. PD75208 P50 XT1 XT2 0.0068 F 32.768 kHz 11 PD75208 4. ARCHITECTURE AND MEMORY MAP OF THE PD75208 The PD75208 has three architectural features: * Bank configuration of data memory : Static RAM (448 words x 4 bits) Display data memory (49 words x 4 bits) Peripheral hardware (128 x 4 bits) * Bank configuration of general registers: 8 x 4 banks (for operation in 4-bit units) 4 x 4 banks (for operation in 8-bit units) * Memory mapped I/O Fig. 4-1 and 4-2 show the memory maps for the PD75208. Fig. 4-1 Program Memory Map Address 0000H 7 6 5 0 Internal Reset Start Address Internal Reset Start Address 0002H MBE RBE 0 INTBT/INT4 Start Address INTBT/INT4 Start Address 0004H MBE RBE 0 INT0 Start Address INT0 Start Address 0006H MBE RBE 0 INT1 Start Address INT1 Start Address 0008H MBE RBE 0 INTSIO Start Address INTSIO Start Address 000AH MBE RBE 0 INTT0 Start Address INTT0 Start Address 000CH MBE RBE 0 NTTPG Start Address INTTPG Start Address 000EH MBE RBE 0 INTKS Start Address INTKS Start Address (High-Order 5 Bits) (Low-Order 8 Bits) (High-Order 5 Bits) (Low-Order 8 Bits) (High-Order 5 Bits) (Low-Order 8 Bits) (High-Order 5 Bits) (Low-Order 8 Bits) (High-Order 5 Bits) (Low-Order 8 Bits) (High-Order 5 Bits) (Low-Order 8 Bits) (High-Order 5 Bits) (Low-Order 8 Bits) (High-Order 5 Bits) (Low-Order 8 Bits) BR ! addr Instruction Branch Address 0020H GETI Instruction Reference Table 007FH 0080H 07FFH 0800H BR $addr Instruction Relative Branch Address (-15 to -1, +2 to +16) Branch Destination Address Specified by GETI Instruction, Subroutine Entry Address BRCB ! caddr Instruction Branch Address CALL ! addr Instruction Subroutine Entry Address CALLF ! faddr Instruction Entry Address 0 MBE RBE 0FFFH 1000H BRCB ! caddr Instruction Branch Address 1F7FH Remarks In all cases other than those listed above, branch to the address with only the lower 8 bits of the PC changed is enabled by BR PCDE and BR PCXA instructions. 12 PD75208 Fig. 4-2 Data Memory Map General Register Area Stack Area 000H (32 x 4) 01FH 020H Bank 0 256 x 4 General Static RAM (497 x 4) 0FFH 100H 241 x 4 Bank 1 Display Data Memory, etc. 1BFH 1C0H (49 x 4) 1FFH Not Incorporated F80H Peripheral Hardware Area FFFH 128 x 4 Bank 15 13 PD75208 5. PERIPHERAL HARDWARE FUNCTIONS 5.1 PORTS The PD75208 has the following three types of I/O port: * 8 CMOS input ports * 20 CMOS I/O ports * 4 P-ch open-drain high-voltage, large-current output ports Total: 32 ports Table 5-1 Functions of Ports Port Name PORT0 Function 4-bit input Operation and Feature Always read or test possible irrespective of the dual-function pin operating mode. Always read or test possible, P10 and P11 are inputs with the noise eliminate function. Remarks Shares the pins with SI, SO, SCK and INT4. Shares the pins with INT0 to 2 and TI0. P23 shares the pin with BUZ. PORT1 PORT2 PORT4 PORT5 PORT3 PORT6 PORTH 4-bit input/output Can be set to the input or output mode in 4-bit units. Ports 4 and 5 can input/output data in pairs in 8-bit units. Ports 4 and 5 can directly drive LEDs. Can be set bit-wise to the input or output mode. Port 6 can incorporate a pull-down resistor as a mask option. 4-bit output P-ch open-drain high-voltage, high-current output port. Can drive an FIP and LED directly. Can incorporate a pull-down resistor bit-wise as a mask option. Shares the pins with T10 to T13. 14 PD75208 5.2 CLOCK GENERATOR Operation of the clock generator is specified by the processor clock control register (PCC) and system clock control register (SCC). The main system clock or subsystem clock can be selected. The instruction execution time is variable. * 0.95 s, 1.91 s, 15.3 s (main system clock: 4.19 MHz) * 122 s (subsystem clock: 32.768 kHz) Fig. 5-1 Clock Generator Block Diagram XT1 Subsystem Clock Generator fXT Watch Timer Timer/Pulse Generator Main System Clock Generator * FIP Controller * Basic Interval Timer (BT) * Timer/Event Counter * Serial Interface * Watch Timer * INT0 Noise Eliminator 1/8 to 1/4096 fXX Frequency Divider 1/2 1/6 SCC SCC3 Oscillation Stop Frequency Divider 1/4 XT2 X1 X2 fX Selector Selector SCC0 PCC Internal Bus PCC0 * CPU * INT0 Noise Eliminator * INT1 Noise Eliminator PCC1 4 HALT F/F HALT* STOP* PCC2 PCC3 R Q S PCC2 and PCC3 Clear STOP F/F Q S Wait Release Signal from BT RES Signal (Internal Reset) * Instruction execution R Remarks 1. 2. 3. 4. 5. 6. 7. fX = Main system clock frequency fXT = Subsystem clock frequency fXX = System clock frequency = CPU clock Standby Release Signal from Interrupt Control Circuit PCC: Processor clock control register SCC: System clock control register 1 clock cycle (tCY) of is 1 machine cycle of an instruction. For tCY, see "AC Characteristics" in 12. ELECTRICAL SPECIFICATIONS. 5 15 PD75208 5.3 BASIC INTERVAL TIMER The basic interval timer has the following functions: * Interval timer operation to generate reference time * Watchdog timer application to detect inadvertent program loop * Wait time select and count upon standby mode release * Count contents read Fig. 5-2 Basic Interval Timer Configuration From Clock Generator fXX/2 5 Clear Clear fXX/2 7 MPX fXX/2 fXX/2 9 Basic Interval Timer (8-Bit Frequency Divider) Set BT Interrupt Request Flag 12 BT IRQBT Vectored Interrupt Request Signal 3 Wait Release Signal during Standby Release BTM3 BTM2 BTM1 BTM0 BTM SET1* 4 Internal Bus 8 * Instruction execution 16 PD75208 5.4 WATCH TIMER The PD75208 incorporates one channel of watch timer. The watch timer has the following functions: * Sets the test flag (IRQW) at 0.5 sec intervals. The standby mode can be released by IRQW. * 0.5 second interval can be set with the main system clock and subsystem clock. * The fast mode enables to set 128-time (3.91 ms) interval useful to program debugging and inspection. * The fixed frequencies (2.048 kHz) can be output to the P23/BUZ pin for use to generate buzzer sound and trim the system clock oscillator frequency. * Since the frequency divider can be cleared, the watch can be started from zero second. Fig. 5-3 Watch Timer Block Diagram fW (256 Hz : 3.91 ms) 7 2 fXX 128 (32.768 kHz) fXT (32.768 kHz) Selector INTW IRQW Set Signal From Clock Generator Selector fW (32.768 kHz) fW 14 2 Frequency Divider 2Hz 0.5 sec fW 16 (2.048 kHz) Clear Output Buffer P23/BUZ WM WM7 WM6 WM5 WM4 WM3 WM2 WM1 WM0 PORT2.3 P23 Output Latch Bit 2 of PMGB Port 2 Input/Output Mode 8 Internal Bus Remarks Values at fXX = 4.194304 MHz and fXT = 32.768 kHz are indicated in parentheses. 17 PD75208 5.5 TIMER/EVENT COUNTER The PD75208 incorporates one channel of timer/event counter. The timer/event counter has the following functions: * Program interval timer operation * Event counter operation * Count state read function Fig. 5-4 Timer/Event Counter Block Diagram Internal Bus SET1 * 8 TM0 8 8 Modulo Register (8) TMOD0 TMn7 TMn6 TMn5 TMn4 TMn3 TMn2 TMn1 TMn0 8 Comparator (8) Input Buffer 8 T0 P13/TI0 From Clock Generator (Refer to Fig. 5-1) MPX Count Register (8) CP Clear Timer Operation Start Match INTT0 IRQT0 Set Signal IRQT0 Clear * Instruction execution 18 PD75208 5.6 TIMER/PULSE GENERATOR The PD75208 incorporates one channel of timer/pulse generator which can be used as a timer or a pulse generator. The timer/pulse generator has the following functions: (a) Functions available in the timer mode * 8-bit interval timer operation (IRQTPG generation) enabling the clock source to be varied at 5 levels * Square wave output to PPO pin Functions available in the PWM pulse generate mode * 14-bit accuracy PWM pulse output to the PPO pin (Used as a digital-to-analog converter and applicable to tuning) 215 * Fixed time interval ( = 7.81 ms : at 4.19 MHz operation) interrupt generation fXX (b) If pulse output is not necessary, the PPO pin can be used as a 1-bit output port. Note If the STOP mode is set while the timer/pulse generator is in operation, erroneous operation may result. To prevent that from occurring, preset the timer/pulse generator to the stop state using its mode register. Fig. 5-5 Block Diagram of Timer/Pulse Generator (Timer Mode) Internal Bus 8 MODL Modulo Register L (8) TPGM3 (Set to "1") 8 MODH Modulo Register H (8) Modulo Latch H (8) 8 Match Comparator (8) Frequency Divider fX 1/2 TPGM1 Prescalar Select Latch (5) Clear T F/F Set Selector INTTPG IRQTPG Set Signal Output Buffer PPO CP 8 Count Register (8) Clear TPGM4 TPGM5 TPGM7 19 PD75208 Fig. 5-6 Timer/Pulse Generator Block Diagram (PWM Pulse Generate Mode) Internal Bus 8 MODH Modulo Register H (8) TPGM3 8 MODL Modulo Register L (6) (2) MODH (8) Modulo Latch (14) MODL7-2 (6) Output Buffer TPGM1 fx 1/2 PWM Pulse Generator Selector PPO Frequency Divider INTTPG TPGM5 (IRQTPG Set Signal) 215 ( = 7.81 ms : at 4.19 MHz operation) fX TPGM7 5.7 SERIAL INTERFACE The serial interface has the following functions: * Clock synchronous 8-bit send/receive operation (simultaneous send/receive) * Clock synchronous 8-bit serial bus operation (data input/output from the SO pin. N-ch open-drain SO output) * Start LSB/MSB switching These functions facilitate data communication with another microcomputer of PD7500 series or 78K series via a serial bus and coupling with peripheral devices. 20 Fig 5-7 Serial Interface Block Diagram Internal Bus 8 P03/SI Selector 8 SIO0 Shift Register (8) SIO7 SIO 8 SET1 *2 SIOM SIOM7 SIOM6 SIOM5 SIOM4 SIOM3 SIOM2 SIOM1 SIOM0 *1 P02/SO SO Output Latch Serial Clock Counter (3) Overflow INTSIO IRQSIO Set Signal IRQSIO Clear Signal Clear P01/SCK R Q S Serial Start fxx/2 MPX fxx/2 4 10 * 1. CMOS output and N-ch open-drain output switchable output buffer. 2. Instruction execution PD75208 21 PD75208 5.8 FIP CONTROLLER/DRIVER The on-chip FIP controller/driver has the following functions: * Generates the segment and digit signals by automatically reading the display data memory executing DMA * * * * operation. Can select up to a total of 26 display devices in the range of 9 to 12 segments and 9 to 16 digits. Can apply the remaining display output as static output. Can adjust the brightness at 8 levels using the dimmer function. Can apply key scan operations. * Generates interrupt at the key scan timing (IRQKS) * Can generate key scan data output from the segment output pin. Owns the high-voltage output pin (40 V) which can directly drive the FIP. * Segment special pins (S0 to S9) : VOD = 40 V, IOD = 3 mA * Digit output pins (T0 to T15) : VOD = 40 V, IOD = 15 mA Can incorporate pull-down resistors bit-wise as mask options. Fig. 5-8 FIP Controller/Driver Block Diagram * * Internal Bus 4 Display Mode Register 4 Digit Select Register 4 Dimmer Select Register Key Scan Flag (KSF) Display Data Memory (48 x 4 Bits) Key Scan Registers (KS0 and KS1) 12 Port H Segment Data Latch (12) Digit Signal Generator IRQKS Generation Signal 2 10 2 4 Selector 4 2 4 10 Hige-Voltage Output Buffer 10 2 4 10 T0-T9 VLOAD VPRE S0-S9 T15/S10 and T13/PH0T14/S11 T10/PH3 Note The FIP controller/driver can only operate in the high and intermediate-speeds (PCC = 0011B or 0010B) of the main system clock (SCC.0 = 0). It may cause errors with any other clock or in the standby mode. Thus, be sure to stop FIP controller operation (DSPM.3 = 0) and then shift the unit to any other clock mode or the standby mode. 22 PD75208 5.9 POWER-ON FLAG (MASK OPTION) The power-on flag (PONF) is automatically set (1) when the power-on reset circuit is activated and the poweron reset signal is generated. (See Fig. 8-1 Reset Signal Generator) The PONF is mapped at bit 0 of address FD1H in the data memory space and can be tested by the memory bit manipulation instructions (SKT, SKF, SKTCLR) or cleared (CLR1). Note The PONF cannot be set by SET1 instruction. 6. INTERRUPT FUNCTIONS The PD75208 has eight types of interrupt sources and can generate multiple interrupts with priority order. It is also equipped with two types of test sources. INT2 is an edge detected testable input. The PD75208 interrupt control circuit has the following functions: * Hardware-controller vectored interrupt function which can control interrupt acknowledge with the interrupt enable flag (IExxx) and the interrupt master enable flag (IME). * * * * Function of setting any interrupt start address. Multiple interrupt function which can specify priority order with the interrupt priority select register (IPS). Interrupt request flag (IRQxxx) test function. (Interrupt generation can be checked by software.) Standby mode release function. (Interrupt to be released by interrupt enable flag can be selected.) 23 24 2 IM1 2 IM0 INT BT INT4 /P00 INT0 /P10 INT1 /P11 * * Both Edges Detection Circuit Edge Detection Circuit Edge Detection Circuit Fig. 6-1 Interrupt Control Circuit Block Diagram Internal Bus 4 (IME) Interrupt Enable Flag (IEXXX) Decoder IRQBT IRQ4 IRQ0 IRQ1 IRQSIO IRQT0 IRQTPG IRQKS IRQW IRQ2 Standby Release Signal Priority Control Circuit Vector Table Address Generator Circuit VRQn IPS 2 IST INTSIO INTT0 INTTPG INTKS INTW INT2 /P12 Rising Edge Detection Circuit * Noise Eliminator PD75208 PD75208 7. STANDBY FUNCTIONS Two standby modes (STOP mode and HALT mode) are available for the PD75208 to decrease power consumption in the program standby mode. Table 7-1 Operation Status in Standby Mode STOP Mode Set instruction System clock when set STOP instruction Setting enabled only with main system clock. Oscillator stops only with main system clock. Operation stopped. HALT Mode HALT instruction Setting enabled with either main system clock or subsystem clock. Stops only with CPU clock (Oscillation continued). Operation (IRQBT set at reference time intervals). Operation enabled when serial clock other than is specified. Operation enabled. Clock oscillator Basic interval timer Operating State Serial interface Operation enabled only when external SCK input is selected for serial clock. Operation enabled only when TI0 pin input is specified for count clock. Operation stopped. Timer/event counter Timer/pulse generator Watch timer Operation enabled. Operation enabled only fXT is selected for Operation enabled. count clock. Operation disabled (display off mode set before disabling). Operation stopped. Interrupt request signal (except INT0, INT1, INT2) or RESET input enabled by interrupt enable flag. FIP controller/driver CPU Release signal 8. RESET FUNCTIONS The reset signal (RES) generator has a configuration shown in Fig. 8-1. Fig. 8-1 Reset Signal Generator RESET Internal Reset Signal (RES) Mask Option Power-On Reset Generator SWB Bit Manipulation Instruction Execution SWA Power-On Flag (PONF) The power-on reset generator is a circuit to generate a one-shot pulse upon detection of the start-up of the power voltage. This pulse is used in three ways according to SWA, SWB mask option specification shown in Fig. 8-1. (See 10. MASK OPTION SELECTION.) 25 Internal Bus PD75208 9. INSTRUCTION SET (1) Operand identifier and description Enter an operand in the operand column of each instruction using the description method relating to the operand identifier of the instruction (refer to RA75X Assembler Package User's Manual, Language (EEU-730) for details). If more than one description method is available, select one. Capital alphabetic letters, plus and minus signs are keywords. Describe them as they are. In the case of immediate data, describe appropriate numerical values or labels. Identifier reg reg1 rp rp1 rp2 rp' rp'1 rpa rpa1 n4 n8 mem bit fmem pmem addr caddr faddr taddr PORTn IExxx RBn MBn X, A, B, C, D, E, H, L X, B, C, D, E, H, L XA, BC, DE, HL BC, DE, HL BC, DE XA, BC, DE, HL, XA', BC', DE', HL' BC, DE, HL, XA', BC', DE', HL' HL, HL+, HL-, DE, DL DE, DL 4-bit immediate data or label 8-bit immediate data or label 8-bit immediate data or label* 2-bit immediate data or label FB0H to FBFH and FF0H to FFFH immediate data or labels FC0H to FFFH immediate data or labels 0000H to 1F7FH immediate data or labels 12-bit immediate data or label 11-bit immediate data or label 20H to 7FH immediate data (bit0 = 0) or label PORT0 to PORT6 IEBT, IESIO, IET0, IETPG, IE0, IE1, IEKS, IEW, IE4 RB0 to RB3 MB0, MB1, MB15 Description Method * For 8-bit data processing, only even addresses can be specified. 26 PD75208 (2) Legend for operation description A B C D E H L X XA BC DE HL XA' BC' DE' HL' PC SP CY PSW MBE RBE PORTn IME IPS IExxx RBS MBS PCC * (xx) xxH : A register; 4-bit accumulator : : : : : : : : : : : : : : : : : : : : : : : : : : : : B register C register D register E register H register L register X register Register pair (XA); 8-bit accumulator Register pair (BC) Register pair (DE) Register pair (HL) Expanded register pair (XA') Expanded register pair (BC') Expanded register pair (DE') Expanded register pair (HL') Program counter Stack pointer Carry flag; Bit accumulator Program status word Memory bank enable flag Register bank enable flag Port n (n = 0 to 6) Interrupt master enable flag Interrupt priority select register Interrupt enable flag Register bank select register Memory bank select register Processor clock control register : Address and bit delimiter : Contents addressed by xx : Hexadecimal data 27 PD75208 (3) Description of symbols in the addressing area column *1 MB = MBE * MBS (MBS = 0, 1, 15) MB = 0 MBE = 0 : MB = 0 (00H to 7FH) MB = 15 (80H to FFH) MBE = 1 : MB = MBS (MBS = 0, 1, 15) MB = 15, fmem = FB0H to FBFH, FF0H to FFFH MB = 15, pmem = FC0H to FFFH addr = 0000H to 1F7FH addr = (Current PC) - 15 to (Current PC) - 1, (Current PC) + 2 to (Current PC) + 16 caddr = 0000H to 0FFFH 1000H to 1F7FH faddr = 0000H to 07FFH taddr = 0020H to 007FH (PC12 = 0) or (PC12 = 1) Program Memory Addressing *2 *3 Data Memory Addressing *4 *5 *6 *7 *8 *9 *10 Remarks 1. 2. 3. 4. MB indicates accessible memory bank. In *2, MB = 0 irrespective of MBE and MBS. In *4 and *5, MB = 15 irrespective of MBE and MBS. *6 to *10 indicate addressable areas. (4) Description of the machine cycle column S indicates the number of machine cycles required for skip operation by an instruction having skip function. The S value varies as follows: * When not skipped ................................................................................................... S = 0 * When 1-byte or 2-byte instructions are skipped ................................................. S = 1 * When 3-byte instructions are skipped (BR !addr, CALL !addr instruction) ..... S = 2 Note GETI instruction is skipped in one machine cycle. One machine cycle is equal to one cycle(=tCY) of CPU clock and three time periods are available according to PCC setting. 28 PD75208 Note 1 Mnemonic MOV Operands A, #n4 reg1, #n4 XA, #n8 HL, #n8 rp2, #n8 A, @HL A, @HL+ A, @HL- A, @rpa1 XA, @HL @HL, A @HL, XA A, mem No. of Machine Bytes Cycle 1 2 2 2 2 1 1 1 1 2 1 2 2 2 2 2 2 2 2 2 1 1 1 1 2 2 2 1 2 1 1 1 2 2 2 2 1 2+S 2+S 1 2 1 2 2 2 2 2 2 2 2 2 1 2+S 2+S 1 2 2 2 1 2 3 3 An4 reg1n4 XAn8 HLn8 rp2n8 A(HL) Operation Addressing Area Skip Condition Stack A Stack A Stack B *1 *1 *1 *2 *1 *1 *1 *3 *3 *3 *3 L=0 L = FH A(HL), then LL+1 A(HL), then LL-1 A(rpa1) XA(HL) (HL)A (HL)XA A(mem) XA(mem) (mem)A (mem)XA Areg XArp' reg1A rp'1XA A(HL) A(HL), then LL+1 A(HL), then LL-1 A(rpa1) XA(HL) A(mem) XA(mem) Areg1 XArp' XA(PC12-8+DE)ROM XA(PC12-8+XA)ROM Transfer XA, mem mem, A mem, XA A, reg XA, rp' reg1, A rp'1, XA XCH A, @HL A, @HL+ A, @HL- A, @rpa1 XA, @HL A, mem XA, mem A, reg1 XA, rp' MOVT XA, @PCDE XA, @PCXA *1 *1 *1 *2 *1 *3 *3 L=0 L = FH Note 2 Note 1. Instruction Group 2. Table reference 29 PD75208 Note Mnemonic MOV1 Operand CY, fmem.bit CY, pmem.@L CY, @H+mem.bit fmem.bit, CY pmem.@L, CY @H+mem.bit, CY No. of Machine Bytes Cycle 2 2 2 2 2 2 1 2 1 2 2 1 2 2 1 2 2 1 2 2 2 1 2 2 2 1 2 2 2 1 2 2 2 2 2 2 2 2 1+S 2+S 1+S 2+S 2+S 1 2 2 1+S 2+S 2+S 1 2 2 2 1 2 2 2 1 2 2 2 1 2 2 Operation CY(fmem.bit) CY(pmem7-2+L3-2.bit(L1-0)) CY(H+mem3-0.bit) (fmem.bit)CY (pmem7-2+L3-2.bit(L1-0))CY (H+mem3-0.bit)CY AA+n4 XAXA+n8 AA+(HL) XAXA+rp' rp'1rp'1+XA A, CYA+(HL)+CY XA, CYXA+rp'+CY rp'1, CYrp'1+XA+CY AA-(HL) XAXA-rp' rp'1rp'1-XA A, CYA-(HL)-CY XA, CYXA-rp'-CY rp'1, CYrp'1-XA-CY AA n4 AA (HL) XAXA rp' rp'1rp'1 XA AA n4 AA (HL) XAXA rp'1rp'1 AA AA n4 (HL) rp' XA rp' XA Addressing Area *4 *5 *1 *4 *5 *1 Skip Condition Bit transfer ADDS A, #n4 XA, #n8 A, @HL XA, rp' rp'1, XA carry carry *1 carry carry carry *1 ADDC A, @HL XA, rp' rp'1, XA SUBS A, @HL XA, rp' *1 borrow borrow borrow Operation rp'1, XA SUBC A, @HL XA, rp' rp'1, XA AND A, #n4 A, @HL XA, rp' rp'1, XA OR A, #n4 A, @HL XA, rp' rp'1, XA XOR A, #n4 A, @HL XA, rp' rp'1, XA *1 *1 *1 *1 XAXA rp'1rp'1 Note Instruction Group 30 PD75208 Note 1 Mnemonic Note 2 RORC NOT INCS A A reg rp1 Operands No. of Machine Bytes Cycle 1 2 1 1 2 2 1 2 2 2 1 2 2 2 1 1 1 1 1 2 1+S 1+S 2+S 2+S 1+S 2+S 2+S 2+S 1+S 2+S 2+S 2+S 1 1 1+S 1 Operation CYA0, A3CY, An-1An AA regreg+1 rp1rp1+1 (HL)(HL)+1 (mem)(mem)+1 regreg-1 rp'rp'-1 Skip if reg = n4 Skip if (HL) = n4 Skip if A = (HL) Skip if XA = (HL) Skip if A = reg Skip if XA = rp' CY1 CY0 Skip if CY = 1 CYCY Addressing Area Skip Condition Increment/decrement reg = 0 rp1 = 00H *1 *3 (HL) = 0 (mem) = 0 reg = FH rp = FFH reg = n4 *1 *1 *1 (HL) = n4 A = (HL) XA = (HL) A = reg XA = rp' @HL mem DECS reg rp' SKE reg, #n4 @HL, #n4 Compare A, @HL XA, @HL A, reg XA, rp' Carry flag manipulation SET1 CLR1 SKT NOT1 CY CY CY CY CY = 1 Note 1. Instruction Group 2. Accumulator manipulation 31 PD75208 Note Mnemonic SET1 Operands mem.bit fmem.bit pmem.@L @H + mem.bit No. of Machine Bytes Cycle 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 -- 2 2 2 2 2 2 2 2 2+S 2+S 2+S 2+S 2+S 2+S 2+S 2+S 2+S 2+S 2+S 2 2 2 2 2 2 2 2 2 -- Operation (mem.bit)1 (fmem.bit)1 (pmem7-2+L3-2.bit(L1-0))1 (H+mem3-0.bit)1 (mem.bit)0 (fmem.bit)0 (pmem7-2+L3-2.bit(L1-0))0 (H+mem3-0.bit)0 Skip if (mem.bit) = 1 Skip if (fmem.bit) = 1 Skip if (pmem7-2+L3-2.bit(L1-0)) = 1 Skip if (H+mem3-0.bit) = 1 Skip if (mem.bit) = 0 Skip if (fmem.bit) = 0 Skip if (pmem7-2+L3-2.bit(L1-0)) = 0 Skip if (H+mem3-0.bit) = 0 Skip if (fmem.bit) = 1 and clear Skip if (pmem7-2+L3-2.bit(L1-0))=1 and clear Skip if (H+mem3-0.bit)=1 and clear CYCY (fmem.bit) CYCY (pmem7-2+L3-2.bit(L1-0)) CYCY (H+mem3-0.bit) CYCY (fmem.bit) CYCY (pmem7-2+L3-2.bit(L1-0)) CYCY (H+mem3-0.bit) CYCY CYCY CYCY (fmem.bit) (pmem7-2+L3-2.bit(L1-0)) (H+mem3-0.bit) Addressing Area *3 *4 *5 *1 *3 *4 *5 *1 *3 *4 *5 *1 *3 *4 *5 *1 *4 *5 *1 *4 *5 *1 *4 *5 *1 *4 *5 *1 *6 Skip Condition CLR1 mem.bit fmem.bit pmem.@L @H+mem.bit SKT mem.bit fmem.bit pmem.@L (mem.bit) = 1 (fmem.bit) = 1 (pmem.@L) = 1 (@H+mem.bit) = 1 (mem.bit) = 0 (fmem.bit) = 0 (pmem.@L) = 0 (@H+mem.bit) = 0 (fmem.bit) = 1 (pmem.@L) = 1 (@H+mem.bit)=1 Memory bit manipulation @H+mem.bit SKF mem.bit fmem.bit pmem.@L @H+mem.bit SKTCLR fmem.bit pmem.@L @H+mem.bit AND1 CY, fmem.bit CY, pmem.@L CY, @H+mem.bit OR1 CY, fmem.bit CY, pmem.@L CY, @H+mem.bit XOR1 CY, fmem.bit CY, pmem.@L CY, @H+mem.bit BR addr PC12-0addr (Optimum instruction is selected from among BR !addr, BRCB !caddr and BR $addr by an assembler.) Branch !addr $addr BRCB BR !caddr PCDE PCXA 3 1 2 2 2 3 2 2 3 3 PC12-0addr PC12-0addr PC12-0PC12+caddr11-0 PC12-0PC12-8+DE PC12-0PC12-8+XA *6 *7 *8 Note Instruction Group 32 PD75208 Note Mnemonic CALL Operands !addr No. of Machine Bytes Cycle 3 3 Operation (SP-4) (SP-1) (SP-2)PC11-0 (SP-3) MBE, RBE, 0, PC12 PC12-0addr, SPSP-4 (SP-4) (SP-1) (SP-2)PC11-0 (SP-3) MBE, RBE, 0, PC12 PC12-000, faddr, SPSP-4 MBE, RBE, 0, PC12(SP+1) PC11-0(SP) (SP+3) (SP+2) SPSP+4 Addressing Area *6 Skip Condition CALLF !faddr 2 2 *9 RET 1 3 Subroutine stack control RETS 1 3+S MBE, RBE, 0, PC12(SP+1) PC11-0(SP) (SP+3) (SP+2) SPSP+4 then skip unconditionally x, x, x, PC12(SP+1) PC11-0(SP) (SP+3) (SP+2) PSW(SP+4) (SP+5), SPSP+6 (SP-1) (SP-2)rp, SPSP-2 (SP-1)MBS, (SP-2)RBS, SPSP-2 rp(SP+1) (SP), SPSP+2 MBS(SP+1), RBS(SP), SPSP+2 IME(IPS.3)1 IExxx1 IME(IPS.3)0 IExxx0 APORTn XAPORTn+1, PORTn PORTnA PORTn+1, PORTnXA Set HALT Mode (PCC.21) Set STOP Mode (PCC.31) No Operation RBSn (n = 0 to 3) (n = 0 to 6) (n = 4) (n = 2 to 6) (n = 4) Unconditional RETI 1 3 PUSH rp BS 1 2 1 2 2 1 2 1 2 2 2 2 2 2 2 2 2 2 2 1 2 2 POP rp BS EI Interrupt control IExxx DI IExxx Input/output IN * A, PORTn XA, PORTn OUT * PORTn, A PORTn, XA HALT STOP NOP SEL RBn MBn 2 2 2 2 2 2 2 2 2 1 2 2 Special CPU control MBSn (n = 0, 1, 15) * MBE = 0 or MBE = 1 and MBS = 15 must be set for execution of IN/OUT instruction Instruction Group Note 33 PD75208 Note Mnemonic GETI * Operands taddr No. of Machine Bytes Cycle 1 3 Operation * TBR instruction PC12-0(taddr)4-0+(taddr+1) ---------------------------------------------------* TCALL instruction (SP-4)(SP-1)(SP-2)PC11-0 (SP-3) MBE, RBE, 0, PC12 PC12-0(taddr)4-0+(taddr+1) SPSP-4 ---------------------------------------------------* (taddr) (taddr+1) instruction executed in the case of instruction other than TBR and TCALL instructions Addressing Area *10 Skip Condition ------------------------ Special -----------------------Depends on instructions referred to. * TBR and TCALL instructions are assembled pseudo-instructions to define the GETI instruction table. Instruction Group Note 34 PD75208 10. MASK OPTION SELECTION The PD75208 has the following mask options enabling or disabling on-chip components. (1) Pin Pin P60 to P63 T0/T9 T10/PH3 to T13/PH0 T14/S11, T15/S10 S0 to S9 XT1, XT2 Deletion of subsystem clock oscillator feedback resistor possible Mask Option Pull-up resistor incorporation enabled bit-wise Note 1. In a system not using subsystem clocks, power consumption in the STOP mode can be decreased by removing the feedback resistor from the oscillator. 2. The feedback resistor must be incorporated when the subsystem clock is used. Power-on reset generator, power-on flag (PONF) One of the following three can be selected. (2) Switch Selection (See Fig. 8-1) SWA ON ON OFF SWB ON OFF OFF Power-On Reset Generator Power-On Flag (PONF) Internal Reset Signal (RES) Incorporated Incorporated Not incorporated Incorporated Incorporated Not incorporated Generate automatically Not generate automatically ----- 35 PD75208 11. APPLICATION BLOCK DIAGRAM 11.1 VCR TIMER TUNER Main Power Supply + Super Capacitor Power Failure Detection VDD INT4 VSS T0-T15 16 Electronic Tuner LPF PPO PD75208 INT1 SCK SO S0-S11 12 Fluorescent Display Panel (FIP) 12 Segments x 16 Digits Tape Count Pulse Tape Up/Down SCK System Controller SO Microcomputer SI Timer Tuner Remote Controlled Reception Tape Counter PORT6 Key Matrix (12 x 4) PD75104/75106 EEPROMTM PD6252 X1 X2 XT1 INT0 Remote Controlled Signal PC2800A BUZ XT2 BZ Piezoelectric Buzzer 36 PD75208 11.2 COMPACT DISK PLAYER Servo Control IC SIO SCK SI/SO T0-T15 16 S0-S11 12 Fluorescent Display Panel (FIP) 12 Segments x 16 Digits Loading Circuit PD75208 Key Matrix (12 x 4) PORT6 BUZ BZ INT0 Remote Controlled Signal PC2800A X1 X2 11.3 ECR Main Power Supply + Power Failure Detection VDD INT4 VSS T0-T15 16 S0-S9 10 RAM Fluorescent Display Panel (FIP) 10 Segments x 16 Digits PD75208 Key Matrix (10 x 4) Printer PPO BZ X1 X2 XT1 XT2 Piezoelectric Buzzer 37 PD75208 12. ELECTRICAL SPECIFICATIONS ABSOLUTE MAXIMUM RATINGS (Ta = 25 C) PARAMETER SYMBOL VDD Power supply voltage VLOAD VPRE Input voltage Output voltage VOD Display output pins 1 pins except display output pins S0 to S9 Output current high IOH T0 to T15 1 pin 1 pin VDD -40 to VDD +0.3 -15 -15 -30 -20 -120 17 60 450 600 -40 to +85 -65 to +150 V mA mA mA mA mA mA mA mW mW C C VI VO Pins except display output pins TEST CONDITIONS RATING -0.3 to +7.0 VDD -40 to VDD +0.3 VDD -12 to VDD +0.3 -0.3 to VDD +0.3 -0.3 to VDD +0.3 UNIT V V V V V Total of pins except display output pins Total of display output pins Output current low IOL 1 pin Total of pins Total loss*1 Operating temperature Storage temperature PT Topt Tstg Plastic QFP Plastic shrink DIP POWER SUPPLY VOLTAGE RANGE (Ta = -40 to +85 C) PARAMETER CPU *2 Display controller Time/pulse generator Other hardware *2 TEST CONDITIONS MIN. *3 4.5 4.5 2.7 MAX. 6.0 6.0 6.0 6.0 UNIT V V V V 38 PD75208 * 1. Calculation of total loss Design so that the sum of the following three power consumption values for the PD75208CW/GF will be less than the total loss PT (It is recommended to use the system with 80 % or less of the rating). CPU loss : Given as VDD (MAX.) x IDD1 (MAX.) Output pin loss : There are normal output pin loss and display output pin loss. It is necessary to add a loss derived from the flow of maximum current to each output pin. Pull-down register loss : Power loss due to a pull-down resistor incorporated in the display output pin by mask option. Example Suppose 4-LED output with 9SEG x 11DIGIT, VDD = 5 V + 10 % and 4.19 MHz oscillation and let a maximum of 3 mA, 15 mA and 10 mA flow to the segment pin, timing pin and LED output pin, respectively. Further, let the voltage of fluorescent display tube (VLOAD voltage) be -30 V and normal voltage be small. CPU loss : 5.5 V x 9.0 mA = 49.5 mW Pin loss : Segment pin ..... 2 V x 3 mA x 9 = 54 mW Timing pin ......... 2 V x 15 mA = 30 mW LED output ........ 10 x2V 15 x 10 mA x 4 = 53 mW Pull-down resistor loss ........ (30 + 5.5 V)2 x 10 = 315 mW 40 k PT = + + = 501.5 mW In this example, the power consumption of 501.5 mW is less than the allowable total loss for the shrink DIP package (600 mW). However, since the allowable total loss is 450 mW for the QFP package, it is necessary to decrease power consumption by decreasing the number of on-chip pull-down resistors. In this example, power consumption can be adjusted to 344 mW by incorporating pull-down resistors in only 11 digit outputs and 4 segment outputs and externally mounting pull-down resistors to the 5 remaining segment outputs. 2. Except the system clock oscillator, display controller and timer/pulse generator. 3. The operating voltage range varies depending on the cycle time. Refer to the section describing AC characteristics. 39 PD75208 MAIN SYSTEM CLOCK OSCILLATOR CHARACTERISTICS (Ta = -40 to +85 C, VDD = 2.7 to 6.0 V) RESONATOR RECOMMENDED CIRCUIT PARAMETER Oscillator frequency (fXX) *2 TEST CONDITIONS VDD = Oscillation voltage range After VDD reaches the minimum value in the oscillation voltage range 2.0 VDD = 4.5 to 6.0 V 4.19 MIN. 2.0 TYP. MAX. 5.0*4 UNIT MHz Ceramic resonator*1 X1 C1 X2 C2 Oscillation stabilization time *3 4 ms X1 Crystal resonator*1 X2 C2 Oscillator frequency (fXX) *2 5.0 *4 10 30 MHz ms ms C1 Oscillation stabilization time *3 X1 External clock X2 X1 input frequency (fX) *2 2.0 5.0*4 MHz PD74HCU04 X1 input high and low level widths (tXH, tXL) 100 250 ns * 1. Resonators are shown in the following page. 2. Oscillator characteristics only. Refer to the description of AC characteristics for details of instruction execution time. 3. Time required for oscillation to become stabilized after VDD application or STOP mode release. 4. When oscillator frequency is " 4.19 < fX 5.0 MHz ", do not select " PCC = 0011 " as instruction execution time. If " PCC = 0011 " is selected, 1 machine cycle becomes less than 0.95 s, with the result that the specified MIN. value of 0.95 s cannot be observed. 5 SUBSYSTEM CLOCK OSCILLATOR CHARACTERISTICS (Ta = -40 to +85 C, VDD = 2.7 to 6.0 V) RESONATOR RECOMMENDED CIRCUIT PARAMETER Oscillator frequency (fXT) *2 VDD = 4.5 to 6.0 V Oscillation stabilization time *3 10 s TEST CONDITIONS MIN. 32 TYP. 32.768 MAX. 35 UNIT kHz XT1 Crystal resonator*1 XT2 330 k 1.0 2 s C3 C4 XT1 External clock XT2 Leave Open XT1 input frequency (fXT) 32 100 kHz XT1 input high and low level widths (tXTH, tXTL) 10 32 s * 1. Recommended resonators are shown in the following page. 2. Oscillator characteristics only. Refer to the description of AC characteristics for instruction execution time. 3. Oscillation stabilization time is a time required for oscillation to become stabilized after VDD application or STOP mode release. 40 PD75208 CAPACITANCE (Ta = 25 C, VDD = 0 V) PARAMETER Input capacitance Except display output Output capacitance Display output Input /output capacitance CIO COUT SYMBOL CIN f = 1 MHz Unmeasured pin returned to 0V TEST CONDITIONS MIN. TYP. MAX. 15 15 35 15 UNIT pF pF pF pF RECOMMENDED OSCILLATOR CONSTANTS MAIN SYSTEM CLOCK : CERAMIC RESONATOR (Ta = -40 to +85 C) EXTERNAL CAPACITANCE (pF) C1 Murata Mfg. Co., Ltd. Kyocera Corp. CSA 4.19MG KBR-2.09MS KBR-3.58MS KBR-4.19MS KBR-4.9M 33 33 30 68 C2 30 68 4.0 6.0 OSCILLATION VOLTAGE RANGE (V) MIN. 4.0 MAX. 6.0 MANUFACTURER PRODUCT NAME MAIN SYSTEM CLOCK : CRYSTAL RESONATOR (Ta = -40 to +85 C) EXTERNAL CAPACITANCE (pF) C1 HC-49/U 15 C2 15 OSCILLATION VOLTAGE RANGE (V) MIN. 2.7 MAX. 6.0 MANUFACTURER Kinseki FREQUENCY (MHz) 4.19 HOLDER Note Carry out fine adjustment of crystal resonator frequency with external capacitance C1 of 10 to 33 pF. 41 PD75208 DC CHARACTERISTICS (Ta = -40 to +85 C, VDD = 2.7 to 6.0 V) PARAMETER SYMBOL VIH1 VIH2 Input voltage high VIH3 VIH4 VIL1 Input Voltage low VIL2 VIL3 Output voltage high VOH Except below Ports 0, 1, RESET X1, X2, XT1 VDD = 4.5 to 6.0 V Port 6 0.7VDD Except below Ports 0, 1, 6, RESET X1, X2, XT1 VDD = 4.5 to 6.0V, IOH = -1 mA All output pins Ports 4, 5 Output voltage low VOL All output pins ILIH1 ILIH2 ILIL1 ILIL2 ILOH ILOL1 ILOL2 Except X1,X2,XT1 VIN = VDD X1, X2, XT1 Except X1,X2,XT1 VIN = 0 V X1, X2, XT1 All output pins VOUT = VDD Except display output VOUT = 0 V Display output S0 to S9 Display output current IOD T0 to T15 VOUT = VLOAD = VDD - 35 V VPRE = VDD - 9 1 V*1 VDD = 4.5 to 6.0 V VPRE = 0 V VOD = VPRE = VDD - 9 1 V*1 VDD - 2 V VPRE = 0 V VDD = 4.5 to 6.0 V -3 -1.5 -15 -7 30 30 VOD - VLOAD = 35 V VDD = 5 V 10 %*3 VDD = 3 V 10 %*4 VDD = 5 V 10 % HALT mode VDD = 3 V 10 % 40 70 3.0 0.55 600 200 40 5 0.5 0.1 -5.5 -3.5 -22 -15 80 200 1000 120 9.0 1.5 1800 600 120 15 20 10 20 -3 -20 3 -3 -10 IOH = -100 A VDD = 4.5 to 6.0V, IOL = 15 mA VDD = 4.5 to 6.0V, IOL = 1.6 mA IOL = 400 A 0 0 0 VDD-1.0 VDD-0.5 0.4 2.0 0.4 0.5 3 TEST CONDITIONS MIN. 0.7VDD 0.75VDD VDD-0.4 0.65VDD TYP. MAX. VDD VDD VDD VDD VDD 0.3VDD 0.2VDD 0.4 UNIT V V V V V V V V V V V V V Input leakage current high Input leakage current low Output leakage current high Output leakage current low A A A A A A A mA mA mA mA k k k mA mA Built-in pull-down resistor (mask option) RP6 RL IDD1 Port 6 VIN = VDD Display output 4.19 MHz crystal oscillation C1 = C2 = 15pF IDD2 Supply current*2 IDD3 IDD4 IDD5 A A A A A A VDD = 3 V 10 % 32 kHz crystal oscillation*5 HALT mode VDD = 3 V 10 % XT1 = 0 V STOP mode VDD = 5 V 10 % VDD = 3 V 10 % 42 PD75208 * 1. The following external circuit is recommended. PD75208 +5 V VDD RD9. 1EL VPRE 68 k VLOAD -30 V VSS RD9. 1EL : Zener Diode (NEC) Zener Voltage = 8.29 to 9.30 V 2. Current to the on-chip pull-down resistor and power-on reset circuit (mask option) is not included. 3. When the processor clock control register (PCC) is set to 0011 and is operated in the high-speed mode. 4. When the PCC register is set to 0000 and is operated in the low-speed mode. 5. When the system clock control register (SCC) is set to 1001 and is operated with the subsystem clock with main system clock oscillation stopped. POWER-ON RESET CIRCUIT CHARACTERISTICS (MASK OPTION) (Ta = -40 to +85 C) PARAMETER Power-on reset operating voltage high Power-on reset operating voltage low Power supply voltage rise time Power supply voltage off time Power-on reset circuit*2 current consumption SYMBOL VDDH TEST CONDITIONS MIN. 4.5 TYP. MAX. 6.0 UNIT V VDDL 0 0.2 V tr 10 *1 s toff VDD = 5 V 10 % VDD = 2.7 V 1 10 2 100 20 s IDDPR A A * 1. 2 17/fXX (31.3 ms at fXX = 4.19 MHz) 2. Current with on-chip power-on reset circuit or power-on flag. VDD VDDH VDDL toff tr Remarks Start the power supply smoothly. 43 PD75208 AC CHARACTERISTICS (Ta = -40 to +85 C , VDD = 2.7 to 6.0 V) PARAMETER SYMBOL TEST CONDITIONS Operation with main system clock VDD = 4.5 to 6.0 V MIN. 0.95 3.8 114 0 0 TYP. MAX. 32 32 UNIT s s s MHz kHz CPU clock cycle time (minimum instruction execution time = 1 machine cycle) *1 tCY Operation with subsystem clock VDD = 4.5 to 6.0 V 122 125 0.6 165 TI0 input frequency fTI tTIH, tTIL Input VDD = 4.5 to 6.0 V VDD = 4.5 to 6.0 V TI0 input high and lowlevel widths 0.83 3 0.8 0.95 3.2 3.8 0.4 tKCY/2-50 1.6 tKCY/2-150 100 400 s s s s s s s ns SCK cycle time tKCY Output Input Output Input VDD = 4.5 to 6.0 V Output Input Output SCK high and low-level widths tKH, tKL s ns ns ns 300 1000 ns ns SI setup time (to SCK) SI hold time (from SCK) SO output delay time from SCK tSIK tKSI VDD = 4.5 to 6.0 V tKSO INT0 Interrupt input high and low-level widths tINTH, INT1 tINTL INT2, 4 RESET low-level width tRSL *2 2tCY 10 10 s s s s 44 PD75208 * 1. CPU clock () cycle time is determined by the oscillator frequency of the connected resonator, the system clock control register (SCC) and the processor clock control register (PCC). The cycle time tCY characteristics for power supply voltage VDD when the main system clock is in operation is shown below. 2. 2tCY or 128/fXX is set by interrupt mode register (IM0) setting. Cycle Time tCY [ s] tCY VS VDD (Main System Clock in Operation) 40 32 30 6 5 4 3 Operation Guaranteed Range 2 1 0.5 0 1 2 3 4 5 6 Power Supply Voltage VDD [V] 45 PD75208 AC Timing Measurement Values (Except X1 and XT1 Inputs) 0.75VDD 0.2VDD Test Points 0.75VDD 0.2VDD Clock Timing 1/fX tXL tXH X1 Input V DD - 0.4 V 0.4 V 1/fXT tXTL tXTH XT1 Input VDD - 0.4 V 0.4 V TI0 Timing 1/fTI tTIL tTIH TI0 46 PD75208 Serial Transfer Timing tKCY tKL tKH SCK tSIK tKSI SI Input Data tKSO SO Output Data Interrupt Input Timing tINTL tINTH INT0,1,2,4 RESET Input Timing tRSL RESET 47 PD75208 DATA MEMORY STOP MODE LOW POWER SUPPLY VOLTAGE DATA RETENTION CHARACTERISTICS (Ta = -40 to +85 C) PARAMETER Data retention power supply voltage Data retention power supply current *1 Release signal set time Oscillation stabilization wait time *2 SYMBOL VDDDR TEST CONDITIONS MIN. 2.0 TYP. MAX. 6.0 UNIT V IDDDR tSREL tWAIT VDDDR = 2.0V 0 Release by RESET Release by interrupt request 0.1 10 A s 217/fX *3 ms ms * 1. Current to the on-chip pull-down resistor and power-on reset circuit (mask option) is not included. 2. Oscillation stabilization wait time is time to stop CPU operation to prevent unstable operation upon oscillation start. 3. According to the setting of the basic interval timer mode register (BTM) (see below). BTM3 -- -- -- -- BTM2 0 0 1 1 BTM1 0 1 0 1 BTM0 0 1 1 1 Wait Time (Values at fXX = 4.19 MHz in parentheses) 220/fX (approx. 250 ms) 217/fX (approx. 31.3 ms) 215/fX (approx. 7.82 ms) 213/fX (approx. 1.95 ms) Data Retention Timing (STOP Mode Release by RESET) Internal Reset Operation HALT Mode Operating Mode STOP Mode Data Retention Mode VDD VDDDR STOP Instruction Execution RESET tWAIT tSREL 48 PD75208 Data Retention Timing (Standby Release Signal: STOP Mode Release by Interrupt Signal) HALT Mode Operating Mode STOP Mode Data Retention Mode VDD VDDDR STOP Instruction Execution Standby Release Signal (Interrupt Request) tWAIT tSREL 49 PD75208 13. CHARACTERISTIC CURVES IDD vs VDD (Ta = 25 C) 5000 High-Speed Mode (0011) Medium-Speed Mode (0010) Low-Speed Mode (0000) 1000 HALT Mode (0100) 500 Supply Current IDD [ A] Subsystem Clock Operating Mode 100 50 Subsystem Clock HALT Mode STOP Mode (1000) 10 Power-on reset circuit and power-on flag incorporated 5 X1 X2 XT1 XT2 330 k 32.768 kHz 4.19 MHz 15 pF 15 pF 22 pF 33 pF 1 0 1 2 3 4 5 6 Supply Voltage VDD [V] Remarks Values of the processor clock control register (PCC) is indicated in parenthesis. 50 PD75208 IOL vs VOL (Ports 0, 2, 3, 6) 20 (Ta = 25 C) VDD = 5 V VDD = 6 V 15 VDD = 4 V Output Current Low IOL [mA] VDD = 3 V 10 VDD = 2.7 V 5 0 0 1 2 3 4 5 Output Voltage Low VOL [V] IOH vs (VDD - VOH) (Ports 0, 2, 3, 6) -20 (Ta = 25 C) VDD = 5 V -15 VDD = 6 V VDD = 4 V Output Current High IOH [mA] -10 VDD = 3 V -5 VDD = 2.7 V 0 0 1 2 VDD - VOH [V] 3 4 5 51 PD75208 IOL vs VOL (Ports 4, 5) 20 (Ta = 25 C) VDD = 5 V 6V 15 4V VDD = 3 V Output Current Low IOL [mA] VDD = 2.7 V 10 5 0 0 1 2 3 4 5 Output Voltage Low VOL [V] IOH vs (VDD - VOH) (Ports 4, 5) -20 (Ta = 25 C) VDD = 6 V -15 Output Current High IOH (mA) VDD = 5 V VDD = 4 V -10 VDD = 3 V -5 VDD = 2.7 V 0 0 1 2 VDD - VOH [V] 3 4 5 52 PD75208 IOD vs (VDD - VOD) (T0 to T15) -40.0 (Ta = 25 C) VDD - VPRE = 8 V -30.0 VDD - VPRE = 10 V VDD - VPRE = 6 V Display Output Current IOD [mA] -20.0 VDD - VPRE = 4 V -10.0 0 0 1 2 VDD - VOD [V] 3 4 5 IOD vs (VDD - VOD) (S0 to S9) -10.0 VDD - VPRE = 10 V (Ta = 25 C) VDD - VPRE = 8 V Display Output Current IOD [mA] VDD - VPRE = 6 V -5.0 VDD - VPRE = 4 V 0 0 1 2 VDD - VOD [V] 3 4 5 53 PD75208 14. PACKAGE INFORMATION 64 PIN PLASTIC SHRINK DIP (750 mil) 64 33 1 A 32 K L J I F D G H N M C B M R NOTE 1) Each lead centerline is located within 0.17 mm (0.007 inch) of its true position (T.P.) at maximum material condition. 2) Item "K" to center of leads when formed parallel. ITEM MILLIMETERS A B C D F G H I J K L M N R 58.68 MAX. 1.78 MAX. 1.778 (T.P.) 0.500.10 0.9 MIN. 3.20.3 0.51 MIN. 4.31 MAX. 5.08 MAX. 19.05 (T.P.) 17.0 0.25 +0.10 -0.05 0.17 0~15 INCHES 2.311 MAX. 0.070 MAX. 0.070 (T.P.) 0.020 +0.004 -0.005 0.035 MIN. 0.1260.012 0.020 MIN. 0.170 MAX. 0.200 MAX. 0.750 (T.P.) 0.669 0.010 +0.004 -0.003 0.007 0~15 P64C-70-750A,C-1 54 PD75208 64 PIN PLASTIC QFP (14x20) A B 51 52 33 32 detail of lead end C D S Q R 64 1 20 19 F G H I M J K P N L M NOTE Each lead centerline is located within 0.20 mm (0.008 inch) of its true position (T.P.) at maximum material condition. ITEM A B C D F G H I J K L M N P Q R S MILLIMETERS 23.60.4 20.00.2 14.00.2 17.60.4 1.0 1.0 0.400.10 0.20 1.0 (T.P.) 1.80.2 0.80.2 0.15 +0.10 -0.05 INCHES 0.9290.016 0.795 +0.008 -0.009 0.551+0.009 -0.008 0.6930.016 0.039 0.039 0.016 +0.004 -0.005 0.008 0.039 (T.P) 0.071 +0.008 -0.009 0.031 +0.009 -0.008 0.006 +0.004 -0.003 0.10 0.004 2.7 0.106 0.10.1 0.0040.004 55 55 3.0 MAX. 0.119 MAX. P64GF-100-3B8,3BE,3BR-2 55 PD75208 64-pin ceramic QFP for ES (reference) (unit : mm) 14.2 12.0 1 64 52 51 18.0 19 20 33 32 1.0 0.4 2.25 20 0.15 Note 1. Care is needed since the metal cap is connected to pin 26 and set to the positive power supply level. 2. Care is needed since the lead of the base is formed obliquely. 3. The lead length is not stipulated since the cutting of the lead ends is not progresscontrolled. Bottom View 56 PD75208 5 15. RECOMMENDED SOLDERING CONDITIONS This product should be soldered and mounted under the conditions recommended below. For details of recommended soldering conditions for the surface mounting type, refer to the document "Semiconductor Device Mount Technology" (IEI-1207). For soldering methods and conditions other than those recommended below, contact our salesman. Table 15-1 Surface Mounting Type Conditions PD75208GF-xxx-3BE : 64-pin plastic QFP (body 14 x 20 mm) Soldering Method Wave soldering Soldiering Conditions Solder bath temperature: 260 C or less, Duration: 10 sec. max. Number of times: Once, Time limit: 7 days* (thereafter 10 hours prebaking required at 125 C) Preheating temperature : 120 C max. (package surface temperature) Package peak temperature: 230 C, Duration: 30 sec. max. (at 210 C or above), Number of times: Once, Time limit: 7 days*(thereafter 10 hours prebaking required at 125 C) Package peak temperature: 215 C, Duration: 40 sec. max. (at 200 C or above), Number of times: Once, Time limit: 7 days* (thereafter 10 hours prebaking required at 125 C) Pin part temperature: 300 C or below , Duration: 3 sec. max. (per device side) Recommended Condition Symbol WS60-107-1 Infrared reflow IR30-107-1 VPS VP15-107-1 Pin part heating --- * For the storage period after dry-pack decompression storage conditions are max. 25 C, 65 % RH. Note Use of more than one soldering method should be avoided (except in the case of pin part heating). Table 15-2 Insertion Type Soldering Conditions PD75208CW-xxx : 64-pin plastic shrink DIP (750 mil) Soldering Method Wave soldering (lead part only) Pin part heating Soldering Conditions Solder bath temperature: 260 C or below , Duration: 10 sec. max. Pin part temperature: 260 C or below , Duration: 10 sec. max. Note Ensure that the application of wave soldering is limited to the lead part and no solder touches the main unit directly. 57 PD75208 5 APPENDIX A DEVELOPMENT TOOLS The following development tools are provided for developing systems including the PD75208: IE-75000-R *1 IE-75001-R IE-75000-R-EM *2 EP-75216ACW-R Hardware EP-75216AGF-R EV-9200G-64 PG-1500 PA-75P216ACW In-circuit emulator for the 75X series Emulation board for the IE-75000-R and IE-75001-R Emulation probe for the PD75216ACW Emulation probe for the PD75216AGF. A 64-pin conversion socket, the EV-9200G-64, is attached to the probe. PROM programmer PROM programmer adapter for the PD75P216ACW and PD75P218CW. Connected to the PG-1500. PROM programmer adapter for the PD75P218GF. Connected to the PG-1500. PROM programmer adapter for the PD75P218KB. Connected to the PG-1500. Host machine * PC-9800 series (MS-DOSTM Ver. 3.30 to Ver. 5.00A *3) * IBM PC series (PC DOSTM Ver. 3.1) PA-75P218GF PA-75P218KB IE control program Software PG-1500 controller RA75X relocatable assembler * 1. Maintenance service only 2. Not contained in the IE-75001-R 3. These software cannot use the task swap function, which is available in MS-DOS Ver. 5.00 and Ver. 5.00A. 58 PD75208 APPENDIX B RELATED DOCUMENTS Documents related to the device 5 Document Name User's manual Application note 75X series selection guide Document No. IEU-1294 IEM-1294 IF-1027 Documents related to development tools Document Name IE-75000-R User's Manual Hardware IE-75001-R User's Manual IE-75000-R-EM User's Manual EP-75216ACW-R User's Manual EP-75216AGF-R User's Manual PG-1500 User's Manual RA75X Assembler Package User's Manual Operation PC-9800 series (MS-DOS) base IBM PC series (PC DOS) base Document No. EEU-1297 EEU-1416 EEU-1294 EEU-1321 EEU-1309 EEU-1335 EEU-1346 Software Language PG-1500 Controller User's Manual EEU-1363 EEU-1291 Other documents Document Name PACKAGE MANUAL SMD SURFACE MOUNT TECHNOLOGY MANUAL QUALITY GRADES ON NEC SEMICONDUCTOR DEVICES NEC SEMICONDUCTOR DEVICE RELIABILITY/QUALITY CONTROL SYSTEM ELECTROSTATIC DISCHARGE (ESD) TEST GUIDE TO QUALITY ASSURANCE FOR SEMICONDUCTOR DEVICES Document No. IEI-1213 IEI-1207 IEI-1209 IEI-1203 IEI-1201 MEI-1202 Note The above documents may be revised without notice. Use the latest versions when you design an application system. 59 PD75208 Cautions on CMOS Devices 1 Countermeasures against static electricity for all MOSs Caution When handling MOS devices, take care so that they are not electrostatically charged. Strong static electricity may cause dielectric breakdown in gates. When transporting or storing MOS devices, use conductive trays, magazine cases, shock absorbers, or metal cases that NEC uses for packaging and shipping. Be sure to ground MOS devices during assembling. Do not allow MOS devices to stand on plastic plates or do not touch pins. Also handle boards on which MOS devices are mounted in the same way. 2 CMOS-specific handling of unused input pins Caution Hold CMOS devices at a fixed input level. Unlike bipolar or NMOS devices, if a CMOS device is operated with no input, an intermediate-level input may be caused by noise. This allows current to flow in the CMOS device, resulting in a malfunction. Use a pull-up or pull-down resistor to hold a fixed input level. Since unused pins may function as output pins at unexpected times, each unused pin should be separately connected to the VDD or GND pin through a resistor. If handling of unused pins is documented, follow the instructions in the document. 3 Statuses of all MOS devices at initialization Caution The initial status of a MOS device is unpredictable when power is turned on. Since characteristics of a MOS device are determined by the amount of ions implanted in molecules, the initial status cannot be determined in the manufacture process. NEC has no responsibility for the output statuses of pins, input and output settings, and the contents of registers at power on. However, NEC assures operation after reset and items for mode setting if they are defined. When you turn on a device having a reset function, be sure to reset the device first. 60 PD75208 [MEMO] 61 PD75208 [MEMO] No part of this document may be copied or reproduced in any form or by any means without the prior written consent of NEC Corporation. NEC Corporation assumes no responsibility for any errors which may appear in this document. NEC Corporation does not assume any liability for infringement of patents, copyrights or other intellectual property rights of third parties by or arising from use of a device described herein or any other liability arising from use of such device. No license, either express, implied or otherwise, is granted under any patents, copyrights or other intellectual property rights of NEC Corporation or others. The devices listed in this document are not suitable for use in aerospace equipment, submarine cables, nuclear reactor control systems and life support systems. If customers intend to use NEC devices for above applications or they intend to use "Standard" quality grade NEC devices for applications not intended by NEC, please contact our sales people in advance. Application examples recommended by NEC Corporation Standard : Computer, Office equipment, Communication equipment, Test and Measurement equipment, Machine tools, Industrial robots, Audio and Visual equipment, Other consumer products, etc. Special : Automotive and Transportation equipment, Traffic control systems, Antidisaster systems, Anticrime systems, etc. M4 92.6 EEPROMTM is a trademark of NEC Corporation. FIP (R) is a trademark of NEC Corporation. MS-DOSTM is a trademark of Microsoft Corporation. PC DOSTM is a trademark of IBM Corporation. |
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