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HD404369 Series Rev. 6.0 Sept. 1998 Description The HD404369 Series is a 4-bit HMCS400-Series microcomputer designed to increase program productivity and also incorporate large-capacity memory. Each microcomputer has an A/D converter, input capture timer, 32-kHz oscillator for clock, and four low-power dissipation modes. The HD404369 Series includes nine chips: the HD404364, HD40A4364 with 4-kword ROM; the HD404368, HD40A4368 with 8-kword ROM; the HD4043612, HD40A43612 with 12-kword ROM; the HD404369, HD40A4369 with 16-kword ROM; the HD407A4369 with 16-kword PROM. The HD40A4364, HD40A4368, HD40A43612, HD40A4369, and HD407A4369 are high speed versions (minimum instruction cycle time: 0.47 µs). The HD407A4369 is a PROM version (ZTAT microcomputer). A program can be written to the PROM by a PROM writer, which can dramatically shorten system development periods and smooth the process from debugging to mass production. (The ZTAT version is 27256-compatible.) Features • 512-digit × 4-bit RAM • 54 I/O pins One input-only pin 53 input/output pins: 8 pins are intermediate-voltage NMOS open drain with high-current pins (15 mA, max.) • On-chip A/D converter (8-bit × 12-channel) Low power voltage 2.7 V to 6.0 V • Three timers One event counter input One timer output One input capture timer • Eight-bit clock-synchronous serial interface (1 channel) • Alarm output HD404369 Series • Built-in oscillators Ceramic oscillator or crystal External clock drive is also possible Subclock: 32.768-kHz crystal oscillator • Seven interrupt sources Two by external sources Three by timers One by A/D converter One by serial interface • Four low-power dissipation modes Standby mode Stop mode Watch mode Subactive mode • Instruction cycle time 0.47 µs (fOSC = 8.5 MHz, 1/4 division ratio): HD40A4364, HD40A4368, HD40A43612, HD40A4369, HD407A4369 0.8 µs (fOSC = 5 MHz, 1/4 division ratio): HD404364, HD404368, HD4043612, HD404369 1/4, 1/8, 1/16, 1/32 system clock division ratio can be selecte 2 HD404369 Series Ordering Information Type Instruction Cycle Time Mask ROM Standard version (fOSC= 5 MHz) Product Name Model Name ROM (Words) Package HD404364 HD404364S 4,096 HD404368 HD4043612 HD404369 High speed versions HD40A4364 (fOSC = 8.5 MHz) HD40A4368 HD40A43612 HD40A4369 ZTAT (fOSC = 8.5 MHz) HD407A4369 DP-64S HD404364F FP-64B HD404364H FP-64A HD404368S 8,192 DP-64S HD404368F FP-64B HD404368H FP-64A HD4043612S 12,288 DP-64S HD4043612F FP-64B HD4043612H FP-64A HD404369S 16,384 DP-64S HD404369F FP-64B HD404369H FP-64A HD40A4364S 4,096 DP-64S HD40A4364F FP-64B HD40A4364H FP-64A HD40A4368S 8,192 DP-64S HD40A4368F FP-64B HD40A4368H FP-64A HD40A43612S 12,288 DP-64S HD40A43612F FP-64B HD40A43612H FP-64A HD40A4369S 16,384 DP-64S HD40A4369F FP-64B HD40A4369H FP-64A HD407A4369S 16,384 DP-64S HD407A4369F FP-64B HD407A4369H FP-64A 3 HD404369 Series 52 53 54 55 56 57 58 59 60 61 62 1 51 2 50 3 49 4 48 5 47 6 46 7 45 8 44 9 43 FP-64B 10 42 35 18 34 19 32 17 31 36 30 16 29 37 28 15 27 38 26 14 25 39 24 13 23 40 22 12 21 41 20 11 33 R11 R10 R93 R92 R91 R90 R83 R82 R81 R80 D13 D12 D11 D10 D9 D8 D7 D6 D5 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 R00/SCK R72 R71 R70 R63 R62 R61 R60 RA1 R23 R22 R21 R20 R13 R12 R11 R42/AN6 R43/AN7 R50/AN8 R51/AN9 R52/AN10 R53/AN11 AVCC VCC D0/INT0 D1/INT1 D2/EVNB D3/BUZZ D4/STOPC R72 R00/SCK R01/SI R02/SO R03/TOC TEST RESET OSC1 OSC2 GND X1 X2 AVSS R30/AN0 R31/AN1 R32/AN2 R33/AN3 R40/AN4 R41/AN5 63 64 R71 R70 R63 R62 R61 R60 RA1 R23 R22 R21 R20 R13 R12 Pin Arrangement FP-64A 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 R41/AN5 R42/AN6 R43/AN7 R50/AN8 R51/AN9 R52/AN10 R53/AN11 AVCC VCC D0/INT0 D1/INT1 D2/EVNB D3/BUZZ D4/STOPC D5 D6 R01/SI R02/SO R03/TOC TEST RESET OSC1 OSC2 GND X1 X2 AVSS R30/AN0 R31/AN1 R32/AN2 R33/AN3 R40/AN4 4 R10 R93 R92 R91 R90 R83 R82 R81 R80 D13 D12 D11 D10 D9 D8 D7 R60 R61 R62 R63 R70 R71 R72 R00/SCK R01/SI R02/SO R03/TOC TEST RESET OSC1 OSC2 GND X1 X2 AVSS R30/AN0 R31/AN1 R32/AN2 R33/AN3 R40/AN4 R41/AN5 R42/AN6 R43/AN7 R50/AN8 R51/AN9 R52/AN10 R53/AN11 AV CC 1 64 2 63 3 62 4 61 5 60 6 59 7 58 8 57 9 56 10 55 11 54 12 53 13 52 14 15 16 51 DP-64S 50 49 17 48 18 47 19 46 20 45 21 44 22 43 23 42 24 41 25 40 26 39 27 38 28 37 29 36 30 35 31 34 32 33 RA1 R23 R22 R21 R20 R13 R12 R11 R10 R93 R92 R91 R90 R83 R82 R81 R80 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4/STOPC D3/BUZZ D2/EVNB D1/INT1 D0/INT0 VCC HD404369 Series Pin Description Pin Number Item Symbol DP-64S FP-64B FP-64A I/O Function Power VCC 33 27 25 Applies power voltage Supply GND 16 10 8 Connected to ground Test TEST 12 6 4 I Cannot be used in user applications. Connect this pin to GND. Reset RESET 13 7 5 I Resets the MCU Oscillator OSC 1 14 8 6 I Input/output pin for the internal oscillator. Connect these pins to the ceramic oscillator or crystal oscillator, or OSC1 to an external oscillator circuit. OSC 2 15 9 7 O X1 17 11 9 I X2 18 12 10 O D0–D 13 34–47 28–41 26–39 I/O Input/output pins consisting of standard voltage pins addressed individually by bits RA 1 64 58 56 I One-bit standard-voltage input port pin R0 0–R0 3, 1–11, 1–5, 1–3, I/O R3 0–R9 3 20–31, 14–25, 12–23, Four-bit input/output pins consisting of standard voltage pins 48–55 42–49, 40–47, Port Interrupt 56–63 50–57 48–55 I/O Four-bit input/output pins consisting of intermediate voltage pins INT0, INT1 34, 35 28, 29 26, 27 I Input pins for external interrupts 38 32 30 I Input pin for transition from stop mode to active mode 8 2 64 I/O Serial interface clock input/output pin 9 3 1 I Serial interface receive data input pin SO 10 4 2 O Serial interface transmit data output pin TOC 11 5 3 O Timer output pin EVNB 36 30 28 I Event count input pin BUZZ 37 31 29 O Square waveform output pin SCK Interface SI Timer Alarm 57–64 R1 0–R2 3 Stop clear STOPC Serial 59–64 Used with a 32.768-kHz crystal ocillator for clock purposes 5 HD404369 Series Pin Description (cont) Pin Number Item DP-64S FP-64B FP-64A I/O Function A/D AVCC converter 32 26 24 Power supply for the A/D converter. Connect this pin as close as possible to the V CC pin and at the same voltage as VCC. If the power supply voltage to be used for the A/D converter is not equal to VCC, connect a 0.1-µF bypass capacitor between the AVCC and AV SS pins. (However, this is not necessary when the AV CC pin is directly connected to the VCC pin.) AVSS 19 13 11 Ground for the A/D converter. Connect this pin as close as possible to GND at the same voltage as GND. AN 0–AN 11 20–31 14–25 12–23 6 Symbol I Analog input pins for the A/D converter HD404369 Series GND VCC X2 X1 OSC2 OSC1 STOPC TEST RESET Block Diagram D0 INT0 D1 System control Interrupt control D2 INT1 D3 RAM (512 × 4 bits) D4 D port D5 W (2 bits) Timer A D6 D7 D8 D9 X (4 bits) D10 D11 D12 D13 R0 port SPX (4 bits) R1 port SCK ALU AVSS R2 port SPY (4 bits) R3 port Serial interface SO Internal data bus SI Internal data bus Timer C TOC Internal address bus Y (4 bits) R4 port Timer B EVNB CA (1 bit) R6 port A (4 bits) AVCC B (4 bits) BUZZ Buzzer SP (10 bits) Data bus Intermediate voltage pin Directional signal line Instruction decoder PC (14 bits) ROM (16,384 × 10 bits) (12,288 × 10 bits) (8,192 × 10 bits) (4,096 × 10 bits) R7 port ST (1 bit) R8 port A/D converter R9 port • • • RA port • • • AN11 R5 port AN0 R00 R01 R02 R03 R10 R11 R12 R13 R20 R21 R22 R23 R30 R31 R32 R33 R40 R41 R42 R43 R50 R51 R52 R53 R60 R61 R62 R63 R70 R71 R72 R80 R81 R82 R83 R90 R91 R92 R93 RA1 7 HD404369 Series Memory Map ROM Memory Map The ROM memory map is shown in figure 1 and described below. Vector Address Area ($0000–$000F): Reserved for JMPL instructions that branch to the start addresses of the reset and interrupt routines. After MCU reset or an interrupt, program execution continues from the vector address. Zero-Page Subroutine Area ($0000–$003F): Reserved for subroutines. The program branches to a subroutine in this area in response to the CAL instruction. Pattern Area ($0000–$0FFF): Contains ROM data that can be referenced with the P instruction. Program Area ($0000-$0FFF (HD404364, HD40A4364), $0000–$1FFF (HD404368, HD40A4368), $0000–$2FFF (HD4043612, HD40A43612), $0000–$3FFF (HD404369, HD40A4369, HD407A4369)): The entire ROM area can be used for program coding. $0000 $000F Vector address (16 words) $0010 Zero-page subroutine (64 words) $003F $0040 $0FFF $1000 $1FFF Program (4,096 words) For HD404364, HD40A4364 Program (8,192 words) For HD404368, HD40A4368 $2000 Program (12,288 words) $2FFF $0000 JMPL instruction $0001 (jump to RESET, STOPC routine) JMPL instruction $0002 (jump to INT 0 routine) $0003 JMPL instruction $0004 (jump to INT 1 routine) $0005 $0006 $0007 $0008 $0009 JMPL instruction (jump to timer A routine) $000A $000B $000C $000D $000E $000F JMPL instruction (jump to timer C routine) JMPL instruction (jump to timer B routine) JMPL instruction (jump to A/D converter routine) JMPL instruction (jump to serial routine) For HD4043612, HD40A43612 $3000 Program (16,384 words) $3FFF Note: For HD404369, HD40A4369, HD407A4369 Since the ROM address areas between $0000–$0FFF overlap, the user can determine how these areas are to be used. Figure 1 ROM Memory Map RAM Memory Map The MCU contains 512-digit × 4 bit RAM areas. These RAM areas consist of a memory register area, a data area, and a stack area. In addition, an interrupt control bits area, special function register area, and register flag area are mapped onto the same RAM memory space labeled as a RAM-mapped register area. The RAM memory map is shown in figure 2 and described below. 8 HD404369 Series RAM Memory Map Initial values after reset $000 $000 $003 $004 $005 $006 $007 $008 $009 $00A $00B $00C $00D $00E $00F RAM-mapped registers $040 Memory registers (MR) $050 Data (432 digits) $200 Not used Interrupt control bits area Port mode register A (PMRA) Serial mode register (SMR) Serial data register lower (SRL) Serial data register upper (SRU) Timer mode register A (TMA) Timer mode register B1 (TMB1) Timer B (TRBL/TWBL) (TRBU/TWBU) Miscellaneous register (MIS) Timer mode register C (TMC) Timer C (TRCL/TWCL) (TRCU/TWCU) W W R/W R/W W W R/W R/W W W R/W R/W 0000 0000 Undefined Undefined 0000 0000 *2/0000 *1 Undefined 0000 0000 *2/0000 Undefined Not used $3C0 Stack (64 digits) (ACR) (ADRL) (ADRU) (AMR1) (AMR2) W R R W W 0000 0000 1000 0000 -000 $020 Register flag area $023 $024 Port mode register B (PMRB) $025 Port mode register C (PMRC) $026 Timer mode register B2 (TMB2) $027 System clock selection register 1 (SSR1) $028 System clock selection register 2 (SSR2) W W W W W 0000 00-0 -000 000--00 Not used Port D0–D3 DCR (DCD0) W $016 $017 $018 $019 $01A $3FF A/D channel register A/D data register lower A/D data register upper A/D mode register 1 A/D mode register 2 Not used $02C $02D Notes: 1. Two registers are mapped on the same area ($00A, $00B, $00E, $00F). 2. Undefined. R: Read only W: Write only R/W: Read/write $02E $02F $030 $031 $032 $033 $034 $035 $036 $037 $038 $039 $03F Port D4–D7 DCR Port D8–D11 DCR Port D12, D13 DCR Port R0 DCR Port R1 DCR Port R2 DCR Port R3 DCR Port R4 DCR Port R5 DCR Port R6 DCR Port R7 DCR Port R8 DCR Port R9 DCR Not used (DCD1) (DCD2) W W 0000 0000 0000 (DCD3) (DCR0) (DCR1) (DCR2) (DCR3) (DCR4) (DCR5) (DCR6) (DCR7) (DCR8) (DCR9) W W W W W W W W W W W --00 0000 0000 0000 0000 0000 0000 0000 -000 0000 0000 $00A Timer read register B lower (TRBL) R Timer write register B lower (TWBL) W $00B Timer read register B upper (TRBU) R Timer write register B upper (TWBU) W $00E Timer read register C lower (TRCL) R Timer write register C lower (TWCL) W $00F Timer read register C upper (TRCU) R Timer write register C upper (TWCU) W Figure 2 RAM Memory Map 9 HD404369 Series RAM-Mapped Register Area ($000–$03F): • Interrupt Control Bits Area ($000–$003) This area is used for interrupt control bits (figure 3). These bits can be accessed only by RAM bit manipulation instructions (SEM/SEMD, REM/REMD, and TM/TMD). However, note that not all the instructions can be used for each bit. Limitations on using the instructions are shown in figure 4. • Special Function Register Area ($004–$01F, $024–$03F) This area is used as mode registers and data registers for external interrupts, serial interface, timer/counters, A/D converter, and as data control registers for I/O ports. The structure is shown in figures 2 and 5. These registers can be classified into three types: write-only (W), read-only (R), and read/write (R/W). RAM bit manipulation instructions cannot be used for these registers. • Register Flag Area ($020–$023) This area is used for the DTON, WDON, and other register flags and interrupt control bits (figure 3). These bits can be accessed only by RAM bit manipulation instructions (SEM/SEMD, REM/REMD, and TM/TMD). However, note that not all the instructions can be used for each bit. Limitations on using the instructions are shown in figure 4. Memory Register (MR) Area ($040–$04F): Consisting of 16 addresses, this area (MR0–MR15) can be accessed by register-register instructions (LAMR and XMRA). The structure is shown in figure 6. Data Area ($050–$1FF) Stack Area ($3C0–$3FF): Used for saving the contents of the program counter (PC), status flag (ST), and carry flag (CA) at subroutine call (CAL or CALL instruction) and for interrupts. This area can be used as a 16-level nesting subroutine stack in which one level requires four digits. The data to be saved and the save conditions are shown in figure 6. The program counter is restored by either the RTN or RTNI instruction, but the status and carry flags can only be restored by the RTNI instruction. Any unused space in this area is used for data storage. 10 HD404369 Series Bit 3 Bit 2 Bit 1 Bit 0 $000 IM0 (IM of INT0) IF0 (IF of INT0) RSP (Reset SP bit) IE (Interrupt enable flag) $001 IMTA (IM of timer A) IFTA (IF of timer A) IM1 (IM of INT1) IF1 (IF of INT1) $002 IMTC (IM of timer C) IFTC (IF of timer C) IMTB (IM of timer B) IFTB (IF of timer B) $003 IMS (IM of serial) IFS (IF of serial) IMAD (IM of A/D) IFAD (IF of A/D) Interrupt control bits area Bit 2 Bit 1 Bit 0 $020 DTON (Direct transfer on flag) Bit 3 ADSF (A/D start flag) WDON (Watchdog on flag) LSON (Low speed on flag) $021 RAME (RAM enable flag) IAOF (IAD off flag) ICEF (Input capture error flag) ICSF (Input capture status flag) $022 IF: IM: IE: SP: Not used $023 Interrupt request flag Interrupt mask Interrupt enable flag Stack pointer Register flag area Figure 3 Configuration of Interrupt Control Bits and Register Flag Areas IE IM LSON IAOF IF ICSF ICEF RAME RSP WDON ADSF DTON Not used SEM/SEMD REM/REMD TM/TMD Allowed Allowed Allowed Not executed Allowed Allowed Not executed Allowed Allowed Not executed in active mode Used in subactive mode Not executed Allowed Not executed Inhibited Inhibited Inhibited Allowed Allowed Allowed Not executed Inhibited Note: WDON is reset by MCU reset or by STOPC enable for stop mode cancellation. The REM or REMD instuction must not be executed for ADSF during A/D conversion. DTON is always reset in active mode. If the TM or TMD instruction is executed for the inhibited bits or non-existing bits, the value in ST becomes invalid. Figure 4 Usage Limitations of RAM Bit Manipulation Instructions 11 HD404369 Series Bit 3 Bit 2 Bit 1 Bit 0 $000 Interrupt control bits area $003 PMRA $004 D3 /BUZZ SMR $005 R00 /SCK R03/TOC R01/SI SRL $006 Serial data register (lower digit) SRU $007 Serial data register (upper digit) TMA $008 *1 TMB1 $009 *2 R02 /SO Serial transmit clock speed selection Clock source selection (timer A) Clock source selection (timer B) Timer B register (lower digit) TRBL/TWBL $00A Timer B register (upper digit) TRBU/TWBU $00B MIS $00C *3 TMC $00D *2 SO PMOS control Interrupt frame period selection Clock source selection (timer C) TRCL/TWCL $00E Timer C register (lower digit) TRCU/TWCU $00F Timer C register (upper digit) Not used ACR $016 Analog channel selection ADRL $017 A/D data register (lower digit) A/D data register (upper digit) ADRU $018 AMR1$019 R33/AN3 AMR2 $01A Not used R32/AN2 R31/AN1 R5/AN8–AN11 R4/AN4–AN7 R30/AN0 *4 Not used $020 Register flag area $023 PMRB $024 PMRC $025 D4/STOPC D2/EVNB TMB2 $026 Not used *7 SSR1 $027 *8 *9 SSR2 $028 D1/INT1 D0/INT0 *5 *6 Buzzer output EVNB detection edge selection Clock select Not used Clock division ratio selection Not used Not used DCD0 $02C Port D3 DCD Port D2 DCD Port D1 DCD Port D0 DCD DCD1 $02D Port D7 DCD Port D6 DCD Port D5 DCD Port D4 DCD DCD2 $02E Port D11 DCD Port D10 DCD Port D9 DCD Port D8 DCD DCD3 $02F DCR0 $030 DCR1 $031 DCR2 $032 DCR3 $033 Not used Port D13 DCD Port D12 DCD Port R03 DCR Port R02 DCR Port R01 DCR Port R00 DCR Port R13 DCR Port R12 DCR Port R11 DCR Port R10 DCR Port R23 DCR Port R22 DCR Port R21 DCR Port R20 DCR Port R33 DCR Port R32 DCR Port R31 DCR Port R30 DCR DCR4 $034 Port R43 DCR Port R42 DCR Port R41 DCR Port R40 DCR DCR5 $035 Port R53 DCR Port R52 DCR Port R51 DCR Port R50 DCR DCR6 $036 Port R63 DCR Port R62 DCR Port R61 DCR Port R60 DCR DCR7 $037 Not used Port R72 DCR Port R71 DCR Port R70 DCR DCR8 $038 Port R83 DCR Port R82 DCR Port R81 DCR Port R80 DCR DCR9 $039 Port R93 DCR Port R92 DCR Port R91 DCR Port R90 DCR Not used Notes: 1. 2. 3. 4. 5. 6. 7. 8. 9. Timer-A/time-base Auto-reload on/off Pull-up MOS control A/D conversion time SO output level control in idle states Serial clock source selection Input capture selection 32-kHz oscillation stop 32-kHz oscillation division ratio $03F Figure 5 Special Function Register Area 12 HD404369 Series Memory registers $040 MR(0) $041 MR(1) $042 MR(2) $043 MR(3) $044 MR(4) $045 MR(5) $046 MR(6) $047 MR(7) $048 MR(8) $049 MR(9) $04A MR(10) $04B MR(11) $04C MR(12) $04D MR(13) $04E MR(14) $04F MR(15) Stack area Level 16 Level 15 Level 14 Level 13 Level 12 Level 11 Level 10 Level 9 Level 8 Level 7 Level 6 Level 5 Level 4 Level 3 Level 2 $3FF Level 1 $3C0 Bit 3 Bit 2 Bit 1 Bit 0 $3FC ST PC13 PC 12 PC11 $3FD PC 10 PC9 PC 8 PC7 $3FE CA PC6 PC 5 PC4 $3FF PC 3 PC2 PC 1 PC0 PC13 –PC0 : Program counter ST: Status flag CA: Carry flag Figure 6 Configuration of Memory Registers and Stack Area, and Stack Position 13 HD404369 Series Functional Description Registers and Flags The MCU has nine registers and two flags for CPU operations. They are shown in figure 7 and described below. 3 Accumulator 0 (A) Initial value: Undefined, R/W 3 B register Initial value: Undefined, R/W W register Initial value: Undefined, R/W 0 (B) 1 0 (W) 3 X register Initial value: Undefined, R/W 0 (X) 3 Y register 0 (Y) Initial value: Undefined, R/W 3 SPX register Initial value: Undefined, R/W SPY register Initial value: Undefined, R/W Carry Initial value: Undefined, R/W Status Initial value: 1, no R/W 0 (SPX) 3 0 (SPY) 0 (CA) 0 (ST) 13 Program counter Initial value: 0, no R/W 0 (PC) 9 Stack pointer Initial value: $3FF, no R/W 1 5 1 1 1 0 (SP) Figure 7 Registers and Flags Accumulator (A), B Register (B): Four-bit registers used to hold the results from the arithmetic logic unit (ALU) and transfer data between memory, I/O, and other registers. W Register (W), X Register (X), Y Register (Y): Two-bit (W) and four-bit (X and Y) registers used for indirect RAM addressing. The Y register is also used for D-port addressing. 14 HD404369 Series SPX Register (SPX), SPY Register (SPY): Four-bit registers used to supplement the X and Y registers. Carry Flag (CA): One-bit flag that stores any ALU overflow generated by an arithmetic operation. CA is affected by the SEC, REC, ROTL, and ROTR instructions. A carry is pushed onto the stack during an interrupt and popped from the stack by the RTNI instruction—but not by the RTN instruction. Status Flag (ST): One-bit flag that latches any overflow generated by an arithmetic or compare instruction, not-zero decision from the ALU, or result of a bit test. ST is used as a branch condition of the BR, BRL, CAL, and CALL instructions. The contents of ST remain unchanged until the next arithmetic, compare, or bit test instruction is executed, but become 1 after the BR, BRL, CAL, or CALL instruction is read, regardless of whether the instruction is executed or skipped. The contents of ST are pushed onto the stack during an interrupt and popped from the stack by the RTNI instruction—but not by the RTN instruction. Program Counter (PC): 14-bit binary counter that points to the ROM address of the instruction being executed. Stack Pointer (SP): Ten-bit pointer that contains the address of the stack area to be used next. The SP is initialized to $3FF by MCU reset. It is decremented by 4 when data is pushed onto the stack, and incremented by 4 when data is popped from the stack. The top four bits of the SP are fixed at 1111, so a stack can be used up to 16 levels. The SP can be initialized to $3FF in another way: by resetting the RSP bit with the REM or REMD instruction. Reset The MCU is reset by inputting a low-level voltage to the RESET pin. At power-on or when stop mode is cancelled, RESET must be low for at least one tRC to enable the oscillator to stabilize. During operation, RESET must be low for at least two instruction cycles. Initial values after MCU reset are listed in table 1. Interrupts The MCU has 7 interrupt sources: two external signals (INT 0 and INT1), three timer/counters (timers A, B, and C), serial interface, and A/D converter. An interrupt request flag (IF), interrupt mask (IM), and vector address are provided for each interrupt source, and an interrupt enable flag (IE) controls the entire interrupt process. Interrupt Control Bits and Interrupt Processing: Locations $000 to $003 in RAM are reserved for the interrupt control bits which can be accessed by RAM bit manipulation instructions. The interrupt request flag (IF) cannot be set by software. MCU reset initializes the interrupt enable flag (IE) and the IF to 0 and the interrupt mask (IM) to 1. A block diagram of the interrupt control circuit is shown in figure 8, interrupt priorities and vector addresses are listed in table 2, and interrupt processing conditions for the 7 interrupt sources are listed in table 3. 15 HD404369 Series An interrupt request occurs when the IF is set to 1 and the IM is set to 0. If the IE is 1 at that point, the interrupt is processed. A priority programmable logic array (PLA) generates the vector address assigned to that interrupt source. The interrupt processing sequence is shown in figure 9 and an interrupt processing flowchart is shown in figure 10. After an interrupt is acknowledged, the previous instruction is completed in the first cycle. The IE is reset in the second cycle, the carry, status, and program counter values are pushed onto the stack during the second and third cycles, and the program jumps to the vector address to execute the instruction in the third cycle. Program the JMPL instruction at each vector address, to branch the program to the start address of the interrupt program, and reset the IF by a software instruction within the interrupt program. 16 HD404369 Series Table 1 Initial Values After MCU Reset Item Abbr. Initial Value Contents Program counter (PC) $0000 Indicates program execution point from start address of ROM area Status flag (ST) 1 Enables conditional branching Stack pointer (SP) $3FF Stack level 0 Interrupt Interrupt enable flag flags/mask (IE) 0 Inhibits all interrupts Interrupt request flag (IF) 0 Indicates there is no interrupt request Interrupt mask (IM) 1 Prevents (masks) interrupt requests Port data register (PDR) All bits 1 Enables output at level 1 Data control register (DCD0DCD2) All bits 0 Turns output buffer off (to high impedance) (DCD3) - - 00 (DCR0– DCR6, DCR8, DCR9) All bits 0 (DCR7) - 000 Port mode register A (PMRA) 0000 Port mode register B bits 2–0 (PMRB2– 000 PMRB0) Refer to description of port mode register B Port mode register C (PMRC) 00 - 0 Refer to description of port mode register C (TMA) 0000 Refer to description of timer mode register A Timer mode register B1 (TMB1) 0000 Refer to description of timer mode register B1 Timer mode register B2 (TMB2) - 000 Refer to description of timer mode register B2 Timer mode register C (TMC) 0000 Refer to description of timer mode register C Serial mode register (SMR) 0000 Refer to description of serial mode register Prescaler S (PSS) $000 — Prescaler W (PSW) $00 — Timer counter A (TCA) $00 — Timer counter B (TCB) $00 — Timer counter C (TCC) $00 — Timer write register B (TWBU, TWBL) $X0 — Timer write register C (TWCU, TWCL) $X0 — 000 — I/O Timer/count- Timer mode register A ers, serial interface Octal counter Refer to description of port mode register A 17 HD404369 Series Item A/D Abbr. Initial Value Contents A/D mode register 1 (AMR1) 0000 A/D mode register 2 (AMR2) - 000 A/D channel register (ACR) 0000 Refer to description of A/D channel register A/D data register (ADRL) 0000 Refer to description of A/D data register (ADRU) 1000 (LSON) 0 Bit registers Low speed on flag Others Refer to description of A/D mode register Refer to description of operating modes Watchdog timer on flag (WDON) 0 Refer to description of timer C A/D start flag (ADSF) 0 Refer to description of A/D converter I AD off flag (IAOF) 0 Refer to the description of A/D converter Direct transfer on flag (DTON) 0 Refer to description of operating modes Input capture status flag (ICSF) 0 Refer to description of timer B Input capture error flag (ICEF) 0 Refer to description of timer B Miscellaneous register (MIS) 0000 Refer to description of operating modes, I/O, and serial interface System clock select register 1 (SSR1) 000 - Refer to description of operating modes, and oscillation circuits System clock select register 2 (SSR2) - - 00 Refer to description of oscillation circuits Notes: 1. The statuses of other registers and flags after MCU reset are shown in the following table. 2. X indicates invalid value. – indicates that the bit does not exist. 18 HD404369 Series Item Abbr. Carry flag (CA) Accumulator (A) B register (B) W register (W) X/SPX register (X/SPX) Y/SPY register (Y/SPY) Serial data register (SRL, SRU) Status After Cancellation of Stop Status After all Other Types of Mode by STOPC Input Reset Pre-stop-mode values are not guaranteed; values must be initialized by program RAM Pre-mcu-reset values are not guaranteed; values must be initialized by program Pre-stop-mode values are retained RAM enable flag (RAME) 1 0 Port mode register B bit 3 (PMRB3) Pre-stop-mode values are retained 0 System clock select register 1 bit 3 (SSR13) Table 2 Vector Addresses and Interrupt Priorities Reset/Interrupt Priority Vector Address RESET, STOPC* — $0000 INT0 1 $0002 INT1 2 $0004 Timer A 3 $0006 Timer B 4 $0008 Timer C 5 $000A A/D 6 $000C Serial 7 $000E Note: * The STOPC interrupt request is valid only in stop mode. 19 HD404369 Series $ 000,0 IE INT0 interrupt Sequence control • Push PC/CA/ST • Reset IE • Jump to vector address $ 000,2 IFO $ 000,3 IMO Vector address Priority control logic INT1 interrupt $ 001,0 IF1 $ 001,1 IM1 Timer A interrupt $ 001,2 IFTA $ 001,3 IMTA Timer B interrupt $ 002,0 IFTB $ 002,1 IMTB Timer C interrupt $ 002,2 IFTC $ 002,3 IMTC A/D interrupt $ 003,0 IFAD $ 003,1 IMAD Serial interrupt $ 003,2 IFS $ 003,3 IMS Note: $m,n is RAM address $m, bit number n. Figure 8 Interrupt Control Circuit 20 HD404369 Series Table 3 Interrupt Processing and Activation Conditions Interrupt Source INT0 INT1 Timer A Timer B Timer C A/D Serial IE 1 1 1 1 1 1 1 IF0 IM0 1 0 0 0 0 0 0 IF1 IM1 * 1 0 0 0 0 0 IFTA IMTA * * 1 0 0 0 0 IFTB IMTB * * * 1 0 0 0 IFTC IMTC * * * * 1 0 0 IFAD IMAD * * * * * 1 0 IFS IMS * * * * * * 1 Note: Bits marked * can be either 0 or 1. Their values have no effect on operation. Instruction cycles 1 2 3 4 5 6 Instruction execution* Interrupt acceptance Stacking IE reset Vector address generation Execution of JMPL instruction at vector address Note: * The stack is accessed and the IE reset after the instruction is executed, even if it is a two-cycle instruction. Execution of instruction at start address of interrupt routine Figure 9 Interrupt Processing Sequence 21 HD404369 Series Power on RESET = 0? Yes No Interrupt request? No Yes No IE = 1? Yes Reset MCU Accept interrupt Execute instruction IE ← 0 Stack ← (PC) Stack ← (CA) Stack ← (ST) PC ←(PC) + 1 PC← $0002 Yes INT0 interrupt? No PC← $0004 Yes INT1 interrupt? No PC← $0006 Yes Timer-A interrupt? No PC← $0008 Yes Timer-B interrupt? No PC ← $000A Yes Timer-C interrupt? No PC ← $000C Yes A/D interrupt? No PC ← $000E (serial interrupt) Figure 10 Interrupt Processing Flowchart 22 HD404369 Series Interrupt Enable Flag (IE: $000, Bit 0): Controls the entire interrupt process. It is reset by the interrupt processing and set by the RTNI instruction, as listed in table 4. Table 4 Interrupt Enable Flag (IE: $000, Bit 0) IE Interrupt Enabled/Disabled 0 Disabled 1 Enabled External Interrupts (INT0, INT1): Two external interrupt signals. External Interrupt Request Flags (IF0: $000, Bit 2; IF1: $001, Bit 0): IF0 and IF1 are set at the rising edge of signals input to INT 0 and INT1, as listed in table 5. Table 5 External Interrupt Request Flags (IF0: $000, Bit2; IF1: $001, Bit 0) IF0, IF1 Interrupt Request 0 No 1 Yes External Interrupt Masks (IM0: $000, Bit 3; IM1: $001, Bit 1): Prevent (mask) interrupt requests caused by the corresponding external interrupt request flags, as listed in table 6. Table 6 External Interrupt Masks (IM0: $000, Bit 3; IM1: $001, Bit 1) IM0, IM1 Interrupt Request 0 Enabled 1 Disabled (masked) Timer A Interrupt Request Flag (IFTA: $001, Bit 2): Set by overflow output from timer A, as listed in table 7. Table 7 Timer A Interrupt Request Flag (IFTA: $001, Bit 2) IFTA Interrupt Request 0 No 1 Yes Timer A Interrupt Mask (IMTA: $001, Bit 3): Prevents (masks) an interrupt request caused by the timer A interrupt request flag, as listed in table 8. 23 HD404369 Series Table 8 Timer A Interrupt Mask (IMTA: 001, Bit 3) IMTA Interrupt Request 0 Enabled 1 Disabled (masked) Timer B Interrupt Request Flag (IFTB: $002, Bit 0): Set by overflow output from timer B, as listed in table 9. Table 9 Timer B Interrupt Request Flag (IFTB: $002, Bit 0) IFTB Interrupt Request 0 No 1 Yes Timer B Interrupt Mask (IMTB: $002, Bit 1): Prevents (masks) an interrupt request caused by the timer B interrupt request flag, as listed in table 10. Table 10 Timer B Interrupt Mask (IMTB: $002, Bit 1) IMTB Interrupt Request 0 Enabled 1 Disabled (masked) Timer C Interrupt Request Flag (IFTC: $002, Bit 2): Set by overflow output from timer C, as listed in table 11. Table 11 Timer C Interrupt Request Flag (IFTC: $002, Bit 2) IFTC Interrupt Request 0 No 1 Yes Timer C Interrupt Mask (IMTC: $002, Bit 3): Prevents (masks) an interrupt request caused by the timer C interrupt request flag, as listed in table 12. Table 12 Timer C Interrupt Mask (IMTC: $002, Bit 3) IMTC Interrupt Request 0 Enabled 1 Disabled (masked) 24 HD404369 Series Serial Interrupt Request Flag (IFS: $003, Bit 2): Set when data transfer is completed or when data transfer is suspended, as listed in table 13. Table 13 Serial Interrupt Request Flag (IFS: $003, Bit 2) IFS Interrupt Request 0 No 1 Yes Serial Interrupt Mask (IMS: $003, Bit 3): Prevents (masks) an interrupt request caused by the serial interrupt request flag, as listed in table 14. Table 14 Serial Interrupt Mask (IMS: $003, Bit 3) Mask IMS Interrupt Request 0 Enabled 1 Disabled (masked) A/D Interrupt Request Flag (IFAD: $003, Bit 0): Set at the completion of A/D conversion, as listed in table 15. Table 15 A/D Interrupt Request Flag (IFAD: $003, Bit 0) IFAD Interrupt Request 0 No 1 Yes A/D Interrupt Mask (IMAD: $003, Bit 1): Prevents (masks) an interrupt request caused by the A/D interrupt request flag, as listed in table 16. Table 16 A/D Interrupt Mask (IMAD: $003, Bit 1) IMAD Interrupt Request 0 Enabled 1 Disabled (masked) 25 HD404369 Series Operating Modes The MCU has five operating modes as shown in table 17. The operations in each mode are listed in tables 18 and 19. Transitions between operating modes are shown in figure 11. Active Mode: All MCU functions operate according to the clock generated by the system oscillator OSC 1 and OSC2. Table 17 Operating Modes and Clock Status Mode Name Active Standby Stop Watch Subactive*2 Activation method RESET cancellation, SBY instruction interrupt STOPC cancellation in stop mode, STOP/SBY instruction in subactive mode (when direct transfer is selected) STOP STOP INT0 or timer A instruction when instruction when interrupt request TMA3 = 0 TMA3 = 1 from watch mode Status System oscillator OP OP Stopped Stopped Stopped Subsystem OP oscillator OP *1 OP OP OP Cancellation method RESET input, RESET STOP/SBY instruction input, interrupt request RESET input, RESET input, RESET input, STOPC input in INT0 or timer A STOP/SBY stop mode interrupt request instruction Notes: OP implies in operation 1. Operating or stopping the oscillator can be selected by setting bit 3 of the system clock select register 1 (SSR1: $027). 2. Subactive mode is an optional function; specify it on the function option list. 26 HD404369 Series Table 18 Operations in Low-Power Dissipation Modes Function Stop Mode Watch Mode Standby Mode Subactive Mode CPU Reset Retained Retained OP RAM Retained Retained Retained OP Timer A Reset OP OP OP Timer B Reset Stopped OP OP Timer C Reset Stopped OP OP Serial Reset Stopped OP OP A/D Reset Stopped OP Stopped I/O Reset Retained Retained OP Note: OP implies in operation Table 19 I/O Status in Low-Power Dissipation Modes Output Input Standby Mode, Watch mode Stop Mode Active Mode, Subactive mode RA 1 — — Input enabled D0–D 13 , R0–R9 Retained or output of peripheral functions High impedance Input enabled 27 HD404369 Series Reset by RESET input or by watchdog timer Stop mode (TMA3 = 0, SSR13 = 0) RAME = 0 RESET1 RAME = 1 RESET2 STOPC STOPC STOP Oscillate Oscillate Stop fcyc fcyc Stop Oscillate Stop Stop Stop Active mode Standby mode fOSC: fX: ø CPU: ø CLK: ø PER: fOSC: fX: ø CPU: ø CLK: ø PER: SBY Interrupt fOSC: fX: ø CPU: ø CLK: ø PER: Oscillate Oscillate fcyc fcyc fcyc (TMA3 = 0, SSR13 = 1) STOP fOSC: fX: ø CPU: ø CLK: ø PER: Stop Stop Stop Stop Stop (TMA3 = 0) Watch mode (TMA3 = 1) fOSC: fX: ø CPU: ø CLK: ø PER: Oscillate Oscillate Stop fW fcyc SBY Interrupt fOSC: fX: ø CPU: ø CLK: ø PER: Oscillate Oscillate fcyc fW fcyc (TMA3 = 1, LSON = 0) STOP INT0, timer A*1 fOSC: fX: ø CPU: ø CLK: ø PER: Stop Oscillate Stop fW Stop *3 fOSC: fX: *2 Main oscillation frequency Subactive Suboscillation frequency STOP mode (TMA3 = 1, LSON = 1) for time-base Stop f : fOSC: Stop OSC *4 fOSC/4, fOSC/8, fOSC/16, fOSC/32 fcyc: Oscillate Oscillate f fX: : X (software selectable) INT0, ø CPU: fSUB ø CPU: Stop *1 fSUB: fX/8 or fX/4 timer A ø CLK: fW ø CLK: fW (software selectable) ø ø PER: Stop : f SUB PER fW: fX/8 ø CPU: System clock ø CLK: Clock for time-base Notes: 1. Interrupt source ø PER: Clock for other 2. STOP/SBY (DTON = 1, LSON = 0) peripheral functions 3. STOP/SBY (DTON = 0, LSON = 0) LSON: Low speed on flag 4. STOP/SBY (DTON = Don’t care, LSON = 1) DTON: Direct transfer on flag Figure 11 MCU Status Transitions 28 HD404369 Series Standby Mode: In standby mode, the oscillators continue to operate, but the clocks related to instruction execution stop. Therefore, the CPU operation stops, but all RAM and register contents are retained, and the D or R port status, when set to output, is maintained. Peripheral functions such as interrupts, timers, and serial interface continue to operate. The power dissipation in this mode is lower than in active mode because the CPU stops. The MCU enters standby mode when the SBY instruction is executed in active mode. Standby mode is terminated by a RESET input or an interrupt request. If it is terminated by RESET input, the MCU is reset as well. After an interrupt request, the MCU enters active mode and executes the next instruction after the SBY instruction. If the interrupt enable flag is 1, the interrupt is then processed; if it is 0, the interrupt request is left pending and normal instruction execution continues. A flowchart of operation in standby mode is shown in figure 12. 29 HD404369 Series Stop Standby Watch Oscillator: Stop Suboscillator: Active/Stop Peripheral clocks: Stop All other clocks: Stop Oscillator: Active Peripheral clocks: Active All other clocks: Stop Oscillator: Stop Suboscillator: Active Peripheral clocks: Stop All other clocks: Stop No RESET = 0? Yes No RESET = 0? Yes IF0 • IM0 = 1? No No STOPC = 0? Yes IF1 • IM1 = 1? No Yes Yes IFTA • IMTA = 1? Yes RAME = 1 No IFTB • IMTB = 1? RAME = 0 No Yes IFTC • IMTC = 1? Yes No IFAD • IMAD = 1? Yes (SBY only) Restart processor clocks (SBY only) (SBY only) (SBY only) No IFS • IMS = 1? (SBY only) No Yes Restart processor clocks Execute next instruction No Reset MCU IF = 1, IM = 0, and IE = 1? Execute next instruction Yes Accept interrupt Figure 12 MCU Operation Flowchart Stop Mode: In stop mode, all MCU operations stop and RAM data is retained. Therefore, the power dissipation in this mode is the least of all modes. The OSC1 and OSC2 oscillator stops. For the X1 and X2 oscillator to operate or stop can be selected by setting bit 3 of the system clock select register 1 (SSR1: $027; operating: SSR13 = 0, stop: SSR13 = 1) (figure 23). The MCU enters stop mode if the STOP instruction is executed in active mode when bit 3 of timer mode register A (TMA: $008) is set to 0 (TMA3 = 0) (figure 37). Stop mode is terminated by a RESET input or a STOPC input as shown in figure 13. RESET or STOPC must be applied for at least one tRC to stabilize oscillation (refer to the AC Characteristics section). When the MCU restarts after stop mode is cancelled, all RAM contents before entering stop mode are retained, 30 , HD404369 Series but the accuracy of the contents of the accumulator, B register, W register, X/SPX register, Y/SPY register, carry flag, and serial data register cannot be guaranteed. Watch Mode: In watch mode, the clock function (timer A) using the X1 and X2 oscillator operates, but other function operations stop. Therefore, the power dissipation in this mode is the second least to stop mode, and this mode is convenient when only clock display is used. In this mode, the OSC 1 and OSC2 oscillator stops, but the X1 and X2 oscillator operates. The MCU enters watch mode if the STOP instruction is executed in active mode when TMA3 = 1, or if the STOP or SBY instruction is executed in subactive mode. Watch mode is terminated by a RESET input or a timer-A/INT0 interrupt request. For details of RESET input, refer to the Stop Mode section. When terminated by a timer-A/INT0 interrupt request, the MCU enters active mode if LSON = 0, or subactive mode if LSON = 1. After an interrupt request is generated, the time required to enter active mode is tRC for a timer A interrupt, and TX (where T + tRC < TX < 2T + tRC) for an INT0 interrupt, as shown in figures 14 and 15. Operation during mode transition is the same as that at standby mode cancellation (figure 12). Stop mode Oscillator Internal clock RESET or STOPC tres STOP instruction execution tres ≥ tRC (stabilization period) Figure 13 Timing of Stop Mode Cancellation Subactive Mode: The OSC1 and OSC2 oscillator stops and the MCU operates with a clock generated by the X1 and X2 oscillator. In this mode, functions except the A/D conversion operate. However, because the operating clock is slow, the power dissipation becomes low, next to watch mode. The CPU instruction execution speed can be selected as 244 µs or 122 µs by setting bit 2 (SSR12) of the system clock select register 1 (SSR1: $027). Note that the SSR12 value must be changed in active mode. If the value is changed in subactive mode, the MCU may malfunction. When the STOP or SBY instruction is executed in subactive mode, the MCU enters either watch or active mode, depending on the statuses of the low speed on flag (LSON: $020, bit 0) and the direct transfer on flag (DTON: $020, bit 3). Interrupt Frame: In watch and subactive modes, øCLK is applied to timer A and the INT0 circuit. Prescaler W and timer A operate as the time-base and generate the timing clock for the interrupt frame. Three interrupt frame lengths (T) can be selected by setting the miscellaneous register (MIS: $00C) (figure 15). In watch and subactive modes, the timer-A/INT0 interrupt is generated synchronously with the interrupt frame. The interrupt request is generated synchronously with the interrupt strobe timing except during transition to active mode. The falling edge of the INT0 signal is input asynchronously with the interrupt 31 HD404369 Series frame timing, but it is regarded as input synchronously with the second interrupt strobe clock after the falling edge. An overflow and interrupt request in timer A is generated synchronously with the interrupt strobe timing. Oscillation stabilization period Active mode Watch mode Active mode Interrupt strobe INT0 Interrupt request generation T (During the transition from watch mode to active mode only) T tRC TX T: Interrupt frame length t RC : Oscillation stabilization period T + tRC ≤ TX ≤ 2T + tRC Figure 14 Interrupt Frame Direct Transition from Subactive Mode to Active Mode: Available by controlling the direct transfer on flag (DTON: $020, bit 3) and the low speed on flag (LSON: $020, bit 0). The procedures are described below: • Set LSON to 0 and DTON to 1 in subactive mode. • Execute the STOP or SBY instruction. • The MCU automatically enters active mode from subactive mode after waiting for the MCU internal processing time and oscillation stabilization time (figure 16). Notes: 1. The DTON flag ($020, bit 3) can be set only in subactive mode. It is always reset in active mode. 2. The transition time (TD) from subactive mode to active mode: tRC < TD < T + tRC 32 HD404369 Series Miscellaneous register (MIS: $00C) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W MIS3 MIS2 MIS1 MIS0 Bit name MIS3 MIS2 Buffer control. Refer to figure 34. MIS1 MIS0 0 0 T*1 tRC * 1 Oscillation Circuit Conditions 0.24414 ms 0.12207 ms 0.24414 External clock input ms* 2 0 1 15.625 ms 7.8125 ms Ceramic oscillator 1 0 125 ms 62.5 ms Crystal oscillator 1 1 Not used — Notes: 1. The values of T and tRC are applied when a 32.768-kHz crystal oscillator is used. 2. The value is applied only when direct transfer operation is used. Figure 15 Miscellaneous Register (MIS) STOP/SBY instruction execution Subactive mode MCU internal processing period Oscillation stabilization time Active mode (Set LSON = 0, DTON = 1) Interrupt strobe Direct transfer completion timing t RC T TD T: tRC: tD: Interrupt frame length Oscillation stabilization period Transition time Figure 16 Direct Transition Timing Stop Mode Cancellation by STOPC: The MCU enters active mode from stop mode by inputting STOPC as well as by R ESET. In either case, the MCU starts instruction execution from the starting address (address 0) of the program. However, the value of the RAM enable flag (RAME: $021, bit 3) differs between cancellation by STOPC and by R ESET. When stop mode is cancelled by R ESET, RAME = 0; when cancelled by STOPC, RAME = 1. RESET can cancel all modes, but STOPC is valid only in stop mode; STOPC input is ignored in other modes. Therefore, when the program requires to confirm that stop mode has been cancelled by STOPC (for example, when the RAM contents before entering stop mode is 33 HD404369 Series used after transition to active mode), execute the TEST instruction to the RAM enable flag (RAME) at the beginning of the program. MCU Operation Sequence: The MCU operates in the sequence shown in figures 17 to 19. It is reset by an asynchronous RESET input, regardless of its status. The low-power mode operation sequence is shown in figure 19. With the IE flag cleared and an interrupt flag set together with its interrupt mask cleared, if a STOP/SBY instruction is executed, the instruction is cancelled (regarded as an NOP) and the following instruction is executed. Before executing a STOP/SBYinstruction, make sure all interrupt flags are cleared or all interrupts are masked. Power on RESET = 0 ? No Yes RAME = 0 MCU operation cycle Reset MCU Figure 17 MCU Operating Sequence (Power On) 34 HD404369 Series MCU operation cycle IF = 1? No Instruction execution Yes SBY/STOP instruction? Yes No IM = 0 and IE = 1? Yes IE ← 0 Stack ← (PC), (CA), (ST) No Low-power mode operation cycle IF: IM: IE: PC: CA: ST: PC ← Next location PC ← Vector address Interrupt request flag Interrupt mask Interrupt enable flag Program counter Carry flag Status flag Figure 18 MCU Operating Sequence (MCU Operation Cycle) 35 HD404369 Series Low-power mode operation cycle IF = 1 and IM = 0? No Yes Standby/watch mode No IF = 1 and IM = 0? Yes Stop mode No STOPC = 0? Yes Hardware NOP execution Hardware NOP execution RAME = 1 PC ← Next Iocation PC ← Next Iocation Reset MCU Instruction execution MCU operation cycle For IF and IM operation, refer to figure 12. Figure 19 MCU Operating Sequence (Low-Power Mode Operation) Note: When the MCU is in watch mode or subactive mode, if the high level period before the falling edge of INT0 is shorter than the interrupt frame, INT0 is not detected. Also, if the low level period after the falling edge of INT0 is shorter than the interrupt frame, INT0 is not detected. Edge detection is shown in figure 20. The level of the INT0 signal is sampled by a sampling clock. When this sampled value changes to low from high, a falling edge is detected. In figure 21, the level of the INT0 signal is sampled by an interrupt frame. In (a) the sampled value is low at point A, and also low at point B. Therefore, a falling edge is not detected. In (b), the sampled value is high at point A, and also high at point B. A falling edge is not detected in this case either. When the MCU is in watch mode or subactive mode, keep the high level and low level period of INT0 longer than the interrupt frame 36 HD404369 Series INT0 Sampling High Low Low Figure 20 Edge Detection INT0 INT0 Interrupt frame Interrupt frame A: Low B: Low (a) High level period A: High B: High (b) Low level period Figure 21 Sampling Example 37 HD404369 Series Oscillator Circuit A block diagram of the clock generation circuit is shown in figure 22. As shown in table 20, a ceramic oscillator or crystal oscillator can be connected to OSC1 and OSC2, and a 32.768-kHz oscillator can be connected to X1 and X2. The system oscillator can also be operated by an external clock. Registers for Oscillator Circuit Operation System Clock Selection Register 1 (SSR1: $027): Four bit write-only register which sets the subsystem clock frequency (fSUB) division ratio, and sets the subsystem clock oscillation in stop mode. Bit 1 (SSR11) of system clock select register 1 must be set according to the frequency of the oscillator connected to OSC1 and OSC2 (figure 23). Bit 1 (SSR11) and bit 2 (SSR12) are initialized to 0 on reset and in stop mode. Bit 3 (SSR13) is initialized to 0 only on reset. LSON OSC2 OSC1 System fOSC 1/4, 1/8, 1/16 or oscillator 1/32 division circuit*1 fX X1 Subsystem oscillator fcyc tcyc Timing generator circuit øCPU CPU with ROM, RAM, registers, flags, and I/O øPER Peripheral function interrupt System clock selection fSUB 1/8 or 1/4 Timing division t subcyc generator circuit*2 circuit TMA3 X2 1/8 division circuit fW tWcyc Timing generator circuit Time-base clock øCLK selection Time-base interrupt Notes: 1. 1/4, 1/8, 1/16 or 1/32 division ratio can be selected by setting bits 0 and 1 of system clock select register 2 (SSR2: $028). 2. 1/8 or 1/4 division ratio can be selected by setting bit 2 of system clock select register 1 (SSR1: $027). Figure 22 Clock Generation Circuit 38 HD404369 Series System clock selection register 1 (SSR1: $027) Bit 3 2 1 0 Initial value 0 0 0 — Read/Write W W W Bit name *1 SSR13 SSR12 — *2 SSR11 Not used SSR11 System Clock Selection 0 0.4 to 1.0 MHz 1 1.6 to 5.0 MHz (HD404369 Series) 1.6 to 8.5 MHz (HD40A4369 Series) SSR12 0 fSUB = fX/8 1 fSUB = fX/4 SSR13 Notes: 1. 2. 32-kHz Oscillation Division Ratio Selection 32-kHz Oscillation Stop 0 Oscillation operates in stop mode 1 Oscillation stops in stop mode SSR13 will only be cleared to 0 by a RESET input. A STOPC input during stop mode will not clear SSR13. Also note that SSR13 will not be cleared upon transition to stop mode. If fOSC = 0.4 to 1.0 MHz, SSR11 must be set 0; if fOSC = 1.6 to 8.5 MHz, SSR11 must be set to 1. Do not use f OSC = 1.0 to 1.6 MHz with 32-kHz oscillation. Figure 23 System Clock Selection Register 1 (SSR1) System Clock Selection Register 2 (SSR2: $028): Four bit write-only register which is used to select the system clock divisor (figure 24). The division ratio of the system clock can be selected as 1/4, 1/8, 1/16, or 1/32 by setting bits 0 and 1 (SSR20, SSR21) of system clock select register 2 (SSR2). The values of SSR20 and SSR21 are valid after the MCU enters watch mode. The system clock must be stopped when the division ratio is to be changed. There are two methods for changing the system clock divisor, as follows. • In active mode, set the divisor by writing to SSR20 and SSR21. At this point, the prior divisor setting will remain in effect. Now, switch to watch mode, and then return to active mode. When active mode resumes, the system clock divisor will have switched to the new value. • In subactive mode, set the divisor by writing to SSR20 and SSR21. Then return to active mode through watch mode. When active mode resumes, the system clock divisor will have switched to the new value. (The change will also take effect for direct transition to active mode.) 39 HD404369 Series SSR2 is initialized to $0 on reset or in stop mode. Notes on Usage If the system clock select register 1 (SSR1: $027) setting does not match the oscillator frequency, the subsystem using the 32.768-kHz oscillation will malfunction. System clock selection register 2 (SSR2: $028) Bit 3 2 1 0 Initial value — — 0 0 Read/Write — — W W Bit name Not used Not used SSR21 SSR20 SSR21 SSR20 0 0 1/4 division 0 1 1/8 division 1 0 1/16 division 1 1 1/32 division System Clock Division Ratio Figure 24 System Clock Selection Register 2 (SSR2) 40 HD404369 Series Table 20 Oscillator Circuit Examples Circut Configuration External clock operation Ceramic oscillator (OSC1, OSC 2) Circut Constants External oscillator OSC 1 Open OSC 2 Ceramic oscillator: CSA4.00MG (Murata) C1 Rf = 1 MΩ ±20% OSC1 Ceramic C1 = C2 = 30 pF ±20% Rf OSC2 C2 GND Crystal oscillator (OSC1, OSC 2) Rf = 1 MΩ ±20% C1 C1 = C2 = 10 to 22 pF ±20% OSC1 Crystal Crystal: Equivalent to circuit shown below Rf C0 = 7 pF max. OSC2 RS = 100 Ω max. C2 GND L CS RS OSC1 OSC2 C0 C1 Crystal oscillator (X1, X2) Crystal: 32.768 kHz: MX38T X1 (Nippon Denpa) C1 = C2 = 20 pF ±20% Crystal RS = 14 kΩ X2 C0 = 1.5 pF C2 GND L CS RS X1 X2 C0 Notes: 1. Since the circuit constants change depending on the crystal or ceramic oscillator and stray capacitance of the board, the user should consult with the crystal or ceramic oscillator manufacturer to determine the circuit parameters. 2. Wiring among OSC1, OSC 2, X1, X2 and elements should be as short as possible, and must not cross other wiring (see figure 25). 3. When a 32.768-kHz crystal oscillator is not used, fix pin X1 to GND and leave pin X2 open. 41 HD404369 Series GND RESET OSC1 OSC2 GND X1 X2 AVSS Figure 25 Typical Layout of Crystal and Ceramic Oscillators 42 HD404369 Series Input/Output The MCU has 53 input/output pins (D0–D13, R0–R9) and an input pin (RA 1). The features are described below. • Eight pins (R1–R2) are high-current (15 mA max) input/output with intermediate voltage NMOS open drain pins. • The D0–D4, R0, R3–R5 input/output pins are multiplexed with peripheral function pins such as for the timers or serial interface. For these pins, the peripheral function setting is done prior to the D or R port setting. Therefore, when a peripheral function is selected for a pin, the pin function and input/output selection are automatically switched according to the setting. • Input or output selection for input/output pins and port or peripheral function selection for multiplexed pins are set by software. • Peripheral function output pins are CMOS output pins. Only the R02/SO pin can be set to NMOS opendrain output by software. • In stop mode, the MCU is reset, and therefore peripheral function selection is cancelled. Input/output pins are in high-impedance state. • Each input/output pin except for R1 and R2 has a built-in pull-up MOS, which can be individually turned on or off by software. I/O buffer configuration is shown in figure 26, programmable I/O circuits are listed in table 21, and I/O pin circuit types are shown in table 22. 43 HD404369 Series Table 21 Programmable I/O Circuits MIS3 (bit 3 of MIS) 0 DCD, DCR 0 PDR 0 1 0 1 0 1 0 1 PMOS — — — On — — — On NMOS — — On — — — On — — — — — — On — On CMOS buffer Pull-up MOS 1 1 0 1 Note: — indicates off status. HLT Pull-up control signal VCC Pull-up MOS MIS3 VCC Buffer control signal DCD, DCR Output data PDR Input data Input control signal Figure 26 I/O Buffer Configuration 44 HD404369 Series Table 22 Circuit Configuration of I/O Pins I/O Pin Type Circuit Input/output pins Pins VCC Pull-up control signal Buffer control signal VCC HLT D0–D 13 , MIS3 R0 0, R0 1, R0 3 DCD, DCR Output data R3 0–R9 3 PDR Input data Input control signal VCC HLT VCC Pull-up control signal Buffer control signal Output data R0 2 MIS3 DCR MIS2 PDR Input data Input control signal HLT R1 0–R2 3 DCR Output data PDR Input data Input control signal Input pins Input data RA 1 Input control signal Notes on next page. 45 HD404369 Series I/O Pin Type Circuit Pins Peripheral Input/output function pins pins VCC HLT VCC Pull-up control signal MIS3 Output data Input data Output pins VCC SCK SCK HLT VCC Pull-up control signal Output data MIS2 SO HLT VCC Pull-up control signal Output data Input pins VCC Input data TOC, BUZZ MIS3 TOC, BUZZ HLT SI, MIS3 PDR INT0, INT1, SI, INT0, INT1, EVNB, STOPC STOPC HLT VCC SO MIS3 PMOS control signal VCC SCK EVNB, AN 0–AN 11 MIS3 PDR A/D input Input control signal Notes: 1. In stop mode, the MCU is reset and the peripheral function selection is cancelled. The HLT signal goes low, and input/output pins enter the high-impedance state. 2. The HLT signal is 1 in active, standby, watch, and subactive modes. 46 HD404369 Series Evaluation Chip Set and ZTAT/Mask ROM Product Differences As shown in figure 27, the NMOS intermediate-voltage open drain pin circuit in the evaluation chip set differs from that used in the ZTAT microcomputer and built-in mask ROM microcomputer products. Please note that although these outputs in the ZTAT microcomputer and built-in mask ROM microcomputer products can be set to high impedance by the combinations shown in table 23, these outputs cannot be set to high impedance in the evaluation chip set. Table 23 Program Control of High Impedance States Register Set Value DCR 0 1 PDR * 1 Notes: * An asterisk indicates that the value may be either 0 or 1 and has no influence on circuit operation. This applies to the ZTAT and built-in mask ROM microcomputer NMOS open drain pins. HLT VCC MIS3 VCC DCR PDR CPU input Input control signal (a) Evaluation Chip Set Circuit Structure HLT DCR PDR CPU input Input control signal (b) ZTAT and Built-In Mask ROM Microcomputer Circuit Structure Figure 27 NMOS Intermediate-Voltage Open Drain Pin Circuits 47 HD404369 Series D Port (D 0–D13): Consist of 14 input/output pins addressed by one bit. Pins D0–D 13 are set by the SED and SEDD instructions, and reset by the RED and REDD instructions. Output data is stored in the port data register (PDR) for each pin. All pins D0–D13 are tested by the TD and TDD instructions. The on/off statuses of the output buffers are controlled by D-port data control registers (DCD0–DCD3: $02C–$02F) that are mapped to memory addresses (figure 28). Pins D0–D2, D4 are multiplexed with peripheral function pins INT0, INT 1, EVNB, and STOPC, respectively. The peripheral function modes of these pins are selected by bits 0–3 (PMRB0– PMRB3) of port mode register B (PMRB: $024) (figure 29). Pin D3 is multiplexed with peripheral function pin BUZZ. The peripheral function mode of this pin is selected by bit 3 (PMRA3) of port mode register A (PMRA: $004) (figure 30). R Ports (R0 0–R93): 39 input/output pins addressed in 4-bit units. Data is input to these ports by the LAR and LBR instructions, and output from them by the LRA and LRB instructions. Output data is stored in the port data register (PDR) for each pin. The on/off statuses of the output buffers of the R ports are controlled by R-port data control registers (DCR0–DCR9: $030–$039) that are mapped to memory addresses (figure 28). Pin R0 0 is multiplexed with peripheral function pin SCK. The peripheral function mode of this pin is selected by bit 3 (SMR3) of serial mode register (SMR: $005) (figure 31). Pins R01–R0 3 are multiplexed with peripheral pins SI, SO and TOC, respectively. The peripheral function modes of these pins are selected by bits 0–2 (PMRA0–PMRA2) of port mode register A (PMRA: $004), as shown in figure 30. Port R3 is multiplexed with peripheral function pins AN 0–AN 3, respectively. The peripheral function modes of these pins can be selected by individual pins, by setting A/D mode register 1 (AMR1: $019) (figure 32). Ports R4 and R5 are multiplexed with peripheral function pins AN4–AN 11, respectively. The peripheral function modes of these pins can be selected in 4-pin units by setting bits 1 and 2 (AMR21, AMR22) of A/D mode register 2 (AMR2: $01A) (figure 33). Pull-Up MOS Transistor Control: A program-controlled pull-up MOS transistor is provided for each input/output pin. The on/off status of all these transistors is controlled by bit 3 (MIS3) of the miscellaneous register (MIS: $00C), and the on/off status of an individual transistor can also be controlled by the port data register (PDR) of the corresponding pin—enabling on/off control of that pin alone (table 21 and figure 34). The on/off status of each transistor and the peripheral function mode of each pin can be set independently. How to Deal with Unused I/O Pins: I/O pins that are not needed by the user system (floating) must be connected to V CC to prevent LSI malfunctions due to noise. These pins must either be pulled up to V CC by their pull-up MOS transistors or by resistors of about 100 kΩ. 48 HD404369 Series Data control register (DCD0 to 3: $02C to $02F) (DCR0 to 9: $030 to $039) DCD0 to DCD3, DCR0 to DCR9 Bit 3 2 0 1 Initial value 0 0 0 0 Read/Write W W W W DCD03– DCD23, DCR03– DCR63, DCR83– DCR93 DCD02– DCD22, DCR02– DCR92 DCD01– DCD31, DCR01– DCR91 DCD00– DCD30, DCR00– DCR90 Bit name Bits 0 to 3 CMOS Buffer On/Off Selection 0 Off (high-impedance) 1 On Correspondence between ports and DCD/DCR bits Register Name Bit 3 Bit 2 Bit 1 Bit 0 DCD0 D3 D2 D1 D0 DCD1 D7 D6 D5 D4 DCD2 D11 D10 D9 D8 DCD3 Not used Not used D13 D12 DCR0 R03 R02 R01 R00 DCR1 R13 R12 R11 R10 DCR2 R23 R22 R21 R20 DCR3 R33 R32 R31 R30 DCR4 R43 R42 R41 R40 DCR5 R53 R52 R51 R50 DCR6 R63 R62 R61 R60 DCR7 Not used R72 R71 R70 DCR8 R83 R82 R81 R80 DCR9 R93 R92 R91 R90 Figure 28 Data Control Registers (DCD, DCR) 49 HD404369 Series Port mode register B (PMRB: $024) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W Bit name PMRB3* PMRB2 PMRB1 PMRB0 PMRB0 PMRB2 D2/EVNB Mode Selection 0 D2 1 EVNB 0 D4 1 STOPC 0 D0 1 INT0 PMRB1 PMRB3 D4/STOPC Mode Selection D0/INT0 Mode Selection D1/INT1 Mode Selection 0 D1 1 INT1 Note: * PMRB3 is reset to 0 only by RESET input. When STOPC is input in stop mode, PMRB3 is not reset but retains its value. Figure 29 Port Mode Register B (PMRB) Port mode register A (PMRA: $004) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W Bit name PMRA3 PMRA2 PMRA1 PMRA0 PMRA0 PMRA2 R03/TOC Mode Selection 0 R03 1 TOC PMRA3 0 D3 1 BUZZ 0 R02 1 SO PMRA1 D3/BUZZ Mode Selection R01/SI Mode Selection 0 R01 1 SI Figure 30 Port Mode Register A (PMRA) 50 R02/SO Mode Selection HD404369 Series Serial mode register (SMR: $005) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W SMR3 SMR2 SMR1 SMR0 Bit name R00/SCK Mode Selection SMR3 0 R00 1 SCK SMR2 SMR1 SMR0 Transmit clock selection. Refer to figure 62 in the serial interface section. Figure 31 Serial Mode Register (SMR) A/D mode register 1 (AMR1: $019) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W AMR13 AMR12 AMR11 AMR10 Bit name AMR10 AMR12 R32/AN2 Mode Selection 0 R32 1 AN2 AMR13 0 R33 1 AN3 0 R30 1 AN0 AMR11 R33/AN3 Mode Selection R30/AN0 Mode Selection R31/AN1 Mode Selection 0 R31 1 AN1 Figure 32 A/D Mode Register 1 (AMR1) 51 HD404369 Series A/D mode register 2 (AMR2: $01A) Bit 3 Initial value — 0 0 0 Read/Write — W W W AMR21 AMR20 Bit name 2 0 1 Not used AMR22 AMR20 AMR22 R5/AN8–AN11 Pin Selection Conversion Time 0 34tcyc 1 67tcyc AMR21 R4/AN4–AN7 Pin Selection 0 R5 0 R4 1 AN8–AN11 1 AN4–AN7 Figure 33 A/D Mode Register 2 (AMR2) Miscellaneous register (MIS: $00C) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write Bit name W W W W MIS3 MIS2 MIS1 MIS0 MIS3 Pull-Up MOS On/Off Selection 0 Pull-up MOS off 1 Pull-up MOS on (refer to table 21) MIS2 CMOS Buffer On/Off Selection for Pin R02/SO 0 PMOS active 1 PMOS off MIS1 tRC selection. Refer to figure 15 in the operation modes section. Figure 34 Miscellaneous Register (MIS) 52 MIS0 HD404369 Series Prescalers The MCU has the following two prescalers, S and W. The prescaler operating conditions are listed in table 24, and the prescaler output supply is shown in figure 35. The timer A–C input clocks except external events and the serial transmit clock except the external clock are selected from the prescaler outputs, depending on corresponding mode registers. Prescaler Operation Prescaler S: 11-bit counter that inputs the system clock signal. After being reset to $000 by MCU reset, prescaler S divides the system clock. Prescaler S keeps counting, except in watch and subactive modes and at MCU reset. Prescaler W: Five-bit counter that inputs the X1 input clock signal (32-kHz crystal oscillation) divided by eight. After being reset to $00 by MCU reset, prescaler W divides the input clock. Prescaler W can be reset by software. Table 24 Prescaler Operating Conditions Prescaler Input Clock Reset Conditions Stop Conditions Prescaler S System clock (in active and standby mode), subsystem clock (in subactive mode) MCU reset MCU reset, stop mode, watch mode Prescaler W 32-kHz crystal oscillation MCU reset, software MCU reset, stop mode Subsystem clock fX/8 Prescaler W Timer A Timer B fX/4 or fX/8 Timer C System clock Clock selector Prescaler S Serial Alarm output circuit Figure 35 Prescaler Output Supply 53 HD404369 Series Timers The MCU has four timer/counters (A to C). • Timer A: Free-running timer • Timer B: Multifunction timer • Timer C: Multifunction timer Timer A is an 8-bit free-running timer. Timers B and C are 8-bit multifunction timers, whose functions are listed in table 25. The operating modes are selected by software. Timer A Timer A Functions: Timer A has the following functions. • Free-running timer • Clock time-base The block diagram of timer A is shown in figure 36. Timer A Operations: • Free-running timer operation: The input clock for timer A is selected by timer mode register A (TMA: $008). Timer A is reset to $00 by MCU reset and incremented at each input clock. If an input clock is applied to timer A after it has reached $FF, an overflow is generated, and timer A is reset to $00. The overflow sets the timer A interrupt request flag (IFTA: $001, bit 2). Timer A continues to be incremented after reset to $00, and therefore it generates regular interrupts every 256 clocks. • Clock time-base operation: Timer A is used as a clock time-base by setting bit 3 (TMA3) of timer mode register A (TMA: $008) to 1. The prescaler W output is applied to timer A, and timer A generates interrupts at the correct timing based on the 32.768-kHz crystal oscillation. In this case, prescaler W and timer A can be reset to $00 by software. Registers for Timer A Operation: Timer A operating modes are set by the following registers. • Timer mode register A (TMA: $008): Four-bit write-only register that selects timer A’s operating mode and input clock source as shown in figure 37. 54 HD404369 Series Table 25 Timer Functions Functions Clock source Timer functions Timer output Timer A Timer B Timer C Prescaler S Available Available Available Prescaler W Available — — External event — Available — Free-running Available Available Available Time-base Available — — Event counter — Available — Reload — Available Available Watchdog — — Available Input capture — Available — PWM — — Available Note: — implies not available. 1/4 fW 1/2 tWcyc 2 fW Timer A interrupt request flag (IFTA) Prescaler W (PSW) ÷2 ÷8 ÷ 16 ÷ 32 32.768-kHz oscillator 1/2 tWcyc Clock Timer counter A (TCA) Overflow System clock ø PER ÷2 ÷4 ÷8 ÷ 32 ÷ 128 ÷ 512 ÷ 1024 ÷ 2048 Selector Internal data bus Selector Selector Prescaler S (PSS) 3 Timer mode register A (TMA) Figure 36 Timer A Block Diagram 55 HD404369 Series Timer mode register A (TMA: $008) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W TMA3 TMA2 TMA1 TMA0 TMA3 TMA2 TMA1 TMA0 0 0 0 0 PSS 2048tcyc 1 PSS 1024tcyc 0 PSS 512tcyc 1 PSS 128tcyc 0 PSS 32tcyc 1 PSS 8tcyc 0 PSS 4tcyc 1 PSS 2tcyc 0 PSW 32tWcyc 1 PSW 16tWcyc 0 PSW 8tWcyc 1 PSW 2tWcyc 0 PSW 1/2tWcyc 1 Inhibited Bit name 1 1 0 1 1 0 0 1 1 0 1 Don't care Source Input Clock Prescaler Frequency Operating Mode Timer A mode Time-base mode PSW and TCA reset Notes: 1. tWcyc = 244.14 µs (when a 32.768-kHz crystal oscillator is used) 2. Timer counter overflow output period (seconds) = input clock period (seconds) × 256. 3. The division ratio must not be modified during time-base mode operation, otherwise an overflow cycle error will occur. Figure 37 Timer Mode Register A (TMA) 56 HD404369 Series Timer B Timer B Functions: Timer B has the following functions. • Free-running/reload timer • External event counter • Input capture timer The block diagram for each operation mode of timer B is shown in figures 38 and 39. Timer B Operations: • Free-running/reload timer operation: The free-running/reload operation, input clock source, and prescaler division ratio are selected by timer mode register B1 (TMB1: $009). Timer B is initialized to the value set in timer write register B (TWBL: $00A, TWBU: $00B) by software and incremented by one at each clock input. If an input clock is applied to timer B after it has reached $FF, an overflow is generated. In this case, if the reload timer function is enabled, timer B is initialized to its initial value set in timer write register B; if the free-running timer function is enabled, the timer is initialized to $00 and then incremented again. The overflow sets the timer B interrupt request flag (IFTB: $002, bit 0). IFTB is reset by software or MCU reset. Refer to figure 3 and table 1 for details. • External event counter operation: Timer B is used as an external event counter by selecting the external event input as an input clock source. In this case, pin D2/EVNB must be set to EVNB by port mode register B (PMRB: $024). Either falling or rising edge, or both falling and rising edges of input signals can be selected as the external event detection edge by timer mode register 2 (TMB2: $026). When both rising and falling edges detection is selected, the time between the falling edge and rising edge of input signals must be 2tcyc or longer. Timer B is incremented by one at each detection edge selected by timer mode register 2 (TMB2: $026). The other operation is basically the same as the free-running/reload timer operation. • Input capture timer operation: The input capture timer counts the clock cycles between trigger edges input to pin EVNB. Either falling or rising edge, or both falling and rising edges of input signals can be selected as the trigger input edge by timer mode register 2 (TMB2: $026). When a trigger edge is input to EVNB, the count of timer B is written to timer read register B (TRBL: $00A, TRBU: $00B), and the timer B interrupt request flag (IFTB: $002, bit 0) and the input capture status flag (ICSF: $021, bit 0) are set. Timer B is reset to $00, and then incremented again. While ICSF is set, if a trigger input edge is applied to timer B, or if timer B generates an overflow, the input capture error flag (ICEF: $021, bit 1) is set. ICSF and ICEF are reset to 0 by MCU reset or by writing 0. 57 HD404369 Series Interrupt request flag of timer B (IFTB) Timer read register B upper (TRBU) Timer read register B lower (TRBL) Free-running timer control signal Timer write register B lower (TWBL) ÷2 ÷4 ÷8 ÷32 ÷128 ÷512 ÷2048 Edge detector øPER 2 Overflow Timer write register B upper (TWBU) Selector EVNB System clock Timer counter B (TCB) 3 Prescaler S (PSS) Timer mode register B1 (TMB1) Edge detection control signal Timer mode register B2 (TMB2) Figure 38 Timer B Free-Running and Reload Operation Block Diagram 58 Internal data bus Clock HD404369 Series Input capture status flag (ICSF) Interrupt request flag of timer B (IFTB) Input capture error flag (ICEF) Error controller Timer read register B upper (TRBU) Timer read register B lower (TRBL) Read signal Edge detector Clock Timer counter B (TCB) Overflow Input capture timer control signal Selector 3 ÷2 ÷4 ÷8 ÷32 ÷128 ÷512 ÷2048 System clock øPER 2 Internal data bus EVNB Timer mode register B1 (TMB1) Prescaler S (PSS) Edge detection control signal Timer mode register B2 (TMB2) Figure 39 Timer B Input Capture Operation Block Diagram Registers for Timer B Operation: By using the following registers, timer B operation modes are selected and the timer B count is read and written. Timer mode register B1 (TMB1: $009) Timer mode register B2 (TMB2: $026) Timer write register B (TWBL: $00A, TWBU: $00B) Timer read register B (TRBL: $00A, TRBU: $00B) Port mode register B (PMRB: $024) 59 HD404369 Series • Timer mode register B1 (TMB1: $009): Four-bit write-only register that selects the free-running/reload timer function, input clock source, and the prescaler division ratio as shown in figure 40. It is reset to $0 by MCU reset. Writing to this register is valid from the second instruction execution cycle after the execution of the previous timer mode register B1 write instruction. Setting timer B’s initialization by writing to timer write register B (TWBL: $00A, TWBU: $00B) must be done after a mode change becomes valid. When selecting the input capture timer operation, select the internal clock as the input clock source. Timer mode register B1 (TMB1: $009) Bit 3 2 0 1 Initial value 0 0 0 0 Read/Write W W W W TMB13 TMB12 TMB11 TMB10 Bit name TMB13 Free-Running/Reload Timer Selection 0 Free-running timer 1 Reload timer Input Clock Period and Input Clock Source TMB12 TMB11 TMB10 0 0 0 2048tcyc 1 512tcyc 0 128tcyc 1 32tcyc 0 8tcyc 1 4tcyc 0 2tcyc 1 D2/EVNB (external event input) 1 1 0 1 Figure 40 Timer Mode Register B1 (TMB1) • Timer mode register B2 (TMB2: $026): Three-bit write-only register that selects the detection edge of signals input to pin EVNB and input capture operation as shown in figure 41. It is reset to $0 by MCU reset. • Timer write register B (TWBL: $00A, TWBU: $00B): Write-only register consisting of the lower digit (TWBL) and the upper digit (TWBU). The lower digit is reset to $0 by MCU reset, but the upper digit value is invalid (figures 42 and 43). Timer B is initialized by writing to timer write register B (TWBL: $00A, TWBU: $00B). In this case, the lower digit (TWBL) must be written to first, but writing only to the lower digit does not change the timer B value. Timer B is initialized to the value in timer write register B at the same time the upper digit (TWBU) is written to. When timer write register B is written to again and if the lower digit value needs no change, writing only to the upper digit initializes timer B. 60 HD404369 Series • Timer read register B (TRBL: $00A, TRBU: $00B): Read-only register consisting of the lower digit (TRBL) and the upper digit (TRBU) that holds the count of the timer B upper digit (figures 44 and 45). The upper digit (TRBU) must be read first. At this time, the count of the timer B upper digit is obtained, and the count of the timer B lower digit is latched to the lower digit (TRBL). After this, by reading TRBL, the count of timer B when TRBU is read can be obtained. When the input capture timer operation is selected and if the count of timer B is read after a trigger is input, either the lower or upper digit can be read first. • Port mode register B (PMRB: $024): Write-only register that selects D2/EVNB pin function as shown in figure 46. It is reset to $0 by MCU reset. Timer mode register B2 (TMB2: $026) Bit 3 2 1 0 Initial value — 0 0 0 — W Read/Write Bit name Not used TMB22 W W TMB21 TMB20 TMB21 TMB20 0 0 No detection 1 Falling edge detection 0 Rising edge detection 1 Rising and falling edge detection 1 EVNB Edge Detection Selection Free-Running/Reload and Input Capture Selection TMB22 0 Free-running/reload 1 Input capture Figure 41 Timer Mode Register B2 (TMB2) Timer write register B (lower digit) (TWBL: $00A) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W TWBL3 TWBL2 TWBL1 TWBL0 Bit name Figure 42 Timer Write Register B Lower Digit (TWBL) 61 HD404369 Series Timer write register B (upper digit) (TWBU: $00B) Bit Initial value Read/Write Bit name 3 2 1 0 Undefined Undefined Undefined Undefined W W W W TWBU3 TWBU2 TWBU1 TWBU0 Figure 43 Timer Write Register B Upper Digit (TWBU) Timer read register B (lower digit) (TRBL: $00A) Bit Initial value Read/Write Bit name 3 2 1 0 Undefined Undefined Undefined Undefined R R R R TRBL3 TRBL2 TRBL1 TRBL0 Figure 44 Timer Read Register B Lower Digit (TRBL) Timer read register B (upper digit) (TRBU: $00B) Bit Initial value Read/Write Bit name 3 2 1 0 Undefined Undefined Undefined Undefined R R R R TRBU3 TRBU2 TRBU1 TRBU0 Figure 45 Timer Read Register B Upper Digit (TRBU) 62 HD404369 Series Port mode register B (PMRB: $024) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W Bit name PMRB3* PMRB2 PMRB1 PMRB0 PMRB0 PMRB2 D2/EVNB Mode Selection 0 D2 1 EVNB 0 D4 1 STOPC 0 D0 1 INT0 PMRB1 PMRB3 D4/STOPC Mode Selection D0/INT0 Mode Selection D1/INT1 Mode Selection 0 D1 1 INT1 Note: * PMRB3 is reset to 0 only by RESET input. When STOPC is input in stop mode, PMRB3 is not reset but retains its value. Figure 46 Port Mode Register B (PMRB) 63 HD404369 Series Timer C Timer C Functions: Timer C has the following functions. • Free-running/reload timer • Watchdog timer • Timer output operation (PWM output) The block diagram of timer C is shown in figure 47. System reset signal Watchdog on flag (WDON) Interrupt request flag of timer C (IFTC) Watchdog timer controller Timer read register C upper (TRCU) TOC Timer output control logic Timer read register C lower (TRCL) Clock Timer output control signal ÷2 ÷4 ÷8 ÷32 ÷128 ÷512 ÷1024 ÷2048 Selector System clock øPER Overflow Internal data bus Timer counter C (TCC) Timer write register C upper (TWCU) Free-running timer control signal Timer write register C lower (TWCL) 3 Prescaler S (PSS) Timer mode register C (TMC) Port mode register A (PMRA) Figure 47 Timer C Block Diagram 64 HD404369 Series Timer C Operations: • Free-running/reload timer operation: The free-running/reload operation, input clock source, and prescaler division ratio are selected by timer mode register C (TMC: $00D). Timer C is initialized to the value set in timer write register C (TWCL: $00E, TWCU: $00F) by software and incremented by one at each clock input. If an input clock is applied to timer C after it has reached $FF, an overflow is generated. In this case, if the reload timer function is enabled, timer C is initialized to its initial value set in timer write register C; if the free-running timer function is enabled, the timer is initialized to $00 and then incremented again. The overflow sets the timer C interrupt request flag (IFTC: $002, bit 2). IFTC is reset by software or MCU reset. Refer to figure 3 and table 1 for details. • Watchdog timer operation: Timer C is used as a watchdog timer for detecting out-of-control program routines by setting the watchdog on flag (WDON: $020, bit 1) to 1. If a program routine runs out of control and an overflow is generated, the MCU is reset. The watchdog timer operation flowchart is shown in figure 48. Program run can be controlled by initializing timer C by software before it reaches $FF. • Timer output operation: The PWM output modes can be selected for timer C by setting port mode register A (PMRA: $004). By selecting the timer output mode, pin R03/TOC is set to TOC. The output from TOC is reset low by MCU reset. PWM output: When PWM output mode is selected, timer C provides the variable-duty pulse output function. The output waveform differs depending on the contents of timer mode register C (TMC: $00D) and timer write register C (TWCL: $00E, TWCU: $00F). The output waveform is shown in figure 49. $FF + 1 Overflow Timer C count value $00 CPU operation Time Normal operation Timer C clear Normal operation Timer C clear Program runaway Reset Normal operation Figure 48 Watchdog Timer Operation Flowchart 65 HD404369 Series T × (N + 1) TMC3 = 0 (free-running timer) T T × 256 TMC3 = 1 (reload timer) T × (256 – N) Notes: T: Input clock period supplied to counter. (The clock source and system clock division ratio are determined by timer mode register C.) N: Value of timer write register C. (When N = 255 ($FF), PWM output is fixed low.) Figure 49 PWM Output Waveform Registers for Timer C Operation: By using the following registers, timer C operation modes are selected and the timer C count is read and written. Timer mode register C (TMC: $00D) Port mode register A (PMRA: $004) Timer write register C (TWCL: $00E, TWCU: $00F) Timer read register C (TRCL: $00E, TRCU: $00F) • Timer mode register C (TMC: $00D): Four-bit write-only register that selects the free-running/reload timer function, input clock source, and the prescaler division ratio as shown in figure 50. It is reset to $0 by MCU reset. Writing to this register is valid from the second instruction execution cycle after the execution of the previous timer mode register C write instruction. Setting timer C’s initialization by writing to timer write register C (TWCL: $00E, TWCU: $00F) must be done after a mode change becomes valid. 66 HD404369 Series Timer mode register C (TMC: $00D) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W TMC3 TMC2 TMC1 TMC0 Bit name TMC3 Free-Running/Reload Timer Selection 0 Free-running timer 1 Reload timer TMC2 TMC1 TMC0 0 0 0 2048tcyc 1 1024tcyc 0 512tcyc 1 128tcyc 0 32tcyc 1 8tcyc 0 4tcyc 1 2tcyc 1 1 0 1 Input Clock Period Figure 50 Timer Mode Register C (TMC) • Port mode register A (PMRA: $004): Write-only register that selects R03/TOC pin function as shown in figure 51. It is reset to $0 by MCU reset. • Timer write register C (TWCL: $00E, TWCU: $00F): Write-only register consisting of the lower digit (TWCL) and the upper digit (TWCU) as shown in figures 52 and 53. The operation of timer write register C is basically the same as that of timer write register B (TWBL: $00A, TWBU: $00B). • Timer read register C (TRCL: $00E, TRCU: $00F): Read-only register consisting of the lower digit (TRCL) and the upper digit (TRCU) that holds the count of the timer C upper digit (figures 54 and 55). The operation of timer read register C is basically the same as that of timer read register B (TRBL: $00A, TRBU: $00B). 67 HD404369 Series Port mode register A (PMRA: $004) Bit 3 2 0 1 Initial value 0 0 0 0 Read/Write W W W W Bit name PMRA3 PMRA2 PMRA1 PMRA0 PMRA0 PMRA2 R03/TOC Mode Selection 0 R03 1 TOC PMRA3 D3 1 BUZZ 0 R02 1 SO PMRA1 D3/BUZZ Mode Selection 0 R02/SO Mode Selection R01/SI Mode Selection 0 R01 1 SI Figure 51 Port Mode Register A (PMRA) Timer write register C (lower digit) (TWCL: $00E) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W TWCL3 TWCL2 TWCL1 TWCL0 Bit name Figure 52 Timer Write Register C Lower Digit (TWCL) Timer write register C (upper digit) (TWCU: $00F) Bit Initial value Read/Write Bit name 3 2 1 0 Undefined Undefined Undefined Undefined W W W W TWCU3 TWCU2 TWCU1 TWCU0 Figure 53 Timer Write Register C Upper Digit (TWCU) 68 HD404369 Series Timer read register C (lower digit) (TRCL: $00E) Bit Initial value Read/Write Bit name 3 2 1 0 Undefined Undefined Undefined Undefined R R R R TRCL3 TRCL2 TRCL1 TRCL0 Figure 54 Timer Read Register C Lower Digit (TRCL) Timer read register C (upper digit) (TRCU: $00F) Bit Initial value Read/Write Bit name 3 2 1 0 Undefined Undefined Undefined Undefined R R R R TRCU3 TRCU2 TRCU1 TRCU0 Figure 55 Timer Read Register C Upper Digit (TRCU) Notes on Use When using the timer output as PWM output, note the following point. From the update of the timer write register until the occurrence of the overflow interrupt, the PWM output differs from the period and duty settings, as shown in table 26. The PWM output should therefore not be used until after the overflow interrupt following the update of the timer write register. After the overflow, the PWM output will have the set period and duty cycle. In this case, the lower digit (TWCL) must be written to first, bit writing only to the lower digit does not change the timer C value. Timer C is changed to the value in timer write register B at the same time the upper digit (TWCU) is written to. 69 HD404369 Series Table 26 PWM Output Following Update of Timer Write Register PWM Output Mode Timer Write Register is Updated during High Timer Write Register is Updated during Low PWM Output PWM Output Timer write register updated to value N Reload T Interrupt request T × (255 – N) T Timer write register updated to value N T T × (255 – N) 70 Interrupt request T HD404369 Series Alarm Output Function The MCU has a built-in pulse output function called BUZZ. The pulse frequency can be selected from the prescaler S’s outputs, and the output frequency depends on the state of port mode register C (PMRC: $025). The duty cycle of the pulse output is fixed at 50%. Port Mode Register C (PMRC: $025): Four-bit write-only register that selects the alarm frequencies as shown in figure 57. It is reset to $0 by MCU reset. BUZZ Alarm output control signal Alarm output controller System clock øPER 2 ÷2048 ÷1024 ÷512 ÷256 Selector Port mode register A (PMRA) Port mode register C (PMRC) Internal data bus Port Mode Register A (PMRA: $004): Four-bit write-only register that selects D3/BUZZ pin function as shown in figure 51. It is reset to $0 by MCU reset. Prescaler S (PSS) Figure 56 Alarm Output Function Block Diagram 71 HD404369 Series Port mode register C (PMRC: $025) Bit 3 2 1 0 Initial value 0 0 Undefined 0 Read/Write W W W W PMRC2 PMRC1 PMRC0 Bit name PMRC3 0 1 PMRC2 PMRC3 System Clock Divisor PMRC0 Serial Clock Division Ratio 0 ÷2048 0 Prescaler output divided by 2 1 ÷1024 1 Prescaler output divided by 4 0 ÷512 1 ÷256 PMRC1 Output Level Control in Idle States 0 Low level 1 High level Figure 57 Port Mode Register C (PMRC) 72 HD404369 Series Serial Interface The serial interface serially transfers and receives 8-bit data, and includes the following features. • Multiple transmit clock sources External clock Internal prescaler output clock System clock • Output level control in idle states Four registers, an octal counter, and a selector are also configured for the serial interface as follows. Serial data register (SRL: $006, SRU: $007) Serial mode register (SMR: $005) Port mode register A (PMRA: $004) Port mode register C (PMRC: $025) Miscellaneous register (MIS: $00C) Octal counter (OC) Selector The block diagram of the serial interface is shown in figure 58. 73 HD404369 Series Octal counter (OC) SO Serial interrupt request flag (IFS) Idle controller SCK I/O controller SI Clock 1/2 Selector 1/2 Transfer control signal Internal data bus Serial data register (SR) Selector ÷2 ÷8 ÷32 ÷128 ÷512 ÷2048 3 System clock øPER Prescaler S (PSS) Serial mode register (SMR) Port mode register C (PMRC) Figure 58 Serial Interface Block Diagram Serial Interface Operation Selecting and Changing the Operating Mode: Table 27 lists the serial interface’s operating modes. To select an operating mode, use one of these combinations of port mode register A (PMRA: $004) and the serial mode register (SMR: $005) settings; to change the operating mode, always initialize the serial interface internally by writing data to the serial mode register. Note that the serial interface is initialized by writing data to the serial mode register. Refer to the following Serial Mode Register section for details. Pin Setting: The R00/SCK pin is controlled by writing data to the serial mode register (SMR: $005). The R0 1/SI and R0 2/SO pins are controlled by writing data to port mode register A (PMRA: $004). Refer to the following Registers for Serial Interface section for details. Transmit Clock Source Setting: The transmit clock source is set by writing data to the serial mode register (SMR: $005) and port mode register C (PMRC: $025). Refer to the following Registers for Serial Interface section for details. Data Setting: Transmit data is set by writing data to the serial data register (SRL: $006, SRU, $007). Receive data is obtained by reading the contents of the serial data register. The serial data is shifted by the transmit clock and is input from or output to an external system. 74 HD404369 Series The output level of the SO pin is invalid until the first data is output after MCU reset, or until the output level control in idle states is performed. Transfer Control: The serial interface is activated by the STS instruction. The octal counter is reset to 000 by this instruction, and it increments at the rising edge of the transmit clock. When the eighth transmit clock signal is input or when serial transmission/receive is discontinued, the octal counter is reset to 000, the serial interrupt request flag (IFS: $003, bit 2) is set, and the transfer stops. When the prescaler output is selected as the transmit clock, the transmit clock frequency is selected as 4tcyc to 8192tcyc by setting bits 0 to 2 (SMR0– SMR2) of serial mode register (SMR: $005) and bit 0 (PMRC0) of port mode register C (PMRC: $025) as listed in table 28. Operating States: The serial interface has the following operating states; transitions between them are shown in figure 59. STS wait state Transmit clock wait state Transfer state Continuous clock output state (only in internal clock mode) • STS wait state: The serial interface enters STS wait state by MCU reset (00, 10 in figure 59). In STS wait state, the serial interface is initialized and the transmit clock is ignored. If the STS instruction is then executed (01, 11), the serial interface enters transmit clock wait state. • Transmit clock wait state: Transmit clock wait state is the period between the STS execution and the falling edge of the first transmit clock. In transmit clock wait state, input of the transmit clock (02, 12) increments the octal counter, shifts the serial data register, and puts the serial interface in transfer state. However, note that if continuous clock output mode is selected in internal clock mode, the serial interface does not enter transfer state but enters continuous clock output state (17). The serial interface enters STS wait state by writing data to the serial mode register (SMR: $005) (04, 14) in transmit clock wait state. • Transfer state: Transfer state is the period between the falling edge of the first clock and the rising edge of the eighth clock. In transfer state, the input of eight clocks or the execution of the STS instruction sets the octal counter to 000, and the serial interface enters another state. When the STS instruction is executed (05, 15), transmit clock wait state is entered. When eight clocks are input, transmit clock wait state is entered (03) in external clock mode, and STS wait state is entered (13) in internal clock mode. In internal clock mode, the transmit clock stops after outputting eight clocks. In transfer state, writing data to the serial mode register (SMR: $005) (06, 16) initializes the serial interface, and STS wait state is entered. If the state changes from transfer to another state, the serial interrupt request flag (IFS: $003, bit 2) is set by the octal counter that is reset to 000. • Continuous clock output state (only in internal clock mode): Continuous clock output state is entered only in internal clock mode. In this state, the serial interface does not transmit/receive data but only outputs the transmit clock from the SCK pin. 75 HD404369 Series When bits 0 and 1 (PMRA0, PMRA1) of port mode register A (PMRA: $004) are 00 in transmit clock wait state and if the transmit clock is input (17), the serial interface enters continuous clock output state. If the serial mode register (SMR: $005) is written to in continuous clock output mode (18), STS wait state is entered. Output Level Control in Idle States: In idle states, that is, STS wait state and transmit clock wait state, the output level of the SO pin can be controlled by setting bit 1 (PMRC1) of port mode register C (PMRC: $025) to 0 or 1. The output level control example is shown in figure 60. Note that the output level cannot be controlled in transfer state. Transmit Clock Error Detection (In External Clock Mode): The serial interface will malfunction if a spurious pulse caused by external noise conflicts with a normal transmit clock during transfer. A transmit clock error of this type can be detected as shown in figure 61. Table 27 Serial Interface Operating Modes SMR PMRA Bit 3 Bit 1 Bit 0 Operating Mode 1 0 0 Continuous clock output mode 1 Transmit mode 0 Receive mode 1 Transmit/receive mode 1 Table 28 Serial Transmit Clock (Prescaler Output) PMRC SMR Bit 0 Bit 2 Bit 1 Bit 0 Prescaler Division Ratio Transmit Clock Frequency 0 0 0 0 ÷ 2048 4096t cyc 1 ÷ 512 1024t cyc 0 ÷ 128 256t cyc 1 ÷ 32 64t cyc 0 ÷8 16t cyc 1 ÷2 4t cyc 0 ÷ 4096 8192t cyc 1 ÷ 1024 2048t cyc 0 ÷ 256 512t cyc 1 ÷ 64 128t cyc 0 ÷ 16 32t cyc 1 ÷4 8t cyc 1 1 1 0 0 0 1 1 76 0 HD404369 Series If more than eight transmit clocks are input in transfer state, at the eighth clock including a spurious pulse by noise, the octal counter reaches 000, the serial interrupt request flag (IFS: $003, bit 2) is set, and transmit clock wait state is entered. At the falling edge of the next normal clock signal, the transfer state is entered. After the transfer completion processing is performed and IFS is reset, writing to the serial mode register (SMR: $005) changes the state from transfer to STS wait. At this time IFS is set again, and therefore the error can be detected. Notes on Use: • Initialization after writing to registers: If port mode register A (PMRA: $004) is written to in transmit clock wait state or in transfer state, the serial interface must be initialized by writing to the serial mode register (SMR: $005) again. • Serial interrupt request flag (IFS: $003, bit 2) set: If the state is changed from transfer to another by writing to the serial mode register (SMR: $005) or executing the STS instruction during the first low pulse of the transmit clock, the serial interrupt request flag is not set. To set the serial interrupt request flag, serial mode register write or STS instruction execution must be programmed to be executed after confirming that the SCK pin is at 1, that is, after executing the input instruction to port R0. External clock mode STS wait state (octal counter = 000, transmit clock disabled) SMR write 04 00 06 01 MCU reset SMR write (IFS ← 1) STS instruction 02 Transmit clock Transmit clock wait state (octal counter = 000) 03 8 transmit clocks Transfer state (octal counter ≠ 000) 05 STS instruction (IFS ← 1) Internal clock mode STS wait state (octal counter = 000, transmit clock disabled) SMR write 18 Continuous clock output state (PMRA 0, 1 = 0, 0) 10 13 SMR write 14 11 STS instruction MCU reset 8 transmit clocks 16 SMR write (IFS← 1) Transmit clock 17 12 Transmit clock Transmit clock wait state (octal counter = 000) Transfer state (octal counter ≠ 000) 15 STS instruction (IFS ← 1) Note: Refer to the Operating States section for the corresponding encircled numbers. Figure 59 Serial Interface State Transitions 77 , HD404369 Series Transmit clock wait state State STS wait state Transmit clock wait state Transfer state STS wait state MCU reset Port selection PMRA write External clock selection SMR write Output level control in idle states Dummy write for state transition Output level control in idle states PMRC write Data write for transmission SRL, SRU write STS instruction SCK pin (input) SO pin Undefined LSB MSB IFS External clock mode Flag reset at transfer completion Transmit clock wait state State STS wait state Transfer state STS wait state MCU reset Port selection PMRA write Internal clock selection SMR write Output level control in idle states PMRC write Output level control in idle states Data write for transmission SRL, SRU write STS instruction SCK pin (output) SO pin Undefined LSB MSB IFS Internal clock mode Flag reset at transfer completion Figure 60 Example of Serial Interface Operation Sequence 78 HD404369 Series Transfer completion (IFS ← 1) Interrupts inhibited IFS ← 0 SMR write IFS = 1 Yes Transmit clock error processing No Normal termination Transmit clock error detection flowchart Transmit clock wait state Transmit clock wait state Transfer state State Transfer state SCK pin (input) Noise 1 2 3 4 5 6 7 8 Transfer state has been entered by the transmit clock error. When SMR is written, IFS is set. SMR write IFS Flag set because octal counter reaches 000 Flag reset at transfer completion Transmit clock error detection procedure Figure 61 Transmit Clock Error Detection Registers for Serial Interface The serial interface operation is selected, and serial data is read and written by the following registers. Serial Mode Register (SMR: $005) Serial Data Register (SRL: $006, SRU: $007) Port Mode Register A (PMRA: $004) Port Mode Register C (PMRC: $025) Miscellaneous Register (MIS: $00C) 79 HD404369 Series Serial Mode Register (SMR: $005): This register has the following functions (figure 62). • • • • R0 0/SCK pin function selection Transmit clock selection Prescaler division ratio selection Serial interface initialization Serial mode register (SMR: $005) is a 4-bit write-only register. It is reset to $0 by MCU reset. A write signal input to serial mode register (SMR: $005) discontinues the input of the transmit clock to the serial data register and octal counter, and the octal counter is reset to 000. Therefore, if a write is performed during data transfer, the serial interrupt request flag (IFS: $003, bit 2) is set. Written data is valid from the second instruction execution cycle after the write operation, so the STS instruction must be executed at least two cycles after that. Serial mode register (SMR: $005) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write Bit name SMR3 W W W W SMR3 SMR2 SMR1 SMR0 R00/SCK Mode Selection 0 R00 1 SCK Clock Source Output Prescaler Refer to table 28 0 Output System clock — 1 Input External clock — SMR1 SMR0 0 0 0 1 1 Prescaler Division Ratio SCK SMR2 0 1 1 0 0 1 1 Figure 62 Serial Mode Register (SMR) 80 HD404369 Series Port Mode Register C (PMRC: $025): This register has the following functions (figure 63). • Prescaler division ratio selection • Output level control in idle states Port mode register C (PMRC: $025) is a 4-bit write-only register. It cannot be written during data transfer. By setting bit 0 (PMRC0) of this register, the prescaler division ratio is selected. Bit 0 (PMRC0) can be reset to 0 by MCU reset. By setting bit 1 (PMRC1), the output level of the SO pin is controlled in idle states. The output level changes at the same time that PMRC1 is written to. Port mode register C (PMRC: $025) Bit 3 2 1 0 Initial value 0 0 Undefined 0 Read/Write Bit name W W W W PMRC3 PMRC2 PMRC1 PMRC0 PMRC0 Alarm output function. Refer to figure 57. Serial Clock Division Ratio 0 Prescaler output divided by 2 1 Prescaler output divided by 4 PMRC1 Output Level Control in Idle States 0 Low level 1 High level Figure 63 Port Mode Register C (PMRC) 81 HD404369 Series Serial Data Register (SRL: $006, SRU: $007): This register has the following functions (figures 64 and 65). • Transmission data write and shift • Receive data shift and read Writing data in this register is output from the SO pin, LSB first, synchronously with the falling edge of the transmit clock; data is input, LSB first, through the SI pin at the rising edge of the transmit clock. Input/output timing is shown in figure 66. Data cannot be read or written during serial data transfer. If a read/write occurs during transfer, the accuracy of the resultant data cannot be guaranteed. Serial data register (lower digit) (SRL: $006) Bit Initial value 1 2 3 0 Undefined Undefined Undefined Undefined Read/Write R/W R/W R/W R/W Bit name SR3 SR2 SR1 SR0 Figure 64 Serial Data Register (SRL) Serial data register (upper digit) (SRU: $007) Bit 1 2 3 Initial value 0 Undefined Undefined Undefined Undefined Read/Write R/W R/W R/W R/W Bit name SR7 SR6 SR5 SR4 Figure 65 Serial Data Register (SRU) Transmit clock 1 Serial output data 2 3 4 5 6 LSB Serial input data latch timing Figure 66 Serial Interface Output Timing 82 7 8 MSB HD404369 Series Port Mode Register A (PMRA: $004): This register has the following functions (figure 67). • R0 1/SI pin function selection • R0 2/SO pin function selection Port mode register A (PMRA: $004) is a 4-bit write-only register, and is reset to $0 by MCU reset. Port mode register A (PMRA: $004) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W Bit name PMRA3 PMRA2 PMRA1 PMRA0 PMRA0 PMRA2 R03/TOC Mode Selection 0 R03 1 TOC PMRA3 0 D3 1 BUZZ 0 R02 1 SO PMRA1 D3/BUZZ Mode Selection R02/SO Mode Selection R01/SI Mode Selection 0 R01 1 SI Figure 67 Port Mode Register A (PMRA) 83 HD404369 Series Miscellaneous Register (MIS: $00C): This register has the following functions (figure 68). • R0 2/SO pin PMOS control Miscellaneous register (MIS: $00C) is a 4-bit write-only register and is reset to $0 by MCU reset. Miscellaneous register (MIS: $00C) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W MIS3 MIS2 MIS1 MIS0 MIS3 Pull-Up MOS On/Off Selection MIS2 CMOS Buffer On/Off Selection for Pin R02/SO 0 Pull-up MOS off 0 PMOS active 1 Pull-up MOS on (refer to table 21) 1 PMOS off Bit name MIS1 tRC selection. Refer to figure 15 in the operation modes section. Figure 68 Miscellaneous Register (MIS) 84 MIS0 HD404369 Series A/D Converter The MCU has a built-in A/D converter that uses a sequential comparison method with a resistor ladder. It can measure twelve analog inputs with 8-bit resolution. The block diagram of the A/D converter is shown in figure 69. 4 A/D mode register 1 (AMR1) A/D interrupt request flag (IFAD) 2 Selector Encoder + Comp – AVCC AVSS D/A A/D controller Control signal for conversion time A/D start flag (ADSF) A/D mode register 2 (AMR2) A/D data register (ADRU, L) Internal data bus 4 AN0 AN1 AN2 AN3 AN4 AN5 AN6 AN7 AN8 AN9 AN10 AN11 A/D channel register (ACR) IAD off flag (IAOF) Operating mode signal (1 in stop, watch, and subactive modes) Figure 69 A/D Converter Block Diagram 85 HD404369 Series Registers for A/D Converter Operation A/D Mode Register 1 (AMR1: $019): Four-bit write-only register which selects digital or analog ports, as shown in figure 70. A/D mode register 1 (AMR1: $019) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W AMR13 AMR12 AMR11 AMR10 Bit name AMR10 AMR12 R32/AN2 Mode Selection 0 R32 1 AN2 AMR13 0 R33 1 AN3 0 R30 1 AN0 AMR11 R33/AN3 Mode Selection R30/AN0 Mode Selection R31/AN1 Mode Selection 0 R31 1 AN1 Figure 70 A/D Mode Register 1 (AMR1) A/D Mode register 2 (AMR2: $01A): Three-bit write-only register which is used to set the A/D conversion period and to select digital or analog ports. Bit 0 of the A/D mode register selects the A/D conversion period, and bits 1 and 2 select ports R4–R5 as pins AN4–AN11 in 4-pin units (figure 71). A/D mode register 2 (AMR2: $01A) Bit 3 2 1 0 Initial value — 0 0 0 — W Read/Write Bit name Not used AMR22 W W AMR21 AMR20 AMR20 AMR22 R5/AN8–AN11 Pin Selection Conversion Time 0 34tcyc 1 67tcyc AMR21 R4/AN4–AN7 Pin Selection 0 R5 0 R4 1 AN8–AN11 1 AN4–AN7 Figure 71 A/D Mode Register 2 (AMR2) 86 HD404369 Series A/D Channel Register (ACR: $016): Four-bit write-only register which indicates analog input pin information, as shown in figure 72. A/D channel register (ACR: $016) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write W W W W ACR3 ACR2 ACR1 ACR0 Bit name ACR3 ACR2 ACR1 ACR0 0 0 0 AN0 1 AN1 0 AN2 1 AN3 0 AN4 1 AN5 0 AN6 1 AN7 0 AN8 1 AN9 1 0 AN10 1 AN11 Don’t care. Don’t care. 0 1 1 0 1 1 0 1 Analog Input Selection 0 Not used Figure 72 A/D Channel Register (ACR) 87 HD404369 Series A/D Start Flag (ADSF: $02C, Bit 2): One-bit flag that initiates A/D conversion when set to 1. At the completion of A/D conversion, the converted data is stored in the A/D data register and the A/D start flag is cleared. Refer to figure 73. A/D start flag (ADSF: $020, bit 2) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write Bit name R/W R/W W R/W DTON ADSF WDON LSON LSON A/D Start Flag (ADSF) 0 A/D conversion completed 1 A/D conversion started Refer to the description of operating modes DTON WDON Refer to the description of operating modes Refer to the description of timers Figure 73 A/D Start Flag (ADSF) IAD Off Flag (IAOF: $021, Bit 2): By setting the IA D off flag to 1, the current flowing through the resistance ladder can be cut off even while operating in standby or active mode, as shown in figure 74. IAD off flag (IAOF: $021, bit 2) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write R/W R/W R/W R/W RAME IAOF ICEF ICSF Bit name ICSF IAD Off Flag (IAOF) 0 IAD current flows 1 IAD current is cut off Refer to the description of timers ICEF RAME Refer to the description of timers Refer to the description of operating modes Figure 74 IAD Off Flag (IAOF) 88 HD404369 Series A/D Data Register (ADRL: $017, ADRU: $018): Eight-bit read-only register consisting of a 4-bit lower digit and 4-bit upper digit. This register is not cleared by reset. After the completion of A/D conversion, the resultant eight-bit data is held in this register until the start of the next conversion (figures 75, 76, and 77). ADRU: $018 3 2 1 ADRL: $017 0 3 2 1 0 MSB LSB Bit 7 Bit 0 Figure 75 A/D Data Registers (ADRU, ADRL) A/D data register (lower digit) (ADRL: $017) Bit 3 2 1 0 Initial value 0 0 0 0 Read/Write R R R R ADRL3 ADRL2 ADRL1 ADRL0 Bit name Figure 76 A/D Data Register Lower Digit (ADRL) A/D data register (upper digit) (ADRU: $018) Bit 3 2 1 0 Initial value 1 0 0 0 Read/Write R R R R ADRU3 ADRU2 Bit name ADRU1 ADRU0 Figure 77 A/D Data Register Upper Digit (ADRU) 89 HD404369 Series Notes on Usage • Use the SEM or SEMD instruction for writing to the A/D start flag (ADSF) • Do not write to the A/D start flag during A/D conversion • Data in the A/D data register during A/D conversion is undefined • Since the operation of the A/D converter is based on the clock from the system oscillator, the A/D converter does not operate in stop, watch, or subactive mode. In addition, to save power while in these modes, all current flowing through the converter’s resistance ladder is cut off. • If the power supply for the A/D converter is to be different from VCC, connect a 0.1-µF bypass capacitor between the AVCC and AVSS pins. (However, this is not necessary when the AVCC pin is directly connected to the VCC pin.) • The contents of the A/D data register are not guaranteed during A/D conversion. To ensure that the A/D converter operates stably, do not execute port output instructions during A/D conversion. • The port data register (PDR) is initialized to 1 by an MCU reset. At this time, if pull-up MOS is selected as active by bit 3 of the miscellaneous register (MIS3), the port will be pulled up to VCC. When using a shared R port/analog input pin as an input pin, clear PDR to 0. Otherwise, if pull-up MOS is selected by MIS3 and PDR is set to 1, a pin selected by A/D mode register 1 or 2 (AMR1 or AMR2) as an analog pin will remain pulled up (figure 78). HLT VCC MIS3 VCC AMR A/D mode register value DCR PDR CPU input Input control signal A/D input ACR A/D channel register value Figure 78 R Port/Analog Multiplexed Pin Circuit 90 HD404369 Series Pin Description in PROM Mode The HD407A4369 is a PROM version of a ZTAT microcomputer. In PROM mode, the MCU stops operating, thus allowing the user to program the on-chip PROM. Pin Number MCU Mode PROM Mode DP-64S FP-64B FP-64A Pin I/O Pin I/O 1 59 57 R6 0 I/O 2 60 58 R6 1 I/O 3 61 59 R6 2 I/O 4 62 60 R6 3 I/O 5 63 61 R7 0 I/O 6 64 62 R7 1 I/O 7 1 63 R7 2 I/O 8 2 64 R0 0/SCK I/O VCC 9 3 1 R0 1/SI I/O VCC 10 4 2 R0 2/SO I/O O1 I/O 11 5 3 R0 3/TOC I/O O2 I/O 12 6 4 TEST I VPP 13 7 5 RESET I RESET 14 8 6 OSC 1 I VCC 15 9 7 OSC 2 O 16 10 8 GND — GND 17 11 9 X1 I GND 18 12 10 X2 O 19 13 11 AVSS — GND 20 14 12 R3 0/AN0 I/O O0 I/O 21 15 13 R3 1/AN1 I/O O1 I/O 22 16 14 R3 2/AN2 I/O O2 I/O 23 17 15 R3 3/AN3 I/O O3 I/O 24 18 16 R4 0/AN4 I/O O4 I/O 25 19 17 R4 1/AN5 I/O M0 I 26 20 18 R4 2/AN6 I/O M1 I 27 21 19 R4 3/AN7 I/O 28 22 20 R5 0/AN8 I/O 29 23 21 R5 1/AN9 I/O 30 24 22 R5 2/AN10 I/O I 91 HD404369 Series Pin Number MCU Mode PROM Mode DP-64S FP-64B FP-64A Pin I/O Pin 31 25 23 R5 3/AN11 I/O 32 26 24 AVCC — VCC 33 27 25 VCC — VCC 34 28 26 D0/INT0 I/O O3 I/O 35 29 27 D1/INT1 I/O O4 I/O 36 30 28 D2/EVNB I/O A1 I 37 31 29 D3/BUZZ I/O A2 I 38 32 30 D4/STOPC I/O 39 33 31 D5 I/O A3 I 40 34 32 D6 I/O A4 I 41 35 33 D7 I/O A9 I 42 36 34 D8 I/O VCC 43 37 35 D9 I/O 44 38 36 D10 I/O 45 39 37 D11 I/O 46 40 38 D12 I/O 47 41 39 D13 I/O 48 42 40 R8 0 I/O CE 49 43 41 R8 1 I/O OE I 50 44 42 R8 2 I/O A13 I 51 45 43 R8 3 I/O A14 I 52 46 44 R9 0 I/O 53 47 45 R9 1 I/O 54 48 46 R9 2 I/O 55 49 47 R9 3 I/O 56 50 48 R1 0 I/O A5 I 57 51 49 R1 1 I/O A6 I 58 52 50 R1 2 I/O A7 I 59 53 51 R1 3 I/O A8 I 60 54 52 R2 0 I/O A0 I 61 55 53 R2 1 I/O A10 I 62 56 54 R2 2 I/O A11 I 63 57 55 R2 3 I/O A12 I 64 58 56 RA 1 I O0 I/O Notes: 1. I/O: Input/output pin; I: Input pin; O: Output pin 2. O0 to O 4 consist of two pins each. Tie each pair together before using them. 92 I/O I HD404369 Series Programming the Built-In PROM The MCU’s built-in PROM is programmed in PROM mode. PROM mode is set by pulling RESET, M0, and M1 low, as shown in figure 79. In PROM mode, the MCU does not operate, but it can be programmed in the same way as any other commercial 27256-type EPROM using a standard PROM programmer and a 100-to-28-pin socket adapter. Recommended PROM programmers and socket adapters are listed in table 29. Since an HMCS400-series instruction is ten bits long, the HMCS400-series MCU has a built-in conversion circuit to enable the use of a general-purpose PROM programmer. This circuit splits each instruction into five lower bits and five upper bits that are read from or written to consecutive addresses. This means that if, for example, 16 kwords of built-in PROM are to be programmed by a general-purpose PROM programmer, a 32-kbyte address space ($0000–$7FFF) must be specified. CE, OE Control signals A14–A0 Address bus O7 O6 O4–O0 O5 O4–O0 O7–O0 Data bus M0 M1 RESET VCC GND VPP HD407A4369 PROM mode pins VCC GND VPP Socket adapter PROM programmer Figure 79 PROM Mode Connections 93 HD404369 Series Table 29 Recommended PROM Programmers and Socket Adapters PROM Programmer Socket Adapter Manufacture Model Name Package Manufacture Model Name DATA I/O corp 121 B DP-64S Hitachi HS4369ESS01H AVAL corp PKW-1000 FP-64B HS4369ESF01H FP-64A HS4369ESH01H DP-64S Hitachi HS4369ESS01H FP-64B HS4369ESF01H FP-64A HS4369ESH01H Warnings 1. Always specify addresses $0000 to $7FFF when programming with a PROM programmer. If address $8000 or higher is accessed, the PROM may not be programmed or verified correctly. Set all data in unused addresses to $FF. Note that the plastic-package version cannot be erased and reprogrammed. 2. Make sure that the PROM programmer, socket adapter, and LSI are aligned correctly (their pin 1 positions match), otherwise overcurrents may damage the LSI. Before starting programming, make sure that the LSI is firmly fixed in the socket adapter and the socket adapter is firmly fixed onto the programmer. 3. PROM programmers have two voltages (VPP ): 12.5 V and 21 V. Remember that ZTAT devices require a VPP of 12.5 V—the 21-V setting will damage them. 12.5 V is the Intel 27256 setting. Programming and Verification The built-in PROM of the MCU can be programmed at high speed without risk of voltage stress or damage to data reliability. Programming and verification modes are selected as listed in table 30. For details of PROM programming, refer to the following Notes on PROM Programming section. Table 30 PROM Mode Selection Pin Mode CE OE VPP O0–O4 Programming Low High VPP Data input Verification High Low VPP Data output Programming inhibited High High VPP High impedance 94 HD404369 Series Addressing Modes RAM Addressing Modes The MCU has three RAM addressing modes, as shown in figure 80 and described below. Register Indirect Addressing Mode: The contents of the W, X, and Y registers (10 bits in total) are used as a RAM address. Direct Addressing Mode: A direct addressing instruction consists of two words. The first word contains the opcode, and the contents of the second word (10 bits) are used as a RAM address. Memory Register Addressing Mode: The memory registers (MR), which are located in 16 addresses from $040 to $04F, are accessed with the LAMR and XMRA instructions. W register W1 W0 RAM address X register X3 X2 X1 Y register X0 Y3 Y2 Y1 Y0 AP9 AP8 AP7 AP6 AP5 AP4 AP3 AP2 AP1 AP0 Register Direct Addressing 1st word of Instruction Opcode 2nd word of Instruction d RAM address 9 d8 d7 d6 d5 d4 d3 d2 d1 d0 AP9 AP8 AP7 AP6 AP5 AP4 AP3 AP2 AP1 AP0 Direct Addressing Instruction Opcode 0 RAM address 0 0 1 m3 m2 0 m1 m0 0 AP9 AP8 AP7 AP6 AP5 AP4 AP3 AP2 AP1 AP0 Memory Register Addressing Figure 80 RAM Addressing Modes 95 HD404369 Series ROM Addressing Modes and the P Instruction The MCU has four ROM addressing modes, as shown in figure 81 and described below. Direct Addressing Mode: A program can branch to any address in the ROM memory space by executing the JMPL, BRL, or CALL instruction. Each of these instructions replaces the 14 program counter bits (PC 13–PC0) with 14-bit immediate data. Current Page Addressing Mode: The MCU has 64 pages of ROM with 256 words per page. A program can branch to any address in the current page by executing the BR instruction. This instruction replaces the eight low-order bits of the program counter (PC7–PC0) with eight-bit immediate data. If the BR instruction is on a page boundary (address 256n + 255), executing that instruction transfers the PC contents to the next physical page, as shown in figure 83. This means that the execution of the BR instruction on a page boundary will make the program branch to the next page. Note that the HMCS400-series cross macroassembler has an automatic paging feature for ROM pages. Zero-Page Addressing Mode: A program can branch to the zero-page subroutine area located at $0000– $003F by executing the CAL instruction. When the CAL instruction is executed, 6 bits of immediate data are placed in the six low-order bits of the program counter (PC5–PC0), and 0s are placed in the eight highorder bits (PC13–PC6). Table Data Addressing Mode: A program can branch to an address determined by the contents of four-bit immediate data, the accumulator, and the B register by executing the TBR instruction. P Instruction: ROM data addressed in table data addressing mode can be referenced with the P instruction as shown in figure 82. If bit 8 of the ROM data is 1, eight bits of ROM data are written to the accumulator and the B register. If bit 9 is 1, eight bits of ROM data are written to the R1 and R2 port output registers. If both bits 8 and 9 are 1, ROM data is written to the accumulator and the B register, and also to the R1 and R2 port output registers at the same time. The P instruction has no effect on the program counter. 96 HD404369 Series 1st word of instruction [JMPL] [BRL] [CALL] Opcode p3 Program counter 2nd word of instruction p2 p1 p0 d9 d8 d7 d6 d5 d4 d3 d2 d1 d0 PC13 PC12 PC11 PC10 PC 9 PC 8 PC 7 PC 6 PC 5 PC 4 PC 3 PC 2 PC 1 PC 0 Direct Addressing Instruction [BR] Program counter Opcode b7 b6 b5 b4 b3 b2 b1 b0 PC13 PC12 PC11 PC10 PC 9 PC 8 PC7 PC 6 PC 5 PC 4 PC 3 PC 2 PC 1 PC 0 Current Page Addressing Instruction [CAL] 0 Program counter 0 0 0 d5 Opcode 0 0 0 d4 d3 d2 d1 d0 0 PC13 PC12 PC11 PC10 PC 9 PC 8 PC 7 PC 6 PC 5 PC 4 PC 3 PC 2 PC 1 PC 0 Zero Page Addressing Instruction [TBR] Opcode p3 p2 p1 p0 B register B3 0 Program counter B2 B1 Accumulator B0 A3 A2 A1 A0 0 PC13 PC12 PC11 PC10 PC 9 PC 8 PC 7 PC 6 PC 5 PC 4 PC 3 PC 2 PC 1 PC 0 Table Data Addressing Figure 81 ROM Addressing Modes 97 HD404369 Series Instruction [P] Opcode p3 p2 p1 p0 B register B3 0 B2 B1 Accumulator B0 A3 A2 A1 A0 0 Referenced ROM address RA13 RA12 RA11 RA10 RA 9 RA 8 RA 7 RA 6 RA 5 RA 4 RA 3 RA 2 RA 1 RA 0 Address Designation ROM data RO9 RO8 RO7 RO6 RO5 RO4 RO3 RO2 RO1 RO0 Accumulator, B register ROM data B3 B2 B1 B0 A3 A A1 A 0 If RO 8 = 1 RO9 RO8 RO7 RO6 RO5 RO4 RO3 RO2 RO1 RO0 Output registers R1, R2 R23 R22 R21 R20 R13 R12 R11 R10 Pattern Output Figure 82 P Instruction 98 2 If RO 9 = 1 HD404369 Series 256 (n – 1) + 255 BR AAA 256n AAA BBB 256n + 254 256n + 255 256 (n + 1) NOP BR BR BBB AAA NOP Figure 83 Branching when the Branch Destination is on a Page Boundary 99 HD404369 Series Instruction Set The HD404369 Series has 101 instructions, classified into the following 10 groups: • Immediate instructions • Register-to-register instructions • RAM address instructions • RAM register instructions • Arithmetic instructions • Compare instructions • RAM bit manipulation instructions • ROM address instructions • Input/output instructions • Control instructions 100 HD404369 Series Absolute Maximum Ratings Item Symbol Value Unit Notes Supply voltage VCC –0.3 to +7.0 V Programming voltage VPP –0.3 to +14.0 V 1 Pin voltage VT –0.3 to VCC + 0.3 V 2 –0.3 to +15.0 V 3 Total permissible input current ∑IO 105 mA 4 Total permissible output current –∑IO 50 mA 5 Maximum input current IO 4 mA 6, 7 30 mA 6, 8 7, 9 Maximum output current –I O 4 mA Operating temperature Topr –20 to +75 °C Storage temperature Tstg –55 to +125 °C Notes: Permanent damage may occur if these absolute maximum ratings are exceeded. Normal operation must be under the conditions stated in the electrical characteristics tables. If these conditions are exceeded, the LSI may malfunction or its reliability may be affected. 1. Applies to pin TEST (VPP ) of HD407A4369. 2. Applies to all standard voltage pins. 3. Applies to intermediate-voltage pins. 4. The total permissible input current is the total of input currents simultaneously flowing in from all the I/O pins to GND. 5. The total permissible output current is the total of output currents simultaneously flowing out from VCC to all I/O pins. 6. The maximum input current is the maximum current flowing from each I/O pin to GND. 7. Applies to ports D0 to D13 , R0, R3 to R9. 8. Applies to ports R1 and R2. 9. The maximum output current is the maximum current flowing from VCC to each I/O pin 101 HD404369 Series Electrical Characteristics DC Characteristics (HD407A4369: VC C = 2.7 to 5.5 V, GND = 0 V, Ta = –20 to +75°C; HD404364/HD404368/HD4043612/HD404369/HD40A4364/HD40A4368/HD40A43612/HD40A4369:V CC = 2.7 to 6.0 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pins Min Typ Max Unit Input high voltage VIH RESET, SCK, 0.8V CC — VCC + 0.3 V SI 0.7 VCC — VCC + 0.3 V OSC 1 VCC – 0.5 — VCC + 0.3 V RESET, SCK, –0.3 — 0.2V CC V SI –0.3 — 0.3V CC V OSC 1 –0.3 — 0.5 V Test Condition Notes INT0, INT1, STOPC, EVNB Input low voltage VIL INT0, INT1, STOPC, EVNB Output high voltage VOH SCK, SO, TOC VCC – 0.5 — — V –I OH = 0.5 mA Output low voltage VOL SCK, SO, TOC — — 0.4 V I OL = 0.4 mA I/O leakage current |IIL| RESET, SCK, — — 1 µA Vin = 0 V to VCC 1 — — 5.0 mA VCC = 5 V, 2 SI, SO, TOC, OSC 1, INT0, INT1, STOPC, EVNB Current dissipation in active mode I CC Current dissipation in standby mode I SBY Current dissipation in subactive mode I SUB Current dissipation in watch mode I WTC 102 VCC f OSC = 4 MHz VCC — — 2.0 mA VCC = 5 V, 3 f OSC = 4 MHz VCC — — 100 µA VCC = 5 V, 4 32 kHz oscillator VCC — — 20 µA VCC = 5 V, 32 kHz oscillator 4 HD404369 Series Item Symbol Pins Min Typ Max Unit Test Condition Notes Current dissipation in stop mode I STOP VCC — — 10 µA VCC = 5V, Stop mode VSTOP retaining voltage 4 X1 = GND, X2 = Open VCC 2 — — V Notes: 1. Excludes current flowing through pull-up MOS and output buffers. 2. I CC is the source current when no I/O current is flowing while the MCU is in reset state. Test conditions: MCU: Reset Pins: RESET, TEST at GND 3. I SBY is the source current when no I/O current is flowing while the MCU timer is operating. Test conditions: MCU: I/O reset Standby mode Pins: RESET at V CC TEST at GND D0–D 13 , R0–R9, RA 1 at V CC 4. This is the source current when no I/O current is flowing. Test conditions: Pins: RESET at V CC TEST at GND D0–D 13 , R0–R9, RA 1 at V CC 103 HD404369 Series I/O Characteristics for Standard Pins (HD407A4369: V CC = 2.7 to 5.5 V, GND = 0 V, Ta = –20 to +75°C; HD404364/HD404368/HD4043612/HD404369/HD40A4364/HD40A4368/HD40A43612/HD40A 4369: VCC = 2.7 to 6.0 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pins Min Typ Max Unit Test Condition Note Input high voltage VIH D0–D 13 , 0.7V CC — VCC + 0.3 V –0.3 — 0.3V CC V VCC – 0.5 — — V –I OH = 0.5 mA R0, R3–R9 D0–D 13 , — — 0.4 V I OL = 1.6 mA — — 1 µA Vin = 0 V to VCC 30 150 300 µA VCC = 5 V, R0, R3–R9, RA1 Input low voltage VIL D0–D 13 , R0, R3–R9, RA1 Output high voltage VOH Output low voltage VOL D0–D 13 , R0, R3–R9 Input leakage current |IIL| D0–D 13 , R0, R3–R9, RA1 Pull-up MOS current –I PU D0–D 13 , Vin = 0 V R0, R3–R9 Note: 1 1. Output buffer current is excluded. I/O Characteristics for Intermediate-Voltage Pins (HD407A4369: V CC = 2.7 to 5.5 V, GND = 0 V, Ta = –20 to +75°C; HD404364/HD404368/HD4043612/HD404369/HD40A4364/HD40A4368/HD40A43612/ HD40A4369: VCC = 2.7 to 6.0 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pins Min Typ Max Unit Input high voltage VIH R1, R2 0.7V CC — 12 V Input low voltage VIL R1, R2 –0.3 — 0.3V CC V Output high voltage VOH R1, R2 11.5 — — V 500 kΩ at 12 V Output low voltage R1, R2 — — 0.4 V I OL = 0.4 mA — — 2.0 V I OL = 15 mA, VOL Test Condition Note VCC = 4.5 to 5.5 V I/O leakage current Note: 104 |IIL| R1, R2 1. Excludes output buffer current. — — 20 µA Vin = 0 V to 12 V 1 HD404369 Series A/D Converter Characteristics (HD407A4369: VCC = 2.7 to 5.5 V, GND = 0 V, T a = –20 to +75°C;HD404364/HD404368/HD4043612/HD404369/HD40A4364/HD40A4368/HD40A43612/HD40A 4369: VCC = 2.7 to 6.0 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pins Min Typ Max Analog supply voltage AVCC AVCC VCC – 0.3 VCC VCC + 0.3 V AN 0–AN 11 AVSS — AVCC V — — 200 µA — — 30 pF Resolution 8 8 8 Bit Number of input channels 0 — 12 Chan nel Absolute accuracy — — ±2.0 LSB Conversion time 34 — 67 t cyc 1 — — MΩ Analog input voltage AVin Current flowing between AV CC and AVSS I AD Analog input capacitance CA in Input impedance Note: AN 0–AN 11 AN 0–AN 11 Unit Test Condition Notes 1 VCC = AVCC = 5.0 V 1. Connect this to V CC if the A/D converter is not used. 105 HD404369 Series Standard fOSC = 5 MHz Version AC Characteristics (HD404364/HD404368/HD4043612/HD404369: VCC = 2.7 to 6.0 V, GND = 0 V, Ta = –20 to +75°C) Item Symbol Pins Min Typ Max Unit Test Condition Notes Clock oscillation frequency f OSC OSC 1, OSC 2 0.4 4 5.0 MHz 1/4 system clock division ratio 1 X1, X2 — 32.768 — kHz t cyc 0.8 1 10 µs t subcyc — 244.14 — µs 32-kHz oscillator, 1/8 system clock division ratio — 122.07 — µs 32-kHz oscillator, 1/4 system clock division ratio Instruction cycle time 1 Oscillation t RC stabilization time (ceramic oscillator) OSC 1, OSC 2 — — 7.5 ms 2 Oscillation stabilization time (crystal oscillator) OSC 1, OSC 2 — — 40 ms 2 X1, X2 — — 2 s 2 External clock high t CPH width OSC 1 80 — — ns 3 External clock low t CPL width OSC 1 80 — — ns 3 External clock rise t CPr time OSC 1 — — 20 ns 3 External clock fall time t CPf OSC 1 — — 20 ns 3 INT0, INT1, EVNB high widths t IH INT0, INT1, EVNB 2 — — t cyc / 4 INT0, INT1, EVNB low widths t IL RESET low width t RSTL RESET 2 — — t cyc 5 STOPC low width t STPL STOPC 1 — — t RC 6 RESET rise time t RSTr RESET — — 20 ms 5 STOPC rise time t STPr STOPC — — 20 ms 6 Input capacitance Cin All input pins — except R1 and R2 — 15 pF R1, R2 — t RC t subcyc INT0, INT1, EVNB 2 — — t cyc / 4 t subcyc — f = 1 MHz, Vin = 0 V 30 pF f = 1 MHz, Vin = 0 V 106 HD404369 Series Notes: 1. When using the subsystem oscillator (32.768 kHz), one of the following relationships for f OSC must be applied. 0.4 MHz ≤ fOSC ≤ 1.0 MHz or 1.6 MHz ≤ fOSC ≤ 5.0 MHz The operating range for fOSC can be set with bit 1 of system clock selection register 1 (SSR1: $027). 2. The oscillation stabilization time is the period required for the oscillator to stabilize in the following situations: a. After V CC reaches 2.7 V at power-on. b. After RESET input goes low when stop mode is cancelled. c. After STOPC input goes low when stop mode is cancelled. To ensure the oscillation stabilization time at power-on or when stop mode is cancelled, RESET or STOPC must be input for at least a duration of t RC. When using a crystal or ceramic oscillator, consult with the manufacturer to determine what stabilization time is required, since it will depend on the circuit constants and stray capacitance. 3. Refer to figure 84. 4. Refer to figure 85. 5. Refer to figure 86. 6. Refer to figure 87. 107 HD404369 Series High-Speed f OSC = 8.5 MHz Version AC Characteristics (HD407A4369: VCC = 2.7 to 5.5 V, GND = 0 V, Ta = –20 to +75°C; HD40A4364/HD40A4368/HD40A43612/HD40A4369: V CC = 2.7 to 6.0 V, GND = 0 V, T a = –20 to +75°C) Item Symbol Pins Min Typ Max Unit Test Condition Notes Clock oscillation frequency f OSC OSC 1, OSC 2 0.4 4 5.0 MHz 1/4 system clock division ratio 1 0.4 4 8.5 MHz — 32.768 — kHz 0.8 1 10 µs 1 0.47 1 10 µs 2, 3 — 244.14 — µs 32-kHz oscillator, 1/8 system clock division ratio — 122.07 — µs 32-kHz oscillator, 1/4 system clock division ratio X1, X2 Instruction cycle time t cyc t subcyc 2, 3 Oscillation t RC stabilization time (ceramic oscillator) OSC 1, OSC 2 — — 7.5 ms 4 Oscillation t RC stabilization time (ceramic oscillator) OSC 1, OSC 2 — — 40 ms 4 X1, X2 — — 2 s 4 OSC 1 80 — — ns 5 47 — — ns 3, 5 80 — — ns 5 47 — — ns 3, 5 — — 20 ns 5 — — 15 ns 3, 5 — — 20 ns 5 — — 15 ns 3, 5 2 — — t cyc / 6 External clock high t CPH width External clock low t CPL width External clock rise t CPr time External clock fall time t CPf INT0, INT1, EVNB high widths t IH INT0, INT1, EVNB low widths t IL 108 OSC 1 OSC 1 OSC 1 INT0, INT1, EVNB INT0, INT1, EVNB t subcyc 2 — — t cyc / t subcyc 6 HD404369 Series Item Symbol Pins Min Typ Max Unit Test Condition Notes RESET low width t RSTL RESET 2 — — t cyc 7 STOPC low width t STPL STOPC 1 — — t RC 8 RESET rise time t RSTr RESET — — 20 ms 7 STOPC rise time t STPr STOPC — — 20 ms 8 Input capacitance Cin All input pins except — TEST, R1 and R2 — 15 pF f = 1 MHz, Vin = 0 V TEST — — 15 pF f = 1 MHz, Vin = 0 V 9 TEST — — 180 pF f = 1 MHz, Vin = 0 V 10 R1, R2 — — 30 pF f = 1 MHz, Vin = 0 V Notes: 1. When using the subsystem oscillator (32.768 kHz), one of the following relationships for f OSC must be applied. 0.4 MHz ≤ fOSC ≤ 1.0 MHz or 1.6 MHz ≤ fOSC ≤ 5.0 MHz The operating range for fOSC can be set with bit 1 of system clock selection register 1 (SSR1: $027). 2. When using the subsystem oscillator (32.768 kHz), one of the following relationships for f OSC must be applied. 0.4 MHz ≤ f OSC ≤ 1.0 MHz or 1.6 MHz ≤ f OSC ≤ 8.5 MHz The operating range for fOSC can be set with bit 1 of system clock selection register 1 (SSR1: $027). 3. VCC = 4.5 to 5.5V 4. The oscillation stabilization time is the period required for the oscillator to stabilize in the following situations: a. After V CC reaches 2.7 V at power-on. b. After RESET input goes low when stop mode is cancelled. c. After STOPC input goes low when stop mode is cancelled. To ensure the oscillation stabilization time at power-on or when stop mode is cancelled, RESET or STOPC must be input for at least a duration of t RC. When using a crystal or ceramic oscillator, consult with the manufacturer to determine what stabilization time is required, since it will depend on the circuit constants and stray capacitance. 5. Refer to figure 84. 6. Refer to figure 85. 7. Refer to figure 86. 8. Refer to figure 87. 9. Applies to the HD40A4364, HD40A4368, HD40A43612, and HD40A4369. 10. Applies to the HD407A4369. 109 HD404369 Series Serial Interface Timing Characteristics (HD407A4369: VCC = 2.7 to 5.5 V, GND = 0 V, Ta = –20 to +75°C; HD404364/HD404368/HD4043612/HD404369/HD40A4364/HD40A4368/HD40A43612/HD40A 4369: VCC = 2.7 to 6.0 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) During Transmit Clock Output Item Symbol Pins Min Typ Max Unit Test Condition Note Transmit clock cycle time t Scyc SCK 1 — — t cyc Load shown in figure 89 1 Transmit clock high width t SCKH SCK 0.4 — — t Scyc Load shown in figure 89 1 Transmit clock low width t SCKL SCK 0.4 — — t Scyc Load shown in figure 89 1 Transmit clock rise time t SCKr SCK — — 80 ns Load shown in figure 89 1 Transmit clock fall time t SCKf SCK — — 80 ns Load shown in figure 89 1 Serial output data delay time t DSO SO — — 300 ns Load shown in figure 89 1 Serial input data setup t SSI time SI 100 — — ns 1 Serial input data hold time SI 200 — — ns 1 t HSI During Transmit Clock Input Item Symbol Pins Min Typ Max Unit Transmit clock cycle time t Scyc SCK 1 — — t cyc 1 Transmit clock high width t SCKH SCK 0.4 — — t Scyc 1 Transmit clock low width t SCKL SCK 0.4 — — t Scyc 1 Transmit clock rise time t SCKr SCK — — 80 ns 1 Transmit clock fall time t SCKf SCK — — 80 ns 1 Serial output data delay time t DSO SO — — 300 ns Serial input data setup t SSI time SI 100 — — ns 1 Serial input data hold time SI 200 — — ns 1 Note: 110 t HSI 1. Refer to figure 88. Test Condition Load shown in figure 89 Note 1 HD404369 Series OSC1 1/fCP VCC – 0.5 V tCPL tCPH 0.5 V tCPr tCPf Figure 84 External Clock Timing INT0, INT1, EVNB 0.8VCC tIL tIH 0.2VCC Figure 85 Interrupt Timing RESET 0.8VCC tRSTL 0.2VCC tRSTr Figure 86 RESET Timing STOPC 0.8VCC tSTPL 0.2VCC tSTPr Figure 87 STOPC Timing 111 HD404369 Series t Scyc t SCKf SCK VCC – 0.5 V (0.8VCC )* 0.4 V (0.2VCC)* t SCKr t SCKL t SCKH t DSO VCC – 0.5 V 0.4 V SO t SSI t HSI 0.7V CC 0.3VCC SI Note: * VCC – 0.5 V and 0.4 V are the threshold voltages for transmit clock output, and 0.8VCC and 0.2VCC are the threshold voltages for transmit clock input. Figure 88 Serial Interface Timing VCC RL = 2.6 kΩ Test point C= 30 pF R= 12 kΩ Hitachi 1S2074 or equivalent Figure 89 Timing Load Circuit 112 HD404369 Series Notes on ROM Out Please pay attention to the following items regarding ROM out. On ROM out, fill the ROM area indicated below with 1s to create the same data size for the HD404364, HD40A4364, HD404368, HD40A4368, HD4043612 and HD40A43612 as a 16-kword version (HD404369, HD40A4369). The 16-kword data sizes are required to change ROM data to mask manufacturing data since the program used is for a 16-kword version. This limitation applies when using an EPROM or a data base. ROM 4-kword version: HD404364, HD40A4364 $0000 ROM 8-kword version: HD404368, HD40A4368 $000F $0010 Zero-page subroutine (64 words) $003F $0040 $000F $0010 Zero-page subroutine (64 words) $000F $0010 Zero-page subroutine (64 words) $003F $0040 $003F $0040 $0FFF $1000 Vector address Vector address Pattern & program (4,096 words) Pattern & program (12,288 words) Pattern & program (8,192 words) $2FFF $3000 $1FFF $2000 Not used $3FFF $0000 $0000 Vector address ROM 12-kword version: HD4043612, HD40A43612 Not used $3FFF Not used $3FFF Fill this area with 1s 113 HD404369 Series HD404364/HD404368/HD4043612/HD404369/HD40A4364/HD40A4368/ HD40A43612/HD40A4369 Option List Please check off the appropriate applications and enter the necessary information. 1. ROM size 5 MHz operation HD404364 4-kword 8.5 MHz operation HD40A4364 5 MHz operation HD404368 Customer 8-kword 8.5 MHz operation HD40A4368 5 MHz operation HD4043612 Department Name 12-kword 8.5 MHz operation HD40A43612 5 MHz operation Date of order ROM code name LSI number 16-kword HD404369 8.5 MHz operation HD40A4369 2. Optional Functions * With 32-kHz CPU operation, with time base for clock * Without 32-kHz CPU operation, with time base for clock Without 32-kHz CPU operation, without time base Note: * Options marked with an asterisk require a subsystem crystal oscillator (X1, X2). 3. ROM Code Media Please specify the first type below (the upper bits and lower bits are mixed together), when using the EPROM on-package microcomputer type (including ZTAT™ version). EPROM: The upper bits and lower bits are mixed together. The upper five bits and lower five bits are programmed to the same EPROM in alternating order (i.e., LULULU...). EPROM: The upper bits and lower bits are separated. The upper five bits and lower five bits are programmed to different EPROMS. 4. System Oscillator (OSC1, OSC2) Ceramic oscillator f= MHz Crystal oscillator f= MHz External clock f= MHz 5. Stop mode 6. Package Used DP-64S Not used FP-64B FP-64A 114 HD404369 Series Cautions 1. Hitachi neither warrants nor grants licenses of any rights of Hitachi’s or any third party’s patent, copyright, trademark, or other intellectual property rights for information contained in this document. Hitachi bears no responsibility for problems that may arise with third party’s rights, including intellectual property rights, in connection with use of the information contained in this document. 2. Products and product specifications may be subject to change without notice. Confirm that you have received the latest product standards or specifications before final design, purchase or use. 3. Hitachi makes every attempt to ensure that its products are of high quality and reliability. However, contact Hitachi’s sales office before using the product in an application that demands especially high quality and reliability or where its failure or malfunction may directly threaten human life or cause risk of bodily injury, such as aerospace, aeronautics, nuclear power, combustion control, transportation, traffic, safety equipment or medical equipment for life support. 4. Design your application so that the product is used within the ranges guaranteed by Hitachi particularly for maximum rating, operating supply voltage range, heat radiation characteristics, installation conditions and other characteristics. Hitachi bears no responsibility for failure or damage when used beyond the guaranteed ranges. Even within the guaranteed ranges, consider normally foreseeable failure rates or failure modes in semiconductor devices and employ systemic measures such as failsafes, so that the equipment incorporating Hitachi product does not cause bodily injury, fire or other consequential damage due to operation of the Hitachi product. 5. This product is not designed to be radiation resistant. 6. No one is permitted to reproduce or duplicate, in any form, the whole or part of this document without written approval from Hitachi. 7. Contact Hitachi’s sales office for any questions regarding this document or Hitachi semiconductor products. Copyright © Hitachi, Ltd., 1998. All rights reserved. Printed in Japan. 115