To all our customers Regarding the change of names mentioned in the document, such as Hitachi Electric and Hitachi XX, to Renesas Technology Corp. The semiconductor operations of Mitsubishi Electric and Hitachi were transferred to Renesas Technology Corporation on April 1st 2003. These operations include microcomputer, logic, analog and discrete devices, and memory chips other than DRAMs (flash memory, SRAMs etc.) Accordingly, although Hitachi, Hitachi, Ltd., Hitachi Semiconductors, and other Hitachi brand names are mentioned in the document, these names have in fact all been changed to Renesas Technology Corp. Thank you for your understanding. Except for our corporate trademark, logo and corporate statement, no changes whatsoever have been made to the contents of the document, and these changes do not constitute any alteration to the contents of the document itself. Renesas Technology Home Page: http://www.renesas.com Renesas Technology Corp. Customer Support Dept. April 1, 2003 Cautions Keep safety first in your circuit designs! 1. Renesas Technology Corporation puts the maximum effort into making semiconductor products better and more reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may lead to personal injury, fire or property damage. Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of nonflammable material or (iii) prevention against any malfunction or mishap. Notes regarding these materials 1. These materials are intended as a reference to assist our customers in the selection of the Renesas Technology Corporation product best suited to the customer's application; they do not convey any license under any intellectual property rights, or any other rights, belonging to Renesas Technology Corporation or a third party. 2. Renesas Technology Corporation assumes no responsibility for any damage, or infringement of any third-party's rights, originating in the use of any product data, diagrams, charts, programs, algorithms, or circuit application examples contained in these materials. 3. All information contained in these materials, including product data, diagrams, charts, programs and algorithms represents information on products at the time of publication of these materials, and are subject to change by Renesas Technology Corporation without notice due to product improvements or other reasons. It is therefore recommended that customers contact Renesas Technology Corporation or an authorized Renesas Technology Corporation product distributor for the latest product information before purchasing a product listed herein. The information described here may contain technical inaccuracies or typographical errors. Renesas Technology Corporation assumes no responsibility for any damage, liability, or other loss rising from these inaccuracies or errors. Please also pay attention to information published by Renesas Technology Corporation by various means, including the Renesas Technology Corporation Semiconductor home page (http://www.renesas.com). 4. When using any or all of the information contained in these materials, including product data, diagrams, charts, programs, and algorithms, please be sure to evaluate all information as a total system before making a final decision on the applicability of the information and products. Renesas Technology Corporation assumes no responsibility for any damage, liability or other loss resulting from the information contained herein. 5. Renesas Technology Corporation semiconductors are not designed or manufactured for use in a device or system that is used under circumstances in which human life is potentially at stake. Please contact Renesas Technology Corporation or an authorized Renesas Technology Corporation product distributor when considering the use of a product contained herein for any specific purposes, such as apparatus or systems for transportation, vehicular, medical, aerospace, nuclear, or undersea repeater use. 6. The prior written approval of Renesas Technology Corporation is necessary to reprint or reproduce in whole or in part these materials. 7. If these products or technologies are subject to the Japanese export control restrictions, they must be exported under a license from the Japanese government and cannot be imported into a country other than the approved destination. Any diversion or reexport contrary to the export control laws and regulations of Japan and/or the country of destination is prohibited. 8. Please contact Renesas Technology Corporation for further details on these materials or the products contained therein. HD404618 Series 4-Bit Single-Chip Microcomputer Rev. 6.0 Sept. 1998 Description The HD404618 Series is designed with the powerful and efficient architecture of the HMCS400 family. The MCU incorporates a high-precision dual-tone multifrequency (DTMF) circuit, LCD driver/controller, voltage comparator, and 32-kHz watch oscillator circuit. The HD404618 Series includes five chips: the HD404612 with 2-kword ROM; the HD404614 with 4kword ROM; the HD404616 with 6-kword ROM; the HD404618 with 8-kword ROM; the HD4074618 with 8-kword PROM. The HD4074618, incorporating PROM, is a ZTAT microcomputer that can dramatically shorten system development periods and smooth the process from debugging to mass production. ZTAT™ : Zero Turn Around time ZTAT is a trademark of Hitachi Ltd. Features • • • • • • • • • • • 2048-word × 10-bit ROM (HD404612) 4096-word × 10-bit ROM (HD404614) 6144-word × 10-bit ROM (HD404616) 8192-word × 10-bit ROM (HD404618, HD4074618) 1184-digit × 4-bit RAM 30 I/O pins 10 high-current output pins CMOS I/O pin circuit configuration Input/output pull-up MOS can be selected by software On-chip DTMF generator LCD controller/driver (32 segments × 4 commons) Three timer/counters Clock-synchronous 8-bit serial interface Six interrupt sources Two by external sources Four by internal sources HD404618 Series • Subroutine stack up to 16 levels, including interrupts • Instruction cycle time 10 µs (fOSC = 400 kHz) 5 µs (fOSC = 800 kHz) • Four low-power dissipation modes Stop mode Standby mode Watch mode Subactive mode • Built-in oscillator Crystal or ceramic oscillator (an external clock also possible) • Voltage comparator (2 channels) • Two operating modes MCU mode PROM mode (HD4074618) • Package 80-pin plastic flat package (FP-80B) (FP-80A) 80-pin plastic thin flat package (TFP-80) Ordering Information Type Product Name Model Name ROM (Word) Package Mask ROM HD404612 HD404612FS 2,048 FP-80B HD404614 HD404616 HD404618 ZTAT 2 HD4074618 HD404612H FP-80A HD404612TF TFP-80 HD404614FS 4,096 FP-80B HD404614H FP-80A HD404614TF TFP-80 HD404616FS 6,144 FP-80B HD404616H FP-80A HD404616TF TFP-80 HD404618FS 8,192 FP-80B HD404618H FP-80A HD404618TF TFP-80 HD4074618FS 8,192 FP-80B HD4074618H FP-80A HD4074618TF TFP-80 HD404618 Series COM1 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 D1 D0 RESET OSC2 OSC1 VCC VTref TONER TONEC V3 V2 V1 COM4 COM3 COM2 Pin Arrangement 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 SEG32 SEG31 SEG30 SEG29 SEG28 SEG27 SEG26 SEG25 SEG24 SEG23 SEG22 SEG21 SEG20 SEG19 SEG18 SEG17 SEG16 SEG15 SEG14 SEG13 SEG12 SEG11 SEG10 SEG9 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 FP-80B R2 0 R2 1 R2 2 R2 3 R3 0 TIMO/R3 1 INT0 /R3 2 INT1 /R3 3 SEG1 SEG2 SEG3 SEG4 SEG5 SEG6 SEG7 SEG8 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 D2 D3 D4 D5 D6 D7 D8 D9 D10 VC ref /D11 COMP0/D 12 COMP1/D 13 TEST X1 X2 GND SCK/R0 0 SI/R01 SO/R02 R03 R10 R11 R12 R13 61 62 63 64 65 66 67 68 69 71 70 73 72 74 75 76 77 78 1 60 2 59 3 4 58 57 5 56 6 55 7 54 8 53 9 10 52 51 FP-80A TFP-80 11 12 50 49 40 39 38 37 36 35 34 33 32 30 31 41 28 29 20 27 43 42 26 44 18 19 25 45 17 24 46 16 23 47 15 22 48 14 21 13 SEG30 SEG29 SEG28 SEG27 SEG26 SEG25 SEG24 SEG23 SEG22 SEG21 SEG20 SEG19 SEG18 SEG17 SEG16 SEG15 SEG14 SEG13 SEG12 SEG11 R1 2 R1 3 R2 0 R2 1 R2 2 R2 3 R3 0 TIMO/R31 INT0 /R32 INT1 /R33 SEG1 SEG2 SEG3 SEG4 SEG5 SEG6 SEG7 SEG8 SEG9 SEG10 D4 D5 D6 D7 D8 D9 D10 VCref /D11 COMP0/D 12 COMP1/D 13 TEST X1 X2 GND SCK/R0 0 SI/R0 1 SO/R0 2 R0 3 R1 0 R1 1 79 80 D3 D2 D1 D0 RESET OSC2 OSC1 VCC VTref TONER TONEC V3 V2 V1 COM4 COM3 COM2 COM1 SEG32 SEG31 (top view) (top view) 3 HD404618 Series Pin Description Pin Number Pin Number FP-80B FP-80A, TFP-80 Pin Name I/O FP-80B FP-80A, TFP-80 Pin Name I/O 1 79 D2 I/O 33 31 SEG1 O 2 80 D3 I/O 34 32 SEG2 O 3 1 D4 I/O 35 33 SEG3 O 4 2 D5 I/O 36 34 SEG4 O 5 3 D6 I/O 37 35 SEG5 O 6 4 D7 I/O 38 36 SEG6 O 7 5 D8 I/O 39 37 SEG7 O 8 6 D9 I/O 40 38 SEG8 O 9 7 D10 I 41 39 SEG9 O 10 8 D11/VCref I 42 40 SEG10 O 11 9 D12/COMP0 I 43 41 SEG11 O 12 10 D13/COMP1 I 44 42 SEG12 O 13 11 TEST I 45 43 SEG13 O 14 12 X1 I 46 44 SEG14 O 15 13 X2 O 47 45 SEG15 O 16 14 GND 48 46 SEG16 O 17 15 R0 0/SCK I/O 49 47 SEG17 O 18 16 R0 1/SI I/O 50 48 SEG18 O 19 17 R0 2/SO I/O 51 49 SEG19 O 20 18 R0 3 I/O 52 50 SEG20 O 21 19 R1 0 I/O 53 51 SEG21 O 22 20 R1 1 I/O 54 52 SEG22 O 23 21 R1 2 I/O 55 53 SEG23 O 24 22 R1 3 I/O 56 54 SEG24 O 25 23 R2 0 I/O 57 55 SEG25 O 26 24 R2 1 I/O 58 56 SEG26 O 27 25 R2 2 I/O 59 57 SEG27 O 28 26 R2 3 I/O 60 58 SEG28 O 29 27 R3 0 I/O 61 59 SEG29 O 30 28 R3 1/TIMO I/O 62 60 SEG30 O 31 29 R3 2/INT0 I/O 63 61 SEG31 O 32 30 R3 3/INT1 I/O 64 62 SEG32 O 4 HD404618 Series Pin Number Pin Number FP-80B FP-80A, TFP-80 Pin Name I/O FP-80B FP-80A, TFP-80 Pin Name I/O 65 63 COM1 O 73 71 TONER O 66 64 COM2 O 74 72 VT ref 67 65 COM3 O 75 73 VCC 68 66 COM4 O 76 74 OSC 1 I 69 67 V1 77 75 OSC 2 O 70 68 V2 78 76 RESET I 71 69 V3 79 77 D0 I/O 72 70 TONEC 80 78 D1 I/O O Note: I/O: Input/output pin, I: Input pin, O: Output pin Pin Functions Power Supply VCC: Apply power voltage to this pin. GND: Connect to ground. TEST: Used for test purposes only. Connect it to VCC. RESET: Resets the MCU. Oscillators OSC 1, OSC2 : Used as pins for the internal oscillator circuit. They can be connected to a ceramic resonator, or OSC1 can be connected to an external oscillator circuit. X1, X2: Used for a 32.768-kHz crystal oscillator that acts as a clock. Ports D 0–D 13 (D Port): Input/output port addressable by individual bits. D0–D 9 are I/O pins and D10–D 13 are input pins. D0–D 9 are high current output pins (15 mA, max.). D11–D 13 are also available as voltage comparators. R0–R3 (R Ports): Input/output ports addressable in 4-bit units. R00, R01, R02, R31, R32, and R3 3, are multiplexed with SCK, SI, SO, TIMO, INT0, and INT 1, respectively. 5 HD404618 Series Interrupts INT0, INT1: Input external interrupts to the MCU. INT1 is also used as an external event input for timer B. INT 0 and INT1 are multiplexed with R32 and R33, respectively. Serial Communications Interface SCK: Input/output serial clock pin multiplexed with R0 0. SI: Serial receive data input pin multiplexed with R01. SO: Serial transmit data output pin multiplexed with R02. Timers TIMO: Outputs a variable-duty square wave. It is multiplexed with R31. LCD Driver/Controller V1, V2, V3: Power supply pins for the LCD driver. Internal resistors provide the voltage level for each pin. The voltage condition is V CC ≥ V1 ≥ V2 ≥ V3 ≥ GND. COM1–COM4: Common signal output pins for LCD display. SEG1–SEG32: Segment signal output pins for LCD display. DTMF Generator TONER, TONEC, VT ref: DTMF signal pins. TONER and TONEC transmit signals for row and column, respectively. VTref is a reference voltage for DTMF signals. Apply condition VCC ≥ VTref ≥ GND to VTref. Voltage Comparator COMP0, COMP1, VC ref: COMP0 and COMP1 are analog inputs for the voltage comparator. VCref is a reference voltage pin that inputs the threshold voltage of the analog input pin. 6 HD404618 Series VCC GND OSC 1 OSC 2 X1 X2 RESET TEST Block Diagram System control circuit External interrupt control circuit RAM (1,184 × 4 bits) D port INT0 INT1 W (2 bits) Timer A X (4 bits) Comparator VTref TONER TONEC DTMF generation circuit ALU CPU R0 port VCref COMP0 COMP1 SPY (4 bits) Internal data bus Serial interface Internal address bus SI SO SCK Internal data bus Y (4 bits) R00 R01 R02 R03 R1 port SPX (4 bits) Timer C R10 R11 R12 R13 R2 port TIMO R20 R21 R22 R23 R3 port Timer B D0 D1 D2 D3 D4 D5 D6 D7 D8 D9 D10 D11 D12 D13 R30 R31 R32 R33 High current pins CA ST (1 bit) (1 bit) A (4 bits) V1 V2 V3 COM1 COM2 COM3 COM4 SEG1 SEG2 SEG3 SEG31 SEG32 B (4 bits) LCD controller/ driver circuit SP (10 bits) Instruction decoder PC (14 bits) ROM (2,048 × 10 bits) (4,096 × 10 bits) (6,144 × 10 bits) (8,192 × 10 bits) : Data bus : Signal lines 7 HD404618 Series Memory Map ROM Memory Map The ROM memory map is shown in figure 1, and the ROM is described below. 0 $0000 Vector address 15 $000F 16 $0010 Zero-page subroutine (64 words) $003F 63 64 $0040 Pattern (4096 words) 4095 $0FFF 4096 $1000 Program* 8191 $1FFF 8192 $2000 Not used 16383 0 1 2 3 JMPL instruction (jump to reset routine) 4 5 6 7 8 9 JMPL instruction (jump to INT1 routine) 10 11 12 13 14 15 JMPL instruction (jump to INT0 routine) JMPL instruction (jump to timer A routine) JMPL instruction (jump to timer B routine) JMPL instruction (jump to timer C routine) JMPL instruction (jump to serial routine) $0000 $0001 $0002 $0003 $0004 $0005 $0006 $0007 $0008 $0009 $000A $000B $000C $000D $000E $000F Note: * HD404612: 2048 words HD404614: 4096 words HD404616: 6144 words HD404618, HD4074618: 8192 words $3FFF Figure 1 ROM Memory Map Vector Address Area ($0000–$000F): Reserved for JMPL instructions that branch to the start addresses of the reset and interrupt routines. After an MCU reset or interrupt execution, the program starts 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–$07FF (HD404612), $0000–$0FFF (HD404614), $0000–$17FF (HD404616), $0000–$1FFF (HD404618, HD4074618)): Used for program coding. 8 HD404618 Series RAM Memory Map The MCU contains a 1,184-digit × 4-bit RAM area consisting of a data area and a stack area. In addition, interrupt control bits and special registers are mapped onto the same RAM memory space outside this area. The RAM memory map is shown in figure 2, and described below. Interrupt Control Bits Area ($000–$003): Used for interrupt control bits and the bit register (figure 3). The register flag area consists of LSON, WDON, TGSP, and DTON flags. Both areas can be accessed only by RAM bit manipulation instructions. In addition, note that the interrupt request flag cannot be set by software, the RSP bit is used only to reset the stack pointer. Limitations on using the instructions are shown in figure 4. Register Flag Area ($020–$023): Consist of the LSON, WDON, TGSP, and DTON flags which are bit registers accessible by RAM bit manipulation instructions. The WDON flag can only be set, only by the SEM/SEMD instruction. The TGSP flag can be set and reset by the SEM/SEMD and REM/REMD instructions. The DTON flag can be set, reset, and tested by the SEM/SEMD, REM/REMD, and TMD instructions. Note that the DTON flag is active only in subactive mode, and is normally reset in active mode. Special Function Registers Area ($004–$01F, $024–$03F): Used as mode or data registers for serial interface, timer/counters, LCD, and DTMF, and as data control registers for I/O ports. These registers are classified into three types: write-only, read-only, and read/write as shown in figure 2. The SEM/REM and SEMD/REMD instructions can be used for the LCD control register (LCR), but RAM bit manipulation instructions cannot be used for other registers. LCD Data Area ($050–$06F): Used for storing LCD data which is automatically output to LCD segments as display data. Data 1 lights the corresponding LCD segment; data 0 extinguishes it. This area can be used as data area. Data Area ($040–$2CF, $100–$2CF; Bank 0, 1): The memory registers (MR), which consist of 16 digits ($040–$04F), can be accessed by the LAMR and XMRA instructions (see figure 5). In the 464 digits from $100–$2CF, a bank can be selected by the V register (see section on V register). 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 interrupt processing. 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 5. 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. 9 HD404618 Series 0 $000 RAM-mapped registers 63 64 80 112 Memory registers (MR) LCD display area (32 digits) $03F $040 $050 $070 Data (144 digits) $100 Data (464 digits × 2) * V = 0 (bank 0) V = 1 (bank 1) Not used $3BF $3C0 Stack (64 digits) $3FF 1023 5 6 7 8 9 10 $2CF 959 960 0 1 2 3 4 11 12 13 14 15 16 17 18 19 20 $000 $001 $002 Interrupt control bits area Port mode register A Serial mode register (PMRA) (SMR) W W Serial data register lower (SRL) R/W Serial data register upper (SRU) R/W Timer mode register A (TMA) W Timer mode register B (TMB) W Timer B (TCBL/TLRL) (TCBU/TLRU) Miscellaneous register (MIS) Timer mode register C (TMC) 32 (LCR) (LMR) $008 $009 R/W R/W $00A $00B W W $00C $00D Timer C (TCCL/TCRL) R/W (TCCU/TCRU) R/W TG mode register (TGM) W W TG control register (TGC) Port mode register B (PMRB) W LCD control register LCD mode register Not used $003 $004 $005 $006 $007 W W $00E $00F $010 $011 $012 $013 $014 $020 Register flag area $023 35 Not used $100 Data (464 digits) V = 0 (bank 0) 48 49 50 51 $030 $031 (DCR2) (DCR3) W W W W Port R0 DCR Port R1 DCR (DCR0) (DCR1) Port R2 DCR Port R3 DCR Data (464 digits) V = 1 (bank 1) $032 $033 Not used $2CF Note: Do not use any area labelled “Not used” * The data area has two banks: V = 0 (bank 0) and V = 1 (bank 1) R: Read only W: Write only R/W: Read/write 59 60 61 Port D 0 –D 3 DCR (DCRB) W Port D 4 –D 7 DCR (DCRC) W W $03B $03C $03D 63 V register R/W $03F Port D 8 –D 9 DCR (DCRD) Not used 10 Timer counter B, lower (TCBL) R Timer load register B, lower (TLRL) W $00A 11 Timer counter B, upper (TCBU) R Timer load register B, upper (TLRU) W 14 Timer counter C, lower (TCCL) R Timer load register C, lower (TCRL) W $00E 15 Timer counter C, upper (TCCU) R Timer load register C, upper (TCRU) W $00F Figure 2 RAM Memory Map 10 (V-REG) $00B HD404618 Series Bit 3 Bit 2 Bit 1 Bit 0 0 IM0 (IM of INT0 ) IF0 (IF of INT0 ) RSP (Reset SP bit) 1 IMTA (IM of timer A) IFTA (IF of timer A) IM1 (IM of INT1 ) IF1 (IF of INT1 ) $001 2 IMTC (IM of timer C) IFTC (IF of timer C) IMTB (IM of timer B) IFTB (IF of timer B) $002 3 Not used Not used IMS (IM of serial) IFS (IF of serial) $003 32 DTON Direct transfer on flag TGSP (Tone generator speed flag) WDON (Watchdog on flag) LSON (Low speed on flag) $020 IE (Interrupt enable flag) $000 $021 Not Used $023 35 IF: IM: IE: SP: Note: Interrupt request flag Interrupt mask Interrupt enable flag Stack pointer Bits in the interrupt control bits area and register flag area are set by the SEM or SEMD instruction, reset by the REM or REMD instruction, and tested by the TM or TMD instruction. Other instructions have no effect. Figure 3 Configuration of Interrupt Control Bits and Register Flag Areas IF RSP WDON TGSP DTON SEM/SEMD Not executed Not executed Allowed Allowed Not executed in active mode Used in subactive mode REM/REMD Allowed Allowed Not executed Allowed TM/TMD Allowed Inhibited Inhibited Inhibited Allowed Allowed Note: WDON is always reset in active mode. 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 HD404618 Series Memory registers 64 65 66 67 68 69 MR (0) MR (1) $040 MR (2) MR (3) $042 MR (4) $044 $045 Stack area 960 $041 $043 Level 16 Level 15 Level 14 Level 13 70 $046 Level 11 Level 10 71 MR (7) $047 Level 9 72 MR (8) MR (9) $048 Level 8 73 $049 74 MR (10) $04A 75 $04B 76 MR (11) MR (12) Level 7 Level 6 Level 5 $04C Level 4 77 MR (13) $04D Level 3 78 MR (14) MR (15) $04E Level 2 Level 1 $04F 1023 PC13 –PC0 : Program counter ST: Status flag CA: Carry flag Level 12 MR (5) MR (6) 79 $3C0 $3FF Bit 3 Bit 2 Bit 1 Bit 0 1020 ST PC13 PC12 PC11 $3FC 1021 PC10 PC 9 PC 8 PC 7 $3FD 1022 CA PC 6 PC 5 PC 4 $3FE 1023 PC 3 PC 2 PC 1 PC 0 $3FF Figure 5 Configuration of Memory Registers and Stack Area, and Stack Position 12 HD404618 Series Functional Description Registers and Flags The MCU has ten registers and two flags for CPU operations. They are illustrated in figure 6 and described below. 3 0 A Accumulator 3 0 B B register 0 V 1 V register 0 W 3 W register 0 X 3 X register 0 Y 3 Y register 0 SPX 3 SPX register 0 SPY SPY register 0 CA Carry flag 0 ST 13 Status flag 0 PC Program counter 9 1 5 1 1 1 0 SP Stack pointer Figure 6 Registers and Flags Accumulator (A), B Register (B): Four-bit registers used to hold results from the arithmetic logic unit (ALU) and transfer data between memory, I/O, and other registers. 13 HD404618 Series V Register (V): Used for RAM address expansion and selecting the bank of RAM addresses $100–$2CF (464 digits). Thus, when accessing locations $100–$2CF, specify the value of the V register (V = $0 for bank 0, V = $1 for bank 1). Locations $000–$0FF and $3C0–$3FF can be accessed independent of the V register. The V register is located at RAM address $03F. 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. 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. During an interrupt, a carry is pushed onto the stack 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, or CALL instruction. 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. During an interrupt, the contents of ST are pushed onto the stack and popped from the stack by the RTNI instruction, but not by the RTN instruction. Program Counter (PC): A 14-bit 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, is decremented by 4 when data is pushed onto the stack, and is incremented by 4 when data is popped from the stack. Since the top four bits of the SP are fixed at 1111, a stack of up to 16 levels can be used. The SP can also be initialized to $3FF in another way: by resetting the RSP bit with the REM or REMD instruction. 14 HD404618 Series Reset The MCU is reset by inputting a high-level voltage to the RESET pin. At power-on or when stop mode is cancelled, RESET must be high for at least one tRC to enable the oscillator to stabilize. During operation, RESET must be high for at least two instruction cycles. I/O pins go to high-impedance at power-on. Initial values after MCU reset are shown in table 1. 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 V register (bank register) (V) 0 Bank 0 (memory) Interrupt flags/mask Interrupt enable flag (IE) 0 Inhibits all interrupts Interrupt request flag (IF) 0 Indicates there is no interrupt request Interrupt mask (IM) 1 Prevents (masks) interrupt request Port data register (PDR) All bits 1 Enables output at level 1 Data control register (DCR) All bits 0 Turns output buffer off (to high impedance) Port mode register A (PMRA) 0000 Refer to description of port mode register A Port mode register B (PMRB) 0000 Refer to description of port mode register B Timer mode register A (TMA) 0000 Refer to description of timer mode register A Timer mode register B (TMB) 0000 Refer to description of timer mode register B 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 $000 — Prescaler W $00 — $00 — I/O Timer/ counters, serial interface Timer counter A (TCA) 15 HD404618 Series Table 1 Initial Values After MCU Reset (cont) Item Timer/ counters, serial interface Abbr. Initial Value Contents Timer counter B (TCB) $00 — Timer counter C (TCC) $00 — Timer load register B (TLR) $00 — Timer load register C (TCR) $00 — 000 — Octal counter LCD DTMF generator Bit registers LCD control register (LCR) 000 Refer to description of LCD control register LCD mode register (LMR) 0000 Refer to description of LCD duty cycle/clock control Tone generator control (TGC) register 000 Refer to description of tone generator control register Tone generator mode register (TGM) 0000 Refer to description of generator mode register Low speed on flag (LSON) 0 Refer to description of operating modes Watchdog timer on flag (WDON) 0 Refer to description of timer C Tone generator speed flag (TGSP) 0 Refer to description of DTMF generation circuit Direct transfer on flag (DTON) 0 Refer to description of operating modes (MIS) 000 — Miscellaneous register 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 (SR) RAM 16 Status after Cancellation of Stop Mode by MCU Reset Status after Cancellation of All Other Modes by MCU Reset Pre-MCU-reset values are not guaranteed; values must be initialized by program Pre-MCU-reset values are not guaranteed; values must be initialized by program Pre-MCU-reset (pre-STOPinstruction) values are retained HD404618 Series Interrupts The MCU has six interrupt sources: two external signals (INT0 and INT1), three timer/counters (timers A, B, and C), and serial interface (serial). 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 Servicing: Locations $000 through $003 in RAM space are reserved for 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. Figure 7 is a block diagram of the interrupt control circuit. Table 2 lists interrupt priorities and vector addresses, and table 3 lists the interrupt processing conditions for the six interrupt sources. An interrupt request occurs when the IF is set to 1 and IM 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. Figure 8 shows the interrupt processing sequence, and figure 9 shows an interrupt processing flowchart. After an interrupt is acknowledged, the previous instruction is completed in the first cycle. The IE is reset in the second cycle, the carry flag, status flag, 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. 17 HD404618 Series $ 000,0 Sequence control • Push PC/CA/ST • Reset IE • Jump to vector address IE $ 000,2 IF0 $ 000,3 IM0 Vector address Priority control logic $ 001,0 IF1 $ 001,1 IM1 $ 001,2 IFTA $ 001,3 IMTA $ 002,0 IFTB $ 002,1 IMTB $ 002,2 IFTC $ 002,3 IMTC $ 003,0 IFS $ 003,1 IMS Note: $m, n is at RAM address $m, bit number n. Figure 7 Block Diagram of Interrupt Control Circuit Table 2 Vector Addresses and Interrupt Priorities Reset/Interrupt Priority RESET Vector Address $0000 INT0 1 $0002 INT1 2 $0004 Timer A 3 $0006 Timer B 4 $0008 Timer C 5 $000A Serial 6 $000C 18 HD404618 Series Table 3 Interrupt Processing and Activation Conditions Interrupt Source Interrupt Control Bit INT0 INT1 Timer A Timer B Timer C Serial IE 1 1 1 1 1 1 IF0·IM0 1 0 0 0 0 0 IF1·IM1 * 1 0 0 0 0 IFTA·IMTA * * 1 0 0 0 IFTB·IMTB * * * 1 0 0 IFTC·IMTC * * * * 1 0 IFS·IMS * * * * * 1 Note: Bits marked by * 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 8 Interrupt Processing Sequence 19 HD404618 Series Power on RESET = 1 ? Yes No Interrupt request ? Yes No 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 Figure 9 Interrupt Processing Flowchart 20 (serial interrupt) HD404618 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 shown in table 4. Table 4 Interrupt Enable Flag IE Interrupt Enabled/Disabled 0 Disabled 1 Enabled External Interrupts (INT0, INT1): Specified by port mode register A (PMRA: $004). The INT1 input can be used as a clock signal input to timer B. Timer B increments at each falling edge of the INT1 input. When using INT1 as a timer B external event input, external interrupt mask IM1 must be set to prevent the INT1 interrupt request from being accepted (see table 6). To detect the edge of INT 0 or INT1, more than two instruction cycle times are required (2tcyc or 2tsubcyc). External Interrupt Request Flags (IF0: $000, Bit 2; IF1: $001, Bit 0): Set at the falling edge of the INT 0 and INT1 inputs as shown in table 5. Table 5 External Interrupt Request Flags 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 shown in table 6. Table 6 External Interrupt Masks 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 shown in table 7. Table 7 Timer A Interrupt Request Flag IFTA Interrupt Request 0 No 1 Yes 21 HD404618 Series Timer A Interrupt Mask (IMTA: $001, Bit 3): Prevents (masks) an interrupt request caused by the timer A interrupt request flag, as shown in table 8. Table 8 Timer A Interrupt Mask 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 shown in table 9. Table 9 Timer B Interrupt Request Flag 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 shown in table 10. Table 10 Timer B Interrupt Mask 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 shown in table 11. Table 11 Timer C Interrupt Request Flag 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 shown in table 12. 22 HD404618 Series Table 12 Timer C Interrupt Mask IMTC Interrupt Request 0 Enabled 1 Disabled (masked) Serial Interrupt Request Flag (IFS: $003,Bit 0): Set when the octal counter counts the eighth transmit clock signal or when data transmit is discontinued by resetting the octal counter, as shown in table 13. Table 13 Serial Interrupt Request Flag IFS Interrupt Request 0 No 1 Yes Serial Interrupt Mask (IMS: $003, Bit 1): Prevents (masks) an interrupt request caused by the serial interrupt request flag, as shown intable 14. Table 14 Serial Interrupt Mask IMS Interrupt Request 0 Enabled 1 Disabled (masked) 23 HD404618 Series Operating Modes The MCU has five operating modes that are specified by how the clock is used. The functions available in each mode are listed in table 15, and operations are shown in table 16. Transitions between operating modes are shown in figure 10. Table 17 provides additional information for table 15. Table 15 Functions Available in Each Operating Mode Mode Name Active Standby Stop Watch Subactive*4 Reset cancellation, interrupt request SBY instruction TMA3 = 0, STOP instruction TMA3 = 1, STOP instruction INT0 or timer A interrupt request from watch mode System oscillator Operating Operating Stopped Stopped Stopped Subsystem oscillator Operating Operating Operating*1 Operating Operating Instruction execution (øCPU) Operating Stopped Stopped Stopped Operating Peripheral Operating function interrupt(øPER) Operating Stopped Stopped Operating Clock function Operating interrupt (øCLK ) Operating Stopped Operating*2 Operating*2 RAM Operating Retained Retained Retained Operating Registers/ flags Operating Retained Reset Retained Operating I/O Operating Retained High Retained*3 3 impedance* Activation method Status Cancellation method Notes: 1. 2. 3. 4. 5. 24 Operating*3 RESET input, RESET input, RESET input RESET input, RESET input, STOP/SBY interrupt INT0 or timer STOP/SBY instruction instruction request A interrupt request To reduce current dissipation, stop all oscillation in external circuits. Refer to the Interrupt Frame section for details. Refer to table 17. Subactive mode is an optional function, specify it on the function option list. In the watch and subactive modes, the MCU requires a 32.768-kHz crystal oscillator. HD404618 Series System Clock (øCPU ) Non-time-base peripheral function clock (ø PER) Operating Operating Stopped Active mode Standby mode Subactive mode Stopped — Watch mode (TMA3 = 1) Stop mode (TMA3 = 0) Table 16 Operations in Low-Power Dissipation Modes Function Stop Mode Watch Mode*3 Standby Mode Subactive Mode*2, 3 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 4 Serial interface Reset Stopped* OP OP LCD Reset OP OP OP DTMF Reset Reset Stopped Reset Retained Retained OP I/O Reset* 1 Notes: OP indicates operating. 1. Output pins are at high impedance. 2. Subactive mode is an optional function specified on the function option list. 3. In the watch and subactive modes, the MCU requires a 32.768 kHz crystal oscillator. 4. Transmission/reception is activated if a clock is input in external clock mode. (However, interrupts stop.) 25 HD404618 Series Reset Standby mode Active mode Stop mode (TMA3 = 0) f OSC : fX: ø CPU: ø CLK : ø PER: Operating Operating Stopped f cyc f cyc f OSC : fX: ø CPU: ø CLK : ø PER: SBY (standby) Interrupt Timers A, B, C, Serial, INT0 , INT 1 Operating Operating f cyc f cyc f cyc (TMA3 = 0) STOP f OSC : fX: ø CPU: ø CLK : ø PER: Stopped Operating Stopped Stopped Stopped Watch mode (TMA3 = 1) f OSC : fX: ø CPU: ø CLK : ø PER: f OSC : fX: f cyc : f SUB : ø CPU : ø CLK : ø PER : LSON: DTON: Operating Operating Stopped f SUB f cyc SBY (standby) Interrupt Timers A, B, C, Serial, INT0 , INT 1 f OSC : fX: ø CPU: ø CLK : ø PER: (TMA3 = 1, LSON = 0) Operating Operating f cyc f SUB f cyc STOP INT0 , Timer A * 1 f OSC : fX: ø CPU: ø CLK : ø PER: Stopped Operating Stopped f SUB Stopped *3 *2 Main oscillation frequency Subactive mode Suboscillation frequency STOP (TMA3 = 1, LSON = 1) for time-base INT0 , f : Stopped f OSC : Stopped * 1 OSC f OSC /4 Timer A fX: Operating fX: Operating f X /8 ø : f ø : Stopped SUB CPU CPU System clock STOP/SBY ø : f ø : f SUB SUB CLK CLK Clock for time-base (LSON = 1) * 4 ø : f ø : Stopped SUB PER PER Clock for other peripheral functions Low speed on flag Notes: 1. Time-base interrupt Direct transfer on flag 2. STOP/SBY (DTON = 1, LSON = 0) 3. STOP/SBY (DTON = 0, LSON = 0) 4. DTON is not affected Figure 10 MCU Status Transitions Table 17 I/O Status in Low-Power Dissipation Modes Output Input Standby Mode, Watch Mode Stop Mode Active Mode, Subactive Mode D0–D 9 Retained High impedance Input enabled D10–D 13 — — Input enabled R0–R3 Retained High impedance Input enabled 26 HD404618 Series Active Mode: The MCU operates according to the clock generated by the system oscillators OSC1 and OSC2. Standby Mode: The MCU enters standby mode when the SBY instruction is executed from active mode. In this mode, the oscillators, interrupts, timer/counters, and serial interface continue to operate, but all instruction execution-related clocks stop. The stopping of these clocks stops the CPU, retaining all RAM and register contents and maintaining the current I/O pin status. 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 resumes, executing the next instruction after the SBY instruction. If the interrupt enable flag is 1, that 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 11. 27 HD404618 Series Standby Watch Oscillator: Active Peripheral clocks: Active All other clocks: Stopped Oscillator: Stopped Sub-oscillator: Active Peripheral clocks: Stopped All other clocks: Stopped RESET =1? No Yes No IF0 = 1? Yes IM0 = 0? Yes No No IF1 = 1? Yes IM1 = 0? Yes No No IFTA = 1? Yes IMTA = 0? No Yes (SBY only) No IFTB = 1? Yes IMTB = No 0? Yes (SBY only) No IFTC = 1? Yes IMTC = No 0? Yes (SBY only) IFS = No 1? Yes IMS = 0? (SBY only) No Yes Restart processor clocks Restart processor clocks Execute next instruction (active mode) No IF = 1, IM = 0, and IE = 1 ? Yes Reset MCU Execute next instruction Accept interrupt Figure 11 MCU Operation Flowchart in Watch and Standby Modes Stop Mode: The MCU enters stop mode if the STOP instruction is executed in active mode when TMA3 = 0. In this mode, the system oscillator stops, which stops all MCU functions as well. Stop mode is terminated by a RESET input as shown in figure 12. RESET must be high 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 are retained, 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. 28 , HD404618 Series Stop mode Oscillator Internal clock RESET t res t res> t RC (stabilization time) STOP instruction execution Figure 12 Timing of Stop Mode Cancellation Watch Mode: The MCU enters watch mode if the STOP instruction is executed in active mode when TMA3 = 1, or if the STOP or SBY instruc-tion 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 is 0, or subactive mode if LSON is 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 figure 13. Operation during mode transition is the same as that at standby mode cancellation (figure 12). 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 t RC Tx T = 2 × tRC: Interrupt frame length tRC: Oscillation stabilization period Figure 13 Interrupt Frame Subactive Mode: The CPU operates with a clock generated by the X1 and X2 oscillation circuits. Functions that can operate in subactive mode are listed in table 16. When the STOP or SBY instruction is executed in subactive mode, the MCU enters either watch or active mode, depending on the statuses of 29 HD404618 Series LSON and DTON. The DTON flag can only be set in subactive mode; it is automatically reset after a transition to active mode. Subactive mode is an optional function that the user must specify on the function option list. Interrupt Frame: In watch and subactive modes, ØCLK is supplied for timer A and the INT0 circuit. Prescaler W and timer A operate as time bases to generate interrupt frame timing. Three interrupt frame cycles (T) can be selected by the settings of the miscellaneous register, as shown in figure 14. In watch and subactive modes, timer A and INT0 interrupts are generated in synchronism with the interrupt frame. An interrupt request is generated at the interrupt strobe timing, except when the MCU enters active mode from watch mode. The INT0 falling edge is acknowledged regardless of the interrupt frame, but the interrupt is executed simultaneously with the next interrupt strobe. Timer A generates an overflow and interrupt request at the timing of an interrupt strobe. MIS: $00C MIS2 MIS1 MIS MIS0 T *1 t RC Bit 1 Bit 0 0 0 0.24414 ms *1 0.12207 ms 0.24414 ms *2 t RC selection 0 1 15.625 ms 7.8125 ms Refer to table 20 1 0 62.5 ms 31.25 ms 1 1 Not used Oscillation circuit condition External clock input 400/800-kHz ceramic oscillator — Notes: 1. The value of t RC applies only when using a 32.768-kHz oscillator. 2. Only direct transfer. Figure 14 Miscellaneous Register Direct Transfer: By controlling the DTON, the MCU would be placed directly from subactive to active mode. The detailed procedure is as follows: • Set the DTON flag in subactive mode while LSON = 0. • Execute the STOP or SBY instruction. • After the oscillation stabilization time (a fixed value), the MCU will move automatically from subactive to active mode. Note that DTON ($020, bit 3) is valid only in subactive mode. When the MCU is in active mode, this flag is always at reset. The transition time (tD) from subactive to active mode is tRC < tD < T + tRC. 30 HD404618 Series STOP/SBY execution Internal execution time (< T) Subactive mode Oscillation stabilization time Active mode (LSON = 0, DTON = 1) Interrupt strobe Direct transfer timing T t RC T: Interrupt frame length t RC : Oscillation stabilization period Figure 15 Direct Transfer Timing MCU Operating Sequence: The MCU operates in the sequence shown in figures 16 to 18. It is reset by an asynchronous RESET input, regardless of its state. The low-power mode operation sequence is shown in figure 18. 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/SBY instruction, make sure all interrupt flags are cleared or all interrupts are masked. Power on RESET = 1 ? Yes Reset MCU No MCU operation cycle Figure 16 MCU Operating Sequence (power on) 31 HD404618 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: Interrupt request flag IM: Interrupt mask IE: Interrupt enable flag PC ← next location PC ← vector address PC: Program counter CA: Carry flag ST: Status flag Figure 17 MCU Operating Sequence (MCU operation cycle) 32 HD404618 Series Low-power mode operation cycle IF = 1 IM = 0 ? No Yes Standby/watch mode No Stop mode IF = 1 IM = 0 ? Yes Hardware NOP execution Hardware NOP execution PC ← next Iocation PC ← next Iocation Instruction execution MCU operation cycle For IF and IM operation, refer to figure 12. Figure 18 MCU Operating Sequence (low-power mode operation) Notes on Use: • In subactive mode, the timer A interrupt request or the external interrupt request (INT 0) occurs in synchronism with the interrupt strobe. If the STOP or SBY instruction is executed at the same time with the interrupt strobe, these interrupt requests will be cancelled and the corresponding interrupt request flags (IFTA, IF0) will not be set. In subactive mode, do not use the STOP or SBY instruction at the time of the interrupt strobe. 33 HD404618 Series • When the MCU is in watch mode or subactive mode, if the high level period before the falling edge of INT 0 is shorter than the interrupt frame, INT 0 is not detected. Also, if the low level period after the falling edge of INT 0 is shorter than the interrupt frame, INT 0 is not detected. Edge detection is shown in figure 19. The level of the INT 0 signal is sampled by a sampling clock. When this sampled value changes to low from high, a falling edge is detected. In figure 20, 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 INT 0 longer than interrupt frame. INT0 Sampling High Low Low Figure 19 Edge Detection INT0 INT0 Interrupt frame Interrupt frame A: Low B: Low (a) High level period Figure 20 Sampling Example 34 A: High B: High (b) Low level period HD404618 Series Internal Oscillator Circuit Figure 21 shows a block diagram of the internal oscillator circuit. A ceramic oscillator can be connected to OSC1 and OSC2, and a 32.768-kHz crystal oscillator can be connected to X1 and X2. The system oscillator can also be operated by an external clock. OSC1 System oscillator f OSC Subsystem oscillator fX Divider (1/4) Timing generator f cyc Divider (1/8) Timing generator f SUB Mode control circuit OSC2 X1 System clock (ø PER ) Timer-base clock (ø CLK ) Figure 21 Internal Oscillator Circuit D0 COMP1/D13 RESET OSC 2 TEST X1 $%&',- X2 System clock (ø CPU ) X2 OSC 1 V CC GND VT ref SCK/R0 0 GND Figure 22 Layout of Crystal and Ceramic Oscillators 35 HD404618 Series Table 18 Oscillator Circuit Examples Circuit Configuration External clock operation (OSC1, OSC 2) Circuit Constants External oscillator OSC 1 Open OSC 2 Ceramic oscillator (OSC1, OSC 2) Ceramic oscillator: CSB400P22, CSB400P (Murata) Rf = 1 MΩ ± 20% C1 = C2 = 220 pF ± 5% Ceramic oscillator: CSB800J122, CSB800J(Murata) Rf = 1 MΩ ± 20% C1 = C2 = 220 pF ± 5% C1 OSC1 Ceramic Rf OSC2 C2 GND Crystal oscillator Crystal: 32.768 kHz: MX38T (Nippon Denpa Kogyo) Rs = 14 kΩ C0 = 1.5 pF C1 = 20 pF ± 20% C2 = 20 pF ± 20% C1 X1 Crystal X2 C2 GND L CS RS C0 Notes: 1. The circuit constants given above are recommended values provided by the oscillator manufacturer. Since they may be affected by stray capacitances from the oscillator or board, consult the crystal or ceramic oscillator manufacturer to determine the actual circuit parameters required. 2. Wiring between the OSC1/OSC2 pins (X1, X2 pins) and other elements must be as short as possible, and must not cross other wiring. Refer to the recommended layout of the crystal and ceramic oscillator in figure 22. 3. If a 32.768-kHz crystal oscillator is not used, fix the X1 pin to VCC and leave the X2 pin open. 36 HD404618 Series Input/Output The MCU provides 26 input/output pins and 4 input pins, including 10 high-current pins (15 mA, max.). A program-controlled pull-up MOS transistor is provided for each input/output pin. The output buffer is turned on and off by the data control register (DCR) during input through an input/output pin. I/O pin circuit types are shown in table 19. D Ports (D 0–D13): Consist of ten 1-bit input/output pins and four input pins. Pins D0–D9 are high-current I/O pins (15 mA, max.). The sum current of the pins can go up to 100 mA. These pins are set by the SED and SEDD instructions, reset by the RED and REDD instructions, and tested by the TD and TDD instructions. Output data is stored in the port data register. The on/off status of the output buffer is controlled by D port data control registers (DCRB, DCRC, and DCRD) that are mapped to the memory address area. Pins D10–D13 are input-only pins. Two operating modes are available to pins D 12 and D13: digital input mode and analog input mode. The operating modes are set by bits 0 and 1 of port mode register B (PMRB). In the digital input mode, these pins can be used as input pins with the same input characteristics as the I/O pins. In the analog input mode, the result of a comparison with the reference voltage can be read as input data. The reference voltage is input by the D11/VCref pin. R Ports: Consist of sixteen 4-bit I/O ports. Data is input to these ports by the LAR and LBR instructions and output from them by the LRA and LRB instructions. The on/off status of the output buffers of the R ports are controlled by R port data control registers (DCR0– DCR3) that are mapped to memory addresses. Pins R00, R01, and R0 2 are multiplexed with pins SCK, SI, and SO, respectively. Pins R31, R32, and R3 3 are multiplexed with TIMO, INT0, and INT 1, respectively. Refer to figure 24. 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 of port mode register B (PMRB), and the on/off status of an individual transistor can also be controlled by the port data register (PDR) of the corresponding pin. This enables on/off control of each individual pin. Refer to table 20. 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 must be connected to VCC to prevent LSI malfunctions due to noise. These pins must either be pulled up to VCC by their pull-up transistors or by resistors of about 100 kΩ. 37 HD404618 Series Table 19 Circuit Configurations of I/O Pins I/O Pin Type Common I/O pin (with pull-up MOS transistor) Circuit Applicable Pins VCC Pull-up control signal VCC DCR Output data PDR D0–D 9 R0 0–R0 3 R1 0–R1 3 R2 0–R2 3 R3 0–R3 3 Input data Input control signal SCK VCC Pull-up control signal VCC DCR Output data SCK (internal) SCK Output pin (with pull-up MOS transistor) SO, TIMO VCC Pull-up control signal VCC DCR Output data Input pin SO or TIMO INT0 , INT1 SI VCC PDR Pull-up control signal Input data Input control signal Input control VCref + – Input data Analog input Mode select signal Note: Refer to table 20, note 3 concerning R0 2/SO. 38 D10 D11/VCref D12/COMP0 D13/COMP1 (multiplexed with analog inputs) HD404618 Series Pin Internal bus MPX Comparator + – VC ref Mode register Figure 23 Configuration of D12 and D13 39 HD404618 Series Serial mode register: $005 (SMR) SMR 3 2 1 0 Bit 3 Port selection 0 R0 0 1 SCK R0 0 /SCK pin mode selection Port mode register A: $004 (PMRA) 3 2 1 0 R0 2 R01 R3 2 R3 3 PMRA Port selection Bit 3 0 R3 3 1 INT1 PMRA Bit 2 /SO pin mode selection /SI pin mode selection /INT0 pin mode selection /INT1 pin mode selection Port selection 0 R3 2 1 INT0 PMRA Bit 1 0 1 Port selection PMRA Bit 0 Port selection R01 0 R0 2 SI 1 SO Port mode register B: $012 (PMRB) 3 2 1 0 D12 /COMP0 pin mode selection D13 /COMP1 pin mode selection R3 1 /TIMO pin mode selection Pull-up MOS on/off selection PMRB Bit 3 Pull-up MOS on/off 0 Off 0 1 On 1 PMRB Bit 2 Port selection PMRB Bit 1 R3 1 0 D13 0 D12 TIMO 1 COMP1 1 COMP0 Port selection PMRB Figure 24 I/O Switching Mode Registers 40 Bit 0 Port selection HD404618 Series Table 20 Programmable I/O Circuits PMRB Bit 3 (PMRB3) 0 DCR 0 PDR 0 1 0 1 0 1 0 1 PMOS (A) — — — On — — — On NMOS (B) — — On — — — On — — — — — — On — On CMOS Buffer Pull-up MOS Transistor 1 1 0 1 Notes: 1. —: Off 2. Various I/O methods can be selected by different combinations of settings of the above mode registers (PMRB3, DCR, PDR). 3. The PMOS (A) transistor of the R1 2/SO pin can be turned off by setting bit 2 of the miscellaneous register (MIS) to 1. MIS Bit 2 R0 2/SO Pin PMOS (A) 0 On 1 Off 4. The relationships between DCRs and pins are as shown below. DCR Bit 3 Bit 2 Bit 1 Bit 0 DCR0 R0 3 R0 2 R0 1 R0 0 DCR1 R1 3 R1 2 R1 1 R1 0 DCR2 R2 3 R2 2 R2 1 R2 0 DCR3 R3 3 R3 2 R3 1 R3 0 DCRB D3 D2 D1 D0 DCRC D7 D6 D5 D4 DCRD — — D9 D8 41 HD404618 Series VCC PMRB3 VCC Pull-up MOS transistor PMOS (A) DCR NMOS (B) PDR Input data Input control signal Figure 25 I/O Buffer Configuration 42 HD404618 Series Timers The MCU has two prescalers (S and W) and three timer/counters (A, B, and C). Figures 26, 27 and 28 show their diagrams. Prescaler S: Eleven-bit counter that inputs the system clock signal. After being initialized to $000 by MCU reset, prescaler S divides the system clock. Prescaler S keeps counting, except at MCU reset and in the stop and watch modes. Of the prescaler S outputs, timer A input clock, timer B input clock, timer C input clock, and serial interface transmit clock are selected by timer mode register A (TMA), timer mode register B (TMB), timer mode register C (TMC), and the serial mode register (SMR), respectively. Prescaler W: Five-bit counter that inputs the X1 input clock signal divided by eight. Prescaler W output can be selected as a timer A input clock by timer mode register A (TMA). Timer A: Eight-bit timer that can be used as a clock time-base (figure 26). It is initialized to $00 and incremented at each clock input. If an input clock is applied to timer A after it has reached $FF, an overflow that sets the timer A interrupt request flag (IFTA: $001, bit 2) is generated, and timer A restarts from $00. Timer A is used to generate regular interrupts (every 256 clocks) for measuring times between events. It can also be used as a clock time-base when bit 3 of timer mode register A (TMA) is set to 1. The timer is driven by the 32-kHz oscillator clock frequency divided by prescaler W, and the clock input to timer A is controlled by TMA. In this case, prescaler W and timer A can be initialized to $00 by software. (tsubcyc) 1/4 1/2 fSUB 2 fSUB Timer A interrupt request flag (IFTA) Prescaler W (PSW) ÷2 ÷8 ÷ 16 ÷ 32 32.768-kHz oscillator 1/2 tsubcyc 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 26 Timer A Block Diagram 43 HD404618 Series Timer B (TCBL and TLRL: $00A, TCBU and TLRU: $00B): Eight-bit write-only timer load register (TLRL and TLRU) and read-only timer counter (TCBL and TCBU) located at the same addresses. The eight-bit configuration consists of lower and upper 4-bit digits located at sequential addresses. A block diagram of timer B is shown in figure 27. Timer counter B is initialized by writing to timer load register B (TLR). In this case, the lower digit must be written to first. The contents of TLR are loaded into the timer counter at the same time the upper digit is written to, initializing the timer counter. TLR is initialized to $00 by MCU reset. The count of timer B is obtained by reading timer counter B. In this case, the upper digit must be read first; the count is latched when the upper digit is read. An auto-reload function, input clock source, and prescaler division ratio of timer B depend on the state of timer mode register B (TMB). When an external event input is used as the input clock source of TMB, the R3 3/INT 1 pin must be set to INT 1 by setting port mode register A (PMRA: $004). Timer B is initialized to the value set in TMB by software, and is then incremented by one each clock input. If an input is applied to timer B after it has reached $FF, an overflow is generated. In this case, if the auto-reload function is enabled, timer B is initialized to its initial value; if auto-reload is disabled, the timer is initialized to $00. The overflow sets the timer B interrupt request flag (IFTB: $002, bit 0). 44 HD404618 Series Timer B interrupt request flag (IFTB) Timer counter register BU (TCBU) Timer counter register BL (TCBL) Clock f System cyc/fSUB clock (t /t cyc subcyc) ÷ 2048 INT1 ÷2 ÷4 ÷8 ÷ 32 ÷ 128 ÷ 512 Selector Timer load register BU (TLRU) Prescaler S (PSS) Free-running control Timer load register BL (TLRL) Internal data bus Timer counter B (TCB) Overflow 3 Timer mode register B (TMB) Figure 27 Timer B Block Diagram Timer C (TCCL and TCRL: $00E, TCCU and TCRU: $00F): Eight-bit write-only timer load register (TCRL and TCRU) and read-only timer counter (TCCL and TCCU) located at the same addresses. The eight-bit configuration consists of lower and upper 4-bit digits located at sequential addresses. The operation of timer C is basically the same as that of timer B. The auto-reload function and prescaler division ratio of timer C depend on the state of timer mode register C (TMC). Timer C is initialized to the value set in TMC by software, and is then incremented by one at each clock input. If an input is applied to timer C after it has reached $FF, an overflow is generated. In this case, if the auto-reload function is enabled, timer C is initialized to its initial value; if auto-reload is disabled, the timer is initialized to $00. The overflow sets the timer C interrupt request flag (IFTC: $002, bit 2). Timer C also functions as a watchdog timer. If a program routine runs out of control and an overflow is generated while the watchdog on (WDON) flag is set, the MCU is reset. This error can be detected by having the program control timer C reset before timer C reaches $FF. The WDON can only have 1 written to it ; it is cleared to 0 only by MCU reset. Timer Mode Register A (TMA: $008): Four-bit write-only register that controls timer A as shown in table 21. 45 HD404618 Series System reset signal Watchdog on flag (WDON) TIMO Timer C interrupt request flag (IFTC) Watchdog timer control logic Timer output control logic Timer counter register CU (TCCU) Clock Timer counter C (TCC) System fcyc/fSUB clock (t /t cyc subcyc) ÷2 ÷4 ÷8 ÷32 ÷128 ÷512 ÷1024 ÷2048 Selector Prescaler S (PSS) Overflow Timer load register CU (TCRU) Free-running /Reload control Timer load register CL (TCRL) 3 Timer mode register C (TMC) Figure 28 Timer C Block Diagram 46 Internal data bus Timer counter register CL (TCCL) HD404618 Series Table 21 Timer Mode Register A TMA Bit 3 Bit 2 Bit 1 Bit 0 Source Prescaler, Input Clock Period, Operating Mode 0 0 0 0 PSS, 2048 tcyc 1 PSS, 1024 tcyc 0 PSS, 512 tcyc 1 PSS, 128 tcyc 0 PSS, 32 tcyc 1 PSS, 8 tcyc 0 PSS, 4 tcyc 1 PSS, 2 tcyc 0 PSW, 32 t subcyc 1 PSW, 16 t subcyc 0 PSW, 8 t subcyc 1 PSW, 2 t subcyc 0 PSW, 1/2 tsubcyc 1 Not used 0 PSW, TCA reset 1 1 0 1 1 0 0 1 1 0 1 Timer A mode Time-base mode 1 Notes: 1. t subcyc = 244.14 µs (when 32.768-kHz crystal oscillator is used) 2. Timer counter overflow output period(s) = input clock period(s) × 256 3. If PSW or TCA reset is selected while the LCD is operating, LCD operation halts (power switch goes off). When LCD is connected for display, the PSW and TCA reset periods must be set in the program to the minimum. 4. In time base mode, the timer counter overflow output cycle must be greater than half of the interrupt frame period (T/2 = tRC). If 1/2 tsubcyc is selected, t RC must be 7.8125 ms ((MIS1, MIS0) = (0, 1), see figure 14). 5. The division ratio must not be modified during time-base mode operation, otherwise an overflow cycle error will occur. 47 HD404618 Series T × (TCR + 1) TMC3 = 0 T × 256 T TMC3 = 1 T × (256 – TCR) T: Period of clock input to the counter (table 23) TCR: Value of timer load register C (0–255) Note: This waveform is always fixed low when TCR = $FF. Figure 29 Variable-Duty Pulse Output Waveform Timer Mode Register B (TMB: $009): Four-bit write-only register that selects the auto-reload function, the prescaler division ratio, and input clock source as shown in table 22. Timer mode register B is initialized to $0 by MCU reset. Writing to this register is valid from the second instruction execution cycle. Timer B initialization set by writing to TMB must be done after a mode change becomes valid. Table 22 Timer Mode Register B TMB Bit 3 Auto-Reload Function 0 Disabled 1 Enabled TMB Bit 2 Bit 1 Bit 0 Prescaler Division Ratio, Clock Input Source 0 0 0 ÷ 2048 0 0 1 ÷ 512 0 1 0 ÷ 128 0 1 1 ÷ 32 1 0 0 ÷8 1 0 1 ÷4 1 1 0 ÷2 1 1 1 INT1 (external event input) 48 HD404618 Series Timer Mode Register C (TMC: $00D): Four-bit write-only register that selects the auto-reload function and prescaler division ratio as shown in table 23. Timer mode register C is initialized to $0 by MCU reset. Writing to this register is valid from the second instruction execution cycle. Timer C initialization set by writing to TMC must be done after a mode change becomes valid. Table 23 Timer Mode Register C TMC Bit 3 Auto-Reload Function 0 Disabled 1 Enabled TMC Bit 2 Bit 1 Bit 0 Prescaler Division Ratio, Clock Input Source 0 0 0 ÷ 2048 0 0 1 ÷ 1024 0 1 0 ÷ 512 0 1 1 ÷ 128 1 0 0 ÷ 32 1 0 1 ÷8 1 1 0 ÷4 1 1 1 ÷2 49 HD404618 Series Note on Use When using the timer output as PWM output, note the following point. From the update of the timer write register untill the occurrence of the overflow interrupt, the PWM output differs from the period and duty settings, as shown in table 24. 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. Table 24 PWM Output Following Update of Timer Write Register PWM Output Mode Timer Load Register is Updated during High PWM Output Timer load register updated to value N Free running Timer Load Register is Updated during Low PWM Output Timer load register updated to value N Interrupt request T × (255 – N) T × (N + 1) Interrupt request T × (N' + 1) T × (255 – N) Timer load register updated to value N Reload T Interrupt request T × (255 – N) T Timer load register updated to value N Interrupt request T T × (255 – N) 50 T × (N + 1) T HD404618 Series Serial Interface The MCU has a clock-synchronous serial interface which transmits and receives 8-bit data. The serial interface consists of a serial data register (SR), serial mode register (SMR), port mode register A (PMRA), octal counter, and multiplexers (see figure 30). The R0 0/SCK pin and the transmit clock are controlled by writing to the SMR. The transmit clock shifts the contents of the SR, which can be read and written to by software. The serial interface is activated by the STS instruction. The octal counter is reset to 000 by this instruction, starts counting at the falling edge of the transmit clock (SCK), and it increments at the rising edge of the clock. A serial interrupt request flag is set when the eighth transmit clock signal is input (the serial interface is reset) or when serial transmission is discontinued (the octal counter is reset). Octal counter (OC) SO I/O control logic Serial interrupt request flag (IFS) SCK I/O control logic SI Clock Selector 1/2 Transfer control signal Internal data bus Serial data register (SR) Selector ÷2 ÷8 ÷ 32 ÷ 128 ÷ 512 ÷ 2048 3 System clock fcyc/fsub Prescaler S (PSS) (tcyc/tsubcyc) Serial mode register (SMR) Port mode register A (PMRA) Figure 30 Serial Interface Block Diagram Serial Mode Register (SMR: $005): Four-bit write-only register that controls the R00/SCK pin, prescaler division ratio, and transmit clock source (table 25 and figure 31). Writing to this register initializes the serial interface. 51 HD404618 Series A write signal input to the serial mode register discontinues the input of the transmit clock to the serial data register and octal counter. Therefore, if a write is performed during data transmission, the octal counter is reset to 000 to stop transmission, and at the same time, the serial interrupt request flag is set. Write operations are valid from the second instruction execution cycle, so the STS instruction must be executed after at least two cycles have been executed. The serial mode register is initialized to $0 by MCU reset. Table 25 Serial Mode Register SMR Bit 3 R0 0/SCK Pin 0 R0 0 port input/output pin 1 SCK input/output pin SMR Transmit Clock Bit 2 Bit 1 Bit 0 R0 0/SCK Pin Clock Source Prescaler Division Ratio System Clock Division Ratio 0 0 0 SCK output Prescaler ÷ 2048 ÷ 4096 0 0 1 SCK output Prescaler ÷ 512 ÷ 1024 0 1 0 SCK output Prescaler ÷ 128 ÷ 256 0 1 1 SCK output Prescaler ÷ 32 ÷ 64 1 0 0 SCK output Prescaler ÷8 ÷ 16 1 0 1 SCK output Prescaler ÷2 ÷4 1 1 0 SCK output System clock — ÷1 1 1 1 SCK input External clock — — PMRA: $004 PMRA3 PMRA2 PMRA1 PMRA0 SMR: $005 SMR3 SMR2 SMR1 SMR0 Transmit clock selection R0 0 /SCK pin mode selection R02 /SO pin mode selection R01 /SI pin mode selection Figure 31 Configurations and Functions of the Mode Registers 52 HD404618 Series Serial Data Register (SRL: $006, SRU: $007): Eight-bit read/write register separated into upper and lower digits located at sequential addresses. Data in this register is output from the SO pin, LSB first, in synchronism with the falling edge of the transmit clock, and data is input LSB first through the SI pin at the rising edge of the transmit clock. Input/output timing is shown in figure 32. Data cannot be read or written during serial data transmission. If a read/write occurs during transmission, the accuracy of the resultant data cannot be guaranteed. Transmit clock 1 Serial output data 2 3 4 5 LSB 6 7 8 MSB Serial input data latch timing Figure 32 Serial Interface Timing Selecting and Changing Operating Mode: Table 26 lists the serial interface operating modes. To select an operating mode, use one of these combinations of PMR and SMR settings; to change the operating mode, always initialize the serial interface internally by writing to the SMR. Table 26 Serial Interface Operating Modes SMR PMRA Bit 3 Bit 1 Bit 0 Operating Mode 1 0 0 Continuous clock output mode 1 0 1 Transmit mode 1 1 0 Receive mode 1 1 1 Transmit/receive mode Serial Interface Operation: Three operating modes are provided for the serial interface; transitions between them are shown in figure 33. In STS waiting state, the serial interface is initialized and the transmit clock is ignored. If the STS instruction is then executed, the serial interface enters transmit clock wait state. In transmit clock wait state, input of the transmit clock increments the octal counter, shifts the serial clock register, and activates serial transmission. However, note that if clock output mode is selected, the transmit clock is continuously output but data is not transmitted. 53 HD404618 Series During transmission, the input of eight clocks or the execution of the STS instruction sets the octal counter to 000, and the serial interface enters transmit clock wait state. If the state changes from transmit to another state, the serial interrupt request flag is set by the octal counter reaching 000. STS instruction wait state ST S SM R ins tru cti on ite wr ) R 1 ← SM al S rn (IF te (in s ck 1) clo ← it S m IF ns ( tra ) 8 ock cl wr i te octal counter = 000 transmit clock disabled Transmit clock Transmit clock wait state Transfer state 8 transmit clocks (external clock) (octal counter = 000) STS instruction (octal counter ≠ 000) (IFS ← 1) Figure 33 Serial Interface Mode Transitions In this state, if the internal clock has been selected, the transmit clock is output in answer to the execution of the STS instruction, but serial transmission is inhibited after the eighth clock is output. If port mode register A (PMRA) is written to in transmit clock wait state or during transmission, the serial mode register (SMR) must be written to, to initialize the serial interface. The serial interface then enters STS wait state. If the serial interface shifts from transfer state to another state, the octal counter returns to 000, setting the serial interrupt request flag. Transmit Clock Error Detection: The serial interface will malfunction if a spurious pulse caused by external noise conflicts with a normal transmit clock during transmission. A transmit clock error of this type can be detected as shown in figure 34. If more than eight transmit clocks are input in transmit clock wait state, the serial interface state changes to transfer, transmit clock wait, then back to transfer. If the serial interface is set to STS wait state by writing data to the SMR after the serial interrupt request flag has been reset, the flag is set again. 54 HD404618 Series Transmission completion (IFS ←1) Interrupts inhibited IFS ← 0 SMR write IFS = 1 ? Yes Transmit clock error processing No Normal termination Figure 34 Transmit Clock Error Detection Note on Use: The serial interrupt request flag might not be set if the status is changed from transfer by the execution of an SMR write or STS instruction during the first period that the transmit clock is low. To prevent this, program a check that the SCK pin is at 1 (by executing an input instruction for the R1 port) before the execution of an SMR write or STS instruction, to ensure that the serial interrupt request flag is set. 55 HD404618 Series Liquid Crystal Display (LCD) The MCU has an LCD controller and driver which drive 4 common signal pins and 32 segment signal pins. The controller consists of a RAM area in which display data is stored, a display control register (LCR), and a duty/clock control register (LMR), as shown in figure 37. Four duties and the LCD clock are program-controllable, and a built-in dual-port RAM ensures that display data can be automatically transmitted to the segment signal pins without program intervention. If a 32-kHz oscillation clock is selected as the LCD clock source, the LCD can be used even in watch mode, in which the system clock stops. V CC Power switch V1 V2 V3 COM1 LCD common driver LCD power control circuit COM2 COM3 COM4 LCD clock Display on/off GND SEG1 1 2 LCD control register (LCR: $013) SEG2 $050 Display area (Dual-port RAM) LCD segment driver LCD duty/clock $06F control register (LMR: $014) 2 2 SEG32 RAM area Duty cycle selection Clock selection LCD clock 3 LCD: Liquid crystal display Divided system clock output (CL1–CL3) 1 Divided 32-kHz clock output (CL0) Figure 35 Liquid Crystal Display Block Diagram LCD Data Area and Segment Data ($050– $06F): Figure 36 shows the configuration of LCD RAM area. Each bit of the storage area corresponds to one of four types of duties. If data is written to an area corresponding to a certain duty cycle, it is automatically output to the corresponding segments as display data. 56 HD404618 Series Bit 3 Bit 2 Bit 1 Bit 0 Bit 3 Bit 2 Bit 1 Bit 0 80 SEG1 SEG1 SEG1 SEG1 $050 96 SEG17 SEG17 SEG17 SEG17 $060 81 SEG2 SEG2 SEG2 SEG2 $051 97 SEG18 SEG18 SEG18 SEG18 $061 82 SEG3 SEG3 SEG3 SEG3 $052 98 SEG19 SEG19 SEG19 SEG19 $062 83 SEG4 SEG4 SEG4 SEG4 $053 99 SEG20 SEG20 SEG20 SEG20 $063 84 SEG5 SEG5 SEG5 SEG5 $054 100 SEG21 SEG21 SEG21 SEG21 $064 85 SEG6 SEG6 SEG6 SEG6 $055 101 SEG22 SEG22 SEG22 SEG22 $065 86 SEG7 SEG7 SEG7 SEG7 $056 102 SEG23 SEG23 SEG23 SEG23 $066 87 SEG8 SEG8 SEG8 SEG8 $057 103 SEG24 SEG24 SEG24 SEG24 $067 88 SEG9 SEG9 SEG9 SEG9 $058 104 SEG25 SEG25 SEG25 SEG25 $068 89 SEG10 SEG10 SEG10 SEG10 $059 105 SEG26 SEG26 SEG26 SEG26 $069 90 SEG11 SEG11 SEG11 SEG11 $05A 106 SEG27 SEG27 SEG27 SEG27 $06A 91 SEG12 SEG12 SEG12 SEG12 $05B 107 SEG28 SEG28 SEG28 SEG28 $06B 92 SEG13 SEG13 SEG13 SEG13 $05C 108 SEG29 SEG29 SEG29 SEG29 $06C 93 SEG14 SEG14 SEG14 SEG14 $05D 109 SEG30 SEG30 SEG30 SEG30 $06D 94 SEG15 SEG15 SEG15 SEG15 $05E 110 SEG31 SEG31 SEG31 SEG31 $06E 95 SEG16 SEG16 SEG16 SEG16 $05F 111 SEG32 SEG32 SEG32 SEG32 $06F COM4 COM3 COM2 COM1 COM4 COM3 COM2 COM1 Figure 36 Configuration of LCD RAM Area LCD Control Register (LCR: $013): Three-bit write-only register which controls LCD blanking, the turning on and off of the LCD’s power supply division resistor, and display in watch and subactive modes (see table 27). • Blank/display Blank: Segment signals are turned off regardless of LCD RAM data setting. Display: LCD RAM data is output as segment signals. • Power switch on/off Off: The power switch is off. On: The power switch is on and V1 is VCC. • Watch/subactive mode display Off: In watch and subactive modes, all common and segment pins are grounded and the liquid crystal power switch is turned off. On: In watch and subactive modes, LCD RAM data is output as segment signals. 57 HD404618 Series Table 27 LCD Control Register LCR LCR LCR Bit 2 Display in Watch Mode or Subactive Mode Bit 1 Power Switch On/Off Bit 0 Blank/Display 0 Off 0 Off 0 Blank 1 On 1 On 1 Display Note: When using an LCD in watch mode or subactive mode, use the divided output of a 32-kHz oscillator as the LCD clock and set bit 2 of the LCR to 1. If using the divided output of the system clock as the LCD clock, always set bit 2 of the LCR to 0. LCD Duty/Clock Control Register (LMR: $014): Four-bit write-only register which selects the display duty and LCD clock source, as shown in table 28. Table 28 LCD Duty/Clock Control Register LMR Bit 3 Bit 2 Bit 1 Bit 0 Duty Selection/Input Clock Selection — — 0 0 1/4 duty cycle — — 0 1 1/3 duty cycle — — 1 0 1/2 duty cycle — — 1 1 Static 0 0 — — CL0 (32.768/64 kHz when using 32.768-kHz oscillator) 0 1 — — CL1 (fcyc/256) 1 0 — — CL2 (fcyc/2048) 1 1 — — CL3 (refer to table 29) Note: fcyc is the divided system clock output. 58 HD404618 Series LCD control register: $013 (LCR) 2 1 0 Blank/display Power switch on/off Display on/off in watch mode (not used) LCD duty/clock control register: $014 (LMR) 3 2 1 0 Duty cycle Input clock Figure 37 LCD Control and LCD Mode Registers 59 HD404618 Series Table 29 LCD Frame Periods for Different Duties Static Duty LMR Instruction cycle time Bit 3 0 Bit 2 0 Bit 3 0 Bit 2 1 Bit 3 1 Bit 2 0 Bit 3 1 CL0 CL1 CL2 CL3* 10 µs 512 Hz 390.6 Hz 48.8 Hz 24.4 Hz/64 Hz 5 µs 512 Hz 781.2 Hz 97.6 Hz 48.8 Hz/64 Hz 1/2 Duty LMR Instruction cycle time Bit 3 0 Bit 2 0 Bit 3 0 Bit 2 1 Bit 3 1 Bit 2 0 Bit 3 1 CL0 CL1 CL2 CL3* 10 µs 256 Hz 195.3 Hz 24.4 Hz 12.2 Hz/32 Hz 5 µs 256 Hz 390.6 Hz 48.8 Hz 24.4 Hz/32 Hz 1/3 Duty LMR Instruction cycle time Bit 3 0 Bit 2 0 Bit 3 0 Bit 2 1 Bit 3 1 Bit 2 0 Bit 3 1 CL0 CL1 CL2 CL3* 10 µs 170.6 Hz 130.2 Hz 16.3 Hz 8.1 Hz/21.3 Hz 5 µs 170.6 Hz 260.4 Hz 32.6 Hz 16.2 Hz/21.3 Hz 1/4 Duty LMR Instruction cycle time Bit 3 0 Bit 2 0 Bit 3 0 Bit 2 1 Bit 3 1 Bit 2 0 Bit 3 1 CL0 CL1 CL2 CL3* 10 µs 128 Hz 97.7 Hz 12.2 Hz 6.1 Hz/16 Hz 5 µs 128 Hz 195.4 Hz 24.4 Hz 12.2 Hz/16 Hz Bit 2 1 Bit 2 1 Bit 2 1 Bit 2 1 Note: * The division ratio depends on the value of bit 3 of timer mode register A (TMA3): The first value is for TMA3 = 0 and the second is for TMA3 = 1. When TMA3 = 0, CL3 = f cyc × duty cycle/4096. When TMA3 = 1, CL3 = 32.768 kHz × duty cycle/512 60 HD404618 Series Large Liquid-Crystal Panel Drive and VLCD : To drive a large-capacity LCD, decrease the resistance of the built-in division resistors by attaching external resistors in parallel, as shown in figure 38. The size of these resistors cannot be simply calculated from the LCD load capacitance because the matrix configuration of the LCD complicates the paths of charge/discharge currents flowing through the capacitors. The resistance will also vary with lighting conditions. This size must be determined by trial and error, taking into account the power dissipation of the device using the LCD, but a resistance of 1 to 10 kΩ would usually be suitable. (Another effective method is to attach capacitors of 0.1 to 0.3 µF.) Always turn off the power switch (set bit 1 of the LCR to 0) before changing the liquid crystal drive voltage (VLCD). VCC (V1 ) VCC (V1 ) R R C V2 V2 R R C V3 V3 C R C = 0.1 to 0.3 µF R GND GND VCC VCC VLCD COM1 . V1 SEG1 V2 to V3 SEG32 GND 4-digit LCD with sign 32 Static drive VCC VCC VCC VLCD COM1 COM2 2 . V1 SEG1 V2 to V3 SEG32 GND 8-digit LCD 32 1/2 duty cycle, 1/2 bias drive 3 10-digit LCD VCC COM1 to . with sign COM3 V 1 VLCD V2 SEG1 to V3 GND SEG32 32 1/3 duty cycle, 1/3 bias drive VCC VCC VCC ≥ V LCD ≥ GND VLCD COM1 to COM4 4 V1 V2 SEG1 to V3 GND SEG32 . 16-digit LCD 32 1/4 duty cycle, 1/3 bias drive Figure 38 LCD Connection Examples 61 HD404618 Series DTMF Generation Circuit The MCU has a dual-tone multifrequency (DTMF) generation circuit. The DTMF signal consists of two sine waves to access the switching system. Figure 39 shows the DTMF keypad and frequencies. Pressing a key generates a tone corresponding to its frequency. Figure 40 shows a block diagram of the DTMF circuit. The MCU uses an oscillation frequency reduced to 400 kHz, an eighth of the conventionally used frequency, for low-power consumption. This, however, causes a potential frequency deviation. The MCU provides transformed programmable dividers in addition to sine wave counters and a control register to reduce frequency deviation. 1 2 3 A R1 (697 Hz) 4 5 6 B R2 (770 Hz) 7 8 9 C R3 (852 Hz) * 0 # D R4 (941 Hz) C1 (1209 Hz) C2 (1336 Hz) C3 (1477 Hz) C4 (1633 Hz) The DTMF generation circuit is controlled by the following three registers. Figure 39 DTMF Keypad and Frequencies 62 HD404618 Series 400 kHz (selected at TGSP reset) 800 kHz Transformed programmable divider Sine wave counter D/A TONER Feedback TGSP flag DTMF register VTref Transformed programmable divider Sine wave counter D/A TONEC Feedback Figure 40 DTMF Circuit Block Diagram Tone Generator Mode Register (TGM: $010): Four-bit write-only register which controls output frequencies (see table 30). It is cleared to $0 by MCU reset. Table 30 Tone Generator Mode Register TGM Bit 3 Bit 2 Option (TONER output is not affected) Bit 1 Bit 0 Output Frequencies 0 0 f R1 (697 Hz) 0 1 f R2 (770 Hz) 1 0 f R3 (852 Hz) 1 1 f R4 (941 Hz) 0 0 Option (TONEC output is not affected) f C1 (1,209 Hz) 0 1 f C2 (1,336 Hz) 1 0 f C3 (1,477 Hz) 1 1 f C4 (1,633 Hz) Output through TONER pin Output through TONEC pin Tone Generator Control Register (TGC: $011): Three-bit write-only register which controls the start and stop of DTMF signal output (see table 31). It is cleared to $0 by MCU reset. 63 HD404618 Series Table 31 Tone Generator Control Register TGC Bit 1 DTMF Enable Bit 0 DTMF disabled 1 DTMF enabled TGC Bit 2 TONER Output Control (row) 0 Stopped 1 TONER output (active) TGC Bit 3 TONEC Output Control (column) 0 Stopped 1 TONEC output (active) Tone Generator Speed Flag (TGSP: $020,Bit 2): One-bit register which can be set and reset by the SEM/REM and SEMD/REMD instructions. The DTMF generation circuit generates output frequencies with a 400-kHz clock (table 30). With an 800-kHz clock, the DTMF generation circuit generates these same frequencies by pulling the TGSP flag high. DTMF Output: The sine waves of the row-group and column-group are individually converted from digital to analog in the D/A conversion circuit, which provides high-precision ladder resistance. The DTMF output pins, TONER and TONEC, transmit the sine waves of the row-group and column-group, respectively. Figure 41 shows thetone output equivalent circuit. Figure 42 shows the output waveform. One cycle of this wave consists of 32 time slots, making the output waveform stable with little distortion. Table 32 lists the frequency deviation of the MCU from standard DTMF signals. Switch control VT ref GND TONER TONEC Figure 41 Tone Output Equivalent Circuit 64 HD404618 Series VT ref 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 GND Time slots Figure 42 Waveform of Tone Output Table 32 Frequency Deviation of the MCU from Standard DTMF Signals Standard DTMF (Hz) MCU (Hz) Deviation from Standard (%) R1 697 694.44 –0.37 R2 770 769.23 –0.10 R3 852 851.06 –0.11 R4 941 938.97 –0.22 C1 1,209 1,212.12 0.26 C2 1,336 1,333.33 –0.20 C3 1,477 1,481.48 0.30 C4 1,633 1,639.34 0.39 Note: This frequency deviation value does not include the frequency deviation due to the oscillator element. Also note that in this case the ratio of the high level and low level widths in the oscillator waveform due to the oscillator element will be 50% : 50%. 65 HD404618 Series Programmable ROM The HD4074618 is a ZTAT microcomputer with built-in PROM that can be programmed in PROM mode. PROM Mode Pin Description Pin Number MCU Mode FP-80A, FP-80B TFP-80 Pin Name Pin I/O Name I/O FP-80A, Pin Name FP-80B TFP-80 I/O Pin Name I/O 1 79 D2 I/O O2 I/O 28 26 R2 3 I/O A12 I 2 80 D3 I/O O3 I/O 29 27 R3 0 I/O A13 I 3 1 D4 I/O O4 I/O 30 28 R3 1/TIMO I/O A14 I 4 2 D5 I/O O5 I/O 31 29 R3 2/INT0 I/O CE I 5 3 D6 I/O O6 I/O 32 30 R3 3/INT1 I/O OE I 6 4 D7 I/O O7 I/O 33 31 SEG1 O 7 5 D8 I/O 34 32 SEG2 O 8 6 D9 I/O 35 33 SEG3 O 9 7 D10 I VPP 36 34 SEG4 O 10 8 D11/VCref I A9 I 37 35 SEG5 O 11 9 D12/COMP0 I M0 I 38 36 SEG6 O 12 10 D13/COMP1 I M1 I 39 37 SEG7 O 13 11 TEST I TEST I 40 38 SEG8 O 14 12 X1 I GND 41 39 SEG9 O 15 13 X2 O 42 40 SEG10 O 16 14 GND 43 41 SEG11 O 17 15 R0 0/SCK I/O A1 I 44 42 SEG12 O 18 16 R0 1/SI I/O A2 I 45 43 SEG13 O 19 17 R0 2/SO I/O A3 I 46 44 SEG14 O 20 18 R0 3 I/O A4 I 47 45 SEG15 O 21 19 R1 0 I/O A5 I 48 46 SEG16 O 22 20 R1 1 I/O A6 I 49 47 SEG17 O 23 21 R1 2 I/O A7 I 50 48 SEG18 O 24 22 R1 3 I/O A8 I 51 49 SEG19 O 25 23 R2 0 I/O A0 I 52 50 SEG20 O 26 24 R2 1 I/O A10 I 53 51 SEG21 O 27 25 R2 2 I/O A11 I 54 52 SEG22 O 66 PROM Mode GND Pin Number MCU Mode PROM Mode HD404618 Series Pin Number MCU Mode PROM Mode FP-80A, FP-80B TFP-80 Pin Name Pin I/O Name 55 53 SEG23 O 68 66 COM4 56 54 SEG24 O 69 67 V1 57 55 SEG25 O 70 68 V2 58 56 SEG26 O 71 69 V3 59 57 SEG27 O 72 70 TONEC O 60 58 SEG28 O 73 71 TONER O 61 59 SEG29 O 74 72 VT ref VCC 62 60 SEG30 O 75 73 VCC VCC 63 61 SEG31 O 76 74 OSC 1 I 64 62 SEG32 O 77 75 OSC 2 O 65 63 COM1 O 78 76 RESET I 66 64 COM2 O 79 77 D0 I/O O0 I/O 67 65 COM3 O 80 78 D1 I/O O1 I/O I/O Pin Number MCU Mode FP-80A, FP-80B TFP-80 Pin Name PROM Mode Pin I/O Name I/O O VCC VCC RESET I 67 HD404618 Series Programming the Built-in PROM The MCU’s built-in PROM is programmed in PROM mode which is set by pulling TEST, M0, and M1 low, and RESET high, as shown in figure 43. In PROM mode, the MCU does not operate, but it can be programmed in the same way as any other commercial 27256 EPROM using a standard PROM programmer and a 80-to-28-pin socket adaptor. Recommended PROM programmers and socket adapters are listed in table 34. Since an HMCS400-series instruction is ten bits long, the HMCS400-series MCU has a built-in conversion circuit to enable use of a general-purpose PROM programmer. This circuit splits each instruction into a lower 5 bits and an upper 5 bits that are read from or written to consecutive addresse. This means that if, for example, 8 kwords of built-in PROM are to be programmed by a general-purpose PROM programmer, a 16-kbyte address space ($0000–$3FFF) must be specified. Programming and Verification: The built-in PROM of the MCU can be programmed at high-speed programming sequence without risk of voltage stress or damage to data reliability. For details of PROM programming, refer to the notes on PROM Programming section. Warnings 1. Always specify addresses $0000 to $3FFF when programming with a PROM programmer. If address $4000 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’s 27256 setting. Table 33 PROM Mode Selection Pin Mode CE OE VPP O0–O7 Programming Low High VPP Data input Verification High Low VPP Data output Programming inhibition High High VPP High impedance 68 HD404618 Series Table 34 Recommended PROM Programmers and Socket Adapters PROM Programmer Socket Adapter Manufacturer Model Name Manufacturer Model Name Package DATA I/O Corp. 121B 29B Hitachi HS460ESF01H FP-80B HS460ESH01H FP-80A HS461EST01H TFP-80 HS460ESF01H FP-80B HS460ESH01H FP-80A HS461EST01H TFP-80 AVAL Corp. PKW-1000 Hitachi VCC VCC VCC RESET TEST M0 M1 VPP D10 /VPP O0–O7 Data O0 to O7 A0–A 14 Address A0 to A14 VCC OSC1 VTref V3 OE OE CE CE X1 GND Figure 43 Connections for PROM Mode 69 HD404618 Series Addressing Modes RAM Addressing Modes The MCU has three RAM addressing modes, as shown in figure 44 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), consisting of 16 digits 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 Indirect 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 0 m1 m0 0 AP9 AP8 AP7 AP6 AP5 AP4 AP3 AP2 AP1 AP0 Memory Register Addressing Figure 44 RAM Addressing Modes 70 m3 m2 HD404618 Series ROM Addressing Modes and the P Instruction The MCU has four ROM addressing modes, as shown in figure 45 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 32 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 46. 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 macro-assembler has an automatic paging feature for ROM pages. Zero-Page Addressing Mode: A program can branch to the zero-page subroutine area located at $000– $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 fourbit 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 47. 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. 71 HD404618 Series 2nd word of instruction 1st word of instruction [JMPL] [BRL] [CALL] Opcode p3 Program counter 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 b6 b7 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 a5 Opcode 0 0 0 0 a4 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 Zero Page Addressing Instruction [TBR] Opcode P3 P2 P1 P0 Accumulator B register B3 0 Program counter 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 45 ROM Addressing Modes 72 B2 B1 HD404618 Series 256 (n – 1) + 255 BR AAA 256 n AAA NOP BR AAA BR BBB 256 n + 254 256 n + 255 256 (n + 1) BBB NOP Figure 46 Page Boundary between BR Instruction and Branch Destination 73 HD404618 Series Instruction [P] p3 Opcode p2 p1 p0 B register B3 0 B2 B1 Accumulator B0 A3 A2 A1 A0 0 Referred 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 Specification 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 47 P Instruction 74 2 If RO 9 = 1 HD404618 Series Absolute Maximum Ratings Item Symbol Value Unit Supply voltage VCC –0.3 to +7.0 V Programming voltage VPP –0.3 to +14.0 V Pin voltage VT –0.3 to (VCC + 0.3) V Total permissible input current ∑IO 100 mA 2 Total permissible output current –∑IO 50 mA 3 Maximum input current IO 4 mA 4, 5 30 mA 4, 6 7, 8 Maximum output current –I O 4 mA Operating temperature Topr –20 to +75 °C Storage temperature Tstg –55 to +125 °C Notes 1 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. D10 (VPP) of the HD4074618. 2. Total permissible input current is the total of input currents simultaneously flowing in from all the I/O pins to GND. 3. Total permissible output current is the total of output currents simultaneously flowing out from V CC to all I/O pins. 4. The maximum input current is the maximum current flowing from any I/O pin to ground. 5. Applies to R0–R3 6. Applies to D 0–D 9 7. The maximum output current is the maximum current flowing from V CC to any I/O pin. 8. Applies to D 0–D 9, R0–R3 75 HD404618 Series Electrical Characteristics (Please inquire about the characteristics of HD404612, HD404614, HD404616, and HD404618 at VCC = 2.2 V) DC Characteristics (HD404612, HD404614, HD404616, HD404618: VC C = 2.7 V to 6.0 V; HD4074618: V CC = 3.0 V to 5.5 V, GND = 0.0 V, Ta = –20 to +75°C, unless otherwise specified) Max Test Unit Condition 0.9V CC VCC + 0.3 V OSC 1 VCC – 0.3 VCC + 0.3 V SI 0.9V CC VCC + 0.3 V RESET, SCK, INT0, INT1 –0.3 0.1V CC V OSC 1 –0.3 0.3 V SI –0.3 0.1V CC V VCC – 1.0 Item Symbol Pin(s) Min Input high voltage VIH RESET, SCK, INT0, INT1 Input low voltage VIL Output high voltage VOH SCK, TIMO, SO Output low voltage VOL SCK, TIMO, SO I/O leakage current |IIL| RESET, SCK, INT0, INT1, SI, SO, TIMO, OSC1 Stop mode retaining voltage VSTOP VCC Typ Notes External clock operation External clock operation V –I OH = 0.5 mA 0.4 V I OL = 0.4 mA 1 µA Vin = 0 to VCC 1 V No 32-kHz oscillator 2 7 Current I CC1 dissipation in VCC 400 1000 µA VCC = 3 V 2 f OSC = 400 kHz active mode I CC2 VCC 500 1500 µA VCC = 3 V 3 DTMF: active f OSC = 400 kHz I CC3 VCC 1 2 mA 4 VCC = 3 V f OSC = 400 kHz D12, D13 analog input mode I SBY Current dissipation in standby mode VCC 200 500 µA VCC = 3 V 5 LCD on f OSC = 400 kHz Current I STOP dissipation in stop mode VCC 1 10 µA VCC = 3 V No 32-kHz oscillator 76 HD404618 Series Item Symbol Pin(s) Current dissipation in subactive mode I SUB VCC Min Typ Max Test Unit Condition 50 100 µA 35 70 µA VCC = 3 V LCD on 6 I WTC1 Current dissipation in watch mode (1) VCC 5 15 µA VCC = 3 V LCD off I WTC2 Current dissipation in watch mode (2) VCC 15 35 µA VCC = 3 V LCD on — VCC – 1.2 V Comparator input reference voltage scope VC ref VC ref 0 Notes Notes: 1. Output buffer current is excluded. 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 V CC 3. I SBY is the source current when no I/O current is flowing while the MCU timer is in operation. Test conditions: D12, D13 in digital input mode DTMF in operation (excludes current flowing from VTref to GND) 4. Pins D 12 and D 13 are in analog input mode and I/O current is not flowing. Test conditions: VC ref/D11 , COMP0/D12 , COMP1/D13 at GND DTMF stopped 5. Timer is in operation and I/O current is not flowing. Test conditions: MCU: I/O in reset state Serial interface stopped D12, D13 in digital input mode DTMF stopped Stanby mode Pins : RESET at GND TEST at V CC 6. Applies only to HD404612, HD404614, HD404616, and HD404618. 7. RAM data retention. 77 HD404618 Series I/O Characteristics for Standard Pins (HD404612, HD404614, HD404616, HD404618: VCC = 2.7 V to 6.0 V; HD4074618: V CC = 3.0 V to 5.5 V, GND = 0.0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pin(s) Min Typ Max Input high voltage VIH Input low voltage Output high voltage D10–D 13 , R0– R3 0.7V CC — VCC + 0.3 V VIL D10–D 13 , R0–R3 –0.3 — 0.3V CC V VOH R0–R3 VCC – 1.0 — — –I OH = 0.5 mA V Pull-up MOS –I PU current R0–R3 5 90 VCC = 3 V, µA Output low voltage VOL R0–R3 — — 0.4 I OL = 0.4 mA V I/O leakage current |IIL| D11 to D13 , R0 to R3 — — 1 HD404612, HD404614 HD404616, HD404618: Vin = 0 V to VCC µA 1 D10 — — 20 HD4074618: Vin = 0 V to VCC µA 2 40 Test Conditions Unit Notes Vin = 0 V Input high voltage VIHA D12, D13 VC ref+ 0.1 (analog compare mode) — — V Input low voltage VILA D12, D13 — (analog compare mode) — VC ref – 0.1 V Note: 78 1. Output buffer current is excluded. 2. The Max value for the HD404618, HD404616, HD404614, and HD404612 is 1µA. HD404618 Series I/O Characteristics for High-Current Pins (HD404612, HD404614, HD404616, HD404618: VCC = 2.7 V to 6.0 V; HD4074618: VCC = 3.0 V to 5.5 V, GND = 0 V, T a = –20 to +75°C, unless otherwise specified) Item Symbol Pin(s) Min Typ Max Input high voltage VIH D0–D 9 0.7V CC — VCC + 0.3 V Input low voltage VIL D0–D 9 –0.3 — 0.3V CC V Output high voltage VOH D0–D 9 VCC – 1.0 — Pull-up MOS current –I PU D0–D 9 5 40 Output low voltage VOL D0–D 9 — I/O leakage current |IIL| D0–D 9 Test Conditions Unit Notes –I OH = 0.5 mA V 90 VCC = 3 V, Vin = 0 V µA — 2.0 I OL = 15 mA V VCC = 4.5 V to 6 V — — 0.4 I OL = 0.4 mA V — — 1 Vin = 0 to VCC µA 1 Note: 1. Output buffer current is excluded. LCD Circuit Characteristics (HD404612, HD404614, HD404616, HD404618: V CC = 2.7 V to 6.0 V; HD4074618: VCC = 3.0 V to 5.5 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pin(s) Min Typ Max Test Condition Unit Notes Segment driver voltage drop Vds SEG1– SEG32 — — 0.6 I d = 3 µA V 1 Common driver voltage drop Vdc COM1– COM4 — — 0.3 I d = 3 µA V 1 LCD power supply division resistor RWell 100 300 900 Between V 1 and GND kΩ LCD voltage VLCD 2.7 — VCC HD404612, HD404614, HD404616, HD404618 V 2 3.0 — VCC HD4074618 V 2 V1 Notes: 1. VDS and VDC are the voltage drops from power supply pins V1, V2, and V 3, and GND to each segment pin and each common pin. 2. When VLCD is supplied from an external source, the following relations must be retained: VCC ≥ V 1 ≥ V 2 ≥ V 3 ≥ GND 79 HD404618 Series DTMF Characteristics (HD404612, HD404614, HD404616, HD404618: VCC = 2.7 V to 6.0 V; HD4074618: VCC = 3.0 V to 5.5 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pin(s) Min Typ Max Test Conditions Unit Notes Tone output voltage (1) VOR TONER 500 660 — VT ref – GND = 2.0 V, RL = 100 kΩ mVrms 1 Tone output voltage (2) VOC TONEC 520 690 — VT ref – GND = 2.0 V, RL = 100 kΩ mVrms 1 Tone output distortion %DIS — 3 7 Short circuit between TONER and TONEC, RL = 100 kΩ % 2 Tone output ratio dBCR — 2.5 — Short circuit between TONER and TONEC, RL = 100 kΩ dB 2 Notes: 1. See figure 48. 2. See figure 49. 80 HD404618 Series AC Characteristics (HD404612, HD404614, HD404616, HD404618: VC C = 2.7 V to 6.0 V; HD4074618: VCC = 3.0 V to 5.5 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) Item Symbol Pin(s) Min Typ Max Test Condition Unit Clock oscillation frequency f OSC OSC 1, OSC 2 — 400 — 1/4 division kHz — 800 — kHz — 32.768 — kHz — 10 — f OSC / fCP = 400 kHz µs — 5 — f OSC / fCP = 800 kHz µs — — 7.5 f OSC = 400 kHz ms 1 — — 7.5 f OSC = 800 kHz ms 1 X1, X2 — — 3 Ta = –10 to +60°C s 2 OSC 1 — 400 — kHz — 800 — kHz 1100 — — f CP = 400 kHz ns 3 550 — — f CP = 800 kHz ns 3 1100 — — f CP = 400 kHz ns 3 550 — — f CP = 800 kHz ns 3 — — 150 f CP = 400 kHz ns 3 — — 75 f CP = 800 kHz ns 3 — — 150 f CP = 400 kHz ns 3 — — 75 f CP = 800 kHz ns 3 X1, X2 Instruction cycle time Oscillator stabilization time External clock frequency External clock high width External clock low width External clock rise time t cyc t RC f CP t CPH t CPL t CPr External t CPf clock fall time OSC 1, OSC 2 OSC 1 OSC 1 OSC 1 OSC 1 Notes INT0 high width t IH INT0 2 — — t cyc / t subcyc 4, 6 INT0 low width t IL INT0 2 — — t cyc / t subcyc 4, 6 INT1 high width t IH INT1 2 — — t cyc 4 81 HD404618 Series Item Symbol Pin(s) Min Typ Max INT1 low width t IL INT1 2 — RESET high width t RSTH RESET 2 Input capacitance Cin D10 All pins except D 10 RESET fall time t RSTf Analog comparator stabilization time t CSTB D12, D13 Test Condition Unit Notes — t cyc 4 — — t cyc 5 — — 90 HD4074618: f = 1 MHz, Vin = 0 V pF 8 — — 15 f = 1 MHz, Vin = 0 V pF — — 20 ms 5 — — 2 t cyc 7 (analog input mode) Notes: 1. The oscillation stabilization time is the period required for the oscillator to stabilize after V CC reaches 2.7 V (3.0 V for HD4074618) at power-on or after RESET input goes high after stop mode is cancelled. At power-on or when stop mode is cancelled, RESET must remain high for at least tRC to ensure the oscillation stabilization time. Since tRC depends on the ceramic oscillator’s circuit constant and stray capacitance, contact the manufacturer when designing a reset circuit. 2. The oscillation stabilization time is the period required for the oscillator to stabilize after V CC reaches 2.7 V (3.0 V for HD4074618) at power-on. The oscillation stabilization time (t RC) must be ensured. If using a crystal oscillator, contact the manufacturer to determine what oscillation stabilization time is required, since it depends on the circuit constants and stray capacitances. 3. See figure 50. 4. See figure 51. The unit t cyc applies when the MCU is in standby mode or active mode. 5. See figure 52. 6. The unit t subcyc applies when the MCU is in watch mode or subactive mode. t subcyc = 244.14 µs (32.768-kHz crystal oscillator) 7. The analog comparator stabilization time is the period required for the oscillator to stabilize and for correct data to be read after D12 /D13 is input to enter analog input mode. 8. The Max value for the HD404618, HD404616, HD404614, and HD404612 is 15pF. 82 HD404618 Series Serial Interface Timing Characteristics (HD404612, HD404614, HD404616, HD404618: VCC = 2.7 V to 6.0 V; HD4074618: VCC = 3.0 V to 5.5 V, GND = 0 V, Ta = –20 to +75°C, unless otherwise specified) During Transmit Clock Output Item Symbol Pin(s) Min Typ Max Test Condition Unit Notes Transmit clock cycle time t Scyc SCK 1 — — Load shown in figure 54 t cyc /tsubcyc 1, 3 Transmit clock high width t SCKH SCK 0.5 — — Load shown in figure 54 t Scyc 1 Transmit clock low width t SCKL SCK 0.5 — — Load shown in figure 54 t Scyc 1 Transmit clock rise time t SCKr SCK — — 200 Load shown in figure 54 ns 1 Transmit clock fall time t SCKf SCK — — 200 Load shown in figure 54 ns 1 Serial output data delay time t DSO SO — — 500 Load shown in figure 54 ns 1 Serial input data t SSI setup time SI 300 — — ns 1 Serial input data t HSI hold time SI 300 — — ns 1 83 HD404618 Series During Transmit Clock Input Item Symbol Pin(s) Min Typ Max Transmit clock cycle time t Scyc SCK 1 — — t cyc /tsubcyc 1, 3 Transmit clock high width t SCKH SCK 0.5 — — t Scyc 1 Transmit clock low width t SCKL SCK 0.5 — — t Scyc 1 Transmit clock rise time t SCKr SCK — — 200 ns 1 Transmit clock fall time t SCKf SCK — — 200 ns 1 Serial output data delay time t DSO SO — — 500 ns 1 Serial input data t SSI setup time SI 300 — — ns 1 Serial input data t HSI hold time SI 300 — — ns 1 Transmit clock completion detect time SCK 1 — — t cyc /tsubcyc 1, 2, 3 t SCKHD Test Condition Unit Load shown in figure 54 Notes Notes: 1. See figure 53. 2. The transmit clock completion detect time is the high level period after eight transmit clock pulses have been input. The serial interrupt request flag is not set if the next transmit clock is input before the transmit clock completion detect time has passed. 3. The unit t subcyc applies when the MCU is in subactive mode. t subcyc = 244.14 µs (32.768-kHz crystal oscillator) RL = 100 kΩ TONEC TONER RL = 100 kΩ Figure 48 Tone Output Load Circuit 84 HD404618 Series R L = 100 k Ω TONEC TONER Figure 49 Distortion and dBCR Load Circuit 1/fCP VCC – 0.3 V OSC1 t CPH 0.3 V t CPL t CPr t CPf Figure 50 Oscillator Timing 0.9VCC INT0 , INT1 tIH 0.1VCC tIL Figure 51 Interrupt Timing 0.9VCC RESET 0.1VCC t RSTH t RSTf Figure 52 Reset Timing After 8 transmit clock pulses are input t Scyc t SCKf SCK VCC – 1.0 V (0.9VCC )* 0.4 V (0.1VCC)* t SCKHD t SCKr t SCKL tSCKH t DSO SO VCC – 0.5 V 0.4 V t SSI SI t HSI 0.9V CC 0.1VCC Note: * VCC – 1.0 V and 0.4 V are the threshold voltages for transmit clock output. 0.9VCC and 0.1VCC are threshold voltages for transmit clock input. Figure 53 Serial Interface Timing 85 HD404618 Series VCC R L = 2.6 k Ω Test point C 30 pF R 1S2074 H or equivalent 12 kΩ Figure 54 Timing Load Circuit 86 HD404618 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 as a 8-kword version (HD404618). An 8-kword data size is required to change ROM data to mask manufac turing data since the program used is for a 8-kword version. This limitation applies when using an EPROM or a data base. $0000 $0000 Vector address Vector address Zero-page subroutine (64 words) Zero-page subroutine (64 words) Pattern & program (2,048 words) Zero-page subroutine (64 words) $003F $0040 Pattern & program (4,096 words) $0FFF $1000 $07FF $0800 Vector address $000F $0010 $003F $0040 $003F $0040 Not used $1FFF $0000 $000F $0010 $000F $0010 ROM 6-kword version: HD404616 Address $1800–$1FFF ROM 4-kword version: HD404614 Address $1000–$1FFF ROM 2-kword version: HD404612 Address $0800–$1FFF Pattern & program (6,144 words) $17FF $1800 Not used $1FFF Not used $1FFF Fill this area with 1s 87 HD404618 Series HD404612, HD404614, HD404616, HD404618 Option List Please check off the appropriate applications and enter the necessary information. Date of order / / Customer Department ROM code name 1. ROM Size HD404612 2-kword HD404614 4-kword HD404616 6-kword HD404618 8-kword LSI number (to be filled in by HITACHI) 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 5. 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. 6. System oscillator (OSC1 and OSC2) Ceramic oscillator f= MHz External clock f= MHz 7. Stop Mode Used Not used 8. Package FP-80A FP-80B TFP-80 88 HD404618 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. 89