Preliminary W742E81A/W742C81A 4-BIT MICROCONTROLLER 1. GENERAL DESCRIPTION The W742E81A/W742C81A is a high-performance 4-bit microcontroller (C) that provides an LCD driver. The device contains a 4-bit ALU, two 8-bit timers, two dividers (for two oscillators) in dualclock operation, a 40 x 4 LCD driver, six 4-bit I/O ports (including 1 output port for LED driving), and one channel DTMF generator. There are also five interrupt sources and 16-levels subroutine nesting for interrupt applications. The W742E81A/W742C81A operates on very low current and has two power reduction modes, that is the dual-clock slow operation and STOP mode, which help to minimize power dissipation. 2. FEATURES * Operating voltage: 2.4V-3.8V * Dual-clock operation or single-clock operation (By option) * Main-oscillator - Connect to 3.58 MHz crystal or 400 KHz that can be selected by option code - Crystal or RC oscillator can be selected by code option (W742E81A) - Connect to 2 MHz typical RC oscillator (W742C81A) * Sub-oscillator - Connect to 32768 Hz crystal only * Memory - 16384 x 16 bits program flash EEPROM (including 64K x 4 bit look-up table) - 2048 x 4 bits data RAM (including 16 nibbles x 16 pages working registers) - 40 x 4 LCD data RAM * 24 input/output pins - Port for input only: 1 ports/4 pins(RC) - Input/output ports: 3 ports/12 pins(RA, RB & RD) - High sink current output port for LED driving: 1 port /4 pins(RE) - Port for output only: 1 port/ 4 pins(RF) * Power-down mode - Hold function: no operation (main-oscillator and sub-oscillator still operate) - Stop function: no operation (main-oscillator and sub-oscillator are stopped) - Dual-clock slow operation mode: system is operated by the sub-oscillator (FOSC=Fs and Fm is stopped) * Five types of interrupts - Four internal interrupts (Divider0, Divider1, Timer 0, Timer 1) - One external interrupts (RC Port) -1- Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A * LCD driver output - 40 segments x 4 commons - 1/4 duty 1/3 bias driving mode - Clock source should be the sub-oscillator clock in the dual-clock operation mode * MFP output pin - Output is software selectable as modulating or nonmodulating frequency - Works as frequency output specified by Timer 1 * DTMF output pin - Output is one channel Dual Tone Multi-Frequency signal for dialling * Two built-in 14-bit frequency dividers - Divider0: the clock source is the output of the main-oscillator - Divider1: the clock source is the output of the sub-oscillator (dual-clock mode) or the Fosc/128 (single-clock mode) * Two built-in 8-bit programmable countdown timers - Timer 0: one of two internal clock frequencies (FOSC/4 or FOSC/1024) can be selected - Timer 1: with auto-reload function and one of three internal clock frequencies (FOSC, FOSC/64 or Fs) can be selected by MR1 register; and the specified frequency can be delivered to MFP pin * Built-in 18/15-bit watchdog timer selectable for system reset; enable the watch dog timer or not is determined by code option * Powerful instruction set: 142 instructions * 16-levels subroutine (include interrupt) nesting -2- Preliminary W742E81A/W742C81A 3. PIN CONFIGURATION For W742E81A X X D X O X O V R T I U V I U D D D N N N N E M N T D N T H H D C C C C S F 1 1 D 2 2 1 2 1 V D D 2 C O M 0 C O M 1 C O M 2 C O M 3 S E G 3 9 S E G 3 8 S E G 3 7 S E G 3 6 S E G 3 5 S E G 3 4 S E G 3 3 S E G 3 2 N N N C C C 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 NC MFP 81 82 RA0 RA1 RA2 83 84 85 RA3 RB0 RB1 86 87 88 RB2 RB3 RC0 89 90 91 92 RC1 RC2 RC3 RD0 RD1 RD2 RD3 NC NC 50 49 48 93 94 95 96 97 98 99 100 NC 47 46 45 NC SEG31 SEG30 SEG29 SEG28 44 43 42 SEG27 SEG26 SEG25 41 40 39 38 SEG24 SEG23 37 36 SEG20 35 34 33 32 SEG18 SEG17 SEG16 31 SEG22 SEG21 SEG19 SEG15 NC 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 N N N R R R R R R R R V S S C C C E E E E F F F F S E E 0 1 2 3 0 1 2 3 S G G 0 1 S E G 2 S E G 3 S E G 4 -3- S E G 5 S E G 6 S E G 7 S E G 8 S E G 9 S E G 1 0 S E G 1 1 S E G 1 2 S E G 1 3 S N N N E C C C G 1 4 Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A For W742C810 X X D X O X O V R T I U V I U D D D N N N N E M N T D N T H H D C C C C S F 1 1 D 2 2 1 2 1 V D D 2 C O M 0 C O M 1 C O M 2 C O M 3 S E G 3 9 S E G 3 8 S E G 3 7 S E G 3 6 S E G 3 5 S E G 3 4 S E G 3 3 N N N N C C C C 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 NC MFP 81 82 RA0 RA1 83 84 RA2 RA3 RB0 85 86 87 RB1 88 89 90 RB2 RB3 RC0 RC1 RC2 RC3 RD0 RD1 RD2 RD3 RE0 NC 50 49 48 47 46 45 91 92 93 94 95 96 97 98 99 100 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 N N N N R R R R R R R V S S C C C C E E E F F F F S E E 1 2 3 0 1 2 3 S G G 0 1 S E G 2 S E G 3 S E G 4 -4- S E G 5 S E G 6 S E G 7 S E G 8 S E G 9 S E G 1 0 S E G 1 1 S E G 1 2 S N N N N E C C C C G 1 3 NC SEG32 SEG31 SEG30 SEG29 SEG28 44 43 42 SEG27 SEG26 41 40 39 38 SEG24 SEG23 SEG22 SEG21 37 36 SEG20 35 34 33 SEG18 SEG17 SEG16 32 31 SEG15 SEG14 SEG25 SEG19 Preliminary W742E81A/W742C81A 4. PIN DESCRIPTION SYMBOL I/O FUNCTION XIN2 I Input pin for sub-oscillator. Connected to 32.768 KHz crystal only. XOUT2 O Output pin for sub-oscillator with internal oscillation capacitor. Connected to 32.768 KHz crystal only. XIN1 I Input pin for main-oscillator. Connected to 3.58 MHz or 400 KHz crystal or RC to generate system clock. XOUT1 O Output pin for main-oscillator. Connected to 3.58 MHz or 400 KHz crystal or RC to generate system clock. RA0-RA3 I/O Input/Output port. Input/output mode specified by port mode 1 register (PM1). RB0-RB3 I/O Input/Output port. Input/output mode specified by port mode 2 register (PM2). RC0-RC3 I 4-bit port for input only. Each pin has an independent interrupt capability. RD0-RD3 I/O Input/Output port. Input/output mode specified by port mode 5 register (PM5). RE0-RE3 O Output port only. With high sink current capacity for the LED application. RF0-RF3 O Output port only. MFP O This pin can output modulating or nonmodulating frequency, or Timer 1 specified frequency. It can be selected by bit 0 of BUZCR (BUZCR.0). DTMF O This pin can output dual-tone multifrequency signal for dialling. RES I System reset pin with pull-high resistor. SEG0-SEG39 O LCD segment output pins. COM0-COM3 O LCD common signal output pins. Output pin only. The LCD alternating frequency can be selected by code option. DH1, DH2 I Connection terminals for voltage doubler (halver) capacitor. VDD1 I Positive (+) supply voltage terminal. VDD2 Refer to Functional Description. VDD I Positive power supply (+). VSS I Negative power supply (-). -5- Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A Pin Description, continued SYMBOL I/O FUNCTION VPP I Voltage control pin for the flash EEPROM programming, erasing and verifying. This pin has the built-in pull-low resistor. MODE I This pin can be used as mode selection control; data read/write clock; program/erase control or address counter control in the flash EEPROM erasing, programming or verifying mode. This pin has the built-in pull-low resistor. DATA I/O Data I/O pin with the built-in pull-low resistor. 5. BLOCK DIAGRAM SEG0~SEG39 COM0~COM3 LCD RAM (2048*4) Flash EEROM VPP DATA (16384*16) MODE (look_up table 64K*4) VDD1-2 DH1-2 DRIVER PORT RA RA0-3 PORT RB RB0-3 PORT RC RC0-3 PORT RD RD0-3 PORT RE RE0-3 PORT RF RF0-3 DTMF Generator DTMF ACC ALU +1(+2) PC STACK (16 Levels) Central Control Unit IEF HEF PEF HCF EVF SEF PSR0 SCR PR PM0 MR0 MR1 PM1 DTMF DTCR . . . SEL Timer 0 (8 Bit) Watch Dog Timer (4 Bit) Modulation Frequency Pulse Timer 1 (8 Bit) MUX MFP Divider 1 (12/14 Bit) VDD VSS Divider 0 (14 Bit) Timing Generator RES XIN1 XOUT1 XIN2 XOUT2 -6- Preliminary W742E81A/W742C81A 6. FUNCTIONAL DESCRIPTION 6.1 Program Counter (PC) Organized as an 14-bit binary counter (PC0 to PC13), the program counter generates the addresses of the 16384 x 16 on-chip ROM containing the program instruction words. Before the jump or subroutine call instructions are to be executed, the destination ROM page must be determined firstly. The confirmation of the ROM page can be done by executing the MOV ROMPR, #I or MOV ROMPR, R instruction. When the interrupt or initial reset conditions are to be executed, the corresponding address will be loaded into the program counter directly. The format used is shown below. Table 1 Vector address and interrupt priority ITEM ADDRESS INTERRUPT PRIORITY Initial Reset 0000H - INT 0 (Divider0) 0004H 1st INT 1 (Timer 0) 0008H 2nd INT 2 (Port RC) 000CH 3rd INT 3 (Divider1) 0014H 4th INT 4 (Timer 1) 0020H 5th JP Instruction XXXXH - Subroutine Call XXXXH - 6.2 Stack Register (STACK) The stack register is organized as 49 bits x 16 levels (first-in, last-out). When either a call subroutine or an interrupt is executed, the program counter will be pushed onto the stack register automatically. At the end of a call subroutine or an interrupt service subroutine, the RTN instruction must be executed to pop the contents of the stack register into the program counter. (Refer to Table 8) When the stack register is pushed over the sixteen levels, the contents of the first level will be lost. In other words, the stack register is always sixteen levels deep. 6.3 Program Memory (ROM) The read-only memory (ROM) is used to store program codes; and the look-up table is arranged as 65536 x 4 bits. The program ROM is divided into eight pages; the size of each page is 2048 x 16 bits. So the total ROM size is 16384 x 16 bits. Before the jump or subroutine call instructions are to be executed, the destination ROM page must be determined firstly. The ROM page can be selected by executing the MOV ROMPR,#I or MOV ROMPR, R instruction. But the branch decision instructions (e.g. JB0, SKB0, JZ, JC, ...) must jump to the same ROM page which the branch decision instructions are in. The whole ROM can store both instruction codes and the look-up table. Each look-up table element is composed of 4 bits, so the look-up table can be addressed up to 65536 elements. Instruction MOVC R is used to read the look-up table content and transfer table data to the RAM. But before reading the addressed look-up table content, the content of the look-up table pointer (TAB) must be determined firstly. The address of the look-up table element is allocated by the content of TAB. The MOV TAB0 (TAB1, TAB2, TAB3), R instructions are used to allocate the address of the wanted look-up table element. The TAB0 register stores the LSB 4 bits of the look-up table address. -7- Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A The organization of the program memory is shown in Figure 6-1. 16 bits 0000H : 03FFH 1st page 0400H : 07FFH 0800H : 2nd page 0BFFH 0C00H : 0FFFH Look-up table address: 0000H : 0FFFH Each element (4 bits) of the look-up table : Look-up table address: 1000H : 1FFFH : Look-up table address: 2000H : 2FFFH Look-up table address: 3000H : 3FFFH : : : : 3800H : 8th page 3BFFH 3C00H : 3FFFH Look-up table address: E000H : EFFFH Look-up table address: F000H : FFFFH 16384 x 16 bits Figure 6-1 Program Memory Organization 6.3.1 ROM Page Register (ROMPR) The ROM page register is organized as a 4-bit binary register. The bit descriptions are as follows: 3 ROMPR 2 1 0 W W W Note: W means write only. Bit 3 is reserved. Bit 2, Bit 1, Bit 0 ROM page preselect bits: 000 = ROM page 0 (0000H - 07FFH) 001 = ROM page 1 (0800H - 0FFFH) 010 = ROM page 2 (1000H - 17FFH) 011 = ROM page 3 (1800H - 1FFFH) 100 = ROM page 4 (2000H - 27FFH) 101 = ROM page 5 (2800H - 2FFFH) 110 = ROM page 6 (3000H - 37FFH) 111 = ROM page 7 (3800H - 3FFFH) -8- Preliminary W742E81A/W742C81A 6.4 Data Memory (RAM) 6.4.1 Architecture The static data memory (RAM) used to store data is arranged as 2048 x 4 bits. The data RAM is divided into sixteen banks; each bank has 128 x 4 bits. Executing the MOV DBKR,WR or MOV DBKR,#I instruction can determine which data bank is used. The data memory can be addressed directly or indirectly. But the data bank must be confirmed firstly; and the page in the data bank will be done in the indirect addressing mode, too. In indirect addressing mode, each data bank will be divided into eight pages. Before the data memory is addressed indirectly, the page which the data memory is in must be confirmed. The organization of the data memory is shown in Figure 6-2. 4 bits 2048 addresses 000H : 07FH 080H : 0FFH 1st data bank 1st data RAM page (or 1st WR page) (or Working Registers bank) 2nd data RAM page (or 2nd WR page) 2nd data bank (or Working Registers bank) 3rd data RAM page (or 3rd WR page) 3rd data bank 780H : 7FFH 00H : 0FH 10H : 1FH 20H : 2FH : : : : 8th data RAM page (or 8th WR page) 16th data bank 70H : 7FH 2048 * 4 bits Figure 6-2 Data Memory Organization The 1st and 2nd data bank (00H to 7FH & 80H to FFH) in the data memory can also be used as the working registers (WR). It is also divided into sixteen pages. Each page contains 16 working registers. When one page is used as WR, the others can be used as the normal data memory. The WR page can be switched by executing the MOV WRP,R or MOV WRP,#I instruction. The data memory cannot operate directly with immediate data, but the WR can do. The relationship between data memory locations and the page register (PAGE) in indirect addressing mode is described in the next subsection. 6.4.2 Page Register (PAGE) The page register is organized as a 4-bit binary register. The bit descriptions are as follows: 3 PAGE 2 1 0 R/W R/W R/W Note: R/W means read/write available. Bit 3 is reserved. Bit 2, Bit 1, Bit 0 Indirect addressing mode preselect bits: 000 = Page 0 (00H - 0FH) -9- Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A 001 = Page 1 (10H 010 = Page 2 (20H 011 = Page 3 (30H 100 = Page 4 (40H 101 = Page 5 (50H 110 = Page 6 (60H 111 = Page 7 (70H - 1FH) 2FH) 3FH) 4FH) 5FH) 6FH) 7FH) 6.4.3 WR Page Register (WRP) The WR page register is organized as a 4-bit binary register. The bit descriptions are as follows: WRP 3 2 1 0 R/W R/W R/W R/W Note: R/W means read/write available. Bit 3, Bit 2, Bit 1, Bit 0 Working registers page preselect bits: 0000 = WR Page 0 (00H - 0FH) 0001 = WR Page 1 (10H - 1FH) 0010 = WR Page 2 (20H - 2FH) 0011 = WR Page 3 (30H - 3FH) 0100 = WR Page 4 (40H - 4FH) 0101 = WR Page 5 (50H - 5FH) 0110 = WR Page 6 (60H - 6FH) 0111 = WR Page 7 (70H - 7FH) 1000 = WR Page 8 (80H - 8FH) 1001 = WR Page 9 (90H - 9FH) 1010 = WR Page A (A0H - AFH) 1011 = WR Page B (B0H - BFH) 1100 = WR Page C (C0H - CFH) 1101 = WR Page D (D0H - DFH) 1110 = WR Page E (E0H - EFH) 1111 = WR Page F (F0H - FFH) 6.4.4 Data Bank Register (DBKR) The data bank register is organized as a 4-bit binary register. The bit descriptions are as follows: DBKR 3 2 1 0 R/W R/W R/W R/W Note: R/W means read/write available. - 10 - Preliminary W742E81A/W742C81A Bit 3, Bit 2, Bit 1, Bit 0 Data memory bank preselect bits: 0000 = Data bank 0 (000H - 07FH) 0001 = Data bank 1 (080H - 0FFH) 0010 = Data bank 2 (100H - 17FH) 0011 = Data bank 3 (180H - 1FFH) 0100 = Data bank 4 (200H - 27FH) 0101 = Data bank 5 (280H - 2FFH) 0110 = Data bank 6 (300H - 37FH) 0111 = Data bank 7 (380H - 3FFH) 1000 = Data bank 8 (400H - 47FH) 1001 = Data bank 9 (480H - 4FFH) 1010 = Data bank A (500H - 57FH) 1011 = Data bank B (580H - 5FFH) 1100 = Data bank C (600H - 67FH) 1101 = Data bank D (680H - 6FFH) 1110 = Data bank E (700H - 77FH) 1111 = Data bank F (780H - 7FFH) 6.5 Accumulator (ACC) The accumulator (ACC) is a 4-bit register used to hold results from the ALU and transfer data between the memory, I/O ports, and registers. 6.6 Arithmetic and Logic Unit (ALU) This is a circuit which performs arithmetic and logic operations. The ALU provides the following functions: * Logic operations: ANL, XRL, ORL * Branch decisions: JB0, JB1, JB2, JB3, JNZ, JZ, JC, JNC, DSKZ, DSKNZ, SKB0, SKB1, SKB2, SKB3 * Shift operations: SHRC, RRC, SHLC, RLC * Binary additions/subtractions: ADC, SBC, ADD, SUB, ADU, DEC, INC After any of the above instructions are executed, the status of the carry flag (CF) and zero flag (ZF) is stored in the internal registers. CF can be read out by executing MOV R, CF. 6.7 Main-Oscillator The W742E81A/W742C81A provides a crystal or RC oscillation circuit to generate the system clock through external connections. If a crystal oscillator is used, The 3.58 MHz or 400KHz crystal must be connected to XIN1 and XOUT1, and a capacitor must be connected to XIN1 and VSS if an accurate frequency is needed. - 11 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A XIN1 or Crystal 3.58 MHz or 400 KHz Figure 6-3 XIN1 XOUT1 XOUT1 System Clock Oscillator Configuration 6.8 Sub-Oscillator The sub-oscillator is used in dual-clock operation mode. In the sub-oscillator application, just only the 32768 Hz crystal could be connected to XIN2 and XOUT2, and it would not be oscillated in STOP mode. 6.9 Dividers Each divider is organized as a 14-bit binary up-counter designed to generate periodic interrupts. When the main oscillator starts action, the Divider0 is incremented by each clock (FOSC). When an overflow occurs, the Divider0 event flag is set to 1 (EVF.0 = 1). Then, if the Divider0 interrupt enable flag has been set (IEF.0 = 1), the interrupt is executed, while if the hold release enable flag has been set (HEF.0 = 1), the hold state is terminated. And the last 4-stage of the Divider0 can be reset by executing CLR DIVR0 instruction. If the sub-oscillator starts action, the Divider1 is incremented by each clock (Fs in dual-clock mode or Fosc/128 in single-clock mode). When an overflow occurs, the Divider1 event flag is set to 1 (EVF.4 = 1). Then, if the Divider1 interrupt enable flag has been set (IEF.4 = 1), the interrupt is executed, while if the hold release enable flag has been set (HEF.4 = 1), the hold state is terminated. And the last 4-stage of the Divider1 can be reset by executing CLR DIVR1 instruction. Same as EVF.0, the EVF.4 is set to 1 periodically. But there are two period time (125 mS & 500mS) that can be selected by setting the SCR.3 bit. When SCR.3 = 0 (default), the 500 mS period time is selected; SCR.3 = 1, the 125 mS period time is selected. 6.10 Dual-clock operation This operation mode is selected by option code. In the dual-clock mode, the clock source of the LCD frequency selector should be the sub-oscillator clock (32768 Hz) only. But in the signal-clock mode, the clock source of the LCD frequency selector will be Fm/128(Fm : main oscillator clock, See figure 6-4). So before the STOP instruction is executing, the LCD must be turned off in the signalclock mode or dual-clock mode. In this dual-clock mode, the normal operation is performed by generating the system clock from the main-oscillator clock (Fm). As required, the slow operation can be performed by generating the system clock from the sub-oscillator clock (Fs). The exchange of the normal operation and the slow operation is performed by resetting or setting the bit 0 of the System clock Control Register (SCR). If the SCR.0 is reset to 0, the clock source of the system clock generator is main-oscillator clock; if the SCR.0 is set to 1, the clock source of the system clock generator is sub-oscillator clock. In the dualclock mode, the main-oscillator can stop oscillating when the STOP instruction is executing or the SCR.1 is set to 1. - 12 - Preliminary W742E81A/W742C81A When the SCR is set or reset, we must care the following cases: 1. X000B X011B: we should not exchange the FOSC from Fm into Fs and disable Fm simultaneously. We could first exchange the FOSC from Fm into Fs, then disable the mainoscillator. So it should be X000BX001BX011B. 2. X011B X000B: we should not enable Fm and exchange the FOSC from Fs into Fm simultaneously. We could first enable the main-oscillator; the 2nd step is calling a delay subroutine to wait the main-oscillator oscillating stably; then exchange the FOSC from Fs into Fm is the last step. So it should be X011BX001Bdelay the Fm oscillating stably timeX000B. The suggestion of the Fm oscillating stably time is 3.5 mS for 455 KHz and 0.8ms for 4 MHz. We must remember that the X010B state is inhibitive, because it will induce the system shutdown. The organization of the dual-clock operation mode is shown in Figure 6-4. HOLD XIN1 XOUT1 Main Oscillator Fm SCR.0 Fosc Fs SCR.1 enable/disable XIN2 Divider 0 STOP Fosc/128 Sub-Oscillator XOUT2 T1 T2 T3 T4 System Clock Generator LCD Frequency Selector Dual/Single Colck Option code is 1/0 Divider 1 Fs or Fosc/128 F LCD INT4 HCF.4 SCR.3(14/12 bit) SCR : System clock Control Register ( default = 00H ) Bit3 Bit1 Bit0 0 : Fosc = Fm 1 : Fosc = Fs 0 : Fm enable 1 : Fm disable 0 : 14 bit 1 : 12 bit Daul clock operation mode : - SCR.0=0, Fosc=Fm : SCR.0=1, Fosc=Fs - Flcd=Fs, In STOP mode LCD work continue. Figure 6-4 Organization of the dual-clock operation mode - 13 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A 6.11 WatchDog Timer (WDT) and WatchDog Timer Register(WDTR) The watchdog timer (WDT) is organized as a 4-bit up counter designed to prevent the program from unknown errors. When the corresponding option code bit of the WDT set to 1, the WDT is enabled, and if the WDT overflows, the chip will be reset. At initial reset, the input clock of the WDT is FOSC/2048. The input clock of the WDT can be switched to FOSC/16384 (or FOSC/2048) by setting WDTR.3 to 1. The contents of the WDT can be reset by the instruction CLR WDT. In normal operation, the application program must reset WDT before it overflows. A WDT overflow indicates that operation is not under control and the chip will be reset. The WDT overflow period is 1 S when the sub-system clock (Fs) is 32 KHz and WDT clock input is Fs/2048. When the corresponding option code bit of the WDT set to 0, the WDT function is disabled. The organization of the Divider0 and watchdog timer is shown in Figure 6-5. Divider0 Fosc Q1 Q2 ... Q9 HEF.0 EVF.0 S Q Q10 Q11 Q12 Q13 Q14 WDTR.3 Fosc/16384 Fosc/2048 R Divider interrupt (INT0) 1. Reset 2. CLR EVF,#01H 3. CLR DIVR0 Option code is "0" WDTR.2 Disable WDT Qw1 Qw2 Qw3 Qw4 R Fss/16384 R R Overflow signal System Reset R 1. Reset 2. CLR WDT Enable Fss/2048 Hold mode release (HCF.0) IEF.0 Option code is "1" Divider1 Q1 Q2 ... Q9 HEF.4 EVF.4 S Q Q10 Q11 Q12 Q13 Q14 IEF.4 R Hold mode release (HCF.4) Divider interrupt (INT1) Fss=Fs or Fosc/128 1. Reset 2. CLR EVF,#10H 3. CLR DIVR1 SCR.3 Figure 6-5 Organization of Divider0, Divider1 and WatchDog Timer - 14 - Preliminary W742E81A/W742C81A WDTR 3 2 1 0 R/W R/W R/W R Note: R/W means read/write available, R means read only. Power On reset default is : 0000 Bit 3 = 0 =1 Bit 2 = 0 =1 Bit 1 = 0 =1 Bit 0 = 0 =1 FOSC/2048(Select Divider0) or Fss/2048(Select Divider1) as the WDT source. FOSC/16384(Select Divider0) or Fss/16384(Select Divider1) as the WDT source. Select Divider0. Select Divider1. Refer to Table 2. Refer to Table 2. No time out. Time out. WDTR.0 will be set to one when WDT time out and can be reset to zero by: Power On Reset, RESET pin, CLR WDT Table 2 The bit 1 of WatchDog Timer Register (WDTR) reset item RESET ITEM Program Counter (PC) Stack Pointer (SP) ROMPR, PAGE, DBKR, WRP, ACC, CF, ZF, SCR registers IEF, HEF, SEF, HCF, PEF, EVF flags DIV0, DIV1 TM0, TM1, MR0, MR1 registers Timer 0 input clock Timer 1 input clock MFP output PM0 register PM1, PM2, PM5 registers PSR0 register Input/output ports RA, RB, RD Output ports RE, RF RA, RB ports output type RC port pull-high resistors Input clock of the watchdog timer DTMF output BUZCR register FLCD LCD display LCDR Segment output mode WDTR.1 = 1 0000H - WDTR.1 = 0 0000H Reset Reset IEF = Reset - Reset Reset Reset FOSC/4 FOSC Low Reset Set (1111B) Reset Input mode High CMOS type Disable FOSC/2048 Hi-Z Reset Q5 to Q9 Reset OFF Reset LCD drive output -: keep the status Note: SCR.2 is reserved - 15 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A 6.12 Timer/Counter 6.12.1 Timer 0 (TM0) Timer 0 (TM0) is a programmable 8-bit binary down-counter. The specified value can be loaded into TM0 by executing the MOV TM0L(TM0H),R instructions. When the MOV TM0L(TM0H),R instructions are executed, it will stop the TM0 down-counting (if the TM0 is down-counting) and reset the MR0.3 to 0, and the specified value can be loaded into TM0. Then we can set MR0.3 to 1, that will cause the event flag 1 (EVF.1) is reset and the TM0 starts to count. When it decreases and underflow to FFH, Timer 0 stops operating and generates an underflow (EVF.1 = 1). Then, if the Timer 0 interrupt enable flag has been set (IEF.1 = 1), the interrupt is executed, while if the hold release enable flag 1 has been set (HEF.1 = 1), the hold state is terminated. The Timer 0 clock input can be set as FOSC/1024 or FOSC/4 by setting MR0.0 to 1 or resetting MR0.0 to 0. The default timer value is FOSC/4. The organization of Timer 0 is shown in Figure 6-6. If the Timer 0 clock input is FOSC/4: Desired Timer 0 interval = (preset value +1) x 4 x 1/FOSC If the Timer 0 clock input is FOSC/1024: Desired Timer 0 interval = (preset value +1) x 1024 x 1/FOSC Preset value: Decimal number of Timer 0 preset value FOSC: Clock oscillation frequency 1. Reset 2. CLR EVF,#02H 3. Reset MR0.3 to 0 4.MOV TM0L,R or MOV TM0H,R MR0.0 Disable Fosc/1024 HEF.1 8-Bit Binary Down Counter (Timer 0) Fosc/4 Enable 4 S R Hold mode release (HCF.1) Q IEF.1 EVF.1 Timer 0 interrupt (INT1) 4 Set MR0.3 to 1 MOV TM0H,R MOV TM0L,R Figure 6-6 Organization of Timer 0 - 16 - 1. Reset 2. CLR EVF,#02H 3.Set MR0.3 to 1 Preliminary W742E81A/W742C81A 6.12.2 Timer 1 (TM1) Timer 1 (TM1) is also a programmable 8-bit binary down counter, as shown in Figure 6-7. Timer 1 can be used as to output an arbitrary frequency to the MFP pin. The input clock of Timer 1 can be one of three sources: FOSC/64, FOSC, or Fs. The source can be selected by setting bit 0 and bit 1 of mode register 1 (MR1). At initial reset, the Timer 1 clock input is FOSC. When the MOV TM1L, R or MOV TM1H,R instruction is executed, the specified data are loaded into the auto-reload buffer; but the TM1 down-counting will keep going on. If the bit 3 of MR1 is set (MR1.3 = 1), the content of the auto-reload buffer will be loaded into the TM1 down counter, and Timer 1 starts to down count, and the event flag 7 is reset (EVF.7 = 0). When the timer decreases and underflow to FFH, it will generate an underflow (EVF.7 = 1) and be auto-reloaded with the specified data, after which it will continue to count down. Then, if interrupt enable flag 7 has been set to 1 (IEF.7 = 1), an interrupt is executed; if hold mode release enable flag 7 is set to 1 (HEF.7 = 1), the hold state is terminated. The specified frequency of Timer 1 can be delivered to the MFP output pin by programming bit 2 of MR1. Bit 3 of MR1 can be used to make Timer 1 stop or start counting. In a case where Timer 1 clock input is FT: Desired Timer 1 interval = (preset value +1) / FT Desired frequency for MFP output pin = FT / (preset value + 1) / 2 (Hz) Preset value: Decimal number of Timer 1 preset value FOSC: Clock oscillation frequency MOV TM1L,R MOV TM1H,R 4 4 S MR1.3 Auto-reload buffer 8 bits Enable Fs FT Fosc MR1.1 Underflow signal 8-Bit Binary Down Counter (Timer 1) Fosc/64 Disable Q R EVF.7 1. Reset 2. INT7 accept 3. CLR EVF, #80H 4. Set MR1.3 to 1 2 circuit MFP output pin 8 bits MR1.0 Reset MOV WR,TM1 Reset MFP signal BUZCR.0 Set MR1.3 to 1 Figure 6-7 Organization of Timer 1 - 17 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A For example, when FT equals 32768 Hz, depending on the preset value of TM1, the MFP pin will output a single tone signal in the tone frequency range from 64 Hz to 16384 Hz. The relation between the tone frequency and the preset value of TM1 is shown in the table below. MOV WR,TM1 can read back the content of TM1, It will save the TM1 MSB to WR and the TM1 LSB to ACC. Table 3 The relation between the tone frequency and the present value of TM1 3rd octave Tone frequency T O N E TM1 preset value & MFP frequency 4th octave Tone frequency 5th octave TM1 preset value & MFP frequency Tone frequency TM1 preset value & MFP frequency C 130.81 7CH 131.07 261.63 3EH 260.06 523.25 1EH 528.51 C# 138.59 75H 138.84 277.18 3AH 277.69 554.37 1CH 564.96 D 146.83 6FH 146.28 293.66 37H 292.57 587.33 1BH 585.14 D# 155.56 68H 156.03 311.13 34H 309.13 622.25 19H 630.15 E 164.81 62H 165.49 329.63 31H 327.68 659.26 18H 655.36 F 174.61 5DH 174.30 349.23 2EH 372.36 698.46 16H 712.34 F# 185.00 58H 184.09 369.99 2BH 390.09 739.99 15H 744.72 G 196.00 53H 195.04 392.00 29H 420.10 783.99 14H 780.19 G# 207.65 4EH 207.39 415.30 26H 443.81 830.61 13H 819.20 A 220.00 49H 221.40 440.00 24H 442.81 880.00 12H 862.84 A# 233.08 45H 234.05 466.16 22H 468.11 932.23 11H 910.22 B 246.94 41H 248.24 493.88 20H 496.48 987.77 10H 963.76 Note: Central tone is A4 (440 Hz). 6.12.3 Mode Register 0 (MR0) Mode Register 0 is organized as a 4-bit binary register (MR0.0 to MR0.3). MR0 can be used to control the operation of Timer 0. The bit descriptions are as follows: 3 MR0 2 1 0 W W Note: W means write only. Bit 0 = 0 =1 The fundamental frequency of Timer 0 is FOSC/4. The fundamental frequency of Timer 0 is FOSC/1024. Bit 1 & Bit 2 are reserved Bit 3 = 0 Timer 0 stops down-counting. =1 Timer 0 starts down-counting. - 18 - Preliminary W742E81A/W742C81A 6.12.4 Mode Register 1 (MR1) & MFP Control Pin (BUZCR) Mode Register 1 is organized as a 4-bit binary register (MR1.0 to MR1.3). MR1 can be used to control the operation of Timer 1. The bit descriptions are as follows: MR1 3 2 1 0 W W W W Note: W means write only. Bit 0 = 0 The internal fundamental frequency of Timer 1 is FOSC. = 1 The internal fundamental frequency of Timer 1 is FOSC/64. Bit 1 = 0 The fundamental frequency source of Timer 1 is the internal clock. = 1 The fundamental frequency source of Timer 1 is the sub-oscillator frequency Fs (32768 Hz). Bit 2 is reserved. Bit 3 = 0 Timer 1 stops down-counting. = 1 Timer 1 starts down-counting. MFP control pin is organized as a 4-bit binary register. 3 BUZCR 2 1 0 W Note: W means write only. Bit 0 = 0 =1 The specified waveform of the MFP generator is delivered to the MFP output pin. The specified frequency of Timer 1 is delivered to the MFP output pin. Bit 1, Bit 2 & Bit 3 are reserved. 6.13 Interrupts The W742E81A/W742C81A provides four internal interrupt sources (Divider 0, Divider 1, Timer 0, Timer 1) and one external interrupt source (port RC). Vector addresses for each of the interrupts are located in the range of program memory (ROM) addresses 004H to 020H. The flags IEF, PEF, and EVF are used to control the interrupts. When EVF is set to "1" by hardware and the corresponding bits of IEF and PEF have been set by software, an interrupt is generated. When an interrupt occurs, all of the interrupts are inhibited until the EN INT or MOV IEF,#I instruction is invoked. The interrupts can also be disabled by executing the DIS INT instruction. When an interrupt is generated in hold mode, the hold mode will be released momentarily and interrupt subroutine will be executed. After the RTN instruction is executed in an interrupt subroutine, the C will enter hold mode again. The operation flow chart is shown in Figure 6-9. The control diagram is shown in Figure 6-9. - 19 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A EN INT Divider 0 overflow signal S EVF.0 Q S EVF.1 Q S EVF.2 Q S IEF.2 Interrupt Interrupt Process Circuit Vector Generator EVF.4 Q R Timer 1 underflow signal 008H IEF.1 R Divider 1 overflow signal 004H IEF.0 R RC port signal change Enable MOV IEF,#I R Timer 0 underflow signal Initial Reset 00CH 014H IEF.4 EVF.7 S Q 020H R IEF.7 Initial Reset CLR EVF,#I instruction Figure 6-8 Disable DIS INT instruction Interrupt event control diagram 6.14 Stop Mode Operation In stop mode, all operations of the C cease, and the MFP pin is kept to high. The C enters stop mode when the STOP instruction is executed and exits stop mode when an external trigger is activated (by a falling signal on the RC). When the designated signal is accepted, the C awakens and executes the next instruction. To prevent erroneous execution, the NOP instruction should follow the STOP command. But In the dual-clock slow operation mode, the STOP instruction will also disable the sub-oscillator oscillating; all operations of the C cease. 6.14.1 Stop Mode Wake-up Enable Flag for RC Port (SEF) The stop mode wake-up flag for port RC is organized as an 4-bit binary register (SEF.0 to SEF.3). Before port RC may be used to make the device exit the stop mode, the content of the SEF must be set first. The SEF is controlled by the MOV SEF, #I instruction. The bit descriptions are as follows: SEF 3 2 1 0 w w w w Note: W means write only. SEF.0 = 1 SEF.1 = 1 Device will exit stop mode when falling edge signal is applied to pin RC.0 Device will exit stop mode when falling edge signal is applied to pin RC.1 - 20 - Preliminary W742E81A/W742C81A SEF.2 = 1 SEF.3 = 1 Device will exit stop mode when falling edge signal is applied to pin RC.2 Device will exit stop mode when falling edge signal is applied to pin RC.3 6.15 Hold Mode Operation In hold mode, all operations of the C cease, except for the operation of the oscillator, Timer, Divider, LCD driver, DTMF generator and MFP generator. The C enters hold mode when the HOLD instruction is executed. The hold mode can be released in one of five ways: by the action of timer 0, timer 1, divider 0, divider 1, the RC port. Before the device enters the hold mode, the HEF, PEF, and IEF flags must be set to define the hold mode release conditions. For more details, refer to the instruction-set table and the following flow chart. Divider 0, Divider 1, Timer 0, Timer 1, Signal Change at RC Port In HOLD Mode? Yes No No Interrupt Enable? No Interrupt Enable? Yes Yes No IEF Flag Set? No IEF Flag Set? Yes Yes Reset EVF Flag Execute Interrupt Service Routine No (Note) Reset EVF Flag Execute Interrupt Service Routine HEF Flag Set? Yes (Note) Disable interrupt Disable interrupt HOLD PC <- (PC+1) Note: The bit of EVF corresponding to the interrupt signal will be reset. Figure 6-9 Hold Mode and Interrupt Operation Flow Chart - 21 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A 6.15.1 Hold Mode Release Enable Flag (HEF) The hold mode release enable flag is organized as an 8-bit binary register (HEF.0 to HEF.7). The HEF is used to control the hold mode release conditions. It is controlled by the MOV HEF, #I instruction. The bit descriptions are as follows: 7 HEF 6 5 4 w 3 w 2 1 0 w w w Note: W means write only. HEF.0 = 1 Overflow from the Divider 0 causes Hold mode to be released. HEF.1 = 1 Underflow from Timer 0 causes Hold mode to be released. HEF.2 = 1 Signal change at port RC causes Hold mode to be released. HEF.3, HEF.5 & HEF.6 are reserved. HEF.4 = 1 Overflow from the Divider 1 causes Hold mode to be released. HEF.7 = 1 Underflow from Timer 1 causes Hold mode to be released. 6.15.2 Interrupt Enable Flag (IEF) The interrupt enable flag is organized as a 8-bit binary register (IEF.0 to IEF.7). These bits are used to control the interrupt conditions. It is controlled by the MOV IEF, #I instruction. When one of these interrupts is accepted, the corresponding to the bit of the event flag will be reset, but the other bits are unaffected. In interrupt subroutine, these interrupts will be disable till the instruction MOV IEF, #I or EN INT is executed again. Otherwise, these interrupts can be disable by executing DIS INT instruction. The bit descriptions are as follows: 7 IEF w 6 5 4 w 3 2 1 0 w w w Note: W means write only. IEF.0 = 1 Interrupt 0 is accepted by overflow from the Divider 0. IEF.1 = 1 Interrupt 1 is accepted by underflow from the Timer 0. IEF.2 = 1 Interrupt 2 is accepted by a signal change at port RC. IEF.3, IEF.5 & IEF.6 are reserved. IEF.4 = 1 Interrupt 4 is accepted by overflow from the Divider 1. IEF.7 = 1 Interrupt 7 is accepted by underflow from Timer 1. 6.15.3 Port Enable Flag (PEF) The port enable flag is organized as 4-bit binary register (PEF.0 to PEF.3). Before port RC may be used to release the hold mode or preform interrupt function, the content of the PEF must be set first. The PEF is controlled by the MOV PEF, #I instruction. The bit descriptions are as follows: - 22 - Preliminary W742E81A/W742C81A PEF 3 2 1 0 w w w w Note: W means write only. PEF.0: Enable/disable the signal change at pin RC.0 to release hold mode or perform interrupt. PEF.1: Enable/disable the signal change at pin RC.1 to release hold mode or perform interrupt. PEF.2: Enable/disable the signal change at pin RC.2 to release hold mode or perform interrupt. PEF.3: Enable/disable the signal change at pin RC.3 to release hold mode or perform interrupt. 6.15.4 Hold Mode Release Condition Flag (HCF) The hold mode release condition flag is organized as a 8-bit binary register (HCF.0 to HCF.7). It indicates by which interrupt source the hold mode has been released, and is loaded by hardware. The HCF can be read out by the MOVA R, HCFL and MOVA R, HCFH instructions. When any of the HCF bits is "1," the hold mode will be released and the HOLD instruction is invalid. The HCF can be reset by the CLR EVF or MOV HEF,#I (HEF = 0) instructions. When EVF and HEF have been reset, the corresponding bit of HCF is reset simultaneously. The bit descriptions are as follows: 7 6 HCF 5 4 R R 3 2 1 0 R R R Note: R means read only. HCF.0 = 1 Hold mode was released by overflow from the divider 0. HCF.1 = 1 Hold mode was released by underflow from the timer 0. HCF.2 = 1 Hold mode was released by a signal change at port RC. HCF.3 is reserved. HCF.4 = 1 Hold mode was released by overflow from the divider 1. HCF.5 = 1 Hold mode was released by underflow from the timer 1. HCF.6 and HCF.7 are reserved. 6.15.5 Event Flag (EVF) The event flag is organized as a 8-bit binary register (EVF.0 to EVF.7). It is set by hardware and reset by CLR EVF,#I instruction or the occurrence of an interrupt. The bit descriptions are as follows: 7 EVF 6 5 R 4 R 3 2 1 0 R R R Note: R means read only. - 23 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A EVF.0 = 1 Overflow from divider 0 occurred. EVF.1 = 1 Underflow from timer 0 occurred. EVF.2 = 1 Signal change at port RC occurred. EVF.3 is reserved. EVF.4 = 1 Overflow from divider 1 occurred. EVF.5 & EVF.6 are reserved. EVF.7 = 1 Underflow from Timer 1 occurred. 6.16 Reset Function The W742E81A/W742C81A is reset either by a power-on reset or by using the external RES pin. The initial state of the W742E81A/W742C81A after the reset function is executed is described below. Table 4 The initial state after the reset function is executed Program Counter (PC) 000H WDTR registers Reset BUZCR registers Reset ACC, CF, ZF registers Reset MR0, MR1, PAGE registers Reset PSR0, SCR, TM0, TM1 registers Reset IEF, HEF, HCF, PEF, EVF, SEF flags Reset WRP, DBKR, PAGE registers Reset Timer 0 input clock FOSC/4 Timer 1 input clock FOSC MFP output Low DTMF output Hi-Z Input/output ports RA, RB, RD Input mode Output port RE & RF High RA, RB ports output type CMOS type RC ports pull-high resistors Disable Input clock of the watchdog timer FOSC/2048 LCD display OFF - 24 - Preliminary W742E81A/W742C81A 6.17 Input/Output Ports RA, RB & RD Port RA consists of pins RA.0 to RA.3. Port RB consists of pins RB.0 to RB.3. Port RD consists of pins RD.0 to RD.3. At initial reset, input/output ports RA, RB and RD are all in input mode. When RA, RB are used as output ports, CMOS or NMOS open drain output type can be selected by the PM0 register. But when RD is used as output port, the output type is just fixed to be CMOS output type. Each pin of port RA, RB and RD can be specified as input or output mode independently by the PM1, PM2 and PM5 registers. The MOVA R, RA or MOVA R, RB or MOVA R, RD instructions operate the input functions and the MOV RA, R or MOV RB, R or MOV RD, R operate the output functions. For more details, refer to the instruction table and Figure 6-10 and Figure 6-11. Input/Output Pin of the RA(RB) PM0.0(PM0.1) DATA BUS I/O PIN RA.n(RB.n) Output Buffer Enable PM1.n (PM2.n) MOV RA,R(MOV RB,R) instruction Enable Figure 6-10 MOVA R,RA(MOVA R,RB) instruction Architecture of RA (RB) Input/Output Pins Input/Output Pin of the RD DATA BUS I/O PIN RD.n Output Buffer Enable PM5.n MOV RD,R instruction Enable Figure 6-11 MOVA R,RD instruction Architecture of RD Input/Output pins 6.17.1 Port Mode 0 Register (PM0) The port mode 0 register is organized as 4-bit binary register (PM0.0 to PM0.3). PM0 can be used to - 25 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A determine the structure of the input/output ports; it is controlled by the MOV PM0, #I instruction. The bit descriptions are as follows: PM0 3 2 1 0 w w w w Note: W means write only. Bit 0 = 0 RA port is CMOS output type. Bit 0 = 1 Bit 1 = 0 RB port is CMOS output type. Bit 1 = 1 Bit 2 = 0 RC port pull-high resistor is disabled. Bit 2 = 1 Bit 3 is reserved. RA port is NMOS open drain output type. RB port is NMOS open drain output type. RC port pull-high resistor is enabled. 6.17.2 Port Mode 1 Register (PM1) The port mode 1 register is organized as 4-bit binary register (PM1.0 to PM1.3). PM1 can be used to control the input/output mode of port RA. PM1 is controlled by the MOV PM1, #I instruction. The bit descriptions are as follows: PM1 3 2 1 0 w w w w Note: W means write only. Bit 0 = 0 RA.0 works as output pin; Bit 0 = 1 RA.0 works as input pin Bit 1 = 0 RA.1 works as output pin; Bit 1 = 1 RA.1 works as input pin Bit 2 = 0 RA.2 works as output pin; Bit 2 = 1 RA.2 works as input pin Bit 3 = 0 RA.3 works as output pin; Bit 3 = 1 RA.3 works as input pin At initial reset, port RA is input mode (PM1 = 1111B). 6.17.3 Port Mode 2 Register (PM2) The port mode 2 register is organized as 4-bit binary register (PM2.0 to PM2.3). PM2 can be used to control the input/output mode of port RB. PM2 is controlled by the MOV PM2, #I instruction. The bit descriptions are as follows: PM2 3 2 1 0 w w w w Note: W means write only. Bit 0 = 0 RB.0 works as output pin; Bit 0 = 1 RB.0 works as input pin Bit 1 = 0 RB.1 works as output pin; Bit 1 = 1 RB.1 works as input pin Bit 2 = 0 RB.2 works as output pin; Bit 2 = 1 RB.2 works as input pin Bit 3 = 0 RB.3 works as output pin; Bit 3 = 1 RB.3 works as input pin At initial reset, the port RB is input mode (PM2 = 1111B). - 26 - Preliminary W742E81A/W742C81A 6.17.4 Port Mode 5 Register (PM5) The port mode 5 register is organized as 4-bit binary register (PM5.0 to PM5.3). PM5 can be used to control the input/output mode of port RD. PM5 is controlled by the MOV PM5, #I instruction. The bit descriptions are as follows: PM5 3 2 1 0 w w w w Note: W means write only. Bit 0 = 0 RD.0 works as output pin; Bit 0 = 1 RD.0 works as input pin Bit 1 = 0 RD.1 works as output pin; Bit 1 = 1 RD.1 works as input pin Bit 2 = 0 RD.2 works as output pin; Bit 2 = 1 RD.2 works as input pin Bit 3 = 0 RD.3 works as output pin; Bit 3 = 1 RD.3 works as input pin At initial reset, the port RD is input mode (PM5 = 1111B). 6.18 Input Ports RC Port RC consists of pins RC.0 to RC.3. Each pin of port RC can be connected to a pull-up resistor, which is controlled by the port mode 0 register (PM0). When the PEF, HEF, and IEF corresponding to the RC port are set, a signal change at the specified pins of port RC will execute the hold mode release or interrupt subroutine. Port status register 0 (PSR0) records the status of ports RC, i.e., any signal changes on the pins that make up the ports. PSR0 can be read out and cleared by the MOV R, PSR0, and CLR PSR0 instructions. In addition, the falling edge signal on the pin of port RC specified by the instruction MOV SEF, #I will cause the device to exit the stop mode. Refer to Figure 6-12 and the instruction table for more details. - 27 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A DATA BUS PM0.2 PEF.0 PSR0.0 D Q Signal change detector RC.0 ck R HEF.2 PM0.2 EVF.2 PEF.1 RC.1 D PSR0.1 D Q Signal change detector HCF.2 Q ck R ck R IEF.2 INT 2 PM0.2 PEF.2 PSR0.2 D Q Signal change detector RC.2 ck R CLR EVF, #I Reset PEF.3 PM0.2 D RC.3 Q Signal change detector PSR0.3 ck R Reset MOV PEF, #I CLR PSR0 SEF.0 Falling Edge detector SEF.1 Falling Edge detector To Wake Up Stop Mode SEF.2 Falling Edge detector SEF.3 Falling Edge detector Figure 6-12 Architecture of Input Ports RC 6.18.1 Port Status Register 0 (PSR0) Port status register 0 is organized as 4-bit binary register (PSR0.0 to PSR0.3). PSR0 can be read or cleared by the MOVA R, PSR0, and CLR PSR0 instructions. The bit descriptions are as follows: PSR0 3 2 1 0 R R R R Note: R means read only. - 28 - Preliminary W742E81A/W742C81A Bit 0 = 1 Bit 1 = 1 Bit 2 = 1 Bit 3 = 1 Signal change at RC.0 Signal change at RC.1 Signal change at RC.2 Signal change at RC.3 6.19 Output Port RE & RF Output port RE is used as an output of the internal RT port. When the MOV RE, R instruction is executed, the data in the RAM will be output to port RT through port RE. It provides a high sink current to drive an LED. RF port is just used as a output port. When the MOV RF, R instruction is executed, the data in the RAM will be output to RF. 6.20 DTMF Output Pin (DTMF) This pin should output the dual tone multi-frequency signal from the DTMF generator. There is the DTMF register that can specify the wanted low/high frequency. And control whether the dual tone will be output or not. The tones are divided into two groups (Row group and Col group) and one tone from each group is selected to represent a digit. The relation between the DTMF signal and the corresponding touch tone keypad is shown in Figure 6-13. C1 C2 C3 C4 1 2 3 A R1 R2 4 R3 5 7 R4 6 8 9 0 * Figure 6-13 B C # D Row/Col Frequency R1 697 Hz R2 770 Hz R3 852 Hz R4 941 Hz C1 1209 Hz C2 1336 Hz C3 1477 Hz C4 1633 Hz The relation between the touch tone keypad and the frequency 6.20.1 DTMF register DTMF register is organized as 4-bit binary register. By controlling the DTMF register, one tone of the low/high group can be selected. The MOV DTMF,R instruction can specify the wanted tones. The bit descriptions are as follows: DTMF 3 2 1 0 W W W W Note: W means write only. - 29 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A B3 B2 B1 B0 SELECTED TONE X X 0 0 1209 Hz High X X 0 1 1336 Hz Group X X 1 0 1477 Hz X 0 X 0 1 X 1 X 1633 Hz 697 Hz Low 0 1 X X 770 Hz Group 1 0 X X 852 Hz 1 1 X X 941 Hz Note: X means this bit do not care. 6.20.2 Dual Tone Control Register (DTCR) Dual tone control register is organized as 4-bit binary register. The output of the dual or single tone will be controlled by this register. The MOV DTCR,#I instruction can specify the wanted status. The bit descriptions are as follows: 3 DTCR 2 1 0 W W W Note: W means write only. Bit 0 = 1 Bit 1 = 1 Bit 2 = 1 Low group tone output is enabled. High group tone output is enabled. DTMF output is enabled. When Bit 2 is reset to 0, the DTMF output pin will be Hi-Z state. Bit 3 is reserved. 6.21 MFP Output Pin (MFP) The MFP output pin can output the Timer 1 clock or the modulation frequency; the output of the pin is determined by bit 0 of BUZCR (BUZCR.0). The organization of MR1 is shown in Figure 6-7. When bit 0 of BUZCR is reset to "0," the MFP output can deliver a modulation output in any combination of one signal from among DC, 4096 Hz, 2048 Hz, and one or more signals from among 128 Hz, 64 Hz, 8 Hz, 4 Hz, 2 Hz, or 1 Hz (when using a 32.768 KHz crystal). The MOV MFP, #I instruction is used to specify the modulation output combination. The data specified by the 8-bit operand and the MFP output pin are shown in next page. - 30 - Preliminary W742E81A/W742C81A Table 5 The relation between the MFP output frequncy and the data specified by 8-bit operand (Fosc = 32.768 KHz) R7 R6 0 0 1 1 0 1 0 1 R5 R4 R3 R2 R1 R0 0 0 0 0 0 0 Low level 0 0 0 0 0 1 128 Hz 0 0 0 0 1 0 64 Hz 0 0 0 1 0 0 8 Hz 0 0 1 0 0 0 4 Hz 0 1 0 0 0 0 2 Hz 1 0 0 0 0 0 1 Hz 0 0 0 0 0 0 High level 0 0 0 0 0 1 128 Hz 0 0 0 0 1 0 64 Hz 0 0 0 1 0 0 8 Hz 0 0 1 0 0 0 4 Hz 0 1 0 0 0 0 2 Hz 1 0 0 0 0 0 1 Hz 0 0 0 0 0 0 2048 Hz 0 0 0 0 0 1 2048 Hz * 128 Hz 0 0 0 0 1 0 2048 Hz * 64 Hz 0 0 0 1 0 0 2048 Hz * 8 Hz 0 0 1 0 0 0 2048 Hz * 4 Hz 0 1 0 0 0 0 2048 Hz * 2 Hz 1 0 0 0 0 0 2048 Hz * 1 Hz 0 0 0 0 0 0 4096 Hz 0 0 0 0 0 1 4096 Hz * 128 Hz 0 0 0 0 1 0 4096 Hz * 64 Hz 0 0 0 1 0 0 4096 Hz * 8 Hz 0 0 1 0 0 0 4096 Hz * 4 Hz 0 1 0 0 0 0 4096 Hz * 2 Hz 1 0 0 0 0 0 4096 Hz * 1 Hz - 31 - FUNCTION Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A 6.22 LCD Controller/Driver The W742E81A/W742C81A can directly drive an LCD with 40 segment output pins and 4 common output pins for a total of 40 x 4 dots. The LCD driving mode is 1/3 bias 1/4 duty. The alternating frequency of the LCD can be set as Fw/64, Fw/128, Fw/256, or Fw/512. The structure of the LCD alternating frequency (FLCD) is shown in the Figure 6-14. Fs or Fosc/128 (By Dual or single clock Option) Fw Q1 Q2 Q3 Q4 Q5 Q6 Q7 Q8 Fw/64 Fw/128 Fw/256 Fw/512 Selector Figure 6-14 Q9 FLCD LCD alternating frequency (FLCD) circuit diagram Fw = 32.768 KHz, the LCD frequency is as shown in the table below. Table 6 The relationship between the FLCD and the duty cycle LCD FREQUENCY Fw/64 (512Hz) Fw/128 (256Hz) Fw/256 (128Hz) Fw/512 (64Hz) 1/4 DUTY 128 Hz 64 Hz 32 Hz 16 Hz Corresponding to the 40 LCD drive output pins, there are 40 LCD data RAM segments. Instructions such as MOV LPL,R, MOV LPH,R, MOV @LP,R, and MOV R,@LP are used to control the LCD data RAM. The data in the LCD data RAM are transferred to the segment output pins automatically without program control. When the bit value of the LCD data RAM is "1," the LCD is turned on. When the bit value of the LCD data RAM is "0," LCD is turned off. The contents of the LCD data RAM (LCDR) are sent out through the segment0 to segment39 pins by a direct memory access. The relation between the LCD data RAM and segment/common pins is shown below. Table 7 The reation between the LCDR and segment/common pins used as LCD drive output pins COM3 COM2 COM1 COM0 LCD DATA RAM OUTPUT PIN BIT 3 BIT 2 BIT 1 BIT 0 LCDR00 SEG0 0/1 0/1 0/1 0/1 LCDR01 SEG1 0/1 0/1 0/1 0/1 : : : : : : : : : : : : LCDR26 SEG38 0/1 0/1 0/1 0/1 LCDR27 SEG39 0/1 0/1 0/1 0/1 - 32 - Preliminary W742E81A/W742C81A The LCDON instruction turns the LCD display on (even in HOLD mode), and the LCDOFF instruction turns the LCD display off. At initial reset, all the LCD segments are unlit. When the initial reset state ends, the LCD display is turned off automatically. To turn on the LCD display, the instruction LCDON must be executed. 6.22.1 LCD RAM addressing method There are 40 LCD RAMs (LCDR00 - LCDR27) that should be indirectly addressed. The LCD RAM pointer (LP) is used to point to the address of the wanted LCD RAM. The LP is organized as 6-bit binary register. The MOV LPL,R and MOV LPH,R instructions can load the LCD RAM address to the LP from R. The MOV @LP,R and MOV R,@LP instructions can access the pointed LCD RAM content. 6.22.2 The output waveforms for the LCD driving mode 1/3 bias 1/4 duty Lighting System (Example) Normal Operating Mode VDD3 VDD2 VDD1 VSS COM0 VDD3 VDD2 VDD1 VSS COM1 VDD3 VDD2 VDD1 VSS COM2 VDD3 VDD2 VDD1 VSS COM3 LCD driver outputs for only seg. on COM0 side being lit VDD3 VDD2 VDD1 VSS LCD driver outputs for only seg. on COM1 side being lit VDD3 VDD2 VDD1 VSS - 33 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A Continued LCD driver outputs for seg. on COM0, COM1 sides being lit VDD3 VDD2 VDD1 VSS LCD driver outputs for seg. on COM1, COM2,3 sides being lit VDD3 VDD2 VDD1 VSS LCD driver outputs for seg. on COM1 COM2 sides being lit VDD3 VDD2 VDD1 VSS LCD driver outputs for seg. on COM0 COM2,3 sides being lit VDD3 VDD2 VDD1 VSS LCD driver outputs for seg. on COM0 COM1,2,3 sides being lit VDD3 VDD2 VDD1 VSS The power connections for the 1/3 bias 1/4 duty LCD driving mode are shown below. 1/3 Bias at VDD = 3.0 V DH1 0.1uF DH2 VSS C H I P 0.1uF VDD VDD1 VDD2 - 34 - VDD = 3.0 V Preliminary W742E81A/W742C81A 6.23 Mode Description The built-in program code memory of the W742E81A/W742C81A is the EEPROM structure. This memory can be programmed, erased and verified through the VPP, MODE and DATA pins. 7. ABSOLUTE MAXIMUM RATINGS PARAMETER RATING UNIT Supply Voltage to Ground Potential -0.3 to +7.0 V Applied Input/Output Voltage -0.3 to +7.0 V 120 mW 0 to +70 C -55 to +150 C Power Dissipation Ambient Operating Temperature Storage Temperature Note: Exposure to conditions beyond those listed under Absolute Maximum Ratings may adversely affect the life and reliability of the device. 8. DC CHARACTERISTICS (VDD-VSS = 3.0 V, Fm = 3.58 MHz, Fs = 32.768 KHz, TA = 25 C, LCD on; unless otherwise specified) PARAMETER Op. Voltage SYM. CONDITIONS MIN. TYP. MAX. UNIT VDD - 2.4 - 3.8 V No load (Ext-V) - 0.9 2.5 mA - 20 30 A - - 450 A - 15 30 A - 1 2 A Op. Current (Crystal type) IOP1 In dual-clock normal operation Op. Current (Crystal type) IOP3 In dual-clock slow operation and Fm is stopped No load (Ext-V) Hold mode No load (Ext-V) Hold Current (Crystal type) IHM1 In dual-clock normal operation Hold Current (Crystal type) IHM3 In dual-clock slow operation and Fm is stopped Hold mode No load (Ext-V) Stop mode No load (Ext-V) Stop Current (Crystal type) ISM1 In dual-clock normal operation - 35 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A DC Characteristics, continued PARAMETER SYM. CONDITIONS MIN. TYP. MAX. UNIT Input Low Voltage VIL - VSS - 0.3 VDD V Input High Voltage VIH - 0.7 VDD - VDD V MFP Output Low Voltage VML IOL = 3.5 mA - - 0.4 V MFP Output High Voltage VMH IOH = 2.4 - - V Port RA, RB, RD and RF Output Low Voltage VABL IOL = 2.0 mA - - 0.4 V Port RA, RB, RD and RF Output high Voltage VABH IOH = 2.0 mA 2.4 - - V LCD Supply Current ILCD All Seg. ON - - 6 A SEG0-SEG39 Sink Current (Used as LCD output) IOL1 VOL = 0.4V VLCD = 0.0V 90 - - A SEG0-SEG39 Drive Current (Used as LCD output) IOH1 VOH = 2.4V VLCD = 3.0V 90 - - A Port RE Sink Current IEL VOL = 0.9V 9 - - mA Port RE Source Current IEH VOH = 2.4V 0.4 1.2 - mA DTMF Output DC level VTDC RL = 5 K, VDD = 2.5 to 3.8V 1.1 - 2.8 V DTMF Distortion THD RL = 5 K, VDD = 2.5 to 3.8V - -30 -23 dB DTMF Output Voltage VTO Low group, RL = 5 K 130 150 170 mVrms Col/Row 1 2 3 dB DTMF Output Sink Current ITL VTO = 0.5V 0.2 - - mA Pull-up Resistor RC Port RC 100 350 1000 K RRES - 20 100 500 K Pre-emphasis RES Pull-up Resistor 3.5 mA 9. AC CHARACTERISTICS PARAMETER SYM. CONDITIONS MIN. TYP. MAX. UNIT FOSC Crystal type - 3.58 - MHz TI One machine cycle - 4/FOSC - S Reset Active Width TRAW FOSC = 32.768 KHz 1 - - S Interrupt Active Width TIAW FOSC = 32.768 KHz 1 - - S Op. Frequency Instruction Cycle time - 36 - Preliminary W742E81A/W742C81A 10. INSTRUCTION SET TABLE Symbol Description ACC: Accumulator ACC.n: Accumulator bit n WR: Working Register WRP: WR Page Register PAGE: Page Register DBKR: Data Bank Register ROMPR: ROM Page Register MR0: Mode Register 0 MR1: Mode Register 1 PM0: Port Mode 0 PM1: Port Mode 1 PM2: Port Mode 2 PM5: Port Mode 5 PSR0: Port Status Register 0 R: Memory (RAM) of address R WDTR: WatchDog Timer Register LPL: LCD data RAM pointer LPH: LCD data RAM pointer R.n: Memory bit n of address R SCR: System Control Register BUZCR: Buzzer Control Register RA: I/O Port RA RC: I/O Port RC DTMF: DTMF Register DTCR: MTMF Control Pin MFP: MFP Output Pin - 37 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A Symbol Description, continued I: Constant parameter L: Branch or Jump address CF: Carry Flag ZF: Zero Flag PC: Program Counter TM0L: Low nibble of the Timer 0 counter TM0H: High nibble of the Timer 0 counter TM1L: Low nibble of the Timer 1 counter TM1H: High nibble of the Timer 1 counter TAB0: Look-up table address buffer 0 TAB1: Look-up table address buffer 1 TAB2: Look-up table address buffer 2 TAB3: Look-up table address buffer 3 IEF.n: Interrupt Enable Flag n HCF.n: HOLD mode release Condition Flag n HEF.n: HOLD mode release Enable Flag n SEF.n: STOP mode wake-up Enable Flag n PEF.n: Port Enable Flag n EVF.n: Event Flag n ! =: Not equal &: AND ^: OR EX: Exclusive OR : Transfer direction, result [PAGE*10H+()]: Contents of address PAGE (bit2, bit1, bit0)*10H+() [P()]: Contents of port P - 38 - Preliminary W742E81A/W742C81A Machine code Mnemonic Function Flag affected W/C Arithmetic 0001 1000 0xxx xxxx ADD R, ACC ACC(R) + (ACC) ZF, CF 1/1 0001 1100 i i i i nnnn ADD WRn, #I ACC(WRn) + I ZF, CF 1/1 0001 1001 0xxx xxxx ADDR R, ACC ACC, R(R) + (ACC) ZF, CF 1/1 0001 1101 i i i i nnnn ADDR WRn, #I ACC, WRn(WRn) + I ZF, CF 1/1 0000 1000 0xxx xxxx ADC R, ACC ACC(R) + (ACC) + (CF) ZF, CF 1/1 0000 1100 i i i i nnnn ADC WRn, #I ACC(WRn) + I + (CF) ZF, CF 1/1 0000 1001 0xxx xxxx ADCR R, ACC ACC, R(R) + (ACC) + (CF) ZF, CF 1/1 0000 1101 i i i i nnnn ADCR WRn, #I ACC, WRn(WRn) + I + (CF) ZF, CF 1/1 0010 1000 0xxx xxxx ADU R, ACC ACC(R) + (ACC) ZF 1/1 0010 1100 i i i i nnnn ADU WRn, #I ACC(WRn) + I ZF 1/1 0010 1001 0xxx xxxx ADUR R, ACC ACC, R(R) + (ACC) ZF 1/1 0010 1101 i i i i nnnn ADUR WRn, #I ACC, WRn(WRn) + I ZF 1/1 0001 1010 0xxx xxxx SUB R, ACC ACC(R) - (ACC) ZF, CF 1/1 0001 1110 i i i i nnnn SUB WRn, #I ACC(WRn) - I ZF, CF 1/1 0001 1011 0xxx xxxx SUBR R, ACC ACC, R(R) - (ACC) ZF, CF 1/1 0001 1111 i i i i nnnn SUBR WRn, #I ACC, WR(WR) - I ZF, CF 1/1 0000 1010 0xxx xxxx SBC R, ACC ACC(R) - (ACC) - (CF) ZF, CF 1/1 0000 1110 i i i i nnnn SBC WRn, #I ACC(WRn) - I - (CF) ZF, CF 1/1 0000 1011 0xxxxxxx SBCR R, ACC ACC, R(R) - (ACC) - (CF) ZF, CF 1/1 0000 1111 i i i i nnnn SBCR WRn, #I ACC, WRn(WRn) - I - (CF) ZF, CF 1/1 0100 1010 0xxx xxxx INC R ACC, R(R) + 1 ZF, CF 1/1 0100 1010 1xxx xxxx DEC R ACC, R(R) - 1 ZF, CF 1/1 - 39 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A Instruction set, continued Machine code Mnemonic Function Flag affected W/C Logic 0010 1010 0xxx xxxx ANL R, ACC ACC(R) & (ACC) ZF 1/1 0010 1110 i i i i nnnn ANL WRn, #I ACC(WRn) & I ZF 1/1 0010 1011 0xxx xxxx ANLR R, ACC ACC, R(R) & (ACC) ZF 1/1 0010 1111 i i i i nnnn ANLR WRn, #I ACC, WRn(WRn) & I ZF 1/1 0011 1010 0xxx xxxx ORL R, ACC ACC(R) (ACC) ZF 1/1 0011 1110 i i i i nnnn ORL WRn, #I ACC(WRn) I ZF 1/1 0011 1011 0xxx xxxx ORLR R, ACC ACC, R(R) (ACC) ZF 1/1 0011 1111 i i i i nnnn ORLR WRn, #I ACC, WRn(WRn) I ZF 1/1 0011 1000 0xxx xxxx XRL R, ACC ACC(R) EX (ACC) ZF 1/1 0011 1100 i i i i nnnn XRL WRn, #I ACC(WRn) EX I ZF 1/1 0011 1001 0xxx xxxx XRLR R, ACC ACC, R(R) EX (ACC) ZF 1/1 0011 1101 i i i i nnnn XRLR WRn, #I ACC, WRn(WRn) EX I ZF 1/1 0111 0aaa aaaa aaaa JMP L PC12~PC0(ROMPR)x800H+L10~L0 1/1 1000 0aaa aaaa aaaa JB0 L PC10~PC0L10~L0; if ACC.0 = "1" 1/1 1001 0aaa aaaa aaaa JB1 L PC10~PC0 L10~L0; if ACC.1 = "1" 1/1 1010 0aaa aaaa aaaa JB2 L PC10~PC0L10~L0; if ACC.2 = "1" 1/1 1011 0aaa aaaa aaaa JB3 L PC10~PC0L10~L0; if ACC.3 = "1" 1/1 1110 0aaa aaaa aaaa JZ L PC10~PC0L10~L0; if ACC = 0 1/1 1100 0aaa aaaa aaaa JNZ L PC10~PC0L10~L0; if ACC ! = 0 1/1 1111 0aaa aaaa aaaa JC L PC10~PC0L10~L0; if CF = "1" 1/1 1101 0aaa aaaa aaaa JNC L PC10~PC0L10~L0; if CF != "1" 1/1 0100 1000 0xxx xxxx DSKZ R 0100 1000 1xxx xxxx DSKNZ R 1010 1000 0xxx xxxx SKB0 R ACC, R(R) - 1; PC (PC) + 2 if ACC = 0 ACC, R(R) - 1; PC (PC) + 2 if ACC != 0 PC (PC) + 2 if R.0 = "1" 1010 1000 1xxx xxxx SKB1 R PC (PC) + 2 if R.1 = "1" 1/1 1010 1001 0xxx xxxx SKB2 R PC (PC) + 2 if R.2 = "1" 1/1 1010 1001 1xxx xxxx SKB3 R PC (PC) + 2 if R.3 = "1" 1/1 Branch - 40 - ZF, CF 1/1 ZF, CF 1/1 1/1 Preliminary W742E81A/W742C81A Instruction set, continued Machine code Mnemonic Function Flag affected W/C ZF 1/1 Data move 0001 0000 0000 iiii MOV ACC, #I ACCI 1110 1nnn nxxx xxxx MOV WRn, R WRn(R) 1/1 1001 1001 iiii nnnn MOV WRn, #I WRnI 1/1 1111 1nnn nxxx xxxx MOV R, WRn R(WRn) 1/1 0110 1nnn nxxx xxxx MOVA WRn, R ACC, WRn(R) ZF 1/1 0111 1nnn nxxx xxxx MOVA R, WRn ACC, R(WRn) ZF 1/1 0101 1001 1xxx xxxx MOV R, ACC R(ACC) 0100 1110 1xxx xxxx MOV ACC, R ACC(R) 1011 1i i i i xxx xxxx MOV R, #I RI 1/1 1100 1nnn n000 qqqq MOV WRn, @WRq WRn[(DBKR)x80H+(PAGE)x10H +(WRq)] 1/2 1101 1nnn n000 qqqq MOV @WRq, WRn [(DBKR)x80H+(PAGE)x10H +(WRq)]WRn 1/2 1000 1100 0xxx xxxx MOV TAB0, R TAB0(R) 1/1 1000 1100 1xxx xxxx MOV TAB1, R TAB1(R) 1/1 1000 1110 0xxx xxxx MOV TAB2, R TAB2(R) 1/1 1000 1110 1xxx xxxx MOV TAB3, R TAB3(R) 1/1 1000 1101 0xxx xxxx MOVC R R[(TAB3)x1000H+(TAB2)x100H+(TAB1) x10H + (TAB0)] 1/2 MOVA R, RA ACC, R[RA] ZF 1/1 0101 1011 1xxx xxxx MOVA R, RB ACC, R[RB] ZF 1/1 0100 1011 0xxx xxxx MOVA R, RC ACC, R[RC] ZF 1/1 0100 1011 1xxx xxxx MOVA R, RD ACC, R[RD] ZF 1/1 0101 1010 0xxx xxxx MOV RA, R [RA](R) 1/1 0101 1010 1xxx xxxx MOV RB, R [RB] (R) 1/1 0100 1010 0xxx xxxx MOV RC, R [RC] (R) 1/1 1010 1100 1xxx xxxx MOV RD, R [RD](R) 1/1 0101 1110 0xxx xxxx MOV RE, R [RE](R) 1/1 1010 1110 0xxx xxxx MOV RF, R [RF](R) 1/1 1/1 ZF 1/1 Input & Output 0101 1011 0xxx xxxx - 41 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A Instruction set, continued Machine code Mnemonic Function Flag affected W/C ZF 1/1 Flag & Register 0101 1111 1xxx xxxx MOVA R, PAGE ACC, RPAGE (Page Register) 0101 1110 1xxx xxxx MOV PAGE, R PAGE(R) 1/1 0101 0110 1000 0i i i MOV PAGE, #I PAGEI 1/1 1001 1101 1xxx xxxx MOV R, WRP RWRP 1/1 1001 1100 1xxx xxxx MOV WRP, R WRP(R) 1/1 0011 0101 1000 i i i i MOV WRP, #I WRPI 1/1 1001 1101 0000 nnnn MOV WRn,DBKR WRnDBKR 1/1 1001 1111 0000 nnnn MOV WRn,TM1 WRnTM1.4 - TM1.7, ACCTM1.0 TM1.3 1/1 1001 1100 0000 nnnn MOV DBKR, WRn DBKRWRn 1/1 0011 0101 0000 ii i i MOV DBKR, #I DBKRI 1/1 0011 0100 0000 0ii i MOV ROMPR, #I ROMPRI 1/1 1000 1000 0xxx xxxx MOV ROMPR, R ROMPR(R) 1/1 1000 1001 0xxx xxxx MOV R, ROMPR R(ROMPR) 1/1 0101 1001 0xxx xxxx MOVA R, CF ACC.0, R.0CF ZF 1/1 0101 1000 0xxx xxxx MOV CF, R CF(R.0) CF 1/1 0100 1001 0xxx xxxx MOVA R, HCFL ACC, RHCF.0~HCF.3 ZF 1/1 0100 1001 1xxx xxxx MOVA R, HCFH ACC, RHCF.4~HCF.7 ZF 1/1 0101 0011 0000 i i i i MOV PM0, #I Port Mode 0 I 1/1 0101 0111 0000 i i i i MOV PM1, #I Port Mode 1 I 1/1 0101 0111 1000 i i i i MOV PM2, #I Port Mode 2 I 1/1 0011 0111 1000 i i i i MOV PM5, #I Port Mode 5 I 1/1 0100 0000 i 0 0 i 0i i i CLR EVF, #I Clear Event Flag if In = 1 1/1 0101 1101 0xxx xxxx MOVA R, EVFL R EVF.0 - EVF.3 1/1 0101 1101 1xxx xxxx MOVA R, EVFH R EVF.4 - EVF.7 1/1 0100 0001 i 0 0 i 0i i i MOV HEF, #I Set/Reset HOLD mode release Enable Flag 1/1 0101 0001 i 0 0 i 0i i i MOV IEF, #I Set/Reset Interrupt Enable Flag 1/1 0100 0011 0000 i i i i MOV PEF, #I Set/Reset Port Enable Flag 1/1 0101 0010 0000 i i i i MOV SEF, #I Set/Reset STOP mode wake-up Enable Flag for RC port 1/1 - 42 - Preliminary W742E81A/W742C81A Instruction set, continued Machine code Mnemonic Function Flag affected W/C Flag & Register 0101 0100 0000 i 0 i i MOV SCR, #I SCRI 0100 1111 0xxx xxxx MOVA R, PSR0 ACC, RPort Status Register 0 0100 0010 0000 0000 CLR PSR0 Clear Port Status Register 0 0101 0000 0100 0000 SET CF Set Carry Flag CF 1/1 0101 0000 0000 0000 CLR CF Clear Carry Flag CF 1/1 0001 0111 0000 0000 CLR DIVR0 Clear the last 4-bit of the Divider 0 1/1 0101 0101 1000 0000 CLR DIVR1 Clear the last 4-bit of the Divider 1 1/1 0101 0110 0000 i i i i MOV WDTR, #I WDTRI 1/1 0101 1111 0xxx xxxx MOVA R,WDTR ACC, RWatchdog Timer Register 1/1 0001 0111 1000 0000 CLR WDT Clear Watchdog Timer 1/1 1001 1110 1xxx xxxx MOV DTMF,R DTMF(R) 1/1 0011 0100 1000 0iii MOV DTCR,I DTCRI 1/1 SHRC R ACC.n, R.n(R.n+1); ZF, CF 1/1 ACC.n, R.n(R.n+1); ZF, CF 1/1 ACC.n, R.n(R.n-1); ZF, CF 1/1 ACC.n, R.n(R.n-1); ZF, CF 1/1 1/1 ZF 1/1 1/1 DTMF Shift & Rotate 0100 1101 0xxx xxxx ACC.3, R.30; CFR.0 0100 1101 1xxx xxxx RRC R ACC.3, R.3CF; CFR.0 0100 1100 0xxx xxxx SHLC R 0100 1100 1xxx xxxx RLC R ACC.0, R.00; CFR.3 ACC.0, R.0CF; CFR.3 - 43 - Publication Release Date: April 2000 Revision A1 Preliminary W742E81A/W742C81A Instruction set, continued Machine code Mnemonic Function Flag affected W/C LCD 1001 1000 0xxx xxxx MOV LPL, R LPL(R) 1/1 1001 1000 1xxx xxxx MOV LPH, R LPH(R) 1/1 1001 1010 0xxx xxxx MOV @LP, R [(LPH)x10H+(LPL)](R) 1/1 1001 1011 0xxx xxxx MOV R, @LP R[(LPH) x10H+(LPL)] 1/1 0000 0010 0000 0000 LCDON LCD ON 1/1 0000 0010 1000 0000 LCDOFF LCD OFF 1/1 MFP 0011 0110 0000 000i MOV BUZCR, #I BUZCR I 1/1 1000 1010 0xxx xxxx MOV BUZCR, R BUZCR(R) 1/1 1000 1011 0xxx xxxx MOV R,BUZCR R(BUZCR) 1/1 0001 0010 MOV MFP, #I [MFP] I 1/1 1010 1010 0xxx xxxx MOV TM0L, R TM0L(R) 1/1 1010 1010 1xxx xxxx MOV TM0H, R TM0H(R) 1/1 1010 1011 0xxx xxxx MOV TM1L, R TM1L(R) 1/1 1010 1011 1xxx xxxx MOV TM1H, R TM1H(R) 1/1 0001 0011 1000 i00i MOV MR0,#I MR0(R) 1/1 0001 0011 0000 iiii MOV MR1,#I MR1(R) 1/1 iiii iiii Timer Other 0000 0000 1000 0000 HOLD Enter Hold mode 1/1 0000 0000 1100 0000 STOP Enter Stop mode 1/1 0000 0000 0000 0000 NOP No operation 1/1 0101 0000 1100 0000 EN INT Enable interrupt function 1/1 0101 0000 1000 0000 DIS INT Disable interrupt function 1/1 Subroutine 0110 0aaa aaaa aaaa CALL L Push Stack: STACK <- PC+1, TAB0, TAB1, TAB2, TAB3, DBKR, WRP, ROMPR, PAGE, ACC, CF; PC12~PC0<- (ROMPR)x800H+L10~L0 1/1 0000 0001 iiii iiii RTN #I (PC) <- STACK; Pop other register by I Table setting (Refer to Table 8) 1/1 - 44 - Preliminary W742E81A/W742C81A Table 8 The bit definition of RTN BIT DEFINITION OF I I = 0000 0000 Pop PC from stack only bit0 = 1 Pop PC and TAB0, TAB1, TAB2, TAB3 from stack bit1 = 1 Pop PC and DBKR from stack bit2 = 1 Pop PC and WRP from stack bit3 = 1 Pop PC and ROMPR from stack bit4 = 1 Pop PC and PAGE from stack bit5 = 1 Pop PC and ACC from stack bit6 = 1 Pop PC and CF from stack Headquarters Winbond Electronics (H.K.) Ltd. Rm. 803, World Trade Square, Tower II, No. 4, Creation Rd. III, 123 Hoi Bun Rd., Kwun Tong, Science-Based Industrial Park, Kowloon, Hong Kong Hsinchu, Taiwan TEL: 852-27513100 TEL: 886-3-5770066 FAX: 852-27552064 FAX: 886-3-5792766 http://www.winbond.com.tw/ Voice & Fax-on-demand: 886-2-27197006 Winbond Electronics North America Corp. Winbond Memory Lab. Winbond Microelectronics Corp. Winbond Systems Lab. 2727 N. First Street, San Jose, CA 95134, U.S.A. TEL: 408-9436666 FAX: 408-5441798 Taipei Office 11F, No. 115, Sec. 3, Min-Sheng East Rd., Taipei, Taiwan TEL: 886-2-27190505 FAX: 886-2-27197502 Note: All data and specifications are subject to change without notice. - 45 - Publication Release Date: April 2000 Revision A1