EM78P451 8-Bit Microcontroller with OTP ROM Product Specification DOC. VERSION 1.1 ELAN MICROELECTRONICS CORP. June 2003 Trademark Acknowledgments: IBM is a registered trademark and PS/2 is a trademark of IBM. Windows is a trademark of Microsoft Corporation. ELAN and ELAN logo are trademarks of ELAN Microelectronics Corporation. Copyright © 2005 by ELAN Microelectronics Corporation All Rights Reserved Printed in Taiwan The contents of this specification are subject to change without further notice. ELAN Microelectronics assumes no responsibility concerning the accuracy, adequacy, or completeness of this specification. ELAN Microelectronics makes no commitment to update, or to keep current the information and material contained in this specification. Such information and material may change to conform to each confirmed order. In no event shall ELAN Microelectronics be made responsible for any claims attributed to errors, omissions, or other inaccuracies in the information or material contained in this specification. ELAN Microelectronics shall not be liable for direct, indirect, special incidental, or consequential damages arising from the use of such information or material. The software (if any) described in this specification is furnished under a license or nondisclosure agreement, and may be used or copied only in accordance with the terms of such agreement. ELAN Microelectronics products are not intended for use in life support appliances, devices, or systems. Use of ELAN Microelectronics product in such applications is not supported and is prohibited. NO PART OF THIS SPECIFICATION MAY BE REPRODUCED OR TRANSMITTED IN ANY FORM OR BY ANY MEANS WITHOUT THE EXPRESSED WRITTEN PERMISSION OF ELAN MICROELECTRONICS. ELAN MICROELECTRONICS CORPORATION Headquarters: Hong Kong: USA: No. 12, Innovation Road 1 Hsinchu Science Park Hsinchu, Taiwan 30077 Tel: +886 3 563-9977 Fax: +886 3 563-9966 http://www.emc.com.tw Elan (HK) Microelectronics Corporation, Ltd. Elan Information Technology Group Rm. 1005B, 10/F Empire Centre 68 Mody Road, Tsimshatsui Kowloon , HONG KONG Tel: +852 2723-3376 Fax: +852 2723-7780 [email protected] 1821 Saratoga Ave., Suite 250 Saratoga, CA 95070 USA Tel: +1 408 366-8223 Fax: +1 408 366-8220 Europe: Shenzhen: Shanghai: Elan Microelectronics Corp. (Europe) Elan Microelectronics Shenzhen, Ltd. Elan Microelectronics Shanghai Corporation, Ltd. Siewerdtstrasse 105 8050 Zurich, SWITZERLAND Tel: +41 43 299-4060 Fax: +41 43 299-4079 http://www.elan-europe.com SSMEC Bldg., 3F, Gaoxin S. Ave. Shenzhen Hi-Tech Industrial Park Shenzhen, Guandong, CHINA Tel: +86 755 2601-0565 Fax: +86 755 2601-0500 23/Bldg. #115 Lane 572, Bibo Road Zhangjiang Hi-Tech Park Shanghai, CHINA Tel: +86 021 5080-3866 Fax: +86 021 5080-4600 Contents Contents 1 2 3 4 GENERAL DESCRIPTION ................................................................................................... 1 FEATURES........................................................................................................................... 1 PIN ASSIGNMENT ............................................................................................................... 2 FUNCTION DESCRIPTION.................................................................................................. 4 4.1 Operational Registers ..................................................................................................4 4.1.1 4.1.2 4.1.3 4.1.4 4.1.5 4.1.6 4.1.7 4.1.8 4.1.9 4.1.10 4.1.11 4.1.12 4.1.13 4.1.14 4.1.15 4.2 R0 (Indirect Address Register) ......................................................................................4 R1 (TCC) .......................................................................................................................4 R2 (Program Counter) & Stack......................................................................................4 R3 (Status Register) ......................................................................................................6 R4 (RAM Select Register) .............................................................................................6 R5~R8 (Port 5 ~ Port8)..................................................................................................6 R9 (Port9) ......................................................................................................................7 RA (SPIRB: SPI Read Buffer)........................................................................................8 RB (SPIWB: SPI Write Buffer).......................................................................................8 RC (SPIS: SPI Status Segister).....................................................................................8 RD (SPIC: SPI Control Register)...................................................................................9 RE (TMR1: Timer1 register) ..........................................................................................9 RF (PWP: Pulse width preset register)........................................................................10 R20~R3E (General Purpose Register)........................................................................10 R3F (Interrupt Status Register) ...................................................................................10 Special Purpose Registers .........................................................................................10 4.2.1 4.2.2 4.2.3 4.2.4 4.2.5 4.2.6 4.2.7 A (Accumulator) ...........................................................................................................10 CONT (Control Register) .............................................................................................10 IOC5 ~ IOC9 (I/O Port Control Register)..................................................................... 11 IOCC (T1CON: Timer1 Control Register).................................................................... 11 IOCD (Pull-high Control Register) ...............................................................................12 IOCE (WDT Control Register) .....................................................................................12 IOCF (Interrupt Mask Register) ...................................................................................13 4.3 TCC/WDT Presacler ..................................................................................................14 4.4 I/O Ports .....................................................................................................................15 4.5 SERIAL PERIPHERAL INTERFACE MODE ..............................................................17 4.5.1 4.5.2 4.5.3 4.5.4 4.5.5 4.5.6 4.6 Overview & Features ...................................................................................................17 SPI Function Description .............................................................................................19 SPI Signal & Pin Description .......................................................................................20 Programmed the Related Registers ............................................................................22 SPI Mode Timing .........................................................................................................24 Software Application of SPI .........................................................................................25 Timer 1 .......................................................................................................................29 4.6.1 4.6.2 Overview......................................................................................................................29 Function Description....................................................................................................30 Product Specification (V1.1) 06.30.2003 • iii Contents 4.6.3 4.7 Programmed the Related Registers ............................................................................30 RESET and Wake-up .................................................................................................31 4.7.1 The Status of RST, T, and P of STATUS Register .......................................................36 4.8 Interrupt......................................................................................................................36 4.9 Oscillator ....................................................................................................................37 4.9.1 4.9.2 4.9.3 Oscillator Modes..........................................................................................................37 Crystal Oscillator/Ceramic Resonators (XTAL) ...........................................................38 RC Oscillator Mode .....................................................................................................39 4.10 Code Option Register.................................................................................................41 4.11 Instruction Set ............................................................................................................42 5 6 4.12 Timing Diagrams ........................................................................................................45 ABSOLUTE MAXIMUM RATING ....................................................................................... 46 ELECTRICAL CHARACTERISTICS .................................................................................. 46 6.1 7 DC Characteristic .......................................................................................................46 6.2 AC Characteristic .......................................................................................................47 Application Circuit ............................................................................................................ 48 APPENDIX A Package Types .................................................................................................................. 49 Specification Revision History iv • Doc. Version Revision Description 1.0 Initial version 1.1 Change Power on reset content Date 2003/06/30 Product Specification (V1.1) 06.30.2003 EM78P451 8-Bit Microcontroller with OTP ROM 1 GENERAL DESCRIPTION The EM78P451 is an 8-bit microprocessor designed and developed with low-power, high speed CMOS technology. Its operational kernel is implemented with RISC-like architecture and is available in the mask ROM version. The one time programmable (OTP) version is flexible, both in mass production or engineering test stages. OTP provide users with unlimited volume with favorable price opportunities. This device is equipped with the Serial Peripheral Interface (SPI) function and an easy-implemented RS-232. The EM78P451 is very suitable for wired communication. Only 58 easy-to-learn instructions are needed and user’s program can be emulated with EMC In-Circuit Emulator (ICE). 2 FEATURES Operating voltage range: 2.3V~5.5V. Operating temperature range: 0°C~70°C. Operating frequency rang (base on 2 clocks ): • Crystal mode: DC~20MHz at 5V, DC~8MHz at 3V, DC~4MHz at 2.3V. • RC mode: DC~4MHz at 5V, DC~4MHz at 3V, DC~4MHz at 2.3V. Low power consumption: • Less then 3 mA at 5V/4MHz • Typically 10 µA during sleep mode Serial Peripheral Interface (SPI) available. 4K × 13 bits on chip ROM (EM78P451). 11 special function registers. 140× 8 bits on chip general-purposed registers. 5 bi-directional I/O ports (35 I/O pins). 3 LED direct sinking pins with internal serial resistors. Built-in RC oscillator with external serial resistor, ±10% variation. Built-in power-on reset. 5 stacks for subroutine nesting. 8-bit real time clock/counter (TCC) with overflow interrupt. Two machine clocks or four machine clocks per instruction cycle. Power down mode. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) •1 EM78P451 8-Bit Microcontroller with OTP ROM Programmable wake up from sleep circuit on I/O ports. Programmable free running on-chip watchdog timer. 12 wake-up pins. 2 open-drain pins. 2 R-option pins. 32 programmable pull-high input pins. Packages: • 40 pin DIP 600mil: EM78P451P. • 44 pin QFP: EM78P451AQ. Four types of interrupts. • • • • SPI transmission completed interrupt. TCC overflow interrupt. Timer1 comparator match interrupt. S C K /P 9 4 9 S S /P 9 5 10 P 50 11 P 51 12 P 52 13 P 53 32 P 65 31 P 64 30 P 63 29 P 62 28 P 61 14 27 P 60 P 54 15 26 P 87 P 55 16 25 P 86 P 56 17 24 P 85 P 57 18 23 P 84 P 80 19 22 P 83 P 81 20 21 P 82 P90 P91 S D I/P 9 2 S D O /P 9 3 S C K /P 9 4 S S /P 9 5 P50 P51 P52 P53 P54 NC NC NC P70 36 35 34 VDD 38 37 R-OSCI 39 1 33 2 32 3 31 4 30 5 29 EM 78P451AQ 6 28 7 27 8 26 9 25 10 24 11 23 P71 P72 P67 P66 P65 P64 P63 P62 P61 P60 P87 22 P 66 P86 33 P85 21 8 P84 20 P 67 S D O /P 9 3 P83 19 P 72 34 17 35 7 P55 12 6 S D I/P 9 2 P82 18 P 91 P 70 NC P 71 VSS 36 O SCO 5 40 P 90 V D D 41 37 P80 15 4 P81 16 C L K DATA 38 INT 3 42 R -O S C I D A T A P57 14 O S C O 39 CLK 40 2 43 1 IN T P56 13 V S S 44 PIN ASSIGNMENT EM78P451P/W M 3 External interrupt (/INT). Fig. 1 Pin Assignment 2• Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Table 1 Pin description Symbol Pin No. Type Function Description R-OSCI 39 I ■ In XTAL mode: Crystal input; In internal C, external R mode: 56Kohm±5% pull high for 1.8432MHz. OSCO 40 O ■ In XTAL mode: Crystal output; In RC mode: Instruction clock output. P90~P95 5~10 I/O P80~P87 19~26 I/O P70~P72 37~35 I/O CLK 4 I/O DATA 3 I/O P60~P67 27~34 I/O P50~P57 11~18 I/O VDD 38 - ■ Power supply pin. VSS 1 - ■ Ground pin. ■ An interrupt schmitt-triggered pin. ■ The function of interrupt triggers at the falling edge. ■ Users can enable it by software. The internal pull-up resistor is around 50K ohms. ■ General bi-directional I/O port. All of its pins can be pulled-high by software. P90 and P91 are pin-change wake up pins. ■ General bi-directional I/O port. All of its pins can be pulled-high by software. P80 and P81 are also used as the R-option pins. ■ LED direct-driving pin with internal serial resistor used as output and is software defined. ■ By connecting P74 and P76 together. ■ P74 can be pulled-high by software and it is also a pin-change wake up pin. ■ P76 can be defined as an open-drain output. ■ By connecting P75 and P77 together. ■ P75 can be pulled-high by software and it is also a pin-change wake up pin. ■ P77 can be defined as an open-drain output. ■ General bi-directional port. All of its pins can be pulled-high by software, and pin-change wake up pins. ■ General bi-directional I/O port. All of its pins can be pulled-high individually by software. /INT 2 I SDI 7 I/O ■ Serial data in for SPI. SDO 8 I/O ■ Serial data out for SPI. SCK 9 I/O ■ Serial clock for SPI. /SS 10 I/O ■ /Slave select for SPI. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) •3 EM78P451 8-Bit Microcontroller with OTP ROM 4 FUNCTION DESCRIPTION W DT Tim er W DT Tim e-out PC STACK 1 STACK 2 Prescaler STACK 3 Oscillator/ Tim m ing Control / INT STACK 4 ROM STACK 5 Interrupt Control R1(TCC) Sleep & W ake Up Control Instruction Register ALU Instruction Decoder RAM R3 ACC TM R1 R4 DATA & CONTROL BUS IOC5 R5 IOC6 R6 IOC7 R7 PPPPPPPP 55555555 01234567 PPPPPPPP 66666666 01234567 P 7 0 P 7 1 IOC9 R9 IOC8 R8 P PP P 9 9 9 9 0 1 2 3 / / S S DD I O PPPPPPPP 88888888 01234567 P 7 2 P 9 4 / S C K SPI ENGIN P 5 5 / / S S Fig. 2 Functional Block Diagram 4.1 Operational Registers 4.1.1 R0 (Indirect Address Register) R0 is not a physically implemented register. It is used as an indirect addressing pointer. Any instruction using R0 as register actually accesses data pointed by the RAM Select Register (R4). 4.1.2 R1 (TCC) Increased by the instruction cycle clock. Written and read by program as any other register. 4.1.3 R2 (Program Counter) & Stack R2 and the hardware stacks are 12 bits wide. The structure is depicted in Fig. 3. Generates 4K × 13 on-chip ROM addresses to the relative programming instruction codes. One program page is 1024 words long. All the R2 bits are set to "1"s as a RESET condition occurs. "JMP" instruction allows direct loading of the lower 10 program counter bits. Thus, "JMP" allows jump to any location on one page. 4• Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM "CALL" instruction loads the lower 10 bits of the PC, and then PC+1 is pushed into the stack. Thus, the subroutine entry address can be located anywhere within a page "RET" ("RETL k", "RETI") instruction loads the program counter with the contents at the top of stack. "MOV R2, A" allows the loading of an address from the "A" register to the lower 8 bits of PC, and the ninth and tenth bits (A8~A9) of PC are cleared. "ADD R2, A" allows a relative address be added to the current PC, and the ninth and tenth bits of PC are cleared. Any instruction that is written to R2 (e.g. "ADD R2, A", "MOV R2, A", "BC R2,6",⋅⋅⋅⋅⋅) (except "TBL") will cause the ninth and tenth bits (A8~A9) of PC to be cleared. Thus, the computed jump is limited to the first 256 locations of any program page. "TBL" allows a relative address be added to the current PC (R2+A→R2), and contents of the ninth and tenth bits (A8~A9) of PC are not changed. Thus, the computed jump can be on the second (or third, 4th) 256 locations on one program page. In case of EM78P451, the most significant bits (A10~A11) will be loaded with the contents of bits PS0~PS1 in the status register (R3) upon the execution of a "JMP", "CALL", or any other instructions which writes to R2. All instructions are single instruction cycle (fclk/2 or fclk/4) except for the instruction that would change the contents R2. Such instruction will need one more instruction cycle. CALL PC A11A10 00 A9A8 000 3FF 01 400 7FF A7 ~ A0 Stack 1 RET Stack 2 RETL Stack 3 RETI Stack 4 Stack 5 Page 0 001:Hareware interrupt location Page 1 002:Software interrupt (INT instruction) location FFF:Reset location 10 800 11 C00 BFF FFF Page 2 Page 3 Fig. 3 Program Counter Organization Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) •5 EM78P451 8-Bit Microcontroller with OTP ROM 4.1.4 R3 (Status Register) 7 6 5 4 3 2 1 0 GP PS1 PS0 T P Z DC C Bit 0 (C) Carry flag Bit 1 (DC) Auxiliary carry flag Bit 2 (Z) Zero flag. Set to "1" if the result of an arithmetic or logic operation is zero. Bit 3 (P) Power down bit. Set to 1 during power on or by a "WDTC" command and reset to 0 by a "SLEP" command. Bit 4 (T) Time-out bit. Set to 1 with the "SLEP" and the "WDTC" commands, or during power up and reset to 0 with WDT timeout. Bits 5 (PS0) ~ 6 (PS1) Page select bits. PS0~PS1 are used to pre-select a program memory page. When executing a "JMP", "CALL", or other instructions which causes the program counter to be changed (e.g. MOV R2, A), PS0~PS1 are loaded into the 11th and 12th bits of the program counter where it selects selecting one of the available program memory pages. Note that RET (RETL, RETI) instruction does not change the PS0~PS1 bits. That is, the return will always be to the page from where the subroutine was called, regardless of the current setting of PS0~PS1 bits. PS1 bit is not used (read as "0") and cannot be modified in EM78P451. PS1 PS0 Program memory page [Address] 0 0 Page 0 [000-3FF] 0 1 Page 1 [400-7FF] 1 0 Page 2 [800-BFF] 1 1 Page 3 [C00-FFF] Bit 7 (GP) General read/write bit. 4.1.5 R4 (RAM Select Register) Bits 0~5 are used to select the registers (address: 00~3F) in the indirect addressing mode. Bits 6~7 determine which bank is activated among the 4 banks. If no indirect addressing is used, the RSR is used as an 8-bit general-purposed read/writer register. See the configuration of the data memory in Fig. 4. 4.1.6 R5~R8 (Port 5 ~ Port8) Four general 8 bits I/O registers Both P74 and P76 read or write data from the DATA pin, while both P75 and P77 read or write data from the CLK pin. 6• Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM 4.1.7 R9 (Port9) A general 6-bit I/O register. The values of the two most significant bits are read as "0". 00 R0 01 R1 (TCC) 02 R2 (PC) STACK 0 03 R3 (Status) STACK 1 04 R4 (RSR) STACK 2 05 R5 (Port 5) STACK 3 IOC5 06 R6 (Port 6) STACK 4 IOC6 07 R7 (Port 7) IOC7 08 R8 (Port 8) IOC8 09 R9 (Port 9) IOC9 0A RA 0B RB 0C RC IOCC 0D RD IOCD 0E RE IOCE 0F RF IOCF 10 11 16x8 Common Register 1E 1F 00 01 10 11 20 21 31x8 Bank Register 31x8 Bank Register 31x8 Bank Register 31x8 Bank Register (Bank 0) (Bank 1) (Bank 2) (Bank 3) 3E 3F R3F Fig. 4 Data memory configuration Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) •7 EM78P451 8-Bit Microcontroller with OTP ROM 4.1.8 RA (SPIRB: SPI Read Buffer) Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 0X0A SPIRB/RA SRB7 SRB6 SRB5 SRB4 SRB3 SRB2 SRB1 SRB7~SRB0 are the 8-bit data when complete transmission by SPI. 4.1.9 RB (SPIWB: SPI Write Buffer) Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0x0B SPIWB/RB SWB7 SWB6 SWB5 SWB4 SWB3 SWB2 SWB1 SWB0 SWB7~SWB0 are the 8-bit data that are waiting for transmission by SPI. 4.1.10 RC (SPIS: SPI Status Segister) Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0x0C SPIS/RC -- -- -- TM1IF OD3 OD4 RBFIF RBF TM1IF (bit 4): 1 = In timer1 mode, receiving completed, and an interrupt occurs if enabled. 0 = In timer1 mode, receiving not completed yet, and an interrupt does not occur. OD3 (bit 3): Open-Drain Control bit 1 = Open-drain enable for SDO, 0 = Open-drain disable for SDO. OD4 (bit 2): Open-Drain Control bit 1 = Open-drain enable for SCK, 0 = Open-drain disable for SCK. RBFIF (bit 1):Read Buffer Full Interrupt Flag 1 = Receiving completed, SPIRB is fully exchanged, and an interrupt occurs if enabled. 0 = Receiving not completed yet; and SPIRB has not fully exchanged. RBF (bit 0): Read Buffer Full flag 1 = Receiving completed; SPIRB is fully exchanged. 0 = Receiving not completed yet, and SPIRB has not fully exchanged. 8• Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM 4.1.11 RD (SPIC: SPI Control Register) Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 0x0D SPIC/RD CES SPIE SRO SSE - Bit 2 Bit 1 Bit 0 SBRS2 SBRS1 SBRS0 CES (bit 7): Clock Edge Select bit 1 = Data shifts out on falling edge, and shifts in on rising edge. Data is on hold during the high level. 0 = Data shifts out on rising edge, and shifts in on falling edge. Data is on hold during the low level. SPIE (bit 6): SPI Enable bit 1= Enable SPI mode 0= Disable SPI mode SRO (bit 5): SPI Read Overflow bit 1 = A new data is received while the previous data is still being held in the SPIB register. In this situation, the data in SPIS register will be destroyed. To avoid setting this bit, users had better read SPIRB register even if only the transmission is implemented. 0 = No overflow. NOTE This can only occur in slave mode. SSE (bit 4): SPI Shift Enable bit 1 = Start to shift, and keep on 1 while the current byte is still being transmitted. 0 = Reset as soon as the shifting is complete, and the next byte is ready to shift. NOTE This bit will reset to 0 at every one-byte transmission by the hardware SBRS (bit 2~bit 0): SPI Baud Rate Select bits SPI baud rate table is illustrated in SPI section in later pages. 4.1.12 RE (TMR1: Timer1 register) Address 0X0E Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 TMR1/RE TMR17 TMR16 TMR15 TMR14 TMR13 TMR12 TMR11 TMR10 TMR17~TMR10 is bit set of timer1 register and it increases until the value matches PWP and then, it resets to 0. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) •9 EM78P451 8-Bit Microcontroller with OTP ROM 4.1.13 RF (PWP: Pulse width preset register) Address 0x0F Name Bit 7 PWP/RF PWP7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 PWP6 PWP5 PWP4 PWP3 PWP2 PWP1 PWP0 PWP7~PWP0 is bit set of pulse width preset in advance for the desired width of baud clock. 4.1.14 R20~R3E (General Purpose Register) RA~R1F, and R20~R3E (including Banks 0~3) are general-purpose registers. 4.1.15 R3F (Interrupt Status Register) Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0x3F ISR/R3F - - - - TM1IF SPIIF EXIF TCIF Bit 0 (TCIF) the flag of the TCC overflow interrupt. Set as TCC overflow; flag cleared by software. Bit 1 (EXIF) External interrupt flag. Set by falling edge on /INT pin, flag cleared by software Bit 2 (SPIIF) SPI interrupt flag. Set by data transmission complete, flag cleared by software. Bit 3 (TM1IF) Timer1 interrupt flag. Set by the comparator at Timer1 application, flag cleared by software. Bits 2~7 are not used and read as “0”. "1" means interrupt request, "0" means non-interrupt. R3F can be cleared by instruction, but cannot be set by instruction. IOCF is the interrupt mask register. Note that to read R3F will result to "logic AND" of R3F and IOCF. 4.2 Special Purpose Registers 4.2.1 A (Accumulator) Internal data transfer, or instruction operand holding. A non-addressable register. 4.2.2 CONT (Control Register) 7 6 5 4 3 2 1 0 /PHEN /INT - - PAB PSR2 PSR1 PSR0 Bit 7 (/PHEN) I/O pin pull-high enable flag. 0: For P60~P67, P74~P75 and P90~P95, the pull-high function is enabled. 1: The pull-high function is disabled. 10 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Bit 6 (INT) An interrupt enable flag cannot be written by the CONTW instruction. 0: interrupt masked by the DISI instruction. 1: interrupt enabled by the ENI or RETI instruction. Bit4, 5 Not used, and to be read as “0”. Bit 3 (PAB) Prescaler assignment bit. 0: TCC 1: WDT Bit 0 (PSR0) ~ Bit 2 (PSR2) TCC/WDT prescaler bits. PSR2 PSR1 PSR0 TCC Rate WDT Rate 0 0 0 1:2 1:1 0 0 1 1:4 1:2 0 1 0 1:8 1:4 0 1 1 1:16 1:8 1 0 0 1:32 1:16 1 0 1 1:64 1:32 1 1 0 1:128 1:64 1 1 1 1:256 1:128 Bits 0~3, and 7 of the CONT register are readable and writable. 4.2.3 IOC5 ~ IOC9 (I/O Port Control Register) "1" put the relative I/O pin into high impedance, while "0" put the relative I/O pin as output. Both P74 and P76 should not be defined as output pins at the same time. This also applies to both P75 and P77. Only the lower 6 bits of the IOC9 register are used. 4.2.4 IOCC (T1CON: Timer1 Control Register) Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 0x0C T1CON/IOCC 0 0 0 0 0 TM1E Bit 1 Bit 0 TM1P1 TM1P0 TM1E (bit2): Timer1 Function Enable bit 1 = Enable timer1 function. 0 = Disable timer1 function as default. TM1P (bit1~bit0): Timer1 Prescaler bit Timer1 prescaler table for FOSC will be illustrated in the Section on Timer1 in later pages. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 11 EM78P451 8-Bit Microcontroller with OTP ROM 4.2.5 IOCD (Pull-high Control Register) 7 6 5 4 3 2 1 0 S7 - - - /PU9 /PU8 /PU6 /PU5 The default values of /PU5, /PU6, /PU8, and /PU9 are one, which means the pull-high function is disabled. /PU6 and /PU9 are “AND” gating with /PHEN, that is, when each one is written as “0” pull high is enabled. S7 defines the driving ability of the P70-P72. 0: Normal output. 1: Enhance the driving ability of LED. 4.2.6 IOCE (WDT Control Register) 7 6 5 4 3 2 1 0 - ODE WDTE SLPC ROC - - /WUE Bit 0 (/WUE) Control bit used to enable the wake-up function of P60~P67, P74~P75, and P90~P91. 0: Enable the wake-up function. 1: Disable the wake-up function. The /WUE bit can be read and written. Bit 3 (ROC) ROC is used for the R-option. Setting ROC to "1" will enable the status of R-option pins (P80, P81) to be read by the controller. Clearing ROC will disable the R-option function. Otherwise, the R-option function is introduced. Users must connect the P81 pin or/and P80 pin to VSS by a 560KΩ external resistor (Rex). If Rex is connected/disconnected with VDD, the status of P80 (P81) will be read as "0"/"1" (refer to Fig. 7(b)). The ROC bit can be read and written. Bit 4 (SLPC) This bit is set by hardware at the falling edge of wake-up signal and is cleared in software. SLPC is used to control the oscillator operation. The oscillator is disabled (oscillator is stopped, and the controller enters the SLEEP2 mode) on the high-to-low transition and is enabled (the controller is awakened from SLEEP2 mode) on low-to-high transition. In order to ensure the stable output of the oscillator, once the oscillator is enabled again, there is a delay for approximately 18 ms (oscillator start-up timer (OST)) before the next program instruction is executed. The OST is always activated by wake-up from sleep mode whether the Code Option bit ENWDT is "0" or not. After waking up, the WDT is enabled if Code Option ENWDT is "1". The block diagram of SLEEP2 mode and wake-up caused by input triggered is depicted in Fig. 5. The SLPC bit can be read and written. 12 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Bit 5 (WDTE) Control bit used to enable Watchdog timer. The WDTE bit can be used only if ENWDT, the CODE Option bit, is "1". If the ENWDT bit is "1", then WDT can be disabled/enabled by the WDTE bit. 0: Disable WDT. 1: Enable WDT. The WDTE bit is not used if ENWDT, the CODE Option bit ENWDT, is "0". That is, if the ENWDT bit is "0", WDT is always disabled no matter what the WDTE bit is. The WDTE bit can be read and written. Bit 6 (ODE) Open-drain control bit. 0: Both P76 and P77 are normally I/O pins. 1: Both P76 and P77 pins have the open-drain function inside. The ODE bit can be read and written. Bits 1~2, and 7 Not used. 4.2.7 IOCF (Interrupt Mask Register) 7 6 5 4 3 2 1 0 - - - - TM1IE SPIIE EXIE TCIE Bit 0 (TCIE) TCIF interrupt enable bit. 0: disable TCIF interrupt 1: enable TCIF interrupt Bit 1 (EXIE) EXIF interrupt enable bit. 0: disable EXIF interrupt 1: enable EXIF interrupt Bit 2 (SPIIE) SPI interrupt enable bit. 0: disable SPI interrupt 1: enable SPI interrupt Bit 3 (TM1IE) TM1IE interrupt enable bit. 0: disable TM1IE interrupt 1: enable TM1IE interrupt Bits 4~7 Not used. Individual interrupt is enabled by setting its associated control bit in IOCF to "1". The IOCF Register could be read and written. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 13 EM78P451 8-Bit Microcontroller with OTP ROM /WUE Oscillator Enable Disable /WUE Reset Q Q Clear P D R CLK C L VCC Set 8 /WUE from S/W P60~P67 VCC /WUE /PHEN 4 P74~P75, P90~P91 Fig. 5 Block Diagram of Sleep Mode and Wake-up Circuits on I/O Ports 4.3 TCC/WDT Presacler An 8-bit counter is available as prescaler for the TCC or WDT. The prescaler is available for either the TCC or WDT only at any given time, and the PAB bit of CONT register is used to determine the prescaler assignment. The PSR0~PSR2 bits determine the prescale ratio. The prescaler is cleared each time the instruction is written to TCC under TCC mode. The WDT and prescaler, when assigned to WDT mode, are cleared by the WDTC or SLEP instructions. Fig. 6 depicts the circuit diagram of TCC/WDT. R1(TCC) is an 8-bit timer/counter. TCC will increase by one at every instruction cycle (without prescaler). The watchdog timer is a free running on-chip RC oscillator. The WDT will keep running even when the oscillator driver has been turned off (i.e. in sleep mode). During normal 14 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM operation or sleep mode, a WDT time-out (if enabled) will cause the device to reset. The WDT can be enabled or disabled any time during the normal mode by software programming (if Code Option bit ENWDT is "1"). Refer to WDTE bit of IOCE register. Without presacler, the WDT time-out period is approximately 18 ms1. 4.4 I/O Ports The I/O registers, from Port 5 to Port 9, are bi-directional tri-state I/O ports. P60~P67, P74~P75, and P90~P91 provide internal pull-high. P60~P67, P74~P75, and P90~P95 provide programmable wake-up function through software. P76~P77 can have open-drain output by software control. P80~P81 are the R-option pins which are enabled by software. When the R-option function is used, it is recommended that P80 and P81 are used as output pins. During R-option enabled state, P80 and P81 must be programmed as input pins. If an external resistor is connected to P80 (P81) for the R-option function, the current consumption should be taken as an important factor in the applications for low power consideration. The I/O ports can be defined as "input" or "output" pins by the I/O control registers (IOC5~IOC9) under program control. The I/O registers and I/O control registers are both readable and writable. The I/O interface circuit is shown in Fig. 7. Note that the reading path source of input and output pins is different when reading the I/O port. Data Bus CLK(=Fosc/2) 1 M U X SYNC TCC(R1) 2 cycles 0 TCC overflow interrupt PAB 0 W DT 1 M U X 8- bit Counter PSR0~PSR2 8 - to - 1 MUX 0 W DTE 1 MUX PAB (in IOCE) W DT tim eout Fig. 6 Block Diagram of TCC WDT 1 NOTE: Vdd = 5V, set up time period = 16.2ms ± 5% Vdd = 3V, set up time period = 18.0ms ± 5% Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 15 EM78P451 8-Bit Microcontroller with OTP ROM PCRD Q PORT 0 1 P R D CLK Q C L Q P R Q C CLK L PCW R IOD D PDW R M U X PDRD Fig. 7 (a) The Circuit of I/O Port and I/O Control Register PCRD VCC ROC P D R CLK Q C L Q Weakly Pull-up P R D C CLK Q L PCWR IOD Q PORT 0 Rex* 1 M U X PDWR PDRD *The Rex is 560K ohm external resistor Fig.7(b) The Circuit of I/O Port with R-option (P80, P81) 16 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM 4.5 SERIAL PERIPHERAL INTERFACE MODE 4.5.1 Overview & Features 4.5.1.1 Overview Figures 8, 9, and 10 show how EM78P451 communicates with other devices through SPI module. If EM78P451 is a master controller, it sends clock through the SCK pin. A couple of 8-bit data are transmitted and received at the same time. However, if EM78P451is defined as a slave, its SCK pin could be programmed as an input pin. Data will continue to be shifted based on both the clock rate and the selected edge. 4.5.1.2 Features Operation in either Master mode or Slave mode, Three-wire or four-wire synchronous communication; that is, full duplex Programmable baud rates of communication, Programming clock polarity, (RD bit7) Interrupt flag available for the read buffer full, Up to 8 MHz ( maximum ) bit frequency, SDO SPIR Reg SPIW SPIW Reg Reg /SS SPIS Reg SDI SPI Module Bit 7 Master Device SCK Slave Device Fig. 8 SPI Master/Slave Communication Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 17 EM78P451 8-Bit Microcontroller with OTP ROM SDI SDO SCK /SS Vdd Master P50 P51 P52 P53 SDO SDI SCK /SS SDO SDI SCK /SS SDO SDI SCK /SS SDO SDI SCK /SS Slave Device 1 Slave Device 2 Slave Device 3 Slave Device 4 Fig. 9 The SPI Configuration of Single-Master and Multi-Slave SDI SDO SCK /SS SDI SDO SCK /SS Master1 or P50 Slave1 P51 Master2 or P50 P51 Slave6 P52 P53 Slave 4 for Master1/2 SDO SDI SCK /SS Slave 3 for Master 1/2 SDO SDI SCK /SS SDO SDI SCK /SS SDO SDI SCK /SS Slave 2 for m aster 1 P52 P53 Slave 5 for Master 2 Fig. 10 The SPI Configuration of Single-Master and Multi-Slave 18 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM 4.5.2 SPI Function Description Read RBF RBFI Write SPIR SE reg SPIW reg Set to 1 Buffer Full Detector SPIS P92/SDI shift right reg bit 0 bit 7 SPIC reg P93/SDO Edge Select SBR0 ~SBR2 P95/ /SS SBR2~SBR0 8 / SS Prescaler 4, 8, 16, 32, 64 Tsco Noise Filter Clock Select 2 Edge Select P94/SCK TMR1/2 SPIC bit6 Fig. 11 SPI Block Diagram SPI SDI Shift Clock SPI Read Register (0X0A) 7~0 SPIWB /SS SPI Write Register (0X0B) 8-1 MUX SPI Mode Select Register 2 1 0 SPIC SDO SPI Shift Buffer FOSC 1 0 7 6 4 1 0 T1CON SPIC SPIS 2 4 INTC SPIC 7~0 SPIRB DATA BUS Fig. 12 The Function Block Diagram of SPI Transmission The following describes the function of each block and explains how to carry out the SPI communication with the signals depicted in Fig.11 and Fig.12: Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 19 EM78P451 8-Bit Microcontroller with OTP ROM P92/SDI: Serial Data In. P93/SDO: Serial Data Out. P94/SCK: Serial Clock. P95//SS: /Slave Select (Option). This pin (/SS) may be required during a slave mode. RBF: Set by Buffer Full Detector, and reset in software. RBIF: Set by Buffer Full Detector, and reset in software. Buffer Full Detector: Sets to 1 when an 8-bit shifting is completed. SSE: Loads the data in SPIS register, and begin to shift SPIS reg.: Shifting byte in and out. The MSB is shifted first. Both the SPIS register and the SPIW register are loaded at the same time. Once data are written, SPIS starts transmission / reception. The received data will be moved to the SPIR register as the shifting of the 8-bit data is completed. The RBF (Read Buffer Full) flag and the RBFI(Read Buffer Full Interrupt) flag are then set. SPIR reg.: Read buffer. The buffer will be updated as the 8-bit shifting is completed. The data must be read before the next reception is completed. The RBF flag is cleared as the SPIR register reads. SPIW reg.: Write buffer. The buffer will deny any attempt to write until the 8-bit shifting is completed. The SSE bit will be kept in 1 if the communication is still undergoing. This flag must be cleared as the shifting is completed. Users can determine if the next write attempt is available. SBRS2~SBRS0: Programming the clock frequency/rates and sources. Clock Select: Selecting either the internal or external clock as the shifting clock. Edge Select: Selecting the appropriate clock edges by programming the CES bit 4.5.3 SPI Signal & Pin Description The detailed functions of the four pins, SDI, SDO, SCK, and /SS, which are shown in Fig. 9, are as follows: SDI/P92 (Pin 7): Serial Data In, Receive serially, the Most Significant Bit (MSB) first, Least Significant Bit (LSB) last, Defined as high-impedance, if not selected, 20 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Program the same clock rate and clock edge to latch on both the master and slave devices, The received byte will update the transmitted byte, Both the RBF and RBFIF bits (located in Register 0x0C) will be set as the SPI operation is completed. Timing is shown in Fig.13 and14. SDO/P93 (Pin 8): Serial Data Out, Transmit serially; the Most Significant Bit (MSB) first, Least Significant Bit (LSB) last, Program the same clock rate and clock edge to latch on both the master and slave devices, The received byte will update the transmitted byte, The CES (located in Register 0x0D) bit will be reset, as the SPI operation is completed. Timing is shown in Fig.13 and 14. SCK/P94 (Pin 9): Serial Clock Generated by a master device Synchronize the data communication on both the SDI and SDO pins The CES (located in Register 0x0D) is used to select the edge to communicate. The SBR0~SBR2 (located in Register 0x0D) is used to determine the baud rate of communication The CES, SBR0, SBR1, and SBR2 bits have no effect in the slave mode Timing is show in Fig.13 and 14 /SS/P95 (Pin 10): Slave Select; negative logic, Generated by a master device to signify the slave(s) to receive data, Goes low before the first cycle of SCK appears, and remains low until the last (eighth) cycle is completed, Ignores the data on the SDI and SDO pins while /SS is high, because the SDO is no longer driven. Timing is shown in Fig.13 and Fig. 14. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 21 EM78P451 8-Bit Microcontroller with OTP ROM 4.5.4 Programmed the Related Registers As the SPI mode is defined, the related registers of this operation are shown in Table 2 and Table 3. Table 2 Related Control Registers of the SPI Mode Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0x0D *SPIC/RD CES SPIE SRO SSE -- SBR2 SBR1 SBR0 0x0F INTC/IOCF -- -- -- -- TM1IE SPIIE EXIE TCIE SPIC: SPI Control Register. CES (bit 7): Clock Edge Select bit 1 = Data shifts out on falling edge, and shifts in on rising edge. Data is on hold during the high level. 0 = Data shifts out on rising edge, and shifts in on falling edge. Data is on hold during the low level. SPIE (bit 6):SPI Enable bit 1 = Enable SPI mode 0 = Disable SPI mode SRO (bit 5): SPI Read Overflow bit 1 = A new data is received while the previous data is still being on hold in the SPIB register. Under this condition, the data in SPIS register will be destroyed. To avoid setting this bit, users should read the SPIRB register even if the transmission is implemented only. 0 = No overflow. NOTE This can only occur under slave mode. SSE (bit 4): SPI Shift Enable bit 1 = Start to shift, and stays on 1 while the current byte continues to transmit. 0 = Reset as soon as the shifting is completed and the next byte is ready to shift. NOTE This bit can be reset by hardware only. 22 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM SBRS (bit 2~0): SPI Baud Rate Select Bits SBRS2 (Bit 2) SBRS1 (Bit 1) SBRS0 (Bit 0) 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1 Mode Baud Rate Master Master Master Master Master Slave Slave Master Fsco/2 Fsco/4 Fsco/8 Fsco/16 Fsco/32 /SS enable /SS disable TMR1/2 NOTE In master mode, /SS is disable. INTC: Interrupt control register Bit 3 (TM1IE) TM1IE interrupt enable bit. 0: disable TM1IE interrupt 1: enable TM1IE interrupt Bit 2 (SPIIE) SPI interrupt enable bit. 0: disable SPI interrupt 1: enable SPI interrupt Bit 1 (EXIE) EXIF interrupt enable bit. 0: disable EXIF interrupt 1: enable EXIF interrupt Bit 0 (TCIE) TCIF interrupt enable bit. 0: disable TCIF interrupt 1: enable TCIF interrupt Table 3 Related Status/Data Registers of the SPI Mode Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0X0A SPIRB/RA SRB7 SRB6 SRB5 SRB4 SRB3 SRB2 SRB1 SRB0 0x0B SPIWB/RB SWB7 SWB6 SWB5 SWB4 SWB3 SWB2 SWB1 SWB0 0 0 TM1IF OD3 OD4 RBFIF RBF 0x0C Name SPIS/RC 0 SPIRB: SPI Read Buffer. Once the serial data is received completely, it will load to SPIRB from SPISR. The RBF bit and the RBFIF bit in the SPIS register will be set also. SPIWB: SPI Write Buffer. As a transmitted data is loaded, the SPIS register stands by and start to shift the data when sensing SCK edge with SSE set to “1”. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 23 EM78P451 8-Bit Microcontroller with OTP ROM SPIS: SPI Status register TM1IF (bit 4): Timer1 interrupt flag. OD3 (bit 3): Open-Drain Control bit (P93) 1 = Open-drain enable for SDO, 0 = Open-drain disable for SDO. OD4 (bit 2): Open Drain-Control bit (P94) 1 = Open-drain enable for SCK, 0 = Open-drain disable for SCK. RBFIF (bit 1): Read Buffer Full Interrupt flag 1 = Receive is completed, SPIB is full, and an interrupt occurs if enabled. 0 = Receive is ongoing, SPIB is empty. RBF (bit 0): Read Buffer Full flag 1 = Receive is completed, SPIB is full. 0 = Receive is ongoingt, SPIB is empty. 4.5.5 SPI Mode Timing The edge of SCK is selected by programming bit CES. The waveform shown in Fig.13 is applicable regardless of whether the EM78P451 is under master or slave mode with /SS disabled. However, The waveform in Fig. 14 can only be implemented in slave mode with /SS enabled. Fig. 13 SPI Mode with /SS Disable 24 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Fig. 14 SPI Mode with /SS Enable 4.5.6 Software Application of SPI Example for SPI: For Master ORG 0X0 SETTING: CLRA IOW 0X05 ;Set Port5 output IOW 0X06 ;Set Port6 output MOV 0X05,A MOV A,@0B11001111 ;Set prescaler for WDT CONTW MOV A,@0B00010001 ;Disable wakeup function IOW 0X0E MOV A,@0B00000000 ;Disable interrupt IOW 0X0F MOV A,@0x07 ;SDI input and SDO, SCK output IOW 0x09 MOV A,@0B10000000 ;Clear RBF and RBFIF flag MOV 0x0C,A MOV A,@0B11100000 ;Select clock edge and enable SPI MOV 0X0D,A START: Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 25 EM78P451 8-Bit Microcontroller with OTP ROM WDTC BC 0X0C,1 ;Clear RBFIF flag MOV A,@0XFF MOV 0X05,A ;Show a signal at Port5 MOV 0X0A,A ;Move FF at read buffer MOV A,@0XAA ;Move AA at write buffer MOV 0X0B,A BS 0X0D,4 ;Start to shift SPI data NOP JBC 0X0D,4 ;Polling loop for checking SPI transmission completed JMP $-2 BC 0X03,2 CALL DELAY ;To catch the data from slaver MOV A,0X0A XOR A,@0X5A ;Compare the data from slaver JBS 0X03,2 JMP START FLAG: MOV A,@0X55 ;Show the signal when receiving correct data from slaver MOV 0X05,A CALL DELAY JMP START DELAY: ;(user’s program) EOP ORG 0XFFF JMP SETTING 26 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM For Slaver ORG 0X0 INITI: JMP INIT ORG 0X2 INTERRUPT: ;Interrupt address MOV A,@0X55 MOV 0X06,A ;Show a signal at Port 6 when entering interrupt MOV A,@0B11100110 ;Enable SPI, /SS disabled MOV 0X0D,A BS 0X0D,4 ;Keep SSE at 1 to wait for SCK signal in order to shift data MOV A,@0X00 ;Move 00 to write buffer in order to keep master’s read buffer as 00 MOV 0X0B,A BS 0X0D,4 ;Keep SSE at 1 to wait for SCK signal in order to shift data NOP JBC 0X0D,4 ;Polling loop for checking SPI transmission completed JMP $-2 BS 0X0D,4 BC ;Keep SSE at 1 to wait for SCK signal in order to shift data 0X03,2 MOV A,0X0A MOV 0X06,A ;Read master’s data from read buffer XOR A,@0XAA ;Check pass signal from read buffer JBS 0X03,2 JMP $-6 JMP SPI ORG 0X30 INIT: CLRA IOW 0X05 IOW 0X06 MOV 0x05,A Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 27 EM78P451 8-Bit Microcontroller with OTP ROM MOV 0X06,A MOV A,@0XFF IOW 0X08 MOV A,@0B11001111 ;Set prescaler for WDT CONTW MOV A,@0B00010001 ;Disable wakeup function IOW 0X0E MOV A,@0B00000010 ;Enable external interrupt IOW 0XF ENI MOV A,@0B00110111 IOW 0x09 BC 0X3F,1 ;Clear RBFIF flag NOP JBS 0X3F,1 ;Polling loop for checking interrupt occurence JMP $-2 JMP INTERRUPT SPI: BS 0X0D,4 ;Keep SSE enabled as long as possible WDTC MOV A,@0X0F ;Show a signal when entering SPI loop MOV 0X06,A JBC 0X08,1 ;Choose P81 as a signal button JMP SPI MOV A,@0X5A ;Move 5A into write buffer when P81 button is pushed MOV 0X0B,A NOP JBC 0X0D,4 ;Polling loop for checking SPI transmission completed JMP $-2 BS 0XD,4 NOP NOP MOV A,@0XF0 ;Display at Port6 when P81 button is pushed MOV 0X06,A 28 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM MOV A,@0X00 ;Send a signal to master to prevent infinite loop MOV 0X0B,A NOP JBC 0X0D,4 JMP $-2 BS 0X0D,4 BS 0x0C,7 BC 0x0C,1 NOP JMP SPI DELAY: ;(user’s program) EOP ORG 0XFFF JMP INITI 4.6 Timer 1 4.6.1 Overview Timer1(TMR1) is an eight-bit clock counter with a programmable prescaler. It is designed for the SPI module as a baud rate clock generator. TMR1 can be read and written and cleared on any reset conditions. If employed, it can be turned down for power saving by setting TMR1EN bit [T1CON<2>] to 0. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 29 EM78P451 8-Bit Microcontroller with OTP ROM 4.6.2 Function Description Fig. 15 shows TIMER1 block diagram. Each signal and block is described as follows: Fig. 15 TIMER1 Block Diagram OSC/4: Input clock. Prescaler: Option of 1:1, 1:4, 1:8, and 1:16 defined by T1P1 and T1P02 (T1CON<1, 0>). It is cleared when a value is written to TMR1 or T1CON, and during any kind of reset as well. PWP: Pulse width preset register. The desired width of baud clock is written in advance. TMR1: Timer 1 register. TMR1 increases until it matches with PWP, and then resets to 0. If it is chosen optionally in the SPI mode, its output is fed as a shifting clock. Comparator: To change the output status while a match occurs. The TMR1IF flag will be set at the same time. 4.6.3 Programmed the Related Registers The related registers of the defining TMR1 operation are shown in Table 4 and Table 5 Table 4 Related Control Registers of the TMR1 30 • Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0x0C SPIS/RC 0 0 0 TM1IF OD3 OD4 RBFIF RBF 0x0F INTC/IOCF 0 0 0 0 TM1IE SPIIE EXIE TCIE Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Table 5 Related Status/Data Registers ofTMR1 Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0X0E TMR1/RE TMR17 TMR16 TMR15 TMR14 TMR13 TMR12 TMR11 TMR10 0x0F PWP/RF PWP7 PWP6 PWP5 PWP4 PWP3 PWP2 PWP1 0x0C T1CON/IOCC 0 0 0 0 0 TM1E TM1P1 TM1P0 TMR1: PWP0 Timer1 Register TMR17~TMR10 is bit set of Timer1 register and it increases until the value matches PWP and then it reset to 0. PWP: Pulse Width Preset Register PWP7~PWP0 is bit set of pulse width preset for the desired width of baud clock in advance. T1CON: Timer1 Control Register TM1E (bit2): Timer1 enable bit TM1P1 and TM1P0 (bit1~0): Timer1 prescaler for FSCO TM1P1 TM1P0 Prescaler Rate 0 0 1 1 0 1 0 1 1:1 1:4 1:8 1:16 4.7 RESET and Wake-up A RESET is initiated by (1) Power on reset, or (2) WDT timeout. (if enabled) VDD D Oscillator Q CLK CLK CLR Pow eron Reset Voltage Detector W DTE W DT tim eout W DT Setup Tim e Reset Fig. 16 Block Diagram of Reset Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 31 EM78P451 8-Bit Microcontroller with OTP ROM EM78P451 POR voltage range is 1.2V~1.8V. Under customer application, when power is OFF, Vdd must drop to below 1.2V and remains OFF for 10us before power can be switched ON again. This way, the EM78P451 will reset and work normally. The extra external reset circuit will work well if Vdd can rise at very fast speed (50 ms or less). However, under most cases where critical applications are involved, extra devices are required to assist in solving the power-up problem. The device is kept in a RESET condition for a period of approx. 18ms2 (one oscillator start-up timer period) after the reset is detected and Fig.16 is the block diagram of reset. Once the RESET occurs, the following functions are performed. The oscillator is running, or will be started. The Program Counter (R2) is set to all "1". When power is switched on, bits 5~6 of R3 and the upper 2 bits of R4 are cleared. All I/O port pins are configured as input mode (high-impedance state). The Watchdog timer and prescaler are cleared. The Watchdog timer is enabled if Code Option bit ENWDT is "1". The CONT register is set to all "1" except bit 6 (INT flag). Bits 3,6 of IOCE register are cleared, bits 0,4~5 of IOCE register are set to "1". Bits 0 of R3F and bits 0 of IOCF registers are cleared. The sleep mode (power down) is achieved by executing the SLEP instruction (named as SLEEP1 MODE). While entering sleep mode, the WDT (if enabled) is cleared but keeps on running. The controller is awakened by WDT timeout (if enabled), and it will cause the controller to reset. The T and P flags of R3 are used to determine the source of the reset (wake-up). In addition to the basic SLEEP1 MODE, EM78P451 has another sleep mode (caused by clearing "SLPC" bit of IOCE register, designated as SLEEP2 MODE). In the SLEEP2 MODE, the controller can be awakened by(a) Any one of the wake-up pins is set to “0.” (refer to Fig.17). Upon waking, the controller will continue to execute the program in-line. In this case, before entering SLEEP2 MODE, the wake-up function of the trigger sources (P60~P67, P74~P75, and P90~P91)should be selected (e.g. input pin) and enabled (e.g. pull-high, wake-up control). One caution should be noted is that after waking up, the WDT is enabled if Code Option bit ENWDT is "1". The WDT operation (to be enabled or disabled) should be appropriately controlled by software after waking up. (b) WDT time-out (if enabled). On wake-up, will cause the controller reset. 2 32 • NOTE: Vdd = 5V, set up time period = 16.2ms ± 5% Vdd = 3V, set up time period = 18.0ms ± 5% Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Table 6 The Summary of the Initialized Values for Registers Address Name N/A IOC5 N/A N/A N/A N/A N/A 0x00 0x01 0x02 0x03 IOC6 IOC7 IOC8 IOC9 CONT R0(IAR) R1(TCC) R2(PC) R3(SR) Reset Type Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Bit Name Power-On /RESET and WDT Wake-Up from Pin Change C57 1 1 C56 1 1 C55 1 1 C54 1 1 C53 1 1 C52 1 1 C51 1 1 C50 1 1 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change C67 1 1 C66 1 1 C65 1 1 C64 1 1 C63 1 1 C62 1 1 C61 1 1 C60 1 1 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change C77 1 1 C76 1 1 C75 1 1 C74 1 1 C73 1 1 C72 1 1 C71 1 1 C70 1 1 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change C87 1 1 C86 1 1 C85 1 1 C84 1 1 C83 1 1 C82 1 1 C81 1 1 C80 1 1 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change C97 1 1 C96 1 1 C95 1 1 C94 1 1 C93 1 1 C92 1 1 C91 1 1 C90 1 1 P P P P P P P P 1 1 1 1 PAB 1 1 Bit Name Power-On /RESET and WDT Wake-Up from Pin Change /PHEN /INT 1 0 1 P PSR2 PSR1 PSR0 1 1 1 1 1 1 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change U P U P U P U P U P U P U P U P P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 P P P P P P P P 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 **P **P **P **P **P **P **P **P GP 0 0 PS1 0 0 PS0 0 0 T t t P t t Z U P DC U P C U P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change Bit Name Power-On /RESET and WDT Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 33 EM78P451 8-Bit Microcontroller with OTP ROM Address Name Reset Type Wake-Up from Pin Change 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B R4(RSR) R5(P5) R6(P6) R7(P7) R8(P8) R9(P9) RA(SPIRB) RB(SPIWB) Bit Name Power-On /RESET and WDT Wake-Up from Pin Change RC(SPIS) Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 P P P t t P P P U P U P U P U P U P U P RSR.1 RSR.0 0 0 0 0 P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change P57 U P P56 U P P55 U P P54 U P P53 U P P52 U P P51 U P P50 U P P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change P67 U P P66 U P P65 U P P64 U P P63 U P P62 U P P61 U P P60 U P P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change P77 U P P76 U P P75 U P P74 U P P73 U P P72 U P P71 U P P70 U P P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change P87 U P P86 U P P85 U P P84 U P P83 U P P82 U P P81 U P P80 U P P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change P97 U P P96 U P P95 U P P94 U P P93 U P P92 U P P91 U P P90 U P P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change SRB7 SRB6 SRB5 SRB4 SRB3 SRB2 SRB1 SRB0 U U U U U U U U P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change SWB7 SWB6 SWB5 SWB4 SWB3 SWB2 SWB1 SWB0 U U U U U U U U P P P P P P P P Power-On /RESET and WDT Wake-Up from Pin Change Bit Name 34 • Bit 6 P Bit Name 0x0C Bit 7 P P P P P P ENSD OBDC IBDC O 0 0 0 0 0 0 P P CES SPIE P P P P P TIIF OD3 0 0 0 0 0 0 0 0 0 0 P P P P P - P P P SRO SPISE P P P OD4 RBFIF RBF SBRS SBRS SBRS Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Address Name 0x0D RD(SPIC) Reset Type 0x0F 0x3F 0x0C 0x0D 0x0E 0x0F 0x10~0x3 E RE(TMR1) RF(PWP) R3F(ISR) IOCC IOCD IOCE IOCF GPR Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0 0 0 0 0 0 0 0 0 0 2 0 0 1 0 0 0 0 0 P P P P P P P P Power-On /RESET and WDT Wake-Up from Pin Change Bit Name 0x0E Bit 7 Power-On /RESET and WDT Wake-Up from Pin Change Bit Name Power-On /RESET and WDT Wake-Up from Pin Change TMR1 TMR1 TMR1 TMR1 TMR1 TMR1 TMR1 TMR1 7 6 5 4 3 2 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 P P P P P P P P PWP7 PWP6 PWP5 PWP4 PWP3 PWP2 PWP1 PWP0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change U U U U U U U U T1IF 0 0 SPIIF 0 0 EXIF 0 0 TCIF 0 0 U U U U P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change 0 0 0 0 0 0 0 0 0 0 T1E 0 0 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change S7 1 1 1 1 1 1 1 1 /PU9 1 1 /PU8 1 1 /PU6 1 1 /PU5 1 1 P P P P P P P P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change U U ODE 0 0 U U U U /WUE 1 1 U P 1 1 P U U P Bit Name Power-On /RESET and WDT Wake-Up from Pin Change U U U U U U U U T1IE 0 0 U U U U P P P P Bit Name - - - - - - - - Power-On U U U U U U U U /RESET and WDT Wake-Up from Pin Change P P P P P P P P P P P P P P P P WTE SLPC ROC 1 1 0 1 1 0 T1P1 T1P0 0 0 0 0 SPIIE EXIE 0 0 0 0 TCIE 0 0 ** To execute the next instruction after the ”SLPC” bit status of IOCE register being on high-to-low transition. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 35 EM78P451 8-Bit Microcontroller with OTP ROM X: Not used. U: Unknown or don’t care. P: Previous value before reset. t : Check Table 7 4.7.1 The Status of RST, T, and P of STATUS Register A RESET condition is initiated by the following events: 1. A power-on condition, 2. Watchdog timer time-out. The values of T and P, listed in Table 7 are used to check how the processor wakes up. Table 8 shows the events that may affect the status of T and P. Table 7 The Values of RST, T and P After RESET Reset Type T P Power on WDT during Operating mode 1 0 1 P WDT wake-up during SLEEP1 mode 0 0 WDT wake-up during SLEEP2 mode 0 P Wake-Up on pin change during SLEEP2 mode P P * P: Previous value before reset Table 8 The Status of RST, T and P Being Affected by Events Event T P Power on 1 1 WDTC instruction 1 1 WDT time-out SLEP instruction 0 1 *P Wake-Up on pin change during SLEEP2 mode P P 0 * P: Previous value before reset 4.8 Interrupt The EM78P451 has the following interrupts. 1. /TCC overflow interrupt 2. External interrupt (/INT) 3. Serial Peripheral Interface (SPI) transmission completed interrupt. 4. Timer1 comparator completed interrupt. R3F is the interrupt status register, which records the interrupt request in flag bit. IOCF is the interrupt mask register. Global interrupt is enabled by ENI instruction and is disabled by DISI instruction. When one of the interrupts (if enabled) is generated, will cause the next instruction to be fetched from address 001H. Once in the interrupt service routine the source of the interrupt can be determined by polling the flag bits in 36 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM the R3F register. The interrupt flag bit must be cleared by software before leaving the interrupt service routine and enabling interrupts to avoid recursive interrupts. The flag in the Interrupt Status Register (R3F) is set regardless of the status of its mask bit or the execution of ENI instruction. Note that reading R3F will obtain the output of logic AND of R3F and IOCF (refer to Fig. 17). The RETI instruction exits interrupt routine and enables the global interrupt (execution of ENI instruction). When an interrupt is generated by INT instruction (if enabled), it causes the next instruction to be fetched from address 002H. IRQn P Q R C CLK L Q D /IRQn interrupt IRQm RFRD R3F ENI/DISI P D R C CLK Q L IOD Q IOCFW R IOCF RESET IOCF RD RFW R Fig. 17 Interrupt Input Circuit 4.9 Oscillator 4.9.1 Oscillator Modes The EM78P451 can operate in four different oscillator modes. There are high XTAL (HXT) oscillator mode, low XTAL (LXT) oscillator mode, External RC oscillator mode (ERC), and Internal C、External R oscillator modes. User can select one of them by programming MS, RCT, HLF and HLP in the Code Option Register. Table 9 depicts how these three modes are defined. Table 9 Oscillator Modes by MS, IRC, RCT. Mode High XTAL Oscillator Low XTAL Oscillator External RC Oscillator External R and Internal C Oscillator MS RCT HLF HLP 1 1 0 0 X X 1 0 1 0 X X X 0 X X NOTE X: Don’t care Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 37 EM78P451 8-Bit Microcontroller with OTP ROM 4.9.2 Crystal Oscillator/Ceramic Resonators (XTAL) EM78P451 can be driven by an external clock signal through the OSCI pin as shown in Fig 18 below. In the most applications, pin OSCI and pin OSCO is connected with a crystal or ceramic resonator to generate oscillation. Fig 19 depicts such circuit. Table 10 provides the recommended values of C1 and C2. Since each resonator has its own attribute, user should refer to its specification for appropriate values of C1 and C2. RS, a serial resistor may be necessary for AT strip cut crystal or low frequency mode. Ext. Clock OSCI OSCO EM 78P451 Fig. 18 Circuit for External Clock Input C1 OSCI EM 78P451 XTAL OSCO RS C2 Fig. 19 Circuit for Crystal/Resonator Table 10 Capacitor Selection Guide for Crystal Oscillator Ceramic Resonators Oscillator Type Ceramic Resonator Frequency Mode HXT LXT Crystal Oscillator HXT 38 • Frequency C1 (pF) C2 (pF) 455 KHz 1.0 MHz 2.0 MHz 4.0 MHz 32.768 KHz 100 KHz 200 KHz 455 KHz 1.0 MHz 2.0 MHz 4.0 MHz 10~150 40~80 20~40 10~30 25 25 25 20~40 15~30 15 15 10~150 40~80 20~40 10~30 15 25 25 20~150 15~30 15 15 Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM 330 330 C OSCI 7404 7404 7404 EM 78P451 XTAL Fig. 20 Circuit for Crystal/Resonator-Series Mode 4.7K 10K VDD O SCI EM 78P451 7404 7404 10K XTAL C1 C2 Fig. 21 Circuit for Crystal/Resonator-Parallel Mode 4.9.3 RC Oscillator Mode For some applications that do not need a very precise timing calculation, the RC oscillator (Fig 22 & Fig 23) offers a lot of cost savings. Nevertheless, it should be noted that the frequency of the RC oscillator is influenced by the supply voltage, the values of the resistor (Rext), the capacitor (Cext), and even by the operation temperature. Moreover, the frequency also changes slightly from one chip to another due to the manufacturing process variation. In order to maintain a stable system frequency, the values of the Cext should not be less than 20pF, and that the value of Rext should not be greater than 1 M ohm. If they cannot be kept in this range, the frequency is easily affected by noise, humidity, and leakage. The smaller the Rext in the RC oscillator, the faster its frequency will be. On the contrary, for very low Rext values, for instance, 1 KΩ, the oscillator becomes unstable because the NMOS cannot discharge the current of the capacitance correctly. Based on the reasons above, it must be kept in mind that all of the supply voltage, the operation temperature, the components of the RC oscillator, the package types, the way the PCB is layout, will affect the system frequency. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 39 EM78P451 8-Bit Microcontroller with OTP ROM VCC Rext OSCI EM 78P451 Cext Fig. 22 Circuit for External RC Oscillator Mode VCC Rext OSCI EM 78P451 Fig. 23 Circuit for External R, Internal C Oscillator Mode Calibrate frequency of External RC oscillator (For reference only) C ext 20pF 100pF 300pF 40 • R ext Fosc @5.0V,25℃ 3.3K 3.4MHz 5.1K 2.2MHz 10K 1.3MHz 100K 144KHz 3.3K 1.39MHz 5.1K 935KHz 10K 500KHz 100K 54.5KHz 3.3K 740KHz 5.1K 490KHz 10K 255KHz 100K 28KHz Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Internal C, external R Table (For reference only) External R (Ohm) Fosc @5.0V, 25℃ (Hz) 10K 15K 20K 30K 51K 100K 150K 200K 510K 2M 3.3M 12M 7.7M 5.7M 3.65M 2.24M 1.14M 749K 559K 214K 56K 32.8K 4.10 Code Option Register Address 12 0xFFF 11 10 9 MS ENWDT CLKS PTB 8 7 6 HLF RCT HLP 5 4 DEL0 DEL1 3 2 1 0 ID3 ID2 ID1 ID0 Bit 12 (MS): Oscillator type selection. 0: RC type 1: XTAL type Bit 11 (ENWDT): Watchdog Timer enabled. 0: Enable 1: Disable Bit 10 (CLKS): Clocks of each instruction cycle. 0: Two clocks 1: Four clocks Bit 9 (PTB): Protect bit. 0: Protect enabled 1: Protect disabled Bit 8 (HLF): XTAL frequency selection. 0: Low frequency (32.768KHz) 1: High frequency This bit is useful only when Bit 12 (MS) is 1. When MS is 0, HLF must be 0. Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 41 EM78P451 8-Bit Microcontroller with OTP ROM Bit 7 (RCT): Resistor Capacitor. 0: internal RC 1: external RC Bit 6 (HLP): Power consumption selection. 0: Low power 1: High power Bit 5 ~ Bit 4: DEL1 and DEL0 (SDI) input delay time options. DEL 1 DEL 0 Delay time 1 0 1 1 1 0 0 ns 50 ns 100 ns Bit3~0 (ID): User’s ID code. 4.11 Instruction Set Each instruction in the instruction set is a 13-bit word divided into an OP code and one or more operands. All instructions are executed within one single instruction cycle (consisting of 2 oscillator periods), unless the program counter is changed by(a) Executing the instruction "MOV R2,A", "ADD R2,A", "TBL", or any other instructions that write to R2 (e.g. "SUB R2,A", "BS R2,6", "CLR R2", ⋅⋅⋅⋅). (b) execute CALL, RET, RETI, RETL, JMP, Conditional skip (JBS, JBC, JZ, JZA, DJZ, DJZA) which were tested to be true. Under these cases, the execution takes two instruction cycles. In addition, the instruction set has the following features: (1). Every bit of any register can be set, cleared, or tested directly. (2). The I/O register can be regarded as general register. That is, the same instruction can operate on I/O register. The symbol "R" represents a register designator that specifies which one of the registers (including operational registers and general purpose registers) is to be utilized by the instruction. Bits 6 and 7 in R4 determine the selected register bank. "b" represents a bit field designator that selects the value for the bit located in the register "R" and affects operation. "k" represents an 8 or 10-bit constant or literal value. 42 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM INSTRUCTION BINARY HEX MNEMONIC 0 0000 0000 0000 0000 NOP No Operation None 0 0000 0000 0001 0001 DAA Decimal Adjust A C 0 0000 0000 0010 0002 CONTW A → CONT None 0 0000 0000 0011 0003 SLEP 0 → WDT, Stop oscillator T,P 0 0000 0000 0100 0004 WDTC 0 → WDT T,P 0 0000 0000 rrrr 000r IOW R A → IOCR None <Note1> 0 0000 0001 0000 0010 ENI Enable Interrupt None 0 0000 0001 0001 0011 DISI Disable Interrupt None 0 0000 0001 0010 0012 RET [Top of Stack] → PC None 0 0000 0001 0011 0013 RETI [Top of Stack] → PC, Enable Interrupt None 0 0000 0001 0100 0014 CONTR CONT → A None 0 0000 0001 rrrr 001r IOR R IOCR → A None <Note1> 0 0000 0010 0000 0020 TBL R2+A → R2, Bits 8~9 of R2 unchanged Z,C,DC 0 0000 01rr rrrr 00rr MOV R,A A→R None 0 0000 1000 0000 0080 CLRA 0→A Z 0 0000 11rr rrrr 00rr CLR R 0→R Z 0 0001 00rr rrrr 01rr SUB A,R R-A → A Z,C,DC 0 0001 01rr rrrr 01rr SUB R,A R-A → R Z,C,DC 0 0001 10rr rrrr 01rr DECA R R-1 → A Z 0 0001 11rr rrrr 01rr DEC R R-1 → R Z 0 0010 00rr rrrr 02rr OR A,R A ∨ VR → A Z 0 0010 01rr rrrr 02rr OR R,A A ∨ VR → R Z 0 0010 10rr rrrr 02rr AND A,R A&R→A Z 0 0010 11rr rrrr 02rr AND R,A A&R→R Z 0 0011 00rr rrrr 03rr XOR A,R A⊕R→A Z 0 0011 01rr rrrr 03rr XOR R,A A⊕R→R Z 0 0011 10rr rrrr 03rr ADD A,R A+R→A Z,C,DC 0 0011 11rr rrrr 03rr ADD R,A A+R→R Z,C,DC 0 0100 00rr rrrr 04rr MOV A,R R→A Z 0 0100 01rr rrrr 04rr MOV R,R R→R Z 0 0100 10rr rrrr 04rr COMA R /R → A Z 0 0100 11rr rrrr 04rr COM R /R → R Z 0 0101 00rr rrrr 05rr INCA R R+1 → A Z 0 0101 01rr rrrr 05rr INC R R+1 → R Z 0 0101 10rr rrrr 05rr DJZA R R-1 → A, skip if zero None 0 0101 11rr rrrr 05rr DJZ R R-1 → R, skip if zero None 0 0110 00rr rrrr 06rr RRCA R R(n) → A(n-1), C Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) OPERATION STATUS AFFECTED • 43 EM78P451 8-Bit Microcontroller with OTP ROM INSTRUCTION BINARY HEX MNEMONIC OPERATION STATUS AFFECTED R(0) → C, C → A(7) 0 0110 01rr rrrr 06rr RRC R 0 0110 10rr rrrr 06rr RLCA R 0 0110 11rr rrrr 06rr RLC R 0 0111 00rr rrrr 07rr SWAPA R 0 0111 01rr rrrr 07rr SWAP R 0 0111 10rr rrrr 07rr 0 0111 11rr rrrr R(n) → R(n-1), R(0) → C, C → R(7) R(n) → A(n+1), R(7) → C, C → A(0) R(n) → R(n+1), R(7) → C, C → R(0) R(0-3) → A(4-7), R(4-7) → A(0-3) C C C None R(0-3) ↔ R(4-7) None JZA R R+1 → A, skip if zero None 07rr JZ R R+1 → R, skip if zero None 0 100b bbrr rrrr 0xxx BC R,b 0 → R(b) None <Note2> 0 101b bbrr rrrr 0xxx BS R,b 1 → R(b) None <Note3> 0 110b bbrr rrrr 0xxx JBC R,b if R(b)=0, skip None 0 111b bbrr rrrr 0xxx JBS R,b if R(b)=1, skip None 1 00kk kkkk kkkk 1kkk CALL k PC+1 → [SP], (Page, k) → PC None 1 01kk kkkk kkkk 1kkk JMP k (Page, k) → PC None 1 1000 kkkk kkkk 18kk MOV A,k k→A None 1 1001 kkkk kkkk 19kk OR A,k A∨k→A Z 1 1010 kkkk kkkk 1Akk AND A,k A&k→A Z 1 1011 kkkk kkkk 1Bkk XOR A,k A⊕k→A Z 1 1100 kkkk kkkk 1Ckk RETL k k → A, [Top of Stack] → PC None 1 1101 kkkk kkkk 1Dkk SUB A,k k-A → A Z,C,DC 1 1110 0000 0010 1E02 INT PC+1 → [SP], 002H → PC None 1 1111 kkkk kkkk 1Fkk ADD A,k k+A → A Z,C,DC NOTE This instruction is applicable to IOC5 ~ IOC9, IOCD~IOCF only. This instruction is not recommended for RF operation. This instruction cannot operate on R3F. 44 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM 4.12 Timing Diagrams AC Test Input/O utput W aveform 2.4 2.0 0.8 TEST POINTS 2.0 0.8 0.4 AC Testing : Input is driven at 2.4V for logic "1",and 0.4V for logic "0".Tim ing m easurem ents are m ade at 2.0V for logic "1",and 0.8V for logic "0". RESET Tim ing (CLK="0") NOP Instruction 1 Executed CLK /RESET T drh TCC Input Tim ing (CLKS="0") Tins CLK TCC Ttcc Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 45 EM78P451 8-Bit Microcontroller with OTP ROM 5 ABSOLUTE MAXIMUM RATING Items Temperature under bias Storage temperature 0°C to 70°C -65°C to 150°C Input voltage -0.3V to +6.0V Output voltage -0.3V to +6.0V DC to 20MHz Operating Frequency (2clk) 6 Rating ELECTRICAL CHARACTERISTICS 6.1 DC Characteristic (Ta=0°C~70°C, VDD=5V±5%, VSS=0V) Symbol Parameter Condition Min XTAL VDD to 2.3V FXT XTAL VDD to 3V Two clocks XTAL VDD to 5V RC VDD to 2.3V FRC RC VDD to 3V Two clocks RC VDD to 5V IIL VIH1 VIL1 VIHX1 VILX1 VIH2 VIL2 VIHX2 VILX2 VOH1 VOH2 46 • Input Leakage Current Input High Voltage VDD=5V) Input Low Voltage (VDD=5V) Clock Input High Voltage (VDD=5V) Clock Input Low Voltage (VDD=5V) Input High Voltage(VDD=3V) Input Low Voltage (VDD=3V) Clock Input High Voltage (VDD=3V) Clock Input Low Voltage (VDD=3V) Output High Voltage (Ports 5,6,8, P74~P77, P90~P92,P95~P97,and PF5~PF7) Output High Voltage (P70~P72) Typ Max DC 4 DC 8 DC 20 DC 4 DC 4 DC 4 ±1 VIN = VDD, VSS 2.0 2.5 1.0 1.5 1.5 0.6 2.4 2 V V V V OSCI S7=1(IOCD Register bit7), IOH = -7.0mA µA V 0.4 IOH = -8.0mA MHz V OSCI OSCI MHz V 0.8 OSCI Unit V V 2.4 V Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM Symbol VOH3 VOL1 VOL2 VOL3 VOL4 Parameter Output High Voltage (P93/SDO,P94/SCK) Output Low Voltage (Ports 5,6,8, P74~P77, P90~P92,P95~P97,and PF5~PF7)) Output Low Voltage (P70~P72) Output Low Voltage (P93/SDO, P94/SCK) Output Low Voltage (P74~P77) Condition Min S7=0(IOCD Register bit7), IOH = -7.0mA 2.4 IOH = -5.0mA 2.4 S7=1(IOCD Register bit7), IOH = 10.0mA S7=0(IOCD Register bit7), IOH = 10.0mA V 0.4 IOL = 15.0mA 0.4 IPH2 Pull-high active, input pin at VSS V 0.8 0.4 Pull-high active, input pin at VSS Operating supply current 0.4 IOL = 7.0mA Pull-high current (P74,P75) ICC Unit 0.4 Pull-high current Power down current Max V IOL = 5.0mA IPH ISB Typ -50 -100 -240 1 V µA mA All input and I/O pin at VDD, output pin floating, WDT enabled /RESET="High", Fosc=1.84324MHz (CK2="0"), output pin floating 10 µA 3 mA 6.2 AC Characteristic (Ta=0°C~70°C, VDD=5V±5%, VSS=0V) Symbol Parameter Dclk Input CLK duty cycle Tins Instruction cycle time (CK2="0") Ttcc TCC input period Twdt Watchdog timer period Tdrh Device reset hold period Conditions RC Type Min Typ Max Unit 45 50 55 % DC ns 500 (Tins+20)/N* Ta=25°C Ta=25°C ns 18 18 3 ms ms N= selected prescaler ratio. 3 NOTE: Vdd = 5V, set up time period = 16.2ms ± 5% Vdd = 3V, set up time period = 18.0ms ± 5% Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 47 EM78P451 8-Bit Microcontroller with OTP ROM 7 Application Circuit EM78P451 48 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) EM78P451 8-Bit Microcontroller with OTP ROM APPENDIX A Package Types OTP MCU Package Type Pin Count Package Size EM78P451P DIP 40 600 mil EM78P451AQ QFP 44 Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice) • 49 EM78P451 8-Bit Microcontroller with OTP ROM 50 • Product Specification (V1.1) 06.30.2003 (This specification is subject to change without further notice)