EM78P259N/260N 8-Bit Microprocessor with OTP ROM Product Specification DOC. VERSION 1.0 ELAN MICROELECTRONICS CORP. June 2005 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 308 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 General Description .................................................................................................. 1 Features ..................................................................................................................... 1 Pin Configuration (Package) .................................................................................... 2 3.1 4 5 6 EM78P259NP/M Pin Assignment....................................................................... 2 3.2 EM78P260NP/M/KM Pin Assignment ................................................................ 3 Functional Block Diagram........................................................................................ 3 Pin Description.......................................................................................................... 4 5.1 EM78P259NP/M Pin Description ....................................................................... 4 5.2 EM78P260NP/M/KM Pin Description ................................................................. 5 Function Description ................................................................................................ 6 6.1 Operational Registers......................................................................................... 6 6.1.1 6.1.2 6.1.3 6.1.4 6.1.5 6.1.6 6.1.7 6.1.8 6.1.9 6.1.10 6.1.11 6.1.12 6.1.13 6.1.14 6.1.15 6.1.16 6.2 R0 (Indirect Address Register) ............................................................................6 R1 (Time Clock /Counter)....................................................................................6 R2 (Program Counter) and Stack........................................................................6 6.1.3.1 Data Memory Configuration .................................................................8 R3 (Status Register) ............................................................................................9 R4 (RAM Select Register)...................................................................................9 R5 ~ R6 (Port 5 ~ Port 6) ..................................................................................10 R7 (Port 7).........................................................................................................10 R8 (AISR: ADC Input Select Register) ..............................................................11 R9 (ADCON: ADC Control Register).................................................................12 RA (ADOC: ADC Offset Calibration Register) ...................................................13 RB (ADDATA: Converted Value of ADC)...........................................................13 RC (ADDATA1H: Converted Value of ADC)......................................................14 RD (ADDATA1L: Converted Value of ADC) ......................................................14 RE (Interrupt Status 2 & Wake-Up Control Register) ........................................14 RF (Interrupt Status 2 Register) ........................................................................15 R10 ~ R3F .........................................................................................................15 Special Purpose Registers ............................................................................... 16 6.2.1 6.2.2 6.2.3 6.2.4 6.2.5 6.2.6 6.2.7 6.2.8 A (Accumulator).................................................................................................16 CONT (Control Register)...................................................................................16 IOC50 ~ IOC70 (I/O Port Control Register) ......................................................17 IOC80 (Comparator and TCCA Control Register).............................................17 IOC90 (TCCB and TCCC Control Register ).....................................................18 IOCA0 (IR and TCCC Scale Control Register) .................................................19 IOCB0 (Pull-Down Control Register).................................................................21 IOCC0 (Open-Drain Control Register) ..............................................................21 Product Specification (V1.0) 06.16.2005 • iii Contents 6.2.9 6.2.10 6.2.11 6.2.12 6.2.13 6.2.14 6.2.15 6.2.16 6.2.17 6.2.18 6.2.19 6.3 TCC/WDT and Prescaler.................................................................................. 28 6.4 I/O Ports ........................................................................................................... 29 6.4.1 6.5 Usage of Port 5 Input Change Wake-up/Interrupt Function..............................32 RESET and Wake-up ....................................................................................... 32 6.5.1 6.5.2 RESET and Wake-up Operation .......................................................................32 6.5.1.1 Wake-Up and Interrupt Modes Operation Summary..........................35 6.5.1.2 Register Initial Values after Reset ......................................................37 6.5.1.3 Controller Reset Block Diagram.........................................................42 The T and P Status under STATUS Register ....................................................42 6.6 Interrupt ............................................................................................................ 42 6.7 Analog-To-Digital Converter (ADC) .................................................................. 45 6.7.1 6.7.2 6.7.3 6.7.4 6.7.5 6.7.6 6.8 6.9 ADC Control Register (AISR/R8, ADCON/R9, ADOC/RA) ...............................45 6.7.1.1 R8 (AISR: ADC Input Select Register) ...............................................45 6.7.1.2 R9 (ADCON: ADC Control Register)..................................................46 6.7.1.3 RA (ADOC: ADC Offset Calibration Register) ....................................47 ADC Data Register (ADDATA/RB, ADDATA1H/RC, ADDATA1L/RD) ...............48 ADC Sampling Time ..........................................................................................48 AD Conversion Time .........................................................................................48 ADC Operation during Sleep Mode...................................................................48 Programming Process/Considerations..............................................................49 6.7.6.1 Programming Process........................................................................49 6.7.6.2 Sample Demo Programs ....................................................................50 Infrared Remote Control Application/PWM Waveform Generation................... 52 6.8.1 6.8.2 6.8.3 Overview ...........................................................................................................52 Function Description..........................................................................................53 Programming the Related Registers ................................................................55 Timer/Counter................................................................................................... 56 6.9.1 6.9.2 6.9.3 iv • IOCD0 (Pull-high Control Register)...................................................................22 IOCE0 (WDT Control & Interrupt Mask Registers 2) ........................................22 IOCF0 (Interrupt Mask Register).......................................................................23 IOC51 (TCCA Counter) .....................................................................................24 IOC61 (TCCB Counter) .....................................................................................24 IOC71 (TCCBH/MSB Counter) .........................................................................25 IOC81 (TCCC Counter).....................................................................................25 IOC91 (Low-Time Register) ..............................................................................26 IOCA1 (High Time Register) .............................................................................26 IOCB1 High/Low Time Scale Control Register) ................................................26 IOCC1 (TCC Prescaler Counter) ......................................................................27 Overview ...........................................................................................................56 Function Description..........................................................................................56 Programming the Related Registers .................................................................58 Product Specification (V1.0) 06.16.2005 Contents 6.10 Comparator ...................................................................................................... 58 6.10.1 6.10.2 6.10.3 6.10.4 6.10.5 External Reference Signal ................................................................................59 Comparator Outputs..........................................................................................60 Using Comparator as an Operation Amplifier....................................................60 Comparator Interrupt .........................................................................................60 Wake-up from SLEEP Mode .............................................................................60 6.11 Oscillator .......................................................................................................... 61 6.11.1 6.11.2 6.11.3 6.11.4 Oscillator Modes................................................................................................61 Crystal Oscillator/Ceramic Resonators (XTAL) .................................................62 External RC Oscillator Mode.............................................................................63 Internal RC Oscillator Mode ..............................................................................64 6.12 Power-on Considerations ................................................................................. 65 6.12.1 Programmable WDT Time-Out Period ..............................................................65 6.12.2 External Power-on Reset Circuit .......................................................................65 6.12.3 Residual Voltage Protection ..............................................................................66 6.13 Code Option ..................................................................................................... 67 6.13.1 Code Option Register (Word 0).........................................................................67 6.13.2 Code Option Register (Word 1).........................................................................68 6.13.3 Customer ID Register (Word 2).........................................................................69 6.14 Instruction Set .................................................................................................. 69 7 8 9 10 Absolute Maximum Ratings ................................................................................... 71 DC Electrical Characteristics ................................................................................. 72 8.1 AD Converter Characteristics........................................................................... 73 8.2 Comparator (OP) Characteristics ..................................................................... 74 8.3 Device Characteristics...................................................................................... 74 AC Electrical Characteristic ................................................................................... 75 Timing Diagrams ..................................................................................................... 76 APPENDIX A. B Package Types Summary ....................................................................................... 77 Packaging Configurations...................................................................................... 77 B.1 18-Lead Plastic Dual in line (PDIP) - 300 mil ................................................... 77 B.2 18-Lead Plastic Small Outline (SOP) - 300 mil ................................................ 78 B.3 20-Lead Plastic Shrink Small Outline (SSOP) - 209 mil ................................... 79 B.4 20-Lead Plastic Dual-in-line (PDIP) - 300 mil ................................................... 80 B.5 20-Lead Plastic Small Outline (SOPP) - 300 mil .............................................. 81 C Quality Assurance and Reliability ......................................................................... 82 C.1 Address Trap Detect......................................................................................... 82 Product Specification (V1.0) 06.16.2005 •v Contents Specification Revision History Doc. Version 1.0 vi • Revision Description Initial official version Date 2005/06/16 Product Specification (V1.0) 06.16.2005 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 1 General Description EM78P259N and EM78P260N are 8-bit microprocessors designed and developed with low-power and high-speed CMOS technology. It is equipped with a 2K*13-bit Electrical One Time Programmable Read Only Memory (OTP-ROM). With its OTP-ROM feature, it is able to offer a convenient way of developing and verifying your programs. Moreover, it provides a protect bit to guard against code intrusion, as well as 3 Code Option words to accommodate your requirements. Furthermore you can take advantage of ELAN Writer to easily write your development code into the EM78P259N and EM78P260N. 2 Features Operating voltage range: 2.3V~5.5V 2.5V~5.5V base on 0°C ~ 70°C (commercial) base on –40°C ~ 85°C (industrial) Operating frequency range (base on 2 clocks): • Crystal mode: DC ~ 20MHz/2clks, 5V; DC ~ 8MHz/2clks, 3V • RC mode: DC ~ 4MHz/2clks, 5V; DC ~ 4MHz/2clks, 3V Low power consumption: • Less than 1.9 mA at 5V/4MHz • Typically 15 µA, at 3V/32kHz • Typically 1 µA, during sleep mode Built-in RC oscillator 4MHz, 8MHz,1MHz, 455kHz (auto calibration) Programmable WDT time (4.5ms:18ms) Independent Programmable prescaler of WDT One configuration register to match your requirements, and user’s ID code for customer use is provided 80× 8 on chip registers (SRAM, general purpose register) 2K × 13 on-chip ROM Bi-directional I/O ports 8-level stacks for subroutine nesting 8-bit real time clock/counter (TCC) with selective signal sources, trigger edges, and overflow interrupt 8-bit real time clock/counter (TCCA, TCCC) and 16-bit real time clock/counter (TCCB) with selective signal sources, trigger edges, and overflow interrupt One pair of comparators (can act as an OP) 4-bit multi-channel Analog-to-Digital Converter with 12-bit resolution Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) •1 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Easily-implemented IR (Infrared remote control) application circuit Power down (SLEEP) mode Six interrupt sources: • • • • • • TCC, TCCA, TCCB, and TCCC overflow interrupt Input-port status change interrupt (wake-up from sleep mode) External interrupt Comparators status change interrupt IR/PWM interrupt ADC completion interrupt Programmable free running watchdog timer 8 programmable pull-high I/O pins 8 programmable open-drain I/O pins 8 programmable pull-down I/O pins. Two or Four clocks per instruction cycle Package types: • • • • • 18-pin DIP 300mil : EM78P259NP 18-pin SOP 300mil : EM78P259NM 20-pin DIP 300mil : EM78P260NP 20-pin SOP 300mil : EM78P260NM 20-pin SSOP 209mil : EM78P260NKM Power-on voltage detector available (2.0V± 0.1V) 3 Pin Configuration (Package) 3.1 EM78P259NP/M Pin Assignment 1 18 P51/ADC1 P53/ADC3 2 17 P50/ADC0 P54/TCC/VREF 3 16 P55/OSCI /RESET 4 15 P70/OSCO Vss 5 14 VDD P60//INT 6 13 P67/IR OUT P61/TCCA 7 12 P66/CIN- P62/TCCB 8 11 P65/CIN+ P63/TCCC 9 10 P64/CO EM78P259NP EM78P259NM P52/ADC2 Fig. 3-1 Pin Assignment – EM78P259NP/M 2• Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 3.2 EM78P260NP/M/KM Pin Assignment 1 20 P57 P52/ADC2 2 19 P51/ADC1 P53/ADC3 3 18 P50/ADC0 P54/TCC/VREF 4 17 P55/OSCI /RESET 5 16 P70/OSCO Vss 6 15 VDD P60//INT 7 14 P67/IR OUT P61/TCCA 8 13 P66/CIN- P62/TCCB 9 12 P65/CIN+ P63/TCCC 10 11 P64/CO EM78P260N P56 Fig. 3-2 Pin Assignment – EM78P260NP/M/KM 4 Functional Block Diagram OSCI TCC WDT timer OSCO /RESET ROM /INT STACK 0 R2 STACK 1 STACK 2 STACK 3 Oscillator Timing STACK 4 Control Prescaler STACK 5 Interrupt Controller Instruction STACK 6 Register STACK 7 RAM Built-in OSC ALU R1 (TCC) Instruction Decoder R4 R3 ACC DATA & CONTROL BUS ADC0/P50 ADC1/P51 ADC2/P52 ADC3/P53 VREF/TCC/P54 OSCI/P55 P56 P57 I/O PORT5 IOC5 R5 COUNTER IOC6/7 I/O PORT6/7 R6/7 P60/INT P61/TCCA P62/TCCB P63/TCCC P64/CO P65/CIN+ P66/CINP67/IR OUT P70/OSCO Fig. 4-1 EM78P259N/260N Functional Block Diagram Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) •3 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 5 Pin Description 5.1 EM78P259NP/M Pin Description Symbol Pin No. Type VDD 14 – OSCI 16 I OSCO 15 I/O Function Power supply ■ XTAL type Crystal input terminal or external clock input pin ■ RC type: RC oscillator input pin ■ XTAL type: Output terminal for crystal oscillator or external clock input pin ■ RC type: Clock output with a duration one instruction cycle ■ External clock signal input P70 15 I/O 6 ~ 13 I/O ■ General-purpose I/O pin ■ Default value at power-on reset ■ General-purpose I/O pin P60 ~ P67 ■ Open drain ■ Default value at power-on reset ■ General-purpose I/O pin P50 ~ P55 1~3 16 ~ 18 I/O ■ Pull-high/pull-down ■ Wake up from sleep mode when the status of the pin changes ■ Default value at power-on reset 12, 11 I 10 O IR OUT 13 O VREF 3 I /INT 6 I CIN–, CIN+ CO ■ “–“ → the input pin of Vin– of a comparator ■ “+” → the input pin of Vin+ of a comparator ■ Pin CO is the output of the comparator ■ Defined by IOC80 <4:3> ■ IR mode output pin. Capable of driving and sinking current = 20mA when the output voltage drops to 0.7Vdd and rise to 0.3Vdd at Vdd = 5V. ■ External reference voltage for ADC ■ Defined by ADCON (R9)<7> ■ External interrupt pin triggered by falling or rising edge ■ Defined by CONT <7> TCC, TCCA, 3, 7, TCCB, TCCC 8, 9 ■ External Counter input ■ TCC defined by CONT<5> I ■ TCCA defined by IOC80 <1> ■ TCCB defined by IOC90 <5> ■ TCCC defined by IOC90 <1> ADC0 ~ ADC3 1, 2, 17, 18 I ■ Analog to Digital Converter ■ Defined by ADCON (R9)<1:0> ■ If it remains at logic low, the device will be reset 4• /RESET 4 I VSS 5 – ■ Wake-up from sleep mode when pin status changes ■ Voltage on /RESET/Vpp must not exceed Vdd during normal mode Ground Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 5.2 EM78P260NP/M/KM Pin Description Symbol Pin No. Type VDD 15 – OSCI 17 I Function Power supply. ■ XTAL type Crystal input terminal or external clock input pin ■ RC type: RC oscillator input pin ■ XTAL type: Output terminal for crystal oscillator or external clock input pin OSCO 16 I/O P70 16 I/O ■ RC type: Clock output with a time period of one instruction cycle. ■ External clock signal input ■ General-purpose I/O pin ■ Default value at power-on reset ■ General-purpose I/O pin P60 ~ P67 7 ~ 14 I/O ■ Open-drain ■ Default value at power-on reset ■ General-purpose I/O pin P50 ~ P57 1~4 17 ~ 20 I/O ■ Pull-high/pull-down ■ Wake up from sleep mode when the status of the pin changes ■ Default value at power-on reset CIN–, CIN+ 13, 12 I CO 11 O IR OUT 14 O VREF 4 I /INT 7 I ■ “–“→ the input pin of Vin– of a comparator ■ “+”→ the input pin of Vin+ of a comparator ■ Pin CO is the output of the comparator ■ Defined by IOC80 <4:3> ■ IR mode output pin. Capable of driving and sinking current = 20mA when the output voltage drops to 0.7Vdd and rise to 0.3Vdd at Vdd = 5V. ■ External reference voltage for ADC ■ Defined by ADCON (R9)<7> ■ External interrupt pin triggered by falling or rising edge. ■ Defined by CONT <7> TCC, TCCA, 4, 8, TCCB, TCCC 9, 10 ■ External Counter input ■ TCC defined by CONT<5> I ■ TCCA defined by IOC80 <1> ■ TCCB defined by IOC90 <5> ■ TCCC defined by IOC90 <1> ADC0 ~ ADC3 2, 3, 18, 19 I ■ Analog to Digital Converter ■ Defined by ADCON (R9)<1:0> ■ If it remains at logic low, the device will be reset /RESET 5 I VSS 6 – ■ Wake-up from sleep mode when pin status changes ■ Voltage on /RESET/Vpp must not exceed Vdd during normal mode Ground Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) •5 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6 Function Description 6.1 Operational Registers 6.1.1 R0 (Indirect Address Register) R0 is not a physically implemented register. Its major function is to perform as an indirect address pointer. Any instruction using R0 as a pointer, actually accesses the data pointed by the RAM Select Register (R4). 6.1.2 R1 (Time Clock /Counter) Increased by an external signal edge which is defined by the TE bit (CONT-4) through the TCC pin, or by the instruction cycle clock. Writable and readable as any other registers The TCC prescaler counter (IOCC1) is assigned to TCC The contents of the IOCC1 register is cleared whenever – • a value is written to TCC register. • a value is written to TCC prescaler bits (Bit3, 2, 1, 0 of the CONT register) • during power on reset, /RESET, or WDT time out reset. 6.1.3 R2 (Program Counter) and Stack R3 A10 A9 A8 A7 ~ A0 Hardware Interrupt Vector 01 PAGE1 0400~07FF Stack Level 1 Stack Level 2 Stack Level 3 Stack Level 4 Stack Level 5 Stack Level 6 Stack Level 7 Stack Level 8 On-chip Program 000H 003H ~ 01EH 3FEH Memory User Memory Space CALL RET RETL RETI 00 PAGE0 0000~03FF Reset Vector 7FFH Fig. 5-2 Program Counter Organization R2 and hardware stacks are 12-bit wide. The structure is depicted in the table under Section 6.1.3.1, Data Memory Configuration (next page). Generates 2K×13 bits on-chip ROM addresses to the relative programming instruction codes. One program page is 1024 words long. The contents of R2 are all set to "0"s when a RESET condition occurs. 6• Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM "JMP" instruction allows direct loading of the lower 10 program counter bits. Thus, "JMP" allows PC to jump to any location within a page. "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 of the top of stack. "ADD R2, A" allows a relative address to be added to the current PC, and the ninth and above bits of the PC will increase progressively. "MOV R2, A" allows loading of an address from the "A" register to the lower 8 bits of the PC, and the ninth and tenth bits (A8 ~ A9) of the PC will remain unchanged. Any instruction (except “ADD R2,A”) that is written to R2 (e.g., "MOV R2, A", "BC R2, 6",⋅⋅⋅⋅⋅) will cause the ninth bit and the tenth bit (A8 ~ A9) of the PC to remain unchanged. In the case of EM78P259N/260N, the most significant bit (A10) will be loaded with the content of PS0 in the status register (R3) upon execution of a "JMP", "CALL", or any other instructions set which write to R2. All instructions are single instruction cycle (fclk/2 or fclk/4) except for the instructions that are written to R2. Note that these instructions need one or two instructions cycle as determined by Code Option Register CYES bit. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) •7 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.1.3.1 Data Memory Configuration Address IOCX0 PAGE registers IOCX1 PAGE registers Reserve 00 R0 (Indirect Addressing Register) 01 R1 (Time Clock Counter) 02 R2 (Program Counter) Reserve Reserve 03 R3 (Status Register) Reserve Reserve 04 R4 (RAM Select Register) Reserve Reserve 05 R5 (Port5) IOC50 (I/O Port Control Register) IOC51 (TCCA Counter) 06 R6 (Port6) IOC60 (I/O Port Control Register) IOC61 (TCCB LSB Counter) 07 R7 (Port7) IOC70 (I/O Port Control Register) IOC71 (TCCB HSB Counter) 08 R8 (ADC Input Select Register IOC81 (TCCC Counter) 09 R9 (ADC Control Register) IOC91 (Low-Time Register) 0A RA IOCA1 (High-Time Register) 0B RB IOCB1 (High-Time and Low-Time Scale control Register) 0C RC IOCC1 (TCC Prescaler Control) 0D RD 0E RE (ADC Offset Calibration Register) (The converted value AD11~AD4 of ADC) (The converted value AD11~AD8 of ADC) (The converted value AD7~AD0 of ADC) (Interrupt Status 2 and Wake-Up Control Register 0F RF 10 ︰ 1F 20 : 3F 8• R PAGE registers (Interrupt Status Register 1) Reserve CONT (Control Register) (Comparator and TCCA Control Register) (TCCB and TCCC IOC90 Control Register) (IR and TCCC Scale IOCA0 Control Register) IOC80 IOCB0 (Pull-down Control Register) IOCC0 (Open-drain Control Register) Reserve IOCD0 (Pull-high Control Register) Reserve IOCE0 (WDT Control Register and Interrupt Mask Register 2) Reserve IOCF0 (Interrupt Mask Register 1) Reserve General Registers Bank0 Bank1 Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.1.4 R3 (Status Register) 7 6 5 4 3 2 1 0 RST IOCS PS0 T P Z DC C Bit 7 (RST): Bit of reset type Set to “1” if wake-up from sleep on pin change, comparator status change, or AD conversion completed. Set to “0” if wake-up from other reset types Bit 6 (IOCS): Select the Segment of IO control register 0 = Segment 0 (IOC50 ~ IOCF0) selected 1 = Segment 1 (IOC51 ~ IOCC1) selected Bit 5 (PS0): Page select bits. PS0 is used to select a program memory page. When executing a "JMP," "CALL," or other instructions which cause the program counter to change (e.g., MOV R2, A), PS0 is loaded into the 11th bit of the program counter where it selects one of the available program memory pages. Note that RET (RETL, RETI) instruction does not change the PS0 bit. That is, the return will always be back to the page from where the subroutine was called, regardless of the current PS0 bit setting. PS0 Program Memory Page [Address] 0 Page 0 [000-3FF] 1 Page 1 [400-7FF] Bit 4 (T): Time-out bit. Set to “1” by the "SLEP" and "WDTC" commands or during power on; and reset to “0” by WDT time-out (see Section 6.5.2, The T and P Status under STATUS Register for more details). 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 (see Section 6.5.2, The T and P Status under STATUS Register for more details). Bit 2 (Z): Zero flag. Set to "1" if the result of an arithmetic or logic operation is zero. Bit 1 (DC): Auxiliary carry flag Bit 0 (C): Carry flag 6.1.5 R4 (RAM Select Register) Bit 7: Set to “0” all the time Bit 6: Used to select Bank 0 or Bank 1 of register Bits 5~0: Used to select a register (address: 00~0F, 10~3F) in the indirect addressing mode See the table under Section 6.1.3.1, Data Memory Configuration for data memory configuration. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) •9 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.1.6 R5 ~ R6 (Port 5 ~ Port 6) R5 & R6 are I/O registers The upper 2 bits of R5 are fixed to “0” (if EM78P259N is selected). Only the lower 6 bits of R5 are available (this applies to EM78P259N only as EM78P260N can use all the bits) 6.1.7 R7 (Port 7) Bit 7 6 5 4 3 2 1 0 EM78P259N/260N ‘0’ ‘0’ ‘0’ ‘0’ ‘0’ ‘0’ ‘0’ I/O ICE259N C3 C2 C1 C0 RCM1 RCM0 ‘0’ I/O NOTE R7 is an I/O register For EM78P259N/260N, only the lower 1 bit of R7 is available. Bit 7 ~ Bit 2: [With EM78P259N/260N]: Unimplemented, read as ‘0’. [With Simulator (C3~C0, RCM1, & RCM0)]: are IRC calibration bits in IRC oscillator mode. Under IRC oscillator mode of ICE259N simulator, these are the IRC mode selection bits and IRC calibration bits. Bit 7 ~ Bit 4 (C3 ~ C0): Calibrator of internal RC mode C3 C2 C1 C0 Frequency (MHz) 0 0 0 0 0 0 0 1 (1-36%) x F (1-31.5%) x F 0 0 1 0 (1-27%) x F 0 0 1 1 (1-22.5%) x F 0 1 0 0 (1-18%) x F 0 1 0 1 (1-13.5%) x F 0 0 1 1 1 1 0 1 (1-9%) x F (1-4.5%) x F 1 1 1 1 F (default) 1 1 1 0 (1+4.5%) x F 1 1 0 1 (1+9%) x F 1 1 0 0 (1+135%) x F 1 1 0 0 1 1 1 0 (1+18%) x F (1+22.5%) x F 1 0 0 1 (1+27%) x F 1 0 0 0 (1+31.5%) x F 1. Frequency values shown are theoretical and taken at an instance of a high frequency mode. Hence, frequency values are shown for reference only. Definite values depend on the actual process. 2. Similar way of calculation is also applicable to low frequency mode. 10 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 3 & Bit 2 ( RCM1, RCM0): IRC mode selection bits RCM 1 RCM 0 Frequency (MHz) 1 1 4 (default) 1 0 8 0 1 1 0 0 455kHz 6.1.8 R8 (AISR: ADC Input Select Register) The AISR register defines the pins of Port 5 as analog inputs or as digital I/O, individually. 7 6 5 4 3 2 1 0 – – – – ADE3 ADE2 ADE1 ADE0 Bit 7 ~ Bit 4: Not used Bit 3 (ADE3 ): AD converter enable bit of P53 pin 0 = Disable ADC3, P53 acts as I/O pin 1 = Enable ADC3, acts as analog input pin Bit 2 (ADE2 ): AD converter enable bit of P52 pin 0 = Disable ADC2, P52 acts as I/O pin 1 = Enable ADC2, acts as analog input pin Bit 1 (ADE1 ): AD converter enable bit of P51 pin 0 = Disable ADC1, P51 acts as I/O pin 1 = Enable ADC1, acts as analog input pin Bit 0 (ADE0 ): AD converter enable bit of P50 pin. 0 = Disable ADC0, P50 acts as I/O pin 1 = Enable ADC0, acts as analog input pin Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 11 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.1.9 R9 (ADCON: ADC Control Register) 7 6 5 4 3 2 1 0 VREFS CKR1 CKR0 ADRUN ADPD – ADIS1 ADIS0 Bit 7 (VREFS): The input source of the Vref of the ADC 0 = The Vref of the ADC is connected to Vdd (default value), and the P54/VREF pin carries out the function of P54 1 = The Vref of the ADC is connected to P54/VREF NOTE The P54/TCC/VREF pin cannot be applied to TCC and VREF at the same time. If P53/TCC/VREF acts as VREF analog input pin, then CONT Bit 5 “TS” must be “0.” The P54/TCC/VREF pin priority is as follows: P53/TCC/VREF Pin Priority High Medium Low VREF TCC P54 Bit 6 & Bit 5 (CKR1 & CKR0): The prescaler of oscillator clock rate of ADC 00 = 1: 4 (default value) 01 = 1: 16 10 = 1: 64 11 = 1: WDT ring oscillator frequency CKR0:CKR1 Operation Mode Max. Operation Frequency 00 Fsco/4 1 MHz 01 Fsco/16 4 MHz 10 Fsco/64 16MHz 11 Internal RC – Bit 4 (ADRUN): ADC starts to RUN. 1 = an AD conversion is started. This bit can be set by software 0 = Reset upon completion of the conversion. This bit cannot be reset through software Bit 3 (ADPD): ADC Power-down mode 1 = ADC is operating 0 = Switch off the resistor reference to save power even while the CPU is operating Bit 2: 12 • Not used Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 1 ~ Bit 0 (ADIS1 ~ADIS0): Analog Input Select 00 = ADIN0/P50 01 = ADIN1/P51 10 = ADIN2/P52 11 = ADIN3/P53 These bits can only be changed when the ADIF bit (see Section 6.1.14, RE (Interrupt Status 2 & Wake-Up Control Register)) and the ADRUN bit are both LOW. 6.1.10 RA (ADOC: ADC Offset Calibration Register) 7 6 5 4 3 2 1 0 CALI SIGN VOF[2] VOF[1] VOF[0] “0” “0” “0” Bit 7 (CALI): Calibration enable bit for ADC offset 0 = Calibration disable 1 = Calibration enable Bit 6 (SIGN): Polarity bit of offset voltage 0 = Negative voltage 1 = Positive voltage Bit 5 ~ Bit 3 (VOF[2] ~ VOF[0]): Offset voltage bits VOF[2] VOF[1] VOF[0] EM78P259N/260N Bit 2 ~ Bit 0: ICE259N 0 0 0 0LSB 0LSB 0 0 1 2LSB 1LSB 0 0 1 1 0 1 4LSB 6LSB 2LSB 3LSB 1 0 0 8LSB 4LSB 1 0 1 10LSB 5LSB 1 1 0 12LSB 6LSB 1 1 1 14LSB 7LSB Unimplemented, read as ‘0’ 6.1.11 RB (ADDATA: Converted Value of ADC) 7 6 5 4 3 2 1 0 AD11 AD10 AD9 AD8 AD7 AD6 AD5 AD4 When the AD conversion is completed, the result is loaded into the ADDATA. The ADRUN bit is cleared, and the ADIF (see Section 6.1.14, RE (Interrupt Status 2 & Wake-Up Control Register)) is set. RB is read only. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 13 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.1.12 RC (ADDATA1H: Converted Value of ADC) 7 6 5 4 3 2 1 0 “0” “0” “0” “0” AD11 AD10 AD9 AD8 When the AD conversion is completed, the result is loaded into the ADDATA1H. The ADRUN bit is cleared, and the ADIF (see Section 6.1.14, RE (Interrupt Status 2 & Wake-Up Control Register)) is set. RC is read only 6.1.13 RD (ADDATA1L: Converted Value of ADC) 7 6 5 4 3 2 1 0 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 When the AD conversion is completed, the result is loaded into the ADDATA1L. The ADRUN bit is cleared, and the ADIF (see Section 6.1.14, RE (Interrupt Status 2 & Wake-Up Control Register)) is set. RD is read only 6.1.14 RE (Interrupt Status 2 & Wake-Up Control Register) 7 6 5 4 3 2 1 0 – – ADIF CMPIF ADWE CMPWE ICWE - NOTE ■ RE <5,4> can be cleared by instruction but cannot be set. ■ IOCE0 is the interrupt mask register. ■ Reading RE will result to "logic AND" of RE and IOCE0. Bit 7 & Bit 6: Not used Bit 5 (ADIF): Interrupt flag for analog to digital conversion. Set when AD conversion is completed. Reset by software 0 = no interrupt occurs 1 = interrupt request Bit 4 (CMPIF): Comparator interrupt flag. Set when a change occurs in the output of Comparator. Reset by software. 0 = no interrupt occurs 1 = interrupt request Bit 3 (ADWE): ADC wake-up enable bit 0 = Disable ADC wake-up 1 = Enable ADC wake-up When AD Conversion enters sleep mode, this bit must be set to “Enable“. 14 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 2 (CMPWE): Comparator wake-up enable bit 0 = Disable Comparator wake-up 1 = Enable Comparator wake-up When Comparator enters sleep mode, this bit must be set to “Enable.“ Bit 1 (ICWE): Port 5 input change to wake-up status enable bit 0 = Disable Port 5 input change to wake-up status 1 = Enable Port 5 input change to wake-up status When Port 5 change enters sleep mode, this bit must be set to “Enable.“ Bit 0: 6.1.15 Not implemented, read as ‘0’ RF (Interrupt Status 2 Register) 7 6 5 4 3 2 1 0 LPWTIF HPWTIF TCCCIF TCCBIF TCCAIF EXIF ICIF TCIF NOTE ■ “1” means interrupt request; “0” means no interrupt occurs. ■ RF can be cleared by instruction but cannot be set. ■ IOCF0 is the relative interrupt mask register. ■ Reading RF will result to "logic AND" of RF and IOCF0. Bit 7 (LPWTIF): Internal low-pulse width timer underflow interrupt flag for IR/PWM function. Reset by software. Bit 6 (HPWTIF): Internal high-pulse width timer underflow interrupt flag for IR/PWM function. Reset by software. Bit 5 (TCCCIF): TCCC overflow interrupt flag. Set when TCCC overflows. Reset by software. Bit 4 (TCCBIF): TCCB overflow interrupt flag. Set when TCCC overflows. Reset by software. Bit 3 (TCCAIF): TCCA overflow interrupt flag. Set when TCCC overflows. Reset by software. Bit 2 (EXIF): External interrupt flag. Set by falling edge on /INT pin. Reset by software. Bit 1 (ICIF): Port 5 input status change interrupt flag. Set when Port 5 input changes. Reset by software. Bit 0 (TCIF): TCC overflow interrupt flag. Set when TCC overflows. Reset by software. 6.1.16 R10 ~ R3F All of these are 8-bit general-purpose registers. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 15 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.2 Special Purpose Registers 6.2.1 A (Accumulator) Internal data transfer, or instruction operand holding. It cannot be addressed. 6.2.2 CONT (Control Register) 7 6 5 4 3 2 1 0 INTE INT TS TE PSTE PST2 PST1 PST0 NOTE ■ The CONT register is both readable and writable. ■ Bit 6 is read only. Bit 7 (INTE): INT signal edge 0 = interrupt occurs at the rising edge on the INT pin 1 = interrupt occurs at the falling edge on the INT pin Bit 6 (INT): Interrupt enable flag 0 = masked by DISI or hardware interrupt 1 = enabled by the ENI/RETI instructions This bit is readable only. Bit 5 (TS): TCC signal source 0 = internal instruction cycle clock. P54 is bi-directional I/O pin. 1 = transition on the TCC pin Bit 4 (TE): TCC signal edge 0 = increment if the transition from low to high takes place on the TCC pin 1 = increment if the transition from high to low takes place on the TCC pin. Bit 3 (PSTE): Prescaler enable bit for TCC 0 = prescaler disable bit. TCC rate is 1:1. 1 = prescaler enable bit. TCC rate is set as Bit 2 ~ Bit 0. 16 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 2 ~ Bit 0 (PST2 ~ PST0): TCC prescaler bits PST2 PST1 PST0 TCC Rate 0 0 0 1:2 0 0 0 1 1 0 1:4 1:8 0 1 1 1:16 1 0 0 1:32 1 0 1 1:64 1 1 0 1:128 1 1 1 1:256 NOTE Tcc timeout period [1/Fosc x prescaler x 256 (Tcc cnt) x 1 (CLK=2)] Tcc timeout period [1/Fosc x prescaler x 256 (Tcc cnt) x 2 (CLK=4)] 6.2.3 IOC50 ~ IOC70 (I/O Port Control Register) "1" puts the relative I/O pin into high impedance, while "0" defines the relative I/O pin as output. Only the lower 6 bits of IOC50 can be defined (this applies to EM78P259N only as EM78P260N can use all the bits). Only the lower 1 bits of IOC70 can be defined, the others bits are not available. IOC50, IOC60, and IOC70 registers are all readable and writable 6.2.4 IOC80 (Comparator and TCCA Control Register) 7 6 5 4 3 2 1 0 – – CMPOUT COS1 COS0 TCCAEN TCCATS TCCATE NOTE ■ Bits 4 ~ 0 of the IOC80 register are both readable and writable. ■ Bit5 of the IOC80 register is readable only. Bit 7 & Bit 6: Not used Bit 5 (CMPOUT): The result of the comparator output This bit is readable only Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 17 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 4 & Bit 3 (COS1 & COS0): Comparator/OP Select bits COS1 COS0 0 0 0 1 1 0 1 1 Bit 2 (TCCAEN): Function Description Comparator and OP not used. P64, P65, and P66 act as normal I/O pin Acts as Comparator and P64 acts as normal I/O pin Acts as Comparator and P64 acts as Comparator output pin (CO) Acts as OP and P64 acts as OP output pin (CO) TCCA enable bit 0 = disable TCCA 1 = enable TCCA as a counter Bit 1 (TCCATS): TCCA signal source 0 =: internal instruction cycle clock. P61 is a bi-directional I/O pin. 1 = transit through the TCCA pin Bit 0 (TCCATE): TCCA signal edge 0 = increment if transition from low to high takes place on the TCCA pin 1 = increment if transition from high to low takes place on the TCCA pin 6.2.5 IOC90 (TCCB and TCCC Control Register) 7 6 5 4 3 2 1 0 TCCBHE TCCBEN TCCBTS TCCBTE – TCCCEN TCCCTS TCCCTE Bit 7 (TCCBHE): Control bit is used to enable the most significant byte of counter 1 = Enable the most significant byte of TCCBH TCCB is a 16-bit counter 0 = Disable the most significant byte of TCCBH (default value) TCCB is an 8-bit counter Bit 6 (TCCBEN): TCCB enable bit 0 = disable TCCB 1 = enable TCCB as a counter Bit 5 (TCCBTS) TCCB signal source 0 = internal instruction cycle clock. P62 is a bi-directional I/O pin. 1 = transit through the TCCB pin 18 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 4 (TCCBTE): TCCB signal edge 0 = increment if the transition from low to high takes place on the TCCB pin 1 = increment if the transition from high to low takes place on the TCCB pin Bit 3: Not used. Bit 2 (TCCCEN): TCCC enable bit 0 = disable TCCC 1 = enable TCCC as a counter Bit 1 (TCCCTS) TCCC signal source 0 = internal instruction cycle clock. P63 is a bi-directional I/O pin. 1 = transit through the TCCC pin Bit 0 (TCCCTE): TCCC signal edge 0 = increment if the transition from low to high takes place on the TCCC pin 1 = increment if the transition from high to low takes place on the TCCC pin 6.2.6 IOCA0 (IR and TCCC Scale Control Register) 7 6 5 4 3 2 1 0 TCCCSE TCCCS2 TCCCS1 TCCCS0 IRE HF LGP IROUTE Bit 7 (TCCCSE): Scale enable bit for TCCC An 8-bit counter is provided as scale for TCCC and IR-Mode. When in IR-Mode, TCCC counter scale uses the low-time segments of the pulse generated by Fcarrier frequency modulation (see Fig. 6-11 in Section 6.8.2, Function Description). 0 = scale disable bit, TCCC rate is 1:1 1 = scale enable bit, TCCC rate is set as Bit 6 ~ Bit 4 Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 19 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 6 ~ Bit 4 (TCCCS2 ~ TCCCS0): TCCC scale bits The TCCCS2 ~ TCCCS0 bits of the IOCA0 register are used to determine the scale ratio of TCCC as shown below: Bit 3 (IRE): TCCCS2 TCCCS1 TCCCS0 TCCC Rate 0 0 0 1:2 0 0 1 1:4 0 1 0 1:8 0 1 1 1:16 1 0 0 1:32 1 0 1 1:64 1 1 0 1:128 1 1 1 1:256 Infrared Remote Enable bit 0 = Disable IRE, i.e., disable H/W Modulator Function. IROUT pin fixed to high level and the TCCC is UP Counter. 1 = Enable IRE, i.e., enable H/W Modulator Function. Pin 67 defined as IROUT. If HP=1, the TCCC counter scale uses the low-time segments of the pulse generated by Fcarrier frequency modulation (see Fig. 6-11 in Section 6.8.2, Function Description). When HP=0, the TCCC is UP Counter. Bit 2 (HF): High Frequency bit 0 = PWM application. IROUT waveform is achieved according to high-pulse width timer and low-pulse width timer which determine the high time width and low time width respectively 1 = IR application mode. The low-time segments of the pulse generated by Fcarrier frequency modulation (see Fig. 6-11 in Section 6.8.2, Function Description) Bit 1 (LGP): Long Pulse. 0 = The high-time register and low-time register is valid 1 = The high-time register is ignored. A single pulse is generated Bit 0 (IROUTE): Control bit to define the P67 (IROUT) pin function 0 = P67 defined as bi-directional I/O pin 1 = P67 defined as IROUT. Under this condition, the I/O control bit of P67 (Bit 7 of IOC60) must be set to “0” 20 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.2.7 IOCB0 (Pull-Down Control Register) 7 6 5 4 3 2 1 0 /PD57 /PD56 /PD55 /PD54 /PD53 /PD52 /PD51 /PD50 NOTE IOCB0 register is both readable and writable Bit 7 (/PD57): Control bit is used to enable the pull-down of the P57 pin (applicable to EM78P260N only) 0 = Enable internal pull-down 1 = Disable internal pull-down Bit 6 (/PD56): Control bit is used to enable the pull-down of the P56 pin (applicable to EM78P260N only) Bit 5 (/PD55): Control bit is used to enable the pull-down of the P55 pin Bit 4 (/PD54): Control bit is used to enable the pull-down of the P54 pin Bit 3 (/PD53): Control bit is used to enable the pull-down of the P53 pin Bit 2 (/PD52): Control bit is used to enable the pull-down of the P52 pin Bit 1 (/PD51): Control bit is used to enable the pull-down of the P51 pin Bit 0 (/PD50): Control bit is used to enable the pull-down of the P50 pin. 6.2.8 IOCC0 (Open-Drain Control Register) 7 6 5 4 3 2 1 0 /OD67 /OD66 /OD65 /OD64 /OD63 /OD62 /OD61 /OD60 NOTE The IOCC0 register is both readable and writable Bit 7 (/OD67): Control bit is used to enable the open-drain of the P67 pin 0 = Enable open-drain output 1 = Disable open-drain output Bit 6 (/OD66): Control bit is used to enable the open-drain of the P66 pin Bit 5 (/OD65): Control bit is used to enable the open-drain of the P65 pin Bit 4 (/OD64): Control bit is used to enable the open-drain of the P64 pin Bit 3 (/OD63): Control bit is used to enable the open-drain of the P63 pin Bit 2 (/OD62): Control bit is used to enable the open-drain of the P62 pin Bit 1 (/OD61): Control bit is used to enable the open-drain of the P61 pin Bit 0 (/OD60): Control bit is used to enable the open-drain of the P60 pin Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 21 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.2.9 IOCD0 (Pull-high Control Register) 7 6 5 4 3 2 1 0 /PH57 /PH56 /PH55 /PH54 /PH53 /PH52 /PH51 /PH50 NOTE The IOCD0 register is both readable and writable Bit 7 (/PH57): Control bit is used to enable the pull-high of the P57 pin (applicable to EM78P260N only). 0 = Enable internal pull-high; 1 = Disable internal pull-high. Bit 6 (/PH56): Control bit is used to enable the pull-high of the P56 pin (applicable to EM78P260N only). Bit 5 (/PH55): Control bit is used to enable the pull-high of the P55 pin. Bit 4 (/PH54): Control bit is used to enable the pull-high of the P54 pin. Bit 3 (/PH53): Control bit is used to enable the pull-high of the P53 pin. Bit 2 (/PH52): Control bit is used to enable the pull-high of the P52 pin. Bit 1 (/PH51): Control bit is used to enable the pull-high of the P51 pin. Bit 0 (/PH50): Control bit is used to enable the pull-high of the P50 pin. 6.2.10 IOCE0 (WDT Control & Interrupt Mask Registers 2) 7 6 5 4 3 2 1 0 WDTE EIS ADIE CMPIE PSWE PSW2 PSW1 PSW0 Bit 7 (WDTE): Control bit is used to enable Watchdog Timer 0 = Disable WDT 1 = Enable WDT WDTE is both readable and writable Bit 6 (EIS): Control bit is used to define the function of the P60 (/INT) pin 0 = P60, bi-directional I/O pin 1 = /INT, external interrupt pin. In this case, the I/O control bit of P60 (Bit 0 of IOC60) must be set to "1" NOTE ■ When EIS is "0," the path of /INT is masked. When EIS is "1," the status of /INT pin can also be read by way of reading Port 6 (R6). Refer to Fig. 6-3 (I/O Port and I/O Control Register Circuit for P60(/INT)) under Section 6.4 (I/O Ports). ■ EIS is both readable and writable. 22 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 5 (ADIE): ADIF interrupt enable bit 0 = disable ADIF interrupt 1 = enable ADIF interrupt Bit 4 (CMPIE): CMPIF interrupt enable bit. 0 = disable CMPIF interrupt 1 = enable CMPIF interrupt Bit 3 (PSWE): Prescaler enable bit for WDT 0 = prescaler disable bit, WDT rate is 1:1 1 = prescaler enable bit, WDT rate is set as Bit2 ~ Bit0 Bit 2 ~ Bit 0 (PSW2 ~ PSW0): WDT prescaler bits 6.2.11 PSW2 PSW1 PSW0 WDT Rate 0 0 0 1:2 0 0 1 1:4 0 1 0 1:8 0 1 1 1:16 1 0 0 1:32 1 0 1 1:64 1 1 0 1:128 1 1 1 1:256 IOCF0 (Interrupt Mask Register) 7 6 5 4 3 2 1 0 LPWTIE HPWTIE TCCCIE TCCBIE TCCAIE EXIE ICIE TCIE NOTE ■ The IOCF0 register is both readable and writable ■ Individual interrupt is enabled by setting its associated control bit in the IOCF0 and in IOCE0 Bit 4 & 5 to "1". ■ Global interrupt is enabled by the ENI instruction and is disabled by the DISI instruction. Refer to Fig. 6-7 (Interrupt Input Circuit) under Section 6.6 (Interrupt). Bit 7 (LPWTIE): LPWTIF interrupt enable bit 0 = Disable LPWTIF interrupt 1 = Enable LPWTIF interrupt Bit 6 (HPWTIE): HPWTIF interrupt enable bit 0 = Disable HPWTIF interrupt 1 = Enable HPWTIF interrupt Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 23 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 5 (TCCCIE): TCCCIF interrupt enable bit 0 = Disable TCCCIF interrupt 1 = Enable TCCCIF interrupt Bit 4 (TCCBIE): TCCBIF interrupt enable bit 0 = Disable TCCBIF interrupt 1 = Enable TCCBIF interrupt Bit 3 (TCCAIE): TCCAIF interrupt enable bit 0 = Disable TCCAIF interrupt 1 = Enable TCCAIF interrupt Bit 2 (EXIE): EXIF interrupt enable bit 0 = Disable EXIF interrupt 1 = Enable EXIF interrupt Bit 1 (ICIE): ICIF interrupt enable bit 0 = Disable ICIF interrupt 1 = Enable ICIF interrupt Bit 0 (TCIE): TCIF interrupt enable bit. 0 = Disable TCIF interrupt 1 = Enable TCIF interrupt 6.2.12 IOC51 (TCCA Counter) IOC51 (TCCA) is an 8-bit clock counter. It can be read, written, and cleared on any reset condition and is an UP Counter. NOTE ■ TCCA timeout period [1/Fosc x (256-TCCA cnt) x 1(CLK=2)] ■ TCCA timeout period [1/Fosc x (256-TCCA cnt) x 2(CLK=4)] 6.2.13 IOC61 (TCCB Counter) An 8-bit clock counter is for the least significant byte of TCCBX (TCCB). It can be read, written, and cleared on any reset condition and is an UP Counter. 24 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.2.14 IOC71 (TCCBH/MSB Counter) An 8-bit clock counter is for the most significant byte of TCCBX (TCCBH). It can be read, written, and cleared on any reset condition. When TCCBHE (IOC90) is “0,” then TCCBH is disabled. When TCCBHE is”1,” then TCCB is a 16-bit length counter. NOTE When TCCBH is Disabled: ■ TCCB timeout period [1/Fosc x ( 256 - TCCB cnt ) x 1(CLK=2)] ■ TCCB timeout period [1/Fosc x ( 256 - TCCB cnt ) x 2(CLK=4)] When TCCBH is Enabled: ■ TCCB timeout period {1/Fosc x [ 65536 - (TCCBH * 256 + TCCB cnt)] x 1(CLK=2)} ■ TCCB timeout period {1/Fosc x [ 65536 - (TCCBH * 256 + TCCB cnt)] x 2(CLK=4)} 6.2.15 IOC81 (TCCC Counter) IOC81 (TCCC) is an 8-bit clock counter that can be extended to 16-bit counter. It can be read, written, and cleared on any reset condition. If HF (Bit 2 of IOCA0) = 1 and IRE (Bit 3 of IOCA0) = 1, TCCC counter scale uses the low-time segments of the pulse generated by Fcarrier frequency modulation (see Fig. 6-11 in Section 6.8.2, Function Description). Then TCCC value will be TCCC predict value. When HP = 0 or IRE = 0, the TCCC is an UP Counter. NOTE Under TCCC UP Counter mode: ■ TCCC timeout period [1/Fosc x scaler (IOCA0) x (256-TCCC cnt) x 1(CLK=2)] ■ TCCC timeout period [1/Fosc x scaler (IOCA0) x (256-TCCC cnt) x 2(CLK=4)] When HP = 1 and IRE = 1, TCCC counter scale uses the low-time segments of the pulse generated by Fcarrier frequency modulation. NOTE Under IR mode: ■ Fcarrier = FT/ 2 { [1+decimal TCCC Counter value (IOC81)] * TCCC Scale (IOCA0) } ■ FT is system clock: FT = Fosc/1 (CLK=2) FT = Fosc/2 (CLK=4) Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 25 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.2.16 IOC91 (Low-Time Register) The 8-bit Low-time register controls the active or Low segment of the pulse. The decimal value of its contents determines the number of oscillator cycles and verifies that the IR OUT pin is active. The active period of IR OUT can be calculated as follows: NOTE ■ Low time width = { [1+decimal low-time value (IOC91)] * Low time Scale(IOCB1) } / FT ■ FT is system clock: FT = Fosc/1 (CLK=2) FT = Fosc/2 (CLK=4) When an interrupt is generated by the Low time down counter underflow (when enabled), the next instruction will be fetched from address 015H (Low time). 6.2.17 IOCA1 (High Time Register) The 8-bit High-time register controls the inactive or High period of the pulse. The decimal value of its contents determines the number of oscillator cycles and verifies that the IR OUT pin is inactive. The inactive period of IR OUT can be calculated as follows: NOTE ■ High time width = {[1+decimal high-time value (IOCA1)] * High time Scale(IOCB1) } / FT ■ FT is system clock: FT=Fosc/1(CLK=2) FT=Fosc/2(CLK=4) When an interrupt is generated by the High time down counter underflow (when enabled), the next instruction will be fetched from address 012H (High time). 6.2.18 IOCB1 High/Low Time Scale Control Register) 7 6 5 4 3 2 1 0 HTSE HTS2 HTS1 HTS0 LTSE LTS2 LTS1 LTS0 Bit 7 (HTSE): High-time scale enable bit. 0 = scale disable bit, High-time rate is 1:1 1 = scale enable bit, High-time rate is set as Bit 6~Bit 4. 26 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 6 ~ Bit 4 (HTS2 ~ HTS0): High-time scale bits: HTS2 HTS1 HTS0 0 0 0 1:2 0 0 1 1:4 0 1 0 1:8 0 1 1 0 1 0 1:16 1:32 1 0 1 1:64 1 1 0 1:128 1 1 1 1:256 Bit 3 (LTSE): High-time rate Low-time scale enable bit. 0 = scale disable bit, Low-time rate is 1:1 1 = scale enable bit, Low-time rate is set as Bit 2~Bit 0. Bit 2 ~ Bit 0 (LTS2 ~ LTS0): Low-time scale bits: LTS2 LTS1 LTS0 Low-time rate 0 0 0 1:2 0 0 1 1:4 0 1 0 1:8 0 1 1 0 1 0 1:16 1:32 1 0 1 1:64 1 1 0 1:128 1 1 1 1:256 6.2.19 IOCC1 (TCC Prescaler Counter) TCC prescaler counter can be read and written: Bit 1 Bit 0 TCC Rate - - V 1:2 - V V 1:4 V V V V V V V 1:8 1:16 V V V V V 1:32 V V V V V V 1:64 V V V V V V 1:128 V V V V V V 1:256 PST2 PST1 PST0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 0 0 0 - - - - - 0 0 1 - - - - - 0 0 1 1 0 1 - - - - 1 0 0 - - - 1 0 1 - - 1 1 0 - V 1 1 1 V V V = valid value The TCC prescaler counter is assigned to TCC (R1). The contents of the IOCC1 register are cleared when one of the following occurs: a value is written to TCC register a value is written to TCC prescaler bits (Bit 3,2,1,0 of CONT) power on reset, /RESET WDT time out reset Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 27 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.3 TCC/WDT and Prescaler There are two 8-bit counters available as prescalers that can be extended to 16-bit counter for the TCC and WDT respectively. The PST2 ~ PST0 bits of the CONT register are used to determine the ratio of the TCC prescaler, and the PWR2 ~ PWR0 bits of the IOCE0 register are used to determine the WDT prescaler. The prescaler counter is cleared by the instructions each time such instructions are written into TCC. The WDT and prescaler will be cleared by the “WDTC” and “SLEP” instructions. Fig. 6-1 (next page) depicts the block diagram of TCC/WDT. TCC (R1) is an 8-bit timer/counter. The TCC clock source can be internal clock or external signal input (edge selectable from the TCC pin). If TCC signal source is from internal clock, TCC will increase by 1 at every instruction cycle (without prescaler). Referring to Fig. 6-1, CLK=Fosc/2 or CLK=Fosc/4 is dependent to the CODE Option bit <CLKS>. CLK=Fosc/2 if the CLKS bit is "0," and CLK=Fosc/4 if the CLKS bit is "1." If TCC signal source is from external clock input, TCC will increase by 1 at every falling edge or rising edge of the TCC pin. TCC pin input time length (kept in High or Low level) must be greater than 1CLK. NOTE The internal TCC will stop running when sleep mode occurs. However, during AD conversion, when TCC is set to “SLEP” instruction, if the ADWE bit of the RE register is enabled, the TCC will keep on running The watchdog timer is a free running on-chip RC oscillator. The WDT will keep on running even when the oscillator driver has been turned off (i.e., in sleep mode). During normal operation or sleep mode, a WDT time-out (if enabled) will cause the device to reset. The WDT can be enabled or disabled at any time during normal mode through software programming. Refer to WDTE bit of IOCE0 register (Section 6.2.10 IOCE0 (WDT Control & Interrupt Mask Registers 2). With no prescaler, the WDT time-out period is approximately 18ms1 or or 4.5ms2. 1 2 28 • VDD=5V, WDT time-out period = 16.5ms ± 30% VDD=3V, WDT time-out period = 18ms ± 30% VDD=5V, WDT time-out period = 4.2ms ± 30% VDD=3V, WDT time-out period = 4.5ms ± 30% Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM CLK (Fosc/2 or Fosc/4) Data Bus 0 TCC Pin 1 8-Bit Counter (IOCC1) MUX 8 to 1 MUX TE (CONT) Prescaler TS (CONT) WDT WDTE (IOCE0) 8-Bit counter 8 to 1 MUX WDT Time out SYNC 2 cycles TCC (R1) TCC overflow interrupt PSR2~0 (CONT) Prescaler PSW2~0 (IOCE0) Fig. 6-1 TCC and WDT Block Diagram 6.4 I/O Ports The I/O registers (Port 5, Port 6, and Port 7) are bi-directional tri-state I/O ports. Port 5 is pulled-high and pulled-down internally by software. Likewise, P6 has its open-drain output through software. Port 5 features an input status changed interrupt (or wake-up) function. Each I/O pin can be defined as "input" or "output" pin by the I/O control register (IOC5 ~ IOC7). The I/O registers and I/O control registers are both readable and writable. The I/O interface circuits for Port 5, Port 6, and Port7 are illustrated in Figures 6-2, 6-3, 6-4, & 6-5 (see next page). Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 29 EM78P259N/260N 8-Bit Microprocessor with OTP ROM PCRD PORT Q P R _ Q C L Q P R _ Q C L D CLK PCWR IOD D CLK PDWR PDRD 0 1 M U X NOTE: Open-drain is not shown in the figure. Fig. 6-2 I/O Port and I/O Control Register Circuit for Port 6 and Port7 PCRD Q P R D _ CLK Q C L Q P R D _ CLK Q C L PORT Bit 6 of IOCE D P R Q CLK _ C Q L 0 1 PCWR IOD PDWR M U X PDRD INT NOTE: Open-drain is not shown in the figure. Fig. 6-3 I/O Port and I/O Control Register Circuit for P60 (/INT) 30 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM PCRD Q P R D _ CLK Q C L PCWR P50 ~ P57 Q PORT 0 P R IOD D _ CLK Q C L PDWR M U X 1 PDRD TI n D P R CLK C L Q _ Q NOTE: Pull-high (down) is not shown in the figure. Fig. 6-4 I/O Port and I/O Control Register Circuit for Port 50 ~ P57 I O C F.1 R F.1 TI 0 TI 1 …. TI 8 Fig. 6-5 Port 5 Block Diagram with Input Change Interrupt/Wake-up Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 31 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.4.1 Usage of Port 5 Input Change Wake-up/Interrupt Function (1) Wake-up (2) Wake-up and Interrupt (a) Before SLEEP (a) Before SLEEP 1. Disable WDT 1. Disable WDT 2. Read I/O Port 5 (MOV R5,R5) 2. Read I/O Port 5 (MOV R5,R5) 3. Execute "ENI" or "DISI" 3. Execute "ENI" or "DISI" 4. Enable wake-up bit (Set RE ICWE =1) 4. Enable wake-up bit (Set RE ICWE =1) 5. Execute "SLEP" instruction 5. Enable interrupt (Set IOCF0 ICIE =1) (b) After wake-up 6. Execute "SLEP" instruction → Next instruction (b) After wake-up 1. IF "ENI" → Interrupt vector (006H) 2. IF "DISI" → Next instruction (3) Interrupt (a) Before Port 5 pin change 1. Read I/O Port 5 (MOV R5,R5) 2. Execute "ENI" or "DISI" 3. Enable interrupt (Set IOCF0 ICIE =1) (b) After Port 5 pin changed (interrupt) 1. IF "ENI" → Interrupt vector (006H) 2. IF "DISI" → Next instruction 6.5 RESET and Wake-up 6.5.1 RESET and Wake-up Operation A RESET is initiated by one of the following events: 1. Power-on reset 2. /RESET pin input "low" 3. WDT time-out (if enabled). The device is kept under RESET condition for a period of approximately 18ms3 (except in LXT mode) after the reset is detected. When in LXT mode, the reset time is 500ms. Two choices (18ms3 or 4.5ms4) are available for WDT-time out period. Once RESET occurs, the following functions are performed (the initial address is 000h): The oscillator continues running, or will be started (if under sleep mode) The Program Counter (R2) is set to all "0" 3 4 32 • VDD=5V, WDT Time-out period = 16.5ms ± 30%. VDD=3V, WDT Time-out period = 18ms ± 30%. VDD=5V, WDT Time-out period = 4.2ms ± 30%. VDD=3V, WDT Time-out period = 4.5ms ± 30%. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM All I/O port pins are configured as input mode (high-impedance state) The Watchdog Timer and prescaler are cleared When power is switched on, the upper 3 bits of R3 is cleared The CONT register bits are set to all "1" except for Bit 6 (INT flag) The IOCB0 register bits are set to all "1" The IOCC0 register bits are set to all "1" The IOCD0 register bits are set to all "1" Bits 7, 5, and 4 of IOCE0 register is cleared Bit 5 and 4 of RE register is cleared RF and IOCF0 registers are cleared Executing the “SLEP” instruction will assert the sleep (power down) mode. While entering into sleep mode, the Oscillator, TCC, TCCA, TCCB, and TCCC are stopped. The WDT (if enabled) is cleared but keeps on running. During AD conversion, when “SLEP” instruction I set; the Oscillator, TCC, TCCA, TCCB, and TCCC keep on running. The WDT (if enabled) is cleared but keeps on running. The controller can be awakened by: Case 1 External reset input on /RESET pin Case 2 WDT time-out (if enabled) Case 3 Port 5 input status changes (if ICWE is enabled) Case 4 Comparator output status changes (if CMPWE is enabled) Case 5 AD conversion completed (if ADWE enable) The first two cases (1 & 2) will cause the EM78P260N to reset. The T and P flags of R3 can be used to determine the source of the reset (wake-up). Cases 3, 4, & 5 are considered the continuation of program execution and the global interrupt ("ENI" or "DISI" being executed) decides whether or not the controller branches to the interrupt vector following wake-up. If ENI is executed before SLEP, the instruction will begin to execute from address 0x06 (Case 3), 0x0F (Case 4), and 0x0C (Case 5) after wake-up. If DISI is executed before SLEP, the execution will restart from the instruction next to SLEP after wake-up. Only one of Cases 1 to 5 can be enabled before entering into sleep mode. That is: Case [a] If WDT is enabled before SLEP, all of the RE bit is disabled. Hence, the EM78P259N/260N can be awakened only with Case 1 or Case 2. Refer to the section on Interrupt (Section 6.6 below) for further details. Case [b] If Port 5 Input Status Change is used to wake -up EM78P259N/260N and the ICWE bit of RE register is enabled before SLEP, WDT must be disabled. Hence, the EM78P259N/260N can be awakened only with Case 3. Wake-up time is dependent on oscillator mode. Under RC mode the reset time is 32 clocks (for oscillator stables). In High XTAL mode, reset time is 2ms and 32clocks (for oscillator stables) ; and in low XTAL mode, the reset time is 500ms. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 33 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Case [c] If Comparator output status change is used to wake-up the EM78P259N/ 260N and CMPWE bit of the RE register is enabled before SLEP, WDT must be disabled by software. Hence, the EM78P259N/260N can be awakened only with Case 4. Wake-up time is dependent on oscillator mode. Under RC mode the reset time is 32 clocks (for oscillator stables). In High XTAL mode, reset time is 2ms and 32clocks (for oscillator stables); and in low XTAL mode, the reset time is 500ms. Case [d] If AD conversion completed is used to wake-up the EM78P259N/260N and ADWE bit of RE register is enabled before SLEP, WDT must be disabled by software. Hence, the EM78P259N/260N can be awakened only with Case 5. The wake-up time is 15 TAD (ADC clock period). If Port 5 Input Status Change Interrupt is used to wake up the EM78P259N/260N (as in Case [b] above), the following instructions must be executed before SLEP: BC R3, 7 MOV A, @00xx1110b IOW IOCE0 WDTC MOV R5, R5 ENI (or DISI) MOV A, @xxxxxx1xb MOV RE MOV A, @xxxxxx1xb IOW IOCF0 SLEP ; Select Segment 0 ; Select WDT prescaler and Disable WDT ; ; ; ; Clear WDT and prescaler Read Port 5 Enable (or disable) global interrupt Enable Port 5 input change wake-up bit ; Enable Port 5 input change interrupt ; Sleep Similarly, if the Comparator Interrupt is used to wake up the EM78P259N/260N (as in Case [c] above), the following instructions must be executed before SLEP: BC MOV R3, 7 A, @xxx10XXXb IOW MOV IOC80 A, @00x11110b IOW IOCE0 WDTC ENI (or DISI) MOV A, @xxx0x1xxb MOV SLEP 34 • ; Select Segment 0 ; Select a comparator and P64 act as CO pin ; Select WDT prescaler and Disable WDT, and enable comparator output status change interrupt ; Clear WDT and prescaler ; Enable (or disable) global interrupt ; Enable comparator output status change wake-up bit RE ; Sleep Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.5.1.1 Wake-Up and Interrupt Modes Operation Summary All categories under Wake-up and Interrupt modes are summarized below. Signal Sleep Mode Normal Mode DISI + IOCF0 (EXIE) bit2=1 INT Pin N/A Next Instruction + Set RF (EXIF)=1 ENI + IOCF0 (EXIE) bit2=1 Interrupt Vector (003H) + Set RF (EXIF)=1 RE (ICWE) bit1=0, IOCF0 (ICIE) bit1=0 Oscillator, TCC, TCCX and IR/PWM are stopped. Port5 input status changed wake-up is invalid. IOCF0 (ICIE) bit1=0 Port5 input status change interrupted is invalid RE (ICWE) bit1=0, IOCF0 (ICIE) bit1=1 N/A Set RF (ICIF)=1, N/A Oscillator, TCC, TCCX and IR/PWM are stopped. Port5 input status changed wake-up is invalid. Port5 Input Status Change RE (ICWE) bit1=1, IOCF0 (ICIE) bit1=0 N/A Wake-up + Next Instruction N/A Oscillator, TCC, TCCX and IR/PWM are stopped. RE (ICWE) bit1=1, DISI + IOCF0 (ICIE) bit1=1 Wake-up + Next Instruction + Set RF (ICIF)=1 Oscillator, TCC, TCCX and IR/PWM are stopped. RE (ICWE) bit1=1, ENI + IOCF0 (ICIE) bit1=1 Wake-up + Interrupt Vector (006H) + Set RF (ICIF)=1 Oscillator, TCC, TCCX and IR/PWM are stopped. DISI + IOCF0 (ICIE) bit1=1 Next Instruction + Set RF (ICIF)=1 ENI + IOCF0 (ICIE) bit1=1 Interrupt Vector(006H)+ Set RF (ICIF)=1 DISI + IOCF0 (TCIE) bit0=1 TCC Over Flow N/A Next Instruction + Set RF (TCIF)=1 ENI + IOCF0 (TCIE) bit0=1 Interrupt Vector (009H) + Set RF (TCIF)=1 RE (ADWE) bit3=0, IOCE0 (ADIE) bit5=0 IOCE0 (ADIE) bit5=0 Clear R9 (ADRUN)=0, ADC is stopped, AD conversion wake-up is invalid. AD conversion interrupted is invalid Oscillator, TCC, TCCX and IR/PWM are stopped. RE (ADWE) bit3=0, IOCE0 (ADIE) bit5=1 N/A Set RF (ADIF)=1, R9 (ADRUN)=0, ADC is stopped, AD conversion wake-up is invalid. N/A Oscillator, TCC, TCCX and IR/PWM are stopped. RE (ADWE) bit3=1, IOCE0 (ADIE) bit5=0 AD Conversion N/A Wake-up + Next Instruction, Oscillator, TCC, TCCX and IR/PWM keep on running. N/A Wake-up when ADC completed. RE (ADWE) bit3=1, DISI + IOCE0 (ADIE) bit5=1 DISI + IOCE0 (ADIE) bit5=1 Wake-up + Next Instruction + RE (ADIF)=1, Oscillator, TCC, TCCX and IR/PWM keep on running. Next Instruction + RE (ADIF)=1 Wake-up when ADC completed. RE (ADWE) bit3=1, ENI + IOCE0 (ADIE) bit5=1 ENI + IOCE0 (ADIE) bit5=1 Wake-up + Interrupt Vector (00CH)+ RE (ADIF)=1, Oscillator, TCC, TCCX and IR/PWM keep on running. Interrupt Vector (00CH) + Set RE (ADIF)=1 Wake-up when ADC completed. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 35 EM78P259N/260N 8-Bit Microprocessor with OTP ROM RE (CMPWE) bit2=0, IOCE0 (CMPIE) bit4=0 Comparator output status changed wake-up is invalid. Oscillator, TCC, TCCX and IR/PWM are stopped. IOCF0 (CMPIE) bit4=0 Comparator output status change interrupted is invalid. RE (CMPWE) bit2=0, IOCE0 (CMPIE) bit4=1 N/A Set RE (CMPIF)=1, Comparator output status changed wake-up is invalid. Comparator (Comparator Output Status Change) N/A Oscillator, TCC, TCCX and IR/PWM are stopped. RE (CMPWE) bit2=1, IOCE0 (CMPIE) bit4=0 N/A Wake-up + Next Instruction, N/A Oscillator, TCC, TCCX and IR/PWM are stopped. RE (CMPWE) bit2=1, DISI + IOCE0 (CMPIE) bit4=1 Wake-up + Next Instruction + Set RE (CMPIF)=1, Oscillator, TCC, TCCX and IR/PWM are stopped. DISI + IOCE0 (CMPIE) bit4=1 Next Instruction + Set RE (CMPIF)=1 RE (CMPWE) bit2=1, ENI + IOCE0 (CMPIE) bit4=1 ENI + IOCE0 (CMPIE) bit4=1 Wake-up + Interrupt Vector (00FH) + Set RE (CMPIF)=1,Oscillator, TCC, TCCX and IR/PWM are stopped. Interrupt Vector (00FH) + Set RE (CMPIF)=1 DISI + IOCF0 (HPWTIF) bit6=1 IR/PWM underflow interrupt N/A Next Instruction + Set RF (HPWTIE)=1 (High-pulse width timer underflow interrupt) ENI + IOCF0 (HPWTIF) bit6 =1 IR/PWM underflow DISI + IOCF0 (LPWTIF) bit7=1 Interrupt Vector (012H) + Set RF (HPWTIE)=1 interrupt N/A (Low-pulse width timer underflow interrupt) Next Instruction + Set RF (LPWTIE)=1 ENI + IOCF0 (LPWTIF) bit7 =1 Interrupt Vector (015H) + Set RF (LPWTIE)=1 DISI + IOCF0 (TCCAIE) bit3=1 TCCA Over Flow N/A Next Instruction + Set RF (TCCAIF)=1 ENI + IOCF0 (TCCAIE) bit3=1 Interrupt Vector (018H) + Set RF (TCCAIF)=1 DISI + IOCF0 (TCCBIE) bit4=1 TCCB Over Flow N/A Next Instruction + Set RF (TCCBIF)=1 ENI + IOCF0 (TCCBIE) bit4=1 Interrupt Vector (01BH) + Set RF (TCCBIF)=1 DISI + IOCF0 (TCCCIE) bit5=1 TCCC Over Flow N/A Next Instruction + Set RF (TCCCIF)=1 ENI + IOCF0 (TCCCIE) bit5=1 Interrupt Vector (01EH) + Set RF (TCCCIF)=1 WDT Time Out IOCE (WDTE) bit7=1 36 • Wake-up + Reset (address 0x00) Reset (address 0x00) Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.5.1.2 Register Initial Values after Reset The following summarizes the initialized values for registers. Address Name Reset Type Bit Name Type N/A N/A N/A N/A IOC50 IOC60 IOC70 IOC80 IOC90 N/A N/A IOCA0 (IR CR) IOCB0 (PDCR) IOCC0 (ODCR) Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 C57 C56 C55 C54 C53 C52 C51 C50 – – – – – – 259 260 259 260 N N N N 0 1 0 1 1 1 1 1 1 1 /RESET and WDT 0 1 0 1 1 1 1 1 1 1 Wake-Up from Pin Change 0 P 0 P P P P P P P Bit Name C67 C66 C65 C64 C63 C62 C61 C60 Power-On 1 1 1 1 1 1 1 1 /RESET and WDT 1 1 1 1 1 1 1 1 Wake-Up from Pin Change P P P P P P P P Bit Name X X X X X X X C70 Power-On 0 0 0 0 0 0 0 1 /RESET and WDT 0 0 0 0 0 0 0 1 Wake-Up from Pin Change P P P P P P P P Bit Name X X CMPOUT COS1 COS0 TCCAEN TCCATS TCCATE Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P TCCBHE TCCBEN TCCBTS TCCBTE X TCCCEN TCCCTS TCCCTE Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P IRE HF LGP IROUTE Bit Name N/A Bit 6 Power-On Bit Name N/A Bit 7 TCCCSE TCCCS2 TCCCS1 TCCCS0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name /PD57 /PD56 /PD55 /PD54 /PD53 /PD52 /PD51 /PD50 Power-On 1 1 1 1 1 1 1 1 /RESET and WDT 1 1 1 1 1 1 1 1 Wake-Up from Pin Change P P P P P P P P Bit Name /OD67 /OD66 /OD65 /OD64 /OD63 /OD62 /OD61 /OD60 Power-On 1 1 1 1 1 1 1 1 /RESET and WDT 1 1 1 1 1 1 1 1 Wake-Up from Pin Change P P P P P P P P Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 37 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Address N/A N/A Name IOCD0 (PHCR) IOCE0 Reset Type Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Bit Name /PH57 /PH56 /PH55 /PH54 /PH53 /PH52 /PH51 /PH50 Power-On 1 1 1 1 1 1 1 1 /RESET and WDT 1 1 1 1 1 1 1 1 Wake-Up from Pin Change P P P P P P P P Bit Name WDTC EIS ADIE CMPIE PSWE PSW2 PSW1 PSW0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P EXIE ICIE TCIE Bit Name N/A N/A N/A IOCF0 IOC51 (TCCA) IOC61 (TCCB) Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name TCCA7 TCCA6 TCCA5 TCCA4 TCCA3 TCCA2 TCCA1 TCCA0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name TCCB7 TCCB6 TCCB5 TCCB4 TCCB3 TCCB2 TCCB1 TCCB0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name N/A N/A N/A 38 • IOC71 (TCCBH) IOC81 (TCCC) IOC91 (LTR) LPWTIE HPWTIE TCCCIE TCCBIE TCCAIE TCCBH7 TCCBH6 TCCBH5 TCCBH4 TCCBH3 TCCBH2 TCCBH1 TCCBH0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name TCCC7 TCCC6 TCCC5 TCCC4 TCCC3 TCCC2 TCCC1 TCCC0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name LTR7 LTR6 LTR5 LTR4 LTR3 LTR2 LTR1 LTR0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Address Name Reset Type Bit Name N/A N/A IOCA1 (HTR) IOCB1 (HLTS) N/A 0x00 0x01 0x02 IOCC1 (TCCPC) CONT R0(IAR) R1(TCC) R2(PC) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 HTR7 HTR6 HTR5 HTR4 HTR3 HTR2 HTR1 HTR0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name HTSE HTS2 HTS1 HTS0 LTSE LTS2 LTS1 LTS0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name N/A Bit 7 TCCPC7 TCCPC6 TCCPC5 TCCPC4 TCCPC3 TCCPC2 TCCPC1 TCCPC0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name INTE INT TS TE PSTE PST2 PST1 PST0 Power-On 1 0 1 1 0 0 0 0 /RESET and WDT 1 0 1 1 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name – – – – – – – – Power-On U U U U U U U U /RESET and WDT P P P P P P P P Wake-Up from Pin Change P P P P P P P P Bit Name – – – – – – – – Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 00 0 Wake-Up from Pin Change P P P P P P P P Bit Name – – – – – – – – Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change 0x03 R3(SR) Jump to address 0x06 or continue to execute next instruction Bit Name RST IOCS PS0 T P Z DC C Power-On 0 0 0 1 1 U U U /RESET and WDT 0 0 0 T t P P P Wake-Up from Pin Change P P P T t P P P Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 39 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Address 0x04 0x05 0x06 0x7 0x8 0x9 0xA Name R4(RSR) R5 R6 R7 R8 (AISR) R9 (ADCON) RA (ADOC) Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Bit Name Reset Type X BS X X X X X X Power-On 0 0 U U U U U U /RESET and WDT 0 0 P P P P P P Wake-Up from Pin Change 0 P P P P P P P Bit Name P57 P56 P55 P54 P53 P52 P51 P50 Power-On 1 1 1 1 1 1 1 1 /RESET and WDT 1 1 1 1 1 1 1 1 Wake-Up from Pin Change P P P P P P P P Bit Name P67 P66 P65 P64 P63 P62 P61 P60 Power-On 1 1 1 1 1 1 1 1 /RESET and WDT 1 1 1 1 1 1 1 1 Wake-Up from Pin Change P P P P P P P P Bit Name – – – – – – – P70 Power-On 0 0 0 0 0 0 0 1 /RESET and WDT 0 0 0 0 0 0 0 1 Wake-Up from Pin Change P P P P P P P P Bit Name – – – – ADE3 ADE2 ADE1 ADE0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change 0 0 0 0 P P P P Bit Name VREFS CKR1 CKR0 ADRUN ADPD – ADIS1 ADIS0 Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P 0 P P Bit Name CALI SIGN VOF[2] VOF[1] VOF[0] – – – Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P AD11 AD10 AD9 AD8 AD7 AD6 AD5 AD4 Bit Name 0XB 40 • RB Power-On (ADDATA) /RESET and WDT Wake-Up from Pin Change U U U U U U U U U U U U U U U U P P P P P P P P Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Address 0XC Name Reset Type RC (ADDATA1H) Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Bit Name “0” “0” “0” “0” AD11 AD10 AD9 AD8 Power-On 0 0 0 0 U U U U /RESET and WDT 0 0 0 0 U U U U Wake-Up from Pin Change 0 0 0 0 P P P P AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 Bit Name 0XD 0xE Power-On RD U U U U U U U U U U U U U U U U P P P P P P P P Bit Name –- – ADIF CMPIF ADWE CMPWE ICWE – Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P EXIF ICIF TCIF (ADDATA1L0) /RESET and WDT Wake-Up from Pin Change RE (ISR2) Bit Name 0xF 0x10~0x3F RF (ISR1) R10~R3F LPWTIF HPWTIF TCCCIF TCCBIF TCCAIF Power-On 0 0 0 0 0 0 0 0 /RESET and WDT 0 0 0 0 0 0 0 0 Wake-Up from Pin Change P P P P P P P P Bit Name – – – – – – – – Power-On U U U U U U U U /RESET and WDT P P P P P P P P Wake-Up from Pin Change P P P P P P P P Legend: X: not used P: previous value before reset U: unknown or don’t care. t: check table under Section 6.5.2 6.5.1.3 Controller Reset Block Diagram VDD D Oscillator Q CLK CLK CLR Power-On Reset Voltage Detector ENWDTB WDT Timeout WDT Setup time Reset /RESET Fig. 6-6 Controller Reset Block Diagram Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 41 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.5.2 The T and P Status under STATUS (R3) Register A RESET condition is initiated by one of the following events: 1. Power-on reset 2. /RESET pin input "low" 3. WDT time-out (if enabled). The values of RST, T, and P as listed in the table below, are used to check how the processor wakes up. Reset Type RST T P Power-on 0 1 1 /RESET during Operating mode 0 *P *P /RESET wake-up during SLEEP mode WDT during Operating mode 0 0 1 0 0 1 WDT wake-up during SLEEP mode 0 0 0 Wake-up on pin change during SLEEP mode 1 1 0 *P: Previous status before reset The following shows the events that may affect the status of T and P. Event RST T P Power-on 0 1 1 WDTC instruction *P 1 1 WDT time-out 0 0 *P SLEP instruction *P 1 0 Wake-up on pin changed during SLEEP mode 1 1 0 *P: Previous value before reset 6.6 Interrupt The EM78P259N/260N has six interrupts as listed below: 1. TCC, TCCA, TCCB, TCCC overflow interrupt 2. Port 5 Input Status Change Interrupt 3. External interrupt [(P60, /INT) pin] 4. Analog to Digital conversion completed 5. IR/PWM underflow interrupt 6. When the comparators status changes Before the Port 5 Input Status Change Interrupt is enabled, reading Port 5 (e.g. "MOV R5,R5") is necessary. Each Port 5 pin will have this feature if its status changes. The Port 5 Input Status Change Interrupt will wake-up the EM78P259N/260N from the sleep mode if it is enabled prior to going into the sleep mode by executing SLEP instruction. When wake-up occurs, the controller will continue to execute program in-line if the global interrupt is disabled. If enabled, the global interrupt will branch out to the interrupt vector 006H. 42 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM External interrupt equipped with digital noise rejection circuit (input pulse less than 8 system clocks time) is eliminated as noise. However, under Low XTAL oscillator (LXT) mode the noise rejection circuit will be disabled. Edge selection is possible with INTE of CONT. When an interrupt is generated by the External interrupt (when enabled), the next instruction will be fetched from address 003H. Refer to the Word 1 Bits 9 & 8 (Section 6.14.2, Code Option Register (Word1)) for digital noise rejection definition RF and RE are the interrupt status register that records the interrupt requests in the relative flags/bits. IOCF0 and IOCE0 are interrupt mask registers. The global interrupt is enabled by the ENI instruction and is disabled by the DISI instruction. Once in the interrupt service routine, the source of an interrupt can be determined by polling the flag bits in RF. The interrupt flag bit must be cleared by instructions before leaving the interrupt service routine to avoid recursive interrupts. The flag (except for the ICIF bit) in the Interrupt Status Register (RF) is set regardless of the ENI execution. Note that the result of RF will be the logic AND of RF and IOCF0 (refer to figure below). The RETI instruction ends the interrupt routine and enables the global interrupt (the ENI execution). When an interrupt is generated by the Timer clock/counter (when enabled), the next instruction will be fetched from Address 009, 018, 01B, and 01EH (TCC, TCCA, TCCB, and TCCC respectively). When an interrupt generated by the AD conversion is completed (when enabled), the next instruction will be fetched from Address 00CH. When an interrupt is generated by the High time / Low time down counter underflow (when enabled), the next instruction will be fetched from Address 012 and 015H (High time and Low time respectively). When an interrupt is generated by the Comparators (when enabled), the next instruction will be fetched from Address) 00FH (Comparator interrupt). Before the interrupt subroutine is executed, the contents of ACC and the R3 and R4 registers will be saved by the hardware. If another interrupt occurs, the ACC, R3, and R4 will be replaced by the new interrupt. After the interrupt service routine is completed, the ACC, R3, and R4 registers are restored. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 43 EM78P259N/260N 8-Bit Microprocessor with OTP ROM VCC P R CLK C L RF D /IRQn Q IRQn INT _ Q IRQm RFRD ENI/DISI P R Q IOCF _ Q C L IOD D CLK IOCFWR /RESET IOCFRD RFWR Fig. 6.7 Interrupt Input Circuit Interrupt sources ACC Interrupt occurs STACKACC ENI/DISI R3 RETI R4 STACKR3 STACKR4 Fig. 6.8 Interrupt Backup Diagram In EM78P259N/260N, each individual interrupt source has its own interrupt vector as depicted in the table below. Interrupt Vector Interrupt Status Priority* 003H External interrupt 1 006H Port 5 pin change 2 009H TCC overflow interrupt 3 00CH AD conversion complete interrupt 4 00FH Comparator interrupt 5 012H High-pulse width timer underflow interrupt 6 015H Low-pulse width timer underflow interrupt 7 018H TCCA overflow interrupt 8 01BH TCCB overflow interrupt 9 01EH TCCC overflow interrupt 10 *Priority: 1 = highest ; 10 = lowest priority 44 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.7 Analog-To-Digital Converter (ADC) The analog-to-digital circuitry consist of a 4-bit analog multiplexer; three control registers (AISR/R8, ADCON/R9, & ADOC/RA), three data registers (ADDATA/RB, ADDATA1H/RC, & ADDATA1L/RD), and an ADC with 12-bit resolution as shown in the functional block diagram below. The analog reference voltage (Vref) and the analog ground are connected via separate input pins. The ADC module utilizes successive approximation to convert the unknown analog signal into a digital value. The result is fed to the ADDATA, ADDATA1H, and ADDATA1L. Input channels are selected by the analog input multiplexer via the ADCON register Bits ADIS1 and ADIS0. Vref h c t i w S g o l a n A 1 8 ADC3 ADC2 ADC1 ADC0 Power-Down ADC ( successive approximation ) Start to Convert Fsco 4-1 MUX Internal RC 7 ~ 0 AISR 1 0 ADCON 6 3 5 ADCON 11 10 RF 9 8 ADDATA1H 7 6 4 5 3 2 0 1 4 3 ADCON ADDATA1L DATA BUS Fig. 6-9 Analog-to-Digital Conversion Functional Block Diagram 6.7.1 ADC Control Register (AISR/R8, ADCON/R9, ADOC/RA) 6.7.1.1 R8 (AISR: ADC Input Select Register) 7 6 5 4 3 2 1 0 – – – – ADE3 ADE2 ADE1 ADE0 AISR register defines the Port 5 pins as analog inputs or as digital I/O, individually. Bit 7 ~ 4: Not used Bit 3 (ADE3 ): AD converter enable bit of P53 pin 0 = Disable ADC3, P53 acts as I/O pin 1 = Enable ADC3 acts as analog input pin Bit 2 (ADE2 ): AD converter enable bit of P52 pin 0 = Disable ADC2, P53 acts as I/O pin 1 = Enable ADC2 acts as analog input pin Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 45 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 1 (ADE1 ): AD converter enable bit of P51 pin 0 = Disable ADC1, P51 acts as I/O pin 1 = Enable ADC1 acts as analog input pin Bit 0 (ADE0 ): AD converter enable bit of P50 pin 0 = Disable ADC0, P50 acts as I/O pin 1 = Enable ADC0 acts as analog input pin 6.7.1.2 R9 (ADCON: AD Control Register) 7 6 5 4 3 2 1 0 VREFS CKR1 CKR0 ADRUN ADPD - ADIS1 ADIS0 ADCON register controls the operation of the AD conversion and decides which pin should be currently active. Bit 7(VREFS): The input source of the ADC Vref 0 = The ADC Vref is connected to Vdd (default value), and the P54/VREF pin carries out the P54 function 1 = The ADC Vref is connected to P54/VREF NOTE The P54/TCC/VREF pin cannot be applied to TCC and VREF at the same time. IF P54/TCC/VREF acts as VREF analog input pin, then CONT Bit 5 (TS) must be “0”. The P54/TCC/VREF pin priority is as follows: P54/TCC/VREF Pin Priority High Medium Low VREF TCC P54 Bit 6 ~ Bit 5 (CKR1 ~ CKR0): The ADC prescaler oscillator clock rate 00 = 1: 4 (default value) 01 = 1: 16 10 = 1: 64 11 = 1: WDT ring oscillator frequency CKR0:CKR1 Operation Mode Max. Operation Frequency 46 • 00 Fsco/4 1 MHz 01 Fsco/16 4 MHz 10 Fsco/64 16MHz 11 Internal RC – Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 4 (ADRUN): ADC starts to RUN. 1 = an AD conversion is started. This bit can be set by software. 0 = reset on completion of the conversion. This bit cannot be reset though software. Bit 3 (ADPD): ADC Power-down mode. 1 = ADC is operating 0 = switch off the resistor reference to save power even while the CPU is operating. Bit 2: Not used Bit 1 ~ Bit 0 (ADIS1 ~ ADIS0): Analog Input Select 00 = ADIN0/P50 01 = ADIN1/P51 10 = ADIN2/P52 11 = ADIN3/P53 These bits can only be changed when the ADIF bit and the ADRUN bit are both LOW. 6.7.1.3 RA (ADOC: AD Offset Calibration Register) 7 6 5 4 3 2 1 0 CALI SIGN VOF[2] VOF[1] VOF[0] – – – Bit 7 (CALI): Calibration enable bit for ADC offset 0 = Calibration disable 1 = Calibration enable Bit 6 (SIGN): Polarity bit of offset voltage 0 = Negative voltage 1 = Positive voltage Bit 5 ~ Bit 3 (VOF[2] ~ VOF[0]): Offset voltage bits. VOF[2] VOF[1] VOF[0] EM78P259N/260N ICE259N 0 0 0 0LSB 0LSB 0 0 1 2LSB 1LSB 0 1 0 4LSB 2LSB 0 1 1 6LSB 3LSB 1 1 0 0 0 1 8LSB 10LSB 4LSB 5LSB 1 1 0 12LSB 6LSB 1 1 1 14LSB 7LSB Bit 2 ~ Bit 0: Unimplemented, read as ‘0’. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 47 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.7.2 ADC Data Register (ADDATA/RB, ADDATA1H/RC, ADDATA1L/RD) When the AD conversion is completed, the result is loaded to the ADDATA, ADDATA1H and ADDATA1L registers. The ADRUN bit is cleared, and the ADIF is set. 6.7.3 ADC Sampling Time The accuracy, linearity, and speed of the successive approximation of AD converter are dependent on the properties of the ADC and the comparator. The source impedance and the internal sampling impedance directly affect the time required to charge the sample holding capacitor. The application program controls the length of the sample time to meet the specified accuracy. Generally speaking, the program should wait for 2µs for each KΩ of the analog source impedance and at least 2µs for the low-impedance source. The maximum recommended impedance for analog source is 10KΩ at Vdd=5V. After the analog input channel is selected, this acquisition time must be done before the conversion is started. 6.7.4 AD Conversion Time CKR0 and CKR1 select the conversion time (Tct), in terms of instruction cycles. This allows the MCU to run at a maximum frequency without sacrificing the AD conversion accuracy. For the EM78P259N/260N, the conversion time per bit is about 4µs. The table below shows the relationship between Tct and the maximum operating frequencies. CKR0:CKR1 Operation Mode Max. Operation Frequency Max. Conversion Rate/Bit Max. Conversion Rate 00 Fsco/4 1 MHz 250kHz (4us) 15*4us=60us(16.7kHz) 01 Fsco/16 4MHz 250kHz (4us) 15*4us=60us(16.7kHz) 10 Fsco/64 16MHz 250kHz( 4us) 15*4us=60us(16.7kHz) 11 Internal RC – 14Kkz (71us) 15*71us=1065us(0.938kHz) NOTE ■ Pin not used as an analog input pin can be used as a regular input or output pin. ■ During conversion, do not perform output instruction to maintain precision for all of the pins. 6.7.5 ADC Operation during Sleep Mode In order to obtain a more accurate ADC value and reduce power consumption, the AD conversion remains operational during sleep mode. As the SLEP instruction is executed, all the MCU operations will stop except for the Oscillator, TCC, TCCA, TCCB, TCCC and AD conversion. The AD Conversion is considered completed as determined by: 1. ADRUN bit of R9 register is cleared (“0” value). 2. ADIF bit of RE register is set to “1”. 48 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 3. ADWE bit of the RE register is set to “1.” Wake-up from ADC conversion (where it remains in operation during sleep mode). 4. Wake-up and executes the next instruction if ADIE bit of IOCE0 is enabled and the “DISI” instruction is executed. 5. Wake-up and enters into Interrupt vector (address 0x00C) if ADIE bit of IOCE0 is enabled and the “ENI” instruction is executed. 6. Enters into Interrupt vector (address 0x00C) if ADIE bit of IOCE0 is enabled and the “ENI” instruction is executed. The results are fed into the ADDATA, ADDATA1H, and ADDATA1L registers when the conversion is completed. If the ADIE is enabled, the device will wake up. Otherwise, the AD conversion will be shut off, no matter what the status of ADPD bit is. 6.7.6 Programming Process/Considerations 6.7.6.1 Programming Process Follow these steps to obtain data from the ADC: 1. Write to the four bits (ADE3:ADE0) on the R8 (AISR) register to define the characteristics of R5 (digital I/O, analog channels, or voltage reference pin) 2. Write to the R9/ADCON register to configure the AD module: a) Select the ADC input channel (ADIS1:ADIS0) b) Define the AD conversion clock rate (CKR1:CKR0) c) Select the VREFS input source of the ADC d) Set the ADPD bit to 1 to begin sampling 3. Set the ADWE bit, if the wake-up function is employed 4. Set the ADIE bit, if the interrupt function is employed 5. Write “ENI” instruction, if the interrupt function is employed 6. Set the ADRUN bit to 1 7. Write “SLEP” instruction or Polling. 8. Wait for wake-up, ADRUN bit is cleared (“0” value), interrupt flag (ADIF) to be set “1,” or the ADC interrupt to occur. 9. Read the ADDATA or ADDATA1H and ADDATA1L conversion data registers. If the ADC input channel changes at this time, the ADDATA, ADDATA1H, and ADDATA1L values can be cleared to ‘0’. 10. Clear the interrupt flag bit (ADIF) Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 49 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 11. For the next conversion, go to Step 1 or Step 2 as required. At least 2 Tct is required before the next acquisition starts. NOTE In order to obtain accurate values, it is necessary to avoid any data transition on the I/O pins during AD conversion. 6.7.6.2 Sample Demo Programs A. Define a General Register R_0 == 0 PSW == 3 PORT5 == 5 PORT6 == 6 R_E== 0XE ; Indirect addressing register ; Status register ; Interrupt status register B. Define a Control Register IOC50 == 0X5 IOC60 == 0X6 C_INT== 0XF ; Control Register of Port 5 ; Control Register of Port 6 ; Interrupt Control Register C. ADC Control Register ADDATA == 0xB AISR == 0x08 ADCON == 0x9 ; The contents are the results of ADC ; ADC input select register ; 7 6 5 4 3 2 1 0 ; VREFS CKR1 CKR0 ADRUN ADPD ADIS2 ADIS1 ADIS0 D. Define Bits in ADCON ADRUN == 0x4 ADPD == 0x3 ; ADC is executed as the bit is set ; Power Mode of ADC E. Program Starts ORG 0 JMP INITIAL ; Initial address ; ORG 0x0C ; Interrupt vector JMP CLRRE ; ; ;(User program section) ; ; CLRRE: MOV A,RE AND A, @0BXX0XXXXX ; To clear the ADIF bit, “X” by application MOV RE,A BS ADCON, ADRUN ; To start to execute the next AD conversion if necessary RETI INITIAL: 50 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM MOV A,@0B00000001 MOV AISR,A MOV A,@0B00001000 MOV ADCON,A ; To define P50 as an analog input ; To select P50 as an analog input channel, and AD power on ; To define P50 as an input pin and set clock rate at fosc/16 En_ADC: MOV A, @0BXXXXXXX1 ; To define P50 as an input pin, and the others IOW PORT5 ; are dependent on applications MOV A, @0BXXXX1XXX ; Enable the ADWE wake-up function of ADC, “X” by application MOV RE,A MOV A, @0BXXXX1XXX ; Enable the ADIE interrupt function of ADC, “X” by application IOW C_INT ENI ; Enable the interrupt function BS ADCON, ADRUN ; Start to run the ADC ; If the interrupt function is employed, the following three lines may be ignored ;If Sleep: SLEP ; ;(User program section) ; or ;If Polling: POLLING: JBC ADCON, ADRUN JMP POLLING ; To check the ADRUN bit continuously; ; ADRUN bit will be reset as the AD conversion is completed ; ;(User program section) ; Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 51 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.8 Infrared Remote Control Application/PWM Waveform Generation 6.8.1 Overview This LSI can easily output infrared carrier or PWM standard waveform. As illustrated below, the IR and PWM waveform generation function include an 8-bit down count timer/counter, high-time, low-time, and IR control register. The IROUT pin waveform is determined by IOCA0 (IR and TCCC scale control register), IOCB1 (high-time rate, low-time rate control register), IOC81 (TCCC counter), IOCA1 (high-time register), and IOC91 (low-time register). FT:CLK(Fosc) 8 Bit counter 8 Bit counter 8-to-1 MUX 8-to-1 MUX 8bit binary down counter 8bit binary down counter 8 Bit counter Scale (IOCA0) Scale (IOCB1) Scale (IOCB1) 8-to-1 MUX Auto-reload buffer (High-time)(IOCA1) 8 8 Fcarrier 8 Auto-reload buffer (Low-time)(IOC91) 8 8bit binary down counter H/W Modulator 8 Auto-reload buffer (TCCC)(IOC81) HF LG IR IROUT Underflow Interrupt HPWTIF LPWTIF Fig. 6-10 IR/PWM System Block Diagram NOTE Details of the Fcarrier high time width and low time width are explained below: Fcarrier = FT/ 2 { [1+decimal TCCC Counter value (IOC81)] * TCCC Scale(IOCA0) } High time width = { [1+decimal high-time value (IOCA1)] * High time Scale(IOCB1) } / FT Low time width = { [1+decimal low-time value (IOC91)] * Low time Scale(IOCB1) } / FT Where FT is the system clock FT=Fosc/1(CLK=2) FT=Fosc/2(CLK=4) 52 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM When an interrupt is generated by the High time down counter underflow (when enabled), the next instruction will be fetched from address 018 and 01BH (High time and Low time respectively). 6.8.2 Function Description The following figure shows LGP=0 and HF=1. The IROUT waveform modulates the Fcarrier waveform at low-time segments of the pulse. Fcarrier low time width high time width HF low time width high time width start IRE IROUT Fig. 6-11a LGP=0, HF=1, IROUT Pin Output Waveform The following figure shows LGP=0 and HF=0. The IROUT waveform cannot modulate the Fcarrier waveform at low-time segments of the pulse. So IROUT waveform is determined by the high time width and low time width instead. This mode can produce standard PWM waveform Fcarrier low time width high time width low time width high time width HF start IRE IROUT Fig. 6-11b LGP=0, HF=0, IROUT Pin Output Waveform Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 53 EM78P259N/260N 8-Bit Microprocessor with OTP ROM The following figure shows LGP=0 and HF=1. The IROUT waveform modulates the Fcarrier waveform at low-time segments of the pulse. When IRE goes low from high, the output waveform of IROUT will keep transmitting till high-time interrupt occurs. Fcarrier low time width high time width low time width HF high time width start IR disable IRE IROUT Always high- level Fig. 6-11c LGP=0, HF=1, When IRE goes Low from High, IROUT Pin Outputs Waveform The following figure shows LGP=0 and HF=0. The IROUT waveform cannot modulate the Fcarrier waveform at low-time segments of the pulse. So IROUT waveform is determined by high time width and low time width. This mode can produce standard PWM waveform when IRE goes low from high. The output waveform of IROUT will keep on transmitting till high-time interrupt occurs. Fcarrier HF low time width high time width low time width high time width start IR disable IRE IROUT Always high-level Fig. 6-11d LGP=0, HF=0, When IRE goes Low from High, Irout Pin Output Waveform 54 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM The following figure shows LGP=1 and HF=1. When this bit is set to high level, the high-time segment of the pulse is ignored. So, IROUT waveform output is determined by low-time width. Fcarrier low time width HF low time width low time width high time width start IR disable IRE IROUT Always high-level Fig. 6-11e LGP=1 and HP=1, IROUT Pin Output Waveform 6.8.3 Programming the Related Registers When defining IR/PWM, refer to the operation of the related registers as shown in the tables below. IR/PWM Related Control Registers Address Name Bit 7 0x09 IOC90 TCCBHE TCCBEN/0 TCCBTS/0 TCCBTE/0 /0 0 0X0A IR CR /IOCA0 TCCCSE TCCCS2/0 TCCCS1/0 TCCCS0/0 /0 IRE/0 0x0F IMR /IOCF0 LPWTIE HPWTIE/0 TCCCIE/0 TCCBIE/0 TCCAIE/0 /0 0X0B HLTS /IOCB1 HTSE /0 Bit 6 HTS2/0 Bit 5 HTS1/0 Bit 4 HTS0/0 Bit 3 Bit 2 Bit 1 Bit 0 TCCCEN/0TCCCTS/0 TCCCTE/0 HF/0 LGP/0 IROUTE/0 EXIE/0 ICIE/0 TCIE/0 LTSE/0 LTS2/0 LTS1/0 LTS0/0 Bit 3 Bit 2 Bit 1 Bit 0 EXIF/0 ICIF/0 TCIF/0 IR/PWM Related Status/Data Registers Address Name Bit 7 Bit 6 Bit 5 0x0F ISR/RF LPWTIF/0 HPWTIF/0 TCCCIF/0 TCCBIF/0 TCCAIF/0 0x06 TCCC /IOC81 TCCC7/0 TCCC6/0 TCCC5/0 TCCC4/0 TCCC3/0 TCCC2/0 TCCC1/0 TCCC0/0 0X09 LTR /IOC91 LTR7/0 LTR6/0 LTR5/0 LTR4/0 LTR3/0 LTR2/0 LTR1/0 LTR0/0 0X0A HTR /IOCA1 HTR7/0 HTR6/0 HTR5/0 HTR4/0 HTR3/0 HTR2/0 HTR1/0 HTR0/0 Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) Bit 4 • 55 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.9 Timer/Counter 6.9.1 Overview TimerA (TCCA) is an 8-bit clock counter. TimerB (TCCB) is a 16-bit clock counter. TimerC (TCCC) is an 8-bit clock counter that can be extended to 16-bit clock counter with programmable scalers. TCCA, TCCB, and TCCC can be read and written to, and are cleared at every reset condition. 6.9.2 Function Description Set predict value Set predict value Set predict value TCCC TCCB TCCA Set TCCCIF Set TCCBIF Set TCCAIF Overflow Overflow Overflow System clock or External input TCCCEN TCCBEN TCCAEN System clock or External input 8-to-1 MUX TCCCS1 ~ TCCCS0 8 Bit counter System clock or External input Fig. 6.12 TIMER Block Diagram Each signal and block of the above TIMER block diagram is described as follows: TCCX: Timer A~C register. TCCX increases until it matches with zero, and then reload the predicted value. When writing a value to TCCX, the predicted value and TCCX value become the set value. When reading from TCCX, the value will be the TCCX direct value. When TCCXEN is enabled, the reload of the predicted value to TCCX, TCCXIE is also enabled. TCCXIF will be set at the same time. It is an up counter. Under TCCA Counter (IOC51): IOC51 (TCCA) is an 8-bit clock counter. It can be read, written, and cleared on any reset condition and is an UP Counter. NOTE ■ TCCA timeout period [1/Fosc x (256-TCCA cnt) x 1(CLK=2)] ■ TCCA timeout period [1/Fosc x (256-TCCA cnt) x 2(CLK=4)] Under TCCB Counter (IOC61): An 8-bit clock counter is for the least significant byte of TCCBX (TCCB). It can be read, written, and cleared on any reset condition and is an UP Counter. 56 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Under TCCBH / MSB Counter (IOC71): An 8-bit clock counter is for the most significant byte of TCCBX (TCCBH). It can be read, written, and cleared on any reset condition. When TCCBHE (IOC90) is “0,” then TCCBH is disabled. When TCCBHE is”1,” then TCCB is a 16-bit length counter. NOTE When TCCBH is Disabled: TCCB timeout period [1/Fosc x ( 256 - TCCB cnt ) x 1(CLK=2)] TCCB timeout period [1/Fosc x ( 256 - TCCB cnt ) x 2(CLK=4)] When TCCBH is Enabled: TCCB timeout period {1/Fosc x [ 65536 - (TCCBH * 256 + TCCB cnt)] x 1(CLK=2)} TCCB timeout period {1/Fosc x [ 65536 - (TCCBH * 256 + TCCB cnt)] x 2(CLK=4)} Under TCCC Counter (IOC81): IOC81 (TCCC) is an 8-bit clock counter. It can be read, written, and cleared on any reset condition. If HF (Bit 2 of IOCA0) = 1 and IRE (Bit 3 of IOCA0) = 1, TCCC counter scale uses the low-time segments of the pulse generated by Fcarrier frequency modulation (see Fig. 6-11 in Section 6.8.2, Function Description). Then the TCCC value will be the TCCC predicted value. When HP = 0 or IRE = 0, the TCCC is an UP Counter. NOTE Under TCCC UP Counter mode: ■ TCCC timeout period [1/Fosc x scaler (IOCA0) x (256-TCCC cnt) x 1(CLK=2)] ■ TCCC timeout period [1/Fosc x scaler (IOCA0) x (256-TCCC cnt) x 2(CLK=4)] When HP = 1 and IRE = 1, the TCCC counter scale uses the low-time segments of the pulse generated by Fcarrier frequency modulation. NOTE Under IR mode: ■ Fcarrier = FT/ 2 { [1+decimal TCCC Counter value (IOC81)] * TCCC Scale (IOCA0) } ■ FT is system clock: FT = Fosc/1 (CLK=2) FT = Fosc/2 (CLK=4) Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 57 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.9.3 Programming the Related Registers When defining TCCX, refer to the operation of its related registers as shown in the tables below. TCCX Related Control Registers: Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0x08 IOC80 0 0 CPOUT/0 COS1/0 COS0/0 TCCAEN TCCATS TCCATE /0 /0 /0 0x09 IOC90 TCCBHE TCCBEN TCCBTS TCCBTE /0 /0 /0 /0 0 TCCCEN TCCCTS TCCCTE /0 /0 /0 0x0A IR CR /IOCA0 TCCCSE TCCCS2 TCCCS1/ TCCCS0 /0 /0 0 /0 IRE/0 0x0F IMR /IOCF0 LPWTE/0 HPWTE/0 TCCCIE/0 TCCBIE/0 TCCAIE/0 HF/0 LGP/0 IROUTE/0 EXIE/0 ICIE/0 TCIE/0 Bit 2 Bit 1 Bit 0 EXIF/0 ICIF/0 TCIF/0 Related TCCX Status/Data Registers: Address Name Bit 7 Bit 6 0x0F ISR/RF LPWTF/0 HPWTF/0 TCCCIF/0 TCCBIF/0 TCCAIF/0 0x05 TCCA /IOC51 TCCA7/0 TCCA6/0 TCCA5/0 TCCA4/0 TCCA3/0 TCCA2/0 TCCA1/0 TCCA0/0 0x06 TCCB /IOC61 TCCB7/0 TCCB6/0 TCCB5/0 TCCB4/0 TCCB3/0 TCCB2/0 TCCB1/0 TCCB0/0 0x07 TCCBH /IOC71 TCCBH7 /0 0x08 TCCC /IOC81 TCCC7/0 TCCC6/0 TCCC5/0 TCCC4/0 TCCC3/0 TCCC2/0 TCCC1/0 TCCC0/0 TCCBH6 /0 Bit 5 Bit 4 TCCBH5 /0 Bit 3 TCCBH4 /0 TCCBH3 /0 TCCBH2 /0 TCCBH1 TCCBH0 /0 /0 6.10 Comparator EM78P259N/260N has one comparator which has two analog inputs and one output. The comparator can be employed to wake-up from the sleep mode. Figure below shows the circuit of the comparator. Cin CMP + Cin+ CO CinCin+ Output 30mV Fig. 6.13 Comparator Operating Mode 58 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.10.1 External Reference Signal The analog signal that is presented at Cin– compares to the signal at Cin+. The digital output (CO) of the comparator is adjusted accordingly by taking the following notes into considerations: NOTE ■ The reference signal must be between Vss and Vdd. ■ The reference voltage can be applied to either pin of the comparator. ■ Threshold detector applications may be of the same reference. ■ The comparator can operate from the same or different reference sources. 6.10.2 Comparator Outputs The compared result is stored in the CMPOUT of IOC80. The comparator outputs are sent to CO (P64) through programming Bit 4 & Bit 3<COS1, COS0> of the IOC80 register to <1,0>. See table under Section 6.2.4, IOC80 (Comparator and TCCA Control Registers) for Comparator/OP select bits function description. The following figure shows the Comparator Output block diagram. To C0 From OP I/O CMRD EN Q EN D Q D To CMPOUT RESET To CPIF CMRD From other comparator Fig. 6-14 The Output Configuration of a Comparator Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 59 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.10.3 Using a Comparator as an Operation Amplifier The comparator can be used as an operation amplifier if a feedback resistor is externally connected from the input to the output. In this case, the Schmitt trigger can be disabled for power saving purposes, by setting Bit 4, Bit 3<COS1, COS0> of the IOC80 register to <1,1>. See table under Section 6.2.4, IOC80 (Comparator and TCCA Control Registers) for Comparator/OP select bits function description. NOTE Under Operation Amplifier: ■ The CMPIE (IOCE0.4), CMPWE (RE.2), and CMPIF (RE.4) bits are invalid. ■ The comparator interrupt is invalid. ■ The comparator wake-up is invalid. 6.10.4 Comparator Interrupt CMPIE (IOCE0.4) must be enabled for the “ENI” instruction to take effect Interrupt is triggered whenever a change occurs on the comparator output pin The actual change on the pin can be determined by reading the Bit CMPOUT, IOC80<5>. CMPIF (RE.4), the comparator interrupt flag, can only be cleared by software 6.10.5 Wake-up from SLEEP Mode If the CMPWE bit of the RE register is set to “1,” the comparator remains active and the interrupt remains functional, even under SLEEP mode. If a mismatch occurs, the change will wake up the device from SLEEP mode. The power consumption should be taken into consideration for the benefit of energy conservation. If the function is unemployed during SLEEP mode, turn off the comparator before entering into sleep mode. The Comparator is considered completed as determined by: 1. COS1 and COS0 bits of IOC80 register setting selects Comparator. 2. CMPIF bit of RE register is set to “1”. 3. CMPWE bit of RE register is set to “1”. Wakes-up from Comparator (where it remains in operation during sleep mode) 4. Wakes-up and executes the next instruction, if CMPIE bit of IOCE0 is enabled and the “DISI” instruction is executed. 5. Wake-up and enters into Interrupt vector (address 0x00F), if ADIE bit of IOCE0 is enabled and the “ENI” instruction is executed 6. Enters into Interrupt vector (address 0x00F), if CMPIE bit of IOCE0 is enabled and the “ENI” instruction is executed. 60 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.11 Oscillator 6.11.1 Oscillator Modes The EM78P259N/260N can be operated in four different oscillator modes, such as High XTAL oscillator mode (HXT), Low XTAL oscillator mode (LXT), External RC oscillator mode (ERC), and RC oscillator mode with Internal RC oscillator mode (IRC). You can select one of them by programming the OSC2, OCS1, and OSC0 in the CODE Option register. The Oscillator modes defined by OSC2, OCS1, and OSC0 are described below. Oscillator Modes OSC2 OSC1 OSC0 1 0 0 0 1 0 0 1 0 1 0 ERC (External RC oscillator mode); P70/OSCO acts as P70 ERC (External RC oscillator mode); P70/OSCO acts as OSCO 2 IRC (Internal RC oscillator mode); P70/OSCO acts as P70 2 0 1 1 3 1 1 0 1 1 1 IRC (Internal RC oscillator mode); P70/OSCO acts as OSCO LXT (Low XTAL oscillator mode) 3 HXT High XTAL oscillator mode) (default) 1 Under ERC mode, OSCI is used as oscillator pin. OSCO/P70 is defined by code option WORD0 Bit6 ~ Bit4. 2 Under IRC mode, P55 is normal I/O pin. OSCO/P70 is defined by code option WORD0 Bit6 ~ Bit4. 3 Under LXT and HXT modes; OSCI and OSCO are used as oscillator pins. These pins cannot and should not be defined as normal I/O pins. NOTE The transient point of the system frequency between HXT and LXY is around 400kHz. The maximum operating frequency limit of crystal/resonator at different VDDs, are as follows: Conditions Two clocks Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) VDD Max. Freq. (MHz) 2.3 4 3.0 8 5.0 20 • 61 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.11.2 Crystal Oscillator/Ceramic Resonators (XTAL) The EM78P259N/260N can be driven by an external clock signal through the OSCI pin as illustrated below. OSCI EM78P259N EM78P260N OSCO Fig. 6-15 External Clock Input Circuit In most applications, Pin OSCI and Pin OSCO can be connected with a crystal or ceramic resonator to generate oscillation. Fig. 6-16 below depicts such circuit. The same applies to the HXT mode and the LXT mode. C1 OSCI EM78P259N EM78P260N XTAL OSCO RS C2 Fig. 6-16 Crystal/Resonator Circuit The following table provides the recommended values for C1 and C2. Since each resonator has its own attribute, you should refer to the resonator specifications for the appropriate values of C1 and C2. RS, a serial resistor, may be required for AT strip cut crystal or low frequency mode. Capacitor selection guide for crystal oscillator or ceramic resonators: Oscillator Type Frequency Mode Ceramic Resonators HXT LXT Crystal Oscillator HXT 62 • Frequency C1(pF) C2(pF) 455kHz 100~150 100~150 2.0 MHz 20~40 20~40 4.0 MHz 10~30 10~30 32.768kHz 25 15 100kHz 25 25 200kHz 25 25 455kHz 20~40 20~150 1.0 MHz 15~30 15~30 2.0 MHz 15 15 4.0 MHz 15 15 Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Circuit diagrams for serial and parallel modes Crystal/Resonator: 330 330 C OSCI 7404 7404 EM78P259N EM78P260N 7404 XTAL Fig. 6-17 Serial Mode Crystal/Resonator Circuit Diagram 4.7K 7404 10K Vdd O SC I EM 78P259N EM 78P260N 10K 7404 XTAL C1 10K C2 Fig. 6-18 Parallel Mode Crystal/Resonator Circuit Diagram 6.11.3 External RC Oscillator Mode For some applications that do not require precise timing calculation, the RC oscillator (Fig. 6-19 right) could offer you with effective 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. Vcc Rext OSCI EM78P259N EM78P260N Cext Fig. 6-19 External RC Oscillator Mode Circuit In order to maintain a stable system frequency, the values of the Cext should be no less than 20pF, and that of Rext should be no greater than 1MΩ. If the frequency cannot be kept within this range, the frequency can be affected easily by noise, humidity, and leakage. The smaller the Rext in the RC oscillator is, the faster its frequency will be. On the contrary, for very low Rext values, for instance, 1 KΩ, the oscillator will become unstable because the NMOS cannot discharge the capacitance current correctly. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 63 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Based on the above reasons, it must be kept in mind that all supply voltage, the operation temperature, the components of the RC oscillator, the package types, and the way the PCB is layout, have certain effect on the system frequency. The RC Oscillator frequencies: Cext 20 pF 100 pF 300 pF Rext Average Fosc 5V,25°C Average Fosc 3V,25°C 3.3k 3.5 MHz 3.2 MHz 5.1k 2.5 MHz 2.3 MHz 10k 1.30 MHz 1.25 MHz 100k 140 KHz 140kHz 3.3k 1.27 MHz 1.21 MHz 5.1k 850kHz 820kHz 10k 450kHz 450kHz 100k 48kHz 50kHz 3.3k 560kHz 540kHz 5.1k 370kHz 360kHz 10k 196kHz 192kHz 100k 20kHz 20kHz NOTE: 1. Measured on DIP packages 2. Design reference only 3. The frequency drift is about ±30% 6.11.4 Internal RC Oscillator Mode EM78P259N/260N offers a versatile internal RC mode with default frequency value of 4MHz. Internal RC oscillator mode has other frequencies (1MHz, 8MHz, and 455kHz) that can be set by CODE OPTION (WORD1), RCM1, and RCM0. The Table below describes the EM78P259N/260N internal RC drift with voltage, temperature, and process variation. Internal RC Drift Rate (Ta=25℃, VDD=5V±5%, VSS=0V) Internal RC Frequency Drift Rate Temperature (-40℃~+80℃) Voltage (2.3V~5.5V) Process Total 4MHz ±10% ±5% ±4% ±19% 8MHz ±10% ±6% ±4% ±20% 1MHz ±10% ±5% ±4% ±19% 455MHz ±10% ±5% ±4% ±19% Theoretical values, for reference only. Actual values may vary depending on the actual process. 64 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.12 Power-On Considerations Any microcontroller is not warranted to start operating properly before the power supply stabilizes in steady state. The EM78P259N/260N POR voltage range is 1.9 ~ 2.1V. Under customer application, when power is switched OFF, Vdd must drop below 1.9V and remains at OFF state for 10µs before power can be switched ON again. Subsequently, the EM78P259N/260N will reset and work normally. The extra external reset circuit will work well if Vdd rises fast enough (50ms or less). However, under critical applications, extra devices are still required to assist in solving power-on problems. 6.12.1 Programmable WDT Time-Out Period The Option word (WDTPS) is used to define the WDT time-out period (18ms5 or 4.5ms6). Theoretically, the range is from 4.5ms or 18ms. For most crystal or ceramic resonators, the lower the operation frequency is, the longer is the required set-up time. 6.12.2 External Power-on Reset Circuit The circuit shown in the following figure implements an external RC to produce a reset pulse. The pulse width (time constant) should be kept long enough to allow Vdd to reach the minimum operating voltage. This circuit is used when the power supply has a slow power rise time. Because the current leakage from the /RESET pin is about ±5µA, it is recommended that R should not be greater than 40 K. This way, the voltage at Pin /RESET is held below 0.2V. The diode (D) acts as a short circuit at power-down. The “C” capacitor is discharged rapidly and fully. Rin, the current-limited resistor, prevents high current discharge or ESD (electrostatic discharge) from flowing into Pin /RESET. Vdd R EM78P259N EM78P260N D /RESET Rin C Fig. 6-20 External Power-on Reset Circuit 5 VDD=5V, WDT time-out period = 16.5ms ± 30%. VDD=3V, WDT time-out period = 18ms ± 30%. 6 VDD=5V, WDT time-out period = 4.2ms ± 30%. VDD=3V, WDT time-out period = 4.5ms ± 30%. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 65 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.12.3 Residual Voltage Protection When the battery is replaced, device power (Vdd) is removed but the residual voltage remains. The residual voltage may trip below Vdd minimum, but not to zero. This condition may cause a poor power-on reset. Fig. 6-21 and Fig. 6-22 show how to create a protection circuit against residual voltage. Vdd Vdd EM78P259N EM78P260N 33K Q1 10K /RESET 100K 1N4684 Fig. 6-21 Residual Voltage Protection Circuit 1 Vdd Vdd EM78P259N EM78P260N R1 Q1 /RESET R3 R2 Fig. 6-22 Residual Voltage Protection Circuit 2 66 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM 6.13 Code Option EM78P259N/260N has two CODE option words and one Customer ID word that are not part of the normal program memory. Word 0 Word1 Word 2 Bit12 ~ Bit0 Bit12 ~ Bit0 Bit12 ~ Bit0 6.13.1 Code Option Register (Word 0) WORD 0 Bit 12 Bit 11 Bit 10 – – – Bit 9 Bit 8 Bit 7 TYPE CLKS ENWDTB Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 OSC2 OSC1 OSC0 HLP PR2 PR1 PR0 Bit 12 ~ 10: Not used (reserved). These bits are set to “1” all the time Bit 9 (TYPE): Type selection for EM78P259N or EM78P260N 0 = EM78P260N 1 = EM78P259N (default) Bit 8 (CLKS): Instruction period option bit 0 = two oscillator periods 1 = four oscillator periods (default) Refer to Section 6.15 for Instruction Set Bit 7 (ENWDTB): Watchdog timer enable bit 0 = Enable 1 = Disable (default) Bit 6, 5 & 4 (OSC2, OSC1 & OSC0): Oscillator Modes Selection bits Oscillator Modes 1 ERC (External RC oscillator mode); P70/OSCO acts as P70 1 ERC (External RC oscillator mode); P70/OSCO acts as OSCO OSC2 OSC1 OSC0 0 0 0 0 0 1 2 0 1 0 2 0 1 1 3 1 1 0 1 1 1 IRC (Internal RC oscillator mode); P70/OSCO acts as P70 IRC (Internal RC oscillator mode); P70/OSCO acts as OSCO LXT (Low XTAL oscillator mode) 3 HXT High XTAL oscillator mode) (default) 1 Under ERC mode, OSCI is used as oscillator pin. OSCO/P70 is defined by code option WORD0 Bit6 ~ Bit4. 2 Under IRC mode, P55 is normal I/O pin. OSCO/P70 is defined by code option WORD0 Bit6 ~ Bit4. 3 Under LXT and HXT modes; OSCI and OSCO are used as oscillator pins. These pins cannot and should not be defined as normal I/O pins. NOTE The transient point of the system frequency between HXT and LXY is around 400kHz. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 67 EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 3 (HLP): Power consumption selection 0 = Low power consumption, applies to working frequency at or below 4MHz 1 = High power consumption, applies to working frequency above 4MHz Bit 2 ~ 0 (PR2 ~ PR0): Protect Bits PR2 ~ PR0 are protect bits. Each protect status is as follows: PR2 PR1 PR0 Protect 0 0 0 Enable 0 0 1 Enable 0 1 0 Enable 0 1 1 Enable 1 0 0 Enable 1 0 1 Enable 1 1 0 Enable 1 1 1 Disable 6.13.2 Code Option Register (Word 1) WORD 1 Bit 12 Bit 11 Bit 10 - - Bit 9 Bit 8 RCOUT NRHL NRE Bit 7 Bit 6 WDTPS CYES Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 C3 C2 C1 C0 RCM1 RCM0 Bits 12 ~ 11: Not used (reserved). These bits are set to “1” all the time Bit 10 (RCOUT): System clock output enable bit in IRC or ERC mode 0 = OSCO pin is open drain 1 = OSCO output system clock Bit 9 (NRHL): Noise rejection high/low pulses define bit. INT pin is falling edge trigger 0 = Pulses equal to 8/fc [s] is regarded as signal 1 = Pulses equal to 32/fc [s] is regarded as signal (default) NOTE The noise rejection function is turned off under the LXT and sleep mode. Bit 8 (NRE): Noise rejection enable 0 = disable noise rejection 1 = enable noise rejection (default), but under Low XTAL oscillator (LXT) mode, the noise rejection circuit is always disabled. 68 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Bit 7 (WDTPS): WDT Time-out Period Selection bit WDT Time Watch-Dog Time* 1 18 ms 0 4.5 ms *Theoretical values, for reference only Bit 6 (CYES): Instruction cycle selection bit 0 = one instruction cycle. 1 = two instructions cycle (default) Bit 5, 4, 3, & Bit 2 (C3, C2, C1, C0): Calibrator of internal RC mode C3, C2, C1, & C0 must be set to “1” only (auto-calibration). Bit 1 & Bit 0 (RCM1, RCM0): RC mode selection bits RCM 1 RCM 0 Frequency (MHz) 1 1 4 1 0 8 0 1 1 0 0 455kHz 6.13.3 Customer ID Register (Word 2) WORD 2 Bit 12 Bit 11 Bit 10 X X X Bit 9 Bit 8 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 X X X X X X X X X X Bit 12 ~ 0 : Customer’s ID code 6.14 Instruction Set Each instruction in the instruction set is a 13-bit word divided into an OP code and one or more operands. Normally, all instructions are executed within one single instruction cycle (one instruction consists of 2 oscillator periods), unless the program counter is changed by instructions "MOV R2,A," "ADD R2,A," or by instructions of arithmetic or logic operation on R2 (e.g., "SUB R2,A," "BS(C) R2,6," "CLR R2," etc.). In this case, these instructions need one or two instruction cycles as determined by Code Option Register CYES bit. 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 registers can be regarded as general registers. That is, the same instruction can operate on I/O registers. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 69 EM78P259N/260N 8-Bit Microprocessor with OTP ROM The symbol "R" represents a register designator that specifies which of the registers (including operational registers and general-purpose registers) is to be utilized by the instruction. The symbol "b" represents a bit field designator that selects the value for the bit located in the register "R" that is affected by the operation. The symbol "k" represents an 8 or 10-bit constant or literal value. The following are the EM78P259N/260N instruction set Instruction Binary HEX Mnemonic 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 70 • 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0001 0001 0001 0001 0010 0010 0010 0010 0011 0011 0011 0011 0100 0100 0100 0100 0101 0101 0101 0101 0110 0110 0110 0110 0111 0111 0111 0000 0000 0000 0000 0000 0000 0001 0001 0001 0001 0001 0001 01rr 1000 11rr 00rr 01rr 10rr 11rr 00rr 01rr 10rr 11rr 00rr 01rr 10rr 11rr 00rr 01rr 10rr 11rr 00rr 01rr 10rr 11rr 00rr 01rr 10rr 11rr 00rr 01rr 10rr 0000 0001 0010 0011 0100 rrrr 0000 0001 0010 0011 0100 rrrr rrrr 0000 rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr rrrr 0000 0001 0002 0003 0004 000r 0010 0011 0012 0013 0014 001r 00rr 0080 00rr 01rr 01rr 01rr 01rr 02rr 02rr 02rr 02rr 03rr 03rr 03rr 03rr 04rr 04rr 04rr 04rr 05rr 05rr 05rr 05rr 06rr 06rr 06rr 06rr 07rr 07rr 07rr NOP DAA CONTW SLEP WDTC IOW R ENI DISI RET RETI CONTR IOR R MOV R,A CLRA CLR R SUB A,R SUB R,A DECA R DEC R OR A,R OR R,A AND A,R AND R,A XOR A,R XOR R,A ADD A,R ADD R,A MOV A,R MOV R,R COMA R COM R INCA R INC R DJZA R DJZ R RRCA R RRC R RLCA R RLC R SWAPA R SWAP R JZA R Operation No Operation Decimal Adjust A A → CONT 0 → WDT, Stop oscillator 0 → WDT A → IOCR Enable Interrupt Disable Interrupt [Top of Stack] → PC [Top of Stack] → PC, Enable Interrupt CONT → A IOCR → A A→R 0→A 0→R R-A → A R-A → R R-1 → A R-1 → R A ∨ VR → A A ∨ VR → R A&R→A A&R→R A⊕R→A A⊕R→R A+R→A A+R→R R→A R→R /R → A /R → R R+1 → A R+1 → R R-1 → A, skip if zero R-1 → R, skip if zero R(n) → A(n-1),R(0) → C, C → A(7) 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) R(0-3) ↔ R(4-7) R+1 → A, skip if zero Status Affected None C None T,P T,P 1 None None None None None None 1 None None Z Z Z,C,DC Z,C,DC Z Z Z Z Z Z Z Z Z,C,DC Z,C,DC Z Z Z Z Z Z None None C C C C None None None Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM Instruction Binary HEX Mnemonic 0 0 0 0 0 1 1 1 1 1 1 1 1 1 7 0111 100b 101b 110b 111b 00kk 01kk 1000 1001 1010 1011 1100 1101 1111 11rr bbrr bbrr bbrr bbrr kkkk kkkk kkkk kkkk kkkk kkkk kkkk kkkk kkkk rrrr rrrr rrrr rrrr rrrr kkkk kkkk kkkk kkkk kkkk kkkk kkkk kkkk kkkk 07rr 0xxx 0xxx 0xxx 0xxx 1kkk 1kkk 18kk 19kk 1Akk 1Bkk 1Ckk 1Dkk 1Fkk Operation Status Affected JZ R R+1 → R, skip if zero None 2 BC R,b 0 → R(b) None 3 BS R,b 1 → R(b) None JBC R,b if R(b)=0, skip None JBS R,b if R(b)=1, skip None CALL k PC+1 → [SP],(Page, k) → PC None JMP k (Page, k) → PC None MOV A,k k→A None OR A,k A∨k→A Z AND A,k A&k→A Z XOR A,k A⊕k→A Z RETL k k → A,[Top of Stack] → PC None SUB A,k k-A → A Z,C,DC ADD A,k k+A → A Z,C,DC 1 This instruction is applicable to IOC50 ~ IOCF0, IOC51 ~ IOCC1 only. 2 This instruction is not recommended for RF operation. 3 This instruction cannot operate under RF. Absolute Maximum Ratings Items Rating Temperature under bias -40°C to 85°C Storage temperature -65°C to 150°C Input voltage Vss-0.3V to Vdd+0.5V Output voltage Vss-0.3V to Vdd+0.5V Working Voltage 2.5V to 5.5V Working Frequency DC to 20MHz Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 71 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 8 DC Electrical Characteristics (Ta=25 °C, VDD=5.0V±5%, VSS=0V) Symbol Parameter XTAL: VDD to 5V Fxt XTAL: VDD to 3V Condition Min Two cycle with two clocks Typ Max Unit DC 20 MHz DC 8 MHz ERC: VDD to 5V R: 5.1KΩ, C: 100 pF F±30% 830 F±30% kHz IRC: VDD to 5 V 8MHz,4MHz, 1MHz, 455kHz F±30% F F±30% Hz IRC1 IRC:VDD to 5V RCM0:RCM1=1:1 3.84 4.0 4.16 MHz IRC2 IRC:VDD to 5V RCM0:RCM1=1:0 7.68 8.0 8.32 MHz IRC3 IRC:VDD to 5V RCM0:RCM1=0:1 0.96 1.0 1.06 MHz IRC4 436.8 455 473.2 kHz IRC:VDD to 5V RCM0:RCM1=0:0 Input High Threshold VIHRC Voltage (Schmitt trigger ) OSCI in RC mode 3.5 V VILRC Input Low Threshold Voltage (Schmitt trigger ) OSCI in RC mode 1.5 V IIL Input Leakage Current for input pins VIN = VDD, VSS VIH1 Input High Voltage (Schmitt trigger ) Ports 5, 6, 7 3.75 V VIL1 Input Low Voltage (Schmitt Ports 5, 6, 7 trigger ) 1.25 V VIHT1 Input High Threshold Voltage (Schmitt trigger ) /RESET 2.0 V VILT1 Input Low Threshold Voltage (Schmitt trigger ) /RESET 1.0 V VIHT2 Input High Threshold Voltage (Schmitt trigger ) TCC,INT 3.75 V VILT2 Input Low Threshold Voltage (Schmitt trigger ) TCC,INT 1.25 V VIHX1 Clock Input High Voltage OSCI in crystal mode 3.5 V VILX1 Clock Input Low Voltage OSCI in crystal mode 1.5 V IOH1 Output High Voltage (Ports 5, P60~66,P70) VOH = VDD-0.5V -3.7 mA IOH2 Output High Voltage (IR OUT (Port67)) VOH = VDD-0.5V -10 mA IOL1 Output Low Voltage (Ports 5, P60~66,P70) VOL = GND+0.5V 10 mA IOL2 Output Low Voltage (IR OUT (Port67)) VOL = GND+0.5V 15 mA IPH Pull-high current Pull-high active, input pin at VSS -70 -75 -80 µA IPL Pull-low current Pull-low active, input pin at Vdd 35 40 45 µA ISB1 Power down current All input and I/O pins at VDD, output pin floating, WDT disabled 1.0 2.0 µA ISB2 Power down current All input and I/O pins at VDD, output pin floating, WDT enabled 6.0 10 µA ICC1 Operating supply current at two clocks (VDD to 3V) /RESET= 'High', Fosc=32kHz (Crystal type,CLKS="0"), output pin floating, WDT disabled 15 20 µA 72 • -1 0 1 µA Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM ICC2 Operating supply current at two clocks (VDD to 3V) /RESET= 'High', Fosc=32kHz (Crystal type,CLKS="0"), output pin floating, WDT enabled 15 25 µA ICC3 Operating supply current at two clocks /RESET= 'High', Fosc=4MHz (Crystal type, CLKS="0"), output pin floating, WDT enabled 1.9 2.2 mA ICC4 Operating supply current at two clocks /RESET= 'High', Fosc=10MHz (Crystal type, CLKS="0"), output pin floating, WDT enabled 3.0 3.5 mA NOTE: 8.1 1. These parameters are hypothetical (not tested) and are provided for design reference use only. 2. Data under minimum, typical, & maximum (Min, Typ, & Max) columns are based on hypothetical results at 25℃. These data are for design reference only. AD Converter Characteristics (Vdd=2.5V to 5.5V, Vss=0V, Ta=25℃) Symbol VAREF VASS VAI Analog reference voltage Condition VAREF - VASS≧2.5V Analog input voltage – Min. Typ. Max. Unit 2.5 – Vdd V Vss – Vss V VASS – VAREF V Analog supply current Vdd=VAREF=5.0V, VASS =0.0V (V referenced from Vdd) 750 850 1000 uA –10 0 +10 uA Analog supply current Vdd=VAREF=5.0V, VASS=0.0V (V referenced from VREF) 500 600 820 uA 200 250 300 uA IOP OP current Vdd=5.0V, OP used Output voltage swing 0.2V to 4.8V 450 550 650 uA RN Resolution Vdd=VAREF=5.0V, VASS =0.0V 10 11 – Bits LN Linearity error Vdd = 2.5 to 5.5V Ta=25℃ 0 ±4 ±8 LSB DNL Differential nonlinear error Vdd = 2.5 to 5.5V Ta=25℃ 0 ±0.5 ±0.9 LSB FSE Full scale error Vdd=VAREF=5.0V, VASS =0.0V ±0 ±4 ±8 LSB OE Offset error Vdd=VAREF=5.0V, VASS =0.0V ±0 ±2 ±4 LSB ZAI Recommended impedance of analog voltage source 0 8 10 KΩ TAD ADC clock period Vdd=VAREF=5.0V, VASS =0.0V 4 – – us TCN AD conversion time Vdd=VAREF=5.0V, VASS =0.0V 15 – 15 TAD ADIV ADC OP input voltage range Vdd=VAREF=5.0V, VASS =0.0V 0 – VAREF V ADOV ADC OP output voltage swing Vdd=VAREF=5.0V, VASS =0.0V, RL=10KΩ 0 0.2 0.3 4.7 4.8 5 ADSR ADC OP slew rate Vdd=VAREF=5.0V, VASS =0.0V 0.1 0.3 – V/us Power Supply Rejection Vdd=5.0V±0.5V ±0 – ±2 LSB IAI1 IAI2 Ivdd Parameter Ivref Ivdd IVref PSR NOTE: – V 1. These parameters are hypothetical (not tested) and are provided for design reference use only. 2. There is no current consumption when ADC is off other than minor leakage current. 3. AD conversion result will not decrease when an increase of input voltage and no missing code will result. Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 73 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 8.2 Comparator (OP) Characteristics (Vdd = 5.0V, Vss=0V, Ta=25℃) Symbol Parameter Condition SR Slew rate IVR Input voltage range Vdd =5.0V, VSS =0.0V OVS Output voltage swing Vd =5.0V, VSS =0.0V, RL=10KΩ Iop Supply current of OP Ico Supply current of Comparator PSR R Vs Power-supply Rejection Ration for OP 8.3 Typ. 0.1 0.2 0 Max. Vdd= 5.0V, VSS =0.0V 0 0.2 0.3 4.7 4.8 5 250 350 500 50 60 2.5 Unit V/us 5 300 Operating range NOTE: Min. V V uA uA 70 dB 5.5 V These parameters are hypothetical (not tested) and are provided for design reference only. Device Characteristics The graphs below were derived based on a limited number of samples and they are provided for reference only. Hence, the device characteristic shown herein cannot be guaranteed as fully accurate. In these graphs, the data maybe out of the specified operating warranted range. IRC OSC Frequency (VDD=3V) 9 Frequency (M Hz) 8 7 6 5 4 3 2 1 0 -40 -20 0 25 50 70 85 Temperature (℃) Fig. 8-1 Internal RC OSC Frequency vs. Temperature, VDD=3V 74 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM IRC OSC Frequency (VDD=5V) 10 9 Frequency (M Hz) 8 7 6 5 4 3 2 1 0 -40 -20 0 25 50 70 85 Temperature (℃) Fig. 8-2 Internal RC OSC Frequency vs. Temperature, VDD=5V 9 AC Electrical Characteristic (Ta=25 °C, VDD=5V±5%, VSS=0V) Symbol Parameter Conditions Min Typ Max Unit 45 50 55 % Dclk Input CLK duty cycle Tins Instruction cycle time (CLKS="0") Ttcc TCC input period Tdrh Device reset hold time Ta = 25°C 11.3 Trst /RESET pulse width Ta = 25°C 2000 Twdt Watchdog timer period Ta = 25°C 11.3 Tset Input pin setup time Thold Input pin hold time Tdelay Output pin delay time Tdrc ERC delay time NOTE: Crystal type 100 DC ns RC type 500 DC ns (Tins+20)/N* ns 16.2 21.6 ms ns 16.2 21.6 0 ms ns 15 20 25 ns Cload=20pF 45 50 55 ns Ta = 25°C 1 3 5 ns 1. N = selected prescaler ratio 2. Twdt1: The Option word1 (WDTPS) is used to define the oscillator set-up time. WDT timeout length is the same as set-up time (18ms). 3. Twdt2: The Option word1 (WDTPS) is used to define the oscillator set-up time. WDT timeout length is the same as set-up time (4.5ms). 4. These parameters are hypothetical (not tested) and are provided for design reference only. 5. Data under minimum, typical, & maximum (Min, Typ, & Max) columns are based on hypothetical results at 25℃. These data are for design reference use only. 6. The Watchdog timer duration is determined by code option Word1 (WDTPS). Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 75 EM78P259N/260N 8-Bit Microprocessor with OTP ROM 10 Timing Diagrams AC Test Input/Output Waveform VDD-0.5V 0.75VDD 0.25VDD TEST POINTS 0.75VDD 0.25VDD GND+0.5V AC Testing : Input is driven at VDD-0.5V for logic "1",and GND+0.5V for logic "0".Timing measurements are made at 0.75VDD for logic "1",and 0.25VDD for logic "0". RESET Timing (CLK="0") NOP Instruction 1 Executed CLK /RESET Tdrh TCC Input Timing (CLKS="0") Tins CLK TCC Ttcc 76 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM APPENDIX A. Package Types Summary OTP MCU Package Type Pin Count Package Size EM78P259NP DIP 18 300mil EM78P259NM SOP 18 300mil EM78P260NP DIP 20 300mil EM78P260NM SOP 20 300mil SSOP 20 209mil EM78P260NKM B Packaging Configurations B.1 18-Lead Plastic Dual in line (PDIP) — 300 mil Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 77 EM78P259N/260N 8-Bit Microprocessor with OTP ROM B.2 18-Lead Plastic Small Outline (SOP) — 300 mil 78 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM B.3 20-Lead Plastic Shrink Small Outline (SSOP) — 209 mil Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 79 EM78P259N/260N 8-Bit Microprocessor with OTP ROM B.4 20-Lead Plastic Dual-in-line (PDIP) — 300 mil 80 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) EM78P259N/260N 8-Bit Microprocessor with OTP ROM B.5 20-Lead Plastic Small Outline (SOPP) — 300 mil Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice) • 81 EM78P259N/260N 8-Bit Microprocessor with OTP ROM C Quality Assurance and Reliability Test Category Test Conditions Remarks Solder temperature=245±5℃, for 5 seconds up to the stopper using a rosin-type flux Solderability Step 1: TCT, 65℃ (15mins)~150℃ (15mins), 10 cycles Step 2: Bake at 125℃, TD (durance)=24 hrs Step 3: Soak at 30°C/60%,TD (durance)=192 hrs Pre-condition For SMD IC (such as SOP, QFP, SOJ, etc) Step 4: IR flow 3 cycles (Pkg thickness≧2.5mm or Pkg volume≧350mm3 ----225±5℃) (Pkg thickness≦2.5mm or Pkg volume≦350mm3 ----240±5℃ ) Temperature cycle test -65℃ (15mins)~150℃ (15mins), 200 cycles Pressure cooker test TA =121℃, RH=100%, pressure=2 atm, TD (durance)= 96 hrs High temperature / High humidity test TA=85℃ , RH=85%,TD (durance)=168 , 500 hrs High-temperature storage life TA=150℃, TD (durance)=500, 1000 hrs High-temperature operating life TA=125℃, VCC=Max. operating voltage, TD (durance) =168, 500, 1000 hrs Latch-up TA=25℃, VCC=Max. operating voltage, 150mA/20V ESD (HBM) TA=25℃, ≧∣± 3KV∣ IP_ND,OP_ND,IO_ND IP_NS,OP_NS,IO_NS IP_PD,OP_PD,IO_PD, IP_PS,OP_PS,IO_PS, ESD (MM) TA=25℃, ≧∣± 300V∣ VDD-VSS(+),VDD_VSS (-)mode C.1 Address Trap Detect An address trap detect is one of the MCU embedded fail-safe functions that detects MCU malfunction caused by noise or the like. Whenever the MCU attempts to fetch an instruction from a certain section of ROM, an internal recovery circuit is auto started. If a noise caused address error is detected, the MCU will repeat execution of the program until the noise is eliminated. The MCU will then continue to execute the next program. 82 • Product Specification (V1.0) 06.16.2005 (This specification is subject to change without further notice)