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EM78P350N
8-Bit Microprocessor with OTP ROM
Product Specification
DOC. VERSION 1.0
ELAN MICROELECTRONICS CORP.
September 2006
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 (c) 2006 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: No. 12, Innovation Road 1 Hsinchu Science Park Hsinchu, Taiwan 30077 Tel: +886 3 563-9977 Fax: +886 3 563-9966 http://www.emc.com.tw Hong Kong: Elan (HK) Microelectronics Corporation, Ltd. Flat A, 19F., World Tech Centre 95 How Ming Street, Kwun Tong Kowloon , HONG KONG Tel: +852 2723-3376 Fax: +852 2723-7780 elanhk@emc.com.hk Shenzhen: Elan Microelectronics Shenzhen, Ltd. SSMEC Bldg., 3F, Gaoxin S. Ave. Shenzhen Hi-Tech Industrial Park Shenzhen, Guandong, CHINA Tel: +86 755 2601-0565 Fax: +86 755 2601-0500 USA: Elan Information Technology Group (USA) 1821 Saratoga Ave., Suite 250 Saratoga, CA 95070 USA Tel: +1 408 366-8225 Fax: +1 408 366-8220
Europe: Elan Microelectronics Corp. (Europe) Siewerdtstrasse 105 8050 Zurich, SWITZERLAND Tel: +41 43 299-4060 Fax: +41 43 299-4079 http://www.elan-europe.com
Shanghai: Elan Microelectronics Shanghai, Ltd. 23/Bldg. #115 Lane 572, Bibo Road Zhangjiang Hi-Tech Park Shanghai, CHINA Tel: +86 21 5080-3866 Fax: +86 21 5080-4600
Contents
Contents
1 2 3 4 5 General Description .................................................................................................. 1 Features ..................................................................................................................... 1 Pin Assignment ......................................................................................................... 2 Functional Block Diagram........................................................................................ 3 Pin Description.......................................................................................................... 4 5.1 6 EM78P350.......................................................................................................... 4 5.2 EM78P351.......................................................................................................... 5 Function Description ................................................................................................ 6 6.1 Operational Registers......................................................................................... 6
6.1.1 6.1.2 6.1.3 R0 (Indirect Address Register) ...........................................................................6 R1 (Time Clock/Counter).....................................................................................6 R2 (Program Counter) and Stack........................................................................6 6.1.3.1 Data Memory Configuration..................................................................8 6.1.4 R3 (Status Register) ............................................................................................9 6.1.5 R4 (RAM Select Register)...................................................................................9 6.1.6 R5 ~ R8 (Port 5 ~ Port 8) ..................................................................................10 6.1.7 R9 (TMR4: Timer 4 Register) ............................................................................10 6.1.8 RA (SPIRB: SPI Read Buffer) ...........................................................................10 6.1.9 RB (SPIWB: SPI Write Buffer)...........................................................................10 6.1.10 RC (SPIS: SPI Status Register) ........................................................................10 6.1.11 RD (SPIC: SPI Control Register) ......................................................................11 6.1.12 RE (WUCR: Wake-up Control Register) ...........................................................12 6.1.13 RF (Interrupt Status Register) ...........................................................................13 6.1.14 R10 ~ R3F .........................................................................................................14 6.1.15 Bank 1 R5 (PWM Control Register #1) .............................................................14 6.1.16 Bank 1 R6 (PWM Control Register 2) ...............................................................15 6.1.17 Bank 1 R7 (PWM Timer/Counter Control Register) ..........................................16 6.1.18 Bank 1 R8 (PRD1H: Most Significant Byte of PWM1 Time Period) ..................16 6.1.19 Bank 1 R9 (PRD2H: Most Significant Byte of PWM2 Time Period) ..................16 6.1.20 Bank 1 RA (PRD3H: Most Significant Byte of PWM3 Time Period) ..................16 6.1.21 Bank 1 RB (PRDL: Least Significant Bits of PWM Period Cycle) .....................17 6.1.22 Bank 1 RC (DT1H: Most Significant Byte of PWM1 Duty Cycle)......................17 6.1.23 Bank 1 RD (DT2H: Most Significant Byte of PWM2 Duty Cycle)......................17 6.1.24 Bank 1 RE (DT3H: Most Significant Byte of PWM3 Duty Cycle) ......................17 6.1.25 Bank 1 RF (DTL: Least Significant Bits of PWM Duty Cycle) ...........................17 6.1.26 Bank 2 R6 (BOCON: Buzzer Output Control Register).....................................18 6.1.27 Bank 2 R7 (System Control Register) ...............................................................19 6.1.28 Bank 2 R8 (AISR: ADC Input Select Register)..................................................20 6.1.29 Bank 2 R9 (ADCON: ADC Control Register) ....................................................21 6.1.30 Bank 2 RA (ADOC: ADC Offset Calibration Register).......................................22 6.1.31 Bank 2 RB (ADDATA: Converted Value of ADC)................................................23
Product Specification (V1.0) 09.14.2006 *iii
Contents
6.1.32 Bank 2 RC (ADDATA1H: Converted Value of ADC ) ..........................................23 6.1.33 Bank 2 RD (ADDATA1L: Converted Value of ADC ) ..........................................23 6.1.34 Bank 2 RE (LVDC: LVD Control Register ).........................................................24 6.1.35 Bank 2 RF (TMR3H: Most Significant Bits of PWM3 Timer) ..............................24 6.1.36 Bank 3 R5 (Pull-low Control Register 1).............................................................24 6.1.37 Bank 3 R6 (Pull-low Control Register 2).............................................................25 6.1.38 Bank 3 R7 (Pull-low Control Register 3).............................................................25 6.1.39 Bank 3 R8 (Pull-low Control Register 4).............................................................26 6.1.40 Bank 3 R9 (Pull-high Control Register 1) ...........................................................26 6.1.41 Bank 3 RA (Pull-high Control Register 2) ..........................................................26 6.1.42 Bank 3 RB (Pull-high Control Register 3)...........................................................27 6.1.43 Bank 3 RC (Pull-high Control Register 4)...........................................................27 6.1.44 Bank 3 RD (TMR1H: Most Significant Bits of PWM1 Timer).............................28 6.1.45 Bank 3 RE (TMR2H: Most Significant Bits of PWM2 Timer).............................28 6.1.46 Bank 3 RF (TMRL: Least Significant Bits of PWM Timer).................................28
6.2
Special Purpose Registers .............................................................................. 28
6.2.1 6.2.2 6.2.3 6.2.4 6.2.5 6.2.6 6.2.7 A (Accumulator).................................................................................................28 CONT (Control Register)...................................................................................28 IOC5 ~ IOC8 (I/O Port Control Register) ..........................................................29 IOC9 (T4CON: Timer 4 Control Register) .........................................................29 IOCA (TCMPCON: Comparator Control Register)............................................30 IOCE (WDT Control Register) ...........................................................................30 IOCF (Interrupt Mask Register).........................................................................32
6.3 6.4 6.5
TCC/WDT and Prescaler.................................................................................. 33 I/O Ports ........................................................................................................... 34
6.4.1 6.5.1 6.5.2 6.5.3 6.5.4 6.5.5 6.5.6 Usage of Port 6 Input Change Wake-up/Interrupt Function..............................37 Overview and Features .....................................................................................37 SPI Function Description..................................................................................39 SPI Signal and Pin Description .........................................................................41 Programming the Related Registers .................................................................42 SPI Mode Timing ...............................................................................................45 SPI Software Application ...................................................................................46 Overview ...........................................................................................................48 Function Description..........................................................................................48 Programming the Related Registers .................................................................49 Reset and Wake-up Operation..........................................................................50 6.7.1.1 Wake-up and Interrupt Mode Operation Summary.............................53 6.7.1.2 Register Initial Values after Reset.......................................................55 6.7.1.3 Controller Reset Block Diagram .........................................................62 The T and P Status under Status Register ........................................................63
Product Specification (V1.0) 09.14.2006
Serial Peripheral Interface Mode...................................................................... 37
6.6
Timer 4 ............................................................................................................. 48
6.6.1 6.6.2 6.6.3
6.7
Reset and Wake-up.......................................................................................... 50
6.7.1
6.7.2
iv*
Contents
6.8 6.9
Interrupt ............................................................................................................ 63 Analog-to-Digital Converter (ADC) ................................................................... 65
6.9.1 ADC Control Register........................................................................................65 6.9.1.1 Bank 2 R8 (AISR: ADC Input Select Register) ...................................65 6.9.1.2 Bank 2 R9 (ADCON: ADC Control Register) ......................................66 6.9.1.3 Bank 2 RA (ADOC: ADC Offset Calibration Register) ........................68 ADC Data Register............................................................................................68 ADC Sampling Time ..........................................................................................68 AD Conversion Time .........................................................................................68 ADC Operation during Sleep Mode...................................................................69 Programming Process/Considerations..............................................................69 6.9.6.1 Programming Process ........................................................................69 6.9.6.2 Sample Demo Programs ....................................................................70 Overview ...........................................................................................................72 Increment Timer Counter ..................................................................................73 PWM Time Period (PRDX : PRD1 or PRD2) ....................................................73 PWM Duty Cycle ...............................................................................................74 Comparator X ....................................................................................................74 PWM Programming Process/Steps...................................................................74
6.9.2 6.9.3 6.9.4 6.9.5 6.9.6
6.10 Dual Sets of PWM (Pulse Width Modulation) ................................................... 72
6.10.1 6.10.2 6.10.3 6.10.4 6.10.5 6.10.6
6.11 Timer ................................................................................................................ 74
6.11.1 Overview ...........................................................................................................74 6.11.2 Function Description..........................................................................................75 6.11.3 Programming the Related Registers .................................................................76 6.11.3.1 Related Control Registers of TMR1, TMR2, and TMR3 .....................76 6.11.4 Timer Programming Process/Steps...................................................................76
6.12 Comparator ...................................................................................................... 76
6.12.1 6.12.2 6.12.3 6.12.4 6.12.5 6.13.1 6.13.2 6.13.3 6.13.4 External Reference Signal ................................................................................77 Comparator Outputs..........................................................................................77 Using Comparator as an Operation Amplifier....................................................78 Comparator Interrupt .........................................................................................78 Wake-up from Sleep Mode................................................................................78 Oscillator Modes................................................................................................78 Crystal Oscillator/Ceramic Resonators (Crystal)...............................................79 External RC Oscillator Mode.............................................................................80 Internal RC Oscillator Mode ..............................................................................81
6.13 Oscillator .......................................................................................................... 78
6.14 Power-on Considerations ................................................................................. 82
6.14.1 External Power-on Reset Circuit .......................................................................82 6.14.2 Residual Voltage Protection ..............................................................................83
6.15 LVD (Low Voltage Detector) ............................................................................. 84
Product Specification (V1.0) 09.14.2006
*v
Contents
6.16 Code Option ..................................................................................................... 85
6.16.1 Code Option Register (Word 0).........................................................................85 6.16.2 Code Option Register (Word 1).........................................................................87 6.15.3 Customer ID Register (Word 2).........................................................................88
7 8
6.17 Instruction Set ................................................................................................. 88 Absolute Maximum Ratings ................................................................................... 90 DC Electrical Characteristics ................................................................................. 91 8.1 8.2 AD Converter Characteristic............................................................................. 92 Comparator (OP) Characteristic ....................................................................... 92
9 10
8.3 Device Characteristics...................................................................................... 93 AC Electrical Characteristic ................................................................................... 94 Timing Diagrams ..................................................................................................... 95
APPENDIX
A B Package Type........................................................................................................... 96 Packaging Configurations...................................................................................... 96 B.1 28-Lead Plastic Dual in line (PDIP) -- 600 mil ................................................. 96 B.2 28-Lead Plastic Small Outline (SOP) -- 300 mil .............................................. 97 B.3 28-Lead Plastic Dual in line (PDIP) -- 400 mil ................................................ 98 B.4 28-Lead Plastic Dual in line (PDIP) -- 300 mil ................................................ 99 B.5 32-LQFP -- 7x7m2 ....................................................................................... 100 B.6 32-Lead Plastic Dual in line (PDIP) --400 mil ................................................ 101 B.7 32-Lead Plastic Dual in line (PDIP) --600 mil ................................................ 102 C B.8 32-Lead Plastic Small Outline (SOP) -- 300 mil ............................................ 103 Quality Assurance and Reliability ..................................................................... 104 C.1 Address Trap Detect....................................................................................... 104
Specification Revision History
Doc. Version 1.0 Revision Description Preliminary version Date 2006/09/14
vi*
Product Specification (V1.0) 09.14.2006
EM78P350N
8-Bit Microprocessor with OTP ROM
1
General Description
The EM78P350N is an 8-bit microprocessors designed and developed with low-power and high-speed CMOS technology. It has an on-chip 8Kx13-bit Electrical One Time Programmable Read Only Memory (OTP-ROM). It provides a protection bit to prevent intrusion of user's OTP memory code. Three Code option bits are also available to meet user's requirements. With its enhanced OTP-ROM feature, the EM78P350N provides a convenient way of developing and verifying user's programs. Moreover, this OTP device offers the advantages of easy and effective program updates, using development and programming tools. User can avail of the ELAN Writer to easily program his development code.
2
Features
CPU configuration
*
4 programmable Level Voltage Detector (LVD) : 4.5V, 4.0V, 3.3V, 2.2V
* * * * * * * * * * * * * * * *
8Kx13 bits on chip ROM 144x8 bits on chip registers (SRAM) 8 level stacks for subroutine nesting
IRC mode: Oscillation mode : 4MHz, 8MHz, 1MHz, 455kHz Process deviation : Typ3%, Max5% Temperature deviation : 10% (-40C~85C ) Sub clock Crystal: 32.768kHz Serial peripheral interface (SPI) available 8-bit real time clock/counter (TCC) with selective signal sources, trigger edges, and overflow interrupt 8-bit channels Analog-to-Digital Converter with 12-bit resolution Three Pulse Width Modulation (PWM ) with 10-bit resolution One pair of comparators or OP
Peripheral configuration
4 programmable Level Voltage Reset (LVR) : 4.0V, 3.5V, 2.7V, 1.8V (POR) Less than 2.2 mA at 5V/4MHz Typically 15 A, at 3V/32kHz Typically 1 A, during sleep mode
* * * * * * * * * * * * * * * * * *
I/O port configuration 4 bidirectional I/O ports : P5, P6, P7, P8 29 I/O pins Wake-up port : P6 29 Programmable pull-down I/O pins 29 programmable pull-high I/O pins External interrupt : P52, P53
Eight available interrupts: TCC overflow interrupt Input-port status changed interrupt (wake-up from sleep mode) Two External interrupt ADC completion interrupt PWM time period match completion interrupt Comparator high/low interrupt Serial I/O interrupt Low voltage detect (LVD)
Operating voltage range: OTP version: Operating voltage range 2.1V~5.5V
Mask ROM version: Operating voltage range: 1.8V~5.5V
Operating temperature range: -40~85 Operating frequency range: Main clock Crystal mode: DC ~ 20MHz/2clks @ 5V; DC ~100ns inst. cycle @ 5V DC ~ 8MHz/2clks @ 3V;DC ~ 250ns inst. cycle @ 3V ERC mode: DC ~ 16MHz/2clks @ 5V; DC ~ 125ns inst. cycle @ 5V DC ~ 8MHz/2clks @ 3V; DC ~ 250ns inst. cycle @ 3V
Special features Programmable free running watchdog timer High ESD immunity High EFT immunity Power saving Sleep mode Selectable Oscillation mode 600mil 300mil 400mil 300mil 400mil 600mil 300mil EM78P350NP EM78P350NM EM78P350NK EM78P350NAK EM78P351NQ EM78P351NK EM78P351NP EM78P351NM
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*
Package types: 28 pin DIP 28 pin SOP 28 pin SDIP 28 pin SDIP 32 pin LQFP 32 pin SDIP 32 pin DIP 32 pin SOP l
3
Pin Assignment
*1
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
(1)
28-Pin DIP/SOP
(2)
32-Pin QFP
Fig. 3-1 28-pin DIP/SOP
Fig. 3-2 32-pin QFP
(3)
32-Pin SOP/SDIP/DIP
Fig. 3-1 32-pin DIP/SOP
2*
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
4
P8
P80 P81 P82 P83 P84
Functional Block Diagram
ROM PC
Ext. OSC. Int. RC Ext. RC
Start-up Timer WDT
Instruction Register
8-level stack (13 bit)
Oscillation Generation
PWM1 (Timer 1) PWM2 (Timer 2) PWM3 (Timer 3) Buzzer SPI
PWM1 PWM2 PWM3 Buzzer Out
Sin Sout SCK
P7
P70 P71 P72 P73 P74 P75 P76 P77
Instruction Decoder
Sub OSC
Reset
ALU
Mux .
TCC CNTR 1 CNTR 2
TCC CNTR1 CNTR2
P6
P60 P61 P62 P63 P64 P65 P66 P67
R4
RAM ACC R3 (Status Reg.) Interrupt Control Register
LVD
LVR
P5
P50 P51 P52 P53 P54 P55 P56 P57
Interrupt Circuit
ADC
Comparator (CO) or OP
Ext INT
Ain0~7
Cin+ Cin- CO
Fig. 4-1 EM78P350N Functional Block Diagram
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
*3
EM78P350N
8-Bit Microprocessor with OTP ROM
5
Pin Description
5.1 EM78P350
Symbol P50~P57 P60~P65 P70~P71 P73~P76 P80 ~ P84 INT0, INT1 Ain0~Ain5 PWM1 PWM2 BO VREF CINCIN+ CO Pin No. 11~12 16~17 24~27 18~23 28, 1 2~5 6~8 10, 15 16, 17 18~22 28 1 10 15 24 25 26 Type I/O I/O I/O I/O I I O O I I I O Function 8-bit General purpose input/output pins Default value at power-on reset 6-bit General purpose input/output pins Default value at power-on reset 6-bit General purpose input/output pins Default value at power-on reset 5-bit General purpose input/output pins Default value at power-on reset External interrupt pin triggered by falling edge 6-bit Analog-to-Digital Converter Defined by AISR (Bank 2 R8) <0 : 7> Pulse width modulation outputs Defined by PWMCON (Bank 1-R5)<5 : 7> Buzzer output driver External reference voltage for ADC Defined by ADCON (Bank 2 R9) <7>. "-" : the input pin of Vin- of the comparator "+" : the input pin of Vin+ of the comparator Pin CO is the comparator output Defined by CMPCON (IOCA) <0:1> General-purpose Input only If it remains at logic low, the device will be reset Wake-up from sleep mode when pin status changes Voltage on /RESET must not exceed Vdd during normal mode Real time clock/counter with Schmitt Trigger input pin. It must be tied to VDD or VSS if not in use. Counter 1 / Counter 2 with Schmitt Trigger input pin. Sin pin is used to input serial data signals by software. Sin pin is also used as port P82. Sout pin is used to input serial data signals by software. Sout pin is also used as port P81. Sck pin is used to input and output synchronous clock signals for serial data transfer by software. Sck pin is also used as Port P80. Crystal type: Crystal input terminal or external clock input pin RC type: RC oscillator input pin Crystal type: Output terminal for crystal oscillator or external clock input pin. RC type: Clock output with a duration of one instruction cycle time. The prescaler is determined by the CONT register. External clock signal input. Low crystal 32.768kHz input Low crystal 32.768kHz output Power supply Ground
/RESET
9
I
TCC CNTR1 Sin Sout Sck
27 5 8 7 6
I I I O I/O
OSCI
12
I
OSCO
11
O
XIN XOUT VDD VSS
2 3 14 13
I O - -
4*
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
5.2
EM78P351
Symbol P50~P57 P60~P67 P70~P77 P80 ~ P84 INT0, INT1 Ain0~Ain7 PWM1 PWM2 PWM3 BO VREF CINCIN+ CO Pin No. 12~13 17~18 27~30 19~26 31~32 1~6 7~9 11, 16 17, 18 19~26 31 32 1 11 16 27 28 29 Type I/O I/O I/O I/O I I O O I I I O Function 8-bit General purpose input/output pins Default value at power-on reset 8-bit General purpose input/output pins Default value at power-on reset 8-bit General purpose input/output pins Default value at power-on reset 5-bit General purpose input/output pins Default value at power-on reset External interrupt pin triggered by falling edge 8-bit Analog-to-Digital Converter Defined by AISR (Bank 2 R8) <0 : 7> Pulse width modulation outputs Defined by PWMCON (Bank 1-R5)<5 : 7> Buzzer output driver External reference voltage for ADC Defined by ADCON (Bank 2 R9) <7>. "-" : the input pin of Vin- of the comparator "+" : the input pin of Vin+ of the comparator Pin CO is the comparator output Defined by CMPCON (IOCA) <0:1> General-purpose Input only If it remains at logic low, the device will be reset Wake-up from sleep mode when pin status changes Voltage on /RESET must not exceed Vdd during normal mode Real time clock/counter with Schmitt Trigger input pin. It must be tied to VDD or VSS if not in use. Counter 1 / Counter 2 with Schmitt Trigger input pin. Sin pin is used to input serial data signals by software. Sin pin is also used as Port P82. Sout pin is used to input serial data signals by software. Sout pin is also used as Port P81. Sck pin is used to input and output synchronous clock signals for serial data transfer by software. Sck pin is also used as Port P80. Crystal type: Crystal input terminal or external clock input pin RC type: RC oscillator input pin Crystal type: Output terminal for crystal oscillator or external clock input pin. RC type: Clock output with a duration of one instruction cycle time. The prescaler is determined by the CONT register. External clock signal input. Low crystal 32.768kHz input Low crystal 32.768kHz output Power supply Ground
/RESET
10
I
TCC CNTR1/ CNTR2 Sin Sout Sck
30 5 6 9 8 7
I I I O I/O
OSCI
13
I
OSCO
12
O
XIN XOUT VDD VSS
2 3 15 13
I O - -
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
*5
EM78P350N
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)
Incremented by an external signal edge through the TCC pin, or by the instruction cycle clock. External signal of TCC trigger pulse width must be greater than one instruction. The signals to increment the counter are determined by Bit 4 and Bit 5 of the CONT register. Writable and readable as any other registers.
6.1.3 R2 (Program Counter) and Stack
Reset Vector Interrupt Vector 000H 008H User Memory Space
PC (A12 ~ A0)
Stack Level 1 Stack Level 2 Stack Level 3 Stack Level 8
On-chip Program Memory
1FFFH
Fig. 6-1 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 section). Generates 8Kx13 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. "JMP" instruction allows direct loading of the lower 10 program counter bits. Thus, "JMP" allows PC to jump to any location within a page.
6*
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
"CALL" instruction loads the lower 10 bits of the PC, and then PC+1 is pushed onto 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 EM78P350N, the most three significant bits (A12,A11 and A10) will be loaded with the content of PS2,PS1 and 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 (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
*7
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.3.1 Data Memory Configuration
Register Bank 0 Address
01 02 03 04 05 06 07 08 09 0A 0B 0C 0D 0E 0F 10 : 1F R1 (TCC Buffer) R2 (PC) R3 (STATUS) R4 (RSR, Bank Select) R5 (Port 5 I/O data) R6 (Port 6 I/O data) R7 (Port 7 I/O data) R8 (Port 8 I/O data) R9 (Timer 4 control register) RA (SPI read buffer) RB (SPI write buffer) RC (SPI status buffer) RD (SPI control buffer ) RE (Wake-up control register) RF (Interrupt flag)
Register Bank 1
Register Bank 2
Register Bank 3
Control Register
R4 (7, 6)
R4 (7, 6)
(0, 1)
R5 (PWM Control Register #1) R6 (PWM Control Register #2) R7 (PWM timer/counter Control register) R8 (PRD1H: PWM1 period) R9 (PRD2H: PWM2 period) RA (PRD3H: PWM3 period) RB (PRDL: PWM Period cycle) RC (DT1L: PWM1 Duty cycle) RD (DT2L: PWM2 Duty cycle)
(1, 0)
R4 (7, 6)
(1, 1)
R5 (Pull Low Control 1) R6 (Pull Low Control 2) R7 (Pull Low Control 3) R8 (Pull Low Control 4) R9 (Pull High Control 1) IOC5 (Port 5 I/O control) IOC6 (Port 6 I/O control) IOC7 (Port 7 I/O control) IOC8 (Port 8 I/O control) IOC9 (Timer 4 control register) IOCA (Comparator Control Register ) Reserved Reserved Reserved IOCE (WDT control register) IOCF (Interrupt Mask 1)
Reserved R6 (Buzzer output Control Register) R7 (System control Register) R8 (TADC input select register) R9 (ADC control register)
RA (ADC offset RA (Pull High Control 2) calibration register) RB (ADDATA ADC Data Bit11~Bit4) RC (ADDATA1H ADC Data Bit 11~Bit 8) RB (Pull High Control 3) RC (Pull High Control 4) RD (TIMER1H: PWM1 timer) RE (TIMER2H: PWM2 timer) RF (TMRL: PWM timer)
RD (ADATA1L ADC Data Bit 7~Bit 0) RE (DT3L: PWM3 Duty RE (LVDC : LVD cycle) Control) RF (DTH: PWM RF (TIMER3H: PWM3 Duty cycle) timer) 16-Byte Common Register
20 : 3F
Bank 0 32 x 8
Bank 1 32 x 8
Bank 2 32 x 8
Bank 3 32 x 8
8*
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.4 R3 (Status Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
PS2
PS1
PS0
T
P
Z
DC
C
Bits 7 ~ 5 (PS2 ~ PS0) Page select bits. PS2~PS0 are used to pre-select a program memory page. When executing a "JMP", "CALL", or other instructions which causes the program counter to change (e.g. MOV R2, A), PS2~PS0 are loaded into the 11th,12th and 13th bits of the program counter and select one of the available program memory pages. Note that RET (RETL, RETI) instruction does not change the PS2~PS0 bits. That is, the return will always be to the page from where the subroutine was called, regardless of the PS2~PS0 bits current setting.
PS2 PS1 PS0 Program Memory Page [Address]
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
Page 0 [0000-03FF] Page 1 [0400-07FF] Page 2 [0800-0BFF] Page 3 [0C00-0FFF] Page 4 [1000-13FF] Page 5 [1400-17FF] Page 6 [1800-1BFF] Page 7 [1C00-1FFF]
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. 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.
NOTE Bit 4 & Bit 3 (T & P) are read only.
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 & Bit 6: are used to select Banks 0 ~ 3. Bit 5 ~ Bit 0: are used to select registers (address: 00 ~ 3F) in the indirect address mode. See the table under Section 6.1.3.1 Data Memory Configuration for the configuration of the data memory.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
*9
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.6 R5 ~ R8 (Port 5 ~ Port 8)
R5 ~ R7 are I/O registers. R8 is an I/O register. The upper 3 bits of R8 are fixed to 0.
6.1.7 R9 (TMR4: Timer 4 Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
TMR47
TMR46
TMR45
TMR44
TMR43
TMR42
TMR41
TMR40
TMR47~TMR40 are set of Timer 4 register bits which are incremented until the value matches PWP and then, it resets to 0.
6.1.8 RA (SPIRB: SPI Read Buffer)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
SRB7
SRB6
SRB5
SRB4
SRB3
SRB2
SRB1
SRB0
SRB7~SRB0 are 8-bit data when transmission is completed by SPI.
6.1.9 RB (SPIWB: SPI Write Buffer)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
SWB7
SWB6
SWB5
SWB4
SWB3
SWB2
SWB1
SWB0
SWB7~SWB0 are 8-bit data, waiting for transmission by SPI.
6.1.10 RC (SPIS: SPI Status Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
DORD
TD1
TD0
T4ROS
OD3
OD4
-
RBF
Bit 7 (DORD): Data transmission order. 0 :Shift left (MSB first) 1 :Shift right (LSB first) Bit 6~Bit 5: Sout Status output Delay times Options
TD1 TD0 Delay Time
0 0 1 1
0 1 0 1
8 CLK 16 CLK 24 CLK 32 CLK
Bit 4 (T4ROS): Timer4 Read Out Buffer Select Bit 0 : Read Value from Timer 4 Preset Register. 1 : Read Value from Timer 4 Counter Register. Bit 3 (OD3): Open-Drain Control bit 0 = Open-drain disable for Sout 1 = Open-drain enable for Sout
10 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 2 (OD4): Open-Drain Control bit 0 = Open-drain disable for SCK 1 = Open-drain enable for SCK Bit 1 are not used and read as "0". Bit 0 (RBF): Read Buffer Full flag 0 = Receiving not completed, and SPIRB has not fully exchanged. When users read SPIRB, RBF bit will be cleared. 1 = Receiving completed; SPIRB is fully exchanged.
6.1.11 RD (SPIC: SPI Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
CES
SPIE
SRO
SSE
SDOC
SBRS2
SBRS1
SBRS0
Bit 7 (CES): Clock Edge Select bit 0 = Data shifts out on a rising edge, and shifts in on a falling edge. Data is on hold during a low-level. 1 = Data shifts out on a falling edge, and shifts in on a rising edge. Data is on hold during a high-level. Bit 6 (SPIE): SPI Enable bit 0 = Disable SPI mode 1 = Enable SPI mode Bit 5 (SRO): SPI Read Overflow bit 0 = No overflow 1 = A new data is received while the previous data is still being held in the SPIB register. In this situation, the data in SPIS register will be destroyed. To avoid setting this bit, users are required to read the SPIRB register although only the transmission is implemented.
NOTE This can only occur in slave mode.
Bit 4 (SSE): SPI Shift Enable bit 0 = Reset as soon as the shifting is completed, and the next byte is ready to shift. 1 = Start to shift, and remain on "1" while the current byte is still being transmitted.
NOTE This bit will reset to 0 at every one-byte transmission by the hardware
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 11
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 3 (SOUTC): Sout output status control bit: 0 = After the Serial data output, the Sout remains high 1 = After the Serial data output, the Sout remains low Bit 2~Bit 0 (SBRS): SPI Baud Rate Select bits Refer to the SPI baud rate table under the "SPI" section on the subsequent pages.
6.1.12 RE (WUCR: Wake-up Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
EM78P350N ICE350N Simulator
"0" C3
"0" C2
"0" C1
LVDIF* C0
ADWE ADWE
CMPWE CMPWE
ICWE ICWE
PWMWE PWMWE
*There is no LVD function in the ICE350N simulator. Bit 7 ~ Bit 5: [EM78P350N]: Unimplemented, read as `0'. Bit 4 (LVDIF) (only for EM78P350N) : Low voltage Detector interrupt flag.
LVDEN LVD1,LVD0 LVD Voltage Interrupt Level LVDIF
1 1 1 1 0
11 10 01 00 XX
2.2V 3.3V 4.0V 4.5V NA
1* 1* 1* 1* 0
* If Vdd has crossover at LVD voltage interrupt level as Vdd changes, LVDIF =1.
[With Simulator (C3~C0)]: are IRC calibration bits in IRC oscillator mode. In IRC oscillator mode of ICE350N simulator, these are the IRC calibration bits of IRC oscillator mode.
C3 C2 C1 C0 Frequency (MHz)
0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1
0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0
0 0 1 1 0 0 1 1 1 1 0 0 1 1 0 0
0 1 0 1 0 1 0 1 1 0 1 0 1 0 1 0
(1-36%) x F (1-31.5%) x F (1-27%) x F (1-22.5%) x F (1-18%) x F (1-13.5%) x F (1-9%) x F (1-4.5%) x F F (default) (1+4.5%) x F (1+9%) x F (1+135%) x F (1+18%) x F (1+22.5%) x F (1+27%) x F (1+31.5%) x F
Note: 1. Frequency values shown are theoretical and taken from an instance of a high frequency mode. Hence, they are shown for reference only. Definite values depend on the actual process. 2. Similar way of calculation is also applicable for low frequency mode.
12 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 3 (ADWE): ADC wake-up enable bit 0 = Disable ADC wake-up 1 = Enable ADC wake-up When the ADC Complete is used to enter an interrupt vector or to wake-up the EM78P350N from sleep with AD conversion running, the ADWE bit must be set to "Enable". Bit 2 (CMPWE): Comparator wake-up enable bit 0 = Disable Comparator wake-up 1 = Enable Comparator wake-up When the Comparator output status change is used to enter an interrupt vector or to wake-up EM78P350N from sleep, the CMPWE bit must be set to "Enable". Bit 1 (ICWE): Port 6 input change to wake-up status enable bit 0 = Disable Port 6 input change to wake-up status 1 = Enable Port 6 input change wake-up status When the Port 6 Input Status Change is used to enter an interrupt vector or to wake-up the EM78P350N from sleep, the ICWE bit must be set to "Enable". Bit 0 (PWMWE): PWM/Timer wake-up enable bit. 0 = Disable PWM/Timer wake-up 1 = Enable PWM/Timer wake up wake-up When the PWM/Timer output status change is used to enter an interrupt vector or to wake-up the EM78P350N from sleep, the PWMWE must be set to "Enable", this is reset by software.
6.1.13 RF (Interrupt Status Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
PWM3IF
PWM2IF
PWM1IF
ADIF
EXIF1
EXIF0
ICIF
TCIF
NOTE "1" means interrupt request; "0" means no interrupt occurs. RF can be cleared by instruction but cannot be set. IOCF is the interrupt mask register. Reading RF will result to "logic AND" of RF and IOCF.
Bit 7 (PWM3IF): PWM3 (Pulse Width Modulation) interrupt flag. Set when a selected duration is reached. Reset by software. Bit 6 (PWM2IF): PWM2 (Pulse Width Modulation) interrupt flag. Set when a selected duration is reached. Reset by software.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 13
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 5 (PWM1IF): PWM1 (Pulse Width Modulation) interrupt flag. Set when a selected duration is reached. Reset by software. Bit 4 (ADIF): Interrupt flag for analog to digital conversion. Set when AD conversion is completed. Reset by software. Bit 3 (EXIF1): External interrupt flag. Set by a falling edge on the /INT1 pin. Reset by software. Bit 2 (EXIF0): External interrupt flag. Set by a falling edge on the /INT0 pin. Reset by software. Bit 1 (ICIF): Port 6 input status change interrupt flag. Set when Port 6 input changes. Reset by software. Bit 0 (TCIF): TCC overflow interrupt flag. Set when TCC overflows. Reset by software.
6.1.14 R10 ~ R3F
All of these are 8-bit general-purpose registers.
6.1.15 Bank 1 R5 (PWM Control Register #1)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
PWM3E
PWM2E
PWM1E
"0"
T1EN
T1P2
T1P1
T1P0
Bit 7 (PWM3E): PWM3 enable bit 0 = PWM3 is off (default value), and its related pin carries out the P72 function 1 = PWM3 is on, and its related pin is automatically set as output Bit 6 (PWM2E): PWM2 enable bit 0 = PWM2 is off (default value), and its related pin carries out the P71 function 1 = PWM2 is on, and its related pin is automatically set as output Bit 5 (PWM1E): PWM1 enable bit 0 = PWM1 is off (default value), and its related pin carries out the P70 function 1 = PWM1 is on, and its related pin is automatically set to output Bit 4: Unimplemented, read as `0' Bit 3 (T1EN): TMR1 enable bit 0 = TMR1 is off (default value) 1 = TMR1 is on
14 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 2 ~ Bit 0 (T1P2 ~ T1P0): TMR1 clock prescale option bits
T1P2 T1P1 T1P0 Prescale
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
1:2 (default) 1:4 1:8 1:16 1:32 1:64 1:128 1:256
6.1.16 Bank 1 R6 (PWM Control Register 2)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
T2EN
T2P2
T2P1
T2P0
T3EN
T3P2
T3P1
T3P0
Bit 7 (T2EN):
TMR2 enable bit 0 = TMR2 is off (default value) 1 = TMR2 is on
Bit 6 ~ Bit 4 (T2P2 ~ T2P0): TMR2 clock prescale option bits
T2P2 T2P1 T2P0 Prescale
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
1:2 (default) 1:4 1:8 1:16 1:32 1:64 1:128 1:256
Bit 3 (T3EN):
TMR3 enable bit 0 = TMR3 is off (default value) 1 = TMR3 is on
Bit 2 ~ Bit 0 (T3P2 ~ T3P0): TMR3 clock prescale option bits
T3P2 T3P1 T3P0 Prescale
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
1:2 (default) 1:4 1:8 1:16 1:32 1:64 1:128 1:256
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 15
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.17 Bank1 R7 (PWM Timer/Counter Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
"0"
"0"
T2TS
T2TE
T1TS
T1TE
Bits 7~4: Unimplemented, read as `0' Bit 3 (T2TS): Timer 2 / Counter 2 signal source 0 = internal instruction cycle clock. If P77 is used as I/O pin, T2TS must be 0 1 = transition on the CNTR2 pin Bit 2 (T2TE): Timer 2 / Counter 2 signal edge 0 = increment if a transition from low to high takes place on the CNTR2 pin 1 = increment if a transition from high to low takes place on the CNTR2 pin Bit 1 (T1TS): Timer 1 / Counter 1 signal source 0 = internal instruction cycle clock. If P76 is used as I/O pin, T1TS must be 0 1 = transition on the CNTR1 pin Bit 0 (T1TE): Timer 1 / Counter 1 signal edge 0 = increment if a transition from low to high takes place on the CNTR1 pin 1 = increment if a transition from high to low takes place on the CNTR1 pin
6.1.18 Bank1 R8 (PRD1H: Most Significant Byte (Bit 9 ~ Bit 2) of PWM1 Time Period)
The content of Bank 1 R8 is the time period (time base) of PWM1. The frequency of PWM1 is the reverse of the period.
6.1.19 Bank1 R9 (PRD2H: Most Significant Byte (Bit 9 ~ Bit 2) of PWM2 Time Period)
The content of Bank 1 R9 is the time period (time base) of PWM2. The frequency of PWM2 is the reverse of the period.
6.1.20 Bank1 RA (PRD3H: Most Significant Byte (Bit 9 ~ Bit 2) of PWM3 Time Period)
The content of Bank 1 RA is the time period (time base) of PWM3. The frequency of PWM3 is the reverse of the period.
16 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.21
Bit 7
Bank1 RB (PRDL: Least Significant Bits of PWM Period Cycle)
Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
PRD3[1]
PRD3[0]
PRD2[1]
PRD2[0]
PRD1[1]
PRD1[0]
Bit 7 & Bit 6: Unimplemented, read as `0'. Bit 5 & Bit 4 (PRD3[1], PRD3[0]): Least Significant Bits of PWM3 Period Cycle. Bit 3 & Bit 2 (PRD2[1], PRD2[0]): Least Significant Bits of PWM2 Period Cycle. Sectioning actions refer to the Reset description. The following actions refer to the section status operation. Bit 1 & Bit 0 (PRD1[1], PRD1[0]): Least Significant Bits of PWM1 Period Cycle.
6.1.22
Bank 1 RC (DT1H: Most Significant Byte (Bit 9 ~ Bit 2) of PWM1 Duty Cycle)
A specified value keeps the output of PWM1 to remain high until the value matches with TMR1.
6.1.23
Bank 1 RD (DT2H: Most Significant Byte (Bit 9 ~ Bit 2) of PWM2 Duty Cycle)
A specified value keeps the output of PWM2 to remain high until the value matches with TMR2.
6.1.24 Bank1 RE (DT3H: Most Significant Byte (Bit 9 ~ Bit 2) of PWM3 Duty Cycle)
A specified value keeps the output of PWM3 to remain high until the value matches with TMR3.
6.1.25 Bank1 RF (DTL: Least Significant Bits of PWM Duty Cycle)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
PWM3[1]
PWM3[0]
PWM2[1]
PWM2[0]
PWM1[1]
PWM1[0]
Bit 7 & Bit 6: Unimplemented, read as `0' Bit 5 & Bit 4 (PWM3[1], PWM3[0]): Least Significant Bits of PWM3 Duty Cycle Bit 3 & Bit 2 (PWM2[1], PWM2[0]): Least Significant Bits of PWM2 Duty Cycle Bit 1 & Bit 0 (PWM1[1], PWM1[0]): Least Significant Bits of PWM1 Duty Cycle
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 17
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.26 Bank 2 R6 (BOCON: Buzzer Output Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
TEN
TCK1
TCK0
FSCS
"0"
"0"
"0"
"0"
Bit 4 (FSCS): High or low frequency select in Function operating 0 = High 1 = Low Bit 5~Bit 6 (TCK0~TCK1): Keytone output clock source select
Clock source TCK1 TCK0 Normal FSCS=0 FSCS=1 Slow, Idle Keytone Output Frequency Fc=8M Fs=32.768K
0 0 1 1
0 1 0 1
Fc/(213) Fc/(212) Fc/(211) Fc/(210)
Fs/(25) Fs/(24) Fs/(23) Fs/(22)
Fs/(25) Fs/(24) Fs/(23) Fs/(22)
0.976kHz 1.953kHz 3.906kHz 7.812kHz
1.024kHz 2.048kHz 4.096kHz 8.192kHz
Bit 7 (TEN): Key_tone enable control. 0 = Disable 1 = Enable
output latch data output 13 fc/2 , fc/212, fc/2 11 , 10 , fc/2 fs/2 5 fs/2 4 3 fs/2 2 fs/2 TCK D Q
output enable /BO pin
MUX
2 TBKTC
TEN
Fig. 6-2 Buzzer Output Pin Configuration
Key tone output can generate 50% duty pulse for driving a piezo-electric buzzer. The P83 must be set to "1" before the keytone is enabled, it can be halted by setting P83 to "0".
18 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
P83/BO pin
TEN P83/BO pin
Fig.6-3 Tone Output Pin Timing Chart
Bit 3 ~ Bit 0: Unimplemented, read as `0'
6.1.27 Bank 2 R7 (System Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
T1S
T2S
T3S
"0"
"0"
"0"
"0"
IDLE
Bit 7: Timer 1 Clock source 0 = Timer 1 source is used as Main Clock 1 = Timer 1 source is used as Sub clock Bit 6: Timer 2 Clock Source 0 = Timer 2 source is used as Main Clock 1 = Timer 2 source is used as Sub clock Bit 5: Timer 3 Clock Source 0 = Timer 3 source is used as Main Clock 1 = Timer 3 source is used as Sub clock Bit 4 ~ Bit 1: Unimplemented, read as `0' Bit 0 (IDLE): select idle mode or sleep mode IDLE = "0" + SLEP Instruction: sub-oscillator (Fs), Fs = 32.768kHz (idle mode). In idle mode, only the sub-oscillator acting as Timer 1, 2, 3 sources, and CPU is halted. IDLE = "1"+SLEP Instruction: all oscillation stop (sleep mode). In this mode, main-oscillator (Fm) and Fs is not work simultaneously. IDLE = "0" + SLEP Instruction idle mode IDLE = "1" + SLEP Instruction sleep mode NOP Instruction must be added after Sleep instruction.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 19
EM78P350N
8-Bit Microprocessor with OTP ROM
Example: Idle mode: IDLE bit = "0" + SLEP instruction + NOP instruction Sleep mode: IDLE bit = "1" + SLEP instruction + NOP instruction. Only the normal can entering sleep mode, idle mode can't entering the sleep mode.
Wake-up Pin change or Timer interrupt or AD or comparator
Normal Mode
IDLE = "0"+SLEP
Wake-up All wake-up function except PWM
Idle Mode
Timer must IDLE = "1"+SLEP select low crystal source Sleep Mode in normal mode
Fig 6-4 CPU Operation Mode
In Sleep mode, the internal oscillator is turned off and all system operation is halted. Sleep mode is released by /Sleep pin (level sensitive or edge sensitive). After warm-up period, the next instruction will be executed which is after the Sleep mode start instruction. Sleep mode can also be released by setting the /Reset pin to low and executing a reset operation. In Idle mode, only the low crystal source existence, the others crystal source were off. Only the Timer (TCC, Timer 1, Timer 2, Timer 3, PWM1, PWM2, PWM3) can work normally when its clock source select low crystal (if clock source select High crystal, timer will not work). If timer set the PWMWE as "1", when the timer or PWM occurs interrupt will wake up the CPU and entering normal mode. The TCC overflow will not wake up CPU.
6.1.28 Bank 2 R8 (AISR: ADC Input Select Register)
The AISR register defines the pins of Port 6 as analog inputs or as digital I/O, individually.
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
ADE7
ADE6
ADE5
ADE4
ADE3
ADE2
ADE1
ADE0
Bit 7 (ADE7): AD converter enable bit of P67 pin 0 = Disable AIN7, P67 functions as I/O pin 1 = Enable AIN7, to function as analog input pin Bit 6 (ADE6): AD converter enable bit of P66 pin 0 = Disable AIN6, P66 functions as I/O pin 1 = Enable AIN6, to function as analog input pin
20 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 5 (ADE5): AD converter enable bit of P65 pin 0 = Disable AIN5, P65 functions as I/O pin 1 = Enable AIN5, to function as analog input pin Bit 4 (ADE4): AD converter enable bit of P64 pin 0 = Disable AIN4, P64 functions as I/O pin 1 = Enable AIN4 to function as analog input pin Bit 3 (ADE3): AD converter enable bit of P63 pin 0 = Disable AIN3, P63 functions as I/O pin 1 = Enable AIN3, to function as analog input pin Bit 2 (ADE2): AD converter enable bit of P62 pin 0 = Disable AIN2, P62 functions as I/O pin 1 = Enable AIN2, to function as analog input pin Bit 1 (ADE1): AD converter enable bit of P61 pin 0 = Disable AIN1, P61 functions as I/O pin 1 = Enable AIN1, to function as analog input pin Bit 0 (ADE0): AD converter enable bit of P60 pin. 0 = Disable AIN0, P60 functions as I/O pin 1 = Enable AIN0, to function as analog input pin
NOTE The P60/AIN0 pin priority is as follows: P60/ADE0 Priority High AIN0 Low P60
6.1.29 Bank 2 R9 (ADCON: ADC Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
VREFS
CKR1
CKR0
ADRUN
ADPD
ADIS2
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 P84/VREF pin carries out the function of P84 1 = The Vref of the ADC is connected to P84/VREF
NOTE The P84/VREF pin priority is as follows: P84/VREF Pin Priority High Low VREF P84
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 21
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 6 & Bit 5 (CKR1 & CKR0): The prescaler of ADC oscillator clock rate 00 = 1: 16 (default value) 01 = 1: 4 10 = 1: 64 11 = 1: WDT ring oscillator frequency
CKR1:CKR0 Operation Mode Max. Operation Frequency
00 01 10 11
Fosc/16 Fosc/4 Fosc/64 Internal RC
4 MHz 1 MHz 16MHz -
Bit 4 (ADRUN): ADC starts to RUN. 0 = Reset upon completion of the conversion. This bit cannot be reset through software 1 = an AD conversion is started. This bit can be set by software Bit 3 (ADPD): ADC Power-down mode 0 = Switch off the resistor reference to save power even while the CPU is operating 1 = ADC is operating Bit 2 ~ Bit 0 (ADIS2 ~ADIS0): Analog Input Select 000 = AIN0/P60 001 = AIN1/P61 010 = AIN2/P62 011 = AIN3/P63 100 = AIN4/P64 101 = AIN5/P65 110 = AIN6/P66 111 = AIN7/P67 These bits can only be changed when the ADIF bit (see Section 6.1.14) and the ADRUN bit are both LOW.
6.1.30 Bank 2 RA (ADOC: ADC Offset Calibration Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
CALI
SIGN
VOF[2]
VOF[1]
VOF[0]
"0"
"0"
"0"
Bit 7 (CALI):
Calibration enable bit for ADC offset 0 = Disable Calibration 1 = Enable Calibration
22 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
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] EM78P350N
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
0LSB 2LSB 4LSB 6LSB 8LSB 10LSB 12LSB 14LSB
Bit 2 ~ Bit 0:
Unimplemented, read as `0'
6.1.31 Bank 2 RB (ADDATA: Converted Value of ADC)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 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) is set. RB is read only.
6.1.32 Bank 2 RC (ADDATA1H: Converted Value of ADC)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 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) is set. RC is read only.
6.1.33 Bank 2 RD (ADDATA1L: Converted Value of ADC)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 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) is set. RD is read only
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 23
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.34 Bank 2 RE (LVDC: LVD Control Register )
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
"0"
"0"
LVDEN
/LVD
LVD1
LVD0
There is no LVD function in the ICE350N simulator. Bits 7 ~ 4: Not used, set to "0" at all time. Bit 3 (LVDEN): Low Voltage Detect Register 0 : disable LVD 1 : enable LVD Bit 2 (/LVD): Low Voltage Detector. This is a read only bit. When the Vdd pin voltage is lower than the LVD voltage interrupt level (selected by LVD1 and LVD0), this bit will be cleared. 0 : If Vdd < .LVD voltage interrupt level 1 : If Vdd > LVD voltage interrupt level Bits 1 ~ 0 (LVD1 ~ LVD0) : Low Voltage Detect level select bits
LVDEN LVD1, LVD0 LVD Voltage Interrupt Level LVDIF
1 1 1 1 0
11 10 01 00 XX
2.2V 3.3V 4.0V 4.5V NA
1* 1* 1* 1* 0
*If Vdd has crossover at LVD voltage interrupt level as Vdd changes, LVDIF =1.
6.1.35 Bank 2 RF (TMR3H: Most Significant Bits (Bit 9 ~ Bit 2) of PWM3 Timer)
The contents of RF are read-only.
6.1.36 Bank3 R5 (Pull-low Control Register 1)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
/PL57
/PL56
/PL55
/PL54
/PL53
/PL52
/PL51
/PL50
Bank 3 R5 register is both readable and writable. Bit 7 (/PL57): Control bit is used to enable the pull-high of the P57 pin. 0 = Enable pull-low output 1 = Disable pull-low output Bit 6 (/PL56): Control bit is used to enable the pull-low function of the P56 output pin. Bit 5 (/PL55): Control bit is used to enable the pull-low function of the P55 output pin. Bit 4 (/PL54): Control bit is used to enable the pull-low function of the P54 output pin. Bit 3 (/PL53): Control bit is used to enable the pull-low function of the P53 output pin. Bit 2 (/PL52): Control bit is used to enable the pull-low function of the P52 output pin. Bit 1 (/PL51): Control bit is used to enable the pull-low function of the P51 output pin. Bit 0 (/PL50): Control bit is used to enable the pull-low function of the P50 output pin.
24 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.37 Bank 3 R6 (Pull-Low Control Register 2)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
/PL67
/PL66
/PL65
/PL64
/PL63
/PL62
/PL61
/PL60
Bank 3 R6 register is both readable and writable. Bit 7 (/PL67): Control bit is used to enable the pull-high of the P67 pin. 0 = Enable pull-low output 1 = Disable pull-low output Bit 6 (/PL66): Control bit used to enable the pull-low function of the P66 output pin. Bit 5 (/PL65): Control bit used to enable the pull-low function of the P65 output pin. Bit 4 (/PL64): Control bit used to enable the pull-low function of the P64 output pin. Bit 3 (/PL63): Control bit used to enable the pull-low function of the P63 output pin. Bit 2 (/PL62): Control bit used to enable the pull-low function of the P62 output pin. Bit 1 (/PL61): Control bit used to enable the pull-low of function the P61 output pin. Bit 0 (/PL60): Control bit used to enable the pull-low of function the P60 output pin.
6.1.38 Bank3 R7 (Pull-Low Control Register 3)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
/PL77
/PL76
/PL75
/PL74
/PL73
/PL72
/PL71
/PL70
Bank 3 R7 register is both readable and writable. Bit 7 (/PL77): Control bit is used to enable the pull-high of the P77 pin. 0 = Enable pull-low output 1 = Disable pull-low output Bit 6 (/PL76): Control bit used to enable the pull-low function of the P76 output pin. Bit 5 (/PL75): Control bit used to enable the pull-low function of the P75 output pin. Bit 4 (/PL74): Control bit used to enable the pull-low function of the P74 output pin. Bit 3 (/PL73): Control bit used to enable the pull-low function of the P73 output pin. Bit 2 (/PL72): Control bit used to enable the pull-low function of the P72 output pin. Bit 1 (/PL71): Control bit used to enable the pull-low function of the P71 output pin. Bit 0 (/PL70): Control bit used to enable the pull-low function of the P70 output pin.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 25
EM78P350N
8-Bit Microprocessor with OTP ROM
6.1.39 Bank3 R8 (Pull-low Control Register 4)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
"0"
/PL84
/PL83
/PL82
/PL81
/PL80
Bank 3 R8 register is both readable and writable. Bits 7 ~ 5: Not used, set "0" at all time. Bit 4 (/PL84): Control bit used to enable the pull-high function of the P84 output pin. 0 = Enable pull-low output 1 = Disable pull-low output Bit 3 (/PL83): Control bit used to enable the pull-low function of the P83 output pin. Bit 2 (/PL82): Control bit used to enable the pull-low function of the P82 output pin. Bit 1 (/PL81): Control bit used to enable the pull-low function of the P81 output pin. Bit 0 (/PL80): Control bit used to enable the pull-low function of the P80 output pin.
6.1.40 Bank3 R9 (Pull-High Control Register 1)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
/PH57
/PH56
/PH55
/PH54
/PH53
/PH52
/PH51
/PH50
Bank 3 R9 register is both readable and writable. Bit 7 (/PH57): Control bit used to enable the pull-high function of the P57 output pin. 0 = Enable pull-high output 1 = Disable pull-high output Bit 6 (/PH56): Control bit used to enable the pull-high function of the P56 output pin. Bit 5 (/PH55): Control bit used to enable the pull-high function of the P55 output pin. Bit 4 (/PH54): Control bit used to enable the pull-high function of the P54 output pin. Bit 3 (/PH53): Control bit used to enable the pull-high function of the P53 output pin. Bit 2 (/PH52): Control bit used to enable the pull-high function of the P52 output pin. Bit 1 (/PH51): Control bit used to enable the pull-high function of the P51 output pin. Bit 0 (/PH50): Control bit used to enable the pull-high function of the P50 output pin.
6.1.41 Bank 3 RA (Pull-High Control Register 2)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
/PH67
/PH66
/PH65
/PH64
/PH63
/PH62
/PH61
/PH60
Bank 3 RA register is both readable and writable. Bit 7 (/PH67): Control bit is used to enable the pull-high of the P67 pin. 0 = Enable pull-high output 1 = Disable pull-high output
26 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 6 (/PH66): Control bit used to enable the pull-high function of the P66 output pin. Bit 5 (/PH65): Control bit used to enable the pull-high function of the P65 output pin. Bit 4 (/PH64): Control bit used to enable the pull-high function of the P64 output pin. Bit 3 (/PH63): Control bit used to enable the pull-high function of the P63 output pin. Bit 2 (/PH62): Control bit used to enable the pull-high function of the P62 output pin. Bit 1 (/PH61): Control bit used to enable the pull-high function of the P61 output pin. Bit 0 (/PH60): Control bit used to enable the pull-high function of the P60 output pin.
6.1.42 Bank 3 RB (Pull-high Control Register 3)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
/PH77
/PH76
/PH75
/PH74
/PH73
/PH72
/PH71
/PH70
Bank 3 RB register is both readable and writable. Bit 7 (/PH77): Control bit used to enable the pull-high function of the P77 output pin. 0 = Enable pull-high output 1 = Disable pull-high output Bit 6 (/PH76): Control bit used to enable the pull-high function of the P76 output pin. Bit 5 (/PH75): Control bit used to enable the pull-high function of the P75 output pin. Bit 4 (/PH74): Control bit used to enable the pull-high function of the P74 output pin. Bit 3 (/PH73): Control bit used to enable the pull-high function of the P73 output pin. Bit 2 (/PH72): Control bit used to enable the pull-high function of the P72 output pin. Bit 1 (/PH71): Control bit used to enable the pull-high function of the P71 output pin. Bit 0 (/PH70): Control bit used to enable the pull-high function of the P70 output pin.
6.1.43
Bit 7
Bank 3 RC (Pull-high Control Register 4)
Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
"0"
/PH84
/PH83
/PH82
/PH81
/PH80
Bank 3 RC register is both readable and writable. Bits 7 ~ 5: Not used, set to "0" at all time. Bit 4 (/PH84): Control bit is used to enable the pull-high function of the P84 output pin. 0 = Enable pull-low output 1 = Disable pull-low output Bit 3 (/PH83): Control bit used to enable the pull-high function of the P83 output pin. Bit 2 (/PH82): Control bit used to enable the pull-low function of the P82 output pin.
* 27
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 1 (/PH81): Control bit used to enable the pull-low function of the P81 output pin. Bit 0 (/PH80): Control bit used to enable the pull-low function of the P80 output pin.
6.1.44 Bank 3 RD (TMR1H: Most Significant Bits (Bit9 ~ Bit2) of PWM1 Timer)
The contents of RD are read-only.
6.1.45 Bank 3 RE (TMR2H: Most Significant Bits (Bit 9 ~ Bit 2) of PWM2 Timer)
The contents of RE are read-only.
6.1.46 Bank 3 RF (TMRL: Least Significant Bits of PWM Timer)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0'
TMR3[1]
TMR3[0]
TMR2[1]
TMR2[0]
TMR1[1]
TMR1[0]
The contents of RF are read only, Bit 7 ~ Bit 6: Unimplemented, read as "0". Bit 5 ~ Bit 4: (TMR3 [1], TMR3 [0]): Most Significant Bits of PWM3 Timer. Bit 3 ~ Bit 2: (TMR2 [1], TMR2 [0]): Most Significant Bits of PWM2 Timer. Bit 1 ~ Bit 0: (TMR1 [1], TMR1 [0]): Most Significant Bits of PWM1 Timer.
6.2
Special Purpose Registers 6.2.1 A (Accumulator)
Internal data transfer operation, or instruction operand holding usually involves the temporary storage function of the Accumulator. The Accumulator is not an addressable register.
6.2.2
Bit 7
CONT (Control Register)
Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
INTE
INT
TS
TE
PSTE
PST2
PST1
PST0
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. If P56 is used as I/O pin, TS must be 0. 1 = transition on the TCC pin
28 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
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. Bit 2 ~ Bit 0 (PST2 ~ PST0): TCC prescaler bits
PST2 PST1 PST0 TCC Rate
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
Note: Tcc time-out period [1/Fosc x prescaler x 256 (Tcc cnt) x 1 (CLK=2)] Tcc time-out period [1/Fosc x prescaler x 256 (Tcc cnt) x 2 (CLK=4)]
6.2.3
IOC5 ~ IOC8 (I/O Port Control Register)
0 = defines the relative I/O pin as outpu 1 = puts the relative I/O pin into high impedance IOC5, IOC6, IOC7, and IOC8 registers are all readable and writable.
6.2.4
Bit 7
IOC9 (T4CON: Timer 4 Control Register)
Bit 6 Bit 5 - Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
SPIE
SPIF
TM4IF
"0"
TM4E
TM4P1
TM4P0
Bit 7(SPIIE):
SPI Interrupt enable bit 0 = Disable SPI interrupt 1 = Enable SPI interrupt
Bit 6 (SPIIF): SPI interrupt flag. Set by data transmission complete, flag is cleared by software. Bit 4 (TM4IF) Timer 4 interrupt flag. Set by the comparator during Timer 4 application, flag is cleared by software. Bit 3: Unimplemented, read as `0' Bit 2 (TM4E): Timer 4 Function Enable bit 0 = Disable Timer 4 function as default 1 = Enable Timer 4 function
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 29
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 1~Bit 0 (TM4P): Timer4 Prescaler bit
TM4P1 TM4P0 Prescaler Rate
0 0 1 1
0 1 0 1
1:1 1:4 1:8 1:16
6.2.5 IOCA (TCMPCON: Comparator Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
"0"
CMPIF
CMPIE
CPOUT
COS1
COS0
Bits 7~ 5:
Unimplemented, read as `0'
Bit 4 (CMPIF): Comparator interrupt flag. Set when a change occurs in the output of Comparator. Reset by software. Bit 3 (CMPIE): CMPIF interrupt enable bit 0 = Disable CMPIF interrupt 1 = Enable CMPIF interrupt When the Comparator output status change is used to enter interrupt vector or to enter next instruction, the CMPIE bit must be set to "Enable". Bit 2 (CPOUT): the result of the comparator output Bit 1 ~ Bit 0 (COS1 ~ COS0): Comparator/OP Select bits
COS1 COS0 Function Description
0 0 1 1
0 1 0 1
The Comparator and OP arenot used. P56 functions as normal I/O pin Functions as Comparator and P56 functions as normal I/O pin Functions as Comparator and P56 functions as Comparator output pin (CO) Functions as OP and P56 functions as OP output pin (CO)
6.2.6 IOCE (WDT Control Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
WDTE
EIS0
EIS1
PSWE
PSW2
PSW1
PSW0
LVDIE
Bit 7 (WDTE): Control bit used to enable the Watchdog Timer 0 = Disable WDT 1 = Enable WDT WDTE is both readable and writable. Bit 6 (EIS0): Control bit used to define the function of the P52 (/INT0) pin 0 = P52, normal I/O pin 1 = /INT0, external interrupt pin. In this case, the I/O control bit of P52 (Bit 2 of IOC50) must be set to "1", and tied to a pull-high register (75 K)
30 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
NOTE When EIS0 is "0," the path of /INT0 is masked. When EIS0 is "1," the status of /INT0 pin can also be read by way of reading Port 5 (R5). Refer to Fig. 6-4 (I/O Port and I/O Control Register Circuit for P52 (/INT0)) under Section 6.4 (I/O Ports). EIS0 is both readable and writable.
Bit 5 (EIS1):
Control bit used to define the function of the P53 (/INT1) pin 0 = P53, normal I/O pin 1 = /INT1, external interrupt pin. In this case, the I/O control bit of P53 (Bit 3 of IOC50) must be set to "1", and tied to a pull-high register (75 K).
NOTE
When EIS1 is "0," the path of /INT1 is masked. When EIS1 is "1," the status of /INT1 pin can also be read by way of reading Port 5 (R5). Refer to Fig. 6-4 (I/O Port and I/O Control Register Circuit for P53 (/INT1)) under Section 6.4 (I/O Ports). EIS1 is both readable and writable.
Bit 4 (PSWE): Prescaler enable bit for WDT 0 = prescaler disable bit. WDT rate is 1:1 1 = prescaler enable bit. WDT rate is set as Bit 4~Bit 2 Bit 3 ~ Bit 1 (PSW2 ~ PSW0): WDT prescaler bits.
PSW2 PSW1 PSW0 WDT Rate
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
Bit 0 (LVDIE) LVDIF interrupt enable bit. 0 = disable LVDIF interrupt 1 = enable LVDIF interrupt
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 31
EM78P350N
8-Bit Microprocessor with OTP ROM
6.2.7 IOCF (Interrupt Mask Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
PWM3IE
PWM2IE
PWM1IE
ADIE
EXIE1
EXIE0
ICIE
TCIE
NOTE IOCF register is both readable and writable Individual interrupt is enabled by setting its associated control bit in the IOCF to "1." Global interrupt is enabled by the ENI instruction and is disabled by the DISI instruction. Refer to Fig. 6-8 (Interrupt Input Circuit) under Section 6.6 (Interrupt).
Bit 7 (PWM3IE): PWM3IF interrupt enable bit 0 = Disable PWM3 interrupt 1 = Enable PWM3 interrupt Bit 6 (PWM2IE): PWM2IF interrupt enable bit 0 = Disable PWM2 interrupt 1 = Enable PWM2 interrupt Bit 5 (PWM1IE): PWM1IF interrupt enable bit 0 = Disable PWM1 interrupt 1 = Enable PWM1 interrupt Bit 4 (ADIE): ADIF interrupt enable bit 0 = Disable ADIF interrupt 1 = Enable ADIF interrupt When the ADC Complete status is used to enter an interrupt vector or to enter next instruction, the ADIE bit must be set to "Enable." Bit 3 (EXIE1): EXIF External 1 interrupt enable bit 0 = Disable EXIF interrupt 1 = Enable EXIF interrupt Bit 2 (EXIE0): EXIF External 0 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 If Port 6 Input Status Change Interrupt is used to enter an interrupt vector or to enter next instruction, the ICIE bit must be set to "Enable". Bit 0 (TCIE): TCIF interrupt enable bit. 0 = Disable TCIF interrupt 1 = Enable TCIF interrupt
32 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.3
TCC/WDT and Prescaler
There are two 8-bit counters available as prescalers for the TCC and WDT respectively. The PST0 ~ PST2 bits of the CONT register are used to determine the ratio of the TCC prescaler, and the PWR0 ~ PWR2 bits of the IOCE0 register are used to determine the prescaler of WDT. 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. 6-2 (next page) depicts the block diagram of TCC/WDT. TCC (R1) is an 8-bit timer/counter. The TCC clock source can be an internal clock or external signal input (edge selectable from the TCC pin). If TCC signal source is from an internal clock, the TCC will be incremented by 1 at every instruction cycle (without prescaler). Referring to Fig. 6-2, CLK=Fosc/2 or CLK=Fosc/4 is dependent to the Code Option bit . CLK=Fosc/2 if the CLKS bit is "0," and CLK=Fosc/4 if the CLKS bit is "1." If the TCC signal source is from an external clock input, TCC will be incremented by 1 at every falling edge or rising edge of the TCC pin. The 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 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 Register). With no prescaler, the WDT time-out duration is approximately 18ms.1
1
VDD=5V, Setup time period = 16.5ms 30%. VDD=3V, Setup time period = 18ms 30%.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 33
EM78P350N
8-Bit Microprocessor with OTP ROM
CLK (Fosc/2 or Fosc/4) Data Bus 0 TCC Pin TE (CONT) 1 MUX 8 to 1 MUX Prescaler TS (CONT) PSR2~0 (CONT) 8-Bit Counter (IOCC1) SYNC 2 cycles TCC (R1)
TCC overflow Interrupt
WDT
8-Bit counter
8 to 1 MUX WDTE (IOCE0) WDT Time out
Prescaler
PSW2~0 (IOCE0)
Fig. 6-2 TCC and WDT Block Diagram
6.4
I/O Ports
The I/O registers (Port 5, Port 6, Port 7 and Port8) are bidirectional tri-state I/O ports. The Pull-high and Pull-down functions can be set internally by IOCB0, IOCC0, and IOCD0 respectively. Port 6 features an input status change interrupt (or wake-up) function. Each I/O pin can be defined as "input" or "output" pin by the I/O control registers (IOC50 ~ IOC80). 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 Port 7 are illustrated in Figures 6-3, 6-4, & 6-5 respectively (see next page). Port 6 with Input Change Interrupt/Wake-up is shown in Fig. 6-6.
34 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
PCRD
Q Q
D
CLK
PCWR
PORT
Q
D
CLK
IOD
PDWR
Q PDRD
0 1
M U X
Note: Pull-high and Open-drain are not shown in the figure.
Fig. 6-3 I/O Port and I/O Control Register Circuit for Port 5, Port 7, and Port 8
PCRD
Q Q
D
CLK
PCWR
P52, /INT0 P53,/INT1
PORT Q Q D
CLK
PDWR
IO D
Bit 6 of IOCE0
D
CLK
Q
0 1
M U X PDRD TI 0
Q
INT
Note: Pull-high and Open-drain are not shown in the figure.
Fig. 6-4 I/O Port and I/O Control Register Circuit for P52 (/INT0) and P53 (/INT1) Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 35
EM78P350N
8-Bit Microprocessor with OTP ROM
PCRD
Q Q
D
CLK
PCWR
P60 ~ P67
PORT Q Q D
CLK
IOD PDWR
0 1
M U X
PDRD TI n
D
CLK
Q
Q
Note: Pull-high (down) and Open-drain are not shown in the figure.
Fig. 6-5 I/O Port and I/O Control Register Circuit for Port 6
IOCE.1
D
P R
Q Interrupt _ Q RE.1 ENI Instruction
CLK
C L
T10 T11
D
P R
Q Q _ Q P R D
CLK
_ CQ L
CLK
C L
T17
DISI Instruction Interrupt (W ake-up from SLEEP)
/SLEP
Next Instruction (W ake-up from SLEEP)
Fig. 6-6 Port 6 Block Diagram with Input Change Interrupt/Wake-up 36 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.4.1 Usage of Port 6 Input Change Wake-up/Interrupt Function
(1) Wake-up (a) Before Sleep 1. Disable WDT 2. Read I/O Port 6 (MOV R6,R6) 3. Execute "ENI" or "DISI" 4. Enable wake-up bit (Set RE ICWE =1) 5. Execute "SLEP" instruction (b) After wake-up
Next instruction
(2) Wake-up and Interrupt (a) Before Sleep 1. Disable WDT 2. Read I/O Port 6 (MOV R6,R6) 3. Execute "ENI" or "DISI" 4. Enable wake-up bit (Set RE ICWE =1) 5. Enable interrupt (Set IOCF ICIE =1) 6. Execute "SLEP" instruction (b) After wake-up 1. IF "ENI" Interrupt vector (008H) 2. IF "DISI" Next instruction
(3) Interrupt (a) Before Port 6 pin change 1. Read I/O Port 6 (MOV R6,R6) 2. Execute "ENI" or "DISI" 3. Enable interrupt (Set IOCF ICIE =1) (b) After Port 6 pin changed (interrupt) 1. IF "ENI" Interrupt vector (008H) 2. IF "DISI" Next instruction
6.5
Serial Peripheral Interface Mode 6.5.1 Overview and Features
Overview: Figures 6-7, 6-8, and 6-9 shows how the EM78P350N communicates with other devices through SPI module. If the EM78P350N is a master controller, it sends clock through the SCK pin. A couple of 8-bit data are transmitted and received at the same time. However, if EM78P350N is defined as a slave, its SCK pin could be programmed as an input pin. Data will continue to be shifted based on both the clock rate and the selected edge. The SPIS Bit 7 (DORD) can also be set to determine the SPI transmission order, SPIC Bit 3 (SDOC) to control SDO pin after serial data output status and SPIS Bit 6 (TD1), Bit 5 (TD0) determines the SDO status output delay times. Features: Operation in either Master mode or Slave mode Three-wire or four-wire full duplex synchronous communication Programmable baud rates of communication, Programming the clock polarity, (RD Bit 7) Interrupt flag available for the read buffer full,
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 37
EM78P350N
8-Bit Microprocessor with OTP ROM
SPI transmission order After serial data output SDO status select SDO status output delay times SPI handshake pin Up to 8 MHz (maximum) bit frequency,
SDO SPIR Reg SPIW SPIW Reg Reg /SS SPIS Reg Bit 7 Master Device SCK Slave Device SDI SPI Module SPIR Reg SPIW SPIW Reg Reg
Fig. 6-7 SPI Master/Slave Communication
SDI SDO SCK /SS Vdd Master P50 P51 P52 P53
SDO SDI SCK /SS
SDO SDI SCK /SS
SDO SDI SCK /SS
Slave Device 1
SDO SDI SCK /SS
Slave Device 2
Slave Device 3
Slave Device 4
Fig. 6-8 SPI Configuration of Single-Master and Multi-Slave
38 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
SDI SDO SCK /SS
SDI SDO SCK /SS
Master 1 or P50 Slave 1 P51
P52 P53
Master 2 or P50 P51 Slave 6
P52 P53
Slave 2 for Master 1
6.5.2 SPI Function Description
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
SDO SDI SCK /SS
Slave 3 for Master 1,2
Fig. 6-9 SPI Configuration of Single-Master and Multi-Slave
Fig. 6-10 SPI Block Diagram
SDO SDI SCK /SS
Slave 4 for Master 1,2
SDO SDI SCK /SS
Slave 5 for Master 2
SDO SDI SCK /SS
* 39
EM78P350N
8-Bit Microprocessor with OTP ROM
SPI SDO SDI Shift Clock /SS SPI Write Register (0X0B)
SPI Read Register (0X0A)
SPI Mode Select Register
210 SPIC
Below are the functions of each block and explanations on how to carry out the SPI communication with the signals depicted in Fig.6-12 and Fig.6-13: P82/Sin: Serial Data In P81/Sout: Serial Data Out P80/SCK: Serial Clock P75//SS: /Slave Select (Option). This pin (/SS) may be required in slave mode. RBF: Set by Buffer Full Detector, and read SPIRB to reset. Buffer Full Detector: Sets to 1 when an 8-bit shifting is completed. SSE: Loads the data in SPIS register, and begin to shift SPIS reg.:Shifting byte in and out. The MSB is shifted first. Both the SPIS and the SPIW registers are loaded at the same time. Once data are written, SPIS starts transmission/reception. The data received will be moved to the SPIR register as the shifting of the 8-bit data is completed. The RBF (Read Buffer Full) flag and the SPIF (SPI Interrupt) flag are then set. SPIR reg.: Read buffer. The buffer will be updated as the 8-bit shifting is completed. The data must be read before the next reception is completed. The RBF flag is cleared as the SPIR register reads. SPIW reg.:Write buffer. The buffer will ignore any attempts to write until the 8-bit shifting is completed.
40 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
8-1 MUX
SPI Shift Buffer
FOSC
7~0 SPIWB
10 T4CON
764 SPIC
0
2 INTC
4 SPIC
SPIS
7~0 SPIRB
DATA BUS
Fig. 6-11 SPI Transmission Function Block Diagram
EM78P350N
8-Bit Microprocessor with OTP ROM
The SSE bit will be kept in "1"if the communication is still undergoing. This flag must be cleared as the shifting is completed. Users can determine if the next write attempt is available. SBRS2~SBRS0: Programming the clock frequency/rates and sources. Clock Select: Selecting either the internal or the external clock as the shifting clock. Edge Select: Selecting the appropriate clock edges by programming the CES bit
6.5.3 SPI Signal and Pin Description
The detailed functions of the four pins, SDI, SDO, SCK, and /SS, which are shown in Fig. 6-9, are as follows: Sin/P82: Serial Data In Receive sequentially, the Most Significant Bit (MSB) first, Least Significant Bit (LSB) last. Defined as high-impedance, if not selected. Program the same clock rate and clock edge to latch on both the master and slave devices. The byte received will update the transmitted byte. The RBF bit (located in Register 0x0C) will be set as the SPI operation is completed. Timing is shown in Fig.6-12 and 6-13. Sout/P81: Serial Data Out Transmit sequentially; the Most Significant Bit (MSB) first, Least Significant Bit (LSB) last. Program the same clock rate and clock edge to latch on both the master and slave devices. The received byte will update the transmitted byte. The CES (located in Register 0x0D) bit will be reset, as the SPI operation is completed. Timing is shown in Fig.6-10 and 6-11.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 41
EM78P350N
8-Bit Microprocessor with OTP ROM
SCK/P80 (Pin 6): Serial Clock Generated by a master device Synchronize the data communication on both the SDI and SDO pins. The CES (located in Register 0x0D) is used to select the edge to communicate. The SBR0~SBR2 (located in Register 0x0D) is used to determine the baud rate of communication. The CES, SBR0, SBR1, and SBR2 bits have no effect in slave mode Timing is shown in Fig.6-12 and 6-13. /SS/P75 (Pin 4): Slave Select; negative logic Generated by a master device to signify the slave to receive data Goes low before the first cycle of SCK appears, and remains low until the last (eighth) cycle is completed, Ignores the data on the SDI and SDO pins while /SS is high, since the SDO is no longer driven. Timing is shown in Fig.6-12 and 6-13.
6.5.4 Programming the Related Registers
As the SPI mode is defined, the related registers of this operation are shown in Table 2 and Table 3. Table 1 Related Control Registers of the SPI Mode
Address
0x0D NA
Name
*SPIC/RD T4CR/IOC9
Bit 7
CES
Bit 6
SPIE
Bit 5
SRO
Bit 4
SSE
Bit 3
SOUTC
Bit 2
SBR2
Bit 1
SBR1
Bit 0
SBR0
SPIIE SPIF
-
TM4IF
"0"
TM4E
TM4P1 TM4P0
SPIC: SPI Control Register. Bit 7 (CES): Clock Edge Select bit 0 = Data shifts out on rising edge, and shifts in on falling edge. Data is on hold during the low level. 1 = Data shifts out on falling edge, and shifts in on rising edge. Data is on hold during the high level. Bit 6 (SPIE): SPI Enable bit 0 = Disable SPI mode 1 = Enable SPI mode
42 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 5 (SRO): SPI Read Overflow bit 0 = No overflow occurs 1 = A new data is received while the previous data is still being on hold in the SPIRB register. Under this condition, the data in SPIS register will be destroyed. To avoid setting this bit, users should read the SPIRB register even if the transmission is implemented only.
NOTE This can only occur in slave mode.
Bit 4 (SSE): SPI Shift Enable bit 0 = Reset as soon as the shifting is completed and the next byte is ready to shift. 1 = Start to shift, and remains on 1 while the current byte continues to transmit.
NOTE This bit can be reset by hardware only.
Bits 2~0 (SBRS):SPI Baud Rate Select Bits
SBRS2 (Bit 2) SBRS1 (Bit 1) SBRS0 (Bit 0) Mode Baud Rate
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
Master Master Master Master Master Slave Slave Master
Fsco/2 Fsco/4 Fsco/8 Fsco/16 Fsco/32 /SS enable /SS disable TMR4/2
Note: In Master mode, /SS is disabled.
T4CR: Timer 4 Control Register Bit 7(SPIIE): SPI Interrupt enable bit 0 : Disable SPI interrupt 1 : Enable SPI interrupt Bit 6 (SPIIF): SPI interrupt flag. Set by data transmission complete, flag by software. Bit 5 (TM4IE): TM4IE interrupt enable bit 0 : Disable TM4IE interrupt 1 : Enable TM4IE interrupt Bit 3 (TM4IF): Timer 4 interrupt flag. Set by the comparator at Timer 4 application, flag is cleared by software.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 43
EM78P350N
8-Bit Microprocessor with OTP ROM Bit 3: Unimplemented, read as `0' Bit 2 (TM4E): Timer 4 Function Enable bit 0 : Disable Timer 4 function (default) 1 : Enable Timer 4 function Bit 1~Bit 0 (TM4P): Timer 4 Prescaler bit
TM4P1 TM4P0 Prescaler Rate
0 0 1 1
0 1 0 1
1:1 1:4 1:8 1:16
Table 2 Related Status/Data Registers of the SPI Mode
Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0X0A 0x0B 0x0C
SPIRB/RA SRB7 SPIWB/RB SWB7 SPIS/RC DORD
SRB6 SWB6 TD1
SRB5 SRB4 SRB3 SWB5 SWB4 SWB3 TD0 T4ROS OD3
SRB2 SWB2 OD4
SRB1 SRB0 SWB1 SWB0 RBF
SPIRB: SPI Read Buffer. Once the serial data is received completely, it will load to SPIRB from SPISR. The RBF bit in the SPIS register will also be set. SPIWB: SPI Write Buffer. As a transmitted data is loaded, the SPIS register stands by and start to shift the data when sensing SCK edge with SSE set to "1". SPIS: SPI Status register Bit 7 (DORD): Data transmission order 0 : Shift left (MSB first) 1 : Shift right (LSB first) Bit 6 ~ Bit 5: SDO Status Output Delay Times Options. There is no action in slave mode.
TD1 TD0 Delay Time
0 0 1 1
0 1 0 1
8 CLK 16 CLK 24 CLK 32 CLK
Bit 4 (T4ROS): Timer 4 Read Out Buffer Select Bit 0 : Read Value from Timer 4 Preset Register 1 : Read Value from Timer 4 Counter Register Bit 3 (OD3) Open-Drain Control bit (P81) 0 : Open-drain disable for Sout 1 : Open-drain enable for Sout Bit 2 (OD4): Open Drain-Control bit (P80) 0 : Open-drain disable for SCK 1 : Open-drain enable for SCK
44 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 0 (RBF): Read Buffer Full flag 0 : Receive is ongoing, SPIB is empty 1 : Receive is completed, SPIB is full
6.5.5 SPI Mode Timing
The edge of SCK is selected by programming bit CES. The waveform shown in Fig. 6-12 is applicable regardless of whether the EM78P350N is in master or slave mode with /SS disabled. However, the waveform in Fig. 6-13 can only be implemented in slave mode with /SS enabled.
Fig. 6-12 SPI Mode with /SS Disabled
Fig. 6-13 SPI Mode with /SS Enable
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 45
EM78P350N
8-Bit Microprocessor with OTP ROM
6.5.6 SPI Software Application
;for master SPIRB == 0X0A SPIWB == 0X0B SPIS == 0X0C RBF == 0 SCK_OD == 2 SDO_OD == 3 TD0 == 5 TD1 == 6 DORD == 7 SPIC == 0X0D SBRS0 == 0 SBRS1 == 1 SBRS2 == 2 SDOC == 3 SSE == 4 SRO == 5 SPIE == 6 CES == 7 TC4CR == 0X09 TM4P0 == 0 TM4P1 == 1 TM4E == 2 TM4IF == 4 TM4IE == 5 SPIF == 6 SPIE == 7 ORG 0X00 JMP INITIAL ORG 0X08 BANK 0 IOR TC4CR AND A,@0B10111111 IOW TC4CR RETI ORG 0X50 INITIAL: MOV A,@0X80 IOW TC4CR MOV A,@0X55 MOV SPIWB,A BS SPIC,SPIE BC SPIS,DORD BC SPIS,TD0 BC SPIS,TD1 BC SPIC,CES BC SPIC,SBRS0 BC SPIC,SBRS1 BC SPIC,SBRS2 BC SPIC,SDOC ENI MAIN: BS SPIC,SSE JBC SPIC,SSE JMP $-1 NOP NOP MOV A,@0X55 MOV SPIWB,A NOP NOP JMP MAIN
46 *
; reset vector ; SPI interrupt vector
; Clear SPI interrupt flag
; enable SPI interrupt ; clear SPI interrupt flag ; Transmit data ; SPI shift enable bit ; shift left ; SDO status output delay times:8 clocks ; rising edge ; set baud rate: Fc/2 ; SDO output status control bit: high ; enable interrupt ; SPI start transmit
; transmit data
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM ;for slave PORT7 == 0X07 SPIRB == 0X0A SPIWB == 0X0B SPIS == 0X0C RBF == 0 SCK_OD == 2 SDO_OD == 3 TD0 == 5 TD1 == 6 DORD == 7 SPIC == 0X0D SBRS0 == 0 SBRS1 == 1 SBRS2 == 2 SDOC == 3 SSE == 4 SRO == 5 SPIE == 6 CES == 7 IOC7 == 0X07 TC4CR == 0X09 TM4P0 == 0 TM4P1 == 1 TM4E == 2 TM4IF == 4 TM4IE == 5 SPIF == 6 SPIE == 7 ORG 0X00 JMP INITIAL ORG 0X08 BANK 0 IOR TC4CR AND A,@0B10111111 IOW TC4CR RETI ORG 0X50 INITIAL: MOV A,@0X00 IOW IOC7 MOV PORT7,A MOV A,@0X80 IOW TC4CR BS SPIC,SPIE BC SPIS,DORD BC SPIS,TD0 BC SPIS,TD1 BC SPIC,CES BC SPIS,DORD BS SPIC,SBRS0 BC SPIC,SBRS1 BS SPIC,SBRS2 BC SPIC,SDOC ENI MIAN: BS SPIC,SSE JBS SPIS,RBF JMP $-1 JBC SPIC,SRO JMP MAIN MOV A,SPIRB MOV PORT7,A NOP JMP MAIN
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
; reset vector ; SPI interrupt vector
; Clear SPI interrupt flag
; set port7 as output ; ; ; ; enable SPI interrupt clear SPI interrupt flag SPI shift enable bit shift left
; SDO status output delay times:8 clocks ; rising edge ; shift left ; set baud rate: /SS enable ; SDO output status control bit: High ; SPI start transmit ; determine data receive finish ; determine data overflow ; receive data
* 47
EM78P350N
8-Bit Microprocessor with OTP ROM
6.6
Timer 4 6.6.1 Overview
Timer 4 (TMR4) is an 8-bit clock up-counter with a programmable prescaler. When TMR4 is in SPI baud rate clock generator mode (SBRS0, SBRS1 and SBRS2 are set to 1) and SPI control register Bit 4 (SSE) is set to 1, Timer 4 will enable automatically without setting TM4E. TMR4 can be read and written to and cleared on any reset conditions.
6.6.2 Function Description
Fig. 6-14 shows Timer 4 block diagram. Each signal and block is described as follows:
Set predict value (Bank 0-R9) TM4E
0
TMR4 value
1
TMR4 Up-counter
Set TM4IF
In SPI baud generator mode ?
Yes
Interrupt and SPI clock output
Overflow T4ROS Prescaler 1:1~1:16 No Interrupt OSC / 4
Fig. 6-14 Timer 4 Block Diagram
OSC/4: Input clock. Prescaler: Option 1:1, 1:4, 1:8, and 1:16 defined by TM4P1 and TM4P2 (T4CON<1, 0>). It is cleared when a value is written to TMR4 or T4CON, and during any kind of reset as well. TMR4: Timer 4 register. TMR4 is incremented until it overflows, and then resets to 0. If it is in the SPI baud rate generator mode, its output is fed as a shifting clock. TMR4 register; increases until it overflows, and then reloads the predicted value. If writing a value to Timer 4, the predicted value and TMR4 value will be the set value. However, if T4ROS is set to 1 and read value from TMR4, the value will be TMR4 direct value, else T4ROS is set to 0 and read value from TMR4, the value will be TMR4 predicted value.
48 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.6.3 Programming the Related Registers
The related registers of the defined TMR4 operation are shown in Table 4 and Table 5 Table 3 TMR4 Related Control Registers
Address
0x0C NA
Name
SPIS/RC (Bank 0) T4CR/IOC9
Bit 7
DORD
Bit 6
TD1
Bit 5
TD0
Bit 4
T4ROS
Bit 3
OD3
Bit 2
OD4
Bit 1
-
Bit 0
RBF
SPIE
SPIF
TM4IE TM4IF
"0"
TM4E TM4P1 TM4P0
Table 4 Related Status/Data Registers ofTMR4
Address
0x09 NA
Name
T4CR/IOC9
Bit 7
Bit 6
Bit 5 -
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
TMR4/R9 (Bank 0) TMR47 TMR46 TMR45 TMR44 TMR43 TMR42 TMR41 TMR40
SPIE
SPIF
TM4IF
"0"
TM4E TM4P1 TM4P0
TMR4: Timer 4 Register TMR47~TMR40 are set of Timer 4 register bits which are incremented until the value matches PWP and then resets to 0. T4ROS (Bit 4): Timer 4 Read Buffer Select Bit 0 : Read Value from Timer 4 Preset Register 1 : Read Value from Timer 4 Counter Register T4CR: Timer 4 Control Register Bit 2 (TM4E): Timer4 enable bit Bit 1 (TM4P1) and Bit 0 (TM4P): Timer 4 prescaler for FSCO
TM4P1 TM4P0 Prescaler Rate
0 0 1 1
0 1 0 1
1:1 1:4 1:8 1:16
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 49
EM78P350N
8-Bit Microprocessor with OTP ROM
6.7
Reset and Wake-up 6.7.1 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) A device is kept in a reset condition for the duration of approximately 18ms.2 after the reset is detected. When in LXT mode, the reset time is 500ms. Once a reset occurs, the following functions are performed (the initial address is 000h): The oscillator continues running, or will be started (if in sleep mode). The Program Counter (R2) is set to all "0". 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 and upper 2 bits of R4 are cleared. The CONT register bits are set to all "0". Executing the "SLEP" instruction will assert the sleep (power down) mode. While entering sleep mode, the Oscillator, TCC, Timer 1, Timer 2, and Timer 3 are stopped. The WDT (if enabled) is cleared but keeps on running. The controller can be awakened by: Case 1 Case 2 Case 3 Case 4 Case 5 Case 6 External reset input on /RESET pin WDT time-out (if enabled) Port 6 input status changes (if ICWE is enabled) Comparator output status changes (if CMPWE is enabled) AD conversion completed (if ADWE enable) PWM/Timer overflows (if PWMWE enable)
The first two cases (1 & 2) will cause the EM78P350N 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 0x8 after wake-up. If DISI is executed before SLEP, the execution will restart from the instruction next to SLEP after wake-up. All sleep mode wake up time is 2ms in high Crystal mode. In RC mode (IRC or ERC), wake-up time is 10s. In low Crystal mode, wake-up time is 500ms.
2
VDD=5V, WDT Time-out period = 16.5ms 30%. VDD=3V, WDT Time-out period = 18ms 30%.
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
50 *
EM78P350N
8-Bit Microprocessor with OTP ROM
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 EM78P350N can be awakened only with Case 1 or Case 2. Refer to the section on Interrupt (Section 6.7) for further details. Case [b] If Port 6 Input Status Change is used to wake -up the EM78P350N and ICWE bit of RE register is enabled before SLEP, WDT must be disabled. Hence, the EM78P350N can be awakened only with Case 3. Wake-up time is dependent on oscillator mode. In RC mode the reset time is 32 clocks (for stable oscillators). In High Crystal mode, reset time is 2ms and 32 clocks (for stable oscillators); and in low Crystal mode, the reset time is 500ms. Case [c] If Comparator output status change is used to wake-up the EM78P350N and the CMPWE bit of the RE register is enabled before SLEP, WDT must be disabled by software. Hence, the EM78P350N can be awakened only with Case 4. Wake-up time is dependent on oscillator mode. In RC mode, the reset time is 32 clocks (for stable oscillators). In High crystal mode, reset time is 2ms and 32 clocks (for stable oscillators), and in low crystal mode, the reset time is 500ms. Case [d] If AD conversion completed is used to wake-up the EM78P350N and the ADWE bit of the RE register is enabled before SLEP, WDT must be disabled by software. Hence, the EM78P350N can be awakened only with Case 5. The wake-up time is 15 TAD (ADC clock period). Wake-up time is dependent on oscillator mode. In RC mode, the reset time is 32 clocks (for stable oscillators). In High crystal mode, reset time is 2ms and 32 clocks (for stable oscillators); and in low crystal mode, the reset time is 500ms. Case [e] If PWM/Timer output status change is used to wake-up the EM78P350N and the PWMWE bit of the RE register is enabled before Idle mode (except in sleep mode), WDT must be disabled by software. Hence, the EM78P350N can be awakening only with Case 6. Wake-up time is dependent on the oscillator mode. In RC mode the reset time is 32 clocks (for stable oscillators). In High crystal mode, reset time is 2ms and 32 clocks (for stable oscillators); and in low crystal mode, the reset time is 500ms.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 51
EM78P350N
8-Bit Microprocessor with OTP ROM
If Port 6 Input Status Change Interrupt is used to wake up the EM78P350N (as in Case b above), the following instructions must be executed before SLEP: MOV A, @001111xxb IOW IOCE0 WDTC MOV R6, R6 ENI (or DISI) MOV A, @00000x1xb MOV RE MOV A, @00000x1xb IOW IOCF SLEP ; Select WDT prescaler and Disable WDT ; ; ; ; Clear WDT and prescaler Read Port 6 Enable (or disable) global interrupt Enable Port 6 input change wake-up bit
; Enable Port 6 input change interrupt ; Sleep
Similarly, if the Comparator Interrupt is used to wake up the EM78P350N (as in Case [c] above), the following instructions must be executed before SLEP: MOV A, @xxxxxx10b ; Select an comparator and P60 act as CO pin ; Select WDT prescaler and Disable WDT ; Clear WDT and prescaler ; Enable (or disable) global interrupt ; Enable comparator output status change wake-up bit ; Enable comparator output status change interrupt ; Sleep
IOW IOCA0 MOV A, @001111xxb IOW IOCE0 WDTC ENI (or DISI) MOV A, @000001xxb MOV MOV IOW SLEP RE A, @xxxx1xxxb IOCA
52 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM 6.7.1.1 Wake-up and Interrupt Mode Operation Summary All categories under Wake-up and Interrupt modes are summarized below.
Signal Sleep Mode Idle Mode Normal Mode
DISI + IOCF (TCIE) Bit 0 = 1 Next Instruction+ Set RF (TCIF) = 1 ENI + IOCF (TCIE) Bit 0 = 1 Interrupt Vector (0x08)+ Set RF (TCIF) = 1 IOCF (ICIE) Bit 1 = 0 Port 6 input status change interrupted is invalid
TCC Over Flow
N/A
N/A
Port 6 Input Status Change
RE (ICWE) Bit 1 = 0, IOCF (ICIE) Bit 1 = 0 Oscillator, TCC and TIMERX are stopped. Port 6 input status changed wake-up is invalid. RE (ICWE) Bit 1 = 0, IOCF (ICIE) Bit 1 = 1 Set RF (ICIF) = 1, Oscillator, TCC and TIMERX are stopped. Port 6 input status changed wake-up is invalid. RE (ICWE) Bit 1 = 1, IOCF (ICIE) Bit 1 = 0 Wake-up+ Next Instruction Oscillator, TCC and TIMERX are stopped. RE (ICWE) Bit 1 = 1, DISI + IOCF (ICIE) Bit 1 = 1 Wake-up+ Next Instruction+ Set RF (ICIF) = 1 Oscillator, TCC and TIMERX are stopped. RE (ICWE) Bit 1 = 1, ENI + IOCF (ICIE) Bit 1 = 1 Wake-up+ Interrupt Vector (0x08)+ Set RF (ICIF) = 1 Oscillator, TCC and TIMERX are stopped.
RE (ICWE) Bit 1 = 0, IOCF (ICIE) Bit 1 = 0 Oscillator, TCC and TIMERX are stopped. Port 6 input status changed wake-up is invalid. RE (ICWE) Bit 1 = 0, IOCF (ICIE) Bit 1 = 1 Set RF (ICIF) = 1, Oscillator, TCC and TIMERX are stopped. Port 6 input status changed wake-up is invalid. RE (ICWE) Bit 1 = 1, IOCF (ICIE) Bit 1 = 0 Wake-up+ Next Instruction Oscillator, TCC and TIMERX are stopped. RE (ICWE) Bit 1 = 1, DISI + IOCF (ICIE) Bit 1 = 1 Wake-up + Next Instruction + Set RF (ICIF) = 1 Oscillator, TCC and TIMERX are stopped. RE (ICWE) Bit1=1, ENI + IOCF (ICIE) Bit 1 = 1 Wake-up+ Interrupt Vector (0x08)+ Set RF (ICIF) = 1 Oscillator, TCC and TIMERX are stopped.
DISI + IOCF (ICIE) Bit 1 = 1 Next Instruction + Set RF (ICIF) = 1 ENI + IOCF (ICIE) Bit 1 = 1 Interrupt Vector (0x08)+ Set RF (ICIF) = 1 DISI + IOCF (EXIE1, 0) Bit 2, 3 = 1 Next Instruction+ Set RF (EXIF)=1 ENI + IOCF (EXIE1, 0) Bit 2, 3 = 1 Interrupt Vector (0x08)+ Set RF (EXIF) = 1
INT Pin
N/A
N/A
AD Conversion
RE (ADWE) Bit 3 = 0, RE (ADWE) Bit 3 = 0, IOCF IOCF (ADIE) Bit 1 = 0 IOCF (ADIE) Bit 4 = 0 (ADIE) Bit 4 = 0 Clear Bank 1-R9 (ADRUN)=0, Clear Bank 1-R9 (ADRUN)=0, ADC is stopped, ADC is stopped, AD conversion interrupted is AD conversion wake-up is AD conversion wake-up is invalid. invalid. invalid Oscillator, TCC and TIMERX Oscillator, TCC and TIMERX are stopped. are stopped. RE (ADWE) Bit 3 = 0, IOCF RE (ADWE) Bit 3 = 0, IOCF (ADIE) Bit 4 = 1 (ADIE) Bit 4 = 1 Set RF (ADIF)=1, Bank 1-R9 Set RF (ADIF) = 1, Bank 1-R9 (ADRUN) = 0, ADC is stopped(ADRUN) = 0, ADC is stopped, AD conversion wake-up is AD conversion wake-up is invalid. invalid. Oscillator, TCC and TIMERX Oscillator, TCC and TIMERX are stopped. are stopped. RE (ADWE) Bit 3 = 1, IOCF RE (ADWE) Bit 3 = 1, IOCF (ADIE) Bit 4 = 0 (ADIE) Bit 4 = 0 Wake-up+ Next Instruction, Wake-up+ Next Instruction, Oscillator, TCC and TIMERX Oscillator, TCC and TIMERX keep on running. keep on running. Wake-up when ADC Wake-up when ADC completed. completed.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 53
EM78P350N
8-Bit Microprocessor with OTP ROM
Signal
Sleep Mode
RE (ADWE) Bit 3 = 1, DISI + IOCF (ADIE) Bit 4 = 1 Wake-up+ Next Instruction+ RF (ADIF) = 1, Oscillator, TCC and TIMERX keep on running. Wake-up when ADC completed. RE (ADWE) Bit 3 = 1, ENI + IOCF (ADIE) Bit 4 = 1 Wake-up+ Interrupt Vector (0x08)+ RF (ADIF) = 1, Oscillator, TCC and TIMERX keep on running. Wake-up when ADC completed.
Idle Mode
RE (ADWE) Bit 3 = 1, DISI + IOCF (ADIE) Bit 4 = 1 Wake-up+ Next Instruction+ RF (ADIF) = 1, Oscillator, TCC and TIMERX keep on running. Wake-up when ADC completed. RE (ADWE) Bit 3 = 1, ENI + IOCF (ADIE) Bit 4 = 1 Wake-up+ Interrupt Vector (0x08)+ RF (ADIF) = 1, Oscillator, TCC and TIMERX keep on running. Wake-up when ADC completed. RE (PWMWE) = 0, IOCA (PWMIE) bit 0 = 0, if TxS = 1 Only sub-clock oscillate. PWM wake-up is invalid. RE (PWMWE) = 0, IOCA (PWMIE) Bit 0 = 1, if TxS = 1 Set PWMIF = 1 Only sub-clock oscillate. PWM wake-up is invalid. RE (PWMWE) = 1, IOCA (PWMIE) Bit 0 = 1, if TxS = 0 Wake-up+ Next Instruction, Only sub-clock oscillate. RE (PWMWE) = 1, IOCA (PWMIE) Bit 0 = 1, DISI, if TxS = 1 Wake-up+ Next Instruction, Only sub-clock oscillate. RE (PWMWE) = 1, IOCA (PWMIE) Bit 0 = 1, ENI, if TxS = 1 Wake-up+ Interrupt Vector (0x08)+ Set RF (PWMIF) = 1 Only sub-clock oscillate. RE (CMPWE) Bit 2 = 0, IOCE (CMPIE) Bit 0 = 0 Comparator output status changed wake-up is invalid. Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 0, IOCE (CMPIE) Bit 0 = 1 Set RF (CMPIF) = 1, Comparator output status changed wake-up is invalid. Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 1, IOCE (CMPIE) Bit 0 = 0 Wake-up+ Next Instruction, Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 1, DISI + IOCE (CMPIE) Bit 0 = 1 Wake-up+ Next Instruction+ Set RF (CMPIF) = 1, Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 1, ENI + IOCE (CMPIE) Bit 0 = 1 Wake-up+ Interrupt Vector (0x08)+ Set RF (CMPIF) = 1, Oscillator, TCC and TIMERX are stopped. Wake-up+ Reset (Address 0x00)
Normal Mode
DISI + IOCF (ADIE) Bit 4=1
Next Instruction+ RF (ADIF)=1
AD Conversion
ENI + IOCF (ADIE) Bit 4 = 1
Interrupt Vector (0x08)+ Set RF (ADIF) = 1
DISI + IOCF (PWMXIE) = 1 Next Instruction+ Set RF (PWMXIF) = 1 ENI + IOCF (PWMXIE) = 1
PWMX (PWM1, PWM2, PWM3) (When TimerX matches PRDX)
N/A
Interrupt Vector (0x08)+ Set RF (PWMXIF) = 1
Comparator (Comparator Output Status Change)
WDT Time Out IOCE (WDTE) Bit 7 = 1
RE (CMPWE) Bit 2 = 0, IOCE (CMPIE) Bit 0 = 0 Comparator output status changed wake-up is invalid. Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 0, IOCE (CMPIE) Bit 0 = 1 Set RF (CMPIF) = 1, Comparator output status changed wake-up is invalid. Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 1, IOCE (CMPIE) Bit 0 = 0 Wake-up+ Next Instruction, Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 1, DISI + IOCE (CMPIE) Bit 0 = 1 Wake-up+ Next Instruction+ Set RF (CMPIF) = 1, Oscillator, TCC and TIMERX are stopped. RE (CMPWE) Bit 2 = 1, ENI + IOCE (CMPIE) Bit 0 = 1 Wake-up+ Interrupt Vector (0x08)+ Set RF (CMPIF) = 1, Oscillator, TCC and TIMERX are stopped. Wake-up+ Reset (Address 0x00)
IOCF (CMPIE) Bit 7 = 0 Comparator output status change interrupted is invalid.
DISI + IOCE (CMPIE) Bit 0 = 1 Next Instruction+ Set RF (CMPIF) = 1 ENI + IOCE (CMPIE) Bit 0 = 1 Interrupt Vector (0x08)+ Set RF (CMPIF) = 1 Reset (Address 0x00)
54 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM 6.7.1.2 Register Initial Values after Reset The following summarizes the registers initialized values.
Address Name Reset Type Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
Bit Name Power-on N/A IOC5 /RESET & WDT Wake-up from Pin change Bit Name Power-on N/A IOC6 /RESET & WDT Wake-up from Pin change Bit Name Power-on N/A IOC7 /RESET & WDT Wake-up from Pin change Bit Name Power-on N/A IOC8 /RESET &WDT Wake-up from Pin change Bit Name N/A IOC9 (T4CR) Power-on /RESET & WDT Wake-up from Pin change Bit Name N/A IOCA (CMPCON) /RESET & WDT Wake-up from Pin change Bit Name Power-on N/A IOCC /RESET & WDT Wake-up from Pin change Bit Name Power-on N/A IOCD /RESET & WDT Wake-up from Pin change Power-on
C57 1 1 P C67 1 1 P C77 1 1 P 0 0 P SPIE 0 0 P 0 0 P 1 1 P 1 1 P
C56 1 1 P C66 1 1 P C76 1 1 P 0 0 P SPIF 0 0 P 0 0 P 1 1 P 1 1 P
C55 1 1 P C65 1 1 P C75 1 1 P 0 0 P TM4IF 0 0 P 0 0 P 1 1 P 1 1 P
C54 1 1 P C64 1 1 P C74 1 1 P C84 1 1 P TM4IE 0 0 P
C53 1 1 P C63 1 1 P C73 1 1 P C83 1 1 P 0 0 P
C52 1 1 P C62 1 1 P C72 1 1 P C82 1 1 P TM4E 0 0 P
C51 1 1 P C61 1 1 P C71 1 1 P C81 1 1 P
C50 1 1 P C60 1 1 P C70 1 1 P C80 1 1 P
TM4P1 TM4P0 0 0 P 0 0 P COS0 0 0 P 1 1 P 1 1 P
CMPIF CMPIE CPOUT COS1 0 0 P 1 1 P 1 1 P 0 0 P 1 1 P 1 1 P 0 0 P 1 1 P 1 1 P 0 0 P 1 1 P 1 1 P
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 55
EM78P350N
8-Bit Microprocessor with OTP ROM
Address
Name
Reset Type
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name Power-on N/A IOCE /RESET & WDT Wake-up from Pin change Bit Name Power-on N/A IOCF /RESET & WDT Wake-up from Pin change Bit Name Power-on N/A CONT /RESET & WDT Wake-up from Pin change Bit Name Power-on 0x00 R0(IAR) /RESET & WDT Wake-up from Pin change Bit Name Power-on 0x01 R1(TCC) /RESET & WDT Wake-up from Pin change Bit Name Power-on 0x02 R2(PC) /RESET & WDT Wake-up from Pin Change Bit Name Power-on 0x03 R3(SR) /RESET & WDT Wake-up from Pin change Bit Name Power-on /RESET & WDT Wake-up from Pin change Bit Name Power-on /RESET & WDT Wake-up from Pin change
WDTE 0 0 P
EIS0 0 0 P
EIS1 0 0 P
PSWE 0 0 P ADIE 0 0 P TE 0 0 P U P P 0 0 P 0 0
PSW2 0 0 P EXIE1 0 0 P PSTE 0 0 P U P P 0 0 P 0 0
PSW1 0 0 P EXIE0 0 0 P PST2 0 0 P U P P 0 0 P 0 0
PSW0 0 0 P ICIE 0 0 P PST1 0 0 P U P P 0 0 P 0 0
LVDIE 0 0 P TCIE 0 0 P PST0 0 0 P U P P 0 0 P 0 0
PMW3IE PMW2IE PWM1IE 0 0 P INTE 0 0 P U P P 0 0 P 0 0 0 0 P INT 0 0 P U P P 0 0 P 0 0 0 0 P TS 0 0 P U P P 0 0 P 0 0
Jump to address 0x08 or continue to execute next instruction PS2 0 0 P RBS1 0 0 P P57 U U P PS1 0 0 P RBS0 0 0 P P56 U U P PS0 0 0 P U P P P55 U U P T 1 t t U P P P54 U U P P 1 t t U P P P53 U U P Z U P P U P P P52 U U P DC U P P U P P P51 U U P C U P P U P P P50 U U P
0x04
R4(RSR)
0x05
P5
56 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Address
Name
Reset Type
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name Power-on 0x06 P6 /RESET & WDT Wake-up from Pin change Bit Name Power-on 0x7 P7 /RESET & WDT Wake-up from Pin change Bit Name Power-on 0x8 P8 /RESET & WDT Wake-up from Pin change Bit Name Power-on 0x9 R9 (T4R) /RESET and WDT Wake-up from Pin change Bit Name Power-on 0xA RA (SPIR) /RESET and WDT Wake-up from Pin change Bit Name Power-on 0xB RB (SPIW) /RESET and WDT Wake-up from Pin change Bit Name Power-on 0xC RC (SPISB) /RESET and WDT Wake-up from Pin change Bit Name Power-on 0xD RD (SPICB) /RESET and WDT Wake-up from Pin change
P67 U U P P74 U U P "0" U U P
P66 U U P P73 U U P "0" U U P
P65 U U P P72 U U P "0" U U P
P64 U U P P74 U U P P84 U U P
P63 U U P P73 U U P P83 U U P
P62 U U P P72 U U P P82 U U P
P61 U U P P71 U U P P81 U U P
P60 U U P P70 U U P P80 U U P
TMR47 TMR46 TMR45 TMR44 TMR43 TMR42 TMR41 TMR40 0 0 P SRB7 U U P SWB7 0 0 P DORD 0 0 P CES 0 0 P 0 0 P SRB6 U U P SWB6 0 0 P TD1 0 0 P SPIE 0 0 P 0 0 P SRB5 U U P SWB5 0 0 P TD0 0 0 P SDO 0 0 P 0 0 P SRB4 U U P SWB4 0 0 P T4ROS 0 0 P SSE 0 0 P 0 0 P SRB3 U U P SWB3 0 0 P OD3 0 0 P SDOC 0 0 P 0 0 P SRB2 U U P SWB2 0 0 P OD4 0 0 P 0 0 P SRB1 U U P SWB1 0 0 P "0" 0 0 P 0 0 P SRB0 U U P SWB0 0 0 P RBF 0 0 P
SBRS2 SBRS1 SBRS0 0 0 P 0 0 P 0 0 P
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 57
EM78P350N
8-Bit Microprocessor with OTP ROM
Address
Name
Reset Type
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name Power-on 0xE RE (WUCR) /RESET and WDT Wake-up from Pin change Bit Name Power-on 0xF RF (ISR) /RESET and WDT Wake-up from Pin change Bit Name 0X5 Power-on R5 (Bank1) /RESET & WDT Wake-up from Pin change Bit Name 0X6 R6 (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0X7 R7 (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0X8 R8 (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0X9 R9 (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0XA RA (Bank 1) Power-on /RESET & WDT Wake-up from Pin change
0 0 P
0 0 P
0 0 P
LVDIF 0 0 P ADIF 0 0 P "0" 0 0 P T2P0 0 0 P "0" 0 0 P
ADWE CMPWE ICWE PWMWE 0 0 P EXIF0 0 0 P T1EN 0 0 P T3EN 0 0 P T2TS 0 0 P 0 0 P EXIF1 0 0 P T1P2 0 0 P T3P2 0 0 P T2TE 0 0 P 0 0 P ICIF 0 0 P T1P1 0 0 P T3P1 0 0 P T1TS 0 0 P 0 0 P TCIF 0 0 P T1P0 0 0 P T3P0 0 0 P T1TE 0 0 P
PWM3IF PWM2IF PWM1IF 0 0 P 0 0 P 0 0 P
PWM3E PWM2E PWM1E 0 0 P T2EN 0 0 P "0" 0 0 P 0 0 P T2P2 0 0 P "0" 0 0 P 0 0 P T2P1 0 0 P "0" 0 0 P
PRD1[9] PRD1[8] PRD1[7] PRD1[6] PRD1[5] PRD1[4] PRD1[3] PRD1[2] 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P
PRD2[9] PRD2[8] PRD2[7] PRD2[6] PRD2[5] PRD2[4] PRD2[3] PRD2[2] 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P
PRD3[9] PRD3[8] PRD3[7] PRD3[6] PRD3[5] PRD3[4] PRD3[3] PRD3[2] 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P
58 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Address
Name
Reset Type
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name 0XB RB (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0XC RC (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0XD RD (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0xE RE (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0xF RF (Bank 1) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0X6 R6 (BOCR, Bank 2) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0X7 R7 (SCR, Bank 2) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0x8 R8 (AISR, Bank 2) Power-on /RESET & WDT Wake-up from Pin change
"0" 0 0 P DT1[9] 0 0 P DT2[9] 0 0 P DT3[9] 0 0 P 0 0 P TEN 0 0 P
"0" 0 0 P DT1[8] 0 0 P DT2[8] 0 0 P DT3[8] 0 0 P 0 0 P TCK1 0 0 P
PRD3[1] PRD3[0] PRD2[1] PRD2[0] PRD1[1] PRD1[0] 0 0 P DT1[7] 0 0 P DT2[7] 0 0 P DT3[7] 0 0 P DT3[1] 0 0 P TCK0 0 0 P 0 0 P DT1[6] 0 0 P DT2[6] 0 0 P DT3[6] 0 0 P DT3[0] 0 0 P FSCS 0 0 P 0 0 P DT1[5] 0 0 P DT2[5] 0 0 P DT3[5] 0 0 P DT2[1] 0 0 P 0 0 P DT1[4] 0 0 P DT2[4] 0 0 0 DT3[4] 0 0 0 DT2[0] 0 0 P 0 0 P DT1[3] 0 0 P DT2[3] 0 0 P DT3[3] 0 0 P DT1[1] 0 0 P 0 0 P DT1[2] 0 0 P DT2[2] 0 0 P DT3[2] 0 0 P DT1[0] 0 0 P
"0"
0 0 P
"0"
0 0 P
"0"
0 0 P
"0"
0 0 P CPUS 1 1 P ADE0 0 0 P
T1S
0 0 P ADE7 0 0 P
T2S
0 0 P ADE6 0 0 P
T3S
0 0 P ADE5 0 0 P
"0"
0 0 P ADE4 0 0 P
"0"
0 0 P ADE3 0 0 P
"0"
0 0 P ADE2 0 0 P
"0"
0 0 P ADE1 0 0 P
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 59
EM78P350N
8-Bit Microprocessor with OTP ROM
Address
Name
Reset Type
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name 0x9 R9 (ADCON, Bank 2) Power-on /RESET and WDT Wake-up from Pin change Bit Name 0xA RA (ADOC, Bank 2) Power-on /RESET and WDT Wake-up from Pin change Bit Name 0xB Power-on RB (ADDDATA, /RESET and Bank 2) WDT Wake-up from Pin change Bit Name 0xC Power-on RC (ADDATA1 /RESET and H, Bank 2) WDT Wake-up from Pin change Bit Name 0XD Power-on RD (ADDATA1 /RESET and L, Bank 2) WDT Wake-up from Pin change Bit Name 0XE RE (LVDC, Bank 2) Power-on /RESET and WDT Wake-up from Pin change Bit Name 0XF Power-on RF (TIMER3H, /RESET & WDT Bank 2) Wake-up from Pin change Bit Name 0X5 R5 (Bank 3) Power-on /RESET & WDT Wake-up from Pin change
60 *
VREFS 0 0 P CALI 0 0 P AD11 U U P 0 0 P AD7 U U P "0" 0 0 P
CKR1 0 0 P SIGN 0 0 P AD10 U U P 0 0 P AD7 U U P "0" 0 0 P
CKR0 ADRUN ADPD 0 0 P 0 0 P 0 0 P
ADIS2 0 0 P 0 0 P AD6 U U P AD10 U U P AD2 U U P /LVD 1 1 P
ADIS1 0 0 P 0 0 P AD5 U U P AD9 U U P AD1 U U P LVD1 0 0 P
ADIS0 0 0 P 0 0 P AD4 U U P AD8 U U P AD0 U U P LVD0 0 0 P
VOF[2] VOF[1] VOF[0] 0 0 P AD9 U U P 0 0 P AD5 U U P "0" 0 0 P 0 0 P AD8 U U P 0 0 P AD4 U U P "0" 0 0 P 0 0 P AD7 U U P AD11 U U P AD3 U U P LVDEN 0 0 P
TMR3H[9] TMR3H[8] TMR3H[7] TMR3H[6] TMR3H[5] TMR3H[4] TMR3H[3] TMR3H[2] 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P 0 0 P
/PL57 1 1 P
/PL56 1 1 P
/PL55 1 1 P
/PL54 1 1 P
/PL53 1 1 P
/PL52 1 1 P
/PL51 1 1 P
/PL50 1 1 P
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Address
Name
Reset Type
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name 0X6 Power-on R6 (Bank3) /RESET & WDT Wake-up from Pin change Bit Name 0X7 Power-on R7 (Bank3) /RESET & WDT Wake-up from Pin change Bit Name 0X8 Power-on R8 (Bank3) /RESET & WDT Wake-up from Pin change Bit Name Power-on 0X9 R9 (Bank3) /RESET & WDT Wake-up from Pin change Bit Name 0XA Power-on RA (Bank3) /RESET & WDT Wake-up from Pin change Bit Name 0XB Power-on RB (Bank3) /RESET & WDT Wake-up from Pin change Bit Name 0XC Power-on RC (Bank3) /RESET & WDT Wake-up from Pin change Bit Name 0XD RD (TMR1H Bank 3) Power-on /RESET & WDT Wake-up from Pin change
/PL67 1 1 P /PL77 1 1 P "0" 0 0 P /PH57 1 1 P /PH67 1 1 P /PH77 1 1 P "0" 0 0 P
/PL66 1 1 P /PL76 1 1 P "0" 0 0 P /PH56 1 1 P /PH66 1 1 P /PH76 1 1 P "0" 0 0 P
/PL65 1 1 P /PL75 1 1 P "0" 0 0 P /PH55 1 1 P /PH65 1 1 P /PH75 1 1 P "0" 0 0 P
/PL64 1 1 P /PL74 1 1 P /PL84 1 1 P /PH54 1 1 P /PH64 1 1 P /PH74 1 1 P /PH84 1 1 P
/PL63 1 1 P /PL73 1 1 P /PL83 1 1 P /PH53 1 1 P /PH63 1 1 P /PH73 1 1 P /PH83 1 1 P
/PL62 1 1 P /PL72 1 1 P /PL82 1 1 P /PH52 1 1 P /PH62 1 1 P /PH72 1 1 P /PH82 1 1 P
/PL61 1 1 P /PL71 1 1 P /PL81 1 1 P /PH51 1 1 P /PH61 1 1 P /PH71 1 1 P /PH81 1 1 P
/PL60 1 1 P /PL70 1 1 P /PL80 1 1 P /PH50 1 1 P /PH60 1 1 P /PH70 1 1 P /PH80 1 1 P
TMR1H[9] TMR1H[8] TMR1H[7] TMR1H[6] TMR1H[5] TMR1H[4] TMR1H[1] TMR1H[0]
0 0 P
0 0 P
0 0 P
0 0 P
0 0 P
0 0 P
0 0 P
0 0 P
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 61
EM78P350N
8-Bit Microprocessor with OTP ROM
Address
Name
Reset Type
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name 0xE RE (TMR2H, Bank 3) Power-on /RESET & WDT Wake-up from Pin change Bit Name 0xF Power-on RF(TMRL, Bank 3) /RESET & WDT Wake-up from Pin change Bit Name Power-on 0x10 ~ R10 ~ R3F /RESET and 0x3F WDT Wake-up from Pin change
Legend: "-" = not used "u" = unknown or don't care
TMR2H[9] TMR2H[8] TMR2H[7] TMR2H[6] TMR2H[5] TMR2H[4] TMR2H[3] TMR2H[2]
0 0 P "0" 0 0 P U P P
0 0 P "0' 0 0 P U P P
0 0 P
0 0 P
0 0 P
0 0 P
0 0 P
0 0 P
TMR3[1] TMR3[0] TMR2[1] TMR2[0] TMR1[3] TMR1[2] 0 0 P U P P 1 1 P U P P 0 0 P U P P 1 1 P U P P 0 0 P U P P 1 1 P U P P
"P" = previous value before reset "t" = check "Reset Type" Table in Section 6.5.2
6.7.1.3 Controller Reset Block Diagram
VDD
D Oscillator
CLK CLR
Power-On Reset Voltage Detector
Q
CLK
W TE
W DT Timeout
W DT
Setup time
Reset
/RESET
Fig. 6-7 Controller Reset Block Diagram
62 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.7.2 The T and P Status under Status 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 T and P as listed in the table below, are used to check how the processor wakes up.
Reset Type T P
Power-on /RESET during Operating mode /RESET wake-up during Sleep mode WDT during Operating mode WDT wake-up during Sleep mode Wake-up on pin change during Sleep mode
1
*P
1
*P
1 0 0 1
0
*P
0 0
*P: Previous status before reset
The following shows the events that may affect the status of T and P.
Event T P
Power-on WDTC instruction WDT time-out SLEP instruction Wake-up on pin changed during Sleep mode
1 1 0 1 1
1 1 *P 0 0
*P: Previous value before reset
6.8
Interrupt
The EM78P350N has seven interrupts as listed below: 1. TCC overflow interrupt 2. Port 6 Input Status Change Interrupt 3. External interrupt [(P52, /INT0), (P53, /INT1) pin] 4. Analog-to-Digital conversion completed 5. When TMR1/TMR2 matches with PRD1/PRD2/PRD3 respectively in PWM 6. When the comparators output changes (for EM78P350N only) 7. Completion of Serial interface transmit/receive Before the Port 6 Input Status Change Interrupt is enabled, reading Port 6 (e.g., "MOV R6, R6") is necessary. Each Port 6 pin will have this feature if its status changes. Any pin configured as output, including the P52 (/INT0), and P53 (/INT1), is excluded from this function. Port 6 Input Status Change Interrupt will wake up the EM78P350N from sleep mode if it is enabled prior to going into sleep mode by executing SLEP. When wake-up occurs, the controller will continue to execute the succeeding program if the global interrupt is disabled. If enabled, it will branch out to the interrupt vector 008H.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 63
EM78P350N
8-Bit Microprocessor with OTP ROM
External interrupt with digital noise rejection circuit (input pulse less than 8 system clock cycle) is eliminated as noise. Edge selection is possible with /INT. Refer to Word 1 Bits 8~7 (Section 6.16.2, Code Option Register (Word 1)) for digital noise rejection definition. RF is the interrupt status register that records the interrupt requests in the relative flags/bits. IOCF is an interrupt mask register. The global interrupt is enabled by the ENI instruction and is disabled by the DISI instruction. When one of the interrupts (when enabled) occurs, the next instruction will be fetched from address 008H. 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 ICIF bit) in the Interrupt Status Register (RF) is set regardless of the status of its mask bit or of the ENI execution. Note that the result of RF will be the logic AND of RF and IOCF (refer to the figure below). The RETI instruction ends the interrupt routine and enables the global interrupt (the ENI execution).
Fig. 6-8 Interrupt Input Circuit
64 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.9
Analog-to-Digital Converter (ADC)
The analog-to-digital circuitry consists of an 8-bit analog multiplexer; three control registers (AISR/R8, ADCON/R9, & ADOC/RA), three data registers (ADDATA1/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.
ADC7 ADC6 ADC5 ADC4
Vref
ADC3 ADC2 ADC1 ADC0 Fsco 4-1 MUX Internal RC 7~0 AISR 2 ADCON 1 0 6 ADCON DATA BUS 5
ADC ( successive approximation )
Power-Down Start to Convert
3 RF
11 10
9
8
7
6
5
4
3
2
1
0
4 ADCON
3
ADDATA1H
ADDATA1L
Fig. 6-9 Analog-to-Digital Conversion Functional Block Diagram
6.9.1 ADC Control Register (AISR/Bank 2 R8, ADCON/ Bank 2 R9, ADOC/ Bank 2 RA)
6.9.1.1 Bank 2 R8 (AISR: ADC Input Select Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
Symbol *Init_Value
ADE7 0
ADE6 0
ADE5 0
ADE4 0
ADE3 0
ADE2 0
ADE1 0
*Init_Value: Initial value at power-on reset
The AISR register individually defines the Port 6 pins as analog inputs or as digital I/O. Bit 7 (ADE7): AD converter enable bit of P67 pin 0 = Disable AIN7, P67 functions as I/O pin 1 = Enable AIN7 to function as analog input pin Bit 6 (ADE6): AD converter enable bit of P66 pin 0 = Disable AIN6, P66 functions as I/O pin 1 = Enable AIN6 to function as analog input pin Bit 5 (ADE5): AD converter enable bit of P65 pin 0 = Disable AIN5, P65 functions as I/O pin 1 = Enable AIN5 to function as analog input pin
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 65
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 4 (ADE4):
AD converter enable bit of P64 pin 0 = Disable AIN4, P64 functions as I/O pin 1 = Enable AIN4 to function as analog input pin
Bit 3 (ADE3):
AD converter enable bit of P63 pin 0 = Disable AIN3, P63 functions as I/O pin 1 = Enable AIN3 to function as analog input pin
Bit 2 (ADE2):
AD converter enable bit of P62 pin 0 = Disable AIN2, P63 functions as I/O pin 1 = Enable AIN2 to function as analog input pin
Bit 1 (ADE1):
AD converter enable bit of P61 pin 0 = Disable AIN1, P61 functions as I/O pin 1 = Enable AIN1 to function as analog input pin
Bit 0 (ADE0):
AD converter enable bit of P60 pin 0 = Disable AIN0, P60 functions as I/O pin 1 = Enable AIN0 to function as analog input pin
NOTE
The P60/AIN0 pin priority is as follows: P60/ADE0 Priority High AIN0 Low P60
6.9.1.2 Bank 2 R9 (ADCON: ADC Control Register)
Bit Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
Symbol
*Init_Value
VREFS 0
CKR1 0
CKR0 0
ADRUN 0
ADPD 0
ADIS2 0
ADIS1 0
ADIS0 0
*Init_Value: Initial value at power on reset
The ADCON register controls the operation of the AD conversion and determines 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 P84/VREF pin carries out the function of P84. 1 = The ADC Vref is connected to P84/VREF.
66 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Bit 6 ~ Bit 5 (CKR1 ~ CKR0): The prescaler oscillator clock rate of ADC 00 = 1:16 (default value) 01 = 1: 4 10 = 1: 64 11 = 1: WDT ring oscillator frequency
CKR1:CKR0 Operation Mode Max. Operation Frequency
00 01 10 11
Fosc/16 Fosc/4 Fosc/64 Internal RC
4MHz 1 MHz 16MHz -
Bit 4 (ADRUN): ADC starts to run 0 = reset on completion of the conversion. This bit cannot be reset though software. 1 = an AD conversion is started. This bit can be set by software. Bit 3 (ADPD): ADC Power-down mode. 0 = switch off the resistor reference to save power even while the CPU is operating. 1 = ADC is operating Bit 2 ~ Bit 0 (ADIS2 ~ ADIS0): Analog Input Select. 000 = AN0/P60 001 = AN1/P61 010 = AN2/P62 011 = AN3/P63 100 = AN4/P64 101 = AN5/P65 110 = AN6/P66 111 = AN7/P67 These bits can only be changed when the ADIF bit and the ADRUN bit are both low.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 67
EM78P350N
8-Bit Microprocessor with OTP ROM
6.9.1.3 Bank 2 RA (ADOC: ADC Offset Calibration Register)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
CALI
SIGN
VOF[2]
VOF[1]
VOF[0]
"0"
"0"
"0"
Bit 7 (CALI): Calibration enable bit for ADC offset 0 = disable Calibration 1 = enable Calibration 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] EM78P350N
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
0LSB 2LSB 4LSB 6LSB 8LSB 10LSB 12LSB 14LSB
Bit 2 ~ Bit 0: Unimplemented, read as `0'.
6.9.2 ADC Data Register (ADDATA/Bank 2 RB, ADDATA1H/Bank 2 RC, ADDATA1L/Bank 2 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.
6.9.3 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 2s for each K of the analog source impedance and at least 2s for the low-impedance source. The maximum recommended impedance for analog source is 10K at Vdd=5V. After the analog input channel is selected, this acquisition time must be done before the conversion is started.
6.9.4 AD Conversion Time
CKR1 and CKR0 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 EM78P350N, the conversion time per bit is 4s.
68 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM The table below shows the relationship between Tct and the maximum operating frequencies.
CKR1: CKR0 Operation Mode Max. Operation Max. Conversion Frequency Rate/Bit Max. Conversion Rate
00 01 10 11
Fosc/16 Fosc/4 Fosc/64 Internal RC
4MHz 1MHz 16MHz -
250kHz (4s) 250kHz (4s) 250kHz ( 4s) 14kHz (71s)
15 x 4s=60s (16.7kHz) 15 x 4s=60s (16.7kHz) 15 x 4s=60s (16.7kHz) 15 x 71s=1065s (0.938kHz)
NOTE
Pin not used as an analog input pin can be used as regular input or output pin. During conversion, do not perform output instruction to maintain precision for all the pins.
6.9.5 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, Timer 1, Timer 2, Timer 3, Timer 4 and AD conversion. The AD Conversion is considered completed as determined by: 1. ADRUN bit of R9 register is cleared ("0" value) 2. Wake-up from AD conversion (where it remains in operation during sleep mode) The results are fed into the ADDATA, ADDATA1H, and ADDATA1L registers when the conversion is completed. If the ADWE is enabled, the device will wake up. Otherwise, the AD conversion will be shut off, no matter what the status of ADPD bit is.
6.9.6 Programming Process/Considerations
6.9.6.1 Programming Process Follow these steps to obtain data from the ADC: 1. Write to the 8 bits (ADE7:ADE0) on the Bank 2 R8 (AISR) register to define the characteristics of R6 (digital I/O, analog channels, or voltage reference pin). 2. Write to the Bank 2 R9/ADCON register to configure the AD module: a) Select ADC input channel (ADIS2: ADIS0). b) Define 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.
Product Specification (V 1.0) 09.14.2006
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EM78P350N
8-Bit Microprocessor with OTP ROM
6. Set the ADRUN bit to 1. 7. Write "SLEP" instruction or Polling. 8. Wait for wake-up or for ADRUN bit to be cleared ("0" value). 9. Read the ADDATA or ADDATA1H and ADDATA1L conversion data registers. If 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). 11. For 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 I/O pins during AD conversion.
6.9.6.2 Sample Demo Programs A. Define a General Registers R_0 == 0 PSW == 3 PORT5 == 5 PORT6 == 6 RE== 0XE RF== 0XF ; Indirect addressing register ; Status register
; Wake-up control resister ; 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 E. Program Starts ORG 0 JMP INITIAL ORG 0x08 ; ;
70 *
; ADC is executed as the bit is set ; Power Mode of ADC
; Initial address ; ; Interrupt vector
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
;(User program section) ; ; CLR RF ; To clear the ADIF bit BS ADCON, ADRUN ; To start to execute the next AD conversion ; if necessary RETI INITIAL: Bank 1 MOV A,@0B00000001 ; To define P60 as an analog input MOV AISR,A MOV A,@0B00001000 ; To select P60 as an analog input channel, and AD power on MOV ADCON,A ; To define P60 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 PORT6 ; 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 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 (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 71
EM78P350N
8-Bit Microprocessor with OTP ROM
6.10 Dual Sets of PWM (Pulse Width Modulation) 6.10.1 Overview
In PWM mode, PWM1, PWM2, and PWM3 pins generate a 10-bit resolution PWM output (see. the functional block diagram below). A PWM output consists of a time period and a duty cycle, and it keeps the output high. The baud rate of the PWM is the inverse of the time period. Fig. 6 -11 (PWM Output Timing) depicts the relationship between a time period and a duty cycle.
DL2H + DL2L
latch To PWM1IF
Fosc
1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
DT1H + DT1L MUX Comparator
Duty Cycle Match
PWM1 R Q
TMR1H + TMR1L
reset
S
bank1-R5,7
Comparator
T1P2 T1P1 T1P0 T1EN
Period Match
PRD1 Data Bus
DL2H + DL2L
latch
Data Bus
To PWM2IF
T2P2 T2P1 T2P0 T2EN
DT2H + DT2L
Comparator
Duty Cycle Match
PWM2 Fosc
TMR2H + TMR2L
1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
reset
R S
Q
MUX Comparator
Period Match
bank1-R5,6
PRD2
latch To PWM3IF
Fosc
1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
DL3H + DL3L
DT3H + DT3L MUX Comparator
Duty Cycle Match
PWM3 R Q
TMR3H + TMR3L
reset
S
bank1-R5,5
Comparator
T3P2 T3P1 T3P0 T3EN
Period Match
PRD3 Data Bus Data Bus
Fig. 6-10 The Three PWMs Functional Block Diagram 72 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Period
Duty Cycle DT1 = TMR1
PRD1 = TMR1
Fig. 6-11 PWM Output Timing
6.10.2 Increment Timer Counter (TMRX: TMR1H/TWR1L, TMR2H /TWR2L, or TMR3H/TWR3L)
TMRX are 10-bit clock counters with programmable prescalers. They are designed for the PWM module as baud rate clock generators. TMRX can be read only. If employed, they can be turned off for power saving by setting the T1EN bit [Bank 1 R5 <3>], T2EN bit [Bank 1 R6 <7>] or T3EN bit [Bank 1 R6 <3>] to 0.
6.10.3 PWM Time Period (PRDX : PRD1 or PRD2)
The PWM time period is defined by writing to the PRDX register. When TMRX is equal to PRDX, the following events occur on the next increment cycle: TMRX is cleared The PWMX pin is set to 1 The PWM duty cycle is latched from DT1/DT2/DT3 to DL1/DL2/DL3
NOTE The PWM output will not be set, if the duty cycle is 0.
The PWMXIF pin is set to 1 The following formula describes how to calculate the PWM time period: PERIOD = (PRDX + 1) * (1/Fosc) * CLKS/2 * (TMRX prescale value ) Example: PRDX=49; Fosc=4MHz; CLKS bit of Code Option Register =0 (2 oscillator periods); TMRX (0, 0, 0) = 1:2, then PERIOD=(49 + 1) * (1/4M) * 2/2 * 2 = 25us
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
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EM78P350N
8-Bit Microprocessor with OTP ROM
6.10.4 PWM Duty Cycle(DTX: DT1H/ DT1L, DT2H/ DT2L and DT3H/DT3L; DLX: DL1H/DL1L, DL2H/DL2L and DL3H/DL3L )
The PWM duty cycle is defined by writing to the DTX register, and is latched from DTX to DLX while TMRX is cleared. When DLX is equal to TMRX, the PWMX pin is cleared. DTX can be loaded anytime. However, it cannot be latched into DLX until the current value of DLX is equal to TMRX. The following formula describes how to calculate the PWM duty cycle: Duty Cycle = (DTX) * (1/Fosc) * CLKS/2 * (TMRX prescale value ) Example: DTX=10; Fosc=4MHz; CLKS bit of Code Option Register = 0 (2 oscillator periods); TMRX (0,0,0)=1:2, then Duty Cycle = 10 * (1/4M) * 2/2 * 2 =5us
6.10.5 Comparator X
Changing the output status while a match occurs will simultaneously set the TMRXIF flag.
6.10.6 PWM Programming Process/Steps
1. Load PRDX with the PWM time period. 2. Load DTX with the PWM Duty Cycle. 3. Enable interrupt function by writing IOCF, if required. 4. Set PWMX pin to be output by writing a desired value to Bank1 R5 or R6. 5. Load a desired value to Bank1 R5 or R6 with TMRX prescaler value and enable both PWMX and TMRX.
6.11 Timer 6.11.1 Overview
Timer 1 (TMR1), Timer 2 (TMR2), and Timer 3 (TMR3) (TMRX) are 10-bit clock counters with programmable prescalers. They are designed for the PWM module as baud rate clock generators. TMRX can be read only. The Timer 1, Timer 2, and Timer 3 will stop running when sleep mode occurs with AD conversion not running. However, if AD conversion is running when sleep mode occurs, the Timer 1, Timer 2 and Timer 3, will keep on running.
74 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.11.2
Function Description
The following figure shows the TMRX block diagram followed by descriptions of its signals and blocks:
Fosc
1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
MUX TMR1X
reset
To PWM1IF Period Match
Comparator
T1P2 T1P1 T1P0 T1EN
PRD1 Data Bus Data Bus
PRD2
T2P2 T2P1 T2P0 T2EN
Comparator
Period Match
Fosc 1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
TMR2X MUX
reset
To PWM2IF
*TMR1X = TMR1H + TMR1L; *TMR2X = TMR2H + TMR2L; *TMR3X = TMR3H + TMR3L
Fosc
1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256
MUX TMR3X
reset
To PWM13F Period Match
Comparator
T3P2 T3P1 T3P0 T3EN
PRD3 Data Bus Data Bus
Fig. 6-12 TMRX Block Diagram
Fosc: Input clock. Prescaler (T1P2, T1P1 and T1P0 / T2P2, T2P1 and T2P0 / T3P2, T3P1 and T3P0): The options 1:2, 1:4, 1:8, 1:16, 1:32, 1:64, 1:128, and 1:256 are defined by TMRX. It is cleared when any type of reset occurs. TMR1X, TMR2X and TMR3X (TMR1H/TWR1L, TMR2H/TMR2L, & TMR3H/TMR3L): Timer X register; TMRX is incremented until it matches with PRDX, and then is reset to 1 (default valve). PRDX (PRD1/PRD1H, PRD2/PRD2H and PRD3/PRD3H): PWM time period register. ComparatorX (Comparator 1 and Comparator 2): Reset TMRX while a match occurs. The TMRXIF flag is set at the same time.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 75
EM78P350N
8-Bit Microprocessor with OTP ROM
6.11.3 Programming the Related Registers
When defining TMRX, refer to the related registers of its operation as shown in the table below. It must be noted that the PWMX bits must be disabled if their related TMRXs are employed. That is, Bit 7 ~ Bit 5 of the PWMCON register must be set to `0'. 6.11.3.1 Related Control Registers of TMR1, TMR2, and TMR3
Address Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0x05 0x06
PWMCON#1/Bank1 R5 PWM3E PWM2E PWM1E PWMCON#2/Bank1 R6 T2EN T2P2 T2P1
"0"
T1EN T1P2 T1P1 T1P0
T2P0 T3EN T3P2 T3P1 T3P0
6.11.4
Timer Programming Process/Steps
1. Load PRDX with the TIMER duration 2. Enable interrupt function by writing IOCF, if required 3. Load a desired a TMRX prescaler value to PWMCON and TMRCON and enable TMRX and disable PWMX
6.12 Comparator
EM78P350N has one comparator comprising of two analog inputs and one output. The comparator can be utilized to wake up the EM78P350N from sleep mode. The comparator circuit diagram is depicted in the figure below.
Cin Cin+ CMP + CO
CinCin+
Output
10mV
Fig. 6-13 Comparator Circuit Diagram & Operating Mode
76 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.12.1
External Reference Signal
The analog signal that is presented at Cin- compares to the signal at Cin+, and 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.
6.12.2 Comparator Outputs
The compared result is stored in the CMPOUT of IOCA0. The comparator outputs are sent to CO (P56) through programming Bit 1, Bit 0 of the IOCA0 register to <1, 0>. See Section 6.2.7, IOCA0 (CMPCON: Comparator Control Register) for Comparator/OP select bits function description.
NOTE The P56/CO pin priority is as follows: P60/ADE0/CO Priority High Low CO P56
The following figure shows the Comparator Output block diagram.
To C0 From OP I/O CMRD
EN
EN
Q To CMPOUT
D
Q
D
RESET To CPIF CMRD From other comparator
Fig. 6-14 Comparator Output Configuration
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 77
EM78P350N
8-Bit Microprocessor with OTP ROM
6.12.3 Using Comparator as an Operation Amplifier
The comparator can be used as an operation amplifier if a feedback resistor is connected from the input to the output externally. In this case, the Schmitt Trigger can be disabled for power saving by setting Bit 1, Bit 0 of the IOCA0 register to <1, 1>. See Section 6.2.6, IOCA0 (CMPCON: Comparator Control Register) for Comparator/OP select bits function description.
6.12.4
Comparator Interrupt
CMPIE (IOCE.0) 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, IOCA0 < 2 >. CMPIF (RE.0), the comparator interrupt flag, can only be cleared by software.
6.12.5
Wake-up from Sleep Mode
If enabled, the comparator remains active and the interrupt remains functional, even in Sleep mode. If a mismatch occurs, the interrupt 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.
6.13 Oscillator 6.13.1 Oscillator Modes
The EM78P350N can be operated in four different oscillator modes namely, High Crystal oscillator mode (HXT), Low Crystal oscillator mode (LXT), External RC oscillator mode (ERC), and RC oscillator mode with Internal RC oscillator mode (IRC). One of such modes can be selected 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 1
ERC (External RC oscillator mode); P50/OSCO acts as P50 ERC (External RC oscillator mode); P50/OSCO acts as OSCO IRC (Internal RC oscillator mode); P50/OSCO acts as P50 IRC (Internal RC oscillator mode); P50/OSCO acts as OSCO LXT (Low Crystal oscillator mode) HXT High Crystal oscillator mode) (default)
1 2 3
0 0 0 0 1 1
0 0 1 1 1 1
0 1 0 1 0 1
2 2
3
3
In ERC mode, OSCI is used as oscillator pin. OSCO/P50 is defined by code option Word 0 Bit 6 ~ Bit 4. In IRC mode, P55 is normal I/O pin. OSCO/P50 is defined by code option Word 0 Bit 6 ~ Bit 4. In 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.
78 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
NOTE The transient point of the system frequency between HXT and LXY is 400kHz.
The maximum operating frequency limit of crystal/resonator at different VDDs, are as follows:
Conditions VDD Max. Freq. (MHz)
2.3 Two clocks 3.0 5.0
4 8 20
6.13.2
Crystal Oscillator/Ceramic Resonators (Crystal)
The EM78P350N can be driven by an external clock signal through the OSCI pin as illustrated below.
OSCI EM78P330 OSCO
Ext. Clock
Fig. 6.15 External Clock Input Circuit
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 79
EM78P350N
8-Bit Microprocessor with OTP ROM In the 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 a circuit. The same applies to the HXT mode and the LXT mode.
C1 OSCI EM78P330 OSCO RS C2 XTAL
Fig. 6-16 Crystal/Resonator Circuit
The following table provides the recommended values for C1 and C2. Since each resonator has its own attribute, user should refer to the resonator specifications for 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 Frequency C1 (pF) C2 (pF)
455 kHz Ceramic Resonators HXT 2.0 MHz 4.0 MHz 32.768 kHz LXT Crystal Oscillator HXT 100 kHz 200 kHz 455 kHz 1.0 MHz 2.0 MHz 4.0 MHz
100~150 20~40 10~30 25 25 25 20~40 15~30 15 15
100~150 20~40 10~30 15 25 25 20~150 15~30 15 15
6.13.3
External RC Oscillator Mode
Vcc Rext
For some applications that do not require precise timing calculation, the RC oscillator (Fig. 6-17 at right) offers a costeffective solution. 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 manufacturing process variations.
80 *
OSCI Cext EM77P330
Fig. 6-17 External RC Oscillator Mode Circuit Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
In order to maintain a stable system frequency, the values of the Cext should be no less than 20pF, and the value of Rext should be no greater than 1M. 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 K, the oscillator will become unstable because the NMOS cannot correctly discharge the capacitance current. 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 effects on the system frequency. The RC Oscillator frequencies:
Cext Rext Average Fosc 5V, 25C Average Fosc 3V, 25C
3.3k 20 pF 5.1k 10k 100k 3.3k 100 pF 5.1k 10k 100k 3.3k 300 pF 5.1k 10k 100k
Note: : Measured based on DIP packages.
2 3 1
3.5 MHz 2.5 MHz 1.30 MHz 140 kHz 1.27 MHz 850 kHz 450 kHz 48 kHz 560 kHz 370 kHz 196 kHz 20 kHz
3.2 MHz 2.3 MHz 1.25 MHz 140 KHz 1.21 MHz 820 kHz 450 kHz 50 kHz 540 kHz 360 kHz 192 kHz 20 kHz
: The values are for design reference only. : The frequency drift is 30%
6.13.4 Internal RC Oscillator Mode
The EM78P350N offers a versatile internal RC mode with default frequency value of 4MHz. Internal RC oscillator mode has other frequencies (1 MHz, 8 MHz, and 455 kHz) that can be set by Code Option (Word 1), RCM1, and RCM0. The Table below describes the EM78P350N internal RC drift with voltage, temperature, and process variations.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 81
EM78P350N
8-Bit Microprocessor with OTP ROM
Internal RC Drift Rate (Ta=25C, VDD=5V 5%, VSS=0V)
Drift Rate Internal RC Frequency Temperature (-40C~+85C) Voltage (2.3V~5.5V) Process Total
4MHz 8MHz 1MHz 455MHz
10% 10% 10% 10%
5% 6% 5% 5%
4% 4% 4% 4%
19% 20% 19% 19%
Theoretical values are for reference only. Actual values may vary depending on the actual process.
6.14 Power-on Considerations
Any microcontroller is not warranted to start operating properly before the power supply stabilizes to a steady state. The EM78P350N has a built-in Power-on Voltage Detector (POVD) with detection level range of 1.9V to 2.1V. The circuitry eliminates the extra external reset circuit. It will work well if Vdd rises quickly enough (50 ms or less). However, under critical applications, extra devices are still required to assist in solving power-on problems.
6.14.1 External Power-on Reset Circuit
The circuits shown in the VDD following figure implements an external RC to produce a /RESET R D reset pulse. The pulse width (time constant) should EM78P330 be kept long enough to Rin C allow Vdd to reach the minimum operating voltage. This circuit is used when the power supply has a slow Fig. 6-18 External Power on Reset Circuit power rise time. Because the current leakage from the /RESET pin is about 5A, 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) functions 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.
82 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.14.2 Residual Voltage Protection
When the battery is replaced, device power (Vdd) is removed but 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. 6-16 and Fig. 6-20 show how to create a protection circuit against residual voltage.
VDD EM78P330 Q1 /RESET 100K 1N4684 10K 33K
VDD
Fig. 6-19 Residual Voltage Protection Circuit 1
VDD EM78P330 Q1 /RESET R3 R2 R1
VDD
Fig. 6-20 Residual Voltage Protection Circuit 2
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 83
EM78P350N
8-Bit Microprocessor with OTP ROM
6.15 LVD (Low Voltage Detector)
During the power source unstable situation, such like external power noise interference of EMS test condition, it will cause the power vibrate fierce. At the time the Vdd is unsettled, it may be below working voltage. When system supplies voltage, Vdd, below the working voltage, the IC kernel must keep all register status automatically. LVD property is setting at Register RE, Bit 1, 0 detail operation mode as follows:
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
"0"
"0"
"0"
"0"
LVDEN
/LVD
LVD1
LVD0
Bits 1 ~ 0 (LVD1 ~ LVD0): Low Voltage Detect level control Bits.
LVDEN LVD1,LVD0 LVD Voltage Interrupt Level LVDIF
1 1 1 1 0
11 10 01 00 XX
2.2V 3.3V 4.0V 4.5V NA
1* 1* 1* 1* 0
* If Vdd has crossover at LVD voltage interrupt level as Vdd changes, LVDIF =1. The LVD status and interrupt flag is referred to as RF
Register Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
RF
"0"
"0"
"0"
LVDIF
ADWE CMPWE ICWE PWMWE
Note: "1" means with interrupt request
"0" means no interrupt occurs
Bit 4 (LVDIF): Low Voltage Detector Interrupt Register
The following steps are needed to setup the LVD function: Set the LVDEN of Register RE of Bank 2 to"1", then use Bit 1, 0 (LVD1, LVD0) of Register RE of Bank 2 to set the LVD interrupt level while waiting for an interrupt to occur. The internal LVD module is using internal circuit to fit. When you set the LVDEN enable the LVD module. The current consumption will increase about 10A. During sleep mode, the LVD module continues to operate. If the device voltage drops slowly and crosses the detect point, the LVDIF bit will be set and device won't wake up from sleep time. Until the other wake-up source of EM78P350N, the LVD interrupt flag still set as the prior status. When the system resets, the LVD flag will be cleared. When Vdd drops not below VLVD, LVDIF remains at "0".
84 * Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM When Vdd drops below VLVD, LVDIF is set to "1". If in global ENI enable, LVDIF will be set to "1", the next instruction will branch to an interrupt vector. The LVD interrupt flag is cleared to "0" by software. When Vdd drops below VRESET to less than 80s, the system will ignore it and keep going. When Vdd drops below VRESET to more than 80s, a system reset will occur. Refer to Section 6.5.1 for Reset description.
6.16 Code Option
The EM78P350N has two Code option words and one Customer ID word that are not part of the normal program memory.
Word 0 Word 1 Word 2
Bit 12 ~ Bit 0
Bit 12 ~ Bit 0
Bit 12 ~ Bit 0
6.16.1 Code Option Register (Word 0)
Word 0 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
-
LVR1 LVR0
LCE
CLKS ENWDTB OSC2 OSC1 OSC0 HLP
PR2
PR1
PR0
Bit 12: Unimplemented, read as "0". Bits 11 ~ 10: Low voltage reset enable bits.
LVR1, LVR0 Reset Level Release Level
00 01 10 11
4.0V 3.5V 2.7V NA
4.2V 3.7V 2.9V NA
If VDD < 1.8V, the IC will be reset. If VDD < 2.7V, the IC will be reset. If VDD < 3.5V, the IC will be reset. If VDD < 4.0V, the IC will be reset.
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 85
EM78P350N
8-Bit Microprocessor with OTP ROM Bit 9 (LCE): Low crystal output enable 1 : Select General-purpose I/O (P74, P73) 0 : Low crystal 32.768kHz mode. P74, P73 can be connected to a low crystal. Bit 8 (CLKS): Instruction time period option bit 0 = two oscillator time periods 1 = four oscillator time periods (default) Refer to the Section 6.15 for Instruction Set Bit 7 (ENWDTB): Watchdog timer enable bit 0 = Enable 1 = Disable (default) Bits 6, 5 & 4 (OSC2, OSC1 & OSC0): Oscillator Modes Selection bits
Oscillator Modes OSC2 OSC1 OSC0
ERC (External RC oscillator mode); P50/OSCO functions as P50 ERC (External RC oscillator mode); P50/OSCO functions as OSCO IRC (Internal RC oscillator mode); P50/OSCO functions as P50 IRC (Internal RC oscillator mode); P50/OSCO functions as OSCO LXT (Low Crystal oscillator mode) HXT (High Crystal oscillator mode) (default)
1 2 3
1 1
0 0 0 0 1 1
0 0 1 1 1 1
0 1 0 1 0 1
2
2
3
3
In ERC mode, OSCI is used as oscillator pin. OSCO/P50 is defined by code option Word 0 Bit 6 ~ Bit 4. In IRC mode, P51 is normal I/O pin. OSCO/P50 is defined by code option Word 0 Bit 6 ~ Bit 4. In 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 400kHz.
Bit 3 (HLP): Power consumption selection 0 = Low power consumption, applies to working frequency at 4MHz or below 4MHz 1 = High power consumption, applies to working frequency above 4MHz Bits 2 ~ 0 (PR2 ~ PR0): Protect Bit PR2 ~ PR0 are protection bits. Each protect status is as follows:
PR2 PR1 PR0 Protect
0 0 0 0 1 1 1 1
86 *
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
Enable Enable Enable Enable Enable Enable Enable Disable
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
6.16.2 Code Option Register (Word 1)
Word 1 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
-
-
-
POREN NRHL NRE
CYES
C3
C2
C1
C0
RCM1 RCM0
Bits 12~10: Not used, (reserved). These bits are set to "1" all the time. Bit 9 (POREN): Power on Reset Enable/Disable bit 0 = Disable power-on reset 1 = Enable power-on reset (default) Bit 8 (NRHL): Noise rejection high/low pulses define bit when the signal at INT pin has a falling edge trigger. 0 = Pulses equal to 8/fc is regarded as signal 1 = Pulses equal to 32/fc is regarded as signal (default)
NOTE The noise rejection function is turned off under the LXT and sleep mode.
Bit 7 (NRE): Noise rejection enable 0 = disable noise rejection 1 = enable noise rejection (default). However in Low Crystal oscillator (LXT) mode, the noise rejection circuit is always disabled. Bit 6 (CYES): Instruction cycle selection bit 0 = one instruction cycle 1 = two instruction cycles (default) Bits 5, 4, 3 & Bit 2 ( C3, C2, C1, & C0 ): Internal RC mode Calibration bits. These bits must always 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 0 0
1 0 1 0
4 8 1 455kHz
6.15.3 Customer ID Register (Word 2)
Word 2 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 x x x x x Bit 7 x Bit 6 Bit 5 x x Bit 4 Bit 3 Bit 2 x x x Bit 1 x Bit 0 x
Bits 12 ~ 0 : Customer's ID code
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 87
EM78P350N
8-Bit Microprocessor with OTP ROM
6.17
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 time 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.
Convention: R = Register designator that specifies which one of the registers (including operation and general purpose
registers) is to be utilized by the instruction.
b = Bit field designator that selects the value for the bit located in the register R and which affects the
operation.
k = 8 or 10-bit constant or literal value
Binary Instruction
HEX
Mnemonic
Operation
Status Affected
0 0000 0000 0000 0 0000 0000 0001 0 0000 0000 0010 0 0000 0000 0011 0 0000 0000 0100 0 0000 0000 rrrr 0 0000 0001 0000 0 0000 0001 0001 0 0000 0001 0010 0 0000 0001 0011 0 0000 0001 0100 0 0000 0001 rrrr 0 0000 01rr rrrr 0 0000 1000 0000 0 0000 11rr rrrr 0 0001 00rr rrrr 0 0001 01rr rrrr 0 0001 10rr rrrr 0 0001 11rr rrrr
0000 0001 0002 0003 0004 000r 0010 0011 0012 0013 0014 001r 00rr 0080 00rr 01rr 01rr 01rr 01rr
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
No Operation Decimal Adjust A A CONT 0 WDT, Stop oscillator 0 WDT A IOCR Enable Interrupt Disable Interrupt [Top of Stack] PC CONT A IOCR A AR 0A 0R R-A A R-A R R-1 A R-1 R
None C None T, P T, P None1 None None None
[Top of Stack] PC, Enable Interrupt None None None1 None Z Z Z,C, DC Z,C, DC Z Z
88 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
Binary Instruction
HEX
Mnemonic
Operation
Status Affected
0 0010 00rr rrrr 0 0010 01rr rrrr 0 0010 10rr rrrr 0 0010 11rr rrrr 0 0011 00rr rrrr 0 0011 01rr rrrr 0 0011 10rr rrrr 0 0011 11rr rrrr 0 0100 00rr rrrr 0 0100 01rr rrrr 0 0100 10rr rrrr 0 0100 11rr rrrr 0 0101 00rr rrrr 0 0101 01rr rrrr 0 0101 10rr rrrr 0 0101 11rr rrrr 0 0110 00rr rrrr 0 0110 01rr rrrr 0 0110 10rr rrrr 0 0110 11rr rrrr 0 0111 00rr rrrr 0 0111 01rr rrrr 0 0111 10rr rrrr 0 0111 11rr rrrr 0 100b bbrr rrrr 0 101b bbrr rrrr 0 110b bbrr rrrr 0 111b bbrr rrrr 1 00kk kkkk kkkk 1 01kk kkkk kkkk
02rr 02rr 02rr 02rr 03rr 03rr 03rr 03rr 04rr 04rr 04rr 04rr 05rr 05rr 05rr 05rr 06rr 06rr 06rr 06rr 07rr 07rr 07rr 07rr 0xxx 0xxx 0xxx 0xxx 1kkk 1kkk
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
A VR A A VR R A&RA A&RR ARA ARR A+RA A+RR RA RR /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) R(4-7) R+1 A, skip if zero R+1 R, skip if zero 0 R(b) 1 R(b) if R(b)=0, skip if R(b)=1, skip PC+1 SP, (Page, k ) PC (Page, k ) PC
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 None None1 None2 None None None None
SWAPA R R(0-3) A(4-7), R(4-7) A(0-3) SWAP R JZA R JZ R BC R,b BS R,b JBC R,b JBS R,b CALL k JMP k
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 89
EM78P350N
8-Bit Microprocessor with OTP ROM
Binary Instruction
HEX
Mnemonic
Operation
Status Affected
1 1000 kkkk kkkk 1 1001 kkkk kkkk 1 1010 kkkk kkkk 1 1011 kkkk kkkk 1 1100 kkkk kkkk 1 1101 kkkk kkkk 1 1110 1000 kkkk 1 1110 1001 kkkk 1 1111 kkkk kkkk
1 2 3
18kk 19kk 1Akk 1Bkk 1Ckk 1Dkk 1E8k 1E9k 1Fkk
MOV A,k OR A,k AND A,k XOR A,k RETL k SUB A,k PAGE k BANK k ADD A,k
kA AkA A&kA AkA k A, [Top of Stack] PC k-A A k R1(5:4) k R1(1:0) k+A A
None Z Z Z None Z,C,DC None None Z, C, DC
Note: This instruction is applicable to IOC50 ~ IOCF, IOC51 ~ IOCF1 only.
This instruction is not recommended for RF operation This instruction cannot operate under RF.
7
Absolute Maximum Ratings
Items Rating
Temperature under bias Storage temperature Input voltage Output voltage Working Voltage Working Frequency
-40C -65C Vss-0.3V Vss-0.3V 2.3V DC
to to to to to to
85C 150C Vdd+0.5V Vdd+0.5V 5.5V 20MHz
90 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
8
DC Electrical Characteristics
Ta= 25 C, VDD= 5.0V, VSS= 0V
Parameter Crystal: VDD to 5V Crystal: VDD to 3V ERC: VDD to 5V IRC:VDD to 5V IRC:VDD to 5V IRC:VDD to 5V IRC:VDD to 5V Input High Threshold Voltage (Schmitt Trigger ) Input Low Threshold Voltage (Schmitt Trigger ) Input Leakage Current for input pins Input High Voltage (Schmitt Trigger ) Input Low Voltage (Schmitt Trigger ) Input High Threshold Voltage (Schmitt Trigger ) Input Low Threshold Voltage (Schmitt Trigger ) Input High Threshold Voltage (Schmitt Trigger ) Input Low Threshold Voltage (Schmitt Trigger ) Clock Input High Voltage Clock Input Low Voltage Output High Voltage (Ports 50~53, Ports 60~63) (Ports 70~77, Ports 80~84) Output High Voltage (Ports P54~P57, P64~P67) Output Low Voltage (Ports 50~53, Ports 60~63) (Ports 70~77, Ports 80~84) Output Low Voltage (Ports P54~P57, P64~P67) Output Sink Current Output Drive Current Pull-high current Pull-low current Condition Min. DC DC F30% 3.84 7.68 0.96 436.8 - - Typ. Max. 20 8 F30% 4.16 8.32 1.06 473.2 - - Unit MHz MHz kHz MHz MHz MHz kHz
Symbol
FXT IRC1 IRC2 IRC3 IRC4 VIHRC VILRC IIL VIH1 VIL1 VIHT1 VILT1 VIHT2 VILT2 VIHX1 VILX1 IOH1 IOH2 IOL1 IOL2 IBOL IBOH IPH IPL ISB1 ISB2 ICC1 ICC2 ICC3 ICC4
Two cycles with two clocks R: 5.1K, C: 100 pF RCM0:RCM1=1:1 RCM0:RCM1=1:0 RCM0:RCM1=0:1 RCM0:RCM1=0:0 OSCI in RC mode OSCI in RC mode VIN = VDD, VSS Ports 5, 6, 7, 8 Ports 5, 6, 7, 8 /RESET /RESET TCC,INT TCC,INT OSCI in crystal mode OSCI in crystal mode VOH = VDD-0.5V (IOH =-6mA) VOH = VDD-0.5V (IOH =-9mA) VOL = GND+0.5V (IOL =12mA) VOL = GND+0.5V (IOL =24mA) Buzzer output sink current Buzzer output drive current Pull-high active, input pin at VSS Pull-low active, input pin at Vdd All input and I/O pins at VDD, Output pin floating, WDT disabled All input and I/O pins at VDD, Output pin floating, WDT enabled /RESET= 'High', Fosc=32kHz, (Crystal type, CLKS="0"), Output pin floating, WDT disabled /RESET= 'High', Fosc=32kHz (Crystal type, CLKS="0"), Output pin floating, WDT enabled /RESET= 'High', Fosc=4MHz (Crystal type, CLKS="0"), Output pin floating, WDT enabled /RESET= 'High', Fosc=10MHz (Crystal type, CLKS="0"), Output pin floating, WDT enabled
850 4.0 8.0 1.0 455 3.5 1.5 0 3.75 1.25 2.0 1.0 3.75 1.25 3.5 1.5 -9.0 -12.0 18.0 24.0 24 24 -75 40 1.0
-
V V
A
-1.0
- - - - - - - - - - - - - - -50 25 - -
1.0
- - - - - - - - - - - - - - -240 120
V V V V V V V V mA mA mA mA mA mA A A
A A A A
Power down current Power down current Operating supply current at two clocks Operating supply current at two clocks Operating supply current at two clocks Operating supply current at two clocks
2.0 15 35 35 2.2 3.5
15
20 25 1.7 3.0
mA mA
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 91
EM78P350N
8-Bit Microprocessor with OTP ROM
8.1
AD Converter Characteristic Vdd=2.5V to 5.5V, Vss=0V, Ta=25C
Symbol
Parameter
Condition
Min.
Typ. - - -
Max.
Unit
VAREF VASS VAI IAI1 IAI2 Ivdd Ivref Ivdd IVref
Analog reference voltage Analog input voltage Analog supply current Analog supply current
VAREF - VASS 2.3V
-
2.3 Vss VASS 750 -10 500 200 450 10 0 0 0 0 0 4 15 0 0 4.7 0.1 0
Vdd Vss VAREF 1000 +10 820 300 650
-
V V V uA uA uA uA uA Bits LSB LSB LSB LSB K us TAD V V V/us LSB
Vdd=VAREF=5.0V, VASS =0.0V (V reference from Vdd) Vdd=VAREF=5.0V, VASS =0.0V (V reference from VREF) Vdd=5.0V, OP used Output voltage swing 0.15V to 4.85V Vdd=VAREF=5.0V, VASS =0.0V Vdd = 2.3 to 5.5V Ta=25 Vdd = 2.3 to 5.5V Ta=25 Vdd=VAREF=5.0V, VASS =0.0V Vdd=VAREF=5.0V, VASS =0.0V
-
850 0 600 250 550 11 4 0.5 4 2 8
- - -
IOP RN LN DNL FSE OE ZAI TAD TCN ADIV ADOV ADSR PSR
OP current Resolution Linearity error Differential nonlinear error Full scale error Offset error Recommended impedance of analog voltage source ADC clock duration AD conversion time ADC OP input voltage range ADC OP output voltage swing ADC OP slew rate Power Supply Rejection
8 0.9 8 4 10
-
Vdd=VAREF=5.0V, VASS =0.0V Vdd=VAREF=5.0V, VASS =0.0V Vdd=VAREF=5.0V, VASS =0.0V Vdd=VAREF=5.0V, VASS =0.0V, RL=10K Vdd=VAREF=5.0V, VASS =0.0V Vdd=5.0V0.5V
15 VAREF 0.3 5
-
0.2 4.8 0.3
-
2
Note: 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. 4. These parameters are subject to change without further notice.
8.2
Comparator (OP) Characteristic Vdd = 5.0V, Vss=0V, Ta=25C
Symbol SR IVR
Parameter Slew rate Input voltage range
Condition - Vdd =5.0V, VSS =0.0V
OVS Iop Ico PSRR Vs
Output voltage swing
Vd =5.0V, VSS =0.0V, RL=10K
Supply current of OP - Supply current of Comparator - Power-supply Rejection Vdd= 5.0V, VSS =0.0V Ration for OP Operating range -
Min. 0.1 0 0 4.7 250 -
Typ. 0.2
Max.
0.2 4.8 350 300 60
-
5 0.3 5 500 - 70 5.5
Unit V/us V
V A A dB V
50 2.5
Note: 1. These parameters are hypothetical (not tested) and are provided for design reference use only. 2. These parameters are subject to change without further notice.
92 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
8.3
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)
Frequency (M Hz) .
Temperature (
)
Fig. 8-1 Internal RC OSC Frequency vs. Temperature, VDD=3V
IRC OSC Frequency (VDD=5V)
Frequency (M Hz) .
Temperature ( )
Fig. 8-2 Internal RC OSC Frequency vs. Temperature, VDD=5V
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 93
EM78P350N
8-Bit Microprocessor with OTP ROM
9
AC Electrical Characteristic
Ta=25 C, VDD=5V5%, VSS=0V
Symbol Parameter Conditions - Min Type Max Unit
Dclk Tins Ttcc Tdrh Trst Twdt Tset Thold Tdelay Tdrc
Input CLK duty cycle Instruction cycle time (CLKS="0") TCC input time period Device reset hold time /RESET pulse width Watchdog timer duration Input pin setup time Input pin hold time Output pin delay time ERC delay time
45 100 500 (Tins+20) x N* 11.3 2000 11.3
-
50
- - -
55 DC DC
-
% ns ns ns ms ns
Crystal type RC type
-
Ta = 25C Ta = 25C Ta = 25C
- -
16.2
21.6
16.2 0 20 50 3
21.6
ms ns
15 45 1
25 55 5
ns ns ns
Cload=20pF Ta = 25C
Note: * N = selected prescaler ratio
94 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
10 Timing Diagrams
AC Test Input/Output Waveform
VDD-0.5V 0.75VDD 0.25VDD GND+0.5V
TEST POINTS
0.75VDD 0.25VDD
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
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 95
EM78P350N
8-Bit Microprocessor with OTP ROM
APPENDIX A Package Type
OTP MCU Package Type Package size Pin Count
EM78P350NP EM78P350NM EM78P350NK EM78P350NAM EM78P351NM EM78P351NK EM78P351NQ EM78P351NP
DIP SOP SDIP SDIP SOP Skinny DIP LQFP DIP
600mil 300mil 400mil 300mil 300mil 400mil 7*7m
2
28 pins 28 pins 28 pins 28 pins 32 pins 32 pins 32 pins 32 pins
600mil
B Packaging Configurations
B.1 28-Lead Plastic Dual in line (PDIP) 600 mil
96 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
B.2
28-Lead Plastic Small Outline (SOP)
300 mil
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 97
EM78P350N
8-Bit Microprocessor with OTP ROM
B.3
28-Lead Plastic Dual in line (PDIP)
400 mil
98 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
B.4
28-Lead Plastic Dual in line (PDIP)
300 mil
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 99
EM78P350N
8-Bit Microprocessor with OTP ROM
B.5
32-LQFP
7x7m2
100 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
B.6
32-Lead Plastic Dual in line (PDIP)
400 mil
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 101
EM78P350N
8-Bit Microprocessor with OTP ROM
B.7
32-Lead Plastic Dual in line (PDIP)
600 mil
102 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)
EM78P350N
8-Bit Microprocessor with OTP ROM
B.8
32-Lead Plastic Small Outline (SOP)
300 mil
Product Specification (V 1.0) 09.14.2006
(This specification is subject to change without further notice)
* 103
EM78P350N
8-Bit Microprocessor with OTP ROM
C Quality Assurance and Reliability
Test Category Test Conditions Remarks -
Solderability
Solder temperature = 255 5C, for 5 seconds up to the stopper using a rosin-type flux Step 1: TCT, 65C (15mins) ~ 150C (15mins), 10 cycles Step 2: Bake at 125C, TD (endurance) = 24 hrs Step 3: Soak at 30C / 60% , TD (endurance) = 192 hrs
Pre-condition
Step 4: IR flow 3 cycles (Pkg thickness 2.5mm or Pkg volume 350 mm3 ----235 5C) (Pkg thickness 2.5 mm or Pkg volume 350 mm3 ----250 5C)
For SMD IC (such as SOP, QFP, SOJ, etc)
Temperature cycle test Pressure cooker test High temperature / High humidity test High-temperature storage life High-temperature operating life Latch-up ESD (HBM)
-65
(15mins)~150C (15mins), 200 cycles
- - - - - -
TA =121C, RH=100%, pressure=2 atm, TD (endurance)= 96 hrs TA=85C , RH=85% TD (endurance) = 168, 500 hrs TA=150C, TD (endurance) = 500, 1000 hrs TA=125C, VCC = Max. operating voltage, TD (endurance) = 168, 500, 1000 hrs TA=25C, VCC = Max. operating voltage, 600 ma / 40V TA=25C, 4KV
IP_ND,OP_ND,IO_ND IP_NS,OP_NS,IO_NS IP_PD,OP_PD,IO_PD, IP_PS,OP_PS,IO_PS, 400V VDD-VSS(+),VDD_VSS (-) mode
ESD (MM)
TA=25C,
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.
104 *
Product Specification (V1.0) 09.14.2006
(This specification is subject to change without further notice)

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