Hynix GMS81C1202 8-bit single-chip microcontroller Datasheet

Jan. 2002
Ver 2.0
8-BIT SINGLE-CHIP MICROCONTROLLERS
GMS81C1102
GMS81C1202
User’s Manual
GMS81C1102 / GMS81C1202
1. OVERVIEW ....................................................................................................................... 1
1.1 Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.3 Development Tools . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
2. BLOCK DIAGRAM(GMS81C1202) .................................................................................. 2
3. PIN ASSIGNMENT(GMS81C1202) .................................................................................. 2
4. BLOCK DIAGRAM(GMS81C1102) .................................................................................. 3
5. PIN ASSIGNMENT(GMS81C1102) .................................................................................. 3
6. PACKAGE DIMENSION(GMS81C1202) .......................................................................... 4
7. PACKAGE DIMENSION(GMS81C1102) .......................................................................... 5
8. PIN FUNCTION ................................................................................................................. 6
9. PORT STRUCTURES ....................................................................................................... 7
10. ELECTRICAL CHARACTERISTICS -GMS81C1102, GMS81C1202 .......................... 10
10.1
10.2
10.3
10.4
10.5
10.6
Absolute Maximum Ratings - GMS81C1102, GMS81C1202 . . . . . . . . . . . . . . . . 10
Recommended Operating Conditions - GMS81C1102, GMS81C1202 . . . . . . . . . 10
DC Electrical Characteristics - GMS81C1102, GMS81C1202 . . . . . . . . . . . . . . . . 11
A/D Converter Characteristics - GMS81C1102, GMS81C1202 . . . . . . . . . . . . . . . 13
AC Characteristics - GMS81C1102, GMS81C1202 . . . . . . . . . . . . . . . . . . . . . . . 14
Typical Characteristics - GMS81C1102, GMS81C1202 . . . . . . . . . . . . . . . . . . . . 15
11. ELECTRICAL CHARACTERISTICS - GMS87C1102, GMS87C1202 ......................... 19
11.1
11.2
11.3
11.4
11.5
11.6
Absolute Maximum Ratings - GMS87C1102, GMS87C1202 . . . . . . . . . . . . . . . . 19
Recommended Operating Conditions - GMS87C1102, GMS87C1202 . . . . . . . . . 19
DC Electrical Characteristics - GMS87C1102, GMS87C1202 . . . . . . . . . . . . . . . . 20
A/D Converter Characteristics - GMS87C1102, GMS87C1202 . . . . . . . . . . . . . . . 21
AC Characteristics - GMS87C1102, GMS87C1202 . . . . . . . . . . . . . . . . . . . . . . . 22
Typical Characteristics - GMS87C1102, GMS87C1202 . . . . . . . . . . . . . . . . . . . . 23
12. MEMORY ORGANIZATION ......................................................................................... 26
12.1
12.2
12.3
12.4
Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
Program Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Data Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Addressing Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
13. I/O PORTS .................................................................................................................... 38
13.1 RA and RAIO registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
13.2 RB and RBIO registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
13.3 RC and RCIO registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
14. CLOCK GENERATOR ................................................................................................. 41
14.1 Oscillation Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
15. BASIC INTERVAL TIMER ........................................................................................... 43
16. TIMER / COUNTER ...................................................................................................... 44
16.1
16.2
16.3
16.4
16.5
16.6
8-bit Timer/Counter Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
16-bit Timer/Counter Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
8-bit Compare Output ( 16-bit ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
8-bit Capture Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
16-bit Capture Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
PWM Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
17. BUZZER OUTPUT FUNCTION .................................................................................... 53
18. ANALOG TO DIGITAL CONVERTER .......................................................................... 54
19. INTERRUPTS ............................................................................................................... 57
19.1
19.2
19.3
19.4
Interrupt Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
BRK Interrupt . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
Multi Interrupt . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
External Interrupt . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
20. WATCHDOG TIMER .................................................................................................... 62
21. POWER SAVING MODE .............................................................................................. 63
22. RESET .......................................................................................................................... 68
23. POWER FAIL PROCESSOR ........................................................................................ 69
24. OTP PROGRAMMING .................................................................................................. 71
APPENDIX
INSTRUCTION MAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i
INSTRUCTION SET . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
GMS81C1102 / GMS81C1202
CMOS SINGLE-CHIP 8-BIT MICROCONTROLLER
1. OVERVIEW
1.1 Description
The GMS81C1102 and GMS81C1202 are an advanced CMOS 8-bit microcontroller with 2K bytes of ROM. The Hynix
GMS81C1102 and GMS81C1202 are a powerful microcontroller which provides a highly flexible and cost effective solution
to many small applications. The GMS81C1102 and GMS81C1202 provide the following standard features: 2K bytes of
ROM, 128 bytes of RAM, 8-bit timer/counter, 8-bit A/D converter, 10-bit High Speed PWM Output, Programmable Buzzer
Driving Port (GMS81C1202 only), on-chip oscillator and clock circuitry. In addition, the GMS81C1102 and GMS81C1202
support power saving modes to reduce power consumption.
This document is only explained for the base of GMS81C1202, the eliminated functions are same as below.
Device name
ROM Size
RAM Size
I/O
BUZ
INT1
Package
GMS81C1102
2K bytes
128 bytes
11
NO
NO
16DIP/SOP
GMS81C1202
2K bytes
128 bytes
15
YES
YES
20DIP/SOP
GMS87C1102
2K bytes(OTP)
128 bytes
11
NO
NO
16DIP/SOP
GMS87C1202
2K bytes(OTP)
128 bytes
15
YES
YES
20DIP/SOP
1.2 Features
• 128 Bytes of On-Chip Data RAM
• Seven Interrupt Sources
(GMS81C1102 has Six interrupt sources)
• Minimum Instruction execution time:
- 500ns at 8MHz (2cycle NOP Instruction)
• 8-Channel 8-Bit On-Chip Analog to Digital Converter
• 2K bytes On-chip Program Memory
• 2.2V to 6.0V Wide Operating Range
• Basic Interval Timer
• Two 8-Bit Timer/ Counters
• 10-Bit High Speed PWM Output
• Two external interrupt ports
(GMS81C1102 has one external interrupt port)
• Watch dog timer
• Oscillation :
- Crystal
- Ceramic Resonator
- External Oscillator
- RC Oscillation
• One Programmable Buzzer Driving port
(GMS81C1202 only)
• Power Down Mode
- STOP mode
- Wake-up Timer mode
- RC-WDT mode
• 15 Programmable I/O Lines
(GMS81C1102 has 11 programmable I/O lines)
• Power Fail Processor
( Noise Immunity Circuit )
1.3 Development Tools
The GMS800 family is supported by a full-featured macro
assembler, an in-circuit emulators CHOICE-Dr.™, and
add-on board type OTP writer Dr.Writer™ .
The availability of OTP devices is especially useful for
customers expecting frequent code changes and updates.
The OTP devices, packaged in plastic packages, permit the
user to program them once.
Jan. 2002 ver 2.0
In Circuit Emulator
CHOICE-Dr.
Assembler
Hynix Semiconductor
Macro Assembler
OTP Writer
Dr.Writer
1
GMS81C1102 / GMS81C1202
2. BLOCK DIAGRAM(GMS81C1202)
PSW
Accumulator
ALU
PC
Stack Pointer
Data
Memory
Program
Memory
Interrupt Controller
RESET
System controller
System
Clock Controller
Data Table
Timing generator
8-bit Basic
Interval
Timer
Clock
Generator
Watch-dog
Timer
Xin
Xout
8-bit
A/D
Converter
8-bit
Timer/
Counter
High
Speed
PWM
Buzzer
Driver
Instruction
Decoder
VDD
RA
VSS
RB
RC
Power
Supply
RA0 / EC0
RA1 / AN1
RA2 / AN2
RA3 / AN3
RA4 / AN4
RA5 / AN5
RA6 / AN6
RA7 / AN7
RB0 / AN0 / Avref
RB1 / BUZ
RB2 / INT0
RB3 / INT1
RB4 / CMP0 / PWM
RC0
RC1
3. PIN ASSIGNMENT(GMS81C1202)
20 DIP
AN4 / RA4
AN5 / RA5
AN6 / RA6
AN7 / RA7
VDD
AN0 / AVref / RB0
AN4 / RA4
1
20
RA3 / AN3
AN5 / RA5
2
19
RA2 / AN2
RA2 / AN2
AN6 / RA6
3
18
RA1 / AN1
RA1 / AN1
AN7 / RA7
4
17
RA0 / EC0
VDD
5
16
RC1
AN0 / AVref / RB0
6
15
RC0
BUZ / RB1
7
14
VSS
INT0 / RB2
8
13
RESET
INT1 / RB3
9
12
Xout
10
11
Xin
1
20
RA3 / AN3
2
19
18
3
4
17
RA0 / EC0
5
16
RC1
6
15
RC0
BUZ / RB1
7
14
VSS
INT0 / RB2
8
13
RESET
INT1 / RB3
9
12
Xout
10
11
Xin
PWM / COMP0 / RB4
2
20 SOP
PWM / COMP0 / RB4
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
4. BLOCK DIAGRAM(GMS81C1102)
PSW
Accumulator
ALU
PC
Stack Pointer
Data
Memory
Program
Memory
Interrupt Controller
RESET
System controller
System
Clock Controller
Data Table
Timing generator
8-bit Basic
Interval
Timer
Clock
Generator
Watch-dog
Timer
Xin
Xout
8-bit
A/D
Converter
8-bit
Timer/
Counter
High
Speed
PWM
Instruction
Decoder
VDD
RA
VSS
RB
Power
Supply
RA0 / EC0
RA1 / AN1
RA2 / AN2
RA3 / AN3
RA4 / AN4
RA5 / AN5
RA6 / AN6
RA7 / AN7
RB0 / AN0 / Avref
RB2 / INT0
RB4 / CMP0 / PWM
5. PIN ASSIGNMENT(GMS81C1102)
16 SOP
16 DIP
AN4 / RA4
AN5 / RA5
1
2
16
15
RA3 / AN3
RA2 / AN2
AN4 / RA4
1
16
RA3 / AN3
AN5 / RA5
2
15
RA2 / AN2
AN6 / RA6
3
14
RA1 / AN1
AN6 / RA6
3
14
RA1 / AN1
AN7 / RA7
4
13
RA0 / EC0
AN7 / RA7
4
13
RA0 / EC0
VDD
5
12
VSS
AN0 / AVref / RB0
6
11
RESET
INT0 / RB2
7
10
Xout
PWM / COMP0 / RB4
8
9
VDD
5
AN0 / AVref / RB0
6
11
RESET
INT0 / RB2
7
10
Xout
PWM / COMP0 / RB4
8
9
Jan. 2002 ver 2.0
12
VSS
Xin
Xin
3
GMS81C1102 / GMS81C1202
6. PACKAGE DIMENSION(GMS81C1202)
20 DIP
unit : mm
TYP 7.62
26.2±0.3
6.54±0.3
MAX 4.57
MIN 0.38
3.3±0.25
0 ~ 15°
TYP 2.54
0.46±0.07
0.25±0.05
1.45±0.2
20 SOP
7.5±0.1
10.35±0.2
12.8±0.2
0.2±0.1
2.5±0.15
0 ~ 8°
0.42±0.08
4
TYP 1.27
0.26±0.05
0.7±0.3
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
7. PACKAGE DIMENSION(GMS81C1102)
16 DIP
unit : mm
TYP 7.62
19.2±0.2
6.3±0.3
MAX 4.32
MIN 0.38
3.3±0.25
0.75±0.3
0 ~ 15°
TYP 2.54
0.46±0.07
0.25±0.05
1.45±0.2
16 SOP
7.5±0.1
10.35±0.2
10.25±0.05
0.18±0.05
2.5±0.15
0 ~ 8°
0.42±0.08
Jan. 2002 ver 2.0
TYP 1.27
0.27±0.04
0.7±0.3
5
GMS81C1102 / GMS81C1202
8. PIN FUNCTION
In addition, RA serves the functions of the various special
features in Table 8-1.
VDD: Supply voltage.
VSS: Circuit ground.
RESET: Reset the MCU.
XIN: Input to the inverting oscillator amplifier and input to
the internal clock operating circuit.
XOUT: Output from the inverting oscillator amplifier. If
RC Option is used, the oscillator frequency divided by 4
(Xin/4) comes out from Xout pin.
RB0~RB4: RB is a 5-bit, CMOS, bidirectional I/O port.
RB pins can be used as outputs or inputs according to “1”
or “0” written in the Port Direction Register(RBIO).
RB serves the functions of the various following special
features.
RA0~RA7: RA is an 8-bit, CMOS, bidirectional I/O port.
RA pins can be used as outputs or inputs according to “1”
or “0” written in the Port Direction Register(RAIO).
Port pin
Alternate function
RB0
AN0 ( Analog Input Port 0 )
AVref ( External Analog Reference Pin )
BUZ ( Buzzer Driving Output Port )
INT0 ( External Interrupt Input Port 0 )
INT1 ( External Interrupt Input Port 1 )
PWM ( PWM Output )
COMP0 ( Timer0 Compare Output )
RB1
RB2
RB3
RB4
Port pin
Alternate function
RA0
RA1
RA2
RA3
RA4
RA5
RA6
RA7
EC0 ( Event Counter Input Source )
AN1 ( Analog Input Port 1 )
AN2 ( Analog Input Port 2 )
AN3 ( Analog Input Port 3 )
AN4 ( Analog Input Port 4 )
AN5 ( Analog Input Port 5 )
AN6 ( Analog Input Port 6 )
AN7 ( Analog Input Port 7 )
RC0~RC1: RC is a 2-bit, CMOS, bidirectional I/O port.
RC pins can be used as outputs or inputs according to “1”
or “0” written in the Port Direction Register(RCIO)
Table 8-1 RA Port
.
PIN NAME
Table 8-2 RB Port
Pin No.
In/Out
Function
VDD
5
-
Supply voltage
VSS
14
-
Circuit ground
RESET
13
I
Reset signal input
XIN
11
I
XOUT
12
O
RA0 (EC0)
17
I/O (Input)
External Event Counter input
RA1 (AN1)
18
I/O (Input)
Analog Input Port 1
RA2 (AN2)
19
I/O (Input)
Analog Input Port 2
RA3 (AN3)
20
I/O (Input)
RA4 (AN4)
1
I/O (Input)
Analog Input Port 4
RA5 (AN1)
2
I/O (Input)
Analog Input Port 5
RA6 (AN1)
3
I/O (Input)
Analog Input Port 6
RA7 (AN7)
4
I/O (Input)
Analog Input Port 7
RB0 (AVref/AN0)
6
I/O (Input)
Analog Input Port 0 / Analog Reference
RB1 (BUZ)
7
I/O (Output)
RB2 (INT0)
8
I/O (Input)
RB3 (INT1)
9
I/O (Input)
RB4 (PWM/COMP0)
10
I/O (Output/Output)
RC0
15
I/O
RC1
16
I/O
8-bit general I/O ports
Analog Input Port 3
Buzzer Driving Output
5-bit general I/O ports
External Interrupt Input 0
External Interrupt Input 1
PWM Output or Timer Compare Output
2-bit general I/O ports
Table 8-3 Pin Description
6
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
9. PORT STRUCTURES
• RESET
VDD
Internal RESET
VSS
• Xin, Xout
VDD
RC option
fxin ÷ 4
1
Xout
0
VSS
STOP
To System CLK
Xin
• RA0/EC0
Data Reg.
Data Bus
Direction Reg.
Data Bus
Data Bus
Read
EC0
Jan. 2002 ver 2.0
7
GMS81C1102 / GMS81C1202
• RA1/AN1 ~ RA7/AN7
VDD
Data Reg.
Data Bus
Direction Reg.
Data Bus
VSS
Data Bus
Read
To A/D Converter
Analog Input Mode
(ANSEL7 ~ 1)
Analog CH. Selection
(ADCM.4 ~ 2)
• RB0 / AN0 / AVref
VDD
Data Reg.
Data Bus
AVREFS
Direction Reg.
Data Bus
VSS
Data Bus
Read
To A/D Converter
Analog Input Mode
(ANSEL0)
Analog CH0 Selection
(ADCM.4 ~ 2)
Internal VDD
1
To Vref of A/D
0
AVREFS
8
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
• RB1/BUZ, RB4/PWM0/COMP
PWM/COMP
BUZ
VDD
1
Data Reg.
0
Data Bus
Function
Select
Direction Reg.
Data Bus
VSS
Data Bus
Read
• RB2/INT0, RB3/INT1
Pull-up
Select
Weak Pull-up
VDD
Data Reg.
Data Bus
Function
Select
Direction Reg.
Data Bus
INT0
INT1
VSS
Data Bus
Read
Schmitt Trigger
• RC0, RC1
VDD
Data Reg.
Data Bus
Direction Reg.
Data Bus
VSS
Data Bus
Read
Jan. 2002 ver 2.0
9
GMS81C1102 / GMS81C1202
10. ELECTRICAL CHARACTERISTICS -GMS81C1102, GMS81C1202
10.1 Absolute Maximum Ratings - GMS81C1102, GMS81C1202
Supply voltage ........................................... -0.3 to +6.5 V
Maximum current (ΣIOL) .................................... 150 mA
Storage Temperature ................................-40 to +125 °C
Maximum current (ΣIOH).................................... 100 mA
Voltage on any pin with respect to Ground (VSS)
............................................................... -0.3 to VDD+0.3
Maximum current out of VSS pin ........................200 mA
Maximum current into VDD pin ..........................150 mA
Maximum current sunk by (IOL per I/O Pin) ........25 mA
Maximum output current sourced by (IOH per I/O Pin)
...............................................................................15 mA
Note: Stresses above those listed under "Absolute Maximum Ratings" may cause permanent damage to the
device. This is a stress rating only and functional operation of the device at any other conditions above
those indicated in the operational sections of this
specification is not implied. Exposure to absolute
maximum rating conditions for extended periods
may affect device reliability.
10.2 Recommended Operating Conditions - GMS81C1102, GMS81C1202
Specifications
Parameter
Supply Voltage
Operating Frequency
Operating Temperature
10
Symbol
VDD
fXIN
TOPR
Condition
Unit
Min.
Max.
fXIN=8MHz
4.5
6.0
fXIN=4.2MHz
2.2
6.0
VDD=4.5~6.0V
1
8
VDD=2.2~6.0V
1
4.2
-20
85
V
MHz
°C
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
10.3 DC Electrical Characteristics - GMS81C1102, GMS81C1202
• (VDD=4.5~6.0V, VSS=0V, fXIN =1MHz~8MHz, TA=-20°°C~+85°°C)
Parameter
Pin1
Symbol
Specification
Test Condition
VIH1
XIN, RESET
VIH2
RB2, RB3
VIH3
RA,RB0,RB1,RB4,RC
VIL1
XIN, RESET
VIL2
RB2, RB3
VIL3
RA,RB0,RB1,RB4,RC
Output High Voltage
VOH
RA, RB, RC
VDD = 5V, IOH = -2mA
Output Low Voltage
VOL
RA, RB, RC
VDD = 5V, IOL= 10mA
Input
Leakage Current
IIL
RESET,RA,RB,RC
IIL
XIN
Input Pull-up Current
IPU
RB2, RB33
Power Fail Detect Voltage
VPFD
VDD
Normal Operating Current
IDD
VDD
Wake-up Timer Mode
Current
IWKUP
RC-oscillated Watchdog
Timer Mode Current
Input High Voltage
Input Low Voltage
VDD=4.5~6.0V
VDD=4.5~6.0V
Min
Typ2
0.8VDD
VDD
0.8VDD
VDD
0.7VDD
VDD
0
0.2VDD
0
0.2VDD
0
0.3VDD
VDD-1
Unit
V
V
V
1
±5
VIN = VSS~VDD
VDD = 5V, VIN = VSS
Max
±20
V
uA
-350
-280
-200
uA
2
3.5
4
V
VDD=6.0V, fXIN=8MHz
4
6
mA
VDD
VDD=6.0V, fXIN=8MHz
1
2
mA
IRCWDT
VDD
VDD = 6.0V,
fXIN = 8MHz
0.6
0.8
mA
STOP Mode Current
ISTOP
VDD
VDD = 6.0V
0.5
2
uA
Hysteresis
VT+
~ VT-
RESET, RB2, RB3
0.5
V
Internal RC Oscillation
Period ( RC-WDT CLK )
TRCWDT XOUT
VDD = 5V,
fXIN = 8MHz
100
200
uS
RC Oscillation Frequency
( System CLK )
fRCOSC4 XOUT
R = 15KΩ, C=30pF
400
600
kHz
1.
2.
3.
4.
RC0, RC1, RB1 and RB3 pins are applied for GMS81C1202 only.
Data in “Typ” column is at 5V, 25°C unless otherwise stated. These parameters are for design guidance only and are not tested.
This parameter is valid when the bit PUPSELx is selected and set the Input mode or Interrupt Input Function.
This parameter is measured in XOUT pin, and measured frequency is must be 4times to be internal system clock because of this
XOUT signal is divided by 4 of system clock.
Jan. 2002 ver 2.0
11
GMS81C1102 / GMS81C1202
• (VDD=2.2~6.0V, VSS=0V, fXIN =1MHz~4.2MHz, TA=-20°C~+85°C)
Parameter
Pin1
Symbol
Specification
Test Condition
VIH1
XIN
VIH2
RESET
VIH3
RB2, RB3
VIH4
RA,RB0,RB1,RB4,RC
VIL1
XIN
VIL2
RESET
VIL3
RB2, RB3
VIL4
RA,RB0,RB1,RB4,RC
Output High Voltage
VOH
RA, RB, RC
VDD = 3V, IOH = -2mA
Output Low Voltage
VOL
RA, RB, RC
VDD = 3V, IOL= 5mA
Input
Leakage Current
IIL
RESET,RA,RB,RC
IIL
XIN
Input Pull-up Current
IPU
RB2, RB33
Power Fail Detect Voltage
VPFD
VDD
Normal Operating Current
IDD
VDD
Wake-up Timer Mode
Current
IWKUP
RC-oscillated Watchdog
Timer Mode Current
Input High Voltage
Input Low Voltage
VDD=2.2~6.0V
VDD=2.2~6.0V
Min
Typ2
0.8VDD
VDD
0.9VDD
VDD
0.8VDD
VDD
0.7VDD
VDD
0
0.2VDD
0
0.1VDD
0
0.2VDD
0
0.3VDD
2.5
Unit
V
V
V
0.7
±5
VIN = VSS~VDD
VDD = 3V, VIN = VSS
Max
±15
V
uA
-100
-60
-40
uA
2
3.5
4
V
VDD = 3V, fXIN = 4MHz
2
3
mA
VDD
VDD = 3V, fXIN = 4MHz
0.5
1
mA
IRCWDT
VDD
VDD = 3V, fXIN = 4MHz
0.3
0.6
mA
STOP Mode Current
ISTOP
VDD
VDD = 3V
0.2
1
uA
Hysteresis
VT+
~ VT-
RESET, RB2, RB3
0.5
V
Internal RC Oscillation
Period ( RC-WDT CLK )
TRCWDT XOUT
VDD = 3V, fXIN = 4MHz
200
400
uS
RC Oscillation Frequency
( System CLK )
fRCOSC4 XOUT
VDD = 3V,
R = 47KΩ, C=7pF
200
300
kHz
1.
2.
3.
4.
12
RC0, RC1, RB1 and RB3 pins are applied for GMS81C1202 only.
Data in “Typ” column is at 3V, 25°C unless otherwise stated. These parameters are for design guidance only and are not tested.
This parameter is valid when the bit PUPSELx is selected and set the Input mode or Interrupt Input Function.
This parameter is measured in XOUT pin, and measured frequency is must be 4times to be internal system clock because of this
XOUT signal is divided by 4 of system clock.
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
10.4 A/D Converter Characteristics - GMS81C1102, GMS81C1202
• (VSS=0V, VDD=3.072V/@fXIN =4MHz, VDD=5.12V/@fXIN =8MHz, TA=-20°°C~+85°°C )
Parameter
Symbol
Condition
Specifications
Unit
Min.
Typ.
Max.
AVREFS=0
VSS
-
VDD
AVREFS=1
VSS
-
VREF
AVREFS=1
3
-
VDD
V
Analog Input Voltage Range
VAIN
Analog Power Supply Input Voltage Range
VREF
Overall Accuracy
NACC
-
±1.0
±1.5
LSB
Non-Linearity Error
NNLE
-
±0.8
±1.2
LSB
Differential Non-Linearity Error
NDNLE
-
±1.0
±1.5
LSB
Zero Offset Error
NZOE
-
±1.0
±1.5
LSB
Full Scale Error
NFSE
-
±0.25
±0.5
LSB
Gain Error
NNLE
-
±1.0
±1.5
LSB
fXIN=4MHz
-
-
20
fXIN=8MHz
-
-
10
fXIN=4MHz
-
0.4
0.6
fXIN=8MHz
-
0.5
1.0
Conversion Time
AVREF Input Current
Jan. 2002 ver 2.0
TCONV
IREF
V
µS
mA
13
GMS81C1102 / GMS81C1202
10.5 AC Characteristics - GMS81C1102, GMS81C1202
(TA=-20~+85°C, VDD=5V±10%, VSS=0V)
Specifications
Parameter
Symbol
Pins
Unit
Min.
Typ.
Max.
fCP
XIN
1
-
8
MHz
tCPW
XIN
50
-
-
nS
tRCP,tFCP
XIN
-
-
20
nS
External Input Pulse Width
tEPW
INT0, INT1, EC0
2
-
-
tSYS
RESET Input Width
tRST
RESET
8
-
-
tSYS
Operating Frequency
External Clock Pulse Width
External Clock Transition Time
tCPW
1/fCP
tCPW
VDD-0.5V
XIN
0.5V
tSYS
tRCP
tFCP
tRST
RESET
0.2VDD
tEPW
tEPW
0.8VDD
INT0, INT1
EC0
0.2VDD
Figure 10-1 Timing Chart
14
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
10.6 Typical Characteristics - GMS81C1102, GMS81C1202
This graphs and tables provided in this section are for design guidance only and are not tested or guranteed.
In some graphs or tables the data presented are outside specified operating range (e.g. outside specified
VDD range). This is for imformation only and divices
are guranteed to operate properly only within the
specified range.
The data presented in this section is a statistical summary
of data collected on units from different lots over a period
of time. “Typical” represents the mean of the distribution
while “max” or “min” represents (mean + 3σ) and (mean −
3σ) respectively where σ is standard deviation
Operating Area
fXIN
(MHz)
Normal Operation
IDD−VDD
Ta= 25°C
12
IDD
(mA)
10
Ta=25°C
8
8
6
6
fXIN = 8MHz
4
4
4MHz
2
2
0
2
3
4
5
VDD
(V)
6
0
2
Stop Mode
ISTOP−VDD
IDD
(µA)
4
5
VDD
6 (V)
Wake-up Timer Mode
IWKUP−VDD
IDD
(mA)
fXIN=8MHz
0.8
2.0
0.6
1.5
Ta= - 40°C
0.4
3
Ta=25°C
1.0
fXIN = 8MHz
4MHz
0.2
0.5
25°C, 125°C
0
2
3
4
5
VDD
6 (V)
0
2
3
4
5
VDD
6 (V)
RC-WDT in Stop Mode
IRCWDT−VDD
IDD
(µA)
Ta=25°C
400
300
fXIN = 4/8 MHz
Frequency affects
the current so little.
200
100
4MHz
0
2
Jan. 2002 ver 2.0
3
4
5
VDD
6 (V)
15
GMS81C1102 / GMS81C1202
IOL−VOL, VDD=5V
IOL−VOL, VDD=3V
IOL
(mA)
IOL
(mA)
-40°C
-40°C
20
25°C
125°C
25°C
12
125°C
16
12
8
8
4
4
0
0.2
0.4
0.6
0.8
VOL
1.0 (V)
0
0.2
IOH−VOH, VDD=5V
0.4
0.6
0.8
VOL
1.0 (V)
IOH−VOH, VDD=5V
IOH
(mA)
-40°C
-10
25°C
IOH
(mA)
-40°C
25°C
-8
125°C
125°C
-8
-6
-6
-4
-4
-2
-2
0
4
16
4.5
5
VOH
(V)
0
2
2.5
3
VOH
(V)
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
VDD−VIH1
VIH1
(V)
VIH2
(V)
fX IN =4MHz
Ta=25°C
4
4
3
3
2
2
1
1
0
1
2
3
VDD−VIH3
VIH3
(V)
4
5
VDD
6 (V)
fXIN =4MHz
Ta=25°C
2
3
4
VDD−VIH4
VIH4
(V)
5
VDD
6 (V)
RESET
fXIN =4MHz
Ta=25°C
4
3
3
2
2
1
1
0
2
3
4
5
VDD−VIL1
VIL1
(V)
Hysteresis input
0
Normal input
fX IN =4MHz
Ta=25°C
4
VDD
6 (V)
XIN
fXIN=4MHz
Ta=25°C
0
2
VIL2
(V)
4
3
3
2
2
1
1
1
2
3
VDD−VIL3
VIL3
(V)
4
5
VDD
6 (V)
VDD
6 (V)
Hysteresis input
3
4
V D D −V IL 4
V IL4
(V)
5
VDD
6 (V)
R ES ET
fXIN =4MHz
Ta=25°C
4
3
2
2
1
1
0
2
5
fXIN =4MHz
Ta=25°C
2
3
1
4
0
Normal input
fX IN =4MHz
Ta=25°C
4
3
VDD−VIL2
4
0
Jan. 2002 ver 2.0
VDD−VIH2
XIN
3
4
5
VDD
6 (V)
0
1
2
3
4
5
VDD
6 (V)
17
GMS81C1102 / GMS81C1202
FO SC
(M H z)
2.5
T ypical R C O scillato r
VDD
T ypical R C O scillator
F re quency V S . V D D
FOSC
F req ue n cy V S .
(M H z )
C e xt=3 9 p F
1.6
Ta=25°C
C ext=24pF
Ta=25°C
1.4
R = 20K
1.2
2.0
R = 2 0k
1.0
1.5
R =3 3K
0.8
R =47K
0.6
R =47 K
1 .0
R =33K
0.4
R =100K
R = 10 0K
0.5
0.2
0
2.5
3
3.5
4
5
4.5
5.5
VDD
6 (V )
T ypical R C O scillator
F req uen cy V S . V D D
2.5
3
3.5
4
4 .5
5
5.5
VDD
6 (V )
Typ ica l R C O scilla tor
F re q ue n cy V S . T e m pe ra ture
FOSC
F O S C (25 °C )
FOSC
(M H z)
0.8 C e xt=100p F
Ta=25°C
0.7
R =20K
0.6
0 .5
0
C ext=24pF
R =25K
1 .0 1 0
1 .0 0 5
1.00 0
V D D =5 V
R =3 3K
0.99 5
0.4
R =47 K
0 .9 9 0
0.3
0.2
0 .9 8 5
R =10 0K
VDD=3V
0 .9 8 0
0.1
0
2.5
3
3.5
4
4 .5
Cext
24pF
39pF
100pF
5
5 .5
VDD
6 (V )
Rext
0 .9 7 5
0
10
20
30
40
50
60
VDD
7 0 (V )
Average
Fosc @ 5V,25°C
20K
2.02MHz
±14.11%
33K
1.34MHz
±11.50%
47K
0.952MHz
±10.30%
100K
0.48MHz
±9.07%
20K
1.536MHz
±14.79%
33K
1.012MHz
±11.67%
47K
0.72MHz
±10.42%
100K
0.364MHz
±9.75%
20K
0.78MHz
±13.53%
33K
0.512MHz
±10.35%
47K
0.364MHz
±9.48%
100K
0.18MHz
±7.34%
Table 10-1 RC Oscillator Frequencies
18
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
11. ELECTRICAL CHARACTERISTICS - GMS87C1102, GMS87C1202
11.1 Absolute Maximum Ratings - GMS87C1102, GMS87C1202
Supply voltage ........................................... -0.3 to +6.5 V
Maximum current (ΣIOL) .................................... 150 mA
Storage Temperature ................................-40 to +125 °C
Maximum current (ΣIOH).................................... 100 mA
Voltage on any pin with respect to Ground (VSS)
............................................................... -0.3 to VDD+0.3
Maximum current out of VSS pin ........................200 mA
Maximum current into VDD pin ..........................150 mA
Maximum current sunk by (IOL per I/O Pin) ........25 mA
Maximum output current sourced by (IOH per I/O Pin)
...............................................................................15 mA
Note: Stresses above those listed under "Absolute Maximum Ratings" may cause permanent damage to the
device. This is a stress rating only and functional operation of the device at any other conditions above
those indicated in the operational sections of this
specification is not implied. Exposure to absolute
maximum rating conditions for extended periods
may affect device reliability.
11.2 Recommended Operating Conditions - GMS87C1102, GMS87C1202
Specifications
Parameter
Supply Voltage
Operating Frequency
Operating Temperature
Jan. 2002 ver 2.0
Symbol
VDD
fXIN
TOPR
Condition
Unit
Min.
Max.
fXIN=8MHz
4.5
5.5
fXIN=4.2MHz
2.7
5.5
VDD=4.5~5.5V
1
8
VDD=2.7~5.5V
1
4.2
-20
85
V
MHz
°C
19
GMS81C1102 / GMS81C1202
11.3 DC Electrical Characteristics - GMS87C1102, GMS87C1202
(TA=-20~85°C, VDD=2.7~5.5V, VSS=0V)
Parameter
Pin1
Symbol
Test Condition
Specification
Min
Typ2
Max
VIH1
XIN, RESET
0.8VDD
VDD
VIH2
RB2, RB3
0.8VDD
VDD
VIH3
RA,RB0,RB1,RB4,RC
0.7VDD
VDD
VIL1
XIN, RESET
0
0.2VDD
VIL2
RB2, RB3
0
0.2VDD
VIL3
RA,RB0,RB1,RB4,RC
0
0.3VDD
Output High
Voltage
VOH
RA, RB, RC
VDD = 5V, IOH = -5mA
Output Low
Voltage
VOL
RA, RB, RC
VDD = 5V, IOL= 10mA
IIH1
RESET,RA,RB,RC
IIH2
XIN
IIL1
RESET,RA,RB,RC
IIL2
XIN
Input Pull-up
Current
IP
RB2, RB33
Power Fail Detect Voltage
VPFD
VDD
Normal Operating Current
IDD
VDD
Wake-up Timer Mode
Current
IWKUP
VDD
RC-oscillated Watchdog
Timer Mode Current
IRCWDT
VDD
STOP Mode Current
ISTOP
VDD
Hysteresis
VT+
~ VT-
RESET, RB2, RB3
Input High Voltage
Input Low Voltage
Input High
Leakage Current
Input Low
Leakage Current
Internal RC Oscillation
Period ( RC-WDT CLK )
RC Oscillation Frequency
( System CLK )
1.
2.
3.
4.
20
TRCWDT XOUT
fRCOSC4
XOUT
VDD-1
V
V
V
1.0
5
VDD = 5.5V
VDD = 5.5V
Unit
15
-5
V
uA
uA
-15
VDD = 5V
-350
-280
-200
VDD = 3V
-100
-60
-40
VDD = 5V
2
3.5
4
VDD = 5.5V, fXIN = 8MHz
4
6
VDD = 3V, fXIN = 4MHz
2
3
VDD = 5.5V, fXIN = 8MHz
1
1.8
VDD = 3V, fXIN = 4MHz
0.5
1
VDD = 5.5V, fXIN = 8MHz
0.6
0.8
VDD = 3V, fXIN = 4MHz
0.3
0.6
VDD = 5.5V, fXIN = 8MHz
0.5
2
VDD = 3V, fXIN = 4MHz
0.2
1
0.5
uA
V
mA
mA
mA
uA
V
VDD = 5V
100
250
VDD = 3V
200
500
VDD = 5V,
R = 15KΩ, C=30pF
400
600
VDD = 3V,
R = 47KΩ, C=7pF
200
300
uS
KHz
RC0, RC1, RB1 and RB3 pins are applied for GMS87C1202 only.
Data in “Typ” column is at 5V, 25°C unless otherwise stated. These parameters are for design guidance only and are not tested.
This parameter is valid when the bit PUPSELx is selected and set the Input mode or Interrupt Input Function.
This parameter is measured in XOUT pin, and measured frequency is must be 4times to be internal system clock because of this
XOUT signal is divided by 4 of system clock.
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
11.4 A/D Converter Characteristics - GMS87C1102, GMS87C1202
(TA=25°C, VSS=0V, VDD=5.12V @fXIN =8MHz , VDD=3.072V @fXIN =4MHz )
Specifications
Parameter
Analog Input Voltage Range
Symbol
VAIN
Condition
Unit
Min.
Typ.
Max.
AVREFS=0
VSS
-
VDD
AVREFS=1
VSS
-
VREF
AVREFS=1
3
-
VDD
V
V
Analog Power Supply Input Voltage Range
VREF
Overall Accuracy
NACC
-
±1.0
±1.51
LSB
Non-Linearity Error
NNLE
-
±0.8
±1.2
LSB
Differential Non-Linearity Error
NDNLE
-
±1.0
±1.5
LSB
Zero Offset Error
NZOE
-
±1.3
±2.0
LSB
Full Scale Error
NFSE
-
±0.25
±0.5
LSB
Gain Error
NNLE
-
±1.0
±1.5
LSB
fXIN=8MHz
-
-
10
fXIN=4MHz
-
-
20
AVREFS=1
-
0.5
1.0
Conversion Time
AVREF Input Current
TCONV
IREF
µS
mA
1.This parameter is valid in the range from 02H to FFH, and typical value ±1.3 LSB, maximum value ±2.0 LSB in the other range (from
00H to 01H).
Jan. 2002 ver 2.0
21
GMS81C1102 / GMS81C1202
11.5 AC Characteristics - GMS87C1102, GMS87C1202
(TA=-20~+85°C, VDD=5V±10%, VSS=0V)
Specifications
Parameter
Symbol
Pins
Unit
Min.
Typ.
Max.
fCP
XIN
1
-
8
MHz
tCPW
XIN
50
-
-
nS
tRCP,tFCP
XIN
-
-
20
nS
Oscillation Stabilizing Time
tST
XIN, XOUT
-
-
20
mS
External Input Pulse Width
tEPW
INT0, INT1, EC0
2
-
-
tSYS
RESET Input Width
tRST
RESET
8
-
-
tSYS
Operating Frequency
External Clock Pulse Width
External Clock Transition Time
tCPW
1/fCP
tCPW
VDD-0.5V
XIN
0.5V
tSYS
tRCP
tFCP
tRST
RESET
0.2VDD
tEPW
tEPW
0.8VDD
INT0, INT1
EC0
0.2VDD
Figure 11-1 Timing Chart
22
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
11.6 Typical Characteristics - GMS87C1102, GMS87C1202
This graphs and tables provided in this section are for design guidance only and are not tested or guranteed.
In some graphs or tables the data presented are outside specified operating range (e.g. outside specified
VDD range). This is for imformation only and divices
are guranteed to operate properly only within the
specified range.
The data presented in this section is a statistical summary
of data collected on units from different lots over a period
of time. “Typical” represents the mean of the distribution
while “max” or “min” represents (mean + 3σ) and (mean −
3σ) respectively where σ is standard deviation
Operating Area
Normal Operation
IDD−VDD
fXIN
(MHz)
IDD
(mA)
Ta= 25°C
10
Ta=25°C
8
8
6
6
fXIN = 8MHz
4
4MHz
4
2
2
0
0
2
3
4
5
6
2
VDD
(V)
Wake-up Timer Mode
IWKUP−VDD
IDD
(mA)
3
4
5
VDD
6 (V)
RC-WDT in Stop Mode
IRCWDT−VDD
IDD
(µA)
Ta=25°C
2.0
Ta=25°C
20
1.5
15
fXIN = 8MHz
1.0
fXIN = 8MHz
10
0.5
5
4MHz
4MHz
0
2
Jan. 2002 ver 2.0
3
4
5
VDD
6 (V)
0
2
3
4
5
VDD
6 (V)
23
GMS81C1102 / GMS81C1202
IOL−VOL, VDD=5V
IOH−VOH, VDD=5V
IOL
(mA)
IOH
(mA)
-25°C
25°C
40
-25°C
25°C
-20
85°C
85°C
-15
30
-10
20
-5
10
0
1
VIH1
(V)
2
3
VDD−VIH1
XIN, RESET
0
VOL
5 (V)
2
VDD−VIH2
VIH2
(V)
fXIN=4MHz
Ta=25°C
Hysteresis input
f X IN =4kH z
Ta=25°C
3
4
VIH3
(V)
4
3
3
3
2
2
2
1
1
1
1
VIL1
(V)
2
3
4
5
VDD
6 (V)
VDD−VIL1
XIN, RESET
4
0
2
3
VDD−VIL2
VIL2
(V)
fXIN=4MHz
Ta=25°C
4
5
VDD
6 (V)
Hysteresis input
f X IN =4kH z
Ta=25°C
VIL3
(V)
3
3
2
2
2
1
1
1
3
4
5
VDD
6 (V)
4
0
2
3
4
5
VDD
6 (V)
3
VDD−VIL3
3
2
f X IN =4kH z
Ta=25°C
2
4
1
Normal input
0
4
0
VOH
6 (V)
5
VDD−VIH3
4
0
24
4
4
5
VDD
6 (V)
Normal input
f X IN =4kH z
Ta=25°C
0
2
3
4
5
VDD
6 (V)
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
FO SC
(M H z)
2.5
T ypical R C O scillato r
VDD
T ypical R C O scillator
F re quency V S . V D D
FOSC
F req ue n cy V S .
(M H z )
C e xt=3 9 p F
1.6
Ta=25°C
C ext=24pF
Ta=25°C
1.4
R = 20K
1.2
2.0
R = 2 0k
1.0
1.5
R =3 3K
0.8
R =47K
0.6
R =47 K
1 .0
R =33K
0.4
R =100K
R = 10 0K
0.5
0.2
0
2.5
3
3.5
4
4.5
5
5.5
VDD
6 (V )
T ypical R C O scillator
F req uen cy V S . V D D
2.5
3
3.5
4
4 .5
5
5.5
VDD
6 (V )
Typ ica l R C O scilla tor
F re q ue n cy V S . T e m pe ra ture
FOSC
F O S C (25 °C )
FOSC
(M H z)
0.8 C e xt=100p F
Ta=25°C
0.7
R =20K
0.6
0 .5
0
C ext=24pF
R =25K
1 .0 1 0
1 .0 0 5
1.00 0
V D D =5 V
R =3 3K
0.99 5
0.4
R =47 K
0 .9 9 0
0.3
0.2
0 .9 8 5
R =10 0K
VDD=3V
0 .9 8 0
0.1
0
2.5
3
3.5
4
4 .5
Cext
24pF
39pF
100pF
5
5 .5
VDD
6 (V )
Rext
0 .9 7 5
0
10
30
20
40
50
60
VDD
7 0 (V )
Average
Fosc @ 5V,25°C
20K
2.02MHz
±14.11%
33K
1.34MHz
±11.50%
47K
0.952MHz
±10.30%
100K
0.48MHz
±9.07%
20K
1.536MHz
±14.79%
33K
1.012MHz
±11.67%
47K
0.72MHz
±10.42%
100K
0.364MHz
±9.75%
20K
0.78MHz
±13.53%
33K
0.512MHz
±10.35%
47K
0.364MHz
±9.48%
100K
0.18MHz
±7.34%
Table 11-1 RC Oscillator Frequencies
Jan. 2002 ver 2.0
25
GMS81C1102 / GMS81C1202
12. MEMORY ORGANIZATION
The GMS81C1202 has separated address spaces for Program memory and Data Memory. Program memory can
only be read, not written to. It can be up to 2K bytes of Pro-
gram memory. Data memory can be read and written to up
to 128 bytes including the stack area.
12.1 Registers
This device has six registers that are the Program Counter
(PC), a Accumulator (A), two index registers (X, Y), the
Stack Pointer (SP), and the Program Status Word (PSW).
The Program Counter consists of 16-bit register.
A
ACCUMULATOR
X
X REGISTER
Y
Y REGISTER
SP
PCH
STACK POINTER
PCL
PROGRAM COUNTER
PSW
PROGRAM STATUS
WORD
Figure 12-1 Configuration of Registers
• Stack Pointer
The Stack Pointer is an 8-bit register used for occurrence
interrupts and calling out subroutines. Stack Pointer identifies the location in the stack to be accessed (save or restore).
Generally, SP is automatically updated when a subroutine
call is executed or an interrupt is accepted. However, if it
is used in excess of the stack area permitted by the data
memory allocating configuration, the user-processed data
may be lost.
The stack can be located at any position within 00H to7FH
of the internal data memory. The SP is not initialized by
hardware, requiring to write the initial value (the location
with which the use of the stack starts) by using the initialization routine. Normally, the initial value of "7FH" is used
.
• Accumulator
Stack Address ( 000H ~ 07FH )
The Accumulator is the 8-bit general purpose register, used
for data operation such as transfer, temporary saving, and
conditional judgement, etc.
The Accumulator can be used as a 16-bit register with Y
Register as shown below
.
Y
Y
A
15
8
0
7
0
SP
Hardware fixed
Note: The Stack Pointer must be initialized by software because its value is undefined after RESET.
Example: To initialize the SP
LDX
#07FH
TXSP
; SP ← 7FH
A
Two 8-bit Registers can be used as a "YA" 16-bit Register
Figure 12-2 Configuration of YA 16-bit Register
• X, Y Registers
In the addressing mode which uses these index registers,
the register contents are added to the specified address,
which becomes the actual address. These modes are extremely effective for referencing subroutine tables and
memory tables. The index registers also have increment,
decrement, comparison and data transfer functions, and
they can be used as simple accumulators.
26
• Program Counter
The Program Counter is a 16-bit wide which consists of
two 8-bit registers, PCH and PCL. This counter indicates
the address of the next instruction to be executed. In reset
state, the program counter has reset routine address
(PCH:0FFH, PCL:0FEH).
• Program Status Word
The Program Status Word (PSW) contains several bits that
reflect the current state of the CPU. The PSW is described
in Figure 12-3. It contains the Negative flag, the Overflow
flag, the Break flag the Half Carry (for BCD operation),
the Interrupt enable flag, the Zero flag, and the Carry flag.
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
[Carry flag C]
[Zero flag Z]
This flag stores any carry or borrow from the ALU of CPU
after an arithmetic operation and is also changed by the
Shift Instruction or Rotate Instruction.
This flag is set when the result of an arithmetic operation
or data transfer is "0" and is cleared by any other result.
MSB
PSW
N
LSB
V
-
B
H
I
Z
C
RESET VALUE : 00H
CARRY FLAG RECEIVES
CARRY OUT
NEGATIVE FLAG
OVERFLOW FLAG
ZERO FLAG
BRK FLAG
INTERRUPT ENABLE FLAG
HALF CARRY FLAG RECEIVES
CARRY OUT FROM BIT 1 OF
ADDITION OPERLANDS
Figure 12-3 PSW (Program Status Word) Register
[Interrupt disable flag I]
dress.
This flag enables/disables all interrupts except interrupt
caused by Reset or software BRK instruction. All interrupts are disabled when cleared to "0". This flag immediately becomes "0" when an interrupt is served. It is set by
the EI instruction and cleared by the DI instruction.
[Overflow flag V]
[Half carry flag H]
After operation, this is set when there is a carry from bit 3
of ALU or there is no borrow from bit 4 of ALU. This bit
can not be set or cleared except CLRV instruction with
Overflow flag (V).
[Break flag B]
This flag is set by software BRK instruction to distinguish
BRK from TCALL instruction with the same vector ad-
Jan. 2002 ver 2.0
This flag is set to "1" when an overflow occurs as the result
of an arithmetic operation involving signs. An overflow
occurs when the result of an addition or subtraction exceeds +127(7FH) or -128(80H). The CLRV instruction
clears the overflow flag. There is no set instruction. When
the BIT instruction is executed, bit 6 of memory is copied
to this flag.
[Negative flag N]
This flag is set to match the sign bit (bit 7) status of the result of a data or arithmetic operation. When the BIT instruction is executed, bit 7 of memory is copied to this flag.
27
GMS81C1102 / GMS81C1202
12.2 Program Memory
A 16-bit program counter is capable of addressing up to
64K bytes, but this device has 2K bytes program memory
space only the physically implemented. Accessing a location above FFFFH will cause a wrap-around to 0000H.
Figure 12-4 shows a map of the upper part of the Program
Memory. After reset, the CPU begins execution from reset
vector which is stored in address FFFEH, FFFFH.
As shown in Figure 12-4, each area is assigned a fixed location in Program Memory. Program Memory area contains the user program, Page Call (PCALL) area contains
subroutine program, to reduce program byte length because of using by 2 bytes PCALL instead of 3 bytes CALL
instruction. If it is frequently called, more useful to save
program byte length.
spaced at 2-byte interval : FFC0H for TCALL15, FFC2H
for TCALL14, etc.
The interrupt causes the CPU to jump to specific location,
where it commences execution of the service routine. The
External interrupt 0, for example, is assigned to location
FFFAH. The interrupt service locations are spaced at 2byte interval : FFF8H for External Interrupt 1, FFFAH for
External Interrupt 0, etc.
0F50H
DEVICE
CONFIGURATION
AREA
0FF0H
NOT USED
F800H
PROGRAM
MEMORY
ID
0F50H
ID
0F60H
ID
0F70H
ID
0F80H
ID
0F90H
ID
0FA0H
ID
0FB0H
ID
0FC0H
ID
0FD0H
ID
0FE0H
CONFIG
0FF0H
FEFFH
FF00H
PCALL
AREA
FFBFH
FFC0H
FFDFH
FFE0H
TCALL
AREA
INTERRUPT
VECTOR AREA
FFFFH
Figure 12-4 Program Memory Map
The Device Configuration Area can be programmed or left
unprogrammed to select device configuration such as RC
oscillation option. This area is not accessible during normal execution but is readable and writable during program
/ verify.
More detail informations are explained in device configuration area section.
Table Call (TCALL) causes the CPU to jump to each
TCALL address, where it commences execution of the
service routine. The Table Call service locations are
28
Address
TCALL Name
FFC0H
FFC2H
FFC4H
FFC6H
FFC8H
FFCAH
FFCCH
FFCEH
FFD0H
FFD2H
FFD4H
FFD6H
FFD8H
FFDAH
FFDCH
FFDEH
TCALL15
TCALL14
TCALL13
TCALL12
TCALL11
TCALL10
TCALL9
TCALL8
TCALL7
TCALL6
TCALL5
TCALL4
TCALL3
TCALL2
TCALL1
TCALL0 / BRK 1
Table 12-1 TCALL Vectors
1.
The BRK software interrupt is using same address
with TCALL0.
As for the area from FF00H to FFFFH, if any area of them
is not going to be used, its service location is available as
general purpose Program Memory.
Address
Vector Name
FFE0H
FFE2H
FFE4H
FFE6H
FFE8H
FFEAH
FFECH
FFEEH
FFF0H
FFF2H
FFF4H
FFF6H
FFF8H
FFFAH
FFFCH
FFFEH
Not Used
Not Used
Not Used
Basic Interval Timer
Watchdog Timer
A/D Converter
Not Used
Not Used
Not Used
Not Used
Timer / Counter 1
Timer / Counter 0
External Interrupt 1
External Interrupt 0
Not Used
RESET
Table 12-2 Interrupt Vectors
Page Call (PCALL) area contains subroutine program to
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
reduce program byte length by using 2 bytes PCALL instead of 3 bytes CALL instruction. If it is frequently called,
it is more useful to save program byte length.
Table Call (TCALL) causes the CPU to jump to each
TCALL address, where it commences the execution of the
service routine. The Table Call service area spaces 2-byte
for every TCALL: 0FFC0H for TCALL15, 0FFC2H for
TCALL14, etc., as shown in Figure 12-5 .
Address
PCALL Area Memory
0FF00H
PCALL Area
(256 Bytes)
0FFFFH
Example: Usage of TCALL
LDA
#5
TCALL 0FH
:
:
;1BYTE INSTR UCTIO N
;INSTEAD OF 3 BYTES
;NOR M AL C ALL
;
;TABLE CALL ROUTINE
;
FUNC_A: LDA
LRG0
RET
;
FUNC_B: LDA
LRG1
2
RET
;
;TABLE CALL ADD. AREA
;
ORG
0FFC0H
DW
FUNC_A
DW
FUNC_B
1
;TCALL ADDRESS AREA
Address
Program Memory
0FFC0H
C1
TCALL 15
C2
C3
C4
C5
C6
C7
C8
C9
CA
CB
CC
CD
CE
CF
TCALL 14
TCALL 13
TCALL 12
TCALL 11
TCALL 10
TCALL 9
TCALL 8
D0
D1
D2
D3
D4
D5
D6
D7
D8
D9
DA
DB
DC
DD
DE
DF
TCALL 7
TCALL 6
TCALL 5
TCALL 4
TCALL 3
TCALL 2
TCALL 1
TCALL 0 / BRK *
NOTE:
* means that the BRK software interrupt is using
same address with TCALL0.
Figure 12-5 PCALL and TCALL Memory Area
Jan. 2002 ver 2.0
29
GMS81C1102 / GMS81C1202
PCALL→
→ rel
TCALL→
→n
4F35
4A
PCALL 35H
TCALL 4
4F
4A
01001010
35
~
~
~
~
~
~
0F125H
~
~
NEXT
➊
Reverse
PC: 11111111 11010110
FH FH
DH 6H
0FF00H
0FF35H
➌
NEXT
0FF00H
0FFFFH
0FFD6H
25
0FFD7H
F1
➋
0FFFFH
Example: The usage software example of Vector address and the initialize part.
ORG
0FFE0H
DW
DW
DW
DW
DW
DW
DW
DW
DW
DW
DW
DW
DW
DW
DW
DW
NOT_USED
NOT_USED
NOT_USED
BIT_INT
WDT_INT
AD_INT
NOT_USED
NOT_USED
NOT_USED
NOT_USED
TMR1_INT
TMR0_INT
INT1
INT0
NOT_USED
RESET
ORG
0F800H
;
;
;
;
;
;
;
;
;
;
;
;
;
;
;
;
(0FFEO)
(0FFE2)
(0FFE4)
(0FFE6)
(0FFE8)
(0FFEA)
(0FFEC)
(0FFEE)
(0FFF0)
(0FFF2)
(0FFF4)
(0FFF6)
(0FFF8)
(0FFFA)
(0FFFC)
(0FFFE)
Basic Interval Timer
Watchdog Timer
A/D
Timer-1
Timer-0
Int.1
Int.0
Reset
;********************************************
;
MAIN
PROGRAM
*
;********************************************
;
RESET: DI
;Disable All Interrupts
LDX
#0
RAM_CLR: LDA
#0
;RAM Clear(!0000H->!007FH)
STA
{X}+
CMPX
#080H
BNE
RAM_CLR
;
LDX
#07FH
;Stack Pointer Initialize
TXSP
;
CALL
INITIAL
;
;
LDM
RA, #0
;Normal Port A
LDM
RAIO,#1000_0010B ;Normal Port Direction
LDM
RB, #0
;Normal Port B
LDM
RBIO,#1000_0010B ;Normal Port Direction
:
:
LDM
PFDR,#0
;Enable Power Fail Detector
:
30
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
12.3 Data Memory
Figure 12-6 shows the internal Data Memory space available. Data Memory is divided into two groups, a user
RAM(including Stack) and control registers.
00H
DATA
MEMORY
(including STACK)
7FH
C0H
CONTROL
REGISTERS
FFH
Figure 12-6 Data Memory Map
Internal Data Memory addresses are always one byte wide,
which implies an address space of 128 bytes including the
stack area.
The stack pointer should be initialized within 00H to 7FH
by software because its value is undefined after RESET.
The Stack area is defined at the Data Memory area, so the
stack should not be overlapped by manipulating RAM Data. For example, we assumed the Stack pointer is 6F. If this
address is accessed by program, the stack value is changed.
So the malfunction is occurred.
The control registers are used by CPU and Peripheral functions for controlling the desired operation of the device.
Therefore these registers contain control and status bits for
the interrupt system, the timer/ counters, analog to digital
converters, I/O ports. The control registers are in address
C0H to FFH.
Address
C0H
C1H
C2H
C3H
C4H
C5H
CAH
CBH
CCH
D0H
D1H
D1H
D1H
D2H
D3H
D3H
D4H
D4H
D4H
D5H
DEH
E2H
E3H
E4H
E5H
E6H
EAH
EBH
ECH
ECH
EDH
EFH
Symbol
R/W
RESET Value
RA
RAIO
RB
RBIO
RC
RCIO
RAFUNC
RBFUNC
PUPSEL
TM0
T0
TDR0
CDR0
TM1
TDR1
T1PPR
T1
CDR1
T1PDR
PWMHR
BUR
IENH
IENL
IRQH
IRQL
IEDS
ADCM
ADCR
BITR
CKCTLR
WDTR
PFDR
R/W
W
R/W
W
R/W
W
W
W
W
R/W
R
W
R
R/W
W
W
R
R
R/W
W
W
R/W
R/W
R/W
R/W
R/W
R/W
R
R
W
R/W
R/W
Undefined
0000_0000
Undefined
---0_0000
Undefined
----_--00
0000_0000
---0_0000
----_--00
--00_0000
0000_0000
1111_1111
0000_0000
0000_0000
1111_1111
1111_1111
0000_0000
0000_0000
0000_0000
----_0000
1111_1111
0000_---000-_---0000_---000-_-------_0000
--00_0001
Undefined
0000_0000
-001_0111
0111_1111
----_-100
Table 12-3 RESET Value of Control Registers
Note: Several names are given at same address. Refer to
below table.
Note that unoccupied addresses may not be implemented
on the chip. Read accesses to these addresses will in general return random data, and write accesses will have an indeterminate effect.
Addr.
More detail informations of each register are explained in
each peripheral sections.
Timer
Mode
Capture
Mode
PWM
Mode
Timer
Mode
PWM
Mode
D1H
T0
CDR0
-
TDR0
-
TDR1
T1PPR
-
T1PDR
When read
D3H
When write
-
Note: Write only registers can not be accessed by bit manipulation instruction. Do not use read-modify-write
instruction. Use byte manipulation instruction.
ECH
Example; To write at CKCTLR
Table 12-4 Various Register Name in Same Adress
LDM
D4H
T1
CDR1
BITR
T1PDR
CKCTLR
CKCTLR,#09H ;Divide ratio ÷16
Jan. 2002 ver 2.0
31
GMS81C1102 / GMS81C1202
Stack Area
The stack provides the area where the return address is
saved before a jump is performed during the processing
routine at the execution of a subroutine call instruction or
the acceptance of an interrupt.
When returning from the processing routine, executing the
subroutine return instruction [RET] restores the contents of
the program counter from the stack; executing the interrupt
32
return instruction [RETI] restores the contents of the program counter and flags.
The save/restore locations in the stack are determined by
the stack pointed (SP). The SP is automatically decreased
after the saving, and increased before the restoring. This
means the value of the SP indicates the stack location
number for the next save.
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
Address
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
C0H
RA
RA Port Data Register
C1H
RAIO
RA Port Direction Register
C2H
RB
RB Port Data Register
C3H
RBIO
RB Port Direction Register
C4H
RC
RC Port Data Register
C5H
RCIO
RC Port Direction Register
CAH
RAFUNC
ANSEL7
ANSEL6
ANSEL5
ANSEL4
ANSEL3
ANSEL2
ANSEL1
ANSEL0
CBH
RBFUNC
-
-
-
PWMO
INT1I
INT0I
BUZO
AVREFS
CCH
PUPSEL
-
-
-
-
-
-
D0H
TM0
-
-
CAP0
T0CK2
T0CK1
T0CK0
D1H
T0/TDR0/
CDR0
D2H
TM1
D3H
TDR1/
T1PPR
Timer Data Register 1/ PWM Period Register 1
D4H
T1/CDR1/
T1PDR
Timer1 Register / Capture Data Register 1 / PWM Duty Register 1
D5H
PWMHR
PWM High Register
DEH
BUR
BUCK1
BUCK0
BUR5
BUR4
BUR3
E2H
IENH
INT0E
INT1E
T0E
T1E
E3H
IENL
ADE
WDTE
BITE
E4H
IRQH
INT0IF
INT1IF
E5H
IRQL
ADIF
E6H
IEDS
EAH
ADCM
EBH
ADCR
ADC Result Data Register
ECH
BITR1
Basic Interval Timer Data Register
ECH
CKCTLR
EDH
WDTR
WDTCL
EFH
PFDR2
-
Note1
PUPSEL1 PUPSEL0
T0CN
T0ST
T1CN
T1ST
BUR2
BUR1
BUR0
-
-
-
-
-
-
-
-
-
T0IF
T1IF
-
-
-
-
WDTIF
BITIF
-
-
-
-
-
-
-
-
-
IED1H
IED1L
IED0H
IED0L
-
-
ADEN
ADS2
ADS1
ADS0
ADST
ADSF
WDTON
BTCL
BTS2
BTS1
BTS0
-
PFDIS
PFDM
PFDS
Timer0 Register / Timer Data Register 0 / Capture Data Register 0
POL
-
16BIT
WAKEUP
PWME
RCWDT
CAP1
T1CK1
T1CK0
7-bit Watchdog Counter Register
-
-
-
Table 12-5 Control Registers of GMS81C1202
These registers of shaded area can not be accessed by bit manipulation instruction as “SET1, CLR1”, so should be accessed by
register operation instruction as “LDM dp,#imm”.
1.
2.
The register BITR and CKCTLR are located at same address. Address ECH is read as BITR, written to CKCTLR.
The register PFDR only be implemented on devices, not on In-circuit Emulator.
Jan. 2002 ver 2.0
33
GMS81C1102 / GMS81C1202
12.4 Addressing Mode
The GMS87C1201 and GMS81C1202 use six addressing
modes.
(3) Direct Page Addressing → dp
• Register addressing
Example;
• Immediate addressing
C535
In this mode, a address is specified within direct page.
LDA
;A ←RAM[35H]
35H
• Direct page addressing
• Absolute addressing
0035H
data
➋
• Indexed addressing
~
~
• Register-indirect addressing
~
~
0F850H
C5
0F851H
35
➊
data → A
Below example is shown for GMS81C1202.
(1) Register Addressing
Register addressing accesses the A, X, Y, C and PSW.
(2) Immediate Addressing → #imm
(4) Absolute Addressing → !abs
In this mode, second byte (operand) is accessed as a data
immediately.
Absolute addressing sets corresponding memory data to
Data , i.e. second byte(Operand I) of command becomes
lower level address and third byte (Operand II) becomes
upper level address.
With 3 bytes command, it is possible to access to whole
memory area.
Example:
0435
ADC
#35H
MEMORY
ADC, AND, CMP, CMPX, CMPY, EOR, LDA, LDX,
LDY, OR, SBC, STA, STX, STY
04
A+35H+C → A
35
Example;
0735F0
ADC
data
0F035H
E45535
LDM
0F900H
➊
0F900H
34
➋
35H,#55H
~
~
data ← 55H
data
0035H
;A ←ROM[0F035H]
!0F035H
~
~
~
~
~
~
➊
A+data+C → A
07
0F901H
35
0F902H
F0
address: 0F035
➋
E4
0F901H
55
0F902H
35
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
The operation within data memory (RAM)
ASL, BIT, DEC, INC, LSR, ROL, ROR
Example; Addressing accesses the address 0035H .
983500
INC
;A ←RAM[035H]
!0035H
X indexed direct page, auto increment→
→ {X}+
In this mode, a address is specified within direct page by
the X register and the content of X is increased by 1.
LDA, STA
Example; X=35H
DB
data
0035H
~
~
LDA
{X}+
➌
~
~
➋
data+1 → data
0FA00H
98
➊
0FA01H
35
address: 0035
0FA02H
00
35H
➋
data
~
~
~
~
data → A
➊
36H → X
DB
(5) Indexed Addressing
X indexed direct page (no offset) → {X}
In this mode, a address is specified by the X register.
ADC, AND, CMP, EOR, LDA, OR, SBC, STA, XMA
Example; X=15H
D4
LDA
{X}
;ACC←RAM[X].
X indexed direct page (8 bit offset) → dp+X
This address value is the second byte (Operand) of command plus the data of -register. And it assigns the memory in Direct page.
ADC, AND, CMP, EOR, LDA, LDY, OR, SBC, STA
STY, XMA, ASL, DEC, INC, LSR, ROL, ROR
Example; X=015H
15H
~
~
0FA50H
C645
data
~
~
D4
LDA
45H+X
➋
data → A
➊
5AH
data
➌
~
~
Jan. 2002 ver 2.0
➋
~
~
0FB50H
C6
0FB51H
45
data → A
➊
45H+15H=5AH
35
GMS81C1102 / GMS81C1202
Y indexed direct page (8 bit offset) → dp+Y
3F35
JMP
[35H]
This address value is the second byte (Operand) of command plus the data of Y-register, which assigns Memory in
Direct page.
This is same with above (2). Use Y register instead of X.
35H
0A
36H
FC
Y indexed absolute → !abs+Y
~
~
Sets the value of 16-bit absolute address plus Y-register
data as Memory. This addressing mode can specify memory in whole area.
Example; Y=55H
D500FA
LDA
~
~
D5
00
0F902H
FA
~
~
~
~
➊
3F
35
!0FA00H+Y
0F900H
➋ jump to address 0FC0AH
NEXT
0FD00H
0F901H
0FA55H
0FC0AH
~
~
➊
0FA00H+55H=0FA55H
~
~
➋
data
➌
data → A
X indexed indirect → [dp+X]
Processes memory data as Data, assigned by 16-bit pair
memory which is determined by pair data
[dp+X+1][dp+X] Operand plusX-register data in Direct
page.
ADC, AND, CMP, EOR, LDA, OR, SBC, STA
Example; X=10H
1625
ADC
[25H+X]
(6) Indirect Addressing
Direct page indirect → [dp]
Assigns data address to use for accomplishing command
which sets memory data(or pair memory) by Operand.
Also index can be used with Index register X,Y.
JMP, CALL
35H
05
36H
F9
0F905H
~
~ ➋
~
~
0F905H
~
~
Example;
0FA00H
~
~
16
25
36
➊ 25 + X(10) = 35H
data
➌ A + data + C → A
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
Y indexed indirect → [dp]+Y
Absolute indirect → [!abs]
Processes momory data as Data, assigned by the data
[dp+1][dp] of 16-bit pair memory paired by Operand in Direct pageplus Y-register data.
The program jumps to address specified by 16-bit absolute
address.
ADC, AND, CMP, EOR, LDA, OR, SBC, STA
Example; Y=10H
1725
ADC
JMP
Example;
1F25F9
JMP
[!0F925H]
[25H]+Y
PROGRAM MEMORY
25H
05
0F925H
E1
26H
F8
0F926H
F9
~
~
0F815H
~
~
0FA00H
0F805H + Y(10) = 0F815H
➊
data
~
~
➋
~
~
➊
0F9E1H
0FA00H
17
Jan. 2002 ver 2.0
➌ A + data + C → A
➋
jump to
address 0F9E1H
NEXT
~
~
~
~
25
~
~
~
~
1F
25
F9
37
GMS81C1102 / GMS81C1202
13. I/O PORTS
The GMS81C1202 has three ports, RA, RB and RC. These
ports pins may be multiplexed with an alternate function
for the peripheral features on the device. In general, when
a initial reset state, all ports are used as a general purpose
input port.
All pins have data direction registers which can set these
ports as output or input. A “1” in the port direction register
defines the corresponding port pin as output. Conversely,
write “0” to the corresponding bit to specify as an input
pin. For example, to use the even numbered bit of RA as
output ports and the odd numbered bits as input ports, write
“55H” to address C1H (RA direction register) during initial
setting as shown in Figure 13-1.
Reading data register reads the status of the pins whereas
writing to it will write to the port latch.
WRITE "55H" TO PORT RA DIRECTION REGISTER
C0H
RA DATA
C1H
RA DIRECTION
C2H
RB DATA
C3H
RB DIRECTION
0 1 0 1 0 1 0 1
7 6 5 4 3 2 1 0
I O I
BIT
O I O I O
7 6 5 4 3 2 1 0 PORT
I : INPUT PORT
O : OUTPUT PORT
Figure 13-1 Example of port I/O assignment
13.1 RA and RAIO registers
RA is an 8-bit bidirectional I/O port (address C0H). Each
port can be set individually as input and output through the
RAIO register (address C1H).
RA7~RA1 ports are multiplexed with Analog Input Port
( AN7~AN1 ) and RA0 port is multiplexed with Event
Counter Input Port ( EC0 ).
RA Data Register
RA
ADDRESS : C0H
RESET VALUE : Undefined
may be used as general I/O ports. To select alternate function such as Analog Input or External Event Counter Input,
write "1" to the corresponding bit of RAFUNC.Regardless
of the direction register RAIO, RAFUNC is selected to use
as alternate functions, port pin can be used as a corresponding alternate features ( RA0/EC0 is controlled by RBFUNC )
PORT
RA7 RA6 RA5 RA4 RA3 RA2 RA1 RA0
RAFUNC.7~0
Description
0
RA7 ( Normal I/O Port )
1
AN7 ( ADS2~0=111 )
0
RA6 ( Normal I/O Port )
1
AN6 ( ADS2~0=110 )
0
RA5 ( Normal I/O Port )
1
AN5 ( ADS2~0=101 )
0
RA4 ( Normal I/O Port )
1
AN4 ( ADS2~0=100 )
0
RA3 ( Normal I/O Port )
1
AN3 ( ADS2~0=011 )
0
RA2 ( Normal I/O Port )
1
AN2 ( ADS2~0=010 )
0
RA1 ( Normal I/O Port )
1
AN1 ( ADS2~0=001 )
RA7/AN7
INPUT / OUTPUT DATA
RA Direction Register
RAIO
ADDRESS : C1H
RESET VALUE : 00000000
RA6/AN6
RA7 RA6 RA5 RA4 RA3 RA2 RA1 RA0
RA5/AN5
DIRECTION SELECT
0 : INPUT PORT
1 : OUTPUT PORT
RA Function Selection Register
RAFUNC
ADDRESS : CAH
RESET VALUE : 00000000
RA4/AN4
RA3/AN3
ANSEL7 ANSEL6 ANSEL5 ANSEL4 ANSEL3 ANSEL2 ANSEL1 ANSEL0
0 : RA4
1 : AN4
0 : RA5
1 : AN5
0 : RA6
1 : AN6
0 : RA7
1 : AN7
0 : RB0
1 : AN0
0 : RA1
1 : AN1
0 : RA2
1 : AN2
0 : RA3
1 : AN3
Figure 13-2 Registers of Port RA
The control register RAFUNC (address CAH) controls to
select alternate function. After reset, this value is "0", port
38
RA2/AN2
RA1/AN1
RA0/EC01
RA0 ( Normal I/O Port )
EC0 ( T0CK2~0=111 )
1. This port is not an Analog Input port, but Event Counter
clock source input port. ECO is controlled by setting
TOCK2~0 = 111.
The bit RAFUNC.0 (ANSEL0) controls the RB0/AN0/AVref
port ( Refer to Port RB).
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
13.2 RB and RBIO registers
RB is a 5-bit bidirectional I/O port (address C2H). Each
pin can be set individually as input and output through the
RBIO register (address C3H).
Pull-up Selection Register
RB Data Register
RB
ADDRESS : C2H
RESET VALUE : Undefined
ADDRESS : CCH
RESET VALUE : ------00
PUPSEL
RB4 RB3 R B 2 RB1 RB0
-
-
-
RB3 / INT1 Pull-up
0 : No Pull-up
1 : With Pull-up
INPUT / OUTPUT DATA
RB Direction Register
ADDRESS : C3H
RESET VALUE : ---00000
RBIO
-
-
-
PUP1
-
PUP0
RB2 / INT0 Pull-up
0 : No Pull-up
1 : With Pull-up
Interrupt Edge Selection Register
RB4 RB3 RB2 RB1 RB0
ADDRESS : E6H
RESET VALUE : ----0000
IEDS
IED1H
DIRECTION SELECT
0 : INPUT PORT
1 : OUTPUT PORT
IED1L
IED0H
INT1
IED0L
INT0
External Interrupt Edge Select
RB Function Selection Register
PWMO
00 : Normal I/O port
01 : Falling ( 1-to-0 transition )
10 : Rising ( 0-to-1 transition )
11 : Both ( Rising & Falling )
ADDRESS : CBH
RESET VALUE : ---00000
RBFUNC
INT1I
INT0I
BUZO
AVREFS
0 : RB0 when ANSEL0 = 0, AN0 when ANSEL0 = 1
1 : AVref
0 : RB4
1 : PWM0 Output or
Compare Output
0 : RB3
1 : INT1
0 : RB2
1 : INT0
0 : RB1
1 : BUZ Output
The shaded areas are only related with in GMS81C1202.
So in GMS81C1102, this area must be written to “0”.
Figure 13-3 Registers of Port RB
In addition, Port RB is multiplexed with various special
features. The control register RBFUNC (address CBH)
controls to select alternate function. After reset, this value
is "0", port may be used as general I/O ports. To select alternate function such as External interrupt or Timer compare output, write "1" to the corresponding bit of
RBFUNC.
Regardless of the direction register RBIO, RBFUNC is selected to use as alternate functions, port pin can be used as
a corresponding alternate features.
PORT
RBFUNC.4~0
RB4/
PWM0/
COMP0
0
RB4 ( Normal I/O Port )
1
PWM0 Output /
Timer1 Compare Output
0
RB3 ( Normal I/O Port )
1
External Interrupt Input 1
0
RB2 ( Normal I/O Port )
1
External Interrupt Input 0
0
RB1 ( Normal I/O Port )
1
Buzzer Output
01
RB0 ( Normal I/O Port ) /
AN0 (ANSEL0=1)
12
External Analog Reference
Voltage
RB3/INT1
RB2/INT0
RB1/BUZ
RB0/AN0/
AVref
Description
1. When ANSEL0 = "0", this port is defined for normal I/O port
( RB0 ).
When ANSEL0 = "1" and ADS2~0 = " 000", this port
can be used Analog Input Port ( AN0 ).
2. When this bit set to "1", this port defined for AVref , so it can
not be used Analog Input Port AN0 and Normal I/O
Port RB0.
Jan. 2002 ver 2.0
39
GMS81C1102 / GMS81C1202
13.3 RC and RCIO registers
RC is an 4-bit bidirectional I/O port (address C4H). Each
pin can be set individually as input and output through the
RCIO register (address C5H).
ADDRESS : C4H
RESET VALUE : Undefined
RC Data Register
RC
-
-
-
-
-
-
RC1 RC0
ADDRESS : C5H
RESET VALUE : ------00
RC Direction Register
RCIO
-
INPUT / OUTPUT DATA
-
-
-
-
-
RC1 RC0
DIRECTION SELECT
0 : INPUT PORT
1 : OUTPUT PORT
Figure 13-4 Registers of Port RC
40
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
14. CLOCK GENERATOR
Xin and Xout pins. External clocks can be input to the main
system clock oscillator. In this case, input a clock signal to
the Xin pin and open the Xout pin
The clock generator produces the basic clock pulses which
provide the system clock to be supplied to the CPU and peripheral hardware. The main system clock oscillator oscillates
with a crystal resonator or a ceramic resonator connected to the
OSCILLATION
CIRCUIT
fxin
CLOCK PULSE
GENERATOR
Internal system clock
PRESCALER
STOP
WAKEUP
÷1
÷2
÷4
÷8
÷16
÷32
÷64
÷128
÷256
÷512
÷1024 ÷2048
Peripheral clock
Figure 14-1 Block Diagram of Clock Pulse Generator
14.1 Oscillation Circuit
XIN and XOUT are the input and output, respectively, a inverting amplifier which can be set for use as an on-chip oscillator, as shown in Figure 14-2 .
Xout
C1
C2
R1
Xin
ings for timing insensitive applications. The RC
oscillator frequency is a function of the supply voltage, the
external resistor (Rext) and capacitor (Cext) values, and
the operating temperature.
The user needs to take into account variation due to tolerance of external R and C components used. Figure 14-4
shows how the RC combination is connected to the
GMS81C1202.
Vss
OPEN
Recommended: C1, C2 = 30pF±10pF for Crystals
R1 = 1MΩ
Figure 14-2 Oscillator Connections
To drive the device from an external clock source, Xout
should be left unconnected while Xin is driven as shown in
Figure 14-3. There are no requirements on the duty cycle
of the external clock signal, since the input to the internal
clocking circuitry is through a divide-by-two flip-flop, but
minimum and maximum high and low times specified on
the data sheet must be observed.
Oscillation circuit is designed to be used either with a ceramic resonator or crystal oscillator. Since each crystal and
ceramic resonator have their own characteristics, the user
should consult the crystal manufacturer for appropriate
values of external components
In addition, the GMS81C1202 has an ability for the external RC oscillated operation. It offers additional cost sav-
Jan. 2002 ver 2.0
External
Clock
Source
Xout
Xin
Vss
Figure 14-3 External Clock Connections
Note: When using a system clock oscillator, carry out wiring in the broken line area in Figure 14-2 to prevent
any effects from wiring capacities.
- Minimize the wiring length.
- Do not allow wiring to intersect with other signal
conductors.
- Do not allow wiring to come near changing high
current.
- Set the potential of the grounding position of the
oscillator capacitor to that of VSS. Do not ground to
any ground pattern where high current is present.
- Do not fetch signals from the oscillator.
41
GMS81C1102 / GMS81C1202
Vdd
Rext
Xin
Note: When using a system clock oscillator, carry out wiring in the broken line area in Figure 14-2 to prevent
any effects from wiring capacities.
- Minimize the wiring length.
Cext
- Do not allow wiring to intersect with other signal
fxin÷4
Xout
Figure 14-4 RC Oscillator Connections
The oscillator frequency, divided by 4, is output from the
Xout pin, and can be used for test purpose or to synchroze
other logic.
conductors.
- Do not allow wiring to come near changing
high current.
- Set the potential of the grounding position of the oscillator capacitor to that of VSS. Do not ground to
any ground pattern where high current is
present.
- Do not fetch signals from the oscillator.
To set the RC oscillation, it should be programmed
RCOPT bit to "1" to CONFIG (0FF0H). ( Refer to DEVICE CONFIGURATION AREA )
42
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
15. Basic Interval Timer
If the STOP instruction executed after writing "1" to bit
RCWDT of CKCTLR, it goes into the internal RC oscillated watchdog timer mode. In this mode, all of the block is
halted except the internal RC oscillator, Basic Interval
Timer and Watchdog Timer. More detail informations are
explained in Power Saving Function. The bit WDTON decides Watchdog Timer or the normal 7-bit timer
The GMS81C1202 has one 8-bit Basic Interval Timer that
is free-run, can not stop. Block diagram is shown in Figure
15-1 .The 8-bit Basic interval timer register (BITR) is increased every internal count pulse which is divided by
prescaler. Since prescaler has divided ratio by 8 to 1024,
the count rate is 1/8 to 1/1024 of the oscillator frequency.
As the count overflows from FF H to 00H, this overflow
causes to generate the Basic interval timer interrupt. The
BITF is interrupt request flag of Basic interval timer.
Note: All control bits of Basic interval timer are in CKCTLR
register which is located at same address of BITR
(address ECH). Address ECH is read as BITR, written to CKCTLR. Therefore, the CKCTLR can not be
accessed by bit manipulation instruction.
When write "1" to bit BTCL of CKCTLR, BITR register is
cleared to "0" and restart to count-up. The bit BTCL becomes "0" after one machine cycle by hardware.
If the STOP instruction executed after writing "1" to bit
WAKEUP of CKCTLR, it goes into the wake-up timer
mode. In this mode, all of the block is halted except the oscillator, prescaler ( only fxin÷2048 ) and Timer0.
.
WAKEUP
RCWDT
STOP
BTS[2:0]
fxin
÷8
÷ 16
÷ 32
÷ 64
÷ 128
÷ 256
÷ 512
÷ 1024
BTCL
3
To Watchdog Timer
Clear
8
MUX
0
BITIF
BITR (8BIT)
Basic Interval Timer
Interrupt
1
Internal RC OSC
Figure 15-1 Block Diagram of Basic Interval Timer
Clock Control Register
CKCTLR
-
WAKEUP RCWDT
WDTON
BTCL
BTS2
BTS1
BTS0
ADDRESS : ECH
RESET VALUE : -0010111
Bit Manipulation Not Available
Basic Interval Timer Clock Selection
Symbol
WAKEUP
Function Description
1: Enables Wake-up Timer
0: Disables Wake-up Timer
RCWDT
1: Enables Internal RC Watchdog Timer
0: Disables Internal RC Watchdog Time
WDTON
1: Enables Watchdog Timer
0: Operates as a 7-bit Timer
BTCL
1: BITR is cleared and BTCL becomes "0" automatically
after one machine cycle, and BITR continue to count-up
000 : fxin ÷ 8
001 : fxin ÷ 16
010 : fxin ÷ 32
011 : fxin ÷ 64
100 : fxin ÷ 128
101 : fxin ÷ 256
110 : fxin ÷ 512
111 : fxin ÷ 1024
Figure 15-2 CKCTLR : Clock Control Register
Jan. 2002 ver 2.0
43
GMS81C1102 / GMS81C1202
16. TIMER / COUNTER
The GMS81C1202 has two Timer/Counter registers. Each
module can generate an interrupt to indicate that an event
has occurred (i.e. timer match).
Timer 0 and Timer 1 can be used either the two 8-bit Timer/Counter or one 16-bit Timer/Counter by combining
them.
In the "timer" function, the register is increased every internal clock input. Thus, one can think of it as counting internal clock input. Since a least clock consists of 2 and
most clock consists of 2048 oscillator periods, the count
rate is 1/2 to 1/2048 of the oscillator frequency in Timer0.
And Timer1 can use the same clock source too. In addition,
Timer1 has more fast clock source ( 1/1 to 1/8 ).
sponse to a 0-to-1 (rising edge) transition at its corresponding external input pin, EC0.
And in the "capture" function, the register is increased in
response external interrupt same with timer function.
When external interrupt edge input, the count register is
captured into capture data register CDRx.
Timer1 is shared with "PWM" function and "Compare output" function
It has seven operating modes: "8-bit timer/counter", "16bit timer/counter", "8-bit capture", "16-bit capture", "8-bit
compare output", "16-bit compare output" and "10-bit
PWM" which are selected by bit in Timer mode register
TM0 and TM1 as shown in Figure 16-1 and Table 16-1.
In the "counter" function, the register is increased in re-
Timer 0 Mode Register
TM0
-
-
CAP0
T0CK2
T0CK1
T0CK0
T0CN
ADDRESS : D0H
RESET VALUE : --000000
T0ST
CAP0
Capture mode selection bit.
0 : Disables Capture
1 : Enables Capture
T0CN
Continue control bit
0 : Stop counting
1 : Start counting continuously
T0CK[2:0]
Input clock selection
000 : fxin ÷ 2
100 : fxin ÷ 128
T0ST
Start control bit
0 : Stop counting
1 : Start countingn
010 : fxin ÷ 8
110 : fxin ÷ 2048
001 : fxin ÷ 4
011 : fxin ÷ 32
101 : fxin ÷ 512
111 : External Event ( EC0 )
Timer 1 Mode Register
TM1
POL
POL
16BIT
PWME
CAP1
T1CK1
T1CK0
T1CN
ADDRESS : D2H
RESET VALUE : 00000000
T1ST
PWM Output Polarity
0 : Duty active low
1 : Duty active high
T1CK[2:0]
16BIT
16-bit mode selection
0 : 8-bit mode
1 : 16-bit mode
T1CN
Continue control bit
0 : Stop counting
1 : Start counting continuously
PWME
PWM enable bit
0 : Disables PWM
1 : Enables PWM
T1ST
Start control bit
0 : Stop counting
1 : Start countingn
CAP1
Capture mode selection bit.
0 : Disables Capture
1 : Enables Capture
Input clock selection
00 : fxin
10 : fxin ÷ 8
01 : fxin ÷ 2
11 : using the Timer 0 clock
Figure 16-1 Timer 0 and Timer 1 Mode Register
44
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
16BIT
CAP0
CAP1
PWME
T0CK[2:0]
T1CK[1:0]
PWMO1
0
0
0
0
XXX
XX
0
8-bit Timer
8-bit Timer
0
0
1
0
111
XX
0
8-bit Event Counter
8-bit Capture
0
1
0
0
XXX
XX
1
8-bit Capture
8-bit Compare output
0
0
0
1
XXX
XX
1
8-bit Timer/Counter
10-bit PWM
1
0
0
0
XXX
11
0
16-bit Timer
1
0
0
0
111
11
0
16-bit Event Counter
1
1
X2
0
XXX
11
0
16-bit Capture
1
0
0
0
XXX
11
1
16-bit Compare output
TIMER 0
TIMER1
Table 16-1 Operating Modes of Timer 0 and Timer 1
1.
2.
This bit is the bit4 of RB Function register(RBFUNC).
X : The value is “0” or “1” corresponding your operation.
16.1 8-bit Timer/Counter Mode
The GMS81C1202 has two 8-bit Timer/Counters, Timer 0
and Timer 1, as shown in Figure 16-2 .
The "timer" or "counter" function is selected by mode registers TM0, TM1 as shown in Figure 16-1 and Table 16-1
-
-
CAP0
T0CK2
T0CK1
T0CK0
T0CN
T0ST
-
-
0
X
X
X
X
X
POL
16BIT
PWME
CAP1
T1CK1
T1CK0
T1CN
T1ST
X
0
0
0
X
X
X
X
TM0
TM1
. To use as an 8-bit timer/counter mode, bit CAP0 of TM0
is cleared to "0" and bits 16BIT of TM1 should be cleared
to “0”(Table 16-1).
ADDRESS : D0H
RESET VALUE : --000000
ADDRESS : D2H
RESET VALUE : 00000000
X : The value "0" or "1" corresponding your operation.
T0CK[2:0]
T0ST
Edge Detector
0 : Stop
1 : Start
1
EC0
fxin
÷2
÷4
÷8
÷ 32
÷ 128
÷ 512
÷ 2048
÷1
÷2
÷8
CLEAR
T0 ( 8-bit )
MUX
TIMER 0
INTERRUPT
T0IF
COMPARATOR
T0CN
TDR0 ( 8-bit )
T1CK[1:0]
T1ST
0 : Stop
1 : Start
1
MUX
T1 ( 8-bit )
COMP0 PIN
CLEAR
F/F
T1IF
T1CN
TIMER 1
INTERRUPT
COMPARATOR
TDR1 ( 8-bit )
Figure 16-2 8-bit Timer / Counter Mode
Jan. 2002 ver 2.0
45
GMS81C1102 / GMS81C1202
(latched in T0F bit). As TDRx and Tx register are in same
address, when reading it as a Tx, written to TDRx.
These timers have each 8-bit count register and data register. The count register is increased by every internal or external clock input. The internal clock has a prescaler divide
ratio option of 2, 4, 8, 32,128, 512, 2048 (selected by control bits T0CK2, T0CK1 and T0CK0 of register TM0) and
1, 2, 8 (selected by control bits T1CK1 and T1CK0 of register TM1). In the Timer 0, timer register T0 increases
from 00H until it matches TDR0 and then reset to 00H. The
match output of Timer 0 generates Timer 0 interrupt
In counter function, the counter is increased every 0-to 1
(rising edge) transition of EC0 pin. In order to use counter
function, the bit RA0 of the RA Direction Register RAIO
is set to "0". The Timer 0 can be used as a counter by pin
EC0 input, but Timer 1 can not.
TDR1
n
n-1
nt
-c
ou
~~
PCP
~~
9
8
~~
up
7
6
5
4
3
2
1
0
Timer 1 (T1IF)
Interrupt
TIME
Interrupt period
= PCP x (n+1)
interrupt occurs
interrupt occurs
interrupt occurs
Figure 16-3 Counting Example of Timer Data Registers
TDR1
disable
nt
~~
clear & start
enable
up
-c
ou
stop
~~
TIME
Timer 1 (T1IF)
Interrupt
interrupt occurs
interrupt occurs
T1ST
Start & Stop
T1ST = 0
T1ST = 1
T1CN
Control count
T1CN = 0
T1CN = 1
Figure 16-4 Timer Count Operation
46
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
16.2 16-bit Timer/Counter Mode
The clock source of the Timer 0 is selected either internal
or external clock by bit T0CK2, T0CK1 and T0SL0.
The Timer register is being run with 16 bits. A 16-bit timer/
counter register T0, T1 are increased from 0000H until it
matches TDR0, TDR1 and then resets to 0000 H . The
match output generates Timer 0 interrupt not Timer 1 interrupt.
-
-
CAP0
T0CK2
T0CK1
T0CK0
T0CN
T0ST
-
-
0
X
X
X
X
X
POL
16BIT
PWME
CAP1
T1CK1
T1CK0
T1CN
T1ST
X
1
0
0
1
1
X
X
TM0
TM1
In 16-bit mode, the bits T1CK1,T1CK0 and 16BIT of TM1
should be set to "1" respectively.
ADDRESS : D0H
RESET VALUE : --000000
ADDRESS : D2H
RESET VALUE : 00000000
X : The value "0" or "1" corresponding your operation.
T0CK[2:0]
T0ST
0 : Stop
1 : Start
Edge Detector
1
EC0
fxin
÷2
÷4
÷8
÷ 32
÷ 128
÷ 512
÷ 2048
T1 ( 8-bit )
MUX
T0 ( 8-bit )
CLEAR
T0IF
T0CN
TIMER 0
INTERRUPT
COMPARATOR
F/F
TDR1 ( 8-bit )
TDR0 ( 8-bit )
COMP0 PIN
Figure 16-5 16-bit Timer / Counter Mode
16.3 8-bit Compare Output ( 16-bit )
The GMS87C1201 and GMS81C1202 has a function of
Timer Compare Output. To pulse out, the timer match can
goes to port pin( COMP0 ) as shown in Figure 16-2 and
Figure 16-5 . Thus, pulse out is generated by the timer
match. These operation is implemented to pin, RB4/
COMP0/PWM.
This pin output the signal having a 50 : 50 duty square
wave, and output frequency is same as below equation.
Oscillation Frequency
= -------------------------------------------------------------------------------2 × Prescaler Value × ( TDR + 1 )
In this mode, the bit PWMO of RB function register (RBFUNC) should be set to "1", and the bit PWME of timer1
mode register ( TM1 ) should be set to "0".
In addition, 16-bit Compare output mode is also available.
16.4 8-bit Capture Mode
The Timer 0 capture mode is set by bit CAP0 of timer
mode register TM0 (bit CAP1 of timer mode register TM1
for Timer 1) as shown in Figure 16-6.
As mentioned above, not only Timer 0 but Timer 1 can also
be used as a capture mode.
Jan. 2002 ver 2.0
The Timer/Counter register is increased in response internal or external input. This counting function is same with
normal timer mode, and Timer interrupt is generated when
timer register T0 (T1) increases and matches TDR0
(TDR1).
47
GMS81C1102 / GMS81C1202
This timer interrupt in capture mode is very useful when
the pulse width of captured signal is more wider than the
maximum period of Timer.
For example, in Figure 16-8 , the pulse width of captured
signal is wider than the timer data value (FFH) over 2
times. When external interrupt is occured, the captured
value (13H) is more little than wanted value. It can be obtained correct value by counting the number of timer overflow occurence.
Timer/Counter still does the above, but with the added feature that a edge transition at external input INTx pin causes
the current value in the Timer x register (T0,T1), to be captured into registers CDRx (CDR0, CDR1), respectively.
TM0
TM1
After captured, Timer x register is cleared and restarts by
hardware.
It has three transition modes: "falling edge", "rising edge",
"both edge" which are selected by interrupt edge selection
register IEDS (Refer to External interrupt section). In addition, the transition at INTx pin generate an interrupt.
Note: The CDRx, TDRx and Tx are in same address. In
the capture mode, reading operation is read the
CDRx, not Tx because path is opened to the CDRx,
and TDRx is only for writing operation.
-
-
CAP0
T0CK2
T0CK1
T0CK0
T0CN
T0ST
-
-
1
X
X
X
X
X
POL
16BIT
PWME
CAP1
T1CK1
T1CK0
T1CN
T1ST
X
0
0
1
X
X
X
X
T0CK[2:0]
ADDRESS : D0H
RESET VALUE : --000000
ADDRESS : D2H
RESET VALUE : 00000000
T0ST
0 : Stop
1 : Start
Edge Detector
1
EC0
fxin
÷2
÷4
÷8
÷ 32
÷ 128
÷ 512
CLEAR
T0 ( 8-bit )
MUX
T0IF
T0CN
CAPTURE
TIMER 0
INTERRUPT
COMPARATOR
CDR0 ( 8-bit )
TDR0 ( 8-bit )
÷ 2048
INT0IF
INT0
INT 0
INTERRUPT
T0ST
0 : Stop
1 : Start
IEDS[1:0]
÷1
÷2
÷8
1
MUX
CLEAR
T1 ( 8-bit )
T1IF
T1CK[1:0]
T1CN
IEDS[3:2]
TIMER 1
INTERRUPT
COMPARATOR
CDR1 ( 8-bit )
TDR1 ( 8-bit )
CAPTURE
INT1IF
INT 1
INTERRUPT
INT1
Figure 16-6 8-bit Capture Mode
48
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
This value is loaded to CDR0
n
T0
n-1
nt
ou
~~
~~
9
up
-c
8
7
6
5
4
~~
3
2
1
0
TIME
Ext. INT0 Pin
Interrupt Request
( INT0F )
Interrupt Interval Period
Ext. INT0 Pin
Interrupt Request
( INT0F )
Delay
Capture
( Timer Stop )
Clear & Start
Figure 16-7 Input Capture Operation
Ext. INT0 Pin
Interrupt Request
( INT0F )
Interrupt Interval Period = FFH + 01H + FFH +01H + 13H = 213H
Interrupt Request
( T0F )
FFH
FFH
T0
13H
00H
00H
Figure 16-8 Excess Timer Overflow in Capture Mode
Jan. 2002 ver 2.0
49
GMS81C1102 / GMS81C1202
16.5 16-bit Capture Mode
16-bit capture mode is the same as 8-bit capture, except
that the Timer register is being run will 16 bits.
In 16-bit mode, the bits T1CK1,T1CK0 and 16BIT of TM1
should be set to "1" respectively.
The clock source of the Timer 0 is selected either internal
or external clock by bit T0CK2, T0CK1 and T0CK0.
-
-
CAP0
T0CK2
T0CK1
T0CK0
T0CN
T0ST
-
-
1
X
X
X
X
X
POL
16BIT
PWME
CAP1
T1CK1
T1CK0
T1CN
T1ST
X
1
0
X
1
1
X
X
TM0
TM1
ADDRESS : D0H
RESET VALUE : --000000
ADDRESS : D2H
RESET VALUE : 00000000
X : The value "0" or "1" corresponding your operation.
T0CK[2:0]
T0ST
Edge Detector
0 : Stop
1 : Start
1
EC0
fxin
÷2
÷4
÷8
÷ 32
÷ 128
÷ 512
÷ 2048
CLEAR
T0 + T1 ( 16-bit )
MUX
T0CN
T0IF
TIMER 0
INTERRUPT
COMPARATOR
CAPTURE
CDR1 CDR0 TDR1 TDR0
( 8-bit ) ( 8-bit ) ( 8-bit ) ( 8-bit )
INT0IF
INT 0
INTERRUPT
INT0
IEDS[1:0]
Figure 16-9 16-bit Capture Mode
16.6 PWM Mode
The GMS81C1202 has a two high speed PWM (Pulse
Width Modulation) functions which shared with Timer1.
And writes duty value to the T1PDR and the
PWM0HR[1:0] same way.
In PWM mode, pin RB4/COMP0/PWM0 outputs up to a
10-bit resolution PWM output. This pin should be defined
as a PWM output by setting "1" bit PWMO in RBFUNC
register.
The T1PDR is configured as a double buffering for glitchless PWM output. In Figure 16-10 , the duty data is transfered from the master to the slave when the period data
matched to the counted value. ( i.e. at the beginning of next
duty cycle )
The period of the PWM output is determined by the
T1PPR (PWM0 Period Register) and PWM0HR[3:2]
(bit3,2 of PWM0 High Register) and the duty of the PWM
output is determined by the T1PDR (PWM0 Duty Register) and PWM0HR[1:0] (bit1,0 of PWM0 High Register).
The user writes the lower 8-bit period value to the T1PPR
and the higher 2-bit period value to the PWM0HR[3:2].
50
PWM Period = [ PWM0HR[3:2]T1PPR ] X Source Clock
PWM Duty = [ PWM0HR[1:0]T1PDR ] X Source Clock
The relation of frequency and resolution is in inverse proportion. Table 16-2 shows the relation of PWM frequency
vs. resolution.
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
determined by the bit POL ( 1: Low, 0: High ).
If it needed more higher frequency of PWM, it should be
reduced resolution.
It can be changed duty value when the PWM output. Howerver the changed duty value is output after the current period is over. And it can be maintained the duty value at
present output when changed only period value shown as
Figure 16-12 . As it were, the absolute duty time is not
changed in varying frequency. But the changed period value must greater than the duty value
Frequency
Resolution
T1CK[1:0]
= 00(125nS)
T1CK[1:0]
= 01(250nS)
T1CK[1:0]
= 10(1uS)
10-bit
7.8KHz
3.9KHz
0.98KHZ
9-bit
15.6KHz
7.8KHz
1.95KHz
8-bit
31.2KHz
15.6KHz
3.90KHz
7-bit
62.5KHz
31.2KHz
7.81KHz
Note: At PWM output start command, one first pulse would
be output abnormally. Because if user writes register values while timer is in operaiton, these register
could be set with certain values at first. To prevent
this operation, user must stop PWM timer clock and
then set the duty and the period register values.
Table 16-2 PWM Frequency vs. Resolution at 8MHz
The bit POL of TM1 decides the polarity of duty cycle.
If the duty value is set same to the period value, the PWM
output is determined by the bit POL ( 1: High, 0: Low ).
And if the duty value is set to "00H", the PWM output is
TM1
PWM0HR
.
POL
16BIT
PWME
CAP1
T1CK1
T1CK0
T1CN
T1ST
X
0
1
0
X
X
X
X
-
-
-
-
-
-
-
-
PWM0HR3PWM0HR2PWM0HR1PWM0HR0
X
X
X
Period High
T1ST
ADDRESS : D5H
RESET VALUE : ----0000
Bit Manipulation Not Available
X
Duty High
X : The value IS "0" or "1" corresponding your operation.
PWM0HR[3:2]
T0 clock source
ADDRESS : D2H
RESET VALUE : 00000000
T1PPR(8-bit)
0 : Stop
1 : Start
COMPARATOR
RB4/
PWM0
S Q
CLEAR
1
fxin
÷1
÷2
÷8
MUX
COMPARATOR
T1CK[1:0]
R
T1 ( 8-bit )
PWM0O
[RBFUNC.4]
POL
T1CN
Slave
T1PDR(8-bit)
PWM0HR[1:0]
Master
T1PDR(8-bit)
Figure 16-10 PWM Mode
Jan. 2002 ver 2.0
51
GMS81C1102 / GMS81C1202
~
~
~
~
fxin
02
03
04
05
80
81
3FF
00 01
02
03
~
~
~
~
PWM
POL=1
7F
~
~
~ ~
00 01
~ ~
~ ~
~
~
T1
~
~
PWM
POL=0
Duty Cycle [ 80H x 125nS = 16uS ]
Period Cycle [ 3FFH x 125nS = 127.875uS, 7.8KHz ]
T1CK[1:0] = 00 ( fxin )
PWM0HR = 0CH
Period PWM0HR3PWM0HR2
1
1
T1PPR (8-bit)
FFH
T1PPR = FFH
T1PDR = 80H
Duty
PWM0HR1PWM0HR0
0
0
T1PDR (8-bit)
80H
Figure 16-11 Example of PWM at 8MHz
T 1 C K [1:0 ] = 10 ( 1 u S )
PW M HR = 00H
T1PPR = 0EH
T 1 P D R = 0 5H
Write T1PPR to 0AH
Period changed
Source
clock
T1
01 02 03 04 05 06 07 08 09
0A 0B 0C 0D 0E
01 02 03 04 05 06 07 08 09 0A
01 02 03 04
05
PWM
POL=1
Duty Cycle
[ 05H x 1uS = 5uS ]
Period Cycle [ 0EH x 1uS = 14uS, 71KHz ]
Duty Cycle
[ 05H x 1uS = 5uS ]
Duty Cycle
[ 05H x 1uS = 5uS ]
Period Cycle [ 0AH x 1uS = 10uS, 100KHz ]
Figure 16-12 Example of Changing the Period in Absolute Duty Cycle (@8MHz)
52
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
17. Buzzer Output Function
Also, it is cleared by counter overflow and count up to output the square wave pulse of duty 50%.
The buzzer driver consists of 6-bit binary counter, the
buzzer register BUR and the clock selector. It generates
square-wave which is very wide range frequency (480
Hz~250 KHz at fxin = 4 MHz) by user programmable
counter.
The bit 0 to 5 of BUR determines output frequency for
buzzer driving. Frequency calculation is following as
shown below.
Pin RB1 is assigned for output port of Buzzer driver by setting the bit BUZO of RBFUNC to "1".
Oscillator Frequency
( ) = -----------------------------------------------------------------------------2 × Prescaler Ratio × ( BUR + 1 )
The 6-bit buzzer counter is cleared and start the counting
by writing signal to the register BUR. It is increased from
00H until it matches 6-bit register BUR.
BUR
BUCK1
BUCK0
Input clock selection
00 : fxin ÷ 8
BUR5
BUR4
BUR3
The bits BUCK1, BUCK0 of BUR selects the source clock
from prescaler output.
BUR2
BUR1
BUR0
ADDRESS : DEH
RESET VALUE : 11111111
Bit Manipulation Not Available
Buzzer Period Data
01 : fxin ÷ 16
10 : fxin ÷ 32
11 : fxin ÷ 64
fxin
÷8
÷ 16
÷ 32
÷ 64
MUX
COUNTER ( 6-bit )
F/F
COMPARATOR
BUCK[1:0]
RB1/BUZ PIN
BUR ( 6-bit )
BUZO
[RBFUNC.1]
Figure 17-1 Buzzer Driver
Jan. 2002 ver 2.0
53
GMS81C1102 / GMS81C1202
18. ANALOG TO DIGITAL CONVERTER
The analog-to-digital converter (A/D) allows conversion
of an analog input signal to a corresponding 8-bit digital
value. The A/D module has eight analog inputs, which are
multiplexed into one sample and hold. The output of the
sample and hold is the input into the converter, which generates the result via successive approximation.
The analog reference voltage is selected to VDD or AVref
by setting of the bit AVREFS in RBFUNC register. If external analog reference AVref is selected, the bit ANSEL0
should not be set to "1", because this pin is used to an analog reference of A/D converter.
The A/D module has two registers which are the control
register ADCM and A/D result register ADCR. The
ADCM register, shown in Figure 18-2 , controls the operation of the A/D converter module. The port pins can be
configured as analog inputs or digital I/O.
To use analog inputs, each port is assigned analog input
port by setting the bit ANSEL[7:0] in RAFUNC register.
And selected the corresponding channel to be converted by
setting ADS[2:0].
The processing of conversion is start when the start bit
ADST is set to "1". After one cycle, it is cleared by hardware. The register ADCR contains the results of the A/D
conversion. When the conversion is completed, the result
is loaded into the ADCR, the A/D conversion status bit
ADSF is set to "1", and the A/D interrupt flag ADIF is set.
The block diagram of the A/D module is shown in Figure
18-1. The A/D status bit ADSF is set automatically when
A/D conversion is completed, cleared when A/D conversion is in process. The conversion time takes maximum 10
uS (at fxin=8 MHz).
ADS[2:0]
111
RA7/AN7
ANSEL7
110
RA6/AN6
A/D Result Register
ANSEL6
101
ADCR(8-bit)
RA5/AN5
ADDRESS : EBH
RESET VALUE : Undefined
ANSEL5
100
RA4/AN4
ANSEL4
Sample & Hold
S/H
Successive
Approximation
Circuit
011
RA3/AN3
A D IF
A/D Interrupt
ANSEL3
010
RA2/AN2
ANSEL2
001
RA1/AN1
Resistor
Ladder
Circuit
ANSEL1
000
RB0/AN0/AVref
ANSEL0 ( RAFUNC.0 )
1
VDD Pin
0
ADEN
AVREFS ( RBFUNC.0 )
Figure 18-1 A/D Converter Block Diagram
54
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
A/D Control Register
-
ADCM
-
ADEN
ADS2
ADS1
ADS0
ADST
ADSF
ADDRESS : EAH
RESET VALUE : --000001
Reserved
A/D Status bit
0 : A/D Conversion is in process
1 : A/D Conversion is completed
Analog Channel Select
000 : Channel 0 ( RB0/AN0 )
001 : Channel 1 ( RA1/AN1 )
010 : Channel 2 ( RA2/AN2 )
011 : Channel 3 ( RA3/AN3)
100 : Channel 4 ( RA4/AN4 )
101 : Channel 5 ( RA5/AN5 )
110 : Channel 6 ( RA6/AN6 )
111 : Channel 7 ( RA7/AN7 )
A/D Start bit
1 : A/D Conversion is started
After 1 cycle, cleared to "0"
0 : Bit force to zero
A/D Enable bit
1 : A/D Conversion is enable
0 : A/D Converter module shut off
and consumes no operation current
A/D Result Data Register
ADCR
ADCR7
ADCR6
ADCR5
ADCR4
ADCR3
ADCR2
ADCR1
ADCR0
ADDRESS : EBH
RESET VALUE : Undefined
Figure 18-2 A/D Converter Registers
A/D Converter Cautions
(1) Input range of AN0 to AN7
ENABLE A/D CONVERTER
The input voltages of AN0 to AN7 should be within the
specification range. In particular, if a voltage above VDD
(or AVref) or below VSS is input (even if within the absolute maximum rating range), the conversion value for that channel can not
be indeterminate. The conversion values of the other channels
may also be affected.
A/D INPUT CHANNEL SELECT
(2) Noise countermeasures
ANALOG REFERENCE SELECT
In order to maintain 8-bit resolution, attention must be paid to
noise on pins AVref(or VDD)and AN0 to AN7. Since the effect
increases in proportion to the output impedance of the analog input source, it is recommended that a capacitor be con-
A/D START ( ADST = 1 )
nected externally as shown in Figure 18-4 in order to reduce
noise
NOP
.
ADSF = 1
NO
Analog
Input
AN0~AN7
YES
100~1000pF
READ ADCR
Figure 18-3 A/D Converter Operation Flow
Jan. 2002 ver 2.0
Figure 18-4 Analog Input Pin Connecting Capacitor
55
GMS81C1102 / GMS81C1202
(3) Pins AN0/RB0 and AN1/RA1 to AN7/RA7
The analog input pins AN0 to AN7 also function as input/
output port (PORT RA and RB0) pins. When A/D conversion is performed with any of pins AN0 to AN7 selected,
be sure not to execute a PORT input instruction while conversion is in progress, as this may reduce the conversion
resolution.
Also, if digital pulses are applied to a pin adjacent to the
pin in the process of A/D conversion, the expected A/D
conversion value may not be obtainable due to coupling
56
noise. Therefore, avoid applying pulses to pins adjacent to
the pin undergoing A/D conversion.
(4) AVREF pin input impedance
A series resistor string of approximately 10KΩ is connected between the AVREFpin and the VSS pin.
Therefore, if the output impedance of the reference voltage
source is high, this will result in parallel connection to the
series resistor string between the AVREF pin and the VSS pin, and
there will be a large reference voltage error.
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
19. INTERRUPTS
The GMS81C1202 interrupt circuits consist of Interrupt
enable register (IENH, IENL), Interrupt request flags of
IRQH, IRQL, Interrupt Edge Selection Register (IEDS),
priority circuit and Master enable flag("I" flag of PSW).
The configuration of interrupt circuit is shown in Figure
19-1 and Interrupt priority is shown in Table 19-1 .
The External Interrupts INT0 and INT1 can each be transition-activated (1-to-0, 0-to-1 and both transiton).
The flags that actually generate these interrupts are bit
INT0IFand INT1IF in Register IRQH. When an external
interrupt is generated, the flag that generated it is cleared
by the hardware when the service routine is vectored to
only if the interrupt was transition-activated.
The Timer 0 and Timer 1 Interrupts are generated by T0IF,
T1IF, which are set by a match in their respective timer/
counter register. The AD converter Interrupt is generated
by ADIF which is set by finishing the analog to digital conversion. The Watch dog timer Interrupt is generated by
WDTIF which set by a match in Watch dog timer register
( when the bit WDTON is set to "0"). The Basic Interval
Timer Interrupt is generated by BITIF which is set by a
overflowing of the Basic Interval Timer Register(BITR).
.
Internal bus line
IENH
I-flag is in PSW, it is cleared by “DI”, set by
“EI” instruction.When it goes interrupt service,
I-flag is cleared by hardware, thus any other
interrupt are inhibited. When interrupt service is
completed by “RETI” instruction, I-flag is set to
“1” by hardware.
Interrupt Enable
Register (Higher byte)
IRQH
INT0IF
IEDS
External Int. 1
INT1IF
Timer 0
T0IF
Timer 1
T1IF
ADIF
A/D Converter
WDT
WDTIF
BIT
BITIF
IRQL
7
Release STOP
6
5
Priority Control
External Int. 0
4
7
To CPU
I Flag
Interrupt Master
Enable Flag
6
Interrupt
Vector
Address
Generator
5
IENL
Interrupt Enable
Register (Lower byte)
Internal bus line
Figure 19-1 Block Diagram of Interrupt Function
The interrupts are controlled by the interrupt master enable
flag I-flag (bit 2 of PSW), the interrupt enable register
(IENH, IENL) and the interrupt request flags (in IRQH,
IRQL) except Power-on reset and software BRK interrupt.
Interrupt enable registers are shown in Figure 19-2 . These
registers are composed of interrupt enable flags of each interrupt source, these flags determines whether an interrupt
will be accepted or not. When enable flag is "0", a corresponding interrupt source is prohibited. Note that PSW
contains also a master enable bit, I-flag, which disables all
interrupts at once.
Jan. 2002 ver 2.0
Reset/Interrupt
Symbol
Priority
Vector Addr.
Hardware Reset
External Interrupt 0
External Interrupt 1
Timer 0
Timer 1
A/D Converter
Watch Dog Timer
Basic Interval Timer
RESET
INT0
INT1
Timer 0
Timer 1
A/D C
WDT
BIT
1
2
3
4
5
6
7
FFFEH
FFFAH
FFF8H
FFF6H
FFF4H
FFEAH
FFE8H
FFE6H
Table 19-1 Interrupt Priority
57
GMS81C1102 / GMS81C1202
Interrupt Enable Register High
IENH
INT0E
INT1E
T0E
T1E
-
-
-
-
ADDRESS : E2H
RESET VALUE : 0000----
-
-
-
-
-
ADDRESS : E3H
RESET VALUE : 000-----
Interrupt Enable Register Low
IENL
ADE
WDTE
BITE
Enables or disables the interrupt individually
If flag is cleared, the interrupt is disabled.
0 : Disable
1 : Enable
Interrupt Request Register High
IRQH
INT0IF
INT1IF
T0IF
T1IF
-
-
-
-
ADDRESS : E4H
RESET VALUE : 0000----
-
-
-
-
-
ADDRESS : E5H
RESET VALUE : 000-----
Interrupt Request Register Low
IRQL
ADIF
WDTIF
BITIF
Shows the interrupt occurrence
0 : Not occurred
1 : Interrupt request is occurred
Figure 19-2 Interrupt Enable Registers and Interrupt Request Registers
When an interrupt is occured, the I-flag is cleared and disable any further interrupt, the return address and PSW are
pushed into the stack and the PC is vectored to. Once in the
interrupt service routine the source(s) of the interrupt can
be determined by polling the interrupt request flag bits.
The interrupt request flag bit(s) must be cleared by software before re-enabling interrupts to avoid recursive interrupts. The Interrupt Request flags are able to be read and
written.
19.1 Interrupt Sequence
An interrupt request is held until the interrupt is accepted
or the interrupt latch is cleared to "0" by a reset or an instruction. Interrupt acceptance sequence requires 8 fOSC (2
µs at fXIN=4MHz) after the completion of the current instruction execution. The interrupt service task is terminated upon execution of an interrupt return instruction
[RETI].
Interrupt acceptance
1. The interrupt master enable flag (I-flag) is cleared to "0"
to temporarily disable the acceptance of any following
maskable interrupts. When a non-maskable interrupt is
accepted, the acceptance of any following interrupts is
58
temporarily disabled.
2. Interrupt request flag for the interrupt source accepted is
cleared to "0".
3. The contents of the program counter (return address)
and the program status word are saved (pushed) onto the
stack area. The stack pointer decreases 3 times.
4. The entry address of the interrupt service program is
read from the vector table address and the entry address
is loaded to the program counter.
5. The instruction stored at the entry address of the interrupt service program is executed.
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
System clock
Instruction Fetch
SP
Address Bus
PC
Data Bus
Not used
SP-1
PCH
PCL
SP-2
PSW
V.L.
V.L.
V.H.
ADL
New PC
ADH
OP code
Internal Read
Internal Write
Interrupt Processing Step
Interrupt Service Task
V.L. and V.H. are vector addresses.
ADL and ADH are start addresses of interrupt service routine as vector contents.
Figure 19-3 Timing chart of Interrupt Acceptance and Interrupt Return Instruction
Basic Interval Timer
Vector Table Address
Entry Address
The following method is used to save/restore the generalpurpose registers.
Example: Register save using push and pop instructions
0FFE6H
0FFE7H
012H
0E3H
0E312H
0E313H
0EH
2EH
Correspondence between vector table address for BIT interrupt
and the entry address of the interrupt service program.
A interrupt request is not accepted until the I-flag is set to
"1" even if a requested interrupt has higher priority than
that of the current interrupt being serviced.
When nested interrupt service is required, the I-flag should
be set to "1" by “EI” instruction in the interrupt service
program. In this case, acceptable interrupt sources are selectively enabled by the individual interrupt enable flags.
INTxx:
PUSH
PUSH
PUSH
A
X
Y
;SAVE ACC.
;SAVE X REG.
;SAVE Y REG.
interrupt processing
POP
POP
POP
RETI
Y
X
A
;RESTORE Y REG.
;RESTORE X REG.
;RESTORE ACC.
;RETURN
General-purpose register save/restore using push and pop
instructions;
main task
Saving/Restoring General-purpose Register
During interrupt acceptance processing, the program
counter and the program status word are automatically
saved on the stack, but accumulator and other registers are
not saved itself. These registers are saved by the software
if necessary. Also, when multiple interrupt services are
nested, it is necessary to avoid using the same data memory
area for saving registers.
Jan. 2002 ver 2.0
acceptance of
interrupt
interrupt
service task
saving
registers
restoring
registers
interrupt return
59
GMS81C1102 / GMS81C1202
19.2 BRK Interrupt
Software interrupt can be invoked by BRK instruction,
which has the lowest priority order.
Interrupt vector address of BRK is shared with the vector
of TCALL 0 (Refer to Program Memory Section). When
BRK interrupt is generated, B-flag of PSW is set to distinguish BRK from TCALL 0.
Each processing step is determined by B-flag as shown in
Figure 19-4.
B-FLAG
BRK or
TCALL0
=0
TIMER1: PUSH
PUSH
PUSH
LDM
LDM
EI
:
:
:
:
:
:
LDM
LDM
POP
POP
POP
RETI
A
X
Y
IENH,#80H
IENL,#0
;Enable INT0 only
;Disable other
;Enable Interrupt
IENH,#0FFH ;Enable all interrupts
IENL,#0F0H
Y
X
A
=1
BRK
INTERRUPT
ROUTINE
TCALL0
ROUTINE
RETI
RET
Main Program
service
TIMER 1
service
enable INT0
disable other
INT0
service
EI
Figure 19-4 Execution of BRK/TCALL0
Occur
TIMER1 interrupt
Occur
INT0
19.3 Multi Interrupt
If two requests of different priority levels are received simultaneously, the request of higher priority level is serviced. If requests of the interrupt are received at the same
time simultaneously, an internal polling sequence determines by hardware which request is serviced.
enable INT0
enable other
However, multiple processing through software for special
features is possible. Generally when an interrupt is accepted, the I-flag is cleared to disable any further interrupt. But
as user sets I-flag in interrupt routine, some further interrupt can be serviced even if certain interrupt is in progress.
In this example, the INT0 interrupt can be serviced without any
pending, even TIMER1 is in progress.
Because of re-setting the interrupt enable registers IENH,IENL
and master enable "EI" in the TIMER1 routine.
Example: Even though Timer1 interrupt is in progress,
INT0 interrupt serviced without any suspend.
Figure 19-5 Execution of Multi Interrupt
60
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
19.4 External Interrupt
The external interrupt on INT0 and INT1 pins are edge
triggered depending on the edge selection register IEDS
(address 0E6H) as shown in Figure 19-6 .
The edge detection of external interrupt has three transition
activated mode: rising edge, falling edge, and both edge
Ext. Interrupt Edge Selection
Register
W
W W
W
ADDRESS : 0E6H
RESET VALUE : 00000000
W
W
W
W
IEDS
INT0 pin
INT1 pin
edge selection
.
INT0IF
INT1IF
INT1 edge select
00: Int. disable
01: falling
10: rising
11: both
INT0 INTERRUPT
INT0 edge select
00: Int. disable
01: falling
10: rising
11: both
INT1 INTERRUPT
IEDS
[0E6H]
Figure 19-6 External Interrupt Block Diagram
The INT0 and INT1 edge are latched into INT0IF and
INT1IF at every machine cycle. The values are not actually
polled by the circuitry until the next machine cycle. If a request is active and conditions are right for it to be acknowledged, a hardware subroutine call to the requested service
routine will be the next instruction to be executed. The
DIV itself takes twelve cycles. Thus, a minimum of twelve
complete machine cycles elapse between activation of an
external interrupt request and the beginning of execution
of the first instruction of the service routine.
Example: To use as an INT0 and INT1
:
:
;**** Set port as an input port RB2,RB3
LDM
RBIO,#1111_0011B
;
;
;**** Set port as an interrupt port
LDM
RBFUNC,#0C0H
;
;
;**** Set Falling-edge Detection
LDM
IEDS,#0000_0101B
:
:
max. 12 fOSC
Interrupt Interrupt
goes
latched
active
Response Time
Below shows interrupt response timings.
8 fOSC
Interrupt
processing
Interrupt
routine
Figure 19-7 Interrupt Response Timing Diagram
Jan. 2002 ver 2.0
61
GMS81C1102 / GMS81C1202
20. WATCHDOG TIMER
The purpose of the watchdog timer is to detect the malfunction (runaway) of program due to external noise or
other causes and return the operation to the normal condition.
The watchdog timer has two types of clock source.
The first type is an on-chip RC oscillator which does not
require any external components. This RC oscillator is separate from the external oscillator of the Xin pin. It means
that the watchdog timer will run, even if the clock on the
Xin pin of the device has been stopped, for example, by entering the STOP mode.
The other type is a prescaled system clock.
The watchdog timer consists of 7-bit binary counter and
the watchdog timer data register. The source clock of
WDT is overflow of Basic Interval Timer. When the value
of 7-bit binary counter is equal to the lower 7 bits of
WDTR, the interrupt request flag is generated. This can be
used as WDT interrupt or CPU reset signal in accordance
with the bit WDTON .
Note: Because the watchdog timer counter is enabled after clearing Basic Interval Timer, after the bit WDTON set to "1", maximum error of timer is depend on
prescaler ratio of Basic Interval Timer.
The 7-bit binary counter is cleared by setting WDTCL(bit7
of WDTR) and the WDTCL is cleared automatically after
1 machine cycle.
The RC oscillated watchdog timer is activated by setting
the bit RCWDT of CKCTLR and executing the STOP instruction as shown below.
:
LDM
LDM
STOP
NOP
NOP
:
CKCTLR,#3FH
WDTR,#0FFH
; enable the RC-osc WDT
; set the WDT period
; enter the STOP mode
; RC-osc WDT running
The RC oscillation period is variable according to the temperature, VDD and process variations from part to part (approximately, 120~180uS). The following equation shows
the RC oscillated watchdog timer time-out.
T R C W D T = C L K R C ×28 ×[W D T R .6~ 0]+ (C L K R C ×28)/2
w here, C L K R C = 12 0~ 180 uS
In addition, this watchdog timer can be used as a simple 7bit timer by interrupt WDTIF. The interval of watchdog
timer interrupt is decided by Basic Interval Timer. Interval
equation is as below.
TWDT = [WDTR.6~0] × Interval of BIT
Clock Control Register
-
CKCTLR
WAKEUP RCWDT
Watchdog Timer Register
0
BTCL
BTS2
BTS1
BTS0
1
X
X
X
X
X
WDTCL
WDTR
WDTON
ADDRESS : ECH
RESET VALUE : -0010111
Bit Manipulation Not Available
ADDRESS : EDH
RESET VALUE : 01111111
Bit Manipulation Not Available
7-bit Watchdog Counter Register
WAKEUP
RCWDT
STOP
BTS[2:0]
fxin
÷8
÷ 16
÷ 32
÷ 64
÷ 128
÷ 256
÷ 512
÷ 1024
WDTR (8-bit)
3
BTCL
WDTCL
WDTON
Clear
8
MUX
Internal RC OSC
0
1
BITR ( 8-bit )
7-bit Counter
CPU RESET
OFD
1
0
Overflow Detection
BITIF
Basic Interval Timer
Interrupt
Watchdog Timer
Interrupt Request
Figure 20-1 Block Diagram of Watchdog Timer
62
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
21. Power Saving Mode
For applications where power consumption is a critical
factor, device provides three kinds of power saving functions, STOP mode, Wake-up Timer mode and internal RCoscillated watchdog timer mode.
The power saving function is activated by execution of
STOP instruction after setting the corresponding bit
(WAKEUP, RCWDT) of CKCTLR.
Note: Before executing STOP instruction, clear all interrupt request flag. Because if the interrupt request flag is set before STOP instruction, the MCU
runs as if it doesn’t perform STOP instruction, even
though the STOP instruction is completed. So insert
two lines to clear all interrupt request flags (IRQH,
IRQL) before STOP instruction as shown each example.
Table 21-1 shows the status of each Power Saving Mode
Peripheral
STOP
Wake-up Timer
Internal RC-WDT
RAM
Retain
Retain
Retain
Control Registers
Retain
Retain
Retain
I/O Ports
Retain
Retain
Retain
CPU
Stop
Stop
Stop
Timer0
Stop
Operation
Stop
Oscillation
Stop
Oscillation
Stop
Prescaler
Stop
÷ 2048 only
Stop
Internal RC oscillator
Stop
Stop
Oscillation
Entering Condition
CKCTLR[6,5]
00
1X
01
Power Saving Release
Source
RESET, INT0, INT1
RESET, INT0, INT1,
Timer0
RESET, INT0, INT1,
RC-WDT
Table 21-1 Power Saving Mode
21.1 Stop Mode
In the Stop mode, the on-chip oscillator is stopped. With
the clock frozen, all functions are stopped, but the on-chip
RAM and Control registers are held. The port pins out the
values held by their respective port data register, port direction registers. Oscillator stops and the systems internal
operations are all held up.
• The states of the RAM, registers, and latches valid
immediately before the system is put in the STOP
state are all held.
• The program counter stop the address of the
instruction to be executed after the instruction
“STOP” which starts the STOP operating mode.
The Stop mode is activated by execution of STOP instruction after setting the bit WAKEUP and RCWDT
of CKCTLR to “00”. (This register should be written
by byte operation. If this register is set by bit manipulation instruction, for example “set1” or “clr1” instruction, it may be undesired operation)
In the Stop mode of operation, VDD can be reduced to minimize power consumption. Care must be taken, however,
to ensure that VDD is not reduced before the Stop mode is
Jan. 2002 ver 2.0
invoked, and that VDD is restored to its normal operating
level, before the Stop mode is terminated.
The reset should not be activated before VDD is restored to
its normal operating level, and must be held active long
enough to allow the oscillator to restart and stabilize.
Note: After STOP instruction, at least two or more NOP
instruction should be written
Ex)
LDM CKCTLR,#0000_1110B
LDM IRQH,#0
LDM IRQL,#0
STOP
NOP
NOP
In the STOP operation, the dissipation of the power associated with the oscillator and the internal hardware is lowered; however, the power dissipation associated with the
pin interface (depending on the external circuitry and program) is not directly determined by the hardware operation
of the STOP feature. This point should be little current
flows when the input level is stable at the power voltage
63
GMS81C1102 / GMS81C1202
level (VDD/VSS), however, when the input level gets higher than the power voltage level (by approximately 0.3 to
0.5V), a current begins to flow. Therefore, if cutting off the
output transistor at an I/O port puts the pin signal into the
high-impedance state, a current flow across the ports input
transistor, requiring to fix the level by pull-up or other
means.
sinking current, if it is practical. Weak pull-ups on port
pins should be turned off, if possible. All inputs should be
either as VSS or at VDD (or as close to rail as possible).
An intermediate voltage on an input pin causes the input
buffer to draw a significant amount of current.
Release the STOP mode
The exit from STOP mode is hardware reset or external interrupt. Reset re-defines all the Control registers but does
not change the on-chip RAM. External interrupts allow
both on-chip RAM and Control registers to retain their values.
After releasing STOP mode, instruction execution is divided into two ways by I-flag(bit2 of PSW).
If I-flag = 1, the normal interrupt response takes place. If Iflag = 0, the chip will resume execution starting with the
instruction following the STOP instruction. It will not vector to interrupt service routine. (refer to Figure 21-1)
When exit from Stop mode by external interrupt, enough
oscillation stabilization time is required to normal operation. Figure 21-2 shows the timing diagram. When release
the Stop mode, the Basic interval timer is activated on
wake-up. It is increased from 00H until FFH. The count
overflow is set to start normal operation. Therefore, before
STOP instruction, user must be set its relevant prescaler divide ratio to have long enough time (more than 20msec).
This guarantees that oscillator has started and stabilized.
STOP
INSTRUCTION
STOP Mode
Interrupt Request
Corresponding Interrupt
Enable Bit (IENH, IENL)
=0
IEXX
=1
STOP Mode Release
Master Interrupt
Enable Bit PSW[2]
I-FLAG
=0
=1
Interrupt Service Routine
Next
INSTRUCTION
By reset, exit from Stop mode is shown in Figure 21-3.
Minimizing Current Consumption in Stop Mode
Figure 21-1 STOP Releasing Flow by Interrupts
The Stop mode is designed to reduce power consumption.
To minimize the current consumption during Stop mode,
the user should turn-off output drivers that are sourcing or
~
~
~
~
Internal
Clock
~
~
External
Interrupt
~
~
STOP Instruction Execution
Clear Basic Interval Timer
~
~
N-2
N-1
N
N+1
N+2
00
01
FE
FF
00
01
~
~
BIT
Counter
~
~
~
~ ~
~
Oscillator
(XIN pin)
Normal Operation
STOP Mode
Stabilization Time
tST > 20mS
Normal Operation
Figure 21-2 Timing of STOP Mode Release by External Interrupt
64
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
STOP Mode
~
~
~~
~ ~
~
~
Oscillator
(XIN pin)
~
~
~ ~
~
~
Internal
Clock
RESET
~
~
Internal
RESET
~
~
STOP Instruction Execution
Time can not be controlled by software
Stabilization Time
tST = 64mS @4MHz
Figure 21-3 Timing of STOP Mode Release by RESET
21.2 Wake-up Timer Mode
In the Wake-up Timer mode, the on-chip oscillator is not
stopped. Except the Prescaler (only 2048 divided ratio) and
Timer0, all functions are stopped, but the on-chip RAM
and Control registers are held. The port pins out the values
held by their respective port data register, port direction
registers.
In addition, the clock source of timer0 should be selected to 2048 divided ratio. Otherwise, the wake-up function can not work. And the timer0 can be operated as
16-bit timer with timer1 (refer to timer function). The
period of wake-up function is varied by setting the timer data register 0, TDR0.
The Wake-up Timer mode is activated by execution of
STOP instruction after setting the bit WAKEUP of
CKCTLR to “1”. (This register should be written by
byte operation. If this register is set by bit manipulation
instruction, for example “set1” or “clr1” instruction, it
may be undesired operation)
Release the Wake-up Timer mode
Note: After STOP instruction, at least two or more NOP instruction should be written
Ex) LDM TDR0,#0FFH
LDM TM0,#0001_1011B
LDM CKCTLR,#0100_1110B
LDM IRQH,#0
LDM IRQL,#0
STOP
NOP
NOP
If I-flag = 1, the normal interrupt response takes place. If Iflag = 0, the chip will resume execution starting with the
instruction following the STOP instruction. It will not vector to interrupt service routine (refer to Figure 21-1).
The exit from Wake-up Timer mode is hardware reset,
Timer0 overflow or external interrupt. Reset re-defines all
the Control registers but does not change the on-chip
RAM. External interrupts and Timer0 overflow allow both
on-chip RAM and Control registers to retain their values.
When exit from Wake-up Timer mode by external interrupt or timer0 overflow, the oscillation stabilization time is
not required to normal operation. Because this mode do not
stop the on-chip oscillator shown as Figure 21-4.
~
~
~
~ ~
~
Oscillator
(XIN pin)
CPU
Clock
STOP Instruction
Execution
~
~
Interrupt
Request
Normal Operation
Wake-up Timer Mode
(stop the CPU clock)
Normal Operation
Do not need Stabilization Time
Figure 21-4 Wake-up Timer Mode Releasing by External Interrupt or Timer0 Interrupt
Jan. 2002 ver 2.0
65
GMS81C1102 / GMS81C1202
21.3 Internal RC-Oscillated Watchdog Timer Mode
In the Internal RC-Oscillated Watchdog Timer mode, the
on-chip oscillator is stopped. But internal RC oscillation
circuit is oscillated in this mode. The on-chip RAM and
Control registers are held. The port pins out the values held
by their respective port data register, port direction registers.
The Internal RC-Oscillated Watchdog Timer mode is
activated by execution of STOP instruction after setting the bit WAKEUP and RCWDT of CKCTLR to
“01”. (This register should be written by byte operation. If this register is set by bit manipulation instruction, for example “set1” or “clr1” instruction, it may be
undesired operation)
Note: After STOP instruction, at least two or more NOP instruction should be written
Ex)
LDM
LDM
LDM
LDM
STOP
NOP
NOP
WDTR,#1111_1111B
CKCTLR,#0010_1110B
IRQH,#0
IRQL,#0
Release the Internal RC-Oscillated Watchdog Timer mode
The exit from Internal RC-Oscillated Watchdog Timer
mode is hardware reset or external interrupt. Reset re-defines all the Control registers but does not change the on-
chip RAM. External interrupts allow both on-chip RAM
and Control registers to retain their values.
If I-flag = 1, the normal interrupt response takes place. In
this case, if the bit WDTON of CKCTLR is set to “0” and
the bit WDTE of IENH is set to “1”, the device will execute the watchdog timer interrupt service routine.(Figure
21-5) However, if the bit WDTON of CKCTLR is set to
“1”, the device will generate the internal RESET signal
and execute the reset processing. (Figure 21-6)
If I-flag = 0, the chip will resume execution starting with
the instruction following the STOP instruction. It will not
vector to interrupt service routine (refer to Figure 21-1).
When exit from Internal RC-Oscillated Watchdog Timer
mode by external interrupt, the oscillation stabilization
time is required for normal operation. Figure 21-5 shows
the timing diagram. When release the Internal RC-Oscillated Watchdog Timer mode, the basic interval timer is activated on wake-up. It is increased from 00H until FFH. The
count overflow is set to start normal operation. Therefore,
before STOP instruction, user must be set its relevant prescaler divide ratio to have long enough time (more than
20msec). This guarantees that oscillator has started and
stabilized.
By reset, exit from internal RC-Oscillated Watchdog Timer mode is shown in Figure 21-6.
~
~
~
~
~
~
Oscillator
(XIN pin)
Internal
RC Clock
~
~
~
~
Internal
Clock
~
~
External
Interrupt
(or WDT Interrupt)
~
~
STOP Instruction Execution
~
~
N-2
N-1
N
N+1
N+2
00
01
FE
FF
00
00
~
~
BIT
Counter
Clear Basic Interval Timer
Normal Operation
RCWDT Mode
Stabilization Time
tST > 20mS
Normal Operation
Figure 21-5 Internal RCWDT Mode Releasing by External Interrupt or WDT Interrupt
66
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
RCWDT Mode
~
~
~
~
~
~
Oscillator
(XIN pin)
Internal
RC Clock
~
~
~
~
Internal
Clock
~
~
~
~
RESET
RESET by WDT
~
~
Internal
RESET
~
~
STOP Instruction Execution
Time can not be controlled by software
Stabilization Time
tST = 64mS @4MHz
Figure 21-6 Internal RCWDT Mode Releasing by RESET.
INPUT PIN
INPUT PIN
VDD
VDD
VDD
internal
pull-up
VDD
OPEN
i=0
O
i
O
i
Very weak current flows
GND
VDD
X
X
i=0
OPEN
Weak pull-up current flows
GND
O
O
When port is configured as an input, input level should
be closed to 0V or 5V to avoid power consumption.
Figure 21-7 Application Example of Unused Input Port
OUTPUT PIN
OUTPUT PIN
VDD
ON
OPEN
OFF
ON
OFF
ON
O
OFF
i
VDD
GND
X
ON
OFF
L
OFF
ON
i
GND
X
O
VDD
L
i=0
GND
O
In the left case, Tr. base current flows from port to GND.
To avoid power consumption, there should be low output
to the port .
In the left case, much current flows from port to GND.
Figure 21-8 Application Example of Unused output Port
Jan. 2002 ver 2.0
67
GMS81C1102 / GMS81C1202
22. RESET
The reset input is the RESET pin, which is the input to a
Schmitt Trigger. A reset in accomplished by holding the
RESET pin low for at least 8 oscillator periods, while the
oscillator running. After reset, 64ms (at 4 MHz) add with
7 oscillator periods are required to start execution as shown
in Figure 22-1 .
Internal RAM is not affected by reset. When VDD is turned
on, the RAM content is indeterminate. Therefore, this
RAM should be initialized before reading or testing it.
Initial state of each register is shown as Table 12-3 .
1
?
?
4
5
6
7
~
~
?
?
FFFE FFFF Start
~
~ ~
~
?
?
?
?
FE
ADL
ADH
OP
~
~
DATA
BUS
3
~
~
RESET
ADDRESS
BUS
2
~
~
Oscillator
(XIN pin)
MAIN PROGRAM
Stabilization Time
tST = 64mS at 4MHz
RESET Process Step
Figure 22-1 Timing Diagram after RESET
68
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
23. POWER FAIL PROCESSOR
cuit emulator, user can not experiment with it. Therefore,
after final development of user program, this function may
be experimented.
The GMS81C1202 has an on-chip power fail detection circuitry to immunize against power noise. A configuration
register, PFDR, can enable (if clear/programmed) or disable (if set) the Power-fail Detect circuitry. If VDD falls below 3.0~4.0V range for longer than 50 nS, the Power fail
situation may reset MCU according to PFDM bit of PFDR.
Note: Power fail processor function is not available on 3V
operation, because this function will detect power
fail all the time.
As below PFDR register is not implemented on the in-cir-
Power Fail Detector Register
PFDR
-
-
-
-
-
PFDIS
PFDM
ADDRESS : EFH
RESET VALUE : -----100
PFS
Reserved
Power Fail Status
0 : Normal Operate
1 : This bit force to "1" when
Power fail was detected
Operation Mode
0 : System clock freezing during power fail
1 : MCU will be reset during power fail
Disable Flag
0 : Power fail detection enable
1 : Power fail detection disable
Figure 23-1 Power Fail Detector Register
RESET VECTOR
PFS =1
YES
NO
RAM CLEAR
INITIALIZE RAM DATA
Skip the
initial routine
INITIALIZE ALL PORTS
INITIALIZE REGISTERS
FUNTION
EXECUTION
Figure 23-2 Example S/W of RESET by Power fail
Jan. 2002 ver 2.0
69
GMS81C1102 / GMS81C1202
VDD
PFVDDMAX
PFVDDMIN
64mS
Internal
RESET
VDD
When PFDM = 1
Internal
RESET
64mS
t < 64mS
VDD
Internal
RESET
PFVDDMAX
PFVDDMIN
PFVDDMAX
PFVDDMIN
64mS
VDD
PFVDDMAX
PFVDDMIN
System
Clock
When PFDM = 0
VDD
PFVDDMAX
PFVDDMIN
System
Clock
Figure 23-3 Power Fail Processor Situations
70
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
24. OTP PROGRAMMING
The GMS87C1102/1202 is one-time PROM(OTP) microcontroller with 2K bytes electrically programmable read only memory for the GMS81C1102/1202 system evaluation, first production and fast mass production.
To programming the OTP device, user must use the universal programmer which is support Hynix Semiconductor.
24.1 Program Memory MAP
Program Memory consists of configuration area and user program memory area. The configuration memory area has two
parts (User ID & System Configuration Bits), the areas are shown below in Figure 24-1.
The Device Configuration Area can be programmed or left unprogrammed to select device configuration such as security bit.
Ten memory locations (0F50H ~ 0FE0H) are designated as Customer ID recording locations where the user can store checksum or other customer identification numbers.
This area is not accessible during normal execution but is readable and writable during program / verify.
0F50H
ID
0F50H
ID
0F60H
ID
0F70H
ID
0F80H
ID
0F90H
ID
0FA0H
ID
0FB0H
ID
0FC0H
ID
0FD0H
ID
0FE0H
CONFIG
0FF0H
DEVICE
CONFIGURATION
AREA
0FF0H
Configuration Register
CONFIG
-
-
-
-
-
LOCK
-
RC
ADDRESS : 0FF0H
RC Option
0 : Normal Oscillator
1 : External RC Oscillator
SECURITY BIT
0 : Allow Code Read Out
1 : Prohibit Code Read Out
Figure 24-1 Device Configuration Area
The Security Definition Method is explained below.
1) After writing “H” to code protect bit in Write & Verify Mode and getting out of Write & Verify Mode, user cannot read
out the program code. But if not getting out of Write & Verify Mode (maintaining Programming Power VPP = 12.75V), user
can verify Program code.
2) Regardless of Code protect, user can read out configuration Memory (User ID and Configuration Bits)
3) If user knows Security (Lock) state, user can read code protect bit in the System Configuration Bits.
Jan. 2002 ver 2.0
71
GMS81C1102 / GMS81C1202
1
16
A_D3
A_D5
2
15
A_D2
A_D6
3
14
A_D1
A_D7
4
13
A_D0
VDD
5
12
VSS
CTL0
6
11
VPP
CTL1
7
10
CTL2
8
9
GMS87C1102
A_D4
NC
EPROM Enable
Figure 24-2 Pin Assignment
User Mode
EPROM MODE
Pin No.
Pin Name
Pin Name
Description
1
RA4 (AN4)
A_D4
A12
A4
D4
2
RA5 (AN5)
A_D5
A13
A5
D5
3
RA6 (AN6)
A_D6
A14
A6
D6
4
RA7 (AN7)
A_D7
A15
A7
D7
5
VDD
VDD
6
RB0 (AVref/AN0)
CTL0
7
RB2 (INT0)
CTL1
8
RB4 (PWM/COMP)
CTL2
9
XIN
EPROM Enable
High Active, Latch Address in falling edge
10
XOUT
NC
No connection
11
RESET
VPP
Programming Power (0V, 12.75V)
12
VSS
VSS
Connect to VSS (0V)
Address Input
Data Input/Output
Connect to VDD (6.0V)
Read/Write Control
Address/Data Control
13
RA0 (EC0)
A_D0
A8
A0
D0
14
RA1 (AN1)
A_D1
A9
A1
D1
15
RA2 (AN2)
A_D2
A10
A2
D2
16
RA3 (AN3)
A_D3
A11
A3
D3
Address Input
Data Input/Output
Table 24-1 Pin Description in EPROM Mode
72
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
1
20
A_D3
A_D5
2
19
A_D2
A_D6
3
18
A_D1
A_D7
4
17
A_D0
VDD
GMS87C1202
A_D4
5
CTL0
6
CTL1
7
CTL2
16
15
14
VSS
8
13
VPP
9
12
10
11
NC
EPROM Enable
Figure 24-3 Pin Assignment
User Mode
EPROM MODE
Pin No.
Pin Name
Pin Name
Description
1
RA4 (AN4)
A_D4
2
RA5 (AN5)
A_D5
3
RA6 (AN6)
A_D6
4
RA7 (AN7)
A_D7
5
VDD
VDD
6
RB0 (AVref/AN0)
CTL0
7
RB1 (BUZ)
CTL1
8
RB2 (INT0)
CTL2
9
RB3 (INT1)
VDD
Connect to VDD (6.0V)
10
RB4 (PWM/COMP)
VDD
Connect to VDD (6.0V)
11
XIN
EPROM Enable
High Active, Latch Address in falling edge
12
XOUT
NC
No connection
13
RESET
VPP
Programming Power (0V, 12.75V)
14
VSS
VSS
Connect to VSS (0V)
RC0, 1
VDD
Connect to VDD (6.0V)
17
RA0 (EC0)
A_D0
18
RA1 (AN1)
A_D1
19
RA2 (AN2)
A_D2
20
RA3 (AN3)
A_D3
15,16
Address Input
Data Input/Output
A12
A4
D4
A13
A5
D5
A14
A6
D6
A15
A7
D7
A8
A0
D0
Connect to VDD (6.0V)
Read/Write Control
Address/Data Control
Address Input
Data Input/Output
A9
A1
D1
A10
A2
D2
A11
A3
D3
Table 24-2 Pin Description in EPROM Mode
Jan. 2002 ver 2.0
73
GMS81C1102 / GMS81C1202
TSET1
THLD1
TDLY1
THLD2
TDLY2
~
~
VIHP
~
~
TVPPS
~
~
~
~
EPROM
Enable
VPP
TVPPR
TVDDS
VDD1H
TCD1
0V
0V
TCD1
HA
LA
DATA IN
~
~
~
~
~~
DATA
OUT
LA
Verify
Low 8bit
Address
Input
DATA
OUT
DATA IN
~
~
A_D7~
A_D0
~
~
TCD1
TCD1
~
~
VDD1H
CTL2
~
~ ~
~
CTL1
0V
~ ~
~
~
CTL0
VDD1H
VDD
High 8bit
Address
Input
Low 8bit
Address
Input
Write Mode
Write Mode
Verify
Figure 24-4 Timing Diagram in Program (Write & Verify) Mode
After input a high address,
output data following low address input
TSET1
THLD1
TDLY1
THLD2
Anothe high address step
TDLY2
EPROM
Enable
TVPPS
VIHP
VPP
TVDDS
CTL0
0V
TVPPR
VDD2H
CTL1
TCD2
0V
VDD2H
CTL2
0V
A_D7~
A_D0
TCD1
TCD2
TCD1
HA
LA
DATA
LA
DATA
HA
LA
DATA
High 8bit
Address
Input
Low 8bit
Address
Input
DATA
Output
Low 8bit
Address
Input
DATA
Output
High 8bit
Address
Input
Low 8bit
Address
Input
DATA
Output
VDD2H
VDD
Figure 24-5 Timing Diagram in READ Mode
74
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
Parameter
Symbol
MIN
TYP
MAX
Unit
Programming Supply Current
IVPP
-
-
50
mA
Supply Current in EPROM Mode
IVDDP
-
-
20
mA
VPP Level during Programming
VIHP
12.0
12.5
13.0
V
VDD Level in Program Mode
VDD1H
5
6
6.5
V
VDD Level in Read Mode
VDD2H
-
2.7
-
V
CTL2~0 High Level in EPROM Mode
VIHC
0.8VDD
-
-
V
CTL2~0 Low Level in EPROM Mode
VILC
-
-
0.2VDD
V
A_D7~A_D0 High Level in EPROM Mode
VIHAD
0.9VDD
-
-
V
A_D7~A_D0 Low Level in EPROM Mode
VILAD
-
-
0.1VDD
V
VDD Saturation Time
TVDDS
1
-
-
mS
VPP Setup Time
TVPPR
-
-
1
mS
VPP Saturation Time
TVPPS
1
-
-
mS
EPROM Enable Setup Time after Data Input
TSET1
200
nS
EPROM Enable Hold Time after TSET1
THLD1
500
nS
EPROM Enable Delay Time after THLD1
TDLY1
200
nS
EPROM Enable Hold Time in Write Mode
THLD2
100
nS
EPROM Enable Delay Time after THLD2
TDLY2
200
nS
CTL2,1 Setup Time after Low Address input and Data input
TCD1
100
nS
CTL1 Setup Time before Data output in Read and Verify Mode
TCD2
100
nS
Table 24-3 AC/DC Requirements for Program/Read Mode
Jan. 2002 ver 2.0
75
GMS81C1102 / GMS81C1202
START
Set VDD=VDD1H
Report
Programming failure
Set VPP=VIHP
Verify OK
NO
Verify blank
Report
Verify failure
Verify fof all address
NO
YES
YES
Report
Programming OK
First Address Location
Next address location
Report
Programming failure
N=1
VDD=Vpp=0v
NO
END
YES
EPROM Write
100uS program time
N > 25
NO
Verify pass
YES
Apply 3N program cycle
NO
Last address
YES
Figure 24-6 Programming Flow Chart
76
Jan. 2002 ver 2.0
GMS81C1102 / GMS81C1202
START
Set VDD=VDD2H
Verify fof all address
Set VPP=VIHP
First Address Location
Next address location
NO
Last address
YES
Report Read OK
VDD=0V
VPP=0V
END
Figure 24-7 Reading Flow Chart
Jan. 2002 ver 2.0
77
GMS81C1102 / GMS81C1202
78
Jan. 2002 ver 2.0
APPENDIX
GMS81C1102/GMS81C1202
APPENDIX
A. INSTRUCTION MAP
LOW 00000
HIGH
00
00001
01
SET1
dp.bit
00010
02
00011
03
BBS
BBS
A.bit,rel dp.bit,rel
00100
04
00101
05
00110
06
00111
07
01000
08
01001
09
ADC
#imm
ADC
dp
ADC
dp+X
ADC
!abs
ASL
A
ASL
dp
01010
0A
01011
0B
01100
0C
01101
0D
01110
0E
01111
0F
TCALL SETA1
0
.bit
BIT
dp
POP
A
PUSH
A
BRK
000
-
001
CLRC
SBC
#imm
SBC
dp
SBC
dp+X
SBC
!abs
ROL
A
ROL
dp
TCALL CLRA1
2
.bit
COM
dp
POP
X
PUSH
X
BRA
rel
010
CLRG
CMP
#imm
CMP
dp
CMP
dp+X
CMP
!abs
LSR
A
LSR
dp
TCALL
4
NOT1
M.bit
TST
dp
POP
Y
PUSH
Y
PCALL
Upage
011
DI
OR
#imm
OR
dp
OR
dp+X
OR
!abs
ROR
A
ROR
dp
TCALL
6
OR1
OR1B
CMPX
dp
POP
PSW
PUSH
PSW
RET
100
CLRV
AND
#imm
AND
dp
AND
dp+X
AND
!abs
INC
A
INC
dp
TCALL AND1
8
AND1B
CMPY
dp
CBNE
dp+X
TXSP
INC
X
101
SETC
EOR
#imm
EOR
dp
EOR
dp+X
EOR
!abs
DEC
A
DEC
dp
TCALL EOR1
10
EOR1B
DBNE
dp
XMA
dp+X
TSPX
DEC
X
110
SETG
LDA
#imm
LDA
dp
LDA
dp+X
LDA
!abs
TXA
LDY
dp
TCALL
12
LDC
LDCB
LDX
dp
LDX
dp+Y
XCN
DAS
111
EI
LDM
dp,#imm
STA
dp
STA
dp+X
STA
!abs
TAX
STY
dp
TCALL
14
STC
M.bit
STX
dp
STX
dp+Y
XAX
STOP
10011
13
10100
14
10101
15
10110
16
10111
17
11000
18
11001
19
11010
1A
11011
1B
11100
1C
11101
1D
11110
1E
11111
1F
ADC
{X}
ADC
!abs+Y
ADC
[dp+X]
ADC
[dp]+Y
ASL
!abs
ASL
dp+X
TCALL
1
JMP
!abs
BIT
!abs
ADDW
dp
LDX
#imm
JMP
[!abs]
TEST
!abs
SUBW
dp
LDY
#imm
JMP
[dp]
TCLR1 CMPW
!abs
dp
CMPX
#imm
CALL
[dp]
LOW 10000
HIGH
10
10001
11
10010
12
000
BPL
rel
001
BVC
rel
SBC
{X}
SBC
!abs+Y
SBC
[dp+X]
SBC
[dp]+Y
ROL
!abs
ROL
dp+X
TCALL
3
CALL
!abs
010
BCC
rel
CMP
{X}
CMP
!abs+Y
CMP
[dp+X]
CMP
[dp]+Y
LSR
!abs
LSR
dp+X
TCALL
5
MUL
011
BNE
rel
OR
{X}
OR
!abs+Y
OR
[dp+X]
OR
[dp]+Y
ROR
!abs
ROR
dp+X
TCALL
7
DBNE
Y
CMPX
!abs
LDYA
dp
CMPY
#imm
RETI
100
BMI
rel
AND
{X}
AND
!abs+Y
AND
[dp+X]
AND
[dp]+Y
INC
!abs
INC
dp+X
TCALL
9
DIV
CMPY
!abs
INCW
dp
INC
Y
TAY
101
BVS
rel
EOR
{X}
EOR
!abs+Y
EOR
[dp+X]
EOR
[dp]+Y
DEC
!abs
DEC
dp+X
TCALL
11
XMA
{X}
XMA
dp
DECW
dp
DEC
Y
TYA
110
BCS
rel
LDA
{X}
LDA
!abs+Y
LDA
[dp+X]
LDA
[dp]+Y
LDY
!abs
LDY
dp+X
TCALL
13
LDA
{X}+
LDX
!abs
STYA
dp
XAY
DAA
111
BEQ
rel
STA
{X}
STA
!abs+Y
STA
[dp+X]
STA
[dp]+Y
STY
!abs
STY
dp+X
TCALL
15
STA
{X}+
STX
!abs
CBNE
dp
XYX
NOP
CLR1
BBC
BBC
dp.bit
A.bit,rel
dp.bit,rel
Jan. 2002 Ver 2.0
i
GMS81C1102/GMS81C1202
B. INSTRUCTION SET
1. ARITHMETIC/ LOGIC OPERATION
NO.
ii
MNEMONIC
OP BYTE CYCLE
CODE NO
NO
04
2
2
1
ADC #imm
2
ADC dp
05
2
3
3
ADC dp + X
06
2
4
4
ADC !abs
07
3
4
5
ADC !abs + Y
15
3
5
6
ADC [ dp + X ]
16
2
6
7
ADC [ dp ] + Y
17
2
6
8
ADC { X }
14
1
3
9
AND #imm
AND dp
84
2
2
10
85
2
3
11
AND dp + X
86
2
4
12
AND !abs
87
3
4
13
AND !abs + Y
95
3
5
14
AND [ dp + X ]
96
2
6
15
AND [ dp ] + Y
97
2
6
16
AND { X }
94
1
3
17
ASL A
08
1
2
18
19
ASL dp
ASL dp + X
09
19
2
2
4
5
20
ASL !abs
18
3
5
21
CMP #imm
44
2
2
22
CMP dp
45
2
3
23
CMP dp + X
46
2
4
24
CMP !abs
47
3
4
25
CMP !abs + Y
55
3
5
26
CMP [ dp + X ]
56
2
6
27
CMP [ dp ] + Y
57
2
6
28
CMP { X }
54
1
3
29
CMPX #imm
5E
2
2
30
CMPX dp
6C
2
3
31
CMPX !abs
7C
3
4
32
CMPY #imm
7E
2
2
33
CMPY dp
8C
2
3
34
CMPY !abs
9C
3
4
FLAG
NVGBHIZC
OPERATION
Add with carry.
A←(A)+(M)+C
NV--H-ZC
Logical AND
A← (A)∧(M)
N-----Z-
Arithmetic shift left
C
7
6
5
4
3
2
1
N-----ZC
0
“0”
Compare accumulator contents with memory contents
(A) -(M)
N-----ZC
Compare X contents with memory contents
(X)-(M)
N-----ZC
Compare Y contents with memory contents
(Y)-(M)
N-----ZC
35
COM dp
2C
2
4
1’S Complement : ( dp ) ← ~( dp )
N-----Z-
36
DAA
DF
1
3
Decimal adjust for addition
N-----ZC
37
DAS
CF
1
3
Decimal adjust for subtraction
N-----ZC
38
DEC A
A8
1
2
Decrement
N-----Z-
39
DEC dp
A9
2
4
40
DEC dp + X
B9
2
5
41
DEC !abs
B8
3
5
42
DEC X
AF
1
2
43
DEC Y
BE
1
2
44
DIV
9B
1
12
M← (M)-1
N-----Z-
Divide : YA / X Q: A, R: Y
NV--H-Z-
Jan. 2002 Ver 2.0
GMS81C1102/GMS81C1202
NO.
MNEMONIC
OP BYTE CYCLE
OPERATION
CODE NO
NO
A4
2
2
Exclusive OR
A5
2
3
A← (A)⊕(M)
45
EOR #imm
46
EOR dp
47
EOR dp + X
A6
2
4
48
EOR !abs
A7
3
4
49
EOR !abs + Y
B5
3
5
50
EOR [ dp + X ]
B6
2
6
51
EOR [ dp ] + Y
B7
2
6
52
EOR { X }
B4
1
3
N-----Z-
53
INC A
88
1
2
54
INC dp
89
2
4
55
INC dp + X
99
2
5
56
INC !abs
98
3
5
57
INC X
8F
1
2
58
INC Y
9E
1
2
59
LSR A
48
1
2
60
LSR dp
49
2
4
61
LSR dp + X
59
2
5
62
LSR !abs
58
3
5
63
MUL
5B
1
9
Multiply : YA ← Y × A
64
OR #imm
64
2
2
Logical OR
65
OR dp
65
2
3
66
OR dp + X
66
2
4
67
OR !abs
67
3
4
68
OR !abs + Y
75
3
5
69
OR [ dp + X ]
76
2
6
70
OR [ dp ] + Y
77
2
6
71
OR { X }
74
1
3
72
ROL A
28
1
2
73
ROL dp
29
2
4
74
ROL dp + X
39
2
5
75
ROL !abs
38
3
5
76
ROR A
68
1
2
77
ROR dp
69
2
4
78
ROR dp + X
79
2
5
79
ROR !abs
78
3
5
FLAG
NVGBHIZC
Increment
N-----Z-
M← (M)+1
N-----Z-
Logical shift right
7
6
5
4
3
2
1
0
C
N-----ZC
“0”
N-----Z-
A ← (A)∨(M)
N-----Z-
Rotate left through carry
C
7
6
5
4
3
2
1
0
N-----ZC
Rotate right through carry
7
6
5
4
3
2
1
0
C
N-----ZC
80
SBC #imm
24
2
2
81
SBC dp
25
2
3
82
SBC dp + X
26
2
4
83
SBC !abs
27
3
4
84
SBC !abs + Y
35
3
5
85
SBC [ dp + X ]
36
2
6
86
SBC [ dp ] + Y
37
2
6
87
SBC { X }
34
1
3
88
TST dp
4C
2
3
Test memory contents for negative or zero
( dp ) - 00H
N-----Z-
89
XCN
CE
1
5
Exchange nibbles within the accumulator
A7~A4 ↔ A3~A0
N-----Z-
Jan. 2002 Ver 2.0
Subtract with carry
A ← ( A ) - ( M ) - ~( C )
NV--HZC
iii
GMS81C1102/GMS81C1202
2. REGISTER / MEMORY OPERATION
NO.
iv
MNEMONIC
OP
BYTE CYCLE
CODE NO
NO
C4
2
2
1
LDA #imm
2
LDA dp
C5
2
3
3
LDA dp + X
C6
2
4
4
LDA !abs
C7
3
4
5
LDA !abs + Y
D5
3
5
6
LDA [ dp + X ]
D6
2
6
7
LDA [ dp ] + Y
D7
2
6
8
LDA { X }
D4
1
3
Load accumulator
A←(M)
N-----Z-
9
LDA { X }+
DB
1
4
X- register auto-increment : A ← ( M ) , X ← X + 1
10
LDM dp,#imm
E4
3
5
Load memory with immediate data : ( M ) ← imm
11
LDX #imm
1E
2
2
Load X-register
12
LDX dp
CC
2
3
13
LDX dp + Y
CD
2
4
14
LDX !abs
DC
3
4
15
LDY #imm
3E
2
2
16
LDY dp
C9
2
3
17
LDY dp + X
D9
2
4
18
LDY !abs
D8
3
4
19
STA dp
E5
2
4
20
STA dp + X
E6
2
5
21
STA !abs
E7
3
5
22
STA !abs + Y
F5
3
6
23
STA [ dp + X ]
F6
2
7
24
STA [ dp ] + Y
F7
2
7
25
STA { X }
F4
1
4
FLAG
NVGBHIZC
OPERATION
--------
X ←(M)
N-----Z-
Load Y-register
Y←(M)
N-----Z-
Store accumulator contents in memory
(M)←A
--------
26
STA { X }+
FB
1
4
X- register auto-increment : ( M ) ← A, X ← X + 1
27
STX dp
EC
2
4
Store X-register contents in memory
28
STX dp + Y
ED
2
5
29
STX !abs
FC
3
5
30
STY dp
E9
2
4
31
STY dp + X
F9
2
5
32
STY !abs
F8
3
5
33
TAX
E8
1
2
Transfer accumulator contents to X-register : X ← A
34
TAY
9F
1
2
Transfer accumulator contents to Y-register : Y ← A
N-----Z-
35
TSPX
AE
1
2
Transfer stack-pointer contents to X-register : X ← sp
N-----Z-
(M)← X
--------
Store Y-register contents in memory
(M)← Y
-------N-----Z-
36
TXA
C8
1
2
Transfer X-register contents to accumulator: A ← X
N-----Z-
37
TXSP
8E
1
2
Transfer X-register contents to stack-pointer: sp ← X
N-----Z-
38
TYA
BF
1
2
Transfer Y-register contents to accumulator: A ← Y
N-----Z-
39
XAX
EE
1
4
Exchange X-register contents with accumulator :X ↔ A --------
40
XAY
DE
1
4
Exchange Y-register contents with accumulator :Y ↔ A --------
41
XMA dp
BC
2
5
Exchange memory contents with accumulator
42
XMA dp+X
AD
2
6
43
XMA {X}
BB
1
5
44
XYX
FE
1
4
(M)↔A
N-----Z-
Exchange X-register contents with Y-register : X ↔ Y
--------
Jan. 2002 Ver 2.0
GMS81C1102/GMS81C1202
3. 16-BIT OPERATION
NO.
MNEMONIC
OP BYTE CYCLE
CODE NO
NO
OPERATION
FLAG
NVGBHIZC
1
ADDW dp
1D
2
5
16-Bits add without carry
YA ← ( YA ) + ( dp +1 ) ( dp )
NV--H-ZC
2
CMPW dp
5D
2
4
Compare YA contents with memory pair contents :
(YA) − (dp+1)(dp)
N-----ZC
3
DECW dp
BD
2
6
Decrement memory pair
( dp+1)( dp) ← ( dp+1) ( dp) - 1
N-----Z-
4
INCW dp
9D
2
6
Increment memory pair
( dp+1) ( dp) ← ( dp+1) ( dp ) + 1
N-----Z-
5
LDYA dp
7D
2
5
Load YA
YA ← ( dp +1 ) ( dp )
N-----Z-
6
STYA dp
DD
2
5
Store YA
( dp +1 ) ( dp ) ← YA
--------
7
SUBW dp
3D
2
5
16-Bits substact without carry
YA ← ( YA ) - ( dp +1) ( dp)
NV--H-ZC
4. BIT MANIPULATION
NO.
MNEMONIC
OP BYTE CYCLE
OPERATION
CODE NO
NO
8B
3
4
Bit AND C-flag : C ← ( C ) ∧ ( M .bit )
FLAG
NVGBHIZC
-------C
1
AND1 M.bit
2
AND1B M.bit
8B
3
4
Bit AND C-flag and NOT : C ← ( C ) ∧ ~( M .bit )
-------C
3
BIT dp
0C
2
4
Bit test A with memory :
MM----Z-
4
BIT !abs
1C
3
5
Z ← ( A ) ∧ ( M ) , N ← ( M7 ) , V ← ( M6 )
5
CLR1 dp.bit
y1
2
4
Clear bit : ( M.bit ) ← “0”
--------
6
CLRA1 A.bit
2B
2
2
Clear A bit : ( A.bit )← “0”
--------
7
CLRC
20
1
2
Clear C-flag : C ← “0”
-------0
8
CLRG
40
1
2
Clear G-flag : G ← “0”
--0-----
9
-0--0---
CLRV
80
1
2
Clear V-flag : V ← “0”
10
EOR1 M.bit
AB
3
5
Bit exclusive-OR C-flag : C ← ( C ) ⊕ ( M .bit )
11
EOR1B M.bit
AB
3
5
4
-------C
Bit exclusive-OR C-flag and NOT : C ← ( C ) ⊕ ~(M .bit) -------C
Load C-flag : C ← ( M .bit )
-------C
12
LDC M.bit
CB
3
13
LDCB M.bit
CB
3
4
Load C-flag with NOT : C ← ~( M .bit )
-------C
14
NOT1 M.bit
4B
3
5
Bit complement : ( M .bit ) ← ~( M .bit )
--------
15
OR1 M.bit
6B
3
5
Bit OR C-flag : C ← ( C ) ∨ ( M .bit )
-------C
16
OR1B M.bit
6B
3
5
Bit OR C-flag and NOT : C ← ( C ) ∨ ~( M .bit )
-------C
17
SET1 dp.bit
x1
2
4
Set bit : ( M.bit ) ← “1”
--------
18
SETA1 A.bit
0B
2
2
Set A bit : ( A.bit ) ← “1”
--------
19
SETC
A0
1
2
Set C-flag : C ← “1”
-------1
20
SETG
C0
1
2
Set G-flag : G ← “1”
--1-----
21
STC M.bit
EB
3
6
Store C-flag : ( M .bit ) ← C
-------N-----ZN-----Z-
22
TCLR1 !abs
5C
3
6
Test and clear bits with A :
A - ( M ) , ( M ) ← ( M ) ∧ ~( A )
23
TSET1 !abs
3C
3
6
Test and set bits with A :
A-(M), (M)← (M)∨(A)
Jan. 2002 Ver 2.0
v
GMS81C1102/GMS81C1202
5. BRANCH / JUMP OPERATION
NO.
vi
MNEMONIC
1
BBC A.bit,rel
2
BBC dp.bit,rel
OP BYTE CYCLE
OPERATION
CODE NO
NO
y2
2
4/6
Branch if bit clear :
y3
3
5/7
if ( bit ) = 0 , then pc ← ( pc ) + rel
FLAG
NVGBHIZC
--------
3
BBS A.bit,rel
x2
2
4/6
Branch if bit set :
4
BBS dp.bit,rel
x3
3
5/7
if ( bit ) = 1 , then pc ← ( pc ) + rel
5
BCC rel
50
2
2/4
Branch if carry bit clear
if ( C ) = 0 , then pc ← ( pc ) + rel
--------
6
BCS rel
D0
2
2/4
Branch if carry bit set
if ( C ) = 1 , then pc ← ( pc ) + rel
--------
7
BEQ rel
F0
2
2/4
Branch if equal
if ( Z ) = 1 , then pc ← ( pc ) + rel
--------
8
BMI rel
90
2
2/4
Branch if minus
if ( N ) = 1 , then pc ← ( pc ) + rel
--------
9
BNE rel
70
2
2/4
Branch if not equal
if ( Z ) = 0 , then pc ← ( pc ) + rel
--------
10
BPL rel
10
2
2/4
Branch if minus
if ( N ) = 0 , then pc ← ( pc ) + rel
--------
11
BRA rel
2F
2
4
Branch always
pc ← ( pc ) + rel
--------
12
BVC rel
30
2
2/4
Branch if overflow bit clear
if (V) = 0 , then pc ← ( pc) + rel
--------
13
BVS rel
B0
2
2/4
Branch if overflow bit set
if (V) = 1 , then pc ← ( pc ) + rel
--------
14
CALL !abs
3B
3
8
Subroutine call
M( sp)←( pcH ), sp←sp - 1, M(sp)← (pcL), sp ←sp - 1,
-------if !abs, pc← abs ; if [dp], pc L← ( dp ), pcH← ( dp+1 ) .
15
CALL [dp]
5F
2
8
16
--------
CBNE dp,rel
FD
3
5/7
17
CBNE dp+X,rel
8D
3
6/8
18
DBNE dp,rel
AC
3
5/7
Decrement and branch if not equal :
19
DBNE Y,rel
7B
2
4/6
if ( M ) ≠ 0 , then pc ← ( pc ) + rel.
20
JMP !abs
1B
3
3
21
JMP [!abs]
1F
3
5
22
JMP [dp]
3F
2
4
23
PCALL upage
4F
2
6
U-page call
M(sp) ←( pcH ), sp ←sp - 1, M(sp) ← ( pcL ),
sp ← sp - 1, pcL ← ( upage ), pcH ← ”0FFH” .
--------
24
TCALL n
nA
1
8
Table call : (sp) ←( pcH ), sp ← sp - 1,
M(sp) ← ( pcL ),sp ← sp - 1,
pcL ← (Table vector L), pcH ← (Table vector H)
--------
Compare and branch if not equal :
--------
if ( A ) ≠ ( M ) , then pc ← ( pc ) + rel.
--------
Unconditional jump
pc ← jump address
--------
Jan. 2002 Ver 2.0
GMS81C1102/GMS81C1202
6. CONTROL OPERATION & etc.
NO.
MNEMONIC
OP BYTE CYCLE
CODE NO
NO
OPERATION
FLAG
NVGBHIZC
0F
1
8
Software interrupt : B ← ”1”, M(sp) ← (pcH), sp ←sp-1,
M(s) ← (pcL), sp ← sp - 1, M(sp) ← (PSW), sp ← sp -1, ---1-0-pcL ← ( 0FFDEH ) , pcH ← ( 0FFDFH) .
DI
60
1
3
Disable interrupts : I ← “0”
-----0--
EI
E0
1
3
Enable interrupts : I ← “1”
-----1---------
1
BRK
2
3
4
NOP
FF
1
2
No operation
5
POP A
0D
1
4
sp ← sp + 1, A ← M( sp )
6
POP X
2D
1
4
sp ← sp + 1, X ← M( sp )
7
POP Y
4D
1
4
sp ← sp + 1, Y ← M( sp )
8
sp ← sp + 1, PSW ← M( sp )
POP PSW
6D
1
4
9
PUSH A
0E
1
4
M( sp ) ← A , sp ← sp - 1
10
PUSH X
2E
1
4
M( sp ) ← X , sp ← sp - 1
11
PUSH Y
4E
1
4
M( sp ) ← Y , sp ← sp - 1
12
PUSH PSW
6E
1
4
M( sp ) ← PSW , sp ← sp - 1
-------restored
--------
13
RET
6F
1
5
Return from subroutine
-------sp ← sp +1, pcL ← M( sp ), sp ← sp +1, pcH ← M( sp )
14
RETI
7F
1
6
Return from interrupt
sp ← sp +1, PSW ← M( sp ), sp ← sp + 1,
pcL ← M( sp ), sp ← sp + 1, pcH ← M( sp )
restored
15
STOP
EF
1
3
Stop mode ( halt CPU, stop oscillator )
--------
Jan. 2002 Ver 2.0
vii
Similar pages