SILAN SC73P1601MCTR

SC73P1601
4-BIT MCU FOR REMOTE CONTROLLER(OTP TYPE)
DESCRIPTION
SC73P1601 is one of Silan’
s 4-bit CMOS single-chip microcontrollers for infrared remote control transmitters (IRCTs). It can be
implemented in various IRCTs circuits by OTP program. And it is
compatible with SC73C1602 on software and package.
SOP-20-300-1.27 SOP-20-375-1.27
FEATURES
* Wide operating voltage (2.0~4.0V), and low static power
consumption (<1µA)
* OTP: 1K x 9 bits
SSOP-20-300-0.65 SSOP-20-225-0.65
* RAM: 16 x 4bits
* Timer/counter: (10~15 bits)
* 8-bit timer, generates various carrier frequencies and outputs
carrier duty
* 16 I/O pins, four 4-bit programmable I/O ports (except P50 and
APPLICATIONS
P53)
* Oscillator frequency (fosc): fosc=4MHz(TYP.)
* Infrared remote control device
* Operating frequency: fmain=fosc/8
* TV controller
* Instruction cycle: 5/fmain
* Video Cassette Recorder controller
* Support low voltage detection
* VTR, laser phonograph and acoustics
remote controller
ORDERING FORMATION
Material
Package Type
SC73P1601M
Part No.
SSOP-20-300-0.65
Package
SC73P1601M
Marking
Pb free
Tube
SC73P1601MTR
SSOP-20-300-0.65
SC73P1601M
Pb free
Tape & Reel
SC73P1601MA
SOP-20-300-1.27
SC73P1601MA
Pb free
Tube
SC73P1601MATR
SOP-20-300-1.27
SC73P1601MA
Pb free
Tape & Reel
SC73P1601MC
SSOP-20-225-0.65
SC73P1601MC
Pb free
Tube
SC73P1601MCTR
SSOP-20-225-0.65
SC73P1601MC
Pb free
Tape & Reel
SC73P1601MD
SOP-20-375-1.27
SC73P1601MD
Pb free
Tube
SC73P1601MDTR
SOP-20-375-1.27
SC73P1601MD
Pb free
Tape & Reel
SC73P1601MG
SSOP-20-300-0.65
SC73P1601MG
Halogen free
Tube
SC73P1601MGTR
SSOP-20-300-0.65
SC73P1601MG
Halogen free
Tape & Reel
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SC73P1601
Part No.
Package
Marking
Material
Package Type
SC73P1601MAG
SOP-20-300-1.27
SC73P1601MAG
Halogen free
Tube
SC73P1601MAGTR
SOP-20-300-1.27
SC73P1601MAG
Halogen free
Tape & Reel
SC73P1601MCG
SSOP-20-225-0.65
SC73P1601MCG
Halogen free
Tube
SC73P1601MCGTR
SSOP-20-225-0.65
SC73P1601MCG
Halogen free
Tape & Reel
SC73P1601MDG
SOP-20-375-1.27
SC73P1601MDG
Halogen free
Tube
SC73P1601MDGTR
SOP-20-375-1.27
SC73P1601MDG
Halogen free
Tape & Reel
BLOCK DIAGRAM
ABSOLUTE MAXIMUM RATINGS (Otherwise specified, Tamb=25°C)
Characteristics
Symbol
Rating
Unit
Supply Voltage
VDD
-0.3 ~ +5.0
V
Input Voltage
VIN
-0.3~VDD+0.3
V
IOUT (P53)
-9
mA
Power Dissipation
PD
500
mW
Storage Temperature
Tstg
-40~+125
°C
Operating Temperature
Topr
-20~+75
°C
Output Current
ELECTRICAL CHARACTERISTICS (Tamb=25°C, VDD=3.0V)
Characteristics
Symbol
Test Conditions
Min.
Typ.
Max.
Unit
--
4
V
1.6
V
Power Supply
VDD
In all the functions
2
Power Reset
VPOC
In all the functions
1.4
IDD
In operating mode
--
--
1.0
mA
FOSC
In operating mode
2M
4M
6M
Hz
Operating Current
Oscillation Frequency
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SC73P1601
Characteristics
Symbol
Quiescent Current
IDS
Test Conditions
Oscillator stops
P50
Min.
Typ.
Max.
Unit
--
--
1
µA
50
60
70
KΩ
60
75
90
KΩ
P00-P03
Input Pull-Down Resistor
R
VDD=3V
P10-P13
P20-P23
P51-P52
Input High Level Voltage
VIH
--
0.7VDD
--
VDD
V
Input Low Level Voltage
VIL
--
0
--
0.3VDD
V
--
-9.0
--
--
-0.8
--
--
10.8
--
--
--
0.17
P53
Output High Level Current
IOH
VDD=3V
VOH=2.7V
P00-P03
P10-P13
P20-P23
mA
P51-P52
P53
Output Low Level Current
IOL
VDD=3V
VOL=0.3V
P00-P03
P10-P13
P20-P23
mA
P51-P52
PIN CONFIGURATIONS
1.Normal working mode
2.EPROM programming mode
SC73P1601M/MA/MC/MD
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SC73P1601
PIN DESCRIPTIONS
Normal mode
Symbol
Description
VDD
Power Supply (2.0V~4.0V)
GND
Ground
XT1
Oscillator output pin
XT2
Oscillator input pin
4-bit I/O pin.
P00~P03
In input mode, it is used as the keyboard-scan input port (with internal pull-down resistor).
In output mode, it is used as the keyboard-scan output port.
4-bit I/O pin.
P10~P13
In input mode, it is used as the keyboard-scan input port (with internal pull-down resistor).
In output mode, it is used as the keyboard-scan output port.
4-bit I/O pin.
P20~P23
In input mode, it is used as the keyboard-scan input port (with internal pull-down resistor).
In output mode, it is used as the keyboard-scan output port.
P50
1-bit input pin with pull-down resistor, used for keyboard-scan input.
1-bit I/O pin.
P51
In input mode, it is used as the keyboard-scan input port (with internal pull-down resistor).
In output mode, it is used as the keyboard-scan output port.
1-bit I/O pin.
P52
In input mode, it is used as the keyboard-scan input port (with internal pull-down resistor).
In output mode, it is used as the keyboard-scan output port,
P53
Outputs remote control signal with carrier or without carrier.
Programming mode:
Symbol
Description
D0-D8
9-bit data when EPROM write in/ verify
Otp_clk
Address increment clock when EPROM write in/ verify
Ceb
EPROM program enable, and high active
Oeb
EPROM output enable, and high active
Progb
EPROM program enable, and high active
VDD
Power supply of +6.5 V
GND
Ground
Vpp
In program mode, provide 12.5V to this pin
Otp_res
Clear eprom address pointer, and high active
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SC73P1601
Program time sequence:
Performance Characteristics
Symbol
Condition
Min.
Typ.
Max.
Unit
Setup time of “Oeb”
tOES
1
-
-
s
Setup time of “Ceb”
tCS
1
-
-
s
Setup time of “D[8:0]”
tDS
1
-
-
s
Hold time of “Ceb”
tCH
1
-
-
s
Hold time of “D[8:0]”
tDH
1
-
-
s
Setup time of “VPP”
tVPS
1
-
-
s
Setup time of “VDD”
tVDS
1
-
-
s
Pulse width of “Progb”
tPW
200
300
-
s
FUNCTION DESCRIPTION
SC73P1601 includes 4-bit MCU, outlay oscillator, system reset module. Next we will mainly introduce the
functions.
1. PC
PC refers to the program address pointer, 10 bits. The maximum addressing space is 1K ROM .The program
counter contains the address of the instruction that will be executed next. The PC value is cleared to 0 after reset.
The PC is set to predefined value when one of the 3 following occasions occurs: 1) when the JUMP instruction is
executed; 2) when a subroutine call is back; 3) when a program call is back. In the SC73P1601, all instructions
are one-byte instructions, PC increments by 1 each time an instruction is executed.
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SC73P1601
2. MBR
Memory buffer register (MBR) is write-only, higher 4-bit of the program pointer. The EPROM of SC73P1601
can be divided into 8 blocks. Each block is 128 bytes. The 8 blocks can be addressed by the MBR. When the
program starts executing a branch instruction, it must load the corresponding value to the MBR register, and then
executes the command BSS label.
3. STACK
Stack register stores the previous value of program pointer during execution of subroutine calls, 11 bits. There
is two-level hardware stack register, so two-level programs can be called. When the user tries to make more than
two-level program call, an error will occur.
4. B, H, D
Referred to as the pointer to data table. BHD are separately 2 bits, 4 bits and 4 bits. The 1K EPROM space of
SC73P1601 can be used as the data table which can be diplex with program space. When addressing the fixed
data of EPROM, the registers act as the pointers to the data table (to form the EPROM address according to
BHD order). In other cases, the H, D registers can be used as general purpose registers. Fixed data stored in the
data table can be addressed by the transmit instructions. When executing the transmit-instructions, the program
will look for the data from the correspond space of EPROM. The low 10 bits address of the EPROM are
composed of two lower bits of B , four bits of H and four bits of D.
When the most significant bit is 1, P53 transmits the data with carrier; while the most significant bit is 0, P53
transmits the data without carrier. The second bit of B is of no real use, and it is set 0 by the software at program
imitation.
5. PROM
Address
1k x 9bits
000H
001H
002H
Subroutine call start address
01FH
020H
Normal program Area
(can be duplex as data table)
3FFH
6. CH0、CH1、CL0、CL1
CH0, CH1, CL0, CL1 are carrier high and low level control registers, which can control the high-low level of
carrier is (CH+1)/fosc and(CL+1)/fosc.
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SC73P1601
7. LL, LH
LL register, 4 bits, LH register, bit. LL[3:0] is the address pointer of RAM, and is used as the general-purpose
register at the same time.
LH register, 4 bits, used as the general-purpose register.
8. RAM
Data memory consists of 16x4 bits and is used to store temporary data and results after a program is executed.
It can address the entire RAM areas by the pointer LL[3:0]. When reset, the contents of RAM are not defined.
We recommend users to initialize it at the beginning of their software program.
9. ALU
The arithmetic and logic unit plays a leading role in performing various operations of 4-bit binaries. The
operation of ALU will change the carry flag (CF) and the zero flag(ZF).
10. Acc
4-bit accumulator, which is in the ALU. It is mostly used to store data and results.
11. CF
Carry flag.
12. SF
Status flag bit, the value of SF is 1 after reset.
13. PR (PR, PR2)
The port mode register, which specifies the input mode or output mode of the I/O port, is 4-bit write-only. When
the value is 1, the corresponding port is set to output mode. PR=0, it is set to input mode. The execution of the
HOLD instruction won’
t affect the I/O modes of operation. When reset, the initialization value is 0000B, and the
port is in input mode.
--
PR2.2
PR2.1
PR2.0
P50 mode select
P51 mode select
P52 mode select
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SC73P1601
14. PORT
SC73P1601 has 4 groups of I/O ports, totally 20 pins. Each group can operate in both input and output mode
(except P50 and P53, P50 is only input port, P53 is only output port). Details are as follows:
P0 port: P00-P03, 4-bit input/output port. The PR determines the port operation mode. In input mode, it has an
internal pull-down resistor and can be used for keyboard scan input. When the input level is high, it
can release the HOLD mode. In output mode, it can be used for keyboard scan output.
P1 port: P10-P13, same as P0 port;
P2 port: P20-P23, same as P0 port;
P5 port: P50-P53
P50: only as input pin with pull-down resistor used for keyboard scan input. When input high level, the
HOLD state is unlocked.
P51: the configuration same as P00;
P52: the configuration same as P00;
P53: large current output port, this pin is used to output infrared remote signal. If P53 is set to 1, this
pin outputs modulated signal with carrier or high level signal. If it is set to 0, it outputs low level
voltage.
15. Timer/counter
SC73P1601 has two internal timers:
One is a 17-bit timer. The clock source of the timer is main frequency (fmain) of the circuit. There are timing
steps from 10 (which generates pulses with frequency fmain/210) to 15 (fmain/215). The timer can output pulse
frequency ranging from fmain/210 to fmain/215, and can be used for timer after releasing the HOLD mode. It can
also be used as a WDT. After the HOLD mode released and the timer reset instruction TMRST executed, the
timer value is cleared.
The other timer is a carrier generator. Setting different length of high and low level time span respectively
through programming, it generates various different duty and frequency carriers.
16. TR
Timer register, it selects the status of the timer mode, use the instruction LD TM, A to write the data.
SC73P1601 uses the instruction LD A, TM or LD @LR, TM to read the status of timer; TM to read the timing
value. For example:
3
IBNS
2
1
0
TIBS
TR timer register
17. IBNS
The control bit of the read timer. When the value is 0, it reads TM3 (IT3), and IT2~IT0 become 0. When the value
is 1, it reads 4-bit data TM3~TM0(IT3~IT0).
TM3: 215/fmain
TM2: 214/fmain
TM1: 213/fmain
TM0: 212/fmain
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SC73P1601
Example: when the crystal oscillator select 455KHz, the corresponding time of port P50 is 212÷455≈9ms. This
means the time from TM=1111B to 1101 is 9ms, and the time from TM=1111B to 1110 is 4.5ms.See the following
program:
LD
A#1000B
LD
TM,A
TMRST
……
LOOP:
LD
L,#TEMP
LD
@LL,#1110B
LD
A,TM
XOR
A,@LL
JMPS
LOOP
END
In above program, the time from TMRST start to END is 4.5ms, that it from TM=1111B to 1110B is 4.5ms..
Time change :
4.5ms 9ms
9ms 9ms
18ms
18ms
36ms
36ms
The maximum adjustable time of the timer is 216/fmain. When the timer acts as a WDT and the timer is activated,
it must execute the TMRST instruction and clear the timer in 2 16/fmain’
s time, otherwise, it will lead the WDT to
overflow, and causes the MCU to reset.
18. POC Circuit
The POC circuit monitors the power supply voltage and applies an internal reset to the micro-controller.
The POC circuit has the following functions:
•Generates an internal reset signal when VDD< VPOC. (Note 1)
•Cancels an internal reset signal when VDD > VPOC.
Here, VDD: power supply voltage. VPOC: POC detection voltage.
VDD
3.6V
Operating ambient temperature Tamb=-20°C~+75°C
2.0V
VPOC
POC detection voltage VPOC =1.4V~1.6V
0V
Internal reset signal
Reset
Operation mode
Note 1
Note 2
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SC73P1601
Notes. 1. After the circuit is power on, there is a short oscillation stabilization wait time before the circuit is in
operation mode. The oscillation stabilization wait time is about 216/fmain.
2. The POC circuit generates an internal reset signal when the power supply voltage has fallen to a
certain value in working mode.
19. Instruction Cycle
Instructions and internal operations are executed in synchronization with the main clock. The minimum time of
carrying out a complete instruction is called the instruction cycle. SC73P1601 has 1 and 2-cycle two kind of
instructions.
An instruction cycle consists of 5 states (STCLK1 to STCLK5). Each state consists of 1 main clock. Therefore,
the instruction cycle time is 5/fmain [s].
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SC73P1601
INSTRUCTION SETS
1. Transmit instruction
Instruction
Operation
CF
SF
Cycle
LD A, LL
A ← LL
---
1
2
LD A, B
A←B
---
1
2
LD A, H
A←H
---
1
2
LD A, D
A←D
---
1
2
LD A, @LL
A ← RAM(LL)
---
1
1
LD A, #k
A←k
---
1
1
LD CL1, A
CL1 ← A
---
1
2
LD CL0, A
CL0 ← A
---
1
2
LD CH1, A
CH1 ← A
---
1
2
LD CH0, A
CH0 ← A
---
1
2
LDH A, @BD
A ← ROM(BD)7-4
---
1
2
LDL A, @BD
A ← ROM(BD)3-0
---
1
2
LDS A, @BD
A ← ROM(BD)8
---
1
2
LDH @LL, @BD
RAM(LL) ← ROM(BD)7-4
---
1
2
LDL @LL, @BD
RAM(LL) ← ROM(BD)3-0
---
1
2
LDS @LL, @BD
RAM(LL) ← ROM(BD)8
---
1
2
LD LL, A
LL ← A
---
1
2
LD LL, #k
LL ← k
---
1
1
LD @LL, A
RAM(LL) ← A
---
1
1
LD @LL, #k
RAM(LL) ← k
---
1
1
LD D, A
D←A
---
1
2
LD H, A
H←A
---
1
2
LD B, A
B←A
---
1
2
LD PR, A
PR ← A
---
1
2
LD PR2, A
PR2 ← A
---
1
2
LD TM, A
TM ← A
---
1
2
A ← TM
---
1
2
LD A, TM
1
LD A, LL
Load values in the LL register to the accumulator.
2
LD A, D
Load values in the D register to the accumulator.
3
LD A, H
Load values in the H register to the accumulator.
4
LD A, B
Load values in the B register to the accumulator.
5
LD A, @LL
Load the contents of RAM pointed at by the LL ( LL & LH) register to accumulator.
6
LD A, #k
Load the 4 bit immediate K to accumulator.
7
LDL A, @BD
Load the lower 4 bit of ROM data pointed at by the BHD to accumulator.
8
LDH A, @BD
Load the higher 4 bit of ROM data pointed at by the BHD to accumulator.
9
LDS A, @BD
Load the highest 1 bit of ROM data pointed at by the BHD to accumulator
10
LDL @LL, @BD
Load the lower 4 bit of ROM data pointed at by the BHD to RAM pointed at by the
LL register.
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SC73P1601
11
LDH @LL, @BD
Load the higher 4 bit of ROM data pointed at by the BHD to RAM pointed at by the
LL register.
12
LDS @LL, @BD
Load the highest 1 bit of ROM data pointed at by the BHD to RAM pointed at by the
LL register.
13
LD LL, A
Load the contents of the accumulator to the LL register.
14
LD LH, A
Load the contents of the accumulator to the LH register.
15
LD LL,#K
Load immediate K to the LL register.
16
LD @LL, A
Load the content of the accumulator to the RAM pointed at by the LL register.
17
LD @LL, #k
Load the immediate K to RAM pointed at by the LL register.
18
LD D, A
Load the content of the accumulator to the D register.
19
LD H, A
Load the content of the accumulator to the H register.
20
LD B, A
Load the content of the accumulator to the B register.
21
LD CL1, A
Load the content of the accumulator to the CL1 register.
22
LD CL0, A
Load the content of the accumulator to the CL0 register.
23
LD CH1, A
Load the content of the accumulator to the CH1 register.
24
LD CH0, A
Load the content of the accumulator to the CH0 register.
25
LD PR, A
Load the content of the accumulator to the port register(PR).
26
LD PR2, A
Load the content of the accumulator to the port register(PR2).
27
LD TM, A
Load the content of the accumulator to the timer register.
28
LD A, TM
Load the content of the timer register to the accumulator.
Execution the above transmit instructions will not affect the carry flag, and the status flag remains 1.
2. Input/output instructions
Instruction
Operation
CF
SF
Cycle
LD A, %p
A ← PORT(p)
---
/Z
2
LD @LL, %p
RAM(LL) ← PORT(p)
---
/Z
2
LD %p, A
PORT(p) ← A
---
1
2
LD %p, @LL
PORT(p) ← RAM(LL)
---
1
2
a.
LD A, %P
Move the value of port(P) to the accumulator
b.
LD @LL, %p
Move the value of port(P) to RAM pointed at by the LL register.
c.
LD %p, A
Move the contents of the accumulator to port (P).
d.
LD %p, @LL
Load the contents of RAM pointed at by the LL register to port(P).
The above four input/output instructions are used mostly for port operation, the two read instructions will affect
the status flag SF.
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SC73P1601
3. Arithmetic and logical instructions
Instruction
Operation
CF
SF
Cycle
ADD A, @LL
A ← A+RAM(LL)
---
/C
1
ADDC A, @LL
A ← A+RAM(LL)+CF
C
/C
1
ADD A, #k
A ← A+k
---
/C
1
ADD LL, #k
LL ← LL+k
---
/C
2
SUBRC A, @LL
A ← RAM(LL)-A-/CF
C
C
1
INC @LL
RAM(LL) ← RAM(LL)+1
---
/C
1
DEC @LL
RAM(LL) ← RAM(LL)-1
---
C
1
INC LL
LL ← LL+1
---
/C
2
DEC LL
LL ← LL-1
---
C
2
INC D
D ← D+1
---
/C
2
INC H
H ← H+1
---
/C
2
INC B
B ←B+1
---
/C
2
DEC D
D ← D-1
---
C
2
DEC H
H ← H-1
---
C
2
DEC B
B ← B-1
---
C
2
AND A, @LL
A ← A&RAM(LL)
---
/Z
1
OR A, @LL
A ← A | RAM(LL)
---
/Z
1
XOR A, @LL
A ← A^RAM(LL)
---
/Z
1
1.
ADD A, @LL
2.
ADDC A, @LL
3.
ADD A,#K
4.
ADD L,#K
Add the contents of RAM pointed at by the LL to accumulator, store the sum in the
ACC. This operation will affect SF, SF=/CF.
Add the contents of RAM pointed at by the LL register to accumulator with carry.
Store the carry bit in the CF. This operation will affect SF, SF=/CF.
Add immediate K to accumulator. Store the sum in the ACC. This will affect SF,
SF=/CF.
Add immediate K to the LL register. Store the sum in the LL. This will affect SF,
SF=/CF.
Subtract instruction with borrow(the complement of carry). Subtract the contents of
5.
SUBRC A, @LL
the accumulator from the contents of RAM pointed at by the LL register, subtract the
complement of the carry bit, then store the results in the accumulator, transfer the
carry bit to the CF, this will affect SF and CF, SF=CF.
6.
INC @LL
7.
DEC @LL
8.
INC D
9.
INC H
10.
INC B
Increment instruction. Increment the contents of RAM pointed at by the LL register
by 1. This will affect SF, SF=/CF.
Decrement instruction. Decrement the contents of RAM pointed at by the LL register
by 1. This will affect SF, SF=CF.
Increment instruction. Increment the contents of the D register by 1. This will affect
SF, SF=/CF.
Increment instruction. Increment the contents of the H register by 1. This will affect
SF, SF=/CF.
Increment instruction. Increment the contents of the B register by 1. This will affect
SF, SF=/CF.
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11.
DEC D
12.
DEC H
13.
DEC B
14.
INC LL
15.
DEC LL
16.
AND A, @LL
17.
OR A, @LL
18.
XOR A,@LL
Decrement instruction. Decrement the contents of the D register by 1. This will affect
SF, SF=CF.
Decrement instruction. Decrement the contents of the H register by 1. This will affect
SF, SF=CF.
Decrement instruction. Decrement the contents of the B register by 1. This will affect
SF, SF=CF.
Increment instruction. Increment the contents of the LL register by 1. This will affect
SF, SF=/CF.
Subtract 1 from the content in register LL. SF is affected, SF=/CF.
The contents of the accumulator and RAM pointed at by the LL register are ANDed
and the results are stored in the accumulator. SF changed, SF=/Z.
The contents of the accumulator and RAM pointed at by the LL register are ORed
and the results are stored in the accumulator. SF changed, SF=/Z.
The contents of the accumulator and RAM pointed at by the LL register are XORed
and the results are stored in the accumulator. SF changed, SF=/Z.
4. Bit operation instructions
Instruction
Operation
CF
SF
Cycle
CLR @LL, b
RAM(LL)b←0
---
1
2
SET @LL, b
RAM(LL)b←1
---
1
2
TEST @LL, b
SF←/RAM(LL)b
---
*
2
a.
CLR @LL, b
Clear the B-bit of the RAM pointed at by the LL register.
b.
SET @LL, b
Set the B-bit of the RAM pointed at by the LL register to be 1.
c.
TEST @LL, b
Test the B-bit of the RAM pointed at by the LL register. If this bit is1, the SF is set to
0; otherwise, the SF is set to 1.
5. Carry operation instructions
Instruction
a.
Operation
CF
SF
Cycle
CLR CF
CF←0
0
1
2
SET CF
CF←1
1
1
2
TESTP CF
SF←CF
---
*
1
CLR CF
Clear the carry flag to logic zero.
b.
SET CF
Set the carry flag to logic 1.
c.
TESTP CF
Test the carry flag, send the carry flag to SF.
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6. Branch instructions
CF
SF
Cycle
BSS label
Instruction
Operation
---
1
2
JMPS label
---
1
3
Jump instruction is active only when SF is 1, or else next instruction is executed. Please read the Pseudoinstruction Set for details.
BSS label Jump to destination address label with range of 128 bytes
JMPS label Jump to destination address label with range of 2K program.
Symbol description of above instructions:
a.
label
Destination address of jump
b.
#k
Immediate (0~15)
c.
b
Bit addressing (0~3)
d.
%p
Port address
7. Subroutine instructions
Instruction
Operation
CF
SF
Cycle
CALLS label
---
---
2
RET
---
---
2
When executing subroutine call and return instructions, the subroutine starting address is limited from 000H to
01FH.
8. Other instructions
Instruction
Operation
CF
SF
Cycle
HOLD
---
1
1
NOP
---
---
1
---
---
1
TMRST
Reset timer counter
a.
HOLD
After executing this instruction, MCU is in the power–save mode, the clock stops
b.
NOP
Null operation. It doesn’
t affect anything.
c.
TMRST
Timer clear command. It will clear all values of the timer to 0. This instruction is often
oscillation and power consumption reduces dramatically.
used to reset WDT in program.
9. Pseudoinstruction
ORG
Format:
[Label:] ORG address
Function:
Redefine following start address
Expression:
Label: selectable
Address: redefined address, can be binary, decimal or hexadecimal.
Redefined address is an absolute address which could not be returned back. That is, the redefined address
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should be higher than that above, or a fault is occurred during compiling. 000H is defaulted if no address is set by
ORG instruction.
Example:
ORG 0100H
EQU
Format:
Symbol EQU digital
Function:
Define a digital as a symbol. Symbol = digital.
Expression:
Symbol should be legal, and digital should be binary, decimal or hexadecimal. There is no colone before
EQU in definition, and it can only useful after the definition.
Example:
Data1 EQU 12H
Data2 EQU 1001B
DB
Format:
[Label:] [num] DB data
Function:
Define data with number of num.
Expression:
Label: selectable
Num: indicates number of data, default value is 1.
Data: data to be written to ROM. It should smaller than 0X200 as ROM is only 9-bit.lower 9-bit value of data
is taken with warning if it is more than 0x200.( only lower 8-bit is taken if the instruction is used for data table)
Example:
DB 12H
; Define one data
DB 10010B
; Define one data
12H DB 55H ; Define continuous 18 data
JMPS
Format:
[Label:] JMPS address
Function:
Jump in ROM.
Expression:
Label: selectable
Address can be a digital, symbol defined by EQU or the address symbol.
Combined by:
LD MBR, #k
BSS label
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The instruction is 2-byte long, and it can jump to any position in the ROM.
Example:
JMPS MAIN
JMPS 100H
VENT
Format:
VENT label
Function:
Define the entry and reset address of sub-program.
Expression:
Label is the sub-program name or the address symbol.
Use VENT to specify the entry and reset address of the sub-program, and it must be at the beginning of the
program. The first VENT denotes the reset address and the following VENT instructions denote the entry of the
sub-program. In general, 16 sub-programs can be defined at most. All the sub-programs called by CALL
instruction should be defined in VENT, or else errors will occur in assembly.
Example:
VENT MAIN
VENT SUB1
VENT SUB2
… … … … ..
ORG 100H
MAIN:
NOP
NOP
CALLS SUB1
CALLS SUB2
………….
SUB1:
………….
SUB2:
………….
END
Format:
END
Function:
Use the END instruction to end the assembly of a program.
Expression:
END pseudoinstruction ends the assembly of a program and the content after END will not be processed by
assembler. If END is omitted, the assembler will process all the lines of the source file.
Example:
END
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Remote control flow chart:
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SC73P1601
TYPICAL APPLICATION CIRCUIT
SC73P1601
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SC73P1601
PACKAGE OUTLINE
SSOP-20-300-0.65
Unit: mm
SOP-20-300-1.27
Unit: mm
0.15±0.05
1.27
0.45
2.25MAX
12.70±0.25
11.43
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PACKAGE OUTLINE (Continued)
SSOP-20-225-0.65
Unit: mm
SOP-20-375-1.27
Unit: mm
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MOS DEVICES OPERATE NOTES:
Electrostatic charges may exist in many things. Please take following preventive measures to prevent effectively
the MOS electric circuit as a result of the damage which is caused by discharge:
l
The operator must put on wrist strap which should be earthed to against electrostatic.
l
Equipment cases should be earthed.
l
All tools used during assembly, including soldering tools and solder baths, must be earthed.
l
MOS devices should be packed in antistatic/conductive containers for transportation.
Disclaimer:
•
Silan reserves the right to make changes to the information herein for the improvement of the design and performance
without further notice!
•
All semiconductor products malfunction or fail with some probability under special conditions. When using Silan products
in system design or complete machine manufacturing, it is the responsibility of the buyer to comply with the safety
standards strictly and take essential measures to avoid situations in which a malfunction or failure of such Silan products
could cause loss of body injury or damage to property.
•
Silan will supply the best possible product for customers!
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