PMC153-S08 [PADAUK]
8-bit OTP Type IO Controller;型号: | PMC153-S08 |
厂家: | PADAUK Technology |
描述: | 8-bit OTP Type IO Controller |
文件: | 总57页 (文件大小:1120K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
PMC153/PMS153 Series
8-bit OTP Type IO Controller
Datasheet
Version 1.08 –Dec. 26, 2019
Copyright 2019 by PADAUK Technology Co., Ltd., all rights reserved
6F-6, No.1, Sec. 3, Gongdao 5th Rd., Hsinchu City 30069, Taiwan, R.O.C.
TEL: 886-3-572-8688 www.padauk.com.tw
PMC153/PMS153 Series
8-bit OTP Type IO Controller
IMPORTANT NOTICE
PADAUK Technology reserves the right to make changes to its products or to terminate
production of its products at any time without notice. Customers are strongly
recommended to contact PADAUK Technology for the latest information and verify
whether the information is correct and complete before placing orders.
PADAUK Technology products are not warranted to be suitable for use in life-support
applications or other critical applications. PADAUK Technology assumes no liability for
such applications. Critical applications include, but are not limited to, those that may
involve potential risks of death, personal injury, fire or severe property damage.
PADAUK Technology assumes no responsibility for any issue caused by a customer’s
product design. Customers should design and verify their products within the ranges
guaranteed by PADAUK Technology. In order to minimize the risks in customers’ products,
customers should design a product with adequate operating safeguards.
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 2 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
Table of Contents
1. Features...............................................................................................................................6
1.1. Special Features.....................................................................................................................6
1.2. System Features.....................................................................................................................6
1.3. CPU Features .........................................................................................................................6
1.4. Package Information: ..............................................................................................................6
2. General Description and Block Diagram ..........................................................................7
3. Pin Assignment and Functional Description....................................................................8
4. Device Characteristics .....................................................................................................11
4.1. DC/AC Characteristics ..........................................................................................................11
4.2. Absolute Maximum Ratings...................................................................................................12
4.3. Typical IHRC Frequency vs. VDD (calibrated to 16MHz).......................................................13
4.4. Typical ILRC Frequency vs. VDD..........................................................................................13
4.5. Typical IHRC Frequency vs. Temperature (calibrated to 16MHz)..........................................14
4.6. Typical ILRC Frequency vs. Temperature.............................................................................14
4.7. Typical Operating Current vs. VDD and CLK=IHRC/n...........................................................15
4.8. Typical Operating Current vs. VDD and CLK=ILRC/n............................................................15
4.9. Typical IO pull high resistance...............................................................................................16
4.10. Typical IO driving current (IOH) and sink current (IOL) .............................................................16
4.11. Typical IO input high / low threshold voltage (VIH/VIL) ............................................................17
4.12. Typical power down current (IPD) and power save current (IPS)..............................................18
5. Functional Description.....................................................................................................19
5.1. Program Memory – OTP .......................................................................................................19
5.2. Boot Up.................................................................................................................................19
5.2.1.
Timing charts for reset conditions ...........................................................................20
5.3. Data Memory – SRAM ..........................................................................................................21
5.4. Oscillator and clock...............................................................................................................21
5.4.1
5.4.2
5.4.3
5.4.4
Internal High RC oscillator and Internal Low RC oscillator ......................................21
IHRC calibration .....................................................................................................21
IHRC Frequency Calibration and System Clock......................................................22
System Clock and LVR levels.................................................................................23
5.5. 16-bit Timer (Timer16) ..........................................................................................................24
5.6. Watchdog Timer....................................................................................................................25
5.7. Interrupt ................................................................................................................................26
5.8. Power-Save and Power-Down ..............................................................................................28
5.8.1
5.8.2
5.8.3
Power-Save mode (“stopexe”)................................................................................28
Power-Down mode (“stopsys”)................................................................................29
Wake-up.................................................................................................................29
5.9. IO Pins..................................................................................................................................31
5.10. Reset and LVR......................................................................................................................32
5.10.1 Reset......................................................................................................................32
5.10.2 LVR reset ...............................................................................................................32
5.10.3 Notice for LVR reset ...............................................................................................32
6. IO Registers.......................................................................................................................34
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 3 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
6.1. ACC Status Flag Register (flag), IO address = 0x00 .............................................................34
6.2. Stack Pointer Register (sp), IO address = 0x02.....................................................................34
6.3. Clock Mode Register (clkmd), IO address = 0x03 .................................................................34
6.4. Interrupt Enable Register (inten), IO address = 0x04.............................................................35
6.5. Interrupt Request Register (intrq), IO address = 0x05 ...........................................................35
6.6. Timer 16 mode Register (t16m), IO address = 0x06..............................................................35
6.7. External Oscillator setting Register (eoscr, write only), IO address = 0x0a............................36
6.8. IHRC oscillator control Register (ihrcr, write only), IO address = 0x0b ..................................36
6.9. Interrupt Edge Select Register (integs), IO address = 0x0c...................................................36
6.10. Port A Digital Input Enable Register (padier), IO address = 0x0d..........................................36
6.11. Port B Digital Input Enable Register (pbdier), IO address = 0x0e..........................................37
6.12. Port A Data Registers (pa), IO address = 0x10 .....................................................................37
6.13. Port A Control Registers (pac), IO address = 0x11................................................................37
6.14. Port A Pull-High Registers (paph), IO address = 0x12...........................................................37
6.15. Port B Data Registers (pb), IO address = 0x14 .....................................................................37
6.16. Port B Control Registers (pbc), IO address = 0x15................................................................37
6.17. Port B Pull-High Registers (pbph), IO address = 0x16...........................................................37
6.18. MISC Register (misc), IO address = 0x3b .............................................................................38
7. Instructions .......................................................................................................................39
7.1. Data Transfer Instructions.....................................................................................................40
7.2. Arithmetic Operation Instructions ..........................................................................................42
7.3. Shift Operation Instructions...................................................................................................44
7.4. Logic Operation Instructions..................................................................................................45
7.5. Bit Operation Instructions......................................................................................................47
7.6. Conditional Operation Instructions ........................................................................................47
7.7. System control Instructions ...................................................................................................48
7.8. Summary of Instructions Execution Cycle .............................................................................50
7.9. Summary of affected flags by Instructions.............................................................................51
7.10. BIT definition.........................................................................................................................51
8. Code Options ....................................................................................................................52
9. Special Notes ....................................................................................................................53
9.1. Warning.................................................................................................................................53
9.2. Using IC................................................................................................................................53
9.2.1.
9.2.2.
9.2.3.
9.2.4.
9.2.5.
9.2.6.
9.2.7.
9.2.8.
IO pin usage and setting.........................................................................................53
Interrupt..................................................................................................................53
System clock switching...........................................................................................54
Power down mode, wakeup and watchdog.............................................................54
TIMER time out.......................................................................................................55
LVR ........................................................................................................................55
IHRC.......................................................................................................................55
Program writing ......................................................................................................56
9.3. Using ICE..............................................................................................................................56
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 4 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
Revision History:
Revision
0.01
Date
Description
2013/12/10 1st version
0.02
2014/2/10
Add section 5.10.3 Notice for LVR reset ,Add chapter 8 Special Notes
0.03
2014/12/22 Amend PMS153 operating temperature to -40°C ~ 85°C
0.04
2015/5/25
2015/6/17
Add 4.1 VFSV forbidden startup voltage range, TPOR and TFSV
0.05
Amend PMS153 operating temperature to -20°C ~ 70°C
1. Add section 5.8.3: the description of wake-up
2. Add section 8.3 Warning
0.06
2016/7/7
1. Amend company address & Tel No.
2. Amend Section 1.1, 1.2, 1.3
3. Add section 1.4 Package Information
4. Add Chapter 3 PMC153/PMS153-S08, PMC153/PMS153-D08 Pin Assignment
5. Amend Section 4.1, 4.3 to 4.11
6. Add Section 4.12 Typical power down current (IPD) and power save current (IPS)
7. Add Section 5.2.1 Timing charts for reset conditions
8. Amend Table2: Two Oscillators provided by PMC153/PMS153
9. Amend Section 5.4.1, 5.4.3, 5.4.4
10. Amend Section 5.5 16-bit Timer
11. Amend Section 5.7 Interrupt
12. Amend Section 5.8.1, 5.8.2, 5.8.3
1.07
2018/12/11
13. Amend Section 5.10.1, 5.10.2, 5.10.3
14. Amend Section 6.6, 6.10, 6.11
15. Delete the Symbol “pc0” in Chapter 7
16. Amend Section 7.8 Summary of Instructions Execution Cycle and delete 8.1.7
17. Move Section 8.1.8 BIT definition to Section 7.10
18. Add Chapter 8 Code Options
19. Move Section 8.3 to Section 9.1 and updated the link
20. Amend Section 9.2.1, 9.2.5, 9.2.8
21. Add section 9.2.7 IHRC
22. Amend Section 9.3 Using ICE
1. Amend Section 1.2, 4.10, 5.2.1, 5.8.1, 5.8.2, 6.3, 6.10, 6.11, 9.2.8
2. Amend Section 4.1: VIL, IOL, IOH
3. Amend Fig 5
1.08
2019/12/26
4. Amend Chapter 8 Code Options
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 5 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
1. Features
1.1. Special Features
PMC153 series:
High EFT series
Operating temperature range: -40°C ~ 85°C
PMS153 series:
General purpose series
Not supposed to use in AC RC step-down powered or high EFT requirement applications.
PADAUK assumes no liability if such kind of applications can not pass the safety regulation tests.
Operating temperature range: -20°C ~ 70°C
1.2. System Features
1KW OTP program memory
64 Bytes data RAM
One hardware 16-bit timer
Support fast wake-up
12 IO pins with 10mA capability and optional pull-high resistor (no pull-high resistor in PA5)
Band-gap circuit to provide 1.20V reference voltage
Internal High RC Oscillator (IHRC) frequency
Operating voltage range: 2.2V ~ 5.5V
Clock sources: internal high RC oscillator and internal low RC oscillator
Eight levels of LVR reset ~ 4.1V, 3.6V, 3.1V, 2.8V, 2.5V, 2.2V, 2.0V, 1.8V
Every IO pin can be configured to enable wake-up function
Two external interrupt pins
1.3. CPU Features
One processing unit operating mode
79 Powerful instructions
Most instructions are 1T execution cycle
Programmable stack pointer and adjustable stack level
Direct and indirect addressing modes for data access. Data memories are available for use as an index
pointer of Indirect addressing mode
IO space and memory space are independent
1.4. Package Information:
PMC153, PMS153 Series
PMC153/PMS153-S14: SOP14(150mil)
PMC153/PMS153-D14: DIP14(150mil)
PMC153/PMS153-S08: SOP8(150mil)
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 6 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
PMC153/PMS153-D08: DIP8(300mil)
2. General Description and Block Diagram
The PMC153/PMS153 is an IO-Type, fully static, OTP-based CMOS 8-bit microcontroller. The
PMC153/PMS153 employs RISC architecture and most the instructions are executed in one cycle except that
few instructions are two cycles that handle indirect memory access.
1KW bits OTP program memory and 64 bytes data SRAM are inside, one hardware 16-bit timer is also
provided in the PMC153/PMS153.
Interrupt
Controller
16-bit Timer
CPU
1KW OTP
&
IO Ports
Task
Control
64 bytes
SRAM
POR / LVR
Watchdog
Timer
Power
management
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 7 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
3. Pin Assignment and Functional Description
PB5
PB6
1
2
3
4
5
6
7
14 PB2
13 PB1
PB7
12 PB0/INT1
11 GND
VDD
PA7
10 PA0/INT0
PA6
9
8
PA4
PA3
PA5/PRST#B
PMC153/PMS153 (SOP14 - 150mil)
PMC153/PMS153 (DIP14 - 300mil)
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 8 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
Pin & Buffer
Type
Pin Name
Description
The function of this pin is Bit 7 of port A. It can be configured as digital input or
two-state output, with pull-high resistor.
IO
ST /
PA7
This pin can be used to wake-up system during sleep mode; however, wake-up
function is also disabled if bit 7 of padier register is “0”.
CMOS
The function of this pin is Bit 6 of port A. It can be configured as digital input or
two-state output, with pull-high resistor.
IO
PA6
ST /
This pin can be used to wake-up system during sleep mode; however, wake-up
function is also disabled if bit 6 of padier register is “0”.
CMOS
The functions of this pin can be:
(1) Bit 5 of port A. It can be configured as digital input or open-drain output pin.
Please notice that there is no pull-high resistor in this pin.
(2) Hardware reset.
IO
PA5/PRSTB
ST /
This pin can be used to wake-up system during sleep mode; however, wake-up
function is also disabled if bit 5 of padier register is “0”.
Please put 33Ω resistor in series to have high noise immunity when this pin is in
input mode.
CMOS
The function of this pin is Bit 4 of port A. It can be configured as digital input or
two-state output, with pull-high resistor. This pin can be used to wake up system
during sleep mode; however, wake-up function from this pin is disabled when bit 4
of padier register is “0”
IO
PA4
PA3
ST /
CMOS
The function of this pin is Bit 3 of port A. It can be configured as digital input or
two-state output, with pull-high resistor. This pin can be used to wake up system
during sleep mode; however, wake-up function from this pin is disabled when bit 3
of padier register is “0”
IO
ST /
CMOS
The functions of this pin can be:
(1) Bit 0 of port A. It can be configured as digital input or two-state output, with
pull-high resistor.
IO
PA0/INT0
ST /
(2) External interrupt line 0. Both rising edge and falling edge are accepted to
request interrupt service.
CMOS
This pin can be used to wake up system during sleep mode; however, wake-up
function from this pin is also disabled when bit 0 of padier register is “0”.
The function of this pin is Bit 7 of port B. It can be configured as digital input or
two-state output, with pull-high resistor. This pin can be used to wake up system
during sleep mode; however, wake-up function from this pin is also disabled when
bit 7 of pbdier register is “0”.
IO
PB7
ST /
CMOS
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 9 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
Pin Type &
Buffer Type
Pin Name
Description
The function of this pin is Bit 6 of port B. It can be configured as digital input or
two-state output, with pull-high resistor. This pin can be used to wake up system
during sleep mode; however, wake-up function from this pin is also disabled
when bit 6 of pbdier register is “0”.
IO
PB6
ST /
CMOS
The function of this pin is Bit 5 of port B. It can be configured as digital input or
two-state output, with pull-high resistor.This pin can be used to wake up system
during sleep mode; however, wake-up function from this pin is also disabled
when bit 5 of pbdier register is “0”.
IO
PB5
PB2
PB1
ST /
CMOS
The function of this pin is Bit 2 of port B. It can be configured as digital input or
two-state output, with pull-high resistor. This pin can be used to wake up system
during sleep mode; however, wake-up function from this pin is also disabled
when bit 2 of pbdier register is “0”.
IO
ST /
CMOS
The function of this pin is Bit 1 of port B. It can be configured as digital input or
two-state output, with pull-high resistor. This pin can be used to wake up system
during sleep mode; however, wake-up function from this pin is also disabled
when bit 1 of pbdier register is “0”.
IO
ST /
CMOS
The functions of this pin can be:
(1) Bit 0 of port B. It can be configured as digital input or two-state output, with
pull-high resistor.
IO
PB0/INT1
ST /
(2) External interrupt line 1. Both rising edge and falling edge are accepted to
request interrupt service.
CMOS
This pin can be used to wake up system during sleep mode; however, wake-up
function from this pin is also disabled when bit 0 of pbdier register is “0”.
VDD
GND
Positive power
Ground
Notes: IO: Input/Output; ST: Schmitt Trigger input; CMOS: CMOS voltage level
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 10 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
4. Device Characteristics
4.1. DC/AC Characteristics
All data are acquired under the conditions of Vdd=5.0V, fSYS=2MHz unless noted.
Symbol
VDD
Description
Operating Voltage
Min
Typ
Max
Unit
Conditions
2.2
5.0
5.5
V
* Subject to LVR tolerance
VFSV
Forbidden VDD Startup voltage
Range*
0.7
1.6
50
10
V
TPOR
TFSV
VDD power on time
(VDD from 0V to 5V)
VDD power on time during VFSV
range
ms
ms
Under_20ms_Vdd_ok**= Y/N
System clock (CLK)* =
IHRC/2
0
0
0
8M
4M
2M
VDD≧2.5V / VDD≧3.1V
VDD≧2.2V / VDD≧2.5V
VDD≧2.2V / VDD≧2.2V
VDD = 5.0V
fSYS
IHRC/4
Hz
IHRC/8
ILRC
35K
1
fSYS=1MIPS@5.0V
mA
IOP
IPD
Operating Current
7
uA fSYS=ILRC=21kHz@3.3V
uA fSYS= 0Hz,VDD=5.0V
uA fSYS= 0Hz,VDD=3.3V
VDD=5.0V;
Power Down Current
1
0.5
(by stopsys command)
Power Save Current
IPS
0.4
mA Band-gap, LVR, IHRC, ILRC,
Timer16 modules are ON.
V
(by stopexe command)
VIL
VIH
Input low voltage for IO lines
0
0.2VDD
VDD
Input high voltage for IO lines
0.7 VDD
V
PA5
4
12
0
IOL
IOH
mA VDD=5.0V, VOL=0.5V
Others
PA5
mA VDD=5.0V, VOH=4.5V
V
Others
9
Input voltage
Injected current on pin
-0.3
VDD+0.3
1
VIN
VDD+0.3≧VIN≧ -0.3
IINJ (PIN)
mA
62
VDD=5.0V
RPH
Pull-high Resistance
100
210
KΩ VDD=3.3V
VDD=2.2V
3.86
3.35
2.84
2.61
2.37
2.04
1.86
1.67
4.15
3.60
3.05
2.80
2.55
2.20
2.00
1.80
4.44
3.85
3.26
3.00
2.73
2.35
2.14
1.93
Low Voltage Detect Voltage *
VLVR
V
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 11 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
Symbol
Description
Min
Typ
Max
Unit
Conditions
VDD=2.2V~5.5V,
MHz -40oC <Ta<85oC*
-20oC <Ta<70oC*
15.20*
15.28*
16*
16*
16.80*
16.72*
Frequency of IHRC after
fIHRC
calibration *
VDD=2.2V~5.5V,
MHz -40oC <Ta<85oC*
-20oC <Ta<70oC*
15.20*
15.28*
29.7*
16*
16*
16.80*
16.72
39.6*
VDD=5.0V, Ta=25oC
35*
VDD=5.0V, -40oC <Ta<85oC*
VDD=5.0V, -20oC <Ta<70oC*
VDD=3.3V, Ta=25oC
VDD=3.3V, -40oC <Ta<85oC*
VDD=3.3V, -20oC <Ta<70oC*
VDD = 5.0V
22.7*
24.5*
47.3*
45.5*
35*
35*
fILRC
Frequency of ILRC *
kHz
14.8*
11.3*
11.9*
17*
17*
17*
19.8*
23.6*
22.1*
tINT
Interrupt pulse width
30
ns
V
VDR
RAM data retention voltage*
1.5
In power-down mode.
2048
4096
misc[1:0]=00 (default)
misc[1:0]=01
ILRC
clock
tWDT
Watchdog timeout period
16384
256
misc[1:0]=10
period
misc[1:0]=11
System boot-up period from
power-on
28
48
@VDD=5V, ILRC~35kHz
@VDD=3.3V, ILRC~21kHz
tSBP
ms
System wake-up period :
Fast wake-up by IO toggle from
STOPEXE suspend
Where TSYS is the time
128
TSYS
period of system clock
Fast wake-up by IO toggle from
STOPSYS suspend, IHRC is the
system clock
128 TSYS
Where TSIHRC is the stable
time of IHRC from power-on.
tWUP
+
TSIHRC
Normal wake-up from
STOPEXE or STOPSYS
suspend
Where TILRC is the clock
1024
TILRC period of ILRC
tRST
External reset pulse width
120
us @VDD=5V
*These parameters are for design reference, not tested for every chip.
** Under_20ms_Vdd_Ok is a checking condition for the VDD rising from 0V to the stated voltage within 20ms.
4.2. Absolute Maximum Ratings
Supply Voltage ……………………………......
Input Voltage …………………………………..
Operating Temperature ………………………
2.2V ~ 5.5V
-0.3V ~ VDD + 0.3V
PMC153 series: -40°C ~ 85°C
PMS153 series: -20°C ~ 70°C
-50oC ~ 125oC
Storage Temperature …………………………
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PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 12 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
Junction Temperature ………………………..
150oC
4.3. Typical IHRC Frequency vs. VDD (calibrated to 16MHz)
4.4. Typical ILRC Frequency vs. VDD
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PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 13 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
4.5. Typical IHRC Frequency vs. Temperature (calibrated to 16MHz)
4.6. Typical ILRC Frequency vs. Temperature
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PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 14 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
4.7. Typical Operating Current vs. VDD and CLK=IHRC/n
Conditions: ON: Band-gap, LVR, IHRC, T16 modules; OFF: ILRC modules;
IO: PA0:0.5Hz output toggle and no loading, others: input and no floating
4.8. Typical Operating Current vs. VDD and CLK=ILRC/n
Conditions: ON: Band-gap, LVR, ILRC, T16 modules; OFF: IHRC modules;
IO: PA0:0.5Hz output toggle and no loading, others: input and no floating
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PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 15 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
4.9. Typical IO pull high resistance
4.10.Typical IO driving current (IOH) and sink current (IOL)
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PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 16 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
4.11.Typical IO input high / low threshold voltage (VIH/VIL)
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PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 17 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
4.12.Typical power down current (IPD) and power save current (IPS)
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PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 18 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
5. Functional Description
5.1. Program Memory – OTP
The OTP (One Time Programmable) program memory is used to store the program instructions to be
executed. The OTP program memory may contains the data, tables and interrupt entry. After reset, the initial
address for FPP0 is 0x000. The interrupt entry is 0x010 if used, the last eight addresses are reserved for
system using, like checksum, serial number, etc. The OTP program memory for PMC153/PMS153 is a 1KW
that is partitioned as Table 1. The OTP memory from address 0x3F8 to 0x3FF is for system using, address
space from 0x001 to 0x00F and from 0x011 to 0x3F7 are user program spaces.
Address
0x000
0x001
•
Function
FPP0 reset – goto instruction
User program
•
•
•
0x00F
0x010
0x011
•
User program
Interrupt entry address
User program
•
0x3F7
0x3F8
•
User program
System Using
•
0x3FF
System Using
Table 1: Program Memory Organization
5.2. Boot Up
POR (Power-On-Reset) is used to reset PMC153/PMS153 when power up, however, the supply voltage may
be not stable. To ensure the stability of supply voltage after power up, it will wait 1024 ILRC clock cycles
before first instruction being executed, which is tSBP and shown in the Fig. 1.
VDD
t
SBP
POR
Program
Execution
Boot up from Power-On Reset
Fig. 1: Power Up Sequence
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.2.1. Timing charts for reset conditions
LVR level
VDD
LVR
SBP
t
Program
Execution
Boot up from LVR detection
VDD
t
SBP
WD
Time Out
Program
Execution
Boot up from Watch Dog Time Out
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.3. Data Memory – SRAM
The access of data memory can be byte or bit operation. Besides data storage, the SRAM data memory is
also served as data pointer of indirect access method and the stack memory.
The stack memory is defined in the data memory. The stack pointer is defined in the stack pointer register; the
depth of stack memory of each processing unit is defined by the user. The arrangement of stack memory fully
flexible and can be dynamically adjusted by the user.
For indirect memory access mechanism, the data memory is used as the data pointer to address the data
byte. All the data memory could be the data pointer; it’s quite flexible and useful to do the indirect memory
access. All the 64 bytes data memory of PMC153/PMS153 can be accessed by indirect access mechanism.
5.4. Oscillator and clock
There are two oscillator circuits provided by PMC153/PMS153: internal high RC oscillator (IHRC) and internal
low RC oscillator (ILRC), and these two oscillators are enabled or disabled by registers clkmd.4 and clkmd.2
independently. User can choose one of these two oscillators as system clock source and use clkmd register
to target the desired frequency as system clock to meet different application.
Oscillator Module
Enable/Disable
clkmd.4
IHRC
ILRC
clkmd.2
Table2: Two Oscillators provided by PMC153/PMS153
5.4.1 Internal High RC oscillator and Internal Low RC oscillator
After boot-up, the IHRC and ILRC oscillators are enabled. The frequency of IHRC can be calibrated to
eliminate process variation by ihrcr register; normally it is calibrated to 16MHz. The frequency deviation can
be within 2% normally after calibration and it still drifts slightly with supply voltage and operating temperature.
Please refer to the measurement chart for IHRC frequency VS VDD and IHRC frequency VS temperature.
The frequency of ILRC will vary by process, supply voltage and temperature, please refer to DC specification
and do not use for accurate timing application.
5.4.2 IHRC calibration
The IHRC frequency may be different chip by chip due to manufacturing variation, PMC153/PMS153 provide
the IHRC frequency calibration to eliminate this variation, and this function can be selected when compiling
user’s program and the command will be inserted into user’s program automatically. The calibration
command is shown as below:
.ADJUST_IC SYSCLK=IHRC/(p1), IHRC=(p2)MHz, VDD=(p3)V
Where,
p1=2, 4, 8, 16, 32; In order to provide different system clock.
p2=14 ~ 18; In order to calibrate the chip to different frequency, 16MHz is the usually one.
p3=2.2 ~ 5.5; In order to calibrate the chip under different supply voltage.
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.4.3 IHRC Frequency Calibration and System Clock
During compiling the user program, the options for IHRC calibration and system clock are shown as Table 3:
SYSCLK
○ Set IHRC / 2
○ Set IHRC / 4
○ Set IHRC / 8
○ Set IHRC / 16
○ Set IHRC / 32
○ Set ILRC
CLKMD
IHRCR
Calibrated
Calibrated
Calibrated
Description
= 34h (IHRC / 2)
= 14h (IHRC / 4)
= 3Ch (IHRC / 8)
IHRC calibrated to 16MHz, CLK=8MHz (IHRC/2)
IHRC calibrated to 16MHz, CLK=4MHz (IHRC/4)
IHRC calibrated to 16MHz, CLK=2MHz (IHRC/8)
IHRC calibrated to 16MHz, CLK=1MHz (IHRC/16)
IHRC calibrated to 16MHz, CLK=0.5MHz (IHRC/32)
IHRC calibrated to 16MHz, CLK=ILRC
= 1Ch (IHRC / 16) Calibrated
= 7Ch (IHRC / 32) Calibrated
= E4h (ILRC / 1)
No change
Calibrated
○ Disable
No Change
IHRC not calibrated, CLK not changed
Table 3: Options for IHRC Frequency Calibration
Usually, .ADJUST_IC will be the first command after boot up, in order to set the target operating frequency
whenever stating the system. The program code for IHRC frequency calibration is executed only one time
that occurs in writing the codes into OTP memory; after then, it will not be executed again. If the different
option for IHRC calibration is chosen, the system status is also different after boot. The following shows the
status of PMC153/PMS153 for different option:
(1) .ADJUST_IC
SYSCLK=IHRC/2, IHRC=16MHz, VDD=5V
After boot up, CLKMD = 0x34:
IHRC frequency is calibrated to 16MHz@VDD=5V and IHRC module is enabled
System CLK = IHRC/2 = 8MHz
Watchdog timer is disabled, ILRC is enabled, PA5 is in input mode
(2) .ADJUST_IC
SYSCLK=IHRC/4, IHRC=16MHz, VDD=3.3V
After boot, CLKMD = 0x14:
IHRC frequency is calibrated to 16MHz@VDD=3.3V and IHRC module is enabled
System CLK = IHRC/4 = 4MHz
Watchdog timer is disabled, ILRC is enabled, PA5 is in input mode
(3) .ADJUST_IC
SYSCLK=IHRC/8, IHRC=16MHz, VDD=2.5V
After boot, CLKMD = 0x3C:
IHRC frequency is calibrated to 16MHz@VDD=2.5V and IHRC module is enabled
System CLK = IHRC/8 = 2MHz
Watchdog timer is disabled, ILRC is enabled, PA5 is in input mode
(4) .ADJUST_IC
SYSCLK=IHRC/16, IHRC=16MHz, VDD=2.2V
After boot, CLKMD = 0x1C:
IHRC frequency is calibrated to 16MHz@VDD=2.2V and IHRC module is enabled
System CLK = IHRC/16 = 1MHz
Watchdog timer is disabled, ILRC is enabled, PA5 is in input mode
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
(5) .ADJUST_IC
SYSCLK=IHRC/32, IHRC=16MHz, VDD=5V
After boot, CLKMD = 0x7C:
IHRC frequency is calibrated to 16MHz@VDD=5V and IHRC module is enabled
System CLK = IHRC/32 = 500kHz
Watchdog timer is disabled, ILRC is enabled, PA5 is in input mode
(6) .ADJUST_IC
SYSCLK=ILRC, IHRC=16MHz, VDD=5V
After boot, CLKMD = 0XE4:
IHRC frequency is calibrated to 16MHz@VDD=5V and IHRC module is disabled
System CLK = ILRC
Watchdog timer is disabled, ILRC is enabled, PA5 is input mode
(7) .ADJUST_IC
DISABLE
After boot, CLKMD is not changed (Do nothing):
IHRC is not calibrated and IHRC module is disabled
System CLK = ILRC
Watchdog timer is enabled, ILRC is enabled, PA5 is in input mode
5.4.4 System Clock and LVR levels
The clock source of system clock comes from IHRC or ILRC, the hardware diagram of system clock in the
PMC153/PMS153 is shown as Fig. 2.
clkmd[7:5]
IHRC
clock
÷2, ÷4, ÷8,
÷16, ÷32, ÷64
System
clock
CLK
M
U
X
ILRC
clock
÷1 (default), ÷4
Fig. 2: Options of System Clock
User can choose different operating system clock depends on its requirement; the selected operating system
clock should be combined with supply voltage and LVR level to make system stable. The LVR level will be
selected during compilation. Please refer to Section 4.1.
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.5. 16-bit Timer (Timer16)
PMC153/PMS153 provides a 16-bit hardware timer (Timer16) and its clock source may come from system
clock (CLK), internal high RC oscillator (IHRC), internal low RC oscillator (ILRC), PA0 or PA4. Before sending
clock to the 16-bit counter, a pre-scaling logic with divided-by-1, 4, 16 or 64 is selectable for wide range
counting. The 16-bit counter performs up-counting operation only, the counter initial values can be stored
from data memory by issuing the stt16 instruction and the counting values can be loaded to data memory by
issuing the ldt16 instruction. The interrupt request from Timer16 will be triggered by the selected bit which
comes from bit[15:8] of this 16-bit counter, rising edge or falling edge can be optional chosen by register
integs.4. The hardware diagram of Timer16 is shown as Fig. 3.
stt16 command
DATA Memory
t16m[7:5]
t16m[4:3]
ldt16 command
CLK
IHRC
ILRC
PA0
M
U
X
Pre-
scalar
÷
1, 4,
16, 64
16-bit
up
counter
Bit[15:0]
Data Bus
PA4
Bit[15:8]
M
U
X
To set
interrupt
request flag
or
t16m[2:0]
integs.4
Fig. 3: Hardware diagram of Timer16
When using the Timer16, the syntax for Timer16 has been defined in the .INC file. There are three parameters
to define the Timer16 using; 1st parameter is used to define the clock source of Timer16, 2nd parameter is used
to define the pre-scalar and the 3rd one is to define the interrupt source.
T16M
IO_RW
0x06
$ 7~5:
STOP, SYSCLK, X, PA4_F, IHRC, X, ILRC, PA0_F
/1, /4, /16, /64
// 1st par.
// 2nd par.
// 3rd par.
$ 4~3:
$ 2~0:
BIT8, BIT9, BIT10, BIT11, BIT12, BIT13, BIT14, BIT15
User can choose the proper parameters of T16M to meet system requirement, examples as below (For more
examples, please refer to IDE software "Application Note Introduction of IC Introduction of Register
T16M"):
$
T16M
SYSCLK, /64, BIT15;
// choose (SYSCLK/64) as clock source, every 2^16 clock to set INTRQ.2=1
// if system clock SYSCLK = IHRC / 2 = 8 MHz
// SYSCLK/64 = 8 MHz/64 = 8 uS, about every 524 mS to generate INTRQ.2=1
$
$
T16M
PA0, /1, BIT8;
// choose PA0 as clock source, every 2^9 to generate INTRQ.2=1
// receiving every 512 times PA0 to generate INTRQ.2=1
T16M
STOP;
// stop Timer16 counting
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.6. Watchdog Timer
The watchdog timer (WDT) is a counter with clock coming from ILRC and its frequency is about 35 kHz. There
are four different timeout periods of watchdog timer can be chosen by setting the misc register, it is:
256 ILRC clock period when misc[1:0]=11
16384 ILRC clock period when misc[1:0]=10
4096 ILRC clock period when misc[1:0]=01
2048 ILRC clock period when misc[1:0]=00 (default)
The frequency of ILRC may drift a lot due to the variation of manufacture, supply voltage and temperature;
user should reserve guard band for safe operation. WDT can be cleared by power-on-reset or by command
wdreset at any time. When WDT is timeout, PMC153/PMS153 will be reset to restart the program execution.
The relative timing diagram of watchdog timer is shown as Fig. 4.
VDD
t
SBP
WD
Time Out
Program
Execution
Watch Dog Time Out Sequence
Fig. 4: Sequence of Watch Dog Time Out
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.7. Interrupt
There are three interrupt lines for PMC153/PMS153:
Two external interrupt: PA0, PB0
One Timer16 interrupt
Every interrupt request line has its own corresponding interrupt control bit to enable or disable it; the hardware
diagram of interrupt function is shown as Fig. 5. All the interrupt request flags are set by hardware and cleared
by writing intrq register. When the request flags are set, it can be rising edge, falling edge or both, depending
on the setting of register integs. All the interrupt request lines are also controlled by engint instruction
(enable global interrupt) to enable interrupt operation and disgint instruction (disable global interrupt) to
disable it. The stack memory for interrupt is shared with data memory and its address is specified by stack
register sp. Since the program counter is 16 bits width, the bit 0 of stack register sp should be kept 0.
Moreover, user can use pushaf / popaf instructions to store or restore the values of ACC and flag register to
/ from stack memory.
Since the stack memory is shared with data memory, the stack position and level are arranged by the
compiler in Mini-C project. When defining the stack level in ASM project, users should arrange their locations
carefully to prevent address conflicts.
Inten.2
T16 output
Integs.4
PB0
Intrq.2
Select Edge
& Set Flag
Interrupt
to FPP0
Inten.1
Intrq.1
Select Edge
& Set Flag
Integs[3:2]
PA0
engint & disgint
Inten.0
Intrq.0
Select Edge
& Set Flag
Integs[1:0]
Fig. 5: Hardware diagram of Interrupt controller
Once the interrupt occurs, its operation will be:
The program counter will be stored automatically to the stack memory specified by register sp.
New sp will be updated to sp+2.
Global interrupt will be disabled automatically.
The next instruction will be fetched from address 0x010.
During the interrupt service routine, the interrupt source can be determined by reading the intrq register.
Note: Even if INTEN=0, INTRQ will be still triggered by the interrupt source.
After finishing the interrupt service routine and issuing the reti instruction to return back, its operation will be:
The program counter will be restored automatically from the stack memory specified by register sp.
New sp will be updated to sp-2.
Global interrupt will be enabled automatically.
The next instruction will be the original one before interrupt.
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
User must reserve enough stack memory for interrupt, two bytes stack memory for one level interrupt and four
bytes for two levels interrupt. For interrupt operation, the following sample program shows how to handle the
interrupt, noticing that it needs four bytes stack memory to handle interrupt and pushaf.
void
{
FPPA0
(void)
...
$
INTEN PA0;
// INTEN =1; interrupt request when PA0 level changed
// clear INTRQ
INTRQ
ENGINT
...
=
0;
// global interrupt enable
DISGINT
...
// global interrupt disable
}
void Interrupt (void)
// interrupt service routine
{
PUSHAF
// store ALU and FLAG register
// If INTEN.PA0 will be opened and closed dynamically,
// user can judge whether INTEN.PA0 =1 or not.
// Example: If (INTEN.PA0 && INTRQ.PA0) {…}
// If INTEN.PA0 is always enable,
// user can omit the INTEN.PA0 judgement to speed up interrupt service routine.
If (INTRQ.PA0)
{
// Here for PA0 interrupt service routine
INTRQ.PA0 = 0;
...
// Delete corresponding bit (take PA0 for example)
}
...
// X : INTRQ = 0;
// It is not recommended to use INTRQ = 0 to clear all at the end of
// the interrupt service routine.
// It may accidentally clear out the interrupts that have just occurred
// and are not yet processed.
POPAF
// restore ALU and FLAG register
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.8. Power-Save and Power-Down
There are three operational modes defined by hardware: ON mode, Power-Save mode and Power-Down
modes. ON mode is the state of normal operation with all functions ON, Power-save mode (“stopexe”) is the
state to reduce operating current and CPU keeps ready to continue, Power-Down mode (“stopsys”) is used
to save power deeply. Therefore, Power-save mode is used in the system which needs low operating power
with wake-up occasionally and Power-Down mode is used in the system which needs power down deeply
with seldom wake-up. table 4 shows the differences in oscillator modules between Power-Save mode
(“stopexe”) and Power-Down mode (“stopsys”).
Differences in oscillator modules between STOPSYS and STOPEXE
IHRC
Stop
ILRC
Stop
STOPSYS
STOPEXE
No Change
No Change
Table 4: Differences in oscillator modules between STOPSYS and STOPEXE
5.8.1 Power-Save mode (“stopexe”)
Using “stopexe” instruction to enter the Power-Save mode, only system clock is disabled, remaining all the
oscillator modules be active. For CPU, it stops executing; however, for Timer16, counter keep counting if its
clock source is not the system clock. The wake-up sources for “stopexe” can be IO-toggle or Timer16 counts
to set values when the clock source of Timer16 is IHRC or ILRC modules. Wake-up from input pins can be
considered as a continuation of normal execution, the detail information for Power-Save mode shown below:
IHRC oscillator modules: No change, keep active if it was enabled
ILRC oscillator modules: must remain enabled, need to start with ILRC when be wakening up.
System clock: Disable, therefore, CPU stops execution
OTP memory is turned off
Timer counter: Stop counting if its clock source is system clock or the corresponding oscillator module is
disabled; otherwise, it keeps counting. (The Timer contains TM16)
Wake-up sources:
a. IO toggle wake-up: IO toggling in digital input mode (PxC bit is 1 and PxDIER bit is 1)
b. Timer wake-up: If the clock source of Timer is not the SYSCLK, the system will be awakened when
the Timer counter reaches the set value.
The watchdog timer must be disabled before issuing the “stopexe” command, the example is shown as
below:
CLKMD.En_WatchDog
stopexe;
=
0;
// disable watchdog timer
// power saving
….
Wdreset;
CLKMD.En_WatchDog
=
1;
// enable watchdog timer
Another example shows how to use Timer16 to wake-up from “stopexe”:
$ T16M IHRC, /1, BIT8
…
// Timer16 setting
WORD
STT16
count
=
0;
count;
stopexe;
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
…
The initial counting value of Timer16 is zero and the system will be waken up after the Timer16 counts 256
IHRC clocks.
5.8.2 Power-Down mode (“stopsys”)
Power-Down mode is the state of deeply power-saving with turning off all the oscillator modules. By using the
“stopsys” instruction, this chip will be put on Power-Down mode directly. The internal low frequency RC
oscillator must be enabled before entering the Power-Down mode, means that bit 2 of register clkmd (0x03)
must be set to high before issuing “stopsys” command in order to resume the system when wakeup. The
following shows the internal status of PMC153/PMS153 in detail when “stopsys” command is issued:
All the oscillator modules are turned off
Enable internal low RC oscillator (set bit 2 of register clkmd)
OTP memory is turned off
The contents of SRAM and registers remain unchanged
Wake-up sources: IO toggle in digital mode (PxDIER bit is 1)
Wake-up from input pins can be considered as a continuation of normal execution. To minimize power
consumption, all the I/O pins should be carefully manipulated before entering power-down mode. The
reference sample program for power down is shown as below:
CMKMD
CLKMD.4 =
=
0xF4;
0;
//
//
change clock from IHRC to ILRC, disable watchdog timer
disable IHRC
…
while (1)
{
STOPSYS;
if (…) break;
//
//
//
enter power-down
if wakeup happen and check OK, then return to high speed,
else stay in power-down mode again.
}
CLKMD
=
0x34;
//
change clock from ILRC to IHRC/2
5.8.3 Wake-up
After entering the Power-Down or Power-Save modes, the PMC153/PMS153 can be resumed to normal
operation by toggling IO pins, Wake-up from timer is available for Power-Save mode ONLY. Table 5 shows the
differences in wake-up sources between STOPSYS and STOPEXE.
Differences in wake-up sources between STOPSYS and STOPEXE
IO Toggle
Yes
Timer wake-up
STOPSYS
STOPEXE
No
Yes
Yes
Table 5: Differences in wake-up sources between Power-Save mode and Power-Down mode
When using the IO pins to wake-up the PMC153/PMS153, registers padier should be properly set to enable
the wake-up function for every corresponding pin. The wake-up time for normal wake-up is about 1024 ILRC
clocks counting from wake-up event; fast wake-up can be selected to reduce the wake-up time by misc
register. For fast wake-up mechanism, the wake-up time is 128 system clocks from IO toggling if STOPEXE
was issued, and 128 system clocks plus IHRC oscillator stable time from IO toggling if STOPSYS was issued.
The oscillator stable time is the time for IHRC oscillator from power-on.
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
Wake-up
mode
System clock
Suspend mode
Wake-up time (tWUP) from IO toggle
source
STOPEXE
suspend
128 * TSYS,
Any one
fast wake-up
Where TSYS is the time period of system clock
128 TSYS + TSIHRC
;
STOPSYS
suspend
fast wake-up
IHRC
Where TSIHRC is the stable time of IHRC from
power-on.
STOPEXE
suspend
normal
wake-up
normal
1024 * TILRC
Where TILRC is the clock period of ILRC
1024 * TILRC
Where TILRC is the clock period of ILRC
,
Any one
Any one
STOPSYS
suspend
,
wake-up
Table 6: Wake-up time (tWUP) from IO toggle
To avoid unable wake-up problem happening from drifted process, please switch the system operating
frequency to ILRC/1 before executing STOPSYS/STOPEXE instruction, and then switch to the original
system operating frequency after waking-up, the example is shown as below:
….
$ CLKMD
stopsys;
$ CLKMD
ILRC/1,En_IHRC,En_ILRC
IHRC/n,En_IHRC,En_ILRC
// SYSCLK swtch to ILRC
// Use stopsys or stopexe
//Switch to SYSCLK after waking-up
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.9. IO Pins
Other than PA5, all the pins can be independently set into two states output or input by configuring the data
registers (pa, pb), control registers (pac, pbc) and pull-high registers (paph, pbph). All these pins have
Schmitt-trigger input buffer and output driver with CMOS level. When it is set to output low, the pull-high
resistor is turned off automatically. If user wants to read the pin state, please notice that it should be set to
input mode before reading the data port; if user reads the data port when it is set to output mode, the reading
data comes from data register, NOT from IO pad. As an example, Table 7 shows the configuration table of bit
0 of port A. The hardware diagram of IO buffer is also shown as Fig. 6.
pa.0 pac.0 paph.0
Description
Input without pull-high resistor
X
X
0
1
1
0
0
1
1
1
0
1
X
0
1
Input with pull-high resistor
Output low without pull-high resistor
Output high without pull-high resistor
Output high with pull-high resistor
Table 7: PA0 Configuration Table
-
RD pull high latch
D
D
D
Q
(weak P -MOS)
-
WR pull high latch
pull -high
latch
Q
Data
latch
Q1
PAD
WR data latch
RD control latch
Q
WR control latch
Control
M
U
latch
X
RD Port
Data Bus
padier .x or pbdier .x
Wakeup module
Interrupt module
(PA0,PB0 only)
Analog Module
Fig. 6: Hardware diagram of IO buffer
Other than PA5, all the IO pins have the same structure; PA5 can be open-drain ONLY when setting to output
mode (without Q1). When PMC153/PMS153 is put in power-down or power-save mode, every pin can be
used to wake-up system by toggling its state. Therefore, those pins needed to wake-up system must be set to
input mode and set the corresponding bits of registers padier to high. The same reason, padier.0 or pbdier.0
should be set high when PA0 or PB0 is used as external interrupt pin.
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
5.10. Reset and LVR
5.10.1 Reset
There are many causes to reset the PMC153/PMS153, once reset is asserted, all the registers in
PMC153/PMS153 will be set to default values, system should be restarted once abnormal cases happen, or
by jumping program counter to address 0x00. The data memory is in uncertain state when reset comes from
power-up and LVR; however, the content will be kept when reset comes from PRSTB pin or WDT timeout.
5.10.2 LVR reset
By code option, there are many different levels of LVR for reset. Usually, user selects LVR reset level to
be in conjunction with operating frequency and supply voltage.
5.10.3 Notice for LVR reset
In some applications, the power VDD may change rapidly because of quick switching the power source
manually or strong power noise. In case, when the power VDD drops to the level that is lower than the LVR
level but higher than 1.0V, if at this time the power VDD is pulled up again to be over LVR level (just see the
diagram below), there may be some chances that cause the MCU malfunction or hanged.
VDD
|
|
|
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
LVR
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
1.0V
|
|
|
|
- - - - - - - - - - - - - - - - - -
|
|
|
|
- - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Output
vvvvvvvvvv
LVR reset state
Reset succeed,IO signal output
Reset fail,IO signal output stop
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Page 32 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
To avoid the above problem, please follow the below steps in your program:
Step 1. Insert the below two instructions just after the .ADJUST_IC instruction
SET1 inten.7
Notice: IDE 0.57 or above version will insert this instruction automatically.
Intrq
=
0;
Notice: IDE 0.59 or above version will insert this instruction automatically.
Step 2. Never clear the inten.7 through out the whole program. Please pay special attention in accidental
clear inten.7 by writing operation to the whole inten register. Please consider using set1/set0 instruction to
change other interrupt enable flags.
Notice: IDE 0.57 or above version will block the reset operation of inten.7 automatically.
Step 3. When wdreset instruction is being used:
Please modify the wdreset instruction inside the main loop of the program:
C language:
If (inten.7==0) reset; else {wdreset;}
Assembly language: t1sn inten.7;
reset
wdreset
or use as below :
.wdreset
(for IDE 0.57 or above version only)
Step 4. When clkmd is being used:
When clkmd instruction is set inside the main loop of the program and clkmd.1 = 0, please insert
below instructions afterward.
C language:
If (inten.7==0) reset;
Assembly language:
t1sn
inten.7;
reset
or use as below to set clkmd:
.clkmd = 0x hh;
( “ hh” is a hexadecimal value. For IDE 0.59 or above version only)
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Page 33 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
6. IO Registers
6.1. ACC Status Flag Register (flag), IO address = 0x00
Bit Reset R/W
Description
7 – 4
3
-
-
-
Reserved. These four bits are “1” when read.
R/W OV (Overflow). This bit is set whenever the sign operation is overflow.
AC (Auxiliary Carry). There are two conditions to set this bit, the first one is carry out of low
R/W nibble in addition operation, and the other one is borrow from the high nibble into low nibble
in subtraction operation.
2
-
C (Carry). There are two conditions to set this bit, the first one is carry out in addition
R/W operation, and the other one is borrow in subtraction operation. Carry is also affected by
shift with carry instruction.
1
0
-
-
Z (Zero). This bit will be set when the result of arithmetic or logic operation is zero;
R/W
Otherwise, it is cleared.
6.2. Stack Pointer Register (sp), IO address = 0x02
Bit Reset R/W
Description
Stack Pointer Register. Read out the current stack pointer, or write to change the stack
pointer. Please notice that bit 0 should be kept 0 due to program counter is 16 bits.
7 – 0 R/W
-
6.3. Clock Mode Register (clkmd), IO address = 0x03
Bit Reset R/W
Description
System clock selection:
Type 0, clkmd[3]=0
Type 1, clkmd[3]=1
000: IHRC/16
001: IHRC/8
000: IHRC/4
001: IHRC/2
01x: reserved
10x: reserved
7 – 5
111 R/W
010: reserved
011: IHRC/32
100: IHRC/64
1xx: reserved.
110: ILRC/4
111: ILRC (default)
4
3
1
0
R/W IHRC oscillator Enable. 0 / 1: disable / enable
Clock Type Select. This bit is used to select the clock type in bit [7:5].
0 / 1: Type 0 / Type 1
RW
ILRC Enable. 0 / 1: disable / enable
2
1
R/W
If ILRC is disabled, watchdog timer is also disabled.
1
0
1
0
R/W Watch Dog Enable. 0 / 1: disable / enable
R/W Pin PA5/PRSTB function. 0 / 1: PA5 / PRSTB.
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Page 34 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
6.4. Interrupt Enable Register (inten), IO address = 0x04
Bit Reset R/W
Description
7 – 3
-
-
-
-
R/W Reserved.
2
1
0
R/W Enable interrupt from Timer16 overflow. 0 / 1: disable / enable.
R/W Enable interrupt from PB0. 0 / 1: disable / enable.
R/W Enable interrupt from PA0. 0 / 1: disable / enable.
6.5. Interrupt Request Register (intrq), IO address = 0x05
Bit Reset R/W
Description
7 – 3
-
-
-
R/W Reserved.
Interrupt Request from Timer16, this bit is set by hardware and cleared by software.
0 / 1: No request / Request
2
1
R/W
R/W
R/W
Interrupt Request from pin PB0, this bit is set by hardware and cleared by software.
0 / 1: No request / Request
Interrupt Request from pin PA0, this bit is set by hardware and cleared by software.
0 / 1: No request / Request
0
-
6.6. Timer 16 mode Register (t16m), IO address = 0x06
Bit Reset R/W
Description
Timer Clock source selection
000: Timer 16 is disabled
001: CLK (system clock)
010: reserved
7 – 5
4 – 3
2 – 0
000 R/W 011: PA4 falling edge (from external pin)
100: IHRC
101: reserved
110: ILRC
111: PA0 falling edge (from external pin)
Internal clock divider.
00: /1
00
R/W 01: /4
10: /16
11: /64
Interrupt source selection. Interrupt event happens when selected bit is changed.
0 : bit 8 of Timer16
1 : bit 9 of Timer16
2 : bit 10 of Timer16
000 R/W 3 : bit 11 of Timer16
4 : bit 12 of Timer16
5 : bit 13 of Timer16
6 : bit 14 of Timer16
7 : bit 15 of Timer16
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
6.7. External Oscillator setting Register (eoscr, write only), IO address = 0x0a
Bit
Reset R/W
Description
7 – 1
-
-
Reserved. Please keep 0.
Power-down the Band-gap and LVR hardware modules.
0 / 1: normal / power-down.
0
0
WO
6.8. IHRC oscillator control Register (ihrcr, write only), IO address = 0x0b
Bit
Reset R/W
Description
Bit [5:0] of internal high RC oscillator for frequency calibration.
For system using only, please user do NOT write this register.
5 – 0
-
WO
6.9. Interrupt Edge Select Register (integs), IO address = 0x0c
Bit
Reset R/W
Description
7 – 5
-
-
Reserved. Please keep 0.
Timer16 edge selection.
4
0
WO 0 : rising edge to trigger interrupt
1 : falling edge to trigger interrupt
PB0 edge selection.
00 : both rising edge and falling edge to trigger interrupt
WO 01 : rising edge to trigger interrupt
10 : falling edge to trigger interrupt
11 : reserved.
3 – 2
00
00
PA0 edge selection.
00 : both rising edge and falling edge to trigger interrupt
WO 01 : rising edge to trigger interrupt
10 : falling edge to trigger interrupt
11 : reserved.
1 – 0
6.10.Port A Digital Input Enable Register (padier), IO address = 0x0d
Bit
Reset R/W
Description
Enable PA7~PA3 digital input and wake up event.
1 / 0 : enable / disable.
7 – 3 11111 WO
These bits can be set to low to disable wake up from PA7~PA3 toggling.
Reserved.
2 – 1
0
-
-
Enable PA0 digital input and wake up event and interrupt request.
1 / 0 : enable / disable.
1
WO
This bit can be set to low to disable wake up from PA0 toggling and interrupt request from
this pin.
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
6.11.Port B Digital Input Enable Register (pbdier), IO address = 0x0e
Bit
Reset
111
-
R/W
WO
-
Description
Enable PB7~ PB5 digital input and wake up event. 1 / 0 : enable / disable.
If these bit set to low, PB7~ PB5 can NOT be used to wake up the system.
Reserved.
7 - 5
4 – 3
2 - 1
Enable PB2~PB1 digital input and wake up event. 1 / 0 : enable / disable.
If these bit set to low, PB2~PB1 can NOT be used to wake up the system.
Enable PB0 digital input and wake up event and interrupt request.
1 / 0 : enable / disable.
11
WO
0
1
WO
If this bit is set to low, PB0 can NOT be used to wake up the system and interrupt
request from this pin.
6.12.Port A Data Registers (pa), IO address = 0x10
Bit
Reset R/W
Description
7 – 0 0x00 R/W Data registers for Port A.
6.13.Port A Control Registers (pac), IO address = 0x11
Bit
Reset R/W
Description
Port A control registers. This register is used to define input mode or output mode for each
corresponding pin of port A. 0 / 1: input / output.
7 – 0 0x00 R/W
6.14.Port A Pull-High Registers (paph), IO address = 0x12
Bit
Reset R/W
Description
Port A pull-high registers. This register is used to enable the internal pull-high device on
7–0
0x00 R/W each corresponding pin of port A. 0 / 1 : disable / enable
Please note that the PA5 does not have pull-high resistor.
6.15.Port B Data Registers (pb), IO address = 0x14
Bit Reset R/W
Description
7–0
0x00 R/W Data registers for Port B.
6.16.Port B Control Registers (pbc), IO address = 0x15
Bit Reset R/W
Description
Port B control registers. This register is used to define input mode or output mode for each
corresponding pin of port B. 0 / 1: input / output
7–0 0x00 R/W
6.17.Port B Pull-High Registers (pbph), IO address = 0x16
Bit Reset R/W
Description
Port B pull-high registers. This register is used to enable the internal pull-high device on
each corresponding pin of port B. 0 / 1 : disable / enable
7–0 0x00 R/W
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Page 37 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
6.18.MISC Register (misc), IO address = 0x3b
Bit
Reset R/W
Description
7 - 6
-
-
WO
-
Reserved
Enable fast Wake up.
0: Normal wake up.
The wake-up time is 1024 ILRC clocks
1: Fast wake-up. (for The wake-up time is 128 CLKs (system clock) + oscillator stable time.
If wake-up from STOPEXE suspend, there is no oscillator stable time;
If wake-up from STOPSYS suspend, it will be IHRC or ILRC stable time from power-on.
Please notice that the clock source will be switched to system clock
(for example: 4MHz) when fast wakeup is enabled, therefore,
it is recommended to turn off the watchdog timer before enabling the fast wakeup
and turn on the watchdog timer after disabling the fast wakeup.
Reserved
5
0
4
3
-
Recover time from LVR reset.
0
WO 0: Normal. The system will take about 1024 ILRC clocks to boot up from LVR reset.
1: Fast. The system will take about 64 ILRC clocks to boot up from LVR reset.
Disable LVR function.
WO
2
0
0 / 1 : Enable / Disable
Watch dog time out period
00: 2048 ILRC clock period
WO 01: 4096 ILRC clock period
10: 16384 ILRC clock period
11: 256 ILRC clock period
1 – 0
00
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
7. Instructions
Symbol
Description
ACC
a
Accumulator ( Abbreviation of accumulator )
Accumulator ( Symbol of accumulator in program )
sp
flag
I
Stack pointer
ACC status flag register
Immediate data
&
Logical AND
|
Logical OR
←
^
Movement
Exclusive logic OR
+
Add
-
〜
〒
OV
Z
Subtraction
NOT (logical complement, 1’s complement)
NEG (2’s complement)
Overflow (The operational result is out of range in signed 2’s complement number system)
Zero (If the result of ALU operation is zero, this bit is set to 1)
Carry (The operational result is to have carry out for addition or to borrow carry for subtraction
in unsigned number system)
C
Auxiliary Carry (If there is a carry out from low nibble after the result of ALU operation, this bit is
set to 1)
AC
word
M.n
Only addressed in 0~0x1F (0~31) is allowed
Only addressed in 0~0xF (0~15) is allowed
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
7.1. Data Transfer Instructions
mov
mov
mov
mov
mov
a, I
Move immediate data into ACC.
Example: mov a, 0x0f;
Result: a ← 0fh;
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
M, a
a, M
Move data from ACC into memory
Example: mov
MEM, a;
Result: MEM ← a
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Move data from memory into ACC
Example: mov
a, MEM ;
Result: a ← MEM; Flag Z is set when MEM is zero.
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
a, IO
Move data from IO into ACC
Example: mov
a, pa ;
Result: a ← pa; Flag Z is set when pa is zero.
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
IO, a
Move data from ACC into IO
Example: mov
Result: pb ← a
pb, a;
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Move 16-bit counting values in Timer16 to memory in word.
Example: ldt16 word;
ldt16 word
Result:
word ← 16-bit timer
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
word
…
T16val ;
// declare a RAM word
clear
clear
stt16
…
lb@ T16val ;
hb@ T16val ;
T16val ;
// clear T16val (LSB)
// clear T16val (MSB)
// initial T16 with 0
set1
…
t16m.5 ;
// enable Timer16
set0
ldt16
….
t16m.5 ;
T16val ;
// disable Timer 16
// save the T16 counting value to T16val
------------------------------------------------------------------------------------------------------------------------
Store 16-bit data from memory in word to Timer16.
Example: stt16 word;
stt16 word
Result:
16-bit timer ←word
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
word
T16val ;
// declare a RAM word
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
…
mov
mov
mov
mov
stt16
…
a, 0x34 ;
lb@ T16val , a ; // move 0x34 to T16val (LSB)
a, 0x12 ;
hb@ T16val , a ; // move 0x12 to T16val (MSB)
T16val ;
// initial T16 with 0x1234
----------------------------------------------------------------------------------------------------------------------
idxm a, index Move data from specified memory to ACC by indirect method. It needs 2T to execute this
instruction.
Example: idxm a, index;
Result:
a ← [index], where index is declared by word.
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Application Example:
-----------------------------------------------------------------------------------------------------------------------
word
…
RAMIndex ;
// declare a RAM pointer
mov
mov
mov
mov
…
a, 0x5B ;
// assign pointer to an address (LSB)
// save pointer to RAM (LSB)
lb@RAMIndex, a ;
a, 0x00 ;
// assign 0x00 to an address (MSB), should be 0
hb@RAMIndex, a ; // save pointer to RAM (MSB)
idxm
a, RAMIndex ; // mov memory data in address 0x5B to ACC
------------------------------------------------------------------------------------------------------------------------
Idxm index, a Move data from ACC to specified memory by indirect method. It needs 2T to execute this
instruction.
Example: idxm index, a;
Result:
[index] ← a; where index is declared by word.
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
word
…
RAMIndex ;
// declare a RAM pointer
mov
mov
mov
mov
…
a, 0x5B ;
// assign pointer to an address (LSB)
// save pointer to RAM (LSB)
lb@RAMIndex, a ;
a, 0x00 ;
// assign 0x00 to an address (MSB), should be 0
hb@RAMIndex, a ; // save pointer to RAM (MSB)
mov
idxm
a, 0xA5 ;
RAMIndex, a ;
// mov 0xA5 to memory in address 0x5B
------------------------------------------------------------------------------------------------------------------------
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Page 41 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
xch
M
Exchange data between ACC and memory
Example: xch MEM ;
Result:
MEM ← a , a ← MEM
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Move the ACC and flag register to memory that address specified in the stack pointer.
Example: pushaf;
pushaf
Result:
[sp] ← {flag, ACC};
sp ← sp + 2 ;
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
.romadr 0x10 ;
// ISR entry address
pushaf ;
…
// put ACC and flag into stack memory
// ISR program
…
// ISR program
popaf ;
reti ;
// restore ACC and flag from stack memory
------------------------------------------------------------------------------------------------------------------------
Restore ACC and flag from the memory which address is specified in the stack pointer.
Example: popaf;
popaf
Result:
sp ← sp - 2
{Flag, ACC} ← [sp] ;
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
;
7.2. Arithmetic Operation Instructions
add
add
add
a, I
Add immediate data with ACC, then put result into ACC
Example: add a, 0x0f ;
Result: a ← a + 0fh
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
a, M
M, a
Add data in memory with ACC, then put result into ACC
Example: add
a, MEM ;
Result: a ← a + MEM
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
Add data in memory with ACC, then put result into memory
Example: add
MEM, a;
Result: MEM ← a + MEM
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
addc a, M
addc M, a
Add data in memory with ACC and carry bit, then put result into ACC
Example: addc
a, MEM ;
Result: a ← a + MEM + C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
Add data in memory with ACC and carry bit, then put result into memory
Example: addc
Result: MEM ← a + MEM + C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
MEM, a ;
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
addc
addc
sub
a
Add carry with ACC, then put result into ACC
Example: addc a ;
Result: a ← a + C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
M
Add carry with memory, then put result into memory
Example: addc
MEM ;
Result: MEM ← MEM + C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
a, I
a, M
M, a
Subtraction immediate data from ACC, then put result into ACC.
Example: sub
a, 0x0f;
Result: a ← a - 0fh ( a + [2’s complement of 0fh] )
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
sub
Subtraction data in memory from ACC, then put result into ACC
Example: sub
a, MEM ;
Result: a ← a - MEM ( a + [2’s complement of M] )
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
sub
Subtraction data in ACC from memory, then put result into memory
Example: sub
MEM, a;
Result: MEM ← MEM - a ( MEM + [2’s complement of a] )
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
subc a, M
subc M, a
Subtraction data in memory and carry from ACC, then put result into ACC
Example: subc
a, MEM;
Result: a ← a – MEM - C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
Subtraction ACC and carry bit from memory, then put result into memory
Example: subc
MEM, a ;
Result: MEM ← MEM – a - C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
subc
subc
inc
a
Subtraction carry from ACC, then put result into ACC
Example: subc
a;
Result: a ← a - C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
M
Subtraction carry from the content of memory, then put result into memory
Example: subc
MEM;
Result: MEM ← MEM - C
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
M
Increment the content of memory
Example: inc
MEM ;
Result: MEM ← MEM + 1
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
dec
M
Decrement the content of memory
Example: dec
MEM;
Result: MEM ← MEM - 1
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
clear
M
Clear the content of memory
Example: clear
Result: MEM ← 0
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
MEM ;
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
7.3. Shift Operation Instructions
sr
a
Shift right of ACC, shift 0 to bit 7
Example: sr a ;
Result: a (0,b7,b6,b5,b4,b3,b2,b1) ← a (b7,b6,b5,b4,b3,b2,b1,b0), C ← a(b0)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Shift right of ACC with carry bit 7 to flag
src
sr
a
Example: src a ;
Result: a (c,b7,b6,b5,b4,b3,b2,b1) ← a (b7,b6,b5,b4,b3,b2,b1,b0), C ← a(b0)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Shift right the content of memory, shift 0 to bit 7
Example: sr MEM ;
M
Result: MEM(0,b7,b6,b5,b4,b3,b2,b1) ← MEM(b7,b6,b5,b4,b3,b2,b1,b0), C ← MEM(b0)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Shift right of memory with carry bit 7 to flag
src
sl
M
Example: src MEM ;
Result: MEM(c,b7,b6,b5,b4,b3,b2,b1) ← MEM (b7,b6,b5,b4,b3,b2,b1,b0), C ← MEM(b0)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Shift left of ACC shift 0 to bit 0
a
Example: sl a ;
Result: a (b6,b5,b4,b3,b2,b1,b0,0) ← a (b7,b6,b5,b4,b3,b2,b1,b0), C ← a (b7)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Shift left of ACC with carry bit 0 to flag
slc
sl
a
Example: slc a ;
Result: a (b6,b5,b4,b3,b2,b1,b0,c) ← a (b7,b6,b5,b4,b3,b2,b1,b0), C ← a(b7)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Shift left of memory, shift 0 to bit 0
M
Example: sl MEM ;
Result: MEM (b6,b5,b4,b3,b2,b1,b0,0) ← MEM (b7,b6,b5,b4,b3,b2,b1,b0), C ← MEM(b7)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Shift left of memory with carry bit 0 to flag
slc
M
Example: slc MEM ;
Result: MEM (b6,b5,b4,b3,b2,b1,b0,C) ← MEM (b7,b6,b5,b4,b3,b2,b1,b0), C ← MEM (b7)
Affected flags: 『N』Z 『Y』C 『N』AC 『N』OV
Swap the high nibble and low nibble of ACC
swap
a
Example: swap
Result: a (b3,b2,b1,b0,b7,b6,b5,b4) ← a (b7,b6,b5,b4,b3,b2,b1,b0)
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
a ;
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
7.4. Logic Operation Instructions
and
and
and
or
a, I
a, M
M, a
a, I
Perform logic AND on ACC and immediate data, then put result into ACC
Example: and a, 0x0f ;
Result: a ← a & 0fh
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Perform logic AND on ACC and memory, then put result into ACC
Example: and
a, RAM10 ;
Result: a ← a & RAM10
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Perform logic AND on ACC and memory, then put result into memory
Example: and
MEM, a ;
Result: MEM ← a & MEM
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Perform logic OR on ACC and immediate data, then put result into ACC
Example: or
a, 0x0f ;
Result: a ← a | 0fh
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
or
a, M
Perform logic OR on ACC and memory, then put result into ACC
Example: or
a, MEM ;
Result: a ← a | MEM
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
or
M, a
a, I
Perform logic OR on ACC and memory, then put result into memory
Example: or
MEM, a ;
Result: MEM ← a | MEM
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
xor
xor
Perform logic XOR on ACC and immediate data, then put result into ACC
Example: xor
a, 0x0f ;
Result: a ← a ^ 0fh
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
IO, a
Perform logic XOR on ACC and IO register, then put result into IO register
Example: xor
pa, a ;
Result: pa ← a ^ pa ; // pa is the data register of port A
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
xor
xor
a, M
M, a
Perform logic XOR on ACC and memory, then put result into ACC
Example: xor
a, MEM ;
Result: a ← a ^ RAM10
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Perform logic XOR on ACC and memory, then put result into memory
Example:
xor
MEM, a ;
Result:
MEM ← a ^ MEM
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
not
a
Perform 1’s complement (logical complement) of ACC
Example: not a ;
Result: a ← 〜a
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
mov
not
a, 0x38 ;
a ;
// ACC=0X38
// ACC=0XC7
------------------------------------------------------------------------------------------------------------------------
Perform 1’s complement (logical complement) of memory
not
M
Example: not
MEM ;
Result: MEM ← 〜MEM
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
mov
mov
not
a, 0x38 ;
mem, a ;
mem ;
// mem = 0x38
// mem = 0xC7
------------------------------------------------------------------------------------------------------------------------
Perform 2’s complement of ACC
neg
a
Example: neg
a;
Result: a ← 〒a
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
mov
neg
a, 0x38 ;
a ;
// ACC=0X38
// ACC=0XC8
------------------------------------------------------------------------------------------------------------------------
Perform 2’s complement of memory
neg
M
Example: neg
MEM;
Result: MEM ← 〒MEM
Affected flags: 『Y』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
mov
mov
not
a, 0x38 ;
mem, a ;
mem ;
// mem = 0x38
// mem = 0xC8
------------------------------------------------------------------------------------------------------------------------
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
7.5. Bit Operation Instructions
set0 IO.n
set1 IO.n
set0 M.n
set1 M.n
Set bit n of IO port to low
Example: set0 pa.5 ;
Result: set bit 5 of port A to low
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Set bit n of IO port to high
Example: set1 pb.5 ;
Result: set bit 5 of port B to high
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Set bit n of memory to low
Example: set0 MEM.5 ;
Result: set bit 5 of MEM to low
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Set bit n of memory to high
Example: set1 MEM.5 ;
Result: set bit 5 of MEM to high
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
7.6. Conditional Operation Instructions
ceqsn a, I
Compare ACC with immediate data and skip next instruction if both are equal.
Flag will be changed like as (a ← a - I)
Example: ceqsn
a, 0x55 ;
MEM ;
error ;
inc
goto
Result: If a=0x55, then “goto error”; otherwise, “inc MEM”.
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
Compare ACC with memory and skip next instruction if both are equal.
Flag will be changed like as (a ← a - M)
ceqsn a, M
Example: ceqsn
a, MEM;
Result: If a=MEM, skip next instruction
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
t0sn IO.n
t1sn IO.n
Check IO bit and skip next instruction if it’s low
Example: t0sn
pa.5;
Result: If bit 5 of port A is low, skip next instruction
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Check IO bit and skip next instruction if it’s high
Example: t1sn
pa.5 ;
Result: If bit 5 of port A is high, skip next instruction
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
t0sn M.n
t1sn M.n
Check memory bit and skip next instruction if it’s low
Example: t0sn MEM.5 ;
Result: If bit 5 of MEM is low, then skip next instruction
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Check memory bit and skip next instruction if it’s high
EX: t1sn MEM.5 ;
Result: If bit 5 of MEM is high, then skip next instruction
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Increment ACC and skip next instruction if ACC is zero
izsn
dzsn
izsn
dzsn
a
Example: izsn
Result:
a;
a
←
a + 1,skip next instruction if a = 0
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
a
Decrement ACC and skip next instruction if ACC is zero
Example: dzsn
Result:
a;
A
←
A - 1,skip next instruction if a = 0
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
M
Increment memory and skip next instruction if memory is zero
Example: izsn
Result: MEM
MEM;
MEM + 1, skip next instruction if MEM= 0
←
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
M
Decrement memory and skip next instruction if memory is zero
Example: dzsn
Result: MEM
Affected flags: 『Y』Z 『Y』C 『Y』AC 『Y』OV
MEM;
←
MEM - 1, skip next instruction if MEM = 0
7.7. System control Instructions
call
label
Function call, address can be full range address space
Example: call
function1;
pc + 1
Result: [sp]
←
pc
sp
←
←
function1
sp + 2
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
goto label
Go to specific address which can be full range address space
Example: goto
error;
Result: Go to error and execute program.
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Place immediate data to ACC, then return
Example: ret 0x55;
ret
I
Result:
A ← 55h
ret ;
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
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Page 48 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
ret
Return to program which had function call
Example: ret;
Result: sp ← sp - 2
pc ← [sp]
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
reti
Return to program that is interrupt service routine. After this command is executed, global
interrupt is enabled automatically.
Example: reti;
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
nop
No operation
Example: nop;
Result: nothing changed
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
pcadd
a
Next program counter is current program counter plus ACC.
Example: pcadd a;
Result: pc ← pc + a
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Application Example:
------------------------------------------------------------------------------------------------------------------------
…
mov
pcadd
goto
goto
goto
goto
…
a, 0x02 ;
a ;
// PC <- PC+2
// jump here
err1 ;
correct ;
err2 ;
err3 ;
correct:
// jump here
…
------------------------------------------------------------------------------------------------------------------------
Enable global interrupt enable
engint
disgint
Example: engint;
Result: Interrupt request can be sent to FPP0
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Disable global interrupt enable
Example: disgint ;
Result: Interrupt request is blocked from FPP0
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
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Page 49 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
stopsys
stopexe
System halt.
Example: stopsys;
Result: Stop the system clocks and halt the system
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
CPU halt. The oscillator module is still active to output clock, however, system clock is disabled
to save power.
Example: stopexe;
Result: Stop the system clocks and keep oscillator modules active.
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Reset the whole chip, its operation will be same as hardware reset.
Example: reset;
reset
Result: Reset the whole chip.
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
Reset Watchdog timer.
wdreset
Example: wdreset ;
Result: Reset Watchdog timer.
Affected flags: 『N』Z 『N』C 『N』AC 『N』OV
7.8. Summary of Instructions Execution Cycle
goto, call, idxm, pcadd, ret, reti
2T
2T
1T
1T
Condition is fulfilled
ceqsn, cneqsn,t0sn, t1sn, dzsn, izsn
Condition is not fulfilled
Others
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Page 50 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
7.9. Summary of affected flags by Instructions
Instruction
mov a, I
Z
-
C
-
AC OV Instruction
Z
-
C
-
AC OV Instruction
Z
Y
-
C
-
AC OV
-
-
-
-
mov M, a
mov IO, a
idxm a, index
pushaf
-
-
-
-
mov a, M
ldt16 word
idxm index, a
popaf
-
-
-
-
mov a, IO
stt16 word
Y
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
xch
M
-
-
-
-
-
-
-
-
Y
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
Y
-
add a, I
Y
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
Y
-
add a, M
addc M, a
sub a, I
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
-
Y
Y
Y
Y
Y
-
add M, a
addc a, M
addc
a
addc
M
sub a, M
sub M, a
subc a, M
subc M, a
subc
dec
src
a
subc
clear
M
M
inc
sr a
src
sl
M
M
a
sr
M
-
Y
Y
-
-
-
M
-
-
-
sl
a
-
-
-
slc
a
-
-
-
M
-
-
-
slc
and
M
-
-
-
swap
and
a
-
-
-
and
a, I
Y
Y
Y
Y
Y
-
-
-
a, M
Y
Y
-
-
-
M, a
Y
Y
Y
Y
-
-
-
-
or a, I
-
-
-
or a, M
-
-
-
or M, a
-
-
-
xor
xor
neg
a, I
-
-
-
xor
not
neg
IO, a
-
-
-
xor
not
a, M
-
-
-
M, a
a
-
-
-
a
Y
Y
-
-
-
-
M
-
-
-
-
-
-
M
-
-
-
set0 IO.n
set1 M.n
t0sn IO.n
t1sn M.n
-
-
-
set1 IO.n
ceqsn a, I
t1sn IO.n
-
-
-
set0 M.n
ceqsn a, M
t0sn M.n
-
-
-
-
-
-
-
Y
-
Y
-
Y
-
Y
-
Y
-
Y
-
Y
-
Y
-
-
-
-
-
-
-
-
-
izsn
dzsn
ret
a
Y
Y
-
Y
Y
-
Y
Y
-
Y
Y
-
dzsn
call
a
Y
-
Y
-
Y
-
Y
-
izsn
M
Y
-
Y
-
Y
-
Y
-
M
label
goto label
reti
I
ret
-
-
-
-
-
-
-
-
nop
-
-
-
-
pcadd
a
-
-
-
-
engint
-
-
-
-
disgint
reset
-
-
-
-
stopsys
wdreset
-
-
-
-
stopexe
-
-
-
-
-
-
-
-
-
-
-
7.10.BIT definition
(1) Bit defined: Only addressed at 0x00 ~ 0x0F
(2) WORD defined : Only addressed at 0x00 ~ 0x1E
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
8. Code Options
Option
Selection
Enable
Disable
4.0V
Description
OTP content is protected and program cannot be read
back
Security
OTP content is not protected so program can be read back
Select LVR = 4.0V
3.5V
Select LVR = 3.5V
3.0V
Select LVR = 3.0V
2.75V
2.5V
Select LVR = 2.75V
LVR
Select LVR = 2.5V
2.2V
Select LVR = 2.2V
2.0V
Select LVR = 2.0V
1.8V
Select LVR = 1.8V
Yes
reach normal operating voltage quickly within 20 mS
can’t reach normal operating voltage quickly within 20 mS
Under_20mS_VDD_OK
No
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Page 52 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
9. Special Notes
This chapter is to remind user who use PMC153/PMS153 series IC in order to avoid frequent errors upon
operation.
9.1. Warning
User must read all application notes of the IC by detail before using it. Please download the related
application notes from the following link:
http://www.padauk.com.tw/tw/technical/index.aspx
9.2. Using IC
9.2.1. IO pin usage and setting
(1)
IO pin as digital input
When IO is set as digital input, the level of Vih and Vil would changes with the voltage and
temperature. Please follow the minimum value of Vih and the maximum value of Vil.
The value of internal pull high resistor would also changes with the voltage, temperature and pin
voltage. It is not the fixed value.
(2) If IO pin is set to be digital input and enable wake-up function
Configure IO pin as input
Set corresponding bit to “1” in PADIER
For those IO pins of PA that are not used, PADIER[1:2] should be set low in order to prevent them
from leakage.
(3) PA5 is set to be output pin
PA5 can be set to be Open-Drain output pin only, output high requires adding pull-high resistor.
(4) PA5 is set to be PRSTB input pin
No internal pull-high resistor for PA5
Configure PA5 as input
Set CLKMD.0=1 to enable PA5 as PRSTB input pin
(5) PA5 is set to be input pin and to connect with a push button or a switch by a long wire
Needs to put a >10Ω resistor in between PA5 and the long wire
Avoid using PA5 as input in such application.
9.2.2. Interrupt
(1) When using the interrupt function, the procedure should be:
Step1: Set INTEN register, enable the interrupt control bit
Step2: Clear INTRQ register
Step3: In the main program, using ENGINT to enable CPU interrupt function
Step4: Wait for interrupt. When interrupt occurs, enter to Interrupt Service Routine
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
Step5: After the Interrupt Service Routine being executed, return to the main program
* Use DISGINT in the main program to disable all interrupts
* When interrupt service routine starts, use PUSHAF instruction to save ALU and FLAG
register. POPAF instruction is to restore ALU and FLAG register before RETI as below:
void Interrupt (void)
// Once the interrupt occurs, jump to interrupt service routine
// enter DISGINT status automatically, no more interrupt is
{
accepted
PUSHAF;
…
POPAF;
}
// RETI will be added automatically. After RETI being executed, ENGINT status
will be restored
(2) INTEN and INTRQ have no initial values. Please set required value before enabling interrupt function
9.2.3. System clock switching
System clock can be switched by CLKMD register. Please notice that, NEVER switch the system clock and
turn off the original clock source at the same time. For example: When switching from clock A to clock B,
please switch to clock B first; and after that turn off the clock A oscillator through CLKMD.
Example : Switch system clock from ILRC to IHRC/2
CLKMD
=
0x36;
0;
// switch to IHRC, ILRC can not be disabled here
CLKMD.2 =
// ILRC can be disabled at this time
ERROR: Switch ILRC to IHRC and turn off ILRC simultaneously
CLKMD 0x50; // MCU will hang
=
9.2.4. Power down mode, wakeup and watchdog
(1) Watchdog will be inactive once ILRC is disabled
(2) Please turn off watchdog before executing STOPSYS or STOPEXE instruction, otherwise IC will be reset
due to watchdog timeout. It is the same as in ICE emulation.
(3) The clock source of Watchdog is ILRC if the fast wakeup is disabled; otherwise, the clock source of
Watchdog will be the system clock and the reset time from watchdog becomes much shorter. It is
recommended to disable Watchdog and enable fast wakeup before entering STOPSYS mode. When the
system is waken up from power down mode, please firstly disable fast wakeup function, and then enable
Watchdog. It is to avoid system to be reset after being waken up.
(4) If enable Watchdog during programming and also wants the fast wakeup, the example as below:
CLKMD.En_WatchDog
=
0;
// disable watchdog timer
$ MISC
stopexe;
nop;
Fast_Wake_Up;
$ MISC
Wdreset;
WT_xx;
// Reset Watchdog time to normal wake-up
// enable watchdog timer
CLKMD.En_WatchDog
=
1;
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
9.2.5. TIMER time out
When select $ INTEGS BIT_R (default value) and T16M counter BIT8 to generate interrupt, if T16M
counts from 0, the first interrupt will occur when the counter reaches to 0x100 (BIT8 from 0 to 1) and the
second interrupt will occur when the counter reaches 0x300 (BIT8 from 0 to 1). Therefore, selecting BIT8 as
1 to generate interrupt means that the interrupt occurs every 512 counts. Please notice that if T16M counter
is restarted, the next interrupt will occur once Bit8 turns from 0 to 1.
If select $ INTEGS BIT_F(BIT triggers from 1 to 0) and T16M counter BIT8 to generate interrupt, the T16M
counter changes to an interrupt every 0x200/0x400/0x600/. Please pay attention to two differences with
setting INTEGS methods.
9.2.6. LVR
(1) VDD must reach or above 2.0V for successful power-on process; otherwise IC will be inactive.
(2) The setting of LVR (1.8V, 2.0V, 2.2V etc) will be valid just after successful power-on process.
(3) User can set EOSCR.0 as “1” to disable LVR. However, VDD must be kept as exceeding the lowest
working voltage of chip; Otherwise IC may work abnormally.
9.2.7. IHRC
(1) The IHRC frequency calibration is performed when IC is programmed by the writer.
(2) Because the characteristic of the Epoxy Molding Compound (EMC) would some degrees affects the IHRC
frequency (either for package or COB), if the calibration is done before molding process, the actual IHRC
frequency after molding may be deviated or becomes out of spec. Normally , the frequency is getting
slower a bit.
(3) It usually happens in COB package or Quick Turnover Programming (QTP). And PADAUK would not take
any responsibility for this situation.
(4) Users can make some compensatory adjustments according to their own experiences. For example, users
can set IHRC frequency to be 0.5% ~ 1% higher and aim to get better re-targeting after molding.
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PMC153/PMS153 Series
8-bit OTP Type IO Controller
9.2.8. Program writing
There are 8 pins for using the writer to program: PA0, PA3, PA4, PA5, PA6, PA7, VDD and GND.
Please use PDK3S-P-002 for program real chip and put the jumper connected to CN38(at the back for the
writer). Then for the SOP14/DIP14 packaged IC, please put the chip at the top of the textool; as for
SOP8/DIP8 package, just put the IC downward three spaces on the Textool. Other packages could be
programmed by connecting the signals correspondingly. All the signals of the left side of the jumpers are the
same and as the descriptions at the left bottom corner. They are VDD, PA0, PA3, PA4, PA5, PA6, PA7, and
GND).
If user use PDK5S-P-003 or above to program, please follow the instructions for connecting jumpers.
Special notes about voltage and current while Multi-Chip-Package(MCP) or On-Board Programming
(1) PA5 (VPP) may be higher than 11V.
(2)
VDD may be higher than 7V, and its maximum current may reach about 20mA.
(3) All other signal pins level (except GND) are the same as VDD.
User should confirm when using this product in MCP or On-Board Programming, the peripheral circuit or
components will not be destroyed or limit the above voltages.
Important Cautions:
You MUST follow the instructions on APN004 and APN011 for programming IC on the handler.
Connecting a 0.01uF capacitor between VDD and GND at the handler port to the IC is always good
for suppressing disturbance. But please DO NOT connect with >0.01uF capacitor, otherwise,
programming may be fail.
9.3. Using ICE
Please use PDK5S-I-S01/2(B) ICE to emulate PMC153/PMS153. Please note in the simulation:
(1) Fast Wakeup time is different from PDK5S-I-S01/2(B): 128 SYSCLK, PMC153/PMS153: refer 5.8.3.
(2) Watch dog time out period is different from PDK5S-I-S01/2(B):
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 56 of 57
PMC153/PMS153 Series
8-bit OTP Type IO Controller
WDT period
PMC153/PMS153
PDK5S-I-S01/2(B)
2048* TILRC
misc[1:0]=00
8K* TILRC
4096* TILRC
misc[1:0]=01
misc[1:0]=10
misc[1:0]=11
16K* TILRC
64K* TILRC
256K* TILRC
16384* TILRC
256* TILRC
©Copyright 2019, PADAUK Technology Co. Ltd
PDK-DS-PMX153-EN_V108 –Dec. 26, 2019
Page 57 of 57
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