Motorola MCU DG128 User Manual

CMD912x  
Development Board for Motorola 68HC912 MCU’s  
68HC912D60/ DG128/ DT128 and MC9S12DP256  
xiom  
anufacturing  
ä
ã 2000  
2813 Industrial Ln. · Garland, TX 75041 · (972) 926-9303 FAX (972) 926-6063  
·
GETTING STARTED  
The Axiom CMD912X single board computer is a fully assembled, fully functional development  
system for the Motorola 68HC912D60/ DG128/ DT128 and MC9S12DP256 microcontrollers,  
complete with wall plug power supply and serial cable. Support software for this development  
board is provided for Windows 95/98 and NT operating systems.  
Follow the steps in this section to get started quickly and verify everything is working correctly.  
Installing the Software  
1. Insert the Axiom 68HC12 support CD in your PC. If the setup program does not start, run  
the file called "SETUP.EXE" on the disk.  
2. Follow the instructions on screen to install the support software onto your PC.  
You should at minimum install the AxIDE for Windows software.  
3. The programming utility “AxIDE” requires you to specify your board. You should select  
"912-xxx" version of your development board.  
Board Startup  
Follow these steps to connect and power on the board for the default Monitor operation. This  
assumes you're using the provided AxIDE utility (installed in the previous section) or a similar  
communications terminal program on your PC. If you're using a different terminal program  
than the one provided, set it's parameters to 9600 baud, N,8,1.  
1. Set the CMD912x board CONFIG SWITCH as follows:  
1
2
3
4
5
ON ON OFF OFF OFF  
2. Set the PM12Dxx module MODE SWITCH as follows:  
Module  
PM12D60  
PM12DG128 ON ON  
PM12DT128  
PM12DP256  
1
2
3
4
x
5
x
ON ON  
OFF  
OFF  
OFF  
ON ON  
ON ON ON *1 OFF OFF  
Note 1: DP256 mask set 1K79X and earlier requires Expanded Wide Emulation Mode.  
3. Verify CMD912x board COM-SWITCH position 1 is ON.  
4. Connect one end of the supplied 9-pin serial cable to a free COM port on your PC.  
Connect the other end of the cable to the COM1 port on the CMD912X board.  
3
5. Apply power to the board by plugging in the power adapter that came with the system.  
6. If everything is working properly, you should see a message to “PRESS KEY TO START  
MONITOR…” in your terminal window. Press the ENTER key and you should see:  
Axiom MON12 - HC12 Monitor / Debugger  
> _  
7. Your board is now ready to use! If you do not see this message prompt, or if the text is  
garbage, see the TROUBLESHOOTING section at the end of this manual.  
Support Software  
There are many programs and documents on the included HC12 support CD you can use with  
the CMD912X board. You should install what you want from the main menu then browse the  
disk and copy what you like to your hard drive.  
At minimum, you should install the AxIDE program.  
This flash programming utility  
communicates with the board via its COM1 port and the supplied serial cable. This program  
also includes a simple terminal for interfacing with other programs running on the CMD912X  
and information from your own programs that send output to the serial port.  
Also on the disk are free assemblers, the GNU C/C++ compiler tools for HC12, example  
source code, and other useful software. The introductory tutorial in this manual uses the free  
AS12 assembler integrated into the AxIDE program. This is a simple assembler with limited  
capability. For a more powerful assembly tool, install the Motorola MCUez program from the  
CD. This will allow you to used PAGED memory in your application.  
Software Development  
Software development on the CMD912x can be performed using either the Mon12 monitor  
utility installed in EPROM (sockets U6/U7), a third party debugger (NoICE, CodeWarrior, etc.)  
or a Background Debug Module (BDM) connected to the PM12xx Module BDM PORT  
connector. Any of these tools can be used to assist in creating and debugging your program  
stored in RAM (see Memory Map).  
After satisfactory operation running under a debugger, your program can be written to Internal  
Flash Memory by changing the PM12xx Module MODE SWITCH settings and programming it  
using one of the included programming utilities. Your program may l then run automatically  
whenever the board is powered on or RESET is applied.  
Option switches on the board allow for easy transition from operating monitor or debugger and  
user code.  
4
TUTORIAL  
This section was written to help you get started developing software with the CMD912X board.  
Be sure to read the rest of this manual as well as the documentation on the disk if you need  
further information.  
The following sections take you through the complete development cycle of a simple "hello  
world" program, which sends the string "Hello World" to the serial port.  
Creating source code  
You can write source code for the CMD912X board using any language that compiles to  
Motorola 68HC12 instructions. Included on the software disk is a free Assembler.  
You can write your source code using any ASCII text editor. You can use the free EDIT or  
NOTEPAD programs that come with your computer. Once your source code is written and  
saved to a file, you can assemble or compile it to a Motorola S-Record (hex) format. This type  
of output file usually has a .MOT, .HEX or .S19 file extension and is in a format that can be  
read by the programming utilities and programmed into the CMD912X board.  
It's important to understand your development board's use of Memory and Addressing when  
writing source code so you can locate your code at valid addresses. For example, when in  
debug mode, you should put your program CODE in External RAM. In assembly language,  
you locate the code with ORG statements in your source code. Any lines following an ORG  
statement will begin at that ORG location, which is the first number following the word ORG,  
for example: ORG $4400. You must start your DATA (or variables) in a RAM location  
unused by your program, for example: ORG $4000.  
In “debug mode” you’ll be using a debugger utility (Mon12, NoICE, etc) which will handle both  
interrupts (reset, timers, etc) and the STACK. When finished debugging, you must add code  
to your application to handle the STACK and Interrupt vector initialization. Set the stack  
somewhere at the top of your available RAM, for example $3FFE, in assembly this would be  
LDS #$3FFE. Also define the RESET vector address, $FFFE, at the end of your program.  
For example:  
ORG $FFFE  
FDB START ; where START is the beginning label of your program  
A look at the example programs on the disk can make all of this clearer. If you're using a  
compiler instead of an assembler, consult the compiler documentation for methods used to  
locate your code, data and stack.  
5
Assembling source code  
An example program called “HELLO.ASM” is provided under the \EXAMPLES\912x directory  
of the CD and if you installed AxIDE, under that programs \EXAMPLEdirectory. You must use  
the example for the PM Module you have installed on the CMD912x board. The PM Label is  
located beside the microcontroller. For example:  
\EXAMPLE\HC12D60\HELLO.ASM Example program for the PM12D60  
\EXAMPLE\HC12D128\HELLO.ASM Example program for the PM12D128  
\EXAMPLE\HC12D256\HELLO.ASM Example program for the PM12D256  
You can assemble your source code using command line tools under a DOS prompt by typing:  
AS12 HELLO.ASM –LHELLO  
Most compilers and assemblers allow many command line options so using a MAKE utility or  
batch file is recommended if you use this method. Run AS12 without any arguments to see all  
the options, or see the AS12.TXT file on the disk.  
The programming utility AxIDE provided with this board contains a simple interface to this  
assembler. Use it by selecting "Build" from its menu. This will prompt you for the file to be  
assembled. NOTE: You must select your board from the pull down menu first, or it may not  
build correctly.  
DO NOT use long path names (> 8 characters). The free assembler is an old DOS tool that  
does not recognize them.  
If there are no errors in your source code, 2 output files will be created:  
HELLO.S19  
HELLO.LST  
a Motorola S-Record file that can be programmed into memory  
a common listing file which shows the relationship between source  
and output  
The listing file is especially helpful to look at when debugging your program. If your program  
has errors, they will be displayed and no output will be generated, otherwise the listing file will  
be displayed.  
If you prefer a windows integrated programming environment, try the Motorola MCU-EZ tools.  
Refer to the MCU-EZ documentation on the disk for more information.  
Also, a port for the free GNU C compiler and tools for the HC12 is available on the CD under  
\Shareware and also online at www.gnu-m68hc11.org.  
6
Running your application  
After creating a Motorola S-Record file you can "upload" it to the development board for a test  
run. The provided example “HELLO.ASM” was created to run from RAM so you can use the  
Mon12 Monitor to test it without programming it into Flash.  
If you haven’t done so already, verify that the CMD912X board is connected and operating  
properly by following the steps under “GETTING STARTED” until you see the Mon12 prompt,  
then follow these steps to run your program:  
1. Press and release the RESET button on the CMD912X board. You should see the PRESS  
ANY KEY message. Hit the return key ¿ to get the monitor prompt.  
2. Type LOAD ¿  
This will prepare Mon12 to receive a program.  
3. Select Upload and when prompted for a file name select your assembled program file in s-  
record format that was created in the previous section called: HELLO.S19  
Your program will be sent to the board thru the serial port.  
4. When finished loading you will see the > prompt again. Type GO 4400 ¿  
This tells Mon12 to execute the program at address $4400, which is the start of our test  
program.  
5. If everything is working properly you should see the message “Hello World” echoed back  
to your terminal screen. Press RESET to return to the monitor.  
6. If you do not get this message, see the TROUBLESHOOTING section in this manual  
You can modify the hello program to display other strings or do anything you want. The  
procedures for assembling your code, uploading it to the board and executing it remain the  
same. Mon12 has many features such as breakpoints, assembly/disassembly, memory dump  
and modify and program trace. Type HELP at the Mon12 prompt for a listing of commands or  
consult the Mon12 documentation on the disk for more information.  
For a more powerful debugger with many advanced features such as source level debugging,  
you can use the NoICE debugger software. A full featured demo version is provided on the  
CD, which you can use to get started. NOTE: To use this program instead of Mon12 you must  
simply move the CONFIG SWITCH position 3 ON, RESET the board, and run the NoICE  
software. See the help documentation in this program for more information.  
NoICE monitor is not installed on Monitor versions R2 and earlier.  
7
Programming Flash EEPROM  
After debugging, you can program your application into Flash Memory so it executes  
automatically when you apply power to the board as follows:  
1. Make a backup copy of HELLO.ASM then use a text editor to modify it.  
2. Change the ORG location for the program start to the internal flash if needed.  
3. Remove the comment ;character before one of the following lines to initialize the stack  
pointer which is necessary when running outside of a debugger:  
LDS  
LDS  
#$3FFE ; DG/DP128 or DP256 – initialize…  
#$7FE ; D60 - initialize the stack pointer  
4. Remove the comment ;character from before the following 2 lines at the end, to set the  
reset vector to go to the beginning of the program (the label START) when powered on:  
org $fffe  
fdb  
reset vector  
START  
5. Re-Assemble HELLO.ASM as described in the "Assembling Source Code" section.  
6. Select Program from the AxIDE menu and follow the message prompts. When prompted  
for a file name, enter the new HELLO.S19 file.  
7. Press the RESET button on the board before clicking OK. When prompted to Erase,  
choose Yes.  
8. When finished programming, REMOVE POWER then set the MODE SWITCH positions 1  
and 2 OFF. Note: turn position 3 off also for DP256 version.  
9. Re-Apply Power to the board. Your new program should start automatically and the “Hello  
World” prompt should be displayed in the terminal window.  
To return to the Mon12 monitor program, set the MODE SWITCH positions 1 and 2 back ON  
then press RESET. Note: MODE switch 3 also must be ON for DP256 1K79 and earlier mask  
sets.  
8
BDM OPERATION  
The CMD912X board will emulate supported HC12 device internal flash memory in external  
ram. This feature allows BDM (Background Debug Modules) such as the AX-BDM12 to load  
and control the execution of code being developed without the necessity of the internal flash  
memory being programmed many times during the development process. This feature  
improves updating time and allows the use of may software breakpoints instead of being  
limited to only 2 hardware breakpoints.  
Operation Notes for BDM use:  
1)  
CMD912x CONFIG SWITCH should be set 1 ON, 2 OFF, 3 OFF, and 4 ON. Position 5  
should be Off unless the DG/DT128 Fixed Page is desired to be emulated in ram.  
These settings provide external ram and PRU operation with the ECS enabled for  
Paging emulation.  
2)  
PM12xxx MODE SWITCH is usually set for positions 1 and 2 off to select Single Chip  
Mode. This setting forces the BDM Monitor in the HC12 active immediately after Reset  
with the BDM connected which is desired for most BDM pods. The BDM can then load  
a script to set the desired operating mode and configuration, see next note. The  
DP256 version should have Mode Switch position 3 ON for correct operation of the  
MODC select buffer during RESET.  
3)  
The BDM initialization of the HC12 should set the correct operating MODE (Expanded  
Wide for memory access) and enable port emulation for the PRU to operate. The EME,  
EMK, LSTRB, RW, IVIS, ROMEN and Stretch configuration bits should be set for  
proper memory map and PRU operation. The external RAM does not require any cycle  
stretch for accesses up to 25MHz E clock. The Axiom support CD contains sample  
set-up macros for the AX-BDM12.  
9
MEMORY MAPS  
Following is the memory map for the CMD912X development board and the various  
Microcontroller PM Modules that it supports. Consult your MCU technical reference manual  
on the CD for internal memory map details for the processor.  
PM12DP256 Memory Map  
FFFF  
Special (BDM) Expanded  
Wide Mode  
Expanded Wide Mode  
Single Chip Mode  
1 2 3  
CONFIG ON ON OFF  
MODE ON ON ON  
1 2 3  
CONFIG ON OFF  
MODE OFF OFF ON  
1 2 3 4  
CONFIG OFF OFF OFF OFF  
MODE OFF OFF OFF  
External EPROM  
(see BDM notes)  
U5/6 (Mon12)  
On-Chip Flash Memory  
C000  
BFFF  
Flash Page  
8000 – C000  
External RAM  
U3/4  
8000  
External RAM  
U3/4  
4000  
3FFF  
On-Chip RAM  
3E00 – 3FFF used by Mon12  
1000  
FFF  
On-Chip EEPROM  
Internal Registers  
800  
7FF  
See your MCU Technical Reference Manual  
000  
NOTE: the DP256 does not provide a Register Following Peripheral Area.  
10  
PM12DG128 / PM12DT128 Memory Map  
FFFF  
Special (BDM) Expanded  
Wide Mode  
Expanded Wide Mode  
Single Chip Mode  
1 2  
CONFIG ON ON  
MODE ON ON  
1 2  
CONFIG ON OFF  
MODE OFF OFF  
1 2 3 4  
CONFIG OFF OFF OFF OFF  
MODE OFF OFF  
External EPROM  
(see BDM notes)  
U5/6 (Mon12)  
On-Chip Flash Memory  
C000  
BFFF  
Flash Page  
8000 – C000  
External RAM  
U3/4  
8000  
External RAM  
U3/4  
4000  
3FFF  
On-Chip RAM  
3E00 – 3FFF used by Mon12  
2000  
1FFF  
Reserved  
1000  
FFF  
On-Chip EEPROM  
Peripheral Area  
800  
7FF  
Unused = 400-7BF  
LCD / CS7 = 7F0-7FF  
CS6 = 7E0-7EF  
CS5 = 7D0-7DF  
CS4 = 7C0-7CF  
CS3 = 7B0-7BF  
CS2 = 7A0-7AF  
CS1 = 790-79F  
CS0 = 780-78F  
400  
3FF  
Internal Registers  
See your MCU Technical Reference Manual  
000  
1. The Peripheral Area (A00-BFF) is set to Narrow (8-bit) data width by the debug utilities. If  
using this memory, you must also do this in your software when booting from flash as  
follows:  
MOVW #$0CF0,PEAR  
MOVB #$73,MISC  
; Flash on, p-sel stretch = 3  
11  
PM12D60 Memory Map  
FFFF  
Special (BDM) Expanded  
Wide Mode  
Expanded Wide Mode  
Single Chip Mode  
1 2  
CONFIG ON ON  
MODE ON ON  
1 2  
CONFIG ON OFF  
MODE OFF OFF  
1 2  
CONFIG OFF OFF  
MODE OFF OFF  
External EPROM  
U5/6 (Mon12)  
C000  
BFFF  
External RAM  
Internal Flash Memory  
U3/4  
External RAM  
On-Chip  
U3/4  
1000  
FFF  
HC12 Internal EEPROM On-Chip  
C00  
BFF  
Peripheral Area - see note 2 below  
Unused = A00-B7F  
LCD / CS7 = BF0-BFF  
CS6 = BE0-BEF  
CS5 = BD0-BDF  
CS4 = BC0-BCF  
CS3 = BB0-BBF  
CS2 = BA0-BAF  
CS1 = B90-B9F  
CS0 = B80-B8F  
A00  
9FF  
Internal Registers - see note 1 below  
See 68HC912D60 Technical Reference Manual  
800  
7FF  
Internal RAM On-Chip  
000  
2. The Internal Register base address is relocated from $000to $800on startup by the  
debug utilities (Mon12 and NoICE). To preserve this memory map, you must also do this  
in your software when booting from flash. To do this, load register $11with $08for  
example:  
MOVB #08,$11  
; post-reset location of INITRG  
3. The Peripheral Area (A00-BFF) is set to Narrow (8-bit) data width by the debug utilities. If  
using this memory, you must also do this in your software when booting from flash as  
follows:  
MOVW #$0CF0,PEAR  
MOVB #$73,MISC  
; Flash on, p-sel stretch = 3  
12  
OPTION SWITCHES  
CONFIG SWITCH  
The CMD912X board is shipped from the manufacturer  
with the following default CONFIG SWITCH settings:  
1
2
3
4
5
ON ON OFF OFF OFF  
The 5 position CONFIG SWITCH provides an easy method of configuring the CMD912X  
board memory operation. Following are the configuration switch descriptions:  
CONFIG  
OPERATION when in ON position  
SWITCH  
1
2
3
EXT – External Memory and PRU enable (1)  
MON – Monitor Memory enable (2)  
MON SEL - Select NOICE Debug kernel  
ECS Enable - Enable ECS (Emulation Chip Select) signal to ram for  
paging emulation on Devices larger than 60K  
FPAGE Enable - Enable DG/DT128 Fixed Page at $4000 hex  
4
5
(1)  
Enables memory bus operation for access to board memory and PRU. Expanded Wide  
bus mode must be enabled for proper operation.  
(2)  
Enables monitor EPROM’s in memory map at 0xC000 – FFFF hex if CONFIG SWITCH  
position 1 is also on. When in off position memory space is SRAM for BDM use.  
COM SWITCH  
The 6 position COM SWITCH on the CMD912x Board provides an easy method of connecting  
or isolating the HC12 SCI and CAN channel RXD pins from the provided on-board  
transceivers. The HC12 SCI channels are connected to RS232 transceivers and the first 4  
CAN channels are connected to 1M baud CAN transceivers. To apply the RXD pins on the  
channels for other user applications requires that the transceiver driver be removed from the  
HC12 pin. User may then apply signals to the respective pins at the MCU PORT connector  
without driver conflict. Please note that the on-board monitor(s) require HC12 SCI channel 0  
for user interface.  
COM  
HC12 Connection in the ON position  
SWITCH  
1
2
3
4
5
6
SCI0 RXD to COM1 RS232 Transceiver (1)  
SCI1 RXD to COM2 RS232 Transceiver  
CAN0 RXD to CAN1 Port Transceiver  
CAN1 RXD to CAN2 Port Transceiver  
CAN2 RXD to CAN3 Port Transceiver  
CAN3 RXD to CAN4 Port Transceiver  
(1)  
Must be ON if using on board Monitor firmware.  
13  
MODE SWITCH  
The 3 to 5 position MODE SWITCH on the PM12xxx Module provides an easy method of  
configuring the HC12 operating Mode and Options from RESET.  
NOTE: Expanded Narrow Mode is not available on this board, Expanded Wide  
operation is required due to the memory application and that any expanded bus  
operation requires both HC12 I/O ports A and B in any case.  
Following are the Mode Switch selections and descriptions:  
PM12D60  
Default: 1 and 2 ON, 3 - 5 OFF.  
MODE  
SWITCH  
SELECTION  
OPTION  
OFF POSITION  
ON POSITION  
1 and 2  
Operating Mode  
Port H pull device  
Port G pull device  
Oscillator Select  
Single Chip Mode  
Port H Pull-Down  
Port G Pull-Down  
Ext. 16Mhz Clock  
Expanded Wide Mode  
Port H Pull-Up  
Port G Pull-Up  
User applied crystal  
3
4
5
PM12DG128 / PM12DT128  
Default: 1 and 2 ON, 3 OFF  
MODE  
SWITCH  
1 and 2  
3
SELECTION  
OPTION  
Operating Mode  
Oscillator Select  
OFF POSITION  
ON POSITION  
Single Chip Mode  
Ext. 16Mhz Clock  
Expanded Wide Mode  
User applied crystal  
PM12DP256  
Default: 1 - 3 ON, 4 and 5 OFF  
MODE  
SWITCH  
SELECTION  
OPTION  
OFF POSITION  
ON POSITION  
1 and 2  
Operating Mode  
MODC Selection  
ROMON Select  
Oscillator Select  
Single Chip Mode  
Normal Modes  
Internal Flash ON  
Ext. 16Mhz Clock  
Expanded Wide Mode  
Special / Emulation Mode  
Internal Flash OFF  
3
4
5
User applied crystal  
14  
PORTS AND CONNECTORS  
PRU PORT  
The Port Replacement Unit (PRU) provides simulation of the HC12 bus and control ports A, B,  
E, and K so expanded memory can be used for single-chip application development. PRU  
operation is enabled with external memory by CONFIG Switch 1 ON. The PRU also provides  
control of the external memories and peripherals on the CMD912x board. Care should be  
taken not to violate PRU operation constraints or user code operation could be rendered  
inoperable until a RESET is performed.  
PRU Ports A, B, E, and K are simulated ports due to the different drive characteristics of the  
PRU logic device. Following are the characteristic differences between the HC12 and PRU  
ports:  
1) The PRU will drive ports to TTL levels with 24ma of source current. Greater than the  
HC12.  
2) The PRU provides pull-up resistance of 47K ohms to +5V is applied to all PRU ports. The  
HC12 allows this to be optioned on input ports.  
3) The PRU will only drive outputs high to +4V. The PRU port pull-up resistors raise the  
output level to +5V with minimal drive.  
4) PRU port inputs will indicate logic high if not driven due to the pull-up resistors.  
The PRU will provide HC12 internal resource memory mapping support with constraints. The  
user should be cautious to stay within the bounds of the constraints for proper operation of the  
board. PRU constraints:  
1) The HC12 R/W, LSTRB, and ECLK signals must be enabled for correct operation of the  
PRU.  
2) The HC12 MODE register must have the IVIS, EME, and EMK bits enabled for correct  
PRU operation.  
3) The IVIS bit in the HC12 MODE register must be enabled prior to any HC12 internal  
resource map changes from default locations.  
4) HC12 internal Ram block (INITRM register) cannot be moved above $4000 hex.  
5) HC12 internal Register block (INITRG register) cannot be moved above $8000 hex and is  
treated as a 2K byte memory space.  
6) HC12 internal EEprom block (INITEE register) is treated as a 4K Byte memory space.  
15  
PRU PORT CONNECTOR  
+5V  
XPB6  
XPB4  
XPB2  
XPB0  
XPA6  
XPA4  
XPA2  
XPA0  
XPE6  
XPE4  
XPE2  
PE0  
+5V  
1 2  
3 4  
5 6  
7 8  
Note: PE0 and PE1 are the same signals as the  
HC12 Port E.  
XPB7  
XPB5  
XPB3  
XPB1  
XPA7  
XPA5  
XPA3  
XPA1  
XPE7  
XPE5  
XPE3  
PE1  
9 10  
11 12  
13 14  
15 16  
17 18  
19 20  
21 22  
23 24  
25 26  
27 28  
29 30  
31 32  
33 34  
XPK4  
XPK2  
XPK0  
GND  
XPK7  
XPK5  
XPK3  
XPK1  
MCU_PORT 1  
+5V  
PP0  
GND  
PP1  
1 2  
The MCU_PORT1 provides access to the peripheral  
features and I/O lines of the HC12. Note:  
3 4  
PP2  
PP3  
5 6  
PP4  
PP5  
7 8  
PP6  
PX0  
PP7  
PX1  
9 10  
1) Not all I/O Ports are provided by all HC12 MCUs.  
11 12  
13 14  
15 16  
17 18  
19 20  
21 22  
23 24  
25 26  
27 28  
29 30  
31 32  
33 34  
35 36  
37 38  
39 40  
41 42  
43 44  
45 46  
47 48  
49 50  
PX2  
PX4  
PX6  
PS6  
PS4  
PS2  
PS0  
PT0  
PX3  
PX5  
PX7  
PS7  
PS5  
PS3  
PS1  
PT1  
PT3  
PT5  
PT7  
PG/PJ1  
PG/PJ3  
PG/PJ5  
PG/PJ7  
PH7  
2) The PX0 - PX7 port is the CAN channel port and  
additional I/O provided by the HC12 devices  
associated with that port. Some devices designate  
this port as PCAN, PIB, ect.  
3) The PG/PJx ports provide either the HC12 port G  
or HC12 port J depending on device installed.  
PT2  
PT4  
PT6  
PG/PJ0  
PG/PJ2  
PG/PJ4  
PG/PJ6  
PH6  
PH4  
PH2  
PH0  
PH5  
PH3  
PH1  
16  
MCU_PORT 2  
PK0  
PK2  
PK1  
1 2  
3 4  
The MCU_PORT 2 provides access to the  
Expanded Bus and I/O lines of the HC12. Note:  
PK3  
PK4  
PK5  
5 6  
PB0/D0  
PB2/D2  
PB4/D4  
PB6/D6  
PE0/XIRQ*  
PE6/MODB  
A14  
PK7/ECS  
PB1/D1  
PB3/D3  
PB5/D5  
PB7/D7  
PE3/LSTRB*  
PE5/MODA  
PE7  
7 8  
1) Not all I/O Ports are provided by all HC12  
MCUs.  
9 10  
11 12  
13 14  
15 16  
17 18  
19 20  
21 22  
23 24  
25 26  
2) The A14 - A19 address signals are provided  
by the PRU. The A16 - A19 signals are  
derived from the HC12 PK0 - PK5 signals  
when emulating internal flash paging  
operation.  
A15  
A16  
A17  
A18  
A19  
BUS_PORT  
GND  
D10  
D9  
D8  
A0  
A1  
A10  
/ OE  
A11  
A9  
D11  
D12  
D13  
D14  
D15  
A2  
A3  
A4  
A5  
A6  
1 2  
3 4  
5 6  
7 8  
The BUS_PORT supports off-board memory devices.  
D8 - D15 High Byte Data Bus in Wide Expanded Mode and  
Peripheral 8 bit data bus. Port A in Single Chip Mode.  
9 10  
11 12  
13 14  
15 16  
17 18  
19 20  
21 22  
23 24  
25 26  
27 28  
29 30  
31 32  
33 34  
35 36  
37 38  
39 40  
A0 – A13 Memory Addresses 0 to 13.  
/OE Memory Output Enable signal, Active Low. Valid with  
ECLK and R/W high.  
CS0 – CS7 Peripheral chip selects, 16 bytes each, see  
memory maps for location, 8 bit access (narrow bus).  
A8  
A7  
A12  
/ WE  
CS1  
CS3  
CS5  
+5V  
/RW  
E
A13  
CS0  
CS2  
CS4  
IRQ  
/P-SEL  
CS6  
CS7  
/ RESET  
/WE Memory Write Enable signal, Active Low. Valid with  
ECLK high and R/W low.  
IRQ HC12 IRQ (PE1) Interrupt Input.  
/RW HC12 Read/Write (PE2) control signal.  
E HC12 ECLK (PE4) bus clock signal. Stretch should be  
enabled in software.  
GND  
/P-SEL Selects Peripheral area, register following space, 8  
bits wide.  
/RESET HC12 active low RESET signal.  
17  
ANALOG PORT  
PAD0  
PAD1  
PAD2  
PAD3  
PAD4  
PAD5  
PAD6  
PAD7  
VRL0  
VRL1  
PAD8  
PAD9  
1 2  
3 4  
5 6  
The ANALOG port provides access to the Port AD0 and  
Port AD1 Analog-to-Digital input lines.  
PAD10  
PAD11  
PAD12  
PAD13  
PAD14  
PAD15  
VRH0  
PAD0 – PAD7 HC12 Port AD0-15 is an input port or A/D  
Converter inputs.  
7 8  
9 10  
11 12  
13 14  
15 16  
17 18  
19 20  
VRH / VRL HC12 A/D Converter Reference Pins. See  
A/D Reference Section. To provide an external reference  
voltage, R3,4,10 and 32 may need to be removed. See  
schematic.  
VRH1  
COM1  
1
The COM-1 port has a Female DB9 connector that interfaces to  
the HC12 internal SCI0 serial port. It uses a simple 2 wire  
asynchronous serial interface and is translated to RS232  
signaling levels.  
TXD0  
RXD0  
2 6  
3 7  
4 8  
5 9  
GND  
COM2  
1 2  
The COM-2 has a Female DB9 connector that interfaces to the  
HC12 internal SCI1 serial port. It uses a simple 2 wire  
asynchronous serial interface and is translated to RS232  
signaling levels.  
TXD1  
RXD1  
3 4  
5 6  
7 8  
JP1 may be used to reverse RS232 RX and TX signals to the  
COM2 connector.  
GND  
9 10  
NOTE:  
1) COM1 and 2 connector Pins 1, 4, and 6 are connected for default handshake standards.  
2) COM1 and 2 connector Pins 7 and 8 are connected for default handshake standards.  
3) Handshake pins are provided access pads behind the COM connectors for user  
application and can be easily isolated from each other on the bottom of the CMD912x  
board.  
4) SCI0:PS0/RXD0 and SCI1:PS2/RXD1 signals can be isolated from the RS232 transceiver  
by turning COM Switch positions 1 and 2 OFF respectfully.  
5) SCI0:PS1/TXD0 and SCI1:PS3/TXD1 signals can be isolated from the RS232 transceiver  
by removing resistors R10 and R11 respectfully from the bottom of the CMD912x board.  
18  
CAN1 - 4 PORTS  
These ports provide the CAN Bus input and output. Each port has a CAN Transceiver (Philips  
PCA82C250) capable of up to 1M Baud data rate. Not all HC12 devices support all of the  
channels, refer to the device data for capability. Each transceiver receive output has a COM  
Switch position associated with it. For proper operation the COM Switch should be turned on  
for each CAN channel that is used for CAN communication. The switch provides isolation for  
the HC12 I/O port if the CAN operation is not supported by the device or desired by the user.  
All HC12 I/O ports are available at the Port Headers for other I/O applications.  
CAN 1 - 4 Port Connections  
GND  
The CAN1-4 connector provides an interface to the MSCAN12  
channels 0 - 3 on the microcontroller.  
1
2
3
4
CAN-H  
CAN-L  
+5V  
CAN BUS TRANSMIT ENABLE  
Each CAN port transceiver transmit driver is enabled for maximum drive and minimum slew  
rate by default. The drive and slew rate may be adjusted by changing the value of RC10,  
RC20, RC30, or RC40 for each CAN 1 - 4 port respectfully (see PCA82C250 data sheet for  
more information). These 1206 size SMT resistors are located on the bottom of the CMD912x  
board near the respective CAN port.  
CAN Bus transceiver transmit enable control can be applied to each CAN 1 - 4 Port by the  
RS1 - 4 tie pads respectfully. The user should select an available HC12 I/O port to perform  
the transmit enable function and connect it from the MCU_PORTx pin to RSx pad as required.  
The RC10, RC20, RC30, or RC40 resistors must be removed from the respective CAN  
port to apply transmit enable control. The transmit enable signal to the CAN transceivers is  
active logic low.  
CAN BUS TERMINATION  
Each CAN port has a set of 1206 SMT size termination resistors on the bottom of the  
CMD912x board that are not installed at the factory. The termination resistors provide  
optional bias and termination impedance for the CAN bus connected to the CAN 1 - 4 ports.  
Type of wire media, data rate, length of wire, and number of CAN bus nodes can all effect the  
requirement or value of the termination for the CAN bus. User should refer to particular  
application for termination requirements.  
CAN-H Bias Resistors: RC11, RC21, RC31, and RC41 provide bias to ground potential for  
CAN 1- 4 ports respectfully.  
CAN-L Bias Resistors: RC13, RC23, RC33, and RC43 provide bias to +5V potential for CAN  
1- 4 ports respectfully.  
CAN Termination Resistors: RC12, RC22, RC32, and RC42 provide termination between  
CAN-H and CAN-L signals for CAN 1- 4 ports respectfully.  
19  
LCD_PORT  
The LCD_PORT interface is connected to the data bus and memory mapped into the Register  
Following memory area of the HC12. Note that the DP256 does not support the LCD Port due  
to no Register following area is available. Refer to the PM12xxx board memory map for LCd  
Port address location. For the standard display, the base address of the LCD Port is the  
Command register and the Base+1 address is the display Data register.  
The interface supports all OPTREXä DMC series displays in 8 bit bus mode with up to 80  
characters and provides the most common pinout for a dual row rear mounted display  
connector. Power, ground, and Vee are also available at this connector.  
+5V 2 1 GND  
A0 4 3 LCD-Vee  
LCD1 6 5 /RW  
D9 8 7 D8  
D11 10 9 D10  
D13 12 11 D12  
D15 14 13 D14  
Command Register: LCD PORT Base+0  
Data Register: LCD PORT Base +1  
LCD-Vee is supplied by U16 and is adjusted by the CONTRAST  
Potentiometer (adjustable resistor).  
See the file KLCD12Dx.ASM for an example program using this  
LCD connector.  
J3  
Additional lines can be used as enables for larger character  
panels and are mapped as:  
LCD3  
LCD2  
LCD4  
2
1
4
3
LCD2 = Base +$4 & $5  
LCD3 = Base +$8 & $9  
LCD4 = Base + $C & $D  
Note: These selects can also be used for peripheral controls.  
KEYPAD  
PH0  
PH1  
PH2  
PH3  
PH4  
PH5  
PH6  
PH7  
The KEYPAD connector is a passive 8-pin connector that can be used to  
connect a 4 x 4 matrix (16 key) keypad device. The connector is  
mapped to HC12 I/O port H. This interface is implemented as a software  
keyscan. Pins PH0-3 are used as column drivers which are active high  
outputs. Pins PH4-7 are used for row input and will read high when their  
row is high.  
1
2
3
4
5
6
7
8
See the file KLCD12Dx.ASM for an example program using this  
connector.  
20  
TB1 and J6 Power  
The TB1 and J6 connectors provide power input to the board or if J6 is used for input, TB1  
maybe used to source additional circuitry. The J6 power jack accepts a standard 2.0 ~ 2.1mm  
center barrel plug connector (positive voltage center) to provide the +VIN supply of +7 to +20  
VDC @ 300ma minimum (+9VDC nominal). TB1 provides access to the +VIN, GND (power  
ground), and +5V power supplies. The CMD912x power supply will provide 500ma of +5V for  
user application. +VIN input power should only be applied by J6 or TB1, not both or a supply  
conflict may occur and the CMD912x board could be damaged.  
BDM PORT  
The BDM port on the PM12xxx module is a 6 pin header compatible with the Motorola  
Background Debug Mode (BDM) Pod. This allows the connection of a background debugger  
for software development, programming and debugging in real-time without using HC12 I/O  
resources.  
BGND  
GND  
/RESET  
+5V  
See the HC12 Technical Reference Manual for complete  
documentation of the BDM.  
1 2  
3 4  
5 6  
A Background Debug Module is available from the manufacturer.  
21  
TROUBLESHOOTING  
The CMD912X board is fully tested and operational before shipping. If it fails to function  
properly, inspect the board for obvious physical damage first. Ensure that all IC devices in  
sockets are properly seated. Verify the communications setup as described under GETTING  
STARTED and see the Tips and Suggestions sections following for more information.  
The most common problems are improperly configured communications parameters, and  
attempting to use the wrong COM port.  
1. Verify that your communications port is working by substituting a known good serial  
device or by doing a loop back diagnostic.  
2. Verify the MODE, CONFIG, and COM switch settings are correct.  
3. Verify the power source. You should measure approximately 9 volts between the GND  
and +VIN connections on the TB1 power connector with the standard power supply  
provided.  
4. If no voltage is found, verify the wall plug connections to 115VAC outlet and the power  
connector.  
5. Verify the logic power source. You should measure +5 volts between the GND and +5V  
connections on the TB1 power connector. If the +VIN supply is good and this supply is  
not +5V, immediately disconnect power from the board. Contact [email protected] by  
email for instructions and provide board name and problem.  
6. Disconnect all external connections to the board except for COM1 to the PC and the wall  
plug.  
7. Make sure that the RESET line is not being held low.  
Check for this by measuring the RESET pin on P4 for +5V.  
8. Verify the presence of a 16MHz square wave at the EXTAL pin or 8MHz E clock signal if  
possible.  
9. Contact [email protected] by email for further assistance. Provide board name and  
describe problem.  
22  
Tips and Suggestions  
Following are a number of tips, suggestions and answers to common questions that will solve  
many problems users have with the CMD912X development system. You can download the  
latest software from the Support section of our web page at:  
Utilities  
·
·
·
If you’re trying to program memory or start the utilities, make sure all jumpers and  
CONFIG SWITCH settings are correct.  
Be certain that the data cable you’re using is bi-directional and is connected securely to  
both the PC and the board. Also, make sure you are using the correct serial port.  
Make sure the correct power is supplied to the board. You should only use a 9 volt,  
300 mA adapter or power supply. If you’re using a power strip, make sure it is turned  
on.  
·
Make sure you load your code to an address space that actually exists. See the  
Memory Map if you’re not sure. The CONFIG switch changes the memory map.  
·
·
If debugging under Mon12, make sure you're not over-writing RAM used by it.  
If you’re running in a multi-tasking environment (such as Windows™) close all  
programs in the background to be certain no serial conflict occurs.  
Code Execution  
·
·
Make sure the CONFIG SWITCH is set for the proper mode.  
CONFIG switch 3 must be ON to access the external bus (LCD display, etc) even if  
executing code from Internal Flash memory.  
·
·
·
·
Under Mon12, breakpoints may not be acknowledged if you use the CALL command.  
You should use one of the GO command instead.  
Check the HC12 reset vector located at FFFE - FFFF. These 2 bytes contain the  
address where execution will begin when the unit is powered on.  
When running your code stand-alone, you must initialize ALL peripherals used by the  
micro, including the Stack, Serial Port, Reset and Interrupt vectors etc.  
You must either reset the COP watchdog timer in the main loop of your code or disable  
it when not running under Mon12 or BDM mode. The micro enables this by default and  
if you don't handle it your code will reset every couple of ms.  
23  
TABLES  
TABLE 1. LCD Command Codes  
Command codes are used for LCD setup and control of character and cursor position. All  
command codes are written to LCD panel address $B5F0. The BUSY flag (bit 7) should be  
tested before any command updates to verify that any previous command is completed. A  
read of the command address $B5F0 will return the BUSY flag status and the current display  
character location address.  
Command  
Clear Display, Cursor to Home  
Cursor to Home  
Code  
$01  
$02  
Delay  
1.65ms  
1.65ms  
Entry Mode:  
$04  
$05  
$06  
$07  
Cursor Decrement, Shift off  
Cursor Decrement, Shift on  
Cursor Increment, Shift off  
Cursor Increment, Shift on  
Display Control:  
40us  
40us  
40us  
40us  
$08  
$0C  
$0E  
$0F  
Display, Cursor, and Cursor Blink off  
Display on, Cursor and Cursor Blink off  
Display and Cursor on, Cursor Blink off  
Display, Cursor, and Cursor Blink on  
Cursor / Display Shift: (nondestructive move)  
Cursor shift left  
40us  
40us  
40us  
40us  
$10  
$14  
$18  
$1C  
$3C  
$40-$7F  
$80- $FF  
40us  
40us  
40us  
40us  
40us  
40us  
40us  
Cursor shift right  
Display shift left  
Display shift right  
Display Function (default 2x40 size)  
Character Generator Ram Address set  
Display Ram Address and set cursor location  
TABLE 2. LCD Character Codes  
$20 Space $2D  
-
.
/
$3A  
$3B  
$3C  
$3D  
$3E  
$3F  
:
;
{
=
}
$47  
$48  
$49  
$4A  
$4B  
$4C  
$4D  
$4E  
$4F  
$50  
$51  
$52  
$53  
G
H
I
J
K
L
M
N
O
P
Q
R
S
$54  
$55  
$56  
$57  
$58  
$59  
$5A  
$5B  
T
U
V
W
X
Y
Z
[
$61  
$62  
$63  
$64  
$65  
$66  
$67  
$68  
a
b
c
d
e
f
g
h
i
$6E  
$6F  
$70  
$71  
$72  
$73  
$74  
$75  
$76  
$77  
$78  
$79  
$7A  
n
$7B  
$7C  
$7D  
$7E  
$7F  
{
|
}
>
<
$21  
$22  
$23  
$24  
$25  
$26  
$27  
$28  
$29  
$2A  
$2B  
$2C  
!
$2E  
$2F  
$30  
$31  
$32  
$33  
$34  
$35  
$36  
$37  
$38  
$39  
o
p
q
r
s
t
u
v
w
x
y
z
#
$
%
&
(
)
*
+
,
0
1
2
3
4
5
6
7
8
9
?
$40 Time  
$41  
$42  
$43  
$44  
$45  
$46  
A
B
C
D
E
F
$5C Yen $69  
$5D  
$5E  
$5F  
$60  
]
$6A  
$6B  
$6C  
$6D  
j
k
l
^
_
`
m
24  
TABLE 3. Mon12 Monitor Commands  
BF <StartAddress> <EndAddress>  
[<data>]  
Fill memory with data  
BR [<Address>]  
Set/Display user breakpoints  
BULK  
CALL [<Address>]  
G [<Address>]  
HELP  
LOAD [P]  
MD <StartAddress> [<EndAddress>]  
Erase entire on-chip EEPROM contents  
Call user subroutine at <Address>  
Begin/continue execution of user code  
Display the Mon12 command summary  
Load S-Records into memory, P = Paged S2  
Memory Display Bytes  
MM <StartAddress>  
Modify Memory Bytes  
<CR>  
</> or <=>  
<^> or <->  
<.>  
Examine/Modify next location  
Examine/Modify same location  
Examine/Modify previous location  
Exit Modify Memory command  
Move a block of memory  
MOVE <StartAddress> <EndAddress>  
<DestAddress>  
RD  
RM  
Display all CPU registers  
Modify CPU Register Contents  
Trace until address  
STOPAT <Address>  
T [<count>]  
Trace <count> instructions  
1. Mon12 uses internal RAM space from $600 - $7FF for the D60 and $3E00 - $3FFF for the  
DG128 and DP256. DO NOT use this space in your program if debugging under Mon12.  
2. Register space is located starting at $0000 for the DG128 and DP256, D60 is at $800.  
3. Mon12 will not trace into interrupts. To trace an interrupt service set a breakpoint in the  
service routine and then trace.  
25  
TABLE 4. I/O Signal Connection Reference  
J1/P1  
J2/P2  
PM12D60  
PM12DG/DT128  
PM12DP256  
CMD912x  
OTHER  
PA0 / D8  
PA1 / D9  
PA2 / D10  
PA3 / D11  
PA4 / D12  
PA5 / D13  
PA6 / D14  
PA7 / D15  
PB0 / D0  
PB1 / D1  
PB2 / D2  
PB3 / D3  
PB4 / D4  
PB5 / D5  
PB6 / D6  
PB7 / D7  
PE0 / XIRQ*  
PE1 / IRQ*  
PE2 / RW  
PE3 / LSTRB*  
PE4 / ECLK  
PE5 / MODA  
PE6 / MODB  
PE7 / DBE  
PG0  
PA0 / D8  
PA1 / D9  
PA2 / D10  
PA3 / D11  
PA4 / D12  
PA5 / D13  
PA6 / D14  
PA7 / D15  
PB0 / D0  
PB1 / D1  
PB2 / D2  
PB3 / D3  
PB4 / D4  
PB5 / D5  
PB6 / D6  
PB7 / D7  
PE0 / XIRQ*  
PE1 / IRQ*  
PE2 / RW  
PE3 / LSTRB*  
PE4 / ECLK  
PE5 / MODA  
PE6 / MODB  
PE7 / DBE  
PJ0  
PA0 / D8  
PA1 / D9  
PA2 / D10  
PA3 / D11  
PA4 / D12  
PA5 / D13  
PA6 / D14  
PA7 / D15  
PB0 / D0  
PB1 / D1  
PB2 / D2  
PB3 / D3  
PB4 / D4  
PB5 / D5  
PB6 / D6  
PB7 / D7  
PE0 / XIRQ*  
PE1 / IRQ*  
PE2 / RW  
PE3 / LSTRB*  
PE4 / ECLK  
PE5 / MODA  
PE6 / MODB  
PE7 /  
J2/P2 - 60  
J2/P2 - 59  
J2/P2 - 58  
J2/P2 - 57  
J2/P2 - 56  
J2/P2 - 55  
J2/P2 - 54  
J2/P2 - 53  
J1/P1 - 30  
J1/P1 - 29  
J1/P1 - 32  
J1/P1 - 31  
J1/P1 - 34  
J1/P1 - 33  
J1/P1 - 36  
J1/P1 - 35  
J1/P1 - 60  
J1/P1 - 59  
J1/P1 - 58  
J1/P1 - 57  
J1/P1 - 44  
J1/P1 - 43  
J1/P1 - 42  
J1/P1 - 41  
J1/P1 - 26  
J1/P1 - 25  
J1/P1 - 24  
J1/P1 - 23  
J1/P1 - 14  
J1/P1 - 13  
J1/P1 - 12  
J1/P1 - 11  
J1/P1 - 56  
J1/P1 - 55  
J1/P1 - 54  
J1/P1 - 53  
J1/P1 - 40  
J1/P1 - 39  
J1/P1 - 38  
J1/P1 - 37  
J1/P1 - 6  
BUS PORT - 7  
BUS PORT - 5  
BUS PORT - 3  
BUS PORT - 2  
BUS PORT - 4  
LCD PORT - 7  
LCD PORT - 8  
LCD PORT - 9  
LCD PORT - 10  
LCD PORT - 11  
LCD PORT - 12  
LCD PORT - 13  
LCD PORT - 14  
BUS PORT - 6  
BUS PORT - 8  
BUS PORT - 10  
MCU PORT2 - 7  
MCU PORT2 - 10  
MCU PORT2 - 9  
MCU PORT2 - 12  
MCU PORT2 - 11  
MCU PORT2 - 14  
MCU PORT2 - 13  
MCU PORT2 - 16  
MCU PORT2 - 15  
BUS PORT - 32  
BUS PORT - 35  
MCU PORT2 - 18  
BUS PORT - 37  
MCU PORT2 - 20  
MCU PORT2 - 17  
MCU PORT2 - 22  
MCU PORT1 - 35  
MCU PORT1 - 36  
MCU PORT1 - 37  
MCU PORT1 - 38  
MCU PORT1 - 39  
MCU PORT1 - 40  
MCU PORT1 - 41  
MCU PORT1 - 42  
MCU PORT1 - 49  
MCU PORT1 - 50  
MCU PORT1 - 47  
MCU PORT1 - 48  
MCU PORT1 - 45  
MCU PORT1 - 46  
MCU PORT1 - 43  
MCU PORT1 - 44  
MCU PORT2 - 1  
MCU PORT2 - 2  
MCU PORT2 - 3  
MCU PORT2 - 4  
MCU PORT2 - 5  
MCU PORT2 - 6  
MCU PORT2 - 8  
MCU PORT1 - 25  
MCU PORT1 - 26  
MCU PORT1 - 23  
MCU PORT1 - 24  
PRU PORT - 25  
PRU PORT - 26  
LCD PORT - 5  
PJ0  
PJ1  
PG1  
PG2  
PG3  
PG4  
PG5  
PG6  
PG7  
PH0  
PH1  
PH2  
PH3  
PH4  
PH5  
PH6  
PH7  
PJ1  
PJ2  
PJ3  
PJ4  
PJ5  
PJ6  
PJ7  
PH0  
PH1  
PH2  
PH3  
PH4  
PH5  
PH6  
PH7  
PK0  
PJ6  
PJ7  
PH0  
PH1  
PH2  
PH3  
PH4  
PH5  
PH6  
PH7  
PK0  
PK1  
PK2  
PK3  
PK4  
PK5  
KEYPAD - 1  
KEYPAD - 2  
KEYPAD - 3  
KEYPAD - 4  
KEYPAD - 5  
KEYPAD - 6  
KEYPAD - 7  
KEYPAD - 8  
PRU  
PK1  
PK2  
PK3  
J1/P1 - 5  
J1/P1 - 4  
J1/P1 - 3  
J1/P1 - 22  
J1/P1 - 21  
J2/P2 - 10  
J2/P2 - 30  
J2/P2 - 29  
J2/P2 - 28  
J2/P2 - 27  
PRU  
PRU  
PRU  
PRU  
PRU  
PRU  
COM 1  
COM 1  
PK7/ECS*  
PS0/RXD0  
PS1/TXD0  
PS2/RXD1  
PS3/TXD1  
PK7/ECS*  
PS0/RXD0  
PS1/TXD0  
PS2/RXD1  
PS3/TXD1  
PS0/RXD0  
PS1/TXD0  
PS2/RXD1  
PS3/TXD1  
COM 2  
COM 2  
26  
J1/P1  
J2/P2  
PM12D60  
PM12DG/DT128  
PM12DP256  
CMD912x  
OTHER  
PS4/MIOS  
PS5/MOIS  
PS6/SCK  
PS7/SS*  
PT0  
PS4/MIOS  
PS5/MOIS  
PS6/SCK  
PS7/SS*  
PT0  
PS4/MIOS  
PS5/MOIS  
PS6/SCK  
J2/P2 - 26  
J2/P2 - 25  
J2/P2 - 24  
J2/P2 - 23  
J1/P1 - 8  
J1/P1 - 7  
J1/P1 - 10  
J1/P1 - 9  
J1/P1 - 18  
J1/P1 - 17  
J1/P1 - 20  
J1/P1 - 19  
J2/P2 - 14  
J2/P2 - 13  
J2/P2 - 16  
J2/P2 - 15  
J2/P2 - 18  
J2/P2 - 17  
J2/P2 - 20  
J2/P2 - 19  
J2/P2 - 2  
J2/P2 - 1  
J2/P2 - 4  
J2/P2 - 3  
J2/P2 - 6  
J2/P2 - 5  
J2/P2 - 8  
J2/P2 - 7  
J1/P1 - 27  
J1/P1 - 47  
J2/P2 - 47  
J2/P2 - 45  
J2/P2 - 43  
J2/P2 - 41  
J2/P2 - 39  
J2/P2 - 37  
J2/P2 - 35  
J2/P2 - 33  
J2/P2 - 48  
J2/P2 - 46  
J2/P2 - 44  
J2/P2 - 42  
J2/P2 - 40  
J2/P2 - 38  
J2/P2 - 36  
J2/P2 - 34  
J2/P2 - 50  
J2/P2 - 49  
J2/P2 - 32  
J2/P2 - 31  
MCU PORT1 - 21  
MCU PORT1 - 22  
MCU PORT1 - 19  
MCU PORT1 - 20  
MCU PORT1 - 27  
MCU PORT1 - 28  
MCU PORT1 - 29  
MCU PORT1 - 30  
MCU PORT1 - 31  
MCU PORT1 - 32  
MCU PORT1 - 33  
MCU PORT1 - 34  
MCU PORT1 - 11  
MCU PORT1 - 12  
MCU PORT1 - 13  
MCU PORT1 - 14  
MCU PORT1 - 15  
MCU PORT1 - 16  
MCU PORT1 - 17  
MCU PORT1 - 18  
MCU PORT1 - 3  
MCU PORT1 - 4  
MCU PORT1 - 5  
MCU PORT1 - 6  
MCU PORT1 - 7  
MCU PORT1 - 8  
MCU PORT1 - 9  
MCU PORT1 - 10  
PS7/SS*  
PT0  
PT1  
PT2  
PT3  
PT4  
PT5  
PT6  
PT7  
PT1  
PT2  
PT3  
PT4  
PT5  
PT6  
PT7  
PT1  
PT2  
PT3  
PT4  
PT5  
PT6  
PT7  
RXCAN0  
TXCAN0  
PCAN2  
PCAN3  
PCAN4  
PCAN5  
PCAN6  
PCAN7  
PP0/PWM0  
PP1/PWM1  
PP2/PWM2  
PP3/PWM3  
RXCAN0  
TXCAN0  
RXCAN1  
TXCAN1  
PIB4  
PIB5  
PIB6  
PIB7  
PP0/PWM0  
PP1/PWM1  
PP2/PWM2  
PP3/PWM3  
PM0/RXCAN0  
PM1/TXCAN0  
PM2/RXCAN1  
PM3/TXCAN1  
PM4/RXCAN2  
PM5/TXCAN2  
PM6/RXCAN3  
PM7/TXCAN3  
PP0/PWM0  
PP1/PWM1  
PP2/PWM2  
PP3/PWM3  
PP4/PWM4  
PP5/PWM5  
PP6/PWM6  
PP7/PWM7  
BGND / MODC  
RESET*  
PAD0 / AN0  
PAD1 / AN1  
PAD2 / AN2  
PAD3 / AN3  
PAD4 / AN4  
PAD5 / AN5  
PAD6 / AN6  
PAD7 / AN7  
PAD8 / AN8  
PAD9 / AN9  
PAD10 / AN10  
PAD11 / AN11  
PAD12 / AN12  
PAD13 / AN13  
PAD14 / AN14  
PAD15 / AN15  
CAN 1  
CAN 1  
CAN 2  
CAN 2  
CAN 3  
CAN 3  
CAN 4  
CAN 4  
BGND  
RESET*  
BGND  
RESET*  
BDM PORT  
BDM PORT  
BUS PORT - 40  
ANALOG PORT - 1  
ANALOG PORT - 3  
ANALOG PORT - 5  
ANALOG PORT - 7  
ANALOG PORT - 9  
ANALOG PORT - 11  
ANALOG PORT - 13  
ANALOG PORT - 15  
ANALOG PORT - 2  
ANALOG PORT - 4  
ANALOG PORT - 6  
ANALOG PORT - 8  
ANALOG PORT - 10  
ANALOG PORT - 12  
ANALOG PORT - 14  
ANALOG PORT - 16  
ANALOG PORT - 18  
ANALOG PORT - 17  
ANALOG PORT - 20  
ANALOG PORT - 19  
PAD0 / AN0  
PAD1 / AN1  
PAD2 / AN2  
PAD3 / AN3  
PAD4 / AN4  
PAD5 / AN5  
PAD6 / AN6  
PAD7 / AN7  
PAD10 / AN10  
PAD11 / AN11  
PAD12 / AN12  
PAD13 / AN13  
PAD14 / AN14  
PAD15 / AN15  
PAD16 / AN16  
PAD17 / AN17  
VRH0  
PAD0 / AN0  
PAD1 / AN1  
PAD2 / AN2  
PAD3 / AN3  
PAD4 / AN4  
PAD5 / AN5  
PAD6 / AN6  
PAD7 / AN7  
PAD10 / AN10  
PAD11 / AN11  
PAD12 / AN12  
PAD13 / AN13  
PAD14 / AN14  
PAD15 / AN15  
PAD16 / AN16  
PAD17 / AN17  
VRH0  
VRL0  
VRH1  
VRL1  
VRL0  
VRH1  
VRL1  
VRH1  
VRL1  
27  

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