In-Circuit Simulator
User’s Manual
A G R E E M E N T
M68ICS08MR
N O N - D I S C L O S U R E
R E Q U I R E D
M68ICS08MRUM/D
User’s Manual
Important Notice to Users
While every effort has been made to ensure the accuracy of all information in
this document, Motorola assumes no liability to any party for any loss or
damage caused by errors or omissions or by statements of any kind in this
document, its updates, supplements, or special editions, whether such errors are
omissions or statements resulting from negligence, accident, or any other cause.
Motorola further assumes no liability arising out of the application or use of any
information, product, or system described herein: nor any liability for incidental
or consequential damages arising from the use of this document. Motorola
disclaims all warranties regarding the information contained herein, whether
expressed, implied, or statutory, including implied warranties of
merchantability or fitness for a particular purpose. Motorola makes no
representation that the interconnection of products in the manner described
herein will not infringe on existing or future patent rights, nor do the
descriptions contained herein imply the granting or license to make, use or sell
equipment constructed in accordance with this description.
Trademarks
This document includes these trademarks:
Motorola and the Motorola logo are registered trademarks
of Motorola, Inc.
Windows and Windows 95 are registered trademarks of Microsoft
Corporation in the U.S. and other countries.
Intel is a registered trademark of Intel Corporation.
Motorola, Inc., is an Equal Opportunity / Affirmative Action Employer.
© Motorola, Inc., 2000; All Rights Reserved
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User’s Manual — M68ICS08MR In-Circuit Simulator
Table of Contents
Section 1. General Information
1.1
Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
1.2
MRICS Components. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
1.2.1
M68ICS08MR Connector Components. . . . . . . . . . . . . . . . . . . . . 13
1.2.2
MRICS Interface Software. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
1.3
Hardware and Software Requirements . . . . . . . . . . . . . . . . . . . . . . . . 14
1.4
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1.5
About This Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1.6
Customer Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Section 2. Preparation and Installation
2.1
Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
2.2
Hardware Preparation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
2.2.1
MRICS Limitations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
2.2.2
Configuring MRICS Jumper Headers . . . . . . . . . . . . . . . . . . . . . . 18
2.2.3
Target Interface Connection Options . . . . . . . . . . . . . . . . . . . . . . . 25
2.2.4
Host Computer (PC) — MRICS Serial Interconnection (J12) . . . 34
2.2.5
J4 Pin Assingments; +5Vdc Power Connector . . . . . . . . . . . . . . . 34
2.3
Connecting the MRICS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
2.4
Connecting the MRICS to a Target System . . . . . . . . . . . . . . . . . . . . 36
2.5
Installing the Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
Section 3. Support Information
3.1
Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
3.2
MRICS Connector Signal Definitions . . . . . . . . . . . . . . . . . . . . . . . . 37
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3.3
Target-Cable Pin Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
3.4
Parts List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
3.5
MRICS Printed Circuit Board Layout and Schematic Diagrams . . . . 60
Section 4. Using the MON08 Interface
4.1
Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
4.2
Target System Header Placement . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
4.3
Target Requirements for Using MON08 . . . . . . . . . . . . . . . . . . . . . . 74
4.4
Connecting to the In-Circuit Simulator . . . . . . . . . . . . . . . . . . . . . . . 74
User’s Manual — Glossary
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List of Figures
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
2-9
2-10
2-11
2-12
2-13
2-14
2-15
2-16
2-17
. MR16/32 Clock Source Selection Jumper (W1) . . . . . . . . . . . . . . . 21
. Reset Source Selection Jumper (W2) . . . . . . . . . . . . . . . . . . . . . . . . 21
. MR16/32 I/O Baud Rate Selection Jumper (W3) . . . . . . . . . . . . . . . 22
. MCU Emulation Selection Jumper (W4) . . . . . . . . . . . . . . . . . . . . . 22
. MRICS XTAL Clock Enable Jumper (W5) . . . . . . . . . . . . . . . . . . . 23
. MR4/8 Clock Source Selection Jumper (W6) . . . . . . . . . . . . . . . . . 23
. Board Reset Selection Jumper (W7). . . . . . . . . . . . . . . . . . . . . . . . . 24
. J2 Pin Assignments; MR16/32 Target Interface. . . . . . . . . . . . . . . . 26
. J3 Pin Assignments; MR16/32 Target Interface. . . . . . . . . . . . . . . . 27
. J5 Pin Assignments; MR4/8 Target Interface. . . . . . . . . . . . . . . . . . 28
. J6 Pin Assignments; MR4/8 Target Interface. . . . . . . . . . . . . . . . . . 29
. J7 Pin Assignments; MR16/32 MON08 Cable Connectors. . . . . . . 30
. J8 Pin Assignments; MR4/8 MON08 Cable Connectors . . . . . . . . . 31
. J1 Pin Assignments; MR16/32 Target Connector . . . . . . . . . . . . . . 32
. J11 Pin Assignments; MR4/8 DIP Target Connector . . . . . . . . . . . . 33
. J12 Pin Assignments; RS232 Connector . . . . . . . . . . . . . . . . . . . . . 34
. J4 Pin Assignment; +5Vdc Power Connector. . . . . . . . . . . . . . . . . . 34
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List of Tables
Table
Title
Page
Table 1-1. M68ICS08MR Product Components . . . . . . . . . . . . . . . . . . . . . . 12
Table 1-2. Hardware Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Table 1-3. Software Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Table 1-4. M68ICS08MR Board Specifications. . . . . . . . . . . . . . . . . . . . . . . 15
Table 2-1. MRICS Jumper Header Description . . . . . . . . . . . . . . . . . . . . . . . 20
Table 2-2. Cable/Connector Options for MCUs . . . . . . . . . . . . . . . . . . . . . . . 25
Table 3-1. MR16/32 Target Connector J2 . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Table 3-2. MR16/32 Target Connector J3 . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
Table 3-3. MR4/8 Target Connector J5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Table 3-4. MR4/8 Target Connector J6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
Table 3-5. MR16/32 MON08 Connector J7 Pin Assignments . . . . . . . . . . . . 46
Table 3-6. MR4/8 MON08 Connector J8 Pin Assignments . . . . . . . . . . . . . . 47
Table 3-7. MR16/32 Target Connector J1 . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
Table 3-8. MR4/8 Target DIP Connector J11. . . . . . . . . . . . . . . . . . . . . . . . . 51
Table 3-9. Power Connector J4 Pin Assignments. . . . . . . . . . . . . . . . . . . . . . 52
Table 3-10. RS-232C Communication Connector J12 Pin Assignments . . . . 52
Table 3-11. Flex Target Cable (M68CBL05C) for QFP Target Head Adapter B53
Table 3-12. Flex Target Cable (M68CBL05C) for DIP Target Head Adapter A54
Table 3-13. Flex Target Cable (M68CBL05C) for QFP Target Head Adapter B55
Table 3-14. Flex Target Cable (M68CBL05C) for DIP/QFP Target Head Adapter B56
Table 3-15. Bill of Materials. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
Table 4-1. MR16/32 MON08 Target System Connector J7. . . . . . . . . . . . . . 72
Table 4-2. MR4/8 MON08 Target System Connector J8 . . . . . . . . . . . . . . . . 73
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Section 1. General Information
1.1 Introduction
This manual provides information about the Motorola M68ICS08MR
in-circuit simulator (MRICS).
The MRICS is a stand-alone development and debugging tool . It contains all of
the hardware and software needed to develop and simulate source code, and to
program this series of MCU devices:
•
MC68HC908MR4
•
MC68HC908MR8
•
MC68HC908MR32
The MRICS and it’s software comprise an editor, assembler, programmer,
simulator, and limited real-time input/output emulator for the MCUs. When
connected to a host PC (personal computer) and target hardware (your prototype
product), actual inputs and outputs of the target system may be used during code
simulation.
The MRICS can interface with any IBM Windows 95-based computer (or
later version) through connection of a single RS-232 serial port using a DB-9
serial cable.
Connection to the target system is accomplished by a ribbon cable, a Motorola
M6CLB05C flex cable, or a MONO8 cable. The ribbon cable or flex cable is
used when an MCU is resident on the MRICS for emulation or simulation, and
the MONO8 cable is used to debug or program a target system’s MCU, directly,
when the MCU resides on the target hardware.
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General Information
The MRICS is a low-cost development system that supports editing,
assembling, in-circuit simulation, in-circuit emulation, and FLASH memory
programming. Its features include:
•
Editing with WinIDE
•
Assembling with CASM08W
•
FLASH memory programming with PROG08SW
•
In-circuit and stand-alone simulation of MC68HC908MR MCUs with
ICS08MRW software, providing:
•
–
Simulation of all instructions, memory, and peripherals
–
Simulation of pin inputs from the target system
–
Installation of conditional breakpoints, script files, and logfiles
Limited real-time emulation and debugging with ICD08SW, including:
–
Loading code into RAM
–
Executing real-time in RAM or FLASH
–
Placing one hardware breakpoint in FLASH
–
Placing multiple breakpoints in RAM
•
On-line help documentation for all software
•
Software integrated into the WinIDE environment, allowing function
key access to all applications
•
MON08 emulation connection to the target system allowing:
•
–
In-circuit emulation (limited)
–
In-circuit programming
Four modes of operation:
–
Standalone — using the MRICS as a standalone system without a
target board
–
Simulation — using the MRICS as an in-circuit simulator/emulator
with a target cable
–
Evaluation - using the MRICS for real-time evaluation of the MCU
and to debug user developed hardware and software
–
Programming — using the MRICS as a programmer
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General Information
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General Information
Introduction
Functions of the MRICS vary depending upon which software you choose:
NOTE:
•
With the WinIDE, CASM08W, editor, simulator, and assembler
software - the function is as a limited real-time emulator.
•
With the PROG08SW software - the function is to program MCU
FLASH memory. (This function is not available on the MC68HC08MR4
MCU, which does not have FLASH). Only one part may be programmed
at a time. The MRICS also supports in-circuit programming of either
version of the part through either MON08 cable.
•
With the ICS08MRZ simulation software, the MCU provides the
required input/output information that lets the host computer simulate
code, performing all functions except for maintaining port values. (The
internal FLASH memory on the device is downloaded with a program
that generates the appropriate port values.) The ICS08MRZ software on
the host computer lets the host computer become a simulator.
•
With using the ICD08SZ debugging software, code can be run directly
out of the MCU’s internal FLASH at real-time speeds.
•
The MRICS board also provides +5 Vdc power, +8.6 Vdc power for the
VTST voltage required to enter monitor mode, either a 4.0000-MHz or
4.9152-MHz clock signal, and host PC RS-232 level translation, when it
is supplied an active DTR signal.
The simulation speed will be slower than this rate because the host computer is
the simulator.
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1.2 MRICS Components
The MRICS system includes the product components listed in Table 1-1.
Table 1-1. M68ICS08MR Product Components
Part Number
Description
ICS08MR
MRICS software development package
ICS08MRZ
MRICS simulator
ICD08SZ
MRICS debugger
MC68HC908MR32
MCU
MC68HC908MR8
MCU
M68CLB05C
Flex target cable
KRISTA 22-122
Serial cable
FRIWO 11.8999-P5
Power supply
01-RE91008WI
MON08 cable
M68DIP28S01C
28-pin SOIC adapter
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General Information
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MRICS Components
1.2.1 M68ICS08MR Connector Components
Table 1-2. Hardware Components
Components
XU1
XU2
XU4
XU3
J2, J3
J4
Description
Target sockets for the Motorola MC68HC908MR16/32 MCUs:
56-pin SDIP (dual-in-line package)
64-pin QFP (quad flat pack)
Target sockets for the Motorola MC68HC(9)08MR4/8 MCUs:
28-pin DIP (dual-in-line package)
32-pin QFP (quad flat pack)
Two 2-row × 20-pin, 0.1-inch spacing connectors connect the
MRICS to a target system using the M68CLB05C flex cable.
Connectors J2 and J3 are used when emulating
MC68HC908MR16/32 MCUs.
+5 Vdc input voltage (VDD)
J5, J6
Two 2-row × 20-pin, 0.1-inch spacing connectors connect the
MRICS to a target system using the M68CLB05C flex cable.
Connectors J5 and J6 are used when emulating
MC68HC(9)08MR4/8 MCUs.
J1
One 60-pin, 0.3-inch spacing connector connect the MRICS to
the target system using a ribbon cable. Connector J1 is used
when emulating a MC68HC908MR16/32 MCU.
J7, J8
Two 2-row × 8-pin, 0.1-inch spacing connectors connect
MON08 debug circuit to your remote target. Use connector J7
when emulating MC68HC908MR32/16 MCUs. Use connector
J8 when emulating MC68HC(9)08MR4/8 MCUs.
J9, J10
Two 3-pin, 0.1-inch spacing connectors connect the MRICS
clock circuit to your remote target. Connector J9 routes the
4.9152 MHz clock for the MC68HC908MR16/32 MCUs.
Connector J10 routes the 4.000 MHz clock for the
MC68HC(9)08MR4/8 MCUs.
J11
One 2-row × 14-pin, 0.3-inch spacing dual in-line package
(28-pin DIP) socket connects the MRICS to the target system,
using a ribbon cable, when emulating an MC68HC(9)08MR4/8
MCU.
J12
RS-232 connector interface to the host serial connector.
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General Information
1.2.2 MRICS Interface Software
Windows-optimized software components, Table 1-3, are referred to,
collectively, as " MRICS software" (part number ICS08MRZ). It is a product of
P&E Microcomputer Systems, Inc., and is included in the MRICS kit.
Table 1-3. Software Components
Components
Description
WINIDE.EXE
Integrated development environment (IDE) software
interface for editing and performing software or
in-circuit simulation
CASM08Z.EXE
CASM08Z command-line cross-assembler
ICS08MRZ.EXE
In-circuit/stand-alone simulator software for
MC68HC908MR MCUs
PROG08SZ.EXE
FLASH memory programming software
ICD08SZ.EXE
In-circuit debugging software for limited, real-time
emulation
1.3 Hardware and Software Requirements
The MRICS software requires an IBM-compatible host computer with this
minimum hardware and software configuration:
•
Windows 95 or later version operating system
•
Approximately 2 Mbytes of available random-access memory (RAM)
and 5 Mbytes of free disk space
•
A serial port for communications between the MRICS and the host
computer
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General Information
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General Information
Specifications
1.4 Specifications
Table 1-4. M68ICS08MR Board Specifications
Characteristic
Specification
Temperature:
Operating
Storage
0° to 40°C
–40° to +85°C
Relative humidity
0 to 95%, non-condensing
Power requirement
+5 Vdc, from included ac/dc adapter
Size
5" 8 "
1.5 About This Manual
The procedural instructions in this manual assume that the user is familiar with
the Windows interface and selection procedures.
1.6 Customer Support
To obtain information about technical support or ordering parts, call the
Motorola help desk at 800-521-6274.
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User’s Manual — M68ICS08MR In-Circuit Simulator
Section 2. Preparation and Installation
2.1 Introduction
This section provides information and instruction for configuring, installing,
and readying the MRICS for use.
2.2 Hardware Preparation
These paragraphs explain:
ESD CAUTION:
•
Limitations of the MRICS
•
Configuration of the MRICS
•
Installation of the MRICS
•
Connection of the MRICS to a target system
Ordinary amounts of static electricity from clothing or the work environment
can damage or degrade electronic devices and equipment. For example, the
electronic components installed on the printed circuit board are extremely
sensitive to electrostatic discharge (ESD). Wear a grounding wrist strap
whenever handling any printed circuit board. This strap provides a conductive
path for safely discharging static electricity to ground.
2.2.1 MRICS Limitations
This section describes system limitations of the MRICS.
2.2.1.1 Bus Frequency
The MRICS communicates using the MON08 features. On the MR16/32 only,
this forces the communication rate to fbus/256. The bus frequencies are limited
by standard baud rates allowed by the host software, or 9600 (and possibly
4800) baud for the MR16/32, and 9600 baud for the MR4/8.
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2.2.1.2 MR16/32 Port A0
On the MR16/32, port A0 is used for communications, so it is unavailable for
emulation.
2.2.1.3 MR4/8 Port B0 and Port B1
On the MR4/8, ports B0 and B1 are used for communications, so they are
unavailable for emulation.
2.2.1.4 Low Voltage Interrupt (LVI)
The LVI is disabled by default in monitor mode. It is enabled by a dummy write
to LVISR.
2.2.1.5 Internal Clock Generator (ICG)
The ICG is bypassed in monitor mode, so it is not available for use.
2.2.2 Configuring MRICS Jumper Headers
The MRICS supports four configuration options: standalone, simulation,
evaluation, and programming.
•
Standalone — ICS08MRZ.exe running on the host computer (the
MRICS is not connected.) Emulation of the M68HC(9)08MR MCU
CPU, registers, and I/O ports are done within the host computer
environment.
•
Simulation — Host computer connected to the MRICS via the RS-232
cable and ICS08MRZ.exe running on the host computer. This provides
access to the M68HC(9)08MR MCU CPU, internal registers, and I/O
ports.
•
Evaluation — Host computer connected to the MRICS and the MRICS
connected to the target system via the flex cable. This method provides
limited real-time evaluation of the MCU and debugging user developed
hardware and software.
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Hardware Preparation
•
Programming — Host computer connected to the MRICS, and the
MRICS connected to the target system via the MON08 cable. Use the
PROG08SZ.exe to program the MCU FLASH module. In the
programming mode there is limited evaluation (port A0 on the MR32 and
port B0 and port B1 on the MR4/8 are used for communications, so they
are unavailable for emulation).
Seven jumper headers on the MRICS are used to configure the hardware
options. Table 2-1 is a quick reference to these optional settings, and
subparagraphs 2.2.2.1 through 2.2.2.6 describe jumper header configuration in
greater detail.
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Table 2-1. MRICS Jumper Header Description
Jumper Header
Type
W1
MR16/32
Target clock
selection
Description
3
2
1
W2
3
Target
reset
selection
2
1
W3
I/O
Baud rate
selection:
MR16/32 only
1
W4
Serial
communication
selection
3
2
3
2
1
W5
1
XTAL
clock
enable
2
3
W6
MR4/8
target
clock
W7
MRICS
reset
clock
1
2
3
3
2
1
Jumper on pins 1 and 2 (factory default) — Connects the
MC68HC908MR16/32 clock to the target system via connectors J1 and
J2. This position is labeled I.
Jumper on pins 2 and 3 — Disconnects the MC68HC908MR16/32 clock
from the target system.
Jumper on pins 1 and 2 — The MC68HC908MR MCU RESET signal
initiates resets to the target system. This position is labeled I.
Jumper on pins 2 and 3 (factory default) — The target-system RESET
signal initiates resets to the MRICS on-board MC68HC908MR MCU.
This position is labeled O.
Jumper on pins 1 and 2 (factory default) — MR16/32 I/O baud rate is set to
4800. This position is labeled 4800.
Jumper on pins 2 and 3 — MR16/32 I/O baud rate is set to 9600. This
position is labeled 9600.
This jumper header does not affect the MR4/8, which operates at
9600 baud only
Jumper on pins 1 and 2 (factory default) — MC68HC908MR16/32 MCU is
installed. This position is labeled MR32/16.
Jumper on pins 2 and 3 — MC68HC(9)08MR4/8 MCU is installed. This
position is labeled MR8/4.
Jumper on pins 1 and 2 — MRICS XTAL clocks are disabled. Jumper
header W5 has a cut-trace short between pins 1 and 2 so no jumper is
required unless the cut-trace short is removed. This position is labeled O.
Jumper on pins 2 and 3 (factory default) — MRICS XTAL clocks are
enabled: 4.9152 MHz for the MC68HC908MR16/32 MCUs and
4.000 MHz for the MC68HC(9)08MR4/8 MCUs. This position is labeled I.
Jumper on pins 1 and 2 (factory default) — Connects the
MC68HC(9)08MR4/8 clock to the target system via connectors J6 and
J11. This position is labeled I.
Jumper on pins 2 and 3 — Disconnects the MC68HC(9)08MR4/8 clock from
the target system. This position is labeled O.
Jumper on pins 1 and 2 (factory default) — Reset clock set at 4.9152 MHz.
Use this setting when using the MC68HC908MR16/32 MCUs. This
position is labeled MR32/16.
Jumper on pins 2 and 3 — Reset clock set at 4.0000 MHz. Use this setting
when using the MC68HC(9)08MR4/8 MCUs. This position is labeled
MR8/4.
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Hardware Preparation
2.2.2.1 MR16/32 Clock Source Selection Jumper (W1)
Use jumper header W1 (Figure 2-1) to connect the MC68HC908MR16/32
clock to the target system clock. Install a jumper on pins 1 and 2 (factory
default) to drive the target system clock with the MC68HC908MR16/32 clock.
Install a jumper on pins 2 and 3 to isolate the MC68HC908MR16/32 clock from
the target system.
W1
3
2
1
Figure 2-1. MR16/32 Clock Source Selection Jumper (W1)
2.2.2.2 Reset Source Selection Jumper (W2)
Use jumper header W2 (Figure 2-2) to select the target system or the MCU as
the source for a system reset. Install a jumpert on jumper header pins 1 and 2
(factory default) to drive the MCU RESET signal to the target system. Install a
jumper on jumper header pins 2 and 3 to reset the MCU whenever the
target-system initiates a reset.
W2
1
2
3
Figure 2-2. Reset Source Selection Jumper (W2)
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Preparation and Installation
2.2.2.3 I/O Baud Rate Selection Jumper (W3) — MR16/32 Only
There are two sockets for clocks on the MRICS board, XY1 and XY2. Socket
XY1 is wired to drive the MR16/32 IC sockets and target connectors, and the
the clock is available for output on J10. Using the 4.9152-MHz clock as Y1
times the MR16/32 to communicate at 4800 or 9600 baud.
Use jumper W3 (Figure 2-3) to define the baud rate of the MR16/32. Install the
jumper in jumper position 1-2 (labeled 9600 baud) to communicate at 9600
baud if a 4.9152-MHz clock is installed as Y1. Place the jumper in the 2-3
position (labeled 4800 baud) to communicate at 4800 baud. If Y1 is not 4.9152
MHz, the baud rate will be scaled proportionally.
W3
1
2
3
Figure 2-3. MR16/32 I/O Baud Rate Selection Jumper (W3)
2.2.2.4 Serial Communication Selection Jumper (W4)
Install the jumper on jumper header W4 (Figure 2-4) pins 1 and 2 (factory
default) when an MC68HC908MR16/32 MCU is installed. Install the jumper on
pins 2 and 3 when an MC68HC(9)08MR4/8 MCU is installed.
W4
3
2
1
Figure 2-4. MCU Emulation Selection Jumper (W4)
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Preparation and Installation
Hardware Preparation
2.2.2.5 MRICS XTAL Clock Enable Jumper (W5)
Install a jumper on jumper header W5 (Figure 2-5) pins 1 and 2 to disable the
MRICS XTAL clock. Install a jumper on pins 2 and 3 (factory default) to enable
the MRICS XTAL clock. The clock is 4.9152 MHz for the
MC68HC908MR16/32 MCUs and 4.0000 MHz for the MC68HC(9)08MR4/8
MCUs.
W5
1
2
3
Figure 2-5. MRICS XTAL Clock Enable Jumper (W5)
2.2.2.6 MR4/8 Clock Source Selection Jumper (W6)
Use jumper header W6 (Figure 2-6) to connect the MC68HC(9)08MR4/8 clock
to the target system clock. Install a jumper on pins 1 and 2 (factory default) to
drive the target system clock with the MC68HC(9)08MR4/8 clock. Install a
jumper on pins 2 and 3 to isolate the MC68HC(9)08MR4/8 clock from the
target system.
W6
3
2
1
Figure 2-6. MR4/8 Clock Source Selection Jumper (W6)
M68ICS08MR In-Circuit Simulator
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Preparation and Installation
2.2.2.7 Board Reset Selection Jumper (W7)
When the power to the MCU is turned on, there is a delay of a few hundred
milliseconds during which the ICS_RST signal is held low (set by U11).
When ICS_RST goes high, the binary ripple counter (U10) begins counting
clock cycles. After 1024 clock cycles are counted, the DELAY_RESET and
DELAY_RESET_1 signals toggle and the counter stops counting. The delayed
reset signals are used to turn on communications to the MCU and to hold several
MCU pins in appropriate states to force monitor mode on power up.
Use jumper W7 (Figure 2-7) to set the ripple counter reset rate. Install the
jumper on jumper header pins 1 and 2 (factory default) to select the MR16/32
clock, which causes Y1 to drive the counter at the factory installed rate of
4.9152 MHz. Use this setting when using the MC68HC908MR16/32 MCUs.
Install the jumper on jumper header pins 2 and 3 to select the MR4/8 clock. This
sets Y2 to drive the counter at the factory installed rate of 4.0000 MHz. Use this
setting when using the MC68HC(9)08MR4/8 MCUs.
W7
3
2
1
Figure 2-7. Board Reset Selection Jumper (W7)
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MOTOROLA
Preparation and Installation
Hardware Preparation
2.2.3 Target Interface Connection Options
There are three ways to connect the MRICS simulator board to your target
system:
•
Flex cable — low-noise target interface connection
•
Ribbon cable — low-cost target interface connection
•
MON08 cable — target interface connection with MCU FLASH
programming and limited emulation
Below is a quick reference for defining the cable/connector setup to use with the
appropriate MCU version. Refer to 2.2.3.1 MR16/32 Target Interface
Connectors (J2 and J3) through 2.2.3.5 MR4/8 DIP Target Connector (J11).
Table 2-2. Cable/Connector Options for MCUs
Flex Cable
M68CLB05C
Ribbon Cable
MON08 Cable
MC68HC08MR4
J5 and J6
J11
J8
MC68HC908MR8
J5 and J6
J11
J8
MC68HC908MR16
J2 and J3
J1
J7
MC68HC908MR32
J2 and J3
J1
J7
MCU
2.2.3.1 MR16/32 Target Interface Connectors (J2 and J3)
Use connectors J2 (Figure 2-8), J3 (Figure 2-9), and Motorola’s M68CLB05C
flex cable, when emulating an MC68HC908MR16/32 MCU, to connect the
MRICS to the target system. Connectors J2 and J3 are 40-pin shrouded headers
(3M 2540-6002).
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Preparation and Installation
J2
MR32_PTB2
1
•
•
2
MR32_PTB3
MR32_PTB5
3
•
•
4
MR32_PTB6
PTC0
5
•
•
6
PTC1
Ground
7
•
•
8
No Connect
Ground
9
•
•
10
MR32_PTA7
MR32_PTA3
11
•
•
12
MR32_PTA4
TGT_PTA0
13
•
•
14
Ground
TGT_CLK
15
•
•
16
No Connect
TGT_RST
17
•
•
18
TGT_IRQ
PTF3
19
•
•
20
PTF2
PTF0
21
•
•
22
Ground
PTE6
23
•
•
24
PTE5
PTE3
25
•
•
26
PTE2
Ground
27
•
•
28
MR32_PWM6
MR32_PWM4
29
•
•
30
MR32_PWM3
PTD6
31
•
•
32
Ground
PTD2
33
•
•
34
PTD3
PTD1
35
•
•
36
No Connect
PTC5
37
•
•
38
Ground
TGT_PTC3
39
•
•
40
Ground
Figure 2-8. J2 Pin Assignments; MR16/32 Target Interface
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Hardware Preparation
J3
Ground
1
•
•
2
MR32_PTB4
MR32_PTB7
3
•
•
4
Ground
No Connect
5
•
•
6
No Connect
MR32_PTB0
7
•
•
8
MR32_PTB1
MR32_PTA5
9
•
•
10
MR32_PTA6
MR32_PTA1
11
•
•
12
MR32_PTA2
No Connect
13
•
•
14
No Connect
No Connect
15
•
•
16
No Connect
PTF5
17
•
•
18
PTF4
Ground
19
•
•
20
PTF1
No Connect
21
•
•
22
PTE7
PTE4
23
•
•
24
Ground
PTE1
25
•
•
26
PTE0
MR32_PWM5
27
•
•
28
No Connect
MR32_PWM2
29
•
•
30
MR32_PWM1
PTD4
31
•
•
32
PTD5
No Connect
33
•
•
34
No Connect
PTC6
35
•
•
36
PTD0
TGT_PTC4
37
•
•
38
Ground
TGT_PTC2
39
•
•
40
Ground
Figure 2-9. J3 Pin Assignments; MR16/32 Target Interface
M68ICS08MR In-Circuit Simulator
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Preparation and Installation
2.2.3.2 MR4/8 Target Interface Connectors (J5 and J6)
Use connectors J5 (Figure 2-10), J6, (Figure 2-11), and Motorola’s
M68CLB05C flex cable to connect the MRICS to the target system when
emulating an MC68HC(9)08MR4/8 MCU. Connectors J5 and J6 are 40-pin
shrouded headers (3M 2540-6002).
J5
No Connect
1
•
•
2
MR4_PTA1
MR4_PTA6
3
•
•
4
No Connect
MR4_PTB1
5
•
•
6
MR4_PTB2
No Connect
7
•
•
8
No Connect
Ground
9
•
•
10
No Connect
MR4_PTA2
11
•
•
12
No Connect
No Connect
13
•
•
14
Ground
MR4_PWM3
15
•
•
16
MR4_PWM4
MR4_PTC0
17
•
•
18
MR4_PTB0
MR4_PTC1
19
•
•
20
No Connect
No Connect
21
•
•
22
No Connect
MR4_PTB5
23
•
•
24
No Connect
MR4_PTA0
25
•
•
26
No Connect
Ground
27
•
•
28
No Connect
No Connect
29
•
•
30
No Connect
No Connect
31
•
•
32
Ground
No Connect
33
•
•
34
TGT_IRQ
No Connect
35
•
•
36
Ground
No Connect
37
•
•
38
Ground
No Connect
39
•
•
40
Ground
Figure 2-10. J5 Pin Assignments; MR4/8 Target Interface
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Hardware Preparation
J6
Ground
1
•
•
2
MR4_PTA4
MR4_PTA5
3
•
•
4
Ground
MR4_PTB3
5
•
•
6
MR4_PTB4
No Connect
7
•
•
8
No Connect
MR4_PTA3
9
•
•
10
No Connect
No Connect
11
•
•
12
No Connect
MR4_PWM1
13
•
•
14
MR4_PWM2
MR4_PWM5
15
•
•
16
MR4_PWM6
No Connect
17
•
•
18
No Connect
Ground
19
•
•
20
No Connect
No Connect
21
•
•
22
No Connect
MR4_PTB6
23
•
•
24
Ground
No Connect
25
•
•
26
No Connect
No Connect
27
•
•
28
No Connect
No Connect
29
•
•
30
No Connect
No Connect
31
•
•
32
No Connect
No Connect
33
•
•
34
MR8/4_TGT_CLK
No Connect
35
•
•
36
TGT_RST
No Connect
37
•
•
38
Ground
No Connect
39
•
•
40
Ground
Figure 2-11. J6 Pin Assignments; MR4/8 Target Interface
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Preparation and Installation
2.2.3.3 MON08 Connectors (J7 and J8)
Use connectors J7 (Figure 2-12), J8 (Figure 2-13), and the provided MON08
cable to connect the MRICS board to the target system. Use connector J7 when
emulating an MC68HC908MR16/32 MCU and J8 when emulating an
MC68HC(9)08MR4/8 MCU. Refer to Section 4. Using the MON08 Interface
for detailed information for using the MON08 interface.
J7
RST_OUT
1
•
•
2
Ground
RST_IN
3
•
•
4
RST
TGT_IRQ
5
•
•
6
IRQ
TGT_PTA0
7
•
•
8
MR32_PTA0
TGT_PTC2
9
•
•
10
PTC2
TGT_PTC3
11
•
•
12
PTC3
TGT_PTC4
13
•
•
14
PTC4
No Connect
15
•
•
16
No Connect
Figure 2-12. J7 Pin Assignments; MR16/32 MON08 Cable
Connectors
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Preparation and Installation
Hardware Preparation
J8
Ground
1
•
•
2
No Connect
MR4_PTB0
3
•
•
4
TGT_MR4_PTB0
MR4_PTB1
5
•
•
6
TGT_MR4_PTB1
IRQ
7
•
•
8
TGT_IRQ
RST
9
•
•
10
RST_IN
No Connect
11
•
•
12
No Connect
No Connect
13
•
•
14
No Connect
No Connect
15
•
•
16
No Connect
Figure 2-13. J8 Pin Assignments; MR4/8 MON08 Cable Connectors
2.2.3.4 MR16/32 Target Connector (J1)
Use connector J1 (Figure 2-14) and the provided 60-pin ribbon cable to connect
the MRICS to the target system when emulating an MC68HC908MR16/32
MCU. shows the interface connector.
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Preparation and Installation
J1
MR32_PTA2
1
MR32_PTA3
3
MR32_PTA4
5
MR32_PTA5
7
MR32_PTA6
9
MR32_PTA7
11
MR32_PTB0
13
MR32_PTB1
15
MR32_PTB2
17
MR32_PTB3
19
MR32_PTB4
21
MR32_PTB5
23
MR32_PTB6
25
MR32_PTB7
27
No Connect
29
No Connect
31
Ground
33
No Connect
35
PTC2
37
PTC3
39
PTC4
41
PTC5
43
PTC6
45
PTD0
47
PTD1
49
PTD2
51
PTD3
53
PTD4
55
Ground
57
Ground
59
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
2
MR32_PTA1
4
MR32_PTA0
6
Ground
8
No Connect
10
TGT_CLK
12
No Connect
14
No Connect
16
TGT-RST
18
TGT_IRQ
20
PTF5
22
PTF4
24
Ground
26
No Connect
28
PTE7
30
PTE6
32
PTE5
34
PTE4
36
PTE3
38
No Connect
40
MR32_PWM6
42
MR32_PWM5
44
Ground
46
MR32_PWM4
48
MR32_PWM3
50
MR32_PWM2
52
MR32_PWM1
54
PTD6
56
PTD5
58
Ground
60
Ground
Figure 2-14. J1 Pin Assignments; MR16/32 Target Connector
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Preparation and Installation
Hardware Preparation
2.2.3.5 MR4/8 DIP Target Connector (J11)
Use connector J11 (Figure 2-15) and the provided 28-pin ribbon cable to
connect the MRICS to the target system when emulating an
MC68HC(9)08MR4/8 MCU.
J11
No Connect
1
•
•
28
MR4_PTA3
TGT_RST
2
•
•
27
MR4_PTA2
No Connect
3
•
•
26
MR4_PTA1
Ground
4
•
•
25
MR4_PTA0
No Connect
5
•
•
24
MR4_PTB6
MR8/4_TGT_CLK
6
•
•
23
MR4_PTB5
No Connect
7
•
•
22
Ground
TGT_IRQ
8
•
•
21
No Connect
MR4_PWM1
9
•
•
20
MR4_PTB4
MR4_PWM2
10
•
•
19
MR4_PTB3
MR4_PWM3
11
•
•
18
MR4_PTB2
MR4_PWM4
12
•
•
17
MR4_PTB1
MR4_PWM5
13
•
•
16
MR4_PTB0
MR4_PWM6
14
•
•
15
MR4_PTC0
Figure 2-15. J11 Pin Assignments; MR4/8 DIP Target Connector
M68ICS08MR In-Circuit Simulator
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Preparation and Installation
2.2.4 Host Computer (PC) — MRICS Serial Interconnection (J12)
Communication with the MRICS requires an RS-232C compatible host
computer connected to the MRICS I/O port J12 (Figure 2-16) . This cable
assembly is supplied with your MRICS kit and is a DE9-male-to-female, 6-ft
(2-m) long serial cable. Connect one end of this cable to your host PC and the
other end to connector J12 on the MRICS board.
DCD 1
RXD 2
6 DSR
7 RTS
TXD 3
8 CTS
DTR 4
9 NC
GND 5
Figure 2-16. J12 Pin Assignments; RS232 Connector
2.2.5 J4 Pin Assingments; +5Vdc Power Connector
Connect +5-Vdc power directly to the MRICS via connector J4 (Figure 2-17)
using the provided power supply.
+5 Vdc
GND
Figure 2-17. J4 Pin Assignment; +5Vdc Power Connector
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M68ICS08MR In-Circuit Simulator
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Preparation and Installation
Connecting the MRICS
2.3 Connecting the MRICS
The following steps provide instructions for connecting the MRICS to the host
PC and power connection.
ESD CAUTION:
Ordinary amounts of static electricity from clothing or the work environment
can damage or degrade electronic devices and equipment. For example, the
electronic components installed on the printed circuit board are extremely
sensitive to electrostatic discharge (ESD). Wear a grounding wrist strap
whenever handling any printed circuit board. This strap provides a conductive
path for safely discharging static electricity to ground.
a. Configure the jumpers W-1 through W-7, on the MRICS, for your
application.
b. Install an MCU into the appropriate socket, for your application, onto the
MRICS board.
–
56-pin SDIP MC68HC908MR16/32 to XU1
–
28-pin DIP MC68HC(9)08MR4/8 to XU4
–
64-pin QFP MC68HC908MR16/32 to XU2
–
32-pin QFP MC68HC(9)08MR4/8 to XU3
Note: Observe the pin 1 orientation with the silkscreened dot. The top (label
side) of the MCU package must be visible when looking at the component side
of the board.
c. Plug the serial cable into J12 on the MRICS .
d. Plug the serial cable into the COM port on the host PC.
NOTE:
Steps e. through g. should not be completed until all connections to the target
are completed (Paragraph 2.4).
e. Connect the power cable to J4 on the MRICS board.
f. Plug the power cable into an ac power outlet, using one of the country-specific
adapters.
g. The MRICS power LED lights.
M68ICS08MR In-Circuit Simulator
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Preparation and Installation
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Preparation and Installation
2.4 Connecting the MRICS to a Target System
Connect the MRICS to the target system using one of these methods:
•
Emulating using a flex cable
When emulating an MC68HC908MR16/32 MCU, connect the 80-pin
M68CLB05C flex cable (provided with the kit) to the connectors labeled
J2 and J3 on the simulator board. (Use the same cable when emulating an
MC68HC(9)08MR4/8 MCU, but connect it to J5 and J6 on the MRICS
board.) Attach the other end of the cable to the appropriate connector on
the target system. Target head adapters are available for the 56-pin SDIP,
28-pin DIP, 32-pin QFP, and 64-pin QFP versions of the MCU.
•
Emulating using a ribbon cable
When emulating an MC68HC908MR16/32 MCU connect a 60-pin flat
ribbon cable to connector J1 on the simulator board. Attach the other end
of the cable to the appropriate connector on the target system.When
emulating an MC68HC(9)08MR4/8 MCU connect a 28-pin DIP cable to
connector J11 on the simulator board. Attach the other end of the cable
to the appropriate connector on the target system.
• Using a MON08 cable to debug the target system.
Note: An MCU must be installed in the target system. No MCU should on the
MRICS.
Connect the MON08 debug interface cable to the appropriate MON08
debug interface connector (J7 for the MR 16/32 or J8 tor the MR 4/8) for
communication with the target system’s MCU.
Note: For more detailed information on the MONO8, refer to Section 3 of this
manual.
2.5 Installing the Software
For instructions for installing the ICS08 software, refer to P&E Microcomputer
Systems, Inc., M68ICS08 68HC08 In-Circuit Simulator Operator’s Manual,
Motorola document order number M68ICS08OM/D.
User’s Manual
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M68ICS08MR In-Circuit Simulator
Preparation and Installation
MOTOROLA
User’s Manual — M68ICS08MR In-Circuit Simulator
Section 3. Support Information
3.1 Introduction
This section includes data and information that can be useful in the design,
installation, and operation of your application.
3.2 MRICS Connector Signal Definitions
The tables in this section detail the pin assignments for the connectors on the
M68ICS08MR board.
NOTE:
The signal descriptions in the following tables are for quick reference only. The
MC68HC908MR32 User’s Manual, MC68HC908MR32/D, contains a complete
description of the MC68HC908MR32 MCU signals.
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Support Information
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Support Information
Table 3-1. MR16/32 Target Connector J2
Pin
No.
Schematic NET
Direction
1
MR32_PTB2
Bidirectional
Port B I/O – bit 2
2
MR32_PTB3
Bidirectional
Port B I/O – bit 3
3
MR32_PTB5
Bidirectional
Port B I/O – bit 5
4
MR32_PTB6
Bidirectional
Port B I/O – bit 6
5
PTC0
Bidirectional
Port C I/O – bit 0
6
PTC1
Bidirectional
Port C I/O – bit 1
7
GND
Ground
8
NC
9
GND
Ground
10
MR32_PTA7
Bidirectional
Port A I/O – bit 7
11
MR32_PTA3
Bidirectional
Port A I/O – bit 3
12
MR32_PTA4
Bidirectional
Port A I/O – bit 4
13
TGT_PTA0
Bidirectional
Port A I/O – bit 0
14
GND
Ground
MCU ground
15
TGT_CLK
In
Target clock
16
NC
17
TGT_RST
In or out
18
TGT_IRQ
In
External interrupt
19
PTF3
Bidirectional
Port F I/O – bit 3
20
PTF2
Bidirectional
Port F I/O – bit 2
21
PTF0
Bidirectional
Port F I/O – bit 0
22
GND
Ground
23
PTE6
Bidirectional
Port E I/O – bit 6
24
PTE5
Bidirectional
Port E I/O – bit 5
25
PTE3
Bidirectional
Port E I/O – bit 3
26
PTE2
Bidirectional
Port E I/O – bit 2
27
GND
Ground
28
MR32_PWM6
Out
Signal Description
MCU ground
No connect
MCU ground
No connect
External reset
MCU ground
MCU ground
Pulse width modulation – bit 6
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Support Information
MRICS Connector Signal Definitions
Table 3-1. MR16/32 Target Connector J2 (Continued)
Pin
No.
Schematic NET
Direction
29
MR32_PWM4
Out
Pulse width modulation – bit 4
30
MR32_PWM3
Out
Pulse width modulation – bit 3
31
PTD6
Bidirectional
32
GND
Ground
33
PTD2
Bidirectional
Port D I/O – bit 2
34
PTD3
Bidirectional
Port D I/O – bit 3
35
PTD1
Bidirectional
Port D I/O – bit 1
36
NC
37
PTC5
Bidirectional
38
GND
Ground
39
TGT_PTC3
Bidirectional
40
GND
Ground
Signal Description
Port D I/O – bit 6
Flex cable shield ground
No connect
Port C I/O – bit 5
MCU ground
Port C I/O – bit 3
MCU ground
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Table 3-2. MR16/32 Target Connector J3
Pin
No.
Schematic NET
Direction
1
GND
Ground
2
MR32_PTB4
Bidirectional
Port B I/O – bit 4
3
MR32_PTB7
Bidirectional
Port B I/O – bit 7
4
GND
Ground
5
NC
No connect
6
NC
No connect
7
MR32_PTB0
Bidirectional
Port B I/O – bit 0
8
MR32_PTB1
Bidirectional
Port B I/O – bit 1
9
MR32_PTA5
Bidirectional
Port A I/O – bit 5
10
MR32_PTA6
Bidirectional
Port A I/O – bit 6
11
MR32_PTA1
Bidirectional
Port A I/O – bit 1
12
MR32_PTA2
Bidirectional
Port A I/O – bit 2
13
NC
No connect
14
NC
No connect
15
NC
No connect
16
NC
No connect
17
PTF5
Bidirectional
Port F I/O – bit 5
18
PTF4
Bidirectional
Port F I/O – bit 4
19
GND
Ground
20
PTF1
Bidirectional
21
NC
22
PTE7
Bidirectional
Port E I/O – bit 7
23
PTE4
Bidirectional
Port E I/O – bit 4
24
GND
Ground
25
PTE1
Bidirectional
Port E I/O – bit 1
26
PTE0
Bidirectional
Port E I/O – bit 0
27
MR32_PWM5
Out
28
NC
Signal Description
MCU ground
MCU ground
MCU ground
Port F I/O – bit 1
No connect
MCU ground
Pulse width modulation – bit 5
No connect
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Support Information
MRICS Connector Signal Definitions
Table 3-2. MR16/32 Target Connector J3 (Continued)
Pin
No.
Schematic NET
Direction
29
MR32_PWM2
Out
Pulse width modulation – bit 2
30
MR32_PWM1
Out
Pulse width modulation – bit 1
31
PTD4
Bidirectional
Port D I/O – bit 4
32
PTD5
Bidirectional
Port D I/O – bit 5
33
NC
No connect
34
NC
No connect
35
PTC6
Bidirectional
Port C I/O – bit 6
36
PTD0
Bidirectional
Port D I/O – bit 0
37
TGT_PTC4
Bidirectional
Port C I/O – bit 4
38
GND
Ground
39
TGT_PTC2
Bidirectional
40
GND
Ground
Signal Description
MCU ground
Port C I/O – bit 2
MCU ground
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Table 3-3. MR4/8 Target Connector J5
Pin
No.
Schematic NET
1
NC
2
MR4_PTA1
Bidirectional
Port A I/O – bit 1
3
MR4_PTA6
Bidirectional
Port A I/O – bit 6
4
NC
5
MR4_PTB1
Bidirectional
Port B I/O – bit 1
6
MR4_PTB2
Bidirectional
Port B I/O – bit 2
7
NC
No connect
8
NC
No connect
9
GND
10
NC
11
MR4_PTA2
12
NC
No connect
13
NC
No connect
14
GND
Ground
15
MR4_PWM3
Out
Pulse width modulation – bit 3
16
MR4_PWM4
Out
Pulse width modulation – bit 4
17
MR4_PTC0
Bidirectional
Port C I/O – bit 0
18
MR4_PTB0
Bidirectional
Port B I/O – bit 0
19
MR4_PTC1
Bidirectional
Port C I/O – bit 1
20
NC
No connect
21
NC
No connect
22
NC
No connect
23
MR4_PTB5
24
NC
25
MR4_PTA0
26
NC
27
GND
28
NC
Direction
Signal Description
No connect
No connect
Ground
MCU ground
No connect
Bidirectional
Bidirectional
Port A I/O – bit 2
MCU ground
Port B I/O – bit 5
No connect
Bidirectional
Port A I/O – bit 0
No connect
Ground
MCU ground
No connect
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Support Information
MRICS Connector Signal Definitions
Table 3-3. MR4/8 Target Connector J5 (Continued)
Pin
No.
Schematic NET
29
NC
No connect
30
NC
No connect
31
NC
No connect
32
GND
33
NC
34
TGT_IRQ
35
NC
36
GND
37
NC
38
GND
39
NC
40
GND
Direction
Ground
Signal Description
MCU ground
No connect
In
External interrupt
No connect
Ground
MCU ground
No connect
Ground
MCU ground
No connect
Ground
MCU ground
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Table 3-4. MR4/8 Target Connector J6
Pin
No.
Schematic NET
Direction
1
GND
Ground
2
MR4_PTA4
Bidirectional
Port A I/O – bit 4
3
MR4_PTA5
Bidirectional
Port A I/O – bit 5
4
GND
Ground
5
MR4_PTB3
Bidirectional
Port B I/O – bit 3
6
MR4_PTB4
Bidirectional
Port B I/O – bit 4
7
NC
No connect
8
NC
No connect
9
MR4_PTA3
10
NC
No connect
11
NC
No connect
12
NC
No connect
13
MR4_PWM1
Out
Pulse width modulation – bit 1
14
MR4_PWM2
Out
Pulse width modulation – bit 2
15
MR4_PWM5
Out
Pulse width modulation – bit 5
16
MR4_PWM6
Out
Pulse width modulation – bit 6
17
NC
No connect
18
NC
No connect
19
GND
20
NC
No connect
21
NC
No connect
22
NC
No connect
23
MR4_PTB6
Bidirectional
24
GND
Ground
25
NC
No connect
26
NC
No connect
27
NC
No connect
28
NC
No connect
Bidirectional
Ground
Signal Description
MCU ground
MCU ground
Port A I/O – bit 3
MCU ground
Port B I/O – bit 6
MCU ground
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MRICS Connector Signal Definitions
Table 3-4. MR4/8 Target Connector J6 (Continued)
Pin
No.
Schematic NET
29
NC
No connect
30
NC
No connect
31
NC
No connect
32
NC
No connect
33
NC
No connect
34
MR8/4_TGT_CLK
35
NC
36
TGT_RST
37
NC
38
GND
39
NC
40
GND
Direction
In
Signal Description
External clock
No connect
In or out
External reset
No connect
Ground
MCU ground
No connect
Ground
MCU ground
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Table 3-5. MR16/32 MON08 Connector J7 Pin Assignments
Pin
No.
Mnemonic
Signal
1
RST-OUT
TARGET SYSTEM RESET — Active-low, bidirectional signal from the
target system to initiate an MRICS MCU reset
2
GND
3
RST-IN
4
RST
5
TGT-IRQ
TARGET INTERRUPT REQUEST — Active-low input signal from the
target that asynchronously provides an interrupt to the MCU
6
IRQ
INTERRUPT REQUEST — Active-low input signal from the MRICS
MCU that asynchronously provides an interrupt to the target system
7
TGT_PTA0
8
MR32_PTA0
PORT A (bit 0) — General-purpose MCU I/O signal
9
TGT_PTC2
TARGET PORT C (bit 2) — General-purpose I/O signal from the target
system
10
PTC2
11
TGT_PTC3
12
PTC3
13
TGT_PTC4
14
PTC4
15
NC
No connection
16
NC
No connection
GROUND
TARGET SYSTEM RESET — Active-low, bidirectional signal from the
target system to initiate an MRICS MCU reset
RESET — Active-low, bidirectional signal from the MRICS MCU to
initiate a target system reset
TARGET PORT A (bit 0) — General-purpose I/O signal from the target
system
PORT C (bit 2) — General-purpose MCU I/O signal
TARGET PORT C (bit 3) — General-purpose I/O signal from the target
system
PORT C (bit 3) — General-purpose MCU I/O signal
TARGET PORT C (bit 4) — General-purpose I/O signal from the target
system
PORT C (bit 4) — General-purpose MCU I/O signal
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MRICS Connector Signal Definitions
Table 3-6. MR4/8 MON08 Connector J8 Pin Assignments
Pin
No.
Mnemonic
1
GND
2
NC
3
MR4_PTB0
4
TGT_MR4_PTB0
5
MR4_PTB1
6
TGT_MR4_PTB1
7
IRQ
INTERRUPT REQUEST — Active-low input signal from the MRICS
MCU that asynchronously provides an interrupt to the target system
8
TGT-IRQ
TARGET INTERRUPT REQUEST — Active-low input signal from the
target that asynchronously provides an interrupt to the MCU
9
RST
10
RST-IN
11
NC
No connection
12
NC
No connection
13
NC
No connection
14
NC
No connection
15
NC
No connection
16
NC
No connection
Signal
GROUND
No connection
PORT B (bit 0) — General-purpose MCU I/O signal
TARGET PORT B BIT 0 — General-purpose I/O signal
PORT B (bit 1) — General-purpose MCU I/O signal
TARGET PORT B BIT 1 — General-purpose I/O signal
RESET — Active-low, bidirectional signal from the MRICS MCU to
initiate a target system reset
TARGET SYSTEM RESET — Active-low, bidirectional signal from the
target system to initiate an MRICS MCU reset
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Table 3-7. MR16/32 Target Connector J1 (Sheet 1 of 3)
Pin
No.
Schematic
NET
Direction
1
MR32_PTA2
Bidirectional
Port A I/O – bit 2
2
MR32_PTA1
Bidirectional
Port A I/O – bit 1
3
MR32_PTA3
Bidirectional
Port A I/O – bit 3
4
MR32_PTA0
Bidirectional
Port A I/O – bit 0
5
MR32_PTA4
Bidirectional
Port A I/O – bit 4
6
GND
Ground
7
MR32_PTA5
Bidirectional
8
None
NC
9
MR32_PTA6
Bidirectional
10
TGT_CLK
In
11
MR32_PTA7
Bidirectional
12
None
NC
13
MR32_PTB0
Bidirectional
14
None
NC
15
MR32_PTB1
Bidirectional
16
TGT_RST
In or out
17
MR32_PTB2
Bidirectional
Port B I/O – bit 2
18
TGT_IRQ
In
External interrupt
19
MR32_PTB3
Bidirectional
Port B I/O – bit 3
20
PTF5
Bidirectional
Port F I/O – bit 5
21
MR32_PTB4
Bidirectional
Port B I/O – bit 4
22
PTF4
Bidirectional
Port F I/O – bit 4
23
MR32_PTB5
Bidirectional
Port B I/O – bit 5
24
GND
Ground
25
MR32_PTB6
Bidirectional
26
None
NC
27
MR32_PTB7
Bidirectional
Port B I/O – bit 7
28
PTE7
Bidirectional
Port E I/O – bit 7
Signal Description
MCU ground
Port A I/O – bit 5
No connection
Port A I/O – bit 6
External clock
Port A I/O – bit 7
No connection
Port B I/O – bit 0
No connection
Port B I/O – bit 1
External reset
MCU ground
Port B I/O – bit 6
No connection
User’s Manual
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MRICS Connector Signal Definitions
Table 3-7. MR16/32 Target Connector J1 (Sheet 2 of 3)
Pin
No.
Schematic
NET
Direction
29
None
NC
30
PTE6
Bidirectional
31
None
NC
32
PTE5
Bidirectional
33
GND
Ground
34
PTE4
Bidirectional
35
None
NC
36
PTE3
Bidirectional
Port E I/O – bit 3
37
PTC2
Bidirectional
Port C I/O – bit 2
38
None
NC
39
PTC3
Bidirectional
40
MR32_PWM6
Out
41
PTC4
Bidirectional
42
MR32_PWM5
Out
43
PTC5
Bidirectional
44
GND
Ground
45
PTC6
Bidirectional
46
MR32_PWM4
Out
47
PTD0
Bidirectional
48
MR32_PWM3
Out
49
PTD1
Bidirectional
50
MR32_PWM2
Out
51
PTD2
Bidirectional
52
MR32_PWM1
Out
53
PTD3
Bidirectional
Port D I/O – bit 3
54
PTD6
Bidirectional
Port D I/O – bit 6
Signal Description
No connection
Port E I/O – bit 6
No connection
Port E I/O – bit 5
MCU ground
Port E I/O – bit 4
No connection
No connection
Port C I/O – bit 3
Pulse width modulation – bit 6
Port C I/O – bit 4
Pulse width modulation – bit 5
Port C I/O – bit 5
MCU ground
Port C I/O – bit 6
Pulse width modulation – bit 4
Port D I/O – bit 0
Pulse width modulation – bit 3
Port D I/O – bit 1
Pulse width modulation – bit 2
Port D I/O – bit 2
Pulse width modulation – bit 1
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Table 3-7. MR16/32 Target Connector J1 (Sheet 3 of 3)
Pin
No.
Schematic
NET
Direction
55
PTD4
Bidirectional
Port D I/O – bit 4
56
PTD5
Bidirectional
Port D I/O – bit 5
57
GND
Ground
MCU ground
58
GND
Ground
MCU ground
59
GND
Ground
MCU ground
60
GND
Ground
MCU ground
Signal Description
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MRICS Connector Signal Definitions
Table 3-8. MR4/8 Target DIP Connector J11
Pin
No.
Schematic
NET
Direction
1
None
NC
No connection
2
TGT_RST
In or out
External reset
3
None
NC
No connection
4
GND
Ground
5
None
NC
No connection
6
MR8/4_TGT_CLK
In
External clock
7
None
NC
No connection
8
TGT_IRQ
In
9
MR4_PWM1
Out
Pulse width modulation – bit 1
10
MR4_PWM2
Out
Pulse width modulation – bit 2
11
MR4_PWM3
Out
Pulse width modulation – bit 3
12
MR4_PWM4
Out
Pulse width modulation – bit 4
13
MR4_PWM5
Out
Pulse width modulation – bit 5
14
MR4_PWM6
Out
Pulse width modulation – bit 6
15
MR4_PTC0
Bidirectional
Port C I/O – bit 0
16
MR4_PTB0
Bidirectional
Port B I/O – bit 0
17
MR4_PTB1
Bidirectional
Port B I/O – bit 1
18
MR4_PTB2
Bidirectional
Port B I/O – bit 2
19
MR4_PTB3
Bidirectional
Port B I/O – bit 3
20
MR4_PTB4
Bidirectional
Port B I/O – bit 4
21
None
NC
22
GND
Ground
23
MR4_PTB5
Bidirectional
Port B I/O – bit 5
24
MR4_PTB6
Bidirectional
Port B I/O – bit 6
25
MR4_PTA0
Bidirectional
Port A I/O – bit 0
26
MR4_PTA1
Bidirectional
Port A I/O – bit 1
27
MR4_PTA2
Bidirectional
Port A I/O – bit 2
28
MR4_PTA3
Bidirectional
Port A I/O – bit 3
Signal Description
MCU ground
External interrupt
No connection
MCU ground
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Table 3-9. Power Connector J4 Pin Assignments
Pin
No.
Mnemonic
Signal
1
5VDC
+5 VDC POWER — Input voltage (+5 Vdc @ 1.0 A) from the provided
power supply used by the MRICS logic circuits
2
GND
GROUND
Table 3-10. RS-232C Communication Connector J12 Pin Assignments
Pin
No.
Mnemonic
1
NC
2
RXD
RECEIVE DATA — Output for sending serial data to the DTE device
3
TXD
TRANSMIT DATA — Input for receiving serial data output from the DTE
device
4
DTR
DATA TERMINAL READY — Input for receiving
on-line/in-service/active status from the DTE device
5
GND
GROUND
6
NC
NO CONNECT
7
NC
NO CONNECT
8
NC
NO CONNECT
9
NC
NO CONNECT
Signal
NO CONNECT
3.3 Target-Cable Pin Assignments
The following tables describe the pin assignments for these cables:
•
Flex target cable for use with the MR16/32 56-pin SDIP and 64-pin QFP
target head adapters
•
Flex target cable for use with the MR4/8 28-pin DIP and 32-pin QFP
target head adapters
•
Target MON08 cable
User’s Manual
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Target-Cable Pin Assignments
Table 3-11. Flex Target Cable (M68CBL05C) for QFP Target Head Adapter B
QFP Package
(UX1)
Pin No.
M68ICS08MR
Board Label
MR/32 MCU
Signal Name
QFP Package
(UX1)
Pin No.
M68ICS08MR
Board Label
MR/32 MCU
Signal Name
1
MR32_PTA2
PTA2
29
PTD5
PTD5/IS2#
2
MR32_PTA3
PTA3
30
PTD6
PTD6/IS3#
3
MR32_PTA4
PTA4
31
MR32_PWM1
PWM1
4
MR32_PTA5
PTA5
32
MR32_PWM2
PWM2
5
MR32_PTA6
PTA6
33
MR32_PWM3
PWM3
6
MR32_PTA7
PTA7
34
MR32_PWM4
PWM4
7
MR32_PTB0
PTB0/ATD0
35
GND
PWMGND
8
MR32_PTB1
PTB1/ATD1
36
MR32_PWM5
PWM5
9
MR32_PTB2
PTB2/ATD2
37
MR32_PWM6
PWM6
10
MR32_PTB3
PTB3/ATD3
38
NC
No Connect
11
MR32_PTB4
PTB4/ATD4
39
PTE3
PTE3/TCLKA
12
MR32_PTB5
PTB5/ATD5
40
PTE4
PTE4/TCLK0A
13
MR32_PTB6
PTB6/ATD6
41
PTE5
PTE5/TCH1A
14
MR32_PTB7
PTB7/ATD7
42
PTE6
PTE6/TCH2A
43
PTE7
PTE7/TCH3A
15
16
VDD_SW
VDDAD
44
VDD_SW
VDD
17
GND
VSSAD/VREFL
45
GND
VSS
18
VDD_SW
VREFH
46
PTF4
PTF4/RXD
19
PTC2
PTC2
47
PTF5
PTF5/TXD
20
PTC3
PTC3
48
IRQ#
IRQ#
21
PTC4
PTC4
49
RST#
RST#
22
PTC5
PTC5
50
VDD_SW
VDDA
23
PTC6
PTC6
51
GND
CGMXFC
24
PTD0
PTD0/FAULT1
52
4.9152MHz
OSC1
25
PTD1
PTD1/FAULT2
53
No Connect
OSC2
26
PTD2
PTD2/FAULT3
54
GND
VSSA
27
PTD3
PTD3/FAULT4
55
MR32_PTA0
PTA0
28
PTD4
PTD4/IS1#
56
MR32_PTA1
PTA1
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Table 3-12. Flex Target Cable (M68CBL05C) for DIP Target Head Adapter A
DIP Package
(UX2)
Pin No.
M68ICS08MR
Board Label
MR4/8 MCU
Signal Name
DIP Package
(UX2)
Pin No.
M68ICS08MR
Board Label
MR4/8 MCU
Signal Name
1
VDD_SW
VREFH
15
MR4_PTC0
PTC0/FAULT1
2
RST#
RST#
16
MR4_PTB0
PTB0/RXD
3
VDD_SW
VDDA
17
MR4_PTB1
PTB1/TXD
4
GND
VSSA
18
MR4_PTB2
PTB2/TCLK
5
No Connect
OSC2
19
MR4_PTB3
PTB3/TCHD
6
4.0000MHz
OSC1
20
MR4_PTB4
PTB4/TCH1
7
GND
CGMXFC
21
VDD_SW
VDD
8
IRQ#
IRQ#
22
GND
VSS
9
MR4_PWM1
PWM1
23
MR4_PTB5
PTB5/TCH2
10
MR4_PWM2
PWM2
24
MR4_PTB6
PTB6/TCH3
11
MR4_PWM3
PWM3
25
MR4_PTA0
PTA0/ATD0
12
MR4_PWM4
PWM4
26
MR4_PTA1
PTA1/ATD1
13
MR4_PWM5
PWM5
27
MR4_PTA2
PTA2/ATD2
14
MR4_PWM6
PWM6
28
MR4_PTA3
PTA3/ATD3
User’s Manual
54
M68ICS08MR In-Circuit Simulator
Support Information
MOTOROLA
Support Information
Target-Cable Pin Assignments
Table 3-13. Flex Target Cable (M68CBL05C) for QFP Target Head Adapter B
QFP Package
(UX3)
Pin No.
M68ICS08MR
Board Label
MR32 MCU
Signal Name
QFP Package
(UX3)
Pin No.
M68ICS08MR
Board Label
MR32 MCU
Signal Name
1
MR32_PTB2
PTB2/ATD2
33
PTE1
PTE1/TCH0B
2
MR32_PTB3
PTB3/ATD3
34
PTE2
PTE2/TCH1B
3
MR32_PTB4
PTB4/ATD4
35
PTE3
PTE3/TCLKA
4
MR32_PTB5
PTB5/ATD5
36
PTE4
PTE4/TCLK0A
5
MR32_PTB6
PTB6/ATD6
37
PTE5
PTE5/TCH1A
6
MR32_PTB7
PTB6/ATD7
38
PTE6
PTE6/TCH2A
7
PTC0
PTC0/FAULT1
39
PTE7
PTE7/TCH3A
8
PTC1
PTC1/FAULT4
40
VDD_SW
VDD
9
VDD_SW
VDDAD
41
GND
VSS
10
GND
VSSAD
42
PTF0
PTF0/SPSCK
11
GND
VREFL
43
PTF1
PTF1/SS#
12
VDD_SW
VREFH
44
PTF2
PTF2/MOSI
13
PTC2
PTC2
45
PTF3
PTF3/MISO
14
PTC3
PTC3
46
PTF4
PTF4/RXD
15
PTC4
PTC4
47
PTF5
PTF5/TXD
16
PTC5
PTC5
48
IRQ#
IRQ#
17
PTC6
PTC6
49
RST#
RST#
18
PTD0
PTD0/FAULT1
50
VDD_SW
VDDA
19
PTD1
PTD1/FAULT2
51
GND
CGMXFC
20
PTD2
PTD2/FAULT3
52
4.9152MHz
OSC1
21
PTD3
PTD3/FAULT4
53
OSC2
No Connect
22
PTD4
PTD4/IS1#
54
VSSA
GND
23
PTD5
PTD5/IS2#
55
MR32_PTA0
PTA0
24
PTD6
PTD6/IS3#
56
MR32_PTA1
PTA1
25
MR32_PWM1
PWM1
57
MR32_PTA2
PTA2
26
MR32_PWM2
PWM2
58
MR32_PTA3
PTA3
27
MR32_PWM3
PWM3
59
MR32_PTA4
PTA4
28
MR32_PWM4
PWM4
60
MR32_PTA5
PTA5
29
GND
PWMGND
61
MR32_PTA6
PTA6
30
MR32_PWM5
PWM5
62
MR32_PTA7
PTA6
31
MR32_PWM6
PWM6
63
MR32_PTB0
PTB0/ATD0
32
PTE0
PTE0/CLKB
64
MR32_PTB1
PTB1/ATD1
M68ICS08MR In-Circuit Simulator
MOTOROLA
User’s Manual
Support Information
55
Support Information
Table 3-14. Flex Target Cable (M68CBL05C) for DIP/QFP Target Head Adapter B
QFP Package
(UX4)
Pin No.
M68ICS08MR
Board Label
MR4/8 MCU
Signal Name
QFP Package
(UX4)
Pin No.
M68ICS08MR
Board Label
MR4/8 MCU
Signal Name
1
VSSA
GND
17
MR4_PTB3
PTB3/TCHD
2
No Connect
OSC2
18
MR4_PTB4
PTB4/TCH1
3
4.0000MHz
OSC1
19
VDD_SW
VDD
4
GND
CGMXFC
20
GND
VSS
5
IRQ#
IRQ#
21
MR4_PTB5
PTB5/TCH2
6
MR4_PWM1
PWM1
22
MR4_PTB6
PTB6/TCH3
7
MR4_PWM2
PWM2
23
MR4_PTA0
PTA0/ATD0
8
MR4_PWM3
PWM3
24
MR4_PTA1
PTA1/ATD1
9
MR4_PWM4
PWM4
25
MR4_PTA2
PTA2/ATD2
10
MR4_PWM5
PWM5
26
MR4_PTA3
PTA3/ATD3
11
MR4_PWM6
PWM6
27
MR4_PTA4
PTA4/ATD4
12
MR4_PTC0
PTC0/FAULT1
28
MR4_PTA5
PTA5/ATD5
13
MR4_PTC1
PTC1/FAULT4
29
MR4_PTA6
PTA6/ATD6
14
MR4_PTB0
PTB0/RXD
30
VDD_SW
VREFH
15
MR4_PTB1
PTB1/TXD
31
RST#
RST#
16
MR4_PTB2
PTB2/TCLK
32
VDD_SW
VDDA
User’s Manual
56
M68ICS08MR In-Circuit Simulator
Support Information
MOTOROLA
Support Information
Parts List
3.4 Parts List
Table 3-15. Bill of Materials (Sheet 1 of 3)
Reference
Designator
Description
Manufacturer
Part Number
Printed circuit board assembly
01-RE10033W01
Test procedure, ICS08MR
12ASE10033W
Test fixture, ICS08MR
81ASE10033W
Printed wiring board, ICS08MR
84-RE10033W01
-
Feet Rubber 0.5-inch tapered squares
Fastex
4009-00-5072
C1-C4, C7,
C9-C14, C17,
C18, C20-C23,
C25-C36, C38,
C39, C41, C42
Capacitor, 0.1 µF, +80–20, 50 V, Z5U,
C0805
AVX
08055E104ZAT2A
C5, C16
Capacitor, tantalum, 47 µF, 20%, 16 V,
C6032
AVX
TPSD476M016R0150
C6, C19
Capacitor, tantalum, 10 µF, 20%, 16 V,
C6032
AVX
TAJC106M016
C8, C24, C37, C40
Capacitor, 22000 pF, 20%, 16 V, X7R,
C0805
AVX
0805YC223MAT2A
C43-C46
Capacitor, tantalum, 1 µF, 20%, 16 V,
C3216
AVX
TAJC106M016
C15
Capacitor, 560 pF, 50 V, COG, C0805
AVX
08055A561KAT2A
D1
Diode, zener, 1SMA6.0AT3, SMA
Motorola
1SMA6.0AT3
D2, D4
Diode, Schottky, MBRA130, SMA
Motorola
MBRA130
D3
Diode, Schottky, MBRA0520, SOD-123
Motorola
MBRA0520
DS1
LED, green, 5 mm, T1-3/4
Dialight
521-9173
DS2
LED, yellow, 5 mm, T1-3/4
Dialight
521-9174
F1
Fuse, 0.5 A, 250 V, 5X20 mm, FAST
Schurter
34.1513
J1
Connector, 60-pin, ribbon, with ejector
Amp
1-499922-1
J11
Socket, 28-pin DIP, machine-pin,
DIP28-600
Augat
828-AG11D
J12
Connector, DE, R/A, socket
Cinch
DEKL-9SAT-F1
J2, J3, J5, J6
Header, 2 x 20, 100, shrouded
3M
2540-6002-UG
M68ICS08MR In-Circuit Simulator
MOTOROLA
User’s Manual
Support Information
57
Support Information
Table 3-15. Bill of Materials (Sheet 2 of 3)
Reference
Designator
Description
Manufacturer
Part Number
J4
Connector, PWR_JACK, 2.5 mm, center
Cui Stack
PJ-202B
J7, J8
Header, 8 x 2, 100, shrouded
3M
2516-6002-UG
L1
Inductor, 180 µH, L1812
Murata
LQH4N181K04
L2
Inductor, 10 µH, L1206
Murata
LQH1N100K04
L3-L15
Inductor, ferrite, 170 Ω, L1206
Murata
BLM31A700S
Q1, Q3
Transistor, PFET, MMBF0201, SOT-23
Motorola
MMBF0201
Q2
Transistor, PFET, MMFT5P03, SOT-223
Motorola
MMFT5P03HD
Q4
Transistor, NPN, MMBT3904, SOT-23
Motorola
MMBT3904
R1, R25
Resistor, 100 k, 5%, 1/8W, R0805
Dale
CRCW0805104J
R2, R12, R31
Resistor, 5 k, 5%, R0805
Dale
CRCW0805332J
R20, R22, R23
Resistor, 10 Ω, 1%, R1206
Dale
CRCW120610R0F
R21
Resistor, 59.0 k, 1%, R0805
Dale
CRCW08055902F
R24
Resistor, 150 Ω, 1%, R0805
Dale
CRCW08051500F
R3, R4, R6-R11,
R13-R17, R19,
R26-R30, R32,
R34, R36-R38
Resistor, 10 k, 5%, R0805
Dale
CRCW0805103J
R33, R35
Resistor, 33 Ω, 5%, 1/8W, R0805
Dale
CRCW0805330J
R5, R18
Resistor, 470 Ω, 5%, R0805
Dale
CRCW0805471J
U10
IC, 12-bit, ripple, AC4040, SO-14
Fairchild
MM74AC4040
U11
IC, 5 V, supervisor, SOT-223
Dallas Semi
DS1233Z-5
U13
IC, MC34063A, SO8
Motorola
MC34063AD
U14
IC, buffer, three-state, SO14
Motorola
MC74ACT125D
U16
IC, LOW_POWER, RS232 driver, SO16W
Linear Tech
LT1181ACSW
U5, U12, U15
IC, hex, inverter, 74AC05, SOIC-14
Motorola
MC74AC05D
U6
IC, NC7SZ38, SOT23-5
Fairchild
NC7SZ38M5
U7
IC, NC7SZ32, SOT23-5
Fairchild
NC7SZ32M5
U8
IC, tripple, 2:1, multiplexor/demultiplexor,
SO16
Motorola
MC74LVX8053D
User’s Manual
58
M68ICS08MR In-Circuit Simulator
Support Information
MOTOROLA
Support Information
Parts List
Table 3-15. Bill of Materials (Sheet 3 of 3)
Reference
Designator
Description
Manufacturer
Part Number
U9
IC, 74AC00, quad NAND, SO-14
Motorola
MC74AC00D
W1-W7, J9, J10
HDR, 3X1, 0.23", GOLD_PLATED
3M
2403-6112TG
XF1
Fuse, holder, 5 x 20, 3AC
Schurter
ODG 0031.8231
XU1
Socket, 56-pin SDIP
Berg
DIP 70-6056-340B
XU2
Socket, 64-pin QFP, clamshell
Yamichi
IC51-0644-824-1
XU3
Socket, 32-pin QFP,
YAM_ICS51-0324-1498
Yamichi
ICS51-0324-1498
XU4
Socket, 28-pin DIP, SCREW_MACH
Robinson
Nugent
ICE-286-S-TG30
XW1-XW7
Shunt, with handle
Amp
881545-1
XY1, XY2
Socket, 14-pin DIP, machine-pin,
DIP14-300
Augat
814-AG11D
Y1
Oscillator, 4.9152 MHz, DIP8
Epson
SG-531P-4.9152MC2
Y2
Oscillator, 4.000 MHz, DIP8
Epson
SG-531P-4.000MC2
M68ICS08MR In-Circuit Simulator
MOTOROLA
User’s Manual
Support Information
59
Support Information
3.5 MRICS Printed Circuit Board Layout and Schematic Diagrams
Figure 3-1. MRICS Board Layout
User’s Manual
60
M68ICS08MR In-Circuit Simulator
Support Information
MOTOROLA
D
C
B
A
4.
SPECIAL SYMBOL USAGE:
3.
Page 3
COMM PORT (DSub9)
1
Power Conditioning/Switching
Page 2
Tx/Rx
2
Oscillator
Page 3
Oscillator
Page 3
INTERPRET DIAGRAM IN ACCORDACE WITH
ANSI SPECIFICATIONS WITH THE
EXCEPTION OF LOGIC BLOCK SYMBOLOGY.
[ ] DENOTES VECTORED SIGNAL.
# DENOTES ACTIVE LOW SIGNAL.
DEVICE TYPE NUMBER IS FOR REFERENCE
ONLY THE NUMBER VARIES WITH THE
PART MANUFACTURER.
CAPACITORS ARE IN MICROFARADS, 50V
RESISTORS ARE IN OHMS, 5%, 1/10W
UNLESS OTHERWISE SPECIFIED:
2
2.
1.
NOTES:
1
Page 9
PTA0, PTC2-4
Busses - PTA, PTB, PTC,
PTD, PTE, PTF, PWM
3
Busses - PTA, PTB, PTC, PWM
MR8/4 Sockets
Pages 5, 6
MR32/24 Sockets
3
4
MR8/4 Target
Head Connectors
Page 10
MR8/4 MON08
Connector/Circuit
Page 10
RST/IRQ Logic
Page 4
MR32/24 MON08
Connector/Circuit
Page 4
TGT-PTA0, TGT-PTC2-4
MR32/24 Target
Head
Connectors
Pages 7, 8
4
5
5
6
7 4 H C05
U 1 2E
7 4 H C05
U12F
10
12
9
7 4 H C05
U5F
8
7 4 H C05
U 1 5E
DATE:
APPROVED:
6
DATE:
9/99
DATE:
CHECKED:
TEAM DEV./WRR
8
7 4 AC00
U9C
13
12
7 4 AC00
U9D
VDD_SW
10
9
11
8
Size
D w g.
No.
7
63BSE10033W
ENG
8
S h e et
1
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
Title:
B
7 4 H C05
U15F
10
7 4 AC00
U9B
VDD_SW
5
4
6
E
12
28 APR 00
Modify input to U12C per request
of M. Scholten. Added C47.
VDD_SW
28 FEB 00
Modify power connections for
the MCU A/D convertor.
D
MOTOROLA
9
Change pin-outs for PTB0 and
PTB1 on MR4/8 Target Head
Connectors.
C
7 4 H C05
VDD
7 4 H C05
11
7 JAN 00
B
11 FEB 00
11/10/99
BACK ANNOTATE REFDES FROM LAYOUT
Change Power Control and update
layout. BACK ANNOTATE REFERENCE
DESIGNATORS FROM LAYOUT
A
DATE
8
DESCRIPTION
RELEASE TO LAYOUT
7
O
REV
U15D
VDD_SW
11
U5E
T H I S D O C U M E N T C O N T A I N S I N F O R M A TION
P R O P R I E T A R Y T O M O T O R O L A A N D SHALL NOT BE
USED FOR ENGINEERING DESIGN, PROCUREMENT
OR MANUFACTURE IN WHOLE OR IN PART WITHOUT
C O N S E N T O F M OTOROLA.
DRAWN:
13
VDD
VDD
7 4 H C05
U5D
8
10
VDD_SW
13
VDD_SW
9
VDD_SW
11
VDD_SW
SPARE GATES
7
Power On
14
7
14
7
14
14
7
14
7
14
7
14
7
14
7
14
7
14
7
14
7
D
C
B
A
D
C
B
A
C47 +
47uF, 16V
3
J4
PWR_JACK
1
TP1
COMMON
1
POWER_ON
PAGE 3
D1
1SMA6.0AT3
GND
VCC
5VDC INPUT
2
2
1
F1
2
D2
MBRA130
4
0.5A, 250V
3
TP3
5VDC IN
10K
R29
R5
470
DS1
GREEN
VDD
R6
10K
3
Q2
MMFT5P03HD
5VDC SWITCHED
TP2
1
Q4
M M B T 3 904
3
DS2
AMBER
2
4
VDD_SW
3
R18
470
RST_OUT#
PAGE 4,8
5
4
74HC05
U12C
6
2
1
L1
3
R28
10K
5
5
10
CLK
U10
4
3
2
1
Q1
Q2
Q3
Q4
Q5
Q6
Q7
Q8
Q9
Q10
Q11
Q12
D4
9
7
6
5
3
2
4
13
12
14
15
1
MBRA130
C15
560 pF
74HC4040
VDD_SW
GND
CAP
SW EMIT
SW COL
MC34063
180 uH
1.25V REF
COMPARE
VCC
SENSE
DR COL
U13
VDD_SW
5
6
7
8
R24
150, 1%
74AC00
U9A
VDD_SW
C4
0.1uF
R23
10, 1%, 1/4W
VDD_SW
+ C5
47uF, 16V
R22
10, 1%, 1/4W
RST_CLK
PAGE 3
C6 +
10uF, 16V
R20
10, 1%, 1/4W
4
14
7
16
VCC
2
RST
11
6
6
R19
10K
13
74HC05
U12D
R9
10K
+ C19
10uF, 16V
DELAY_RESET_1
PAGE 4
DELAY_RESET
PAGE 3
7
R31
3.3k
VTST
PAGE 4
Updated 28 APR 00
C18
0.1uF
TP4
8.6VDC +/-0.4V TEST
8
B
Size
Dwg.
No.
7
63BSE10033W
8
Sheet
2
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
Title:
12
C17
0.1uF
VDD_SW
10 uH
+ C16
10uF, 16V
L2
VDD_SW
R21
59.0K, 1%
14
1
14
7
GND
8
G
7
D
S
D
C
B
A
A
B
C
D
C35
0.1uF
5
VDD_SW
C27
0.1uF
VDD_SW
VDD_SW
R17
1
6
2
7
3
8
4
9
5
7
4
14
10K
GND
GND8
VCC
Y1
ENABLE
OUTPUT
OUTPUT8
4.9152MHz
I
1
8
11
7
T X _ O UT
XTAL EN
W5
0
8
DTR
GND
GND8
VCC
Y2
4.0000MHz
ENABLE
OUTPUT
OUTPUT8
1
8
11
SOCKETED TO ALLOW FULL
OR HALF SIZE XTAL
7
4
14
12
8
4
74ACT125
11
U14D
74ACT125
VDD_SW
9
11
10
9
12
5
4
3
1
U14C
TR1 IN
TR2 IN
RX2 OUT
RX1 OUT
C2-
C2+
C1-
C1+
LT1181A
VDD_SW
TR1 OUT
16
VDD
TR2 OUT
RX2 IN
RX1 IN
V-
V+
U16
VDD_SW
14
13
6
2
RX_IN
0.1uF
C31
SOCKETED TO ALLOW FULL
OR HALF SIZE XTAL
J12
CONNECTOR DSub9
0.1uF
VDD
C32
C30
R38
10K
0.1uF
0.1uF
33
1
R33
33
4.0000MHz
PAGE 9,10
FOR MR8/4
MR8/4
1
RST CLK
W7
MR32/24/16
R35
4.9152MHz
PAGE 5,6,8
FOR MR32/24/16
J9
J10
3
14
7
VCC
15
3
3
74HC05
U15B
4
VDD
R36
10K
3
RST_CLK
PAGE 2
3
5
14
7
4
100K
R25
R26
10K
74HC05
U15C
6
2
74HC05
U12A
2
1
VDD_SW
R37
10K
VDD_SW
U14A
3
1
2
74HC05
2
2
4
R32
10K
VDD_SW
74HC05
3
U14B
6
R30
10K
MR32_PTA0
10K
R16
MR4_PTB1
1
Updated 28 APR 00
POWER_ON
PAGE 2
MR32_PTA[0..7]
PAGE 4..8
MR4_PTB[0..6]
PAGE 9,10
B
Size
Title:
Dwg.
No.
1
63BSE10033W
Sheet
3
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
VDD
MR32/24/16
MR4_PTB0
R34
10K
VDD_SW
MR8/4
W4
74ACT125
VDD_SW
5
VDD_SW
U12B
DELAY_RESET
PAGE 2
U15A
VDD
R27
10K
VDD_SW
74ACT125
1
C29
1
3
14
7
4
5
10
13
14
7
GND
14
7
14
7
1
3
14
7
14
7
14
7
3
1
A
B
C
D
A
B
C
R14 10K
VDD_SW
DELAY_RESET_1
PAGE 2
5
4800
9600
W3
5
74HC05
U5C
6
TGT_PTA0
PAGE 7,8
RST_OUT#
PAGE 2,8
TGT_IRQ#
PAGE 7,8,10
VDD_SW
R8 10K
R15
10K
VDD_SW
R11
10K
VDD_SW
1
4
2
TGT_PTC4
TGT_PTC3
13
PTC2_RST
3
5
1
12
9
10
11
6
TGT_PTC2
TGT_PTC3
TGT_PTC4
D3
2
2
4
6
8
10
12
14
16
MON08
Z1
Z0
Y1
Y0
X1
X0
C
B
A
EN
U8
Z
Y
X
7 4 L V X8053
VDD_SW
MR32/24/16
1
3
5
7
9
11
13
15
J7
PTC3
PTC4
15
RST#
IRQ#
MR32_PTA0
PTC2
PTC3
PTC4
PTC2
4
VDD_SW
C13
0.1uF
14
R4
10K
VDD_SW
MBRA0520
74HC05
U5A
VDD_SW
RST_OUT#
RST_IN#
TGT_IRQ#
R7
10K
TGT_PTC2
R10
10K
4
14
7
RST_IN#
PAGE 8,10
VDD_SW
14
7
1
3
16
VCC
4
1
3
RST*
DS1233
3
TGT_PTC[2..4]
PAGE 8
PTC[0..6]
PAGE 5..8
MR32_PTA[0..7]
PAGE 3,5..8
GND2
GND
VCC
U11
3
2
2
1
VDD_SW
5
3
U7
4
NC7SZ32
2
1
VDD_SW
5
3
D
5
GND
GND7
8
7
4
NC7SZ38
U6
R3
10K
VTST
PAGE 2
2
3
R2
3.3K
74HC05
U5B
4
Q1
MMBF0201
VDD_SW
2
14
7
Q3
M M B F 0 2 01
R12
3.3K
Updated 28 APR 00
IRQ#
PAGE 5,6,9,10
RST#
PAGE 5,6,9,10
B
Size
Dwg.
No.
1
63BSE10033W
Sheet
4
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
Title:
R13
10K
VDD_SW
R1
100K
1
A
B
C
D
A
B
C
D
5
5
L6
49
48
FERRITE, 70 OHM
PTF[0..5]
PAGE 6..8
PTE[0..7]
PAGE 6..8
4
FERRITE, 70 OHM
46
47
PTF4
PTF5
11
10
54
41
45
39
PTE7
PTF3
38
PTE6
44
37
PTE5
43
36
PTE4
PTF2
35
PTE3
PTF1
34
PTE2
42
33
PTE1
PTF0
32
PTE0
51
53
C24
0.022uF
C23
0.1uF
4.9152MHz
PAGE 3,6,8
L5
C22
0.1uF
9
12
50
40
52
+
L3
C26
0.1uF
FERRITE, 70 OHM
C25
0.1uF
VDD_SW
RST#
PAGE 4,6,9,10
IRQ#
PAGE 4,6,9,10
C43
1uF, 16V
L4
FERRITE, 70 OHM
4
VREFL
VSSAD
VSSA
VSS
PTF5/TxD
PTF4/RxD
PTF3/MISO
PTF2/MOSI
PTF1/SS#
PTF0/SPSCK
PTE7/TCH3A
PTE6/TCH2A
PTE5/TCH1A
PTE4/TCH0A
PTE3/TCLKA
PTE2/TCH1B
PTE1/TCH0B
3
PTD6/IS3#
PTD5/IS2#
PTD4/IS1#
PTD3/FAULT4
PTD2/FAULT3
PTD1/FAULT2
PTD0/FAULT1
PTC6
PTC5
PTC4
PTC3
PTC2
PTC1/ATD9
PTC0/ATD8
PTB7/ATD7
PTB6/ATD6
PTB5/ATD5
PTB4/ATD4
PTB3/ATD3
PTB2/ATD2
PTB1/ATD1
PTB0/ATD0
PTA7
PTA6
PTA5
PTA4
PTA3
PTA2
PTA1
PTA0
PWMGND
PWM6
PWM5
PWM4
PWM3
PWM2
PWM1
MC68HC908MRxx-64QFP
PTE0/CLKB
CGMXFC
OSC2
OSC1
RST#
IRQ#
VDDAD
VREFH
VDDA
VDD
XU2
3
24
23
22
PTD6
PTD5
PTD4
PTD3
PTD2
20
21
PTD1
PTD0
PTC6
PTC5
PTC4
PTC3
PTC2
PTC1
PTC0
MR32_PTB7
MR32_PTB6
MR32_PTB5
MR32_PTB4
MR32_PTB3
MR32_PTB2
19
18
17
16
15
14
13
8
7
6
5
4
3
2
1
64
MR32_PTB1
MR32_PTB0
MR32_PTA7
62
63
MR32_PTA6
61
MR32_PTA5
MR32_PTA4
59
60
MR32_PTA3
58
MR32_PTA2
MR32_PTA1
56
57
MR32_PTA0
MR32_PWM6
MR32_PWM5
MR32_PWM4
MR32_PWM3
MR32_PWM2
MR32_PWM1
55
29
31
30
28
27
26
25
PTD[0..6]
PAGE 6..8
PTC[0..6]
PAGE 4,6..8
2
MR32_PTB[0..7]
PAGE 6..8
MR32_PTA[0..7]
PAGE 3,4,6..8
MR32_PWM[1..6]
PAGE 6..8
2
Updated 28 APR 00
B
Size
Title:
Dwg.
No.
1
63BSE10033W
Sheet
5
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
1
A
B
C
D
A
B
C
D
5
5
PTF[0..5]
PAGE 5,7,8
PTE[0..7]
PAGE 5,7,8
4.9152MHz
PAGE 3,5,8
RST#
PAGE 4,5,9,10
IRQ#
PAGE 4,5,9,10
L9
C7
0.1uF
4
FERRITE, 70 OHM
C44 +
1uF, 16V
L8
FERRITE, 70 OHM
4
C9
0.1uF
C20
0.1uF
C8
0.022uF
FERRITE, 70 OHM
L7
C21
0.1uF
43
PTE7
17
54
45
47
42
PTE6
PTF5
41
PTE5
46
40
PTE4
PTF4
39
51
53
52
49
48
16
18
50
44
PTE3
VDD_SW
3
PIN 38 = N/C
VSSAD/VREFL
VSSA
VSS
PTF5/TxD
PTF4/RxD
PTE7/TCH3A
PTE6/TCH2A
PTE5/TCH1A
PTE4/TCH0A
PTD6/IS3#
PTD5/IS2#
PTD4/IS1#
PTD3/FAULT4
PTD2/FAULT3
PTD1/FAULT2
PTD0/FAULT1
PTC6
PTC5
PTC4
PTC3
PTC2
PTC0/ATD8
PTB7/ATD7
PTB6/ATD6
PTB5/ATD5
PTB4/ATD4
PTB3/ATD3
PTB2/ATD2
PTB1/ATD1
PTB0/ATD0
PTA7
PTA6
PTA5
PTA4
PTA3
PTA2
PTA1
PTA0
PWMGND
PWM6
PWM5
PWM4
PWM3
PWM2
PWM1
MC68HC908MRxx-56DIP
PTE3/TCLKA
CGMXFC
OSC2
OSC1
RST#
IRQ#
VDDAD
VREFH
VDDA
VDD
XU1
3
56
PTD0
PTD1
24
25
PTD5
PTD6
30
PTD4
28
29
PTD3
27
PTD2
PTC6
23
26
PTC5
22
PTC4
PTC3
20
21
PTC2
PTC0
MR32_PTB7
MR32_PTB6
MR32_PTB5
19
15
14
13
12
MR32_PTB4
MR32_PTB3
11
MR32_PTB2
10
MR32_PTB1
8
9
MR32_PTB0
7
MR32_PTA7
MR32_PTA6
6
MR32_PTA5
5
MR32_PTA4
3
4
MR32_PTA3
2
MR32_PTA2
MR32_PTA1
1
MR32_PTA0
MR32_PWM6
55
35
37
MR32_PWM5
MR32_PWM4
34
36
MR32_PWM3
MR32_PWM2
MR32_PWM1
33
32
31
2
PTD[0..6]
PAGE 5,7,8
PTC[0..6]
PAGE 4,5,7,8
MR32_PTB[0..7]
PAGE 5,7,8
MR32_PTA[0..7]
PAGE 3..5,7,8
MR32_PWM[1..6]
PAGE 5,7,8
2
Updated 28 APR 00
B
Size
Title:
Dwg.
No.
1
63BSE10033W
Sheet
6
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
1
A
B
C
D
A
B
C
D
5
5
PTC[0..6]
PAGE 4..6,8
MR32_PTB[0..7]
PAGE 5,6,8
PTD4
PTD3
PTD2
PTD1
PTD0
PTC6
PTC5
PTC4
PTC3
PTC2
MR32_PTB7
MR32_PTB6
MR32_PTB5
MR32_PTB4
MR32_PTB3
MR32_PTB2
MR32_PTB1
MR32_PTB0
MR32_PTA7
MR32_PTA6
MR32_PTA5
MR32_PTA4
MR32_PTA3
MR32_PTA2
58
60
57
59
60_PIN_RBN
56
54
52
50
48
46
44
42
40
38
55
53
51
49
47
45
43
41
39
37
36
34
35
32
33
30
31
28
26
24
22
20
18
16
14
12
10
8
6
4
2
29
J1
27
25
23
21
19
17
15
13
11
9
7
5
3
1
4
4
PTD5
PTD6
MR32_PWM1
MR32_PWM2
MR32_PWM3
MR32_PWM4
MR32_PWM5
MR32_PWM6
PTE3
PTE4
PTE5
PTE6
PTE7
PTF4
PTF5
TGT_PTA0
MR32_PTA1
PTD[0..6]
PAGE 5,6,8
MR32_PWM[1..6]
PAGE 5,6,8
PTE[0..7]
PAGE 5,6,8
PTF[0..5]
PAGE 5,6,8
TGT_IRQ#
PAGE 4,8,10
TGT_RST#
PAGE 8,10
TGT_CLK
PAGE 8
TGT_PTA0
PAGE 4,8
MR32_PTA[0..7]
PAGE 3..6,8
3
3
VDD
C28
0.1uF
C33
0.1uF
2
2
C12
0.1uF
C11
0.1uF
MH2
FID1
C2
0.1uF
MH4
FID3
MH5
C1
0.1uF
Updated 28 APR 00
MH3
FID2
Reference
C3
0.1uF
B
Size
Dwg.
No.
1
63BSE10033W
Sheet
7
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MH1
C10
0.1uF
VDD_SW
MOTOROLA
Title:
C14
0.1uF
IC DECOUPLING CAPS
1
A
B
C
D
A
B
C
D
TGT_PTC[2..4]
PAGE 4
MR32_PWM[1..6]
PAGE 5..7
PTF[0..5]
PAGE 5..7
PTE[0..7]
PAGE 5..7
PTD[0..6]
PAGE 5..7
PTC[0..6]
PAGE 4..7
MR32_PTB[0..7]
PAGE 5..7
MR32_PTA[0..7]
PAGE 3..7
5
5
4
PTC6
TGT_PTC4
TGT_PTC2
PTE4
PTE1
MR32_PWM5
MR32_PWM2
PTD4
PTF5
MR32_PTB0
MR32_PTA5
MR32_PTA1
MR32_PTB7
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
HEADER 20X2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
J3
PTD0
MR32_PWM1
PTD5
PTE0
PTF4
PTF1
PTE7
MR32_PTB1
MR32_PTA6
MR32_PTA2
MR32_PTB4
MR32/16 TARGET HEADER A
4
RST_OUT#
PAGE 2,4
RST_IN#
PAGE 4,10
4.9152MHz
PAGE 3,5,6
TGT_PTA0
PAGE 4,7
3
3
0
I
TGT RESET
W2
0
MR32/16 TGT CLOCK
W1
I
1
3
1
3
TGT_RST#
PAGE 7,10
TGT_CLK
PAGE 7
MR32_PWM4
PTD6
PTD2
PTD1
PTC5
TGT_PTC3
MR32_PTA3
TGT_PTA0
TGT_CLK
TGT_RST#
PTF3
PTF0
PTE6
PTE3
MR32_PTB2
MR32_PTB5
PTC0
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
2
HEADER 20X2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
J2
TGT_IRQ#
PAGE 4,7,10
1
Updated 28 APR 00
B
Size
Title:
Dwg.
No.
1
63BSE10033W
Sheet
8
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
PTD3
PTE5
PTE2
MR32_PWM6
MR32_PWM3
TGT_IRQ#
PTF2
MR32_PTA7
MR32_PTA4
MR32_PTB3
MR32_PTB6
PTC1
MR32/16 TARGET HEADER B
2
A
B
C
D
A
B
C
D
4.0000MHz
PAGE 3,10
RST#
PAGE 4..6,10
IRQ#
PAGE 4..6,10
C45 +
1uF, 16V
5
L10
VDD_SW
C41
0.1uF
C34
0.1uF
C37
0.022uF
FERRITE, 70 OHM
FERRITE, 70 OHM
L12
C36
0.1uF
L11
FERRITE, 70 OHM
5
1
20
4
2
3
31
5
30
32
19
VSSA
VSS
CGMXFC
OSC2
OSC1
RST#
IRQ#
VREFH
VDDA
VDD
XU3
4
PTC1/FAULT4
PTC0/FAULT1
PTB6/TCH3
PTB5/TCH2
PTB4/TCH1
PTB3/TCH0
PTB2/TCLK
PTB1/TxD
PTB0/RxD
PTA6/ATD6
PTA5/ATD5
PTA4/ATD4
PTA3/ATD3
PTA2/ATD2
PTA1/ATD1
PTA0/ATD0
PWM6
PWM5
PWM4
PWM3
PWM2
PWM1
MC68HC908MRx-32QFP
4
13
MR4_PTC1
MR4_PTC0
MR4_PTB6
22
12
MR4_PTB5
21
MR4_PTB3
17
MR4_PTB4
MR4_PTB2
18
MR4_PTB1
16
MR4_PTB0
15
14
MR4_PTA6
MR4_PTA5
28
29
MR4_PTA4
27
MR4_PTA3
MR4_PTA2
26
MR4_PTA1
25
MR4_PTA0
24
23
11
MR4_PWM6
MR4_PWM5
MR4_PWM4
9
10
MR4_PWM3
MR4_PWM2
MR4_PWM1
8
7
6
MR4_PTC[0..1]
PAGE 10
MR4_PTB[0..6]
PAGE 3,10
MR4_PTA[0..6]
PAGE 10
MR4_PWM[1..6]
PAGE 10
3
3
4.0000MHz
PAGE 3,10
RST#
PAGE 4..6,10
IRQ#
PAGE 4..6,10
C46 +
1uF, 16V
L14
C40
0.022uF
C38
0.1uF
FERRITE, 70 OHM
FERRITE, 70 OHM
L15
C39
0.1uF
L13
FERRITE, 70 OHM
C42
0.1uF
2
VDD_SW
2
4
22
7
5
6
2
8
1
3
21
VSSA
VSS
CGMXFC
OSC2
OSC1
RST#
IRQ#
VREFH
VDDA
VDD
XU4
15
24
23
20
19
18
17
16
28
27
26
25
14
13
12
11
10
9
MR4_PTC0
MR4_PTB6
MR4_PTB5
MR4_PTB4
MR4_PTB3
MR4_PTB2
MR4_PTB1
MR4_PTB0
MR4_PTA3
MR4_PTA2
MR4_PTA1
MR4_PTA0
MR4_PWM6
MR4_PWM5
MR4_PWM4
MR4_PWM3
MR4_PWM2
MR4_PWM1
Updated 28 APR 00
MR4_PTC[0..1]
PAGE 10
MR4_PTB[0..6]
PAGE 3,10
MR4_PTA[0..6]
PAGE 10
MR4_PWM[1..6]
PAGE 10
B
Size
Title:
Dwg.
No.
1
63BSE10033W
Sheet
9
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
PTC0/FAULT1
PTB6/TCH3
PTB5/TCH2
PTB4/TCH1
PTB3/TCH0
PTB2/TCLK
PTB1/TxD
PTB0/RxD
PTA3/ATD3
PTA2/ATD2
PTA1/ATD1
PTA0/ATD0
PWM6
PWM5
PWM4
PWM3
PWM2
PWM1
MC68HC908MRx-28DIP
1
A
B
C
D
A
B
C
D
TGT_IRQ#
PAGE 4,7,8
4.0000MHz
PAGE 3,9
TGT_RST#
PAGE 7,8
5
0
MR8/4 TGT CLOCK
W6
I
MR4_PWM[1..6]
PAGE 9
MR4_PTC[0..1]
PAGE 9
MR4_PTB[0..6]
PAGE 3,9
MR4_PTA[0..6]
PAGE 9
5
1
3
11
12
13
14
MR4_PWM3
MR4_PWM4
MR4_PWM5
MR4_PWM6
4
9
10
MR4_PWM2
8
7
6
5
4
3
2
1
MR4_PWM1
MR4_PTB6
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
PWM6
PWM5
PWM4
PWM3
PWM2
PWM1
IRQ#
PTC0
PTB0
PTB1
PTB2
PTB3
PTB4
VDD
VSS
PTB5
PTB6
PTA0
PTA1
PTA2
PTA3
SKT_28PIN
CGMXFC
OSC1
OSC2
VSSA
VDDA
RST#
VREFH
J11
HEADER 20X2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
J6
15
16
17
18
19
20
21
22
23
24
25
26
27
28
MR4_PTC0
TGT_MR4_PTB0
TGT_MR4_PTB1
MR4_PTB2
MR4_PTB3
MR4_PTB4
MR4_PTB5
MR4_PTB6
MR4_PTA0
MR4_PTA1
MR4_PTA2
MR4_PTA3
MR4_TGT_CLOCK
TGT_RST#
MR4_PWM2
MR4_PWM6
MR4_PTB4
MR4_PTA4
MR8/4 TARGET HEADER A
MR4_PWM1
MR4_PWM5
MR4_PTA3
MR4_PTA5
MR4_PTB3
4
3
3
RST#
PAGE 4..6,9
IRQ#
PAGE 4..6,9
MR4_PTB0
MR4_PTB1
MR4_PTB5
MR4_PTA0
MR4_PWM3
MR4_PTC0
MR4_PTC1
MR4_PTA2
MR4_PTA6
TGT_MR4_PTB1
2
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
2
4
6
8
10
12
14
16
MON08
MR8/4
1
3
5
7
9
11
13
15
J8
TGT_MR4_PTB[0..1]
HEADER 20X2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
J5
RST_IN#
PAGE 4,8
TGT_IRQ#
PAGE 4,7,8
1
Updated 28 APR 00
TGT_IRQ#
PAGE 4,7,8
B
Size
Title:
Dwg.
No.
1
63BSE10033W
Sheet
10
of
10
E
Rev:
AUSTIN, TX 78735 USA
IN CIRCUIT SIMULATOR - ICS08MR
6501 WILLIAM CANNON DRIVE WEST
SEMICONDUCTOR PRODUCTS SECTOR
MOTOROLA
TGT_MR4_PTB0
TGT_MR4_PTB1
TGT_IRQ#
MR4_PWM4
TGT_MR4_PTB0
MR4_PTB2
MR4_PTA1
MR8/4 TARGET HEADER B
2
A
B
C
D
User’s Manual — M68ICS08MR In-Circuit Simulator
Section 4. Using the MON08 Interface
4.1 Introduction
The MON08 debugging interface is used to debug and program an MCU that is
installed on your target application. To facilitate this operation, your target
board MCU must be connected to the appropriate MRICS’s MONO8 connector
by a MON08 interface cable. This section explains how to accomplish the
MON08 interface connection.
4.2 Target System Header Placement
Two headers are available for use on the target board, however only one is used
at a time for a given application. The header used is dependent upon which
MCU is selected for installation.
•
MR16/32 — 16-pin header, such as Berg Electronics part number
67997-616, installed in J7 (Table 4-1)
•
MR4/8 — 16-pin header, such as Berg Electronics part number
67997-616, installed in J8 (Table 4-2)
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Table 4-1. MR16/32 MON08 Target System Connector J7
Pin
No.
M68ICS08MR
Label
Direction
1
RST-OUT
Out to target
2
GND
Ground
3
RST-IN
In from target
Connect to all logic that generates resets.
4
RST
Bidirectional
Connect to MCU RST pin and P1 pin 1. No other target-system
logic should be tied to this signal. It will swing from 0 to +8.6 Vdc.
5
TGT-IRQ
In from target
Connect to logic that generates interrupts.
6
IRQ
Out to target
Connect to MCU IRQ pin. No other target-system logic should be
tied to this signal. It will swing from 0 to +8.6 Vdc.
7
TGT-PTA0
Bidirectional
Connect to user circuit that would normally be connected to PTA0
on the MCU. This circuit will not be connected to the MCU when
the in-circuit simulator is being used.
8
PTA0
Bidirectional
Connect to MCU PTA0 pin. No other target-system logic should be
tied to this signal. Host I/O present on this pin.
9
TGT-PTB0
Bidirectional
Connect to user circuit that normally would be connected to PTB0
on the MCU.
10
PTB0
Bidirectional
Connect to MCU PTB0 pin. No other target-system logic should be
tied to this signal. Grounded during reset and for 256 cycles after
reset.
11
TGT-PTB2
Bidirectional
Connect to user circuit that normally would be connected to PTB2
on the MCU.
12
PTB2
Bidirectional
Connect to MCU PTB2 pin. No other target-system logic should be
tied to this signal. Held at +5 Vdc during reset.
13
TGT-PTB3
Bidirectional
Connect to user circuit that normally would be connected to PTB3
on the MCU.
14
PTB3
Bidirectional
Connect to MCU PTB3 pin. No other target-system logic should be
tied to this signal. Grounded during reset.
15
NC
NC
Not connected
16
NC
NC
Not connected
Target System Connection
Connect to logic that is to receive the RST signal.
Connect to ground (VSS).
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Using the MON08 Interface
Target System Header Placement
Table 4-2. MR4/8 MON08 Target System Connector J8
Pin
No.
M68ICS08MR
Label
Direction
1
RST-OUT
Out to target
2
GND
Ground
3
MR4_PTB0
Bidirectional
Connect to MCU PTB0 pin. No other target-system logic should be
tied to this signal. Grounded during reset and for 256 cycles after
reset.
4
TGT_MR4_PTB0
Bidirectional
Connect to user circuit that normally would be connected to PTB0
on the MCU.
5
MR4_PTB1
Bidirectional
Connect to MCU PTB1 pin. No other target-system logic should be
tied to this signal. Held at +5 Vdc during reset.
6
TGT_MR4_PTB1
Bidirectional
Connect to user circuit that normally would be connected to PTB1
on the MCU.
7
IRQ
Out to target
Connect to MCU IRQ pin. No other target-system logic should be
tied to this signal. It will swing from 0 to +8.6 Vdc.
8
TGT-IRQ
In from target
Connect to logic that generates interrupts.
9
RST
Bidirectional
Connect to MCU RST pin and P1 pin 1. No other target-system
logic should be tied to this signal. It will swing from 0 to +8.6 Vdc.
10
RST-IN
In from target
Connect to all logic that generates resets.
11
NC
NC
Not connected
12
NC
NC
Not connected
13
NC
NC
Not connected
14
NC
NC
Not connected
15
NC
NC
Not connected
16
NC
NC
Not connected
Target System Connection
Connect to logic that is to receive the RST signal.
Connect to ground (VSS).
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Using the MON08 Interface
4.3 Target Requirements for Using MON08
The MRICS connects PTB1..3 to TGT-PTB1..3, except during reset. During
reset, PTB1..3 have voltages placed on them that configure the processor to
enter the proper mode when coming out of reset.(The preceding is true for the
MR16/32 but not the MR4/8) Refer to Section 9, Monitor ROM, in the Motorola
MC68HC908MR manual for more information. PTB0 will not be connected to
TGT-PTB0 because this signal is used for serial communications with the
debugging software.(This sentence should refer to PTA0 and TGT_PTA0 for
the MR16/32. For the MR4/8 it should be PTB0 and PTB1 not connected to
TGT_MR4_PTB0 and TGTMR4_PTB1)
Any pullups on the reset and IRQ signals should be on the target board side of
the MON08 connector and not on the MCU side. Any connections to RST or
IRQ may cause MON08 debugging to fail and may damage components on the
target since these signals will go up to 8.6 Vdc.
4.4 Connecting to the In-Circuit Simulator
Using the 16-pin cable provided with the MRICS kit, connect one end of the
cable to the MRICS board at J7 (for the MR16/32) or J8 (for the MR4/8).
Connect the other end to connector P1 on the target-system board. The pin-1
indicators on each cable end must correspond to the pin-1 indicators on the
headers. P2 is not used when connecting to the MRICS board.
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Appendix A. S-Record Information
A.1 Introduction
The Motorola S-record format was devised to encode programs or data files in
a printable format for transport between computer platforms. The format also
supports editing S-records and monitoring cross-platform transfer processes.
A.2 S-Record Contents
Each S record (Table A-1) is a character string composed of several fields
which identify:
•
Record type
•
Record length
•
Memory address
•
Code/data
•
Checksum
Each byte of binary data is encoded in the S record as a 2-character hexadecimal
number:
•
The first character represents the high-order four bits of the byte.
•
The second character represents the low-order four bits of the byte.
Table A-1. S-Record Fields
Record
Type
Record
Length
Memory
Address
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Code/Data
Checksum
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S-Record Information
The S-record fields are described in Table A-2.
Table A-2. S-Record Field Contents
Field
Printable
Characters
Type
2
S-record type — S0, S1, etc.
Record
Length
2
Character pair count in the record, excluding the
type and record length
Address
4, 6, or 8
2-, 3-, or 4-byte address at which the data field is
to be loaded into memory
0 – 2n
From 0 to n bytes of executable code, memory
loadable data, or descriptive information. For
compatibility with teletypewriter, some programs
may limit the number of bytes to as few as 28
(56 printable characters in the S-record).
2
Least significant byte of the one’s complement of
the sum of the values represented by the pairs of
characters making up the record length,
address, and the code/data fields
Code/Data
Checksum
Contents
Each record may be terminated with a CR/LF/NULL. Additionally, an S-record
may have an initial field to accommodate other data such as the line number
generated by some time-sharing systems.
Accuracy of transmission is ensured by the record length (byte count) and
checksum fields.
A.3 S-Record Types
Eight types of S-records have been defined to accommodate the several needs
of the encoding, transport, and decoding functions. The various Motorola
upload, download, and other record transport control programs (as well as cross
assemblers, linkers, and other file-creating or debugging programs) utilize only
those S-records which serve the purpose of the program.
For specific information on which S-records are supported by a particular
program, consult the user manual for the program.
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S-Record Information
S Record Creation
NOTE:
The ICS08MR supports only the S0, S1, and S9 record types. All data before the
S1 record is ignored. Thereafter, all records must be S1 type until the S9 record,
which terminates data transfer.
An S-record format may contain the record types in Table A-3.
Table A-3. S-Record Types
Record Type
Description
S0
Header record for each block of S-records. The code/data field
may contain any descriptive information identifying the following
block of S records. The address field is normally 0s.
S1
Code/data record and the 2-byte address at which the code/data
is to reside
S2 – S8
S9
Not applicable to MRICS
Termination record for a block of S1 records. Address field may
optionally contain the 2-byte address of the instruction to which
control is to be passed. If not specified, the first interplant
specification encountered in the input will be used. There is no
code/data field.
Only one termination record is used for each block of S-records. Normally, only
one header record is used, although it is possible for multiple header records to
occur.
A.4 S Record Creation
S-record format programs may be produced by dump utilities, debuggers, cross
assemblers, or cross linkers. Several programs are available for downloading a
file in the S-record format from a host system to an 8- or 16-bit
microprocessor-based system.
A.5 S-Record Example
A typical S-record format, as printed or displayed, is shown in this example:
S00600004844521B
S1130000285F245F2212226A00042429008237C2A
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S-Record Information
S11300100002000800082529001853812341001813
S113002041E900084#42234300182342000824A952
S107003000144ED492
S9030000FC
In the example, the format consists of:
•
An S0 header
•
Four S1 code/data records
•
An S9 termination record
A.5.1 S0 Header Record
The S0 header record is described in Table A-4.
Table A-4. S0 Header Record
Field
S-Record
Entry
Type
S0
S-record type S0, indicating a header record
Record
Length
06
Hexadecimal 06 (decimal 6), indicating six
character pairs (or ASCII bytes) follow
Address
00
00
4-character, 2-byte address field; 0s
Description
Code/Data
48
44
52
Descriptive information identifies these S1
records:
ASCII H
D
R — “HDR”
Checksum
1B
Checksum of S0 record
A.5.2 First S1 Record
The first S1 record is described in Table A-5.
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S-Record Information
S-Record Example
Table A-5. S1 Header Record
Field
S-Record
Entry
Description
Type
S1
S-record type S1, indicating a code/data record
to be loaded/verified at a 2-byte address
Record
Length
13
Hexadecimal 13 (decimal 19), indicating 19
character pairs, representing 19 bytes of binary
data, follow
Address
0000
4-character, 2-byte address field; hexadecimal
address 0000 indicates location where the
following data is to be loaded
Opcode
Code/Data
Checksum
28
24
22
22
00
29
08
5F
5F
12
6A
04
00
23
Instruction
24
7C
2A
BHCC
BCC
BHI
BHI
BRSET
BHCS
BRSET
$0161
$0163
$0118
$0172
0, $04, $012F
$010D
4, $23, $018C
Checksum of the first S1 record
The 16 character pairs shown in the code/data field of Table A-5 are the ASCII
bytes of the actual program.
The second and third S1 code/data records each also contain $13 (19T)
character pairs and are ended with checksum 13 and 52, respectively. The fourth
S code/data record contains 07 character pairs and has a checksum of 92.
A.5.3 S9 Termination Record
The S9 termination record is described in Table A-6.
Table A-6. S9 Header Record
Field
S-Record
Entry
Description
Type
S9
S-record type S9, indicating a termination record
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S-Record Information
Table A-6. S9 Header Record
Field
S-Record
Entry
Description
Record
Length
03
Hexadecimal 04, indicating three character pairs
(three bytes) follow
Address
00
00
4-character, 2-byte address field; zeroes
Code/Data
There is no code/data in an S9 record.
Checksum
FC
Checksum of S9 record
A.5.4 ASCII Characters
Each printable ASCII character in an S record is encoded in binary. Table A-5
gives an example of encoding for the S1 record. The binary data is transmitted
during a download of an S record from a host system to a 9- or 16-bit
microprocessor-based system. For example, the first S1 record in Table A-5 is
sent as shown in Figure A-1.
TYPE
S
5
LENGTH
1
3
3
1
1
3
ADDRESS
3
1
3
0
3
3
0
0
3
CODE/DATA
0
0
3
0
0
3
2
0
3
8
2
3
5
8
3
F
5
4
6
0101 0011 0011 0001 0011 0001 0011 0011 0011 0000 0011 0000 0011 0000 0011 0000 0011 0010 0011 1000 0011 0101 0100 0110
...
CHECKSUM
...
2
...
...
3
A
2
4
1
0011 0010 0100 0001
Figure A-1. S-1 Record Example
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User’s Manual — M68ICS08MR In-Circuit Simulator
Appendix B. Quick Start Hardware Configuration Guide
B.1 Introduction
This quick start guide explains the:
•
Configuration of the M68ICS08MR in-circuit simulator (MRICS) board
•
Installation of the hardware
•
Connection of the board to a target system
There are four methods for configuring the MRICS: standalone, simulation,
evaluation, and programming.
ESD CAUTION:
•
Standalone — ICS08MRZ.exe is running on the host computer (the
MRICS is not connected). Emulation of the M68HC(9)08MR MCU
CPU, registers, and I/O ports within the host computer environment.
•
Simulation — Host computer is connected to the MRICS via the RS-232
cable and the ICS08MRZ.exe is running on the host computer. This
provides access to the M68HC(9)08MR MCU CPU, internal registers,
and I/O ports.
•
Evaluation — Host computer is connected to the MRICS and the MRICS
is connected to the target system via the flex cable. This method provides
limited real-time evaluation of the MCU and debugging user developed
hardware and software.
•
Programming — Host computer is connected to the MRICS, and the
MRICS is connected to the target system via the MON08 cable. Use the
PROG08SZ.exe to program the MCU FLASH module. In the
programming mode there is limited evaluation (port A0 on the MR24/32,
and port B0 and port B1 on the MR4/8 are used for communications, so
they are unavailable for emulation).
Ordinary amounts of static electricity from clothing or the work environment
can damage or degrade electronic devices and equipment. For example, the
electronic components installed on the printed circuit board are extremely
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sensitive to electrostatic discharge (ESD). Wear a grounding wrist strap
whenever handling any printed circuit board. This strap provides a conductive
path for safely discharging static electricity to ground.
B.1.1 MRICS Configurable Jumper Headers
Configure the seven jumper headers on the MRICS for your application
according to the tables in this section.
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Introduction
B.1.1.1 MC68HC908MR16/32 Quick Start Configuration - Standalone Mode
Table B-1. MC68HC908MR16/32 Quick Start Jumper Header Configuration
Jumper Header
W1
MR16/32
clock
selection
W2
Target
reset
selection
Type
1
Description
3
2
Jumper on pins 2 and 3 — Disconnects the MC68HC908MR16/32 clock
from the target system. This position is labeled O.
Not applicable when using an MC68HC908MR16/32 MCU in standalone
mode.
NA
W3
I/O baud rate
selection:
MR16/32 only
1
W4
Serial
communication
selection
1
W5
XTAL
clock
enable
1
2
3
2
3
2
3
Jumper on pins 1 and 2 (factory default) — MR16/32 I/O baud rate is set to
9600. This position is labeled 9600.
Jumper on pins 1 and 2 (factory default) — MC68HC908MR16/32 MCU is
installed. This position is labeled MR32/16.
Jumper on pins 2 and 3 (factory default) — MRICS XTAL clocks are
enabled: 4.9152 MHz for the MC68HC908MR16/32 MCUs. This position
is labeled I.
W6
MR4/8
target
clock
W7
MRICS
reset clock
Not applicable when using an MC68HC908MR16/32 MCU in standalone
mode.
NA
1
2
3
Jumper on pins 1 and 2 (factory default) — Reset clock set at 4.9152 MHz.
Use this setting when using the MC68HC908MR16/32 MCUs. This
position is labeled MR32/16.
B.1.1.2 MC68HC908MR4/8 Quick Start Configuration - Standalone Mode
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Table B-2. MC68HC(9)08MR4/8 Quick Start Jumper Header Configuration
Jumper Header
Type
Description
W1
MR16/32
clock
selection
NA
Not applicable when using an MC68HC(9)08MR4/8 MCU in standalone
mode.
W2
Target
reset
selection
NA
Not applicable when using an MC68HC(9)08MR4/8 MCU in standalone
mode.
W3
I/O baud rate
selection:
MR16/32 only
NA
Not applicable when using an MC68HC(9)08MR4/8 MCU in standalone
mode.
W4
Serial
communication
selection
1
W5
XTAL
clock
enable
1
2
3
2
3
Jumper on pins 2 and 3 — MC68HC(9)08MR4/8 is installed. This position is
labeled MR8/4.
Jumper on pins 2 and 3 — MRICS XTAL clock is enabled: 4.0000 MHz for
the MC68HC(9)08MR4/8 MCUs. This position is labeled I.
W6
MR4/8
target
clock
W7
MRICS
reset clock
1
2
Jumper on pins 2 and 3: Disconnects the MC68HC(9)08MR4/8 clock from
the target system. This position is labeled O.
3
1
2
3
Jumper on pins 2 and 3: Reset clock set at 4.000 MHz. This position is
labeled MR8/4.
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Introduction
B.1.2 Target Interface Cable Connections
Table B-3. MCU Version to Cable/Connector Configuration
Flex Cable
M68CLB05C
Ribbon Cable
(User Supplied)
MON08 Cable
MC68HC08MR4
J5 and J6
J11
J8
MC68HC908MR8
J5 and J6
J11
J8
MC68HC908MR16
J2 and J3
J1
J7
MC68HC908MR32
J2 and J3
J1
J7
MCU
B.1.3 Host Computer — MRICS Interconnection (J12)
Connect the DE9 serial cable. Connect one end of this cable to your host PC and
the other end to connector J12 on the MRICS board.
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B.2 Installing the Hardware
For installing Motorola development tools, the following steps provide
installation instructions for the MRICS hardware.
Before beginning, locate these items:
•
9-pin RS-232 serial connector on the board, labeled J12
•
5-volt circular power-input connector on the MRICS (J4)
To prepare the MRICS for use with a host PC:
1. Install the MCU into the M68ICS08MR board.
Locate the appropriate socket on the board:
–
For 56-pin SDIP MC68HC908MR16/32, locate XU1
–
For 28-pin DIP MC68HC(9)08MR4/8, locate XU4
–
For 64-pin QFP MC68HC908MR16/32, locate XU2 (a 64-pin QFP
MC68HC908MR32 is provided in the kit)
–
For 32-pin QFP MC68HC(9)08MR4/8, locate XU3
Install an MCU (provided with the MRICS package) into the appropriate
socket, observing the pin 1 orientation with the silkscreened dot. The top
(label side) of the MCU package must be visible when looking at the
component side of the board.
2. Connect the board to the host PC.
Locate the 9-pin connector labeled J12 on the board. Using the cable
provided, connect it to a serial COM port on the host PC.
3. Apply power to the board.
Connect the 5-volt power supply to the round connector on the board, J4.
Plug the power supply into an ac power outlet, using one of the
country-specific adapters provided. The ICS power LED on the board
should light.
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Installing the Software
B.3 Installing the Software
For instructions for installing the ICS08 software, refer to P&E Microcomputer
Systems, Inc., M68ICS08 68HC08 In-Circuit Simulator Operator’s Manual,
Motorola document order number M68ICS08OM/D.
B.4 Connecting to a Target System
The three ways to connect the M68ICS08MR simulator board to a target system
are via:
•
The flex cable
•
The ribbon cable
•
The MON08 cable
Connect the simulator board to the target system using one of these methods:
•
Using a flex cable
When emulating an MC68HC908MR16/32 MCU, connect the 80-pin
M68CLB05C flex cable (provided with the kit) to the connectors labeled
J2 and J3 on the simulator board. (Use the same cable when emulating an
MC68HC(9)08MR4/8 MCU, but connect it to J5 and J6 on the MRICS
board.) Attach the other end of the cable to the appropriate connector on
the target system. Target head adapters are available for the 56-pin SDIP,
28-pin DIP, 32-pin QFP, and 64-pin QFP versions of the MCU.
•
Using a ribbon cable
When emulating an MC68HC908MR16/32 MCU connect a 60-pin flat
ribbon cable to connector J1 on the simulator board. Attach the other end
of the cable to the appropriate connector on the target system. When
emulating an MC68HC(9)08MR4/8 MCU connect a 28-pin DIP cable to
connector J11 on the simulator board. Attach the other end of the cable
to the appropriate connector on the target system.
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•
Using a MON08 cable
Connect the MON08 debug interface cable to the appropriate MON08
debug interface connector (either J7 or J8) for communication with the
target system’s MCU. The MON08 cable lets you program and debug the
target system’s MCU FLASH. An MCU must be installed in the target
system while the MRICS board’s MCU must be removed.
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Glossary
8-bit MCU — A microcontroller whose data is communicated over a data bus
made up of eight separate data conductors. Members of the
MC68HC(9)08 Family of microcontrollers are 8-bit MCUs.
A — An abbreviation for the accumulator of the HC08 MCU.
accumulator — An 8-bit register of the HC08 CPU. The contents of this
register may be used as an operand of an arithmetic or logical
instruction.
assembler — A software program that translates source code mnemonics into
opcodes that can then be loaded into the memory of a microcontroller.
assembly language — Instruction mnemonics and assembler directives that
are meaningful to programmers and can be translated into an object
code program that a microcontroller understands. The CPU uses
opcodes and binary numbers to specify the operations that make up a
computer program. Humans use assembly language mnemonics to
represent instructions. Assembler directives provide additional
information such as the starting memory location for a program. Labels
are used to indicate an address or binary value.
ASCII — American Standard Code for Information Interchange. A widely
accepted correlation between alphabetic and numeric characters and
specific 7-bit binary numbers.
breakpoint — During debugging of a program, it is useful to run instructions
until the CPU gets to a specific place in the program, and then enter a
debugger program. A breakpoint is established at the desired address
by temporarily substituting a software interrupt (SWI) instruction for
the instruction at that address. In response to the SWI, control is passed
to a debugging program.
byte — A set of exactly eight binary bits.
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Glossary
clock — A square wave signal that is used to sequence events in a computer.
command set — The command set of a CPU is the set of all operations that
the CPU knows how to perform. One way to represent an instruction set
is with a set of shorthand mnemonics such as LDA meaning load A.
Another representation of an instruction set is the opcodes that are
recognized by the CPU.
CPU — Central processor unit. The part of a computer that controls execution
of instructions.
CPU cycles — A CPU clock cycle is one period of the internal bus-rate clock.
Normally, this clock is derived by dividing a crystal oscillator source by
two or more so the high and low times will be equal. The length of time
required to execute an instruction is measured in CPU clock cycles.
CPU registers — Memory locations that are wired directly into the CPU logic
instead of being part of the addressable memory map. The CPU always
has direct access to the information in these registers. The CPU
registers in an MC68HC908 are A (8-bit accumulator), X (8-bit index
register), CCR (condition code register containing the H, I, N, Z, and C
bits), SP (stack pointer), and PC (program counter).
cycles — See CPU cycles.
data bus — A set of conductors that are used to convey binary information
from a CPU to a memory location or from a memory location to a CPU;
in the HC08, the data bus is 8-bits.
development tools — Software or hardware devices used to develop computer
programs and application hardware. Examples of software
development tools include text editors, assemblers, debug monitors,
and simulators. Examples of hardware development tools include
simulators, logic analyzers, and PROM programmers. An in-circuit
simulator combines a software simulator with various hardware
interfaces.
DIP — Dual in-line package.
DTR — Data transfer request.
EPROM — Erasable, programmable read-only memory. A non-volatile type
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of memory that can be erased by exposure to an ultra-violet light
source. MCUs that have EPROM are easily recognized by their
packaging: a quartz window allows exposure to UV light. If an
EPROM MCU is packaged in an opaque plastic package, it is termed a
one-time-programmable OTP MCU, since there is no way to erase and
rewrite the EPROM.
EEPROM — Electrically erasable, programmable read-only memory.
ESD — Electrostatic discharge.
IC — Integrated circuit.
index register — An 8-bit CPU register in the HC08 that is used in indexed
addressing mode. The index register (X) also can be used as a
general-purpose 8-bit register in addition to the 8-bit accumulator.
input-output (I/O) — Interfaces between a computer system and the external
world. For example, a CPU reads an input to sense the level of an
external signal and writes to an output to change the level on an
external signal.
instructions — Instructions are operations that a CPU can perform.
Instructions are expressed by programmers as assembly language
mnemonics. A CPU interprets an opcode and its associated operand(s)
as an instruction.
listing — A program listing shows the binary numbers that the CPU needs
alongside the assembly language statements that the programmer
wrote. The listing is generated by an assembler in the process of
translating assembly language source statements into the binary
information that the CPU needs.
LSB — Least significant bit.
MCU – Microcontroller unit — Microcontroller. A complete computer
system including CPU, memory, clock oscillator, and I/O on a single
integrated circuit.
MRICS — M68ICS08MR in-circuit simulator and programmer board.
MR4/8 — MCUs MC68HC08MR4 and MC68HC908MR8.
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MR32 — MCU MC68HC908MR32.
MSB — Most significant bit.
N — Abbreviation for negative, a bit in the condition code register of the
HC08. In two’s-complement computer notation, positive signed
numbers have a 0 in their MSB (most significant bit) and negative
numbers have a 1 in their MSB. The N condition code bit reflects the
sign of the result of an operation. After a load accumulator instruction,
the N bit will be set if the MSB of the loaded value was a 1.
object code file — A text file containing numbers that represent the binary
opcodes and data of a computer program. An object code file can be
used to load binary information into a computer system. Motorola uses
the S-record file format for object code files.
operand — An input value to a logical or mathematical operation.
opcode — A binary code that instructs the CPU to do a specific operation in a
specific way. The HC08 CPU recognizes 210 unique 8-bit opcodes that
represent addressing mode variations of 62 basic instructions.
OTPROM — A non-volatile type of memory that can be programmed but
cannot be erased. An OTPROM is an EPROM MCU that is packaged in
an opaque plastic package. It is called a one-time-programmable MCU
because there is no way to expose the EPROM to a UV light.
PC — Abbreviation for program counter CPU register of the HC08.
PCBA — Printed circuit board assembly.
PLL — Phase-locked loop.
program counter — The CPU register that holds the address of the next
instruction or operand that the CPU will use.
QFP — Quad flat pack.
RAM — Random access memory. Any RAM location can be read or written
by the CPU. The contents of a RAM memory location remain valid
until the CPU writes a different value or until power is turned off.
registers — Memory locations that are wired directly into the CPU logic
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instead of being part of the addressable memory map. The CPU always
has direct access to the information in these registers. The CPU
registers in the HC08 are A (8-bit accumulator), X (8-bit index
register), CCR (condition code register containing the H, I, N, Z, and C
bits), SP (stack pointer), and PC (program counter). Memory locations
that hold status and control information for on-chip peripherals are
called I/O and control registers.
reset — Reset is used to force a computer system to a known starting point and
to force on-chip peripherals to known starting conditions.
S record — A Motorola standard format used for object code files.
SDIP — Skinny dual in-line package.
simulator — A computer program that copies the behavior of a real MCU.
source code — See source program.
SP — Abbreviation for stack pointer CPU register in the HC08 MCU.
source program — A text file containing instruction mnemonics, labels,
comments, and assembler directives. The source file is processed by an
assembler to produce a composite listing and an object file
representation of the program.
stack pointer — A CPU register that holds the address of the next available
storage location on the stack.
TTL — Transistor-to-transistor logic.
TVS — Transient voltage suppression.
VDD — The positive power supply to a microcontroller (typically 5 volts dc).
VSS — The 0-volt dc power supply return for a microcontroller.
Word — A group of binary bits. Some larger computers consider a set of
16 bits to be a word but this is not a universal standard.
X — Abbreviation for index register, a CPU register in the HC08.
Z — Abbreviation for zero, a bit in the condition code register of the HC08. A
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compare instruction subtracts the contents of the tested value from a
register. If the values were equal, the result of this subtraction would be
0 so the Z bit would be set; after a load accumulator instruction, the Z
bit will be set if the loaded value was $00.
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User’s Manual — M68ICS08MR In-Circuit Simulator
Index
A
ASCII
characters 80
assembler
description 14
B
baud rates 17
bus frequency 17
bus frequency selection 17
C
cables
flex target 52
CASM08Z 14
description 14
checksum 75
communications 18
connectors
Target 38, 40, 42, 44
Target DIP 48, 51
D
debuggers
ICD08SW
description 10
MON08 interface 71
E
examples
S records 77
F
features 10
FLASH memory 11, 14
Flex 12
flex target cable 12
function keys 10
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H
hardware
installation 17, 81
requirements 14
host 9
hotkeys. See function keys
humidity 15
I
ICD08SZ
debugger 12
description 14
ICG
MON08 limitations to 18
ICS PWR LED 86
ICS08MR software 12
ICS08MRZ
description 14
simulator 12
integrated development environment 14
L
LED
ICS power 86
limitations
ICG MON08 18
LVI MON08 18
MRICS 17
LVI
MON08 limitations to 18
M
M68CLB05C 12
M68ICS08MR 9
M68ICS08MR board 17, 35, 81, 86
M68ICS08MR in-circuit simulator
components 12
hardware 14
M68ICS08RK in-circuit simulator
features 10
M68ICS08RK2 board 37
MC68HC908MR MCUs 12
MC68HC908MR32 9
MC68HC908MR4 9
MC68HC908MR8 9
MCU 9, 13
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MCU subsystem
clocks 23
target interface connector 26, 28
memory
address 75
system requirements 14
MON08 12, 13, 52
MONO8 9
Motorola 9
MRICS 12
limitations 17
software 12
MRICS limitations 17
O
operating systems 14
P
port A0 18
port B0 18
port B1 18
Power 12
power
connector 86
requirements 15
power connector 86
PROG08SZ
description 14
R
RAM 10, 14
record length 75
record type 75
relative humidity 15
requirements
hardware 14
software 14
RS 9
RS-232 serial connector 86
S
S records 75–80
Serial 12
serial port
connector 86
software
ICS08MR (or MRICS software) 14
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MRICS (or ICS08MR software) 14
requirements 14
SOIC 12
S-record
content 75
creating 77
field contents 76
fields 75
overview 75
S0 record 78
S1 record 78
S9 record 79
termination record 79
types 76
T
target 9
target system
cables 52–56
connecting to 9
connectors 37–52
description 9
MON08 interface 71
temperature
operating 15
storage 15
W
Windows 95 9
Windows 98 9
WinIDE 10
description 14
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MOTOROLA
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