Instruction Manual
TMS 222
MCF5206/5206E Microprocessor Support
071-0149-01
Warning
The servicing instructions are for use by
qualified personnel only. To avoid personal
injury, do not perform any servicing unless you
are qualified to do so. Refer to all safety
summaries prior to performing service.
Copyright E T ektronix, Inc. All rights reserved. Licensed software products are owned by Tektronix or its suppliers and are
protected by United States copyright laws and international treaty provisions.
Use, duplication, or disclosure by the Government is subject to restrictions as set forth in subparagraph (c)(1)(ii) of the
Rights in T echnical Data and Computer Software clause at DFARS 252.227-7013, or subparagraphs (c)(1) and (2) of the
Commercial Computer Software – Restricted Rights clause at F AR 52.227-19, as applicable.
T ektronix products are covered by U.S. and foreign patents, issued and pending. Information in this publication supercedes
that in all previously published material. Specifications and price change privileges reserved.
Printed in the U.S.A.
T ektronix, Inc., P.O. Box 1000, Wilsonville, OR 97070–1000
TEKTRONIX and TEK are registered trademarks of T ektronix, Inc.
SOFTWARE WARRANTY
T ektronix warrants that the media on which this software product is furnished and the encoding of the programs on
the media will be free from defects in materials and workmanship for a period of three (3) months from the date of
shipment. If a medium or encoding proves defective during the warranty period, T ektronix will provide a
replacement in exchange for the defective medium. Except as to the media on which this software product is
furnished, this software product is provided “as is” without warranty of any kind, either express or implied.
T ektronix does not warrant that the functions contained in this software product will meet Customer’s
requirements or that the operation of the programs will be uninterrupted or error-free.
In order to obtain service under this warranty, Customer must notify Tektronix of the defect before the expiration
of the warranty period. If T ektronix is unable to provide a replacement that is free from defects in materials and
workmanship within a reasonable time thereafter, Customer may terminate the license for this software product
and return this software product and any associated materials for credit or refund.
THIS WARRANTY IS GIVEN BY TEKTRONIX IN LIEU OF ANY OTHER WARRANTIES, EXPRESS
OR IMPLIED. TEKTRONIX AND ITS VENDORS DISCLAIM ANY IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. TEKTRONIX’
RESPONSIBILITY TO REPLACE DEFECTIVE MEDIA OR REFUND CUSTOMER’S PAYMENT IS
THE SOLE AND EXCLUSIVE REMEDY PROVIDED TO THE CUSTOMER FOR BREACH OF THIS
WARRANTY. TEKTRONIX AND ITS VENDORS WILL NOT BE LIABLE FOR ANY INDIRECT,
SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES IRRESPECTIVE OF WHETHER
TEKTRONIX OR THE VENDOR HAS ADVANCE NOTICE OF THE POSSIBILITY OF SUCH
DAMAGES.
HARDWARE WARRANTY
T ektronix warrants that the products that it manufactures and sells will be free from defects in materials and
workmanship for a period of one (1) year from the date of shipment. If a product proves defective during this
warranty period, T ektronix, at its option, either will repair the defective product without charge for parts and labor,
or will provide a replacement in exchange for the defective product.
In order to obtain service under this warranty, Customer must notify Tektronix of the defect before the expiration
of the warranty period and make suitable arrangements for the performance of service. Customer shall be
responsible for packaging and shipping the defective product to the service center designated by T ektronix, with
shipping charges prepaid. Tektronix shall pay for the return of the product to Customer if the shipment is to a
location within the country in which the T ektronix service center is located. Customer shall be responsible for
paying all shipping charges, duties, taxes, and any other charges for products returned to any other locations.
This warranty shall not apply to any defect, failure or damage caused by improper use or improper or inadequate
maintenance and care. T ektronix shall not be obligated to furnish service under this warranty a) to repair damage
resulting from attempts by personnel other than T ektronix representatives to install, repair or service the product;
b) to repair damage resulting from improper use or connection to incompatible equipment; c) to repair any
damage or malfunction caused by the use of non-T ektronix supplies; or d) to service a product that has been
modified or integrated with other products when the effect of such modification or integration increases the time
or difficulty of servicing the product.
THIS WARRANTY IS GIVEN BY TEKTRONIX IN LIEU OF ANY OTHER WARRANTIES, EXPRESS
OR IMPLIED. TEKTRONIX AND ITS VENDORS DISCLAIM ANY IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. TEKTRONIX’
RESPONSIBILITY TO REPAIR OR REPLACE DEFECTIVE PRODUCTS IS THE SOLE AND
EXCLUSIVE REMEDY PROVIDED TO THE CUST OMER FOR BREACH OF THIS WARRANTY.
TEKTRONIX AND ITS VENDORS WILL NOT BE LIABLE FOR ANY INDIRECT , SPECIAL,
INCIDENTAL, OR CONSEQUENTIAL DAMAGES IRRESPECTIVE OF WHETHER TEKTRONIX OR
THE VENDOR HAS ADVANCE NOTICE OF THE POSSIBILITY OF SUCH DAMAGES.
Table of Contents
Getting Started
General Safety Summary v. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Service Safety Summary vii. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Preface: Microprocessor Support Documentation ix. . . . . . . . . . . . . . . .
Manual Conventions ix. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Logic Analyzer Documentation x. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contacting T ektronix x. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Support Description 1–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Logic Analyzer Software Compatibility 1–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Logic Analyzer Configuration 1–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Requirements And Restrictions 1–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Microprocessor Functionality Not Supported 1–2. . . . . . . . . . . . . . . . . . . . . . . . . . .
Configuring The Probe Adapter 1–3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Connecting To A System Under Test With A Probe Adapter 1–4. . . . . . . . . . . . . . .
Removing The Probe Adapter From The SUT 1–8. . . . . . . . . . . . . . . . . . . . . . .
Connecting To A System Under Test Without A Probe Adapter 1–8. . . . . . . . . . . . .
Channel Assignments 1–9. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CPU To Mictor Connections 1–15. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Operating Basics
Setting Up the Support 2–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Channel Groups 2–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Custom Clocking 2–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Clocking Options 2–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Symbols 2–3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Acquiring And Viewing Disassembled Data 2–7. . . . . . . . . . . . . . . . . . . . .
Acquiring Data 2–7. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Viewing Disassembled Data 2–7. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Timing Display Format 2–8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
State Display Format 2–8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Hardware Display Format 2–8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Software Display Format 2–11. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Control Flow Display Format 2–11. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Subroutine Display Format 2–11. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Changing How Data is Displayed 2–12. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Optional Display Selections 2–13. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Marking Cycles 2–17. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Displaying Exception Vectors 2–18. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TMS 222 MCF5206/5206E Microprocessor Support
i
Table of Contents
Specifications
Specification Tables 3–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Maintenance
Probe Adapter Description 4–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
T est Clip Inspection 4–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Replaceable Electrical Parts
Parts Ordering Information 5–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Using the Replaceable Electrical Parts List 5–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Diagrams and Circuit Board Illustrations 5–5. . . . . . . . . . . . . . . . . . . . . .
Symbols 5–5. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Component Values 5–5. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Graphic Items and Special Symbols Used in This Manual 5–5. . . . . . . . . . . . . . . . .
Component Locator Diagrams 5–5. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Replaceable Mechanical Parts
Index
Parts Ordering Information 6–1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Using the Replaceable Mechanical Parts List 6–1. . . . . . . . . . . . . . . . . . . . . . . . . . .
ii
TMS 222 MCF5206/5206E Microprocessor Support
List of Figures
List of Tables
Table of Contents
Figure 1–1: Connecting the test clip to the probe adapter 1–5. . . . . . . . .
Figure 1–2: Connecting P6434 probes to the probe adapter 1–6. . . . . . . .
Figure 1–3: Placing the probe adapter onto the SUT 1–7. . . . . . . . . . . . .
Figure 2–1: 5206 Byte Write Transfer from an 8-bit port. 2–2. . . . . . . . .
Figure 2–2: 5206 Byte Read transfer in Normal mode with
8-bit DRAM. 2–3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Figure 2–3: Hardware display format 2–10. . . . . . . . . . . . . . . . . . . . . . . . . .
Figure 3–1: Dimensions of the probe adapter 3–4. . . . . . . . . . . . . . . . . . . .
Table 1–1: DIP switch settings 1–3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Table 1–2: Address group channel assignments 1–9. . . . . . . . . . . . . . . . .
Table 1–3: Data group channel assignments 1–10. . . . . . . . . . . . . . . . . . . .
Table 1–4: Control group channel assignments 1–11. . . . . . . . . . . . . . . . . .
Table 1–5: DataSize group channel assignments 1–12. . . . . . . . . . . . . . . . .
Table 1–6: DramEnbl group channel assignments 1–12. . . . . . . . . . . . . . .
Table 1–7: Misc group channel assignments 1–12. . . . . . . . . . . . . . . . . . . .
Table 1–8: Clock channel assignments 1–13. . . . . . . . . . . . . . . . . . . . . . . . .
Table 1–9: BDM connector pinout 1–13. . . . . . . . . . . . . . . . . . . . . . . . . . . .
Table 1–10: CPU to Mictor connections for Mictor A pins 1–15. . . . . . . .
Table 1–11: CPU to Mictor connections for Mictor C pins 1–17. . . . . . . .
Table 1–12: CPU to Mictor connections for Mictor D pins 1–18. . . . . . . .
Table 1–13: Signals not required for clocking or disassembly 1–20. . . . . .
Table 2–1: Control group symbol table definitions 2–4. . . . . . . . . . . . . . .
Table 2–2: DataSize group symbol table definitions 2–6. . . . . . . . . . . . . .
Table 2–3: Description of special characters in the display 2–7. . . . . . . .
Table 2–4: Cycle type definitions 2–8. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Table 2–5: Address, Chip Select, or Write Enable Matrix 2–14. . . . . . . . .
Table 2–6: Exception vectors 2–18. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Table 3–1: Electrical specifications 3–1. . . . . . . . . . . . . . . . . . . . . . . . . . . .
Table 3–2: Environmental specifications* 3–3. . . . . . . . . . . . . . . . . . . . . .
TMS 222 MCF5206/5206E Microprocessor Support
iii
Table of Contents
iv
TMS 222 MCF5206/5206E Microprocessor Support
General Safety Summary
Review the following safety precautions to avoid injury and prevent damage to
this product or any products connected to it. To avoid potential hazards, use this
product only as specified.
Only qualified personnel should perform service procedures.
While using this product, you may need to access other parts of the system. Read
the General Safety Summary in other system manuals for warnings and cautions
related to operating the system.
To Avoid Fire or
Personal Injury
Connect and Disconnect Properly . Do not connect or disconnect probes or test
leads while they are connected to a voltage source.
Ground the Product. This product is indirectly grounded through the grounding
conductor of the mainframe power cord. To avoid electric shock, the grounding
conductor must be connected to earth ground. Before making connections to the
input or output terminals of the product, ensure that the product is properly
grounded.
Observe All Terminal Ratings. To avoid fire or shock hazard, observe all ratings
and marking on the product. Consult the product manual for further ratings
information before making connections to the product.
Do Not Operate Without Covers. Do not operate this product with covers or panels
removed.
Avoid Exposed Circuitry. Do not touch exposed connections and components
when power is present.
Do Not Operate With Suspected Failures. If you suspect there is damage to this
product, have it inspected by qualified service personnel.
Do Not Operate in Wet/Damp Conditions.
Do Not Operate in an Explosive Atmosphere.
Keep Product Surfaces Clean and Dry .
Provide Proper Ventilation. Refer to the manual’s installation instructions for
details on installing the product so it has proper ventilation.
TMS 222 MCF5206/5206E Microprocessor Support
v
General Safety Summary
Symbols and Terms
T erms in this Manual. These terms may appear in this manual:
WARNING. Warning statements identify conditions or practices that could result
in injury or loss of life.
CAUTION. Caution statements identify conditions or practices that could result in
damage to this product or other property.
T erms on the Product. These terms may appear on the product:
DANGER indicates an injury hazard immediately accessible as you read the
marking.
WARNING indicates an injury hazard not immediately accessible as you read the
marking.
CAUTION indicates a hazard to property including the product.
Symbols on the Product. The following symbols may appear on the product:
WARNING
High Voltage
Protective Ground
(Earth) T erminal
CAUTION
Refer to Manual
Double
Insulated
vi
TMS 222 MCF5206/5206E Microprocessor Support
Service Safety Summary
Only qualified personnel should perform service procedures. Read this Service
Safety Summary and the General Safety Summary before performing any service
procedures.
Do Not Service Alone. Do not perform internal service or adjustments of this
product unless another person capable of rendering first aid and resuscitation is
present.
Disconnect Power. To avoid electric shock, disconnect the main power by means
of the power cord or, if provided, the power switch.
Use Care When Servicing With Power On. Dangerous voltages or currents may
exist in this product. Disconnect power, remove battery (if applicable), and
disconnect test leads before removing protective panels, soldering, or replacing
components.
To avoid electric shock, do not touch exposed connections.
TMS 222 MCF5206/5206E Microprocessor Support
vii
Service Safety Summary
viii
TMS 222 MCF5206/5206E Microprocessor Support
Preface: Microprocessor Support Documentation
This instruction manual contains specific information about the TMS 222
MCF5206 microprocessor support package and is part of a set of information on
how to operate this product on compatible Tektronix logic analyzers.
If you are familiar with operating microprocessor support packages on the logic
analyzer for which the TMS 222 MCF5206 support was purchased, you will
probably only need this instruction manual to set up and run the support.
If you are not familiar with operating microprocessor support packages, you will
need to supplement this instruction manual with information on basic operations
to set up and run the support.
Information on basic operations of microprocessor support packages is included
with each product. Each logic analyzer has basic information describing how to
perform tasks common to support packages on that platform. This information
can be in the form of online help, an installation manual, or a user manual.
This manual provides detailed information on the following topics:
H Connecting the logic analyzer to your system under test
Manual Conventions
H Setting up the logic analyzer to acquire data
H Acquiring and viewing disassembled data
This manual uses the following conventions:
The term “disassembler” refers to the software that disassembles bus cycles
into instruction mnemonics and cycle types.
The phrase “information on basic operations” refers to online help, an
installation manual, or a basic operations of microprocessor supports user
manual.
The term “5206” refers to all supported variations of the MCF5206 micro-
processor unless otherwise noted.
In the information on basic operations, the term MCF5206 refers to both
MCF5206 processor and
The term “logic analyzer” refers to the Tektronix logic analyzer for which
this product was purchased.
MCF5206E processor unless stated otherwise.
A tilde (~) following a signal name indicates an active low signal.
TMS 222 MCF5206/5206E Microprocessor Support
ix
Preface: Microprocessor Support Documentation
Logic Analyzer Documentation
A description of other documentation available for each type of Tektronix logic
analyzer is located in the corresponding module user manual. The manual set
provides the information necessary to install, operate, maintain, and service the
logic analyzer and associated products.
Contacting Tektronix
Product
Support
Service
Support
For other
information
To write us Tektronix, Inc.
For application-oriented questions about a Tektronix measurement product, call toll free in North America:
1-800-TEK-WIDE (1-800-835-9433 ext. 2400)
6:00 a.m. – 5:00 p.m. Pacific time
Or, contact us by e-mail:
tm_app_supp@tektronix.com
For product support outside of North America, contact your
local Tektronix distributor or sales office.
Contact your local Tektronix distributor or sales office. Or, visit
our web site for a listing of worldwide service locations.
www.tektronix.com
In North America:
1-800-TEK-WIDE (1-800-835-9433)
An operator will direct your call.
P.O. Box 1000
Wilsonville, OR 97070-1000
x
TMS 222 MCF5206/5206E Microprocessor Support
Getting Started
Getting Started
This chapter contains information on the TMS 222 microprocessor support, and
information on connecting your logic analyzer to your system under test.
Support Description
The TMS 222 microprocessor support package disassembles data from systems
that are based on the Motorola MCF5206 and MCF5206E microprocessors.
The TMS 222 supports the MCF5206 and MCF5206E microprocessors in a
160-pin QFP package.
To use this support efficiently, you need to have the items listed in the
information on basic operations as well as the MCF5206 User’s Manual,
Motorola, 1995 and the MCF5206E User’s Manual, Motorola, 1998.
Logic Analyzer Software Compatibility
The label on the microprocessor support floppy disk states which version of logic
analyzer software the support is compatible with.
Logic Analyzer Configuration
For use with a Tektronix logic analyzer (TLA) the TMS 222 support requires a
minimum of one 102-channel module.
Requirements And Restrictions
You should review the general requirements and restrictions of microprocessor
supports in the information on basic operations as they pertain to your system
under test.
You should review electrical, environmental, and mechanical specifications in the
Specifications chapter in this manual as they pertain to your system under test, as
well as the following descriptions of other MCF5206 support requirements and
restrictions.
System Clock Rate. The TMS 222 support can acquire data from the MCF5206
microprocessor at speeds of up to 33.33 MHz; it has been tested to 25 MHz and
TMS 222 MCF5206/5206E Microprocessor Support
1–1
Getting Started
MCF5206E microprocessor at speeds of up to 54 MHz; it has been tested to
the
54 MHz.
This specification is valid at the time this manual was printed. Please contact
your Tektronix sales representative for current information on the fastest devices
supported.
Hardware Reset. If a hardware reset occurs in your MCF5206 system during an
acquisition, the disassembler may acquire an invalid sample.
Disabling The Internal Cache. To disassemble acquired data, you must disable the
internal cache. Disabling the cache makes all instruction prefetches visible on the
bus so they can be acquired and disassembled.
Big-Endian Byte Ordering. The disassembler always uses Big-Endian byte
ordering for instruction disassembly. Big-Endian byte ordering is when the most
significant data byte is located at the highest address.
Data Reads And Writes. The disassembler will not link data reads and writes with
the instructions which cause them.
Microprocessor Functionality Not Supported
Cache. Cache must be disabled (turned off) for correct disassembly.
Address Hold. Address Hold is not supported for the default memory region.
Alternate Bus Master Cycles. Alternate Bus Master Cycles are not supported.
1–2
TMS 222 MCF5206/5206E Microprocessor Support
Configuring The Probe Adapter
Configuring the Chip Select Module Switch. The probe adapter has a DIP switch
that must be set according to the chip select module configuration of the
MCF5206. Use Table 1–1 to configure the ChipSelect DIP switch. By default, all
switches are off.
T able 1–1: DIP switch settings
Switch Description
S0 CS0~
S1 CS1~
S2 CS2~
S3 CS3~
S4 CS4~
S5 CS5~
Getting Started
S6 CS6~
S7 CS7~
Examples of Switch Settings. The following example shows two possible settings:
H Example 1
If CS0~, CS1~ and CS2~ are used as ChipSelects, the following configura-
tion would be used:
S0 – ON (CS0~)
S1 – ON (CS1~)
S2 – ON (CS2~)
S3 – OFF (CS3~)
S4 – OFF (CS4~)
S5 – OFF (CS5~)
S6 – OFF (CS6~)
S7 – OFF (CS7~)
TMS 222 MCF5206/5206E Microprocessor Support
1–3
Getting Started
H Example 2
If none of the ChipSelects are used, the following configuration would be
used:
S0 – OFF (CS0~)
S1 – OFF (CS1~)
S2 – OFF (CS2~)
S3 – OFF (CS3~)
S4 – OFF (CS4~)
S5 – OFF (CS5~)
S6 – OFF (CS6~)
S7 – OFF (CS7~)
Connecting To A System Under Test With A Probe Adapter
To connect the logic analyzer to a system under test (SUT) using the probe
adapter and test clip, follow these steps:
Connect The Test Clip To
The Probe Adapter
1. Turn off power to your SUT.
It is not necessary to turn off the logic analyzer.
CAUTION. To prevent static damage, handle all the above only in a static-free
environment. Static discharge can damage the microprocessor, the probe adapter,
the probes, or the module.
Always wear a grounding wrist strap or similar device while handling the
microprocessor and probe adapter.
2. To discharge your stored static electricity, touch the ground connector located
on the logic analyzer.
To connect the test clip to the probe adapter follow these steps:
3. Line up pin 1 on the test clip, to pin 1 on the connector located on the bottom
of the probe adapter circuit board, as shown in Figure 1–1.
1–4
TMS 222 MCF5206/5206E Microprocessor Support
Getting Started
Connect The P6434
Probes To The Probe
Adapter
Figure 1–1: Connecting the test clip to the probe adapter
To connect the P6434 probes to the probe adapter follow these steps:
CAUTION. To prevent damage to the probe and probe adapter, always position the
probe perpendicular to the mating connector and gently connect the probe.
Incorrect handling of the P6434 probe while connecting it to the probe adapter
can result in damage to the probe or to the mating connector on the probe
adapter.
4. Refer to Figure 1–2, and connect the P6434 probes to the probe adapter.
Match the channel groups and numbers on the probe labels to the corre-
sponding connectors on the probe adapter.
5. Position the probe tip perpendicular to the mating connector and gently
connect the probe as shown in Figure 1–2.
6. When connected, push down the latch releases on the probe to set the latch.
TMS 222 MCF5206/5206E Microprocessor Support
1–5
Getting Started
Push down to latch after
probe is connected
Connect The Probe
Adapter Assembly To The
System Under Test
Pin 1
Pin 1
Figure 1–2: Connecting P6434 probes to the probe adapter
To connect the probe adapter assembly (probe adapter and test clip) to your SUT
follow these instructions:
7. Inspect the microprocessor on your SUT for bent or broken leads. Verify that
the leads on the microprocessor are clean and free from dirt, dust, or any
foreign material.
8. Inspect the pins of the test clip for bent or broken contacts. Verify that the
leads on the test clip are clean and free from dirt, dust or any foreign
material.
9. Verify that the locking devise on the test clip is not locked by turning the
locking device counter-clockwise.
10. Place the probe adapter onto the SUT as shown in Figure 1–3.
CAUTION. To prevent damage to electrical components when power is applied,
correctly place the probe adapter onto the microprocessor..
Center the clip on the microprocessor and apply an equal downward force on all
four sides of the clip. It is important to keep the QFP test clip parallel to the
microprocessor to avoid damage to the SUT or QFP test clip.
Do not apply leverage to the probe adapter when installing or removing it.
1–6
TMS 222 MCF5206/5206E Microprocessor Support
Probe
adapter
Getting Started
SUT
Figure 1–3: Placing the probe adapter onto the SUT
11. Lock the test clip to the microprocessor by turning the locking knob
clockwise.
CAUTION. To prevent faulty and unreliable connections, it is HIGHLY recommended that the test clip IS NOT used on any other microprocessor then the one
it was originally connected to.
The test clip was designed to be used on one and only one microprocessor.
Because of the tight tolerances required for QFP test clip connectivity, the test
clip that attaches to the microprocessor has a soft plastic collar that conforms to
the unique shape of the target microprocessor.
The test clip has a manufacturers stated life expectancy of 8–10 connections.
TMS 222 MCF5206/5206E Microprocessor Support
1–7
Getting Started
CAUTION. The probe adapter board might slip off or slip to one side of the
microprocessor because of the extra weight of the probes. This can damage the
microprocessor
To prevent this from occurring, stabilize the probe adapter by placing a
non-conductive object (such as non-conductive foam) between the probe adapter
and the SUT.
and the SUT.
Removing The Probe
Adapter From The SUT
To remove the probe adapter from the SUT follow these steps:
1. Unlock the test clip from the microprocessor by turning the locking knob
counter-clockwise.
2. Gently lift and pull the probe adapter off of the microprocessor.
Connecting To A System Under Test Without A Probe Adapter
You can use the channel and clock probes and leadsets with a commercial test
clip (or adapter) to make connections between the logic analyzer and your SUT.
To connect probes to MCF5206 signals in the SUT using a test clip, follow these
steps:
1. Turn off power to your SUT. It is not necessary to turn off power to the logic
analyzer.
CAUTION. Static discharge can damage the microprocessor, the probes, or the
module. To prevent static damage, handle all of the above only in a static-free
environment.
Always wear a grounding wrist strap or similar device while handling the
microprocessor.
1–8
2. To discharge your stored static electricity, touch the ground connector located
on the back of the logic analyzer. If you are using a test clip, touch any of the
ground pins on the clip to discharge stored static electricity from it.
3. Table 1–2 through Table 1–8 lists the channel probes the MCF5206 signal
pins on the test clip or in the SUT to connect to.
Use leadsets to connect at least one ground lead from each channel probe and
the ground lead from each clock probe to ground pins on your test clip.
4. Align pin 1 or A1 of your test clip with the corresponding pin 1 or A1 of the
MCF5206 microprocessor in your SUT and attach the clip.
TMS 222 MCF5206/5206E Microprocessor Support
Channel Assignments
Getting Started
The following channel assignment tables show the probe section and channel
assignments, and the signal to which each channel connects.
Channel assignments shown in Table 1–2 through Table 1–8 use the following
conventions:
H All signals are required by the support unless indicated otherwise.
H Channels are shown starting with the most significant bit (MSB) descending
to the least significant bit (LSB).
H Channel group assignments are for all modules unless otherwise noted.
H A tilde (~) following a signal name indicates an active low signal.
By default, the Address group is displayed in hexadecimal.
T able 1–2: Address group channel assignments
Bit order Section:channel MCF5206 signal name
31 A3:7 CS3~
30 A3:6 CS2~
29 A3:5 CS1~
28 A3:4 CS0~
27 A3:3 A27
26 A3:2 A26
25 A3:1 A25
24 A3:0 A24
23 A2:7 A23
22 A2:6 A22
21 A2:5 A21
20 A2:4 A20
19 A2:3 A19
18 A2:2 A18
17 A2:1 A17
16 A2:0 A16
TMS 222 MCF5206/5206E Microprocessor Support
1–9
Getting Started
T able 1–2: Address group channel assignments (cont.)
Bit order MCF5206 signal nameSection:channel
15 A1:7 A15
14 A1:6 A14
13 A1:5 A13
12 A1:4 A12
11 A1:3 A11
10 A1:2 A10
9 A1:1 A9
8 A1:0 A8
7 A0:7 A7
6 A0:6 A6
5 A0:5 A5
4 A0:4 A4
3 A0:3 A3
2 A0:2 A2
1 A0:1 A1
0 A0:0 A0
By default, the Data group is displayed in hexadecimal.
T able 1–3: Data group channel assignments
Bit order Section:channel MCF5206 signal name
31 D3:7 D31
30 D3:6 D30
29 D3:5 D29
28 D3:4 D28
27 D3:3 D27
26 D3:2 D26
25 D3:1 D25
24 D3:0 D24
23 D2:7 D23
22 D2:6 D22
21 D2:5 D21
20 D2:4 D20
19 D2:3 D19
18 D2:2 D18
1–10
TMS 222 MCF5206/5206E Microprocessor Support
T able 1–3: Data group channel assignments (cont.)
Bit order MCF5206 signal nameSection:channel
17 D2:1 D17
16 D2:0 D16
15 D1:7 D15
14 D1:6 D14
13 D1:5 D13
12 D1:4 D12
11 D1:3 D11
10 D1:2 D10
9 D1:1 D9
8 D1:0 D8
7 D0:7 D7
6 D0:6 D6
5 D0:5 D5
4 D0:4 D4
3 D0:3 D3
2 D0:2 D2
1 D0:1 D1
0 D0:0 D0
Getting Started
By default, the Control group is displayed symbolically. The symbol
table file name is 5206_Ctrl.
T able 1–4: Control group channel assignments
Bit order Section:channel MCF5206 signal name
13 C2:3 TS~
12 C2:2
11 C2:0
10 C2:7 ATM
9 C1:6 ATM=
8 C1:3 R/W~
7 C1:7 DRAMW~
6 C1:5 TT1
5 C1:4 TT0
4 C1:2 BG~
3 C1:1 BD~
D_RAS~ [
D_CAS~ [
TMS 222 MCF5206/5206E Microprocessor Support
1–11
Getting Started
T able 1–4: Control group channel assignments (cont.)
Bit order MCF5206 signal nameSection:channel
2 C3:1 TEA~
1 C0:6 RSTI~
0 C0:4 HIZ~
= Double probe.
[ Signal derived on the probe adapter.
By default, the DataSize group is displayed symbolically. The symbol table file
name is 5206_Dsiz.
T able 1–5: DataSize group channel assignments
Bit order Section:channel MCF5206 signal name
1 C3:7 SIZ1
0 C3:3 SIZ0
By default, the DramEnbl group is not visible.
T able 1–6: DramEnbl group channel assignments
Bit order Section:channel MCF5206 signal name
5 C3:6 RAS1~
4 C2:6 CAS3~
3 C3:4 CAS2~
2 C3:2 RAS0~
1 C3:0 CAS1~
0 C2:4 CAS0~
By default, the radix of the Misc group is OFF.
T able 1–7: Misc group channel assignments
Bit order Section:channel MCF5206 signal name
4 C3:5 TA~
3 C2:5 ATA~
2 C2:1
1 C1:0 BR~
D_CS~ [
1–12
TMS 222 MCF5206/5206E Microprocessor Support
Getting Started
T able 1–7: Misc group channel assignments (cont.)
Bit order MCF5206 signal nameSection:channel
0 C0:7 CLK
[ Signal derived on the probe adapter.
Table 1–8 lists the probe section and channel assignments for the clock probes.
The clock probes are not part of any group.
T able 1–8: Clock channel assignments
Section:channel MCF5206 signal name
CK:3 CLK=
CK:2 A2=
CK:1 A1=
CK:0 A0=
C2:3 TS~
C2:2
C2:1
C2:0
QUAL:1 NC
QUAL:0 NC
= Doubled probe.
[ Signal derived on the probe adapter.
D_RAS~ [
D_CS~ [
D_CAS~ [
Table 1–9 lists the pinout of J136, the BDM (Background Debug Mode)
connector.
T able 1–9: BDM connector pinout
J136 BDM connector
MCF5206 signal name
NC (Developer Reserved) 1
TMS/BKPT~ 2
GND 3
TRST~/DSCLK 4
GND 5
NC (Developer Reserved) 6
pin number
TMS 222 MCF5206/5206E Microprocessor Support
1–13
Getting Started
T able 1–9: BDM connector pinout (cont.)
J136 BDM connector
MCF5206 signal name
RSTI~ 7
TDI/DSI 8
+5V w
TDO/DSO 10
GND 11
PP7/PST3 12
PP6/PST2 13
PP5/PST1 14
PP4/PST0 15
PP3/DDATA3 16
PP2/DDATA2 17
PP1/DDATA1 18
PP0/DDATA0 19
GND 20
NC (Motorola Reserved) 21
NC (Motorola Reserved) 22
GND 23
CLK 24
VCC w
TEA~ 26
w Supplied by the target. If the SUT can supply this
voltage, then pin-9 on the BDM connector may
be connected to pin-25 on the BDM connector.
Otherwise an external +5V supply must be used
to connect +5V to pin-9.
pin number
9
25
CPU To Mictor Connections
To probe the microprocessor, you will need to make connections between the
CPU and the Mictor pins of the P6434 Mass Termination Probe. Refer to the
P6434 Mass Termination Probe manual, Tektronix part number 070-9793-XX,
for more information on mechanical specifications. Tables 1–10 through 1–12
show the CPU pin to Mictor pin connections.
Tektronix uses a counterclockwise pin assignment. Pin 1 is located at the top left,
and pin 2 is located directly below it. Pin 20 is located on the bottom right, and
pin 21 is located directly above it (see Figure1–4).
1–14
TMS 222 MCF5206/5206E Microprocessor Support
Getting Started
AMP uses an odd side-even side pin assignment. Pin 1 is located at the top left,
and pin 3 is located directly below it. Pin 2 is located on the top right, and pin 4
is located directly below it (see Figure1–4).
NOTE. When designing Mictor connectors into your system under test, always
follow the Tektronix pin assignment.
Tektronix Pinout AMP Pinout
Pin 1
Pin 19
Pin 38
Pin 20
Pin 1
Pin 37
Pin 2
Pin 38
Figure 1–4: Pin assignments for a Mictor connector (component side)
T able 1–10: CPU to Mictor connections for Mictor A pins
Tektronix
Mictor A
pin number
1 1 NC NC NC
2 3 NC NC NC
3 5 CLOCK:0 A0= 1
4 7 A3:7 CS3~ 46
5 9 A3:6 CS2~ 45
6 11 A3:5 CS1~ 43
7 13 A3:4 CS0~ 42
8 15 A3:3 A27 41
9 17 A3:2 A26 40
10 19 A3:1 A25 38
11 21 A3:0 A24 37
12 23 A2:7 A23 35
13 25 A2:6 A22 34
14 27 A2:5 A21 32
15 29 A2:4 A20 31
16 31 A2:3 A19 29
17 33 A2:2 A18 28
AMP
Mictor A
pin number
LA channel
MCF5206
signal name
MCF5206
pin number
TMS 222 MCF5206/5206E Microprocessor Support
1–15
Getting Started
T able 1–10: CPU to Mictor connections for Mictor A pins (cont.)
Tektronix
Mictor A
pin number
18 35 A2:1 A17 26
19 37 A2:0 A16 25
20 38 A0:0 A0 1
21 36 A0:1 A1 2
22 34 A0:2 A2 4
23 32 A0:3 A3 5
24 30 A0:4 A4 7
25 28 A0:5 A5 8
26 26 A0:6 A6 10
27 24 A0:7 A7 11
28 22 A1:0 A8 13
29 20 A1:1 A9 14
30 18 A1:2 A10 16
31 16 A1:3 A11 17
32 14 A1:4 A12 19
33 12 A1:5 A13 20
34 10 A1:6 A14 22
35 8 A1:7 A15 23
36 6 CLOCK:1 A1= 2
37 4 NC NC NC
38 2 NC NC NC
39 39 GND GND NC
40 40 GND GND NC
41 41 GND GND NC
42 42 GND GND NC
43 43 GND GND NC
= Double probe
AMP
Mictor A
pin number
LA channel
MCF5206
signal name
MCF5206
pin number
1–16
TMS 222 MCF5206/5206E Microprocessor Support
T able 1–11: CPU to Mictor connections for Mictor C pins
Getting Started
Tektronix
Mictor C
pin number
1 1 NC NC NC
2 3 NC NC NC
3 5 CLOCK:3 CLK= 135
4 7 C3:7 SIZ1 53
5 9 C3:6 RAS1~ 71
6 11 C3:5 TA~ 55
7 13 C3:4 CAS2~ 75
8 15 C3:3 SIZ0 51
9 17 C3:2 RAS0~ 70
10 19 C3:1 TEA~ 57
11 21 C3:0 CAS1~ 74
12 23 C2:7 ATM 50
13 25 C2:6 CAS3~ 76
14 27 C2:5 ATA~ 61
15 29 C2:4 CAS0~ 72
16 31 C2:3 TS~ 58
17 33 C2:2 D_RAS~ NC
18 35 C2:1 D_CS~ NC
19 37 C2:0 D_CAS~ NC
20 38 C0:0 NC NC
21 36 C0:1 NC NC
22 34 C0:2 NC NC
23 32 C0:3 NC NC
24 30 C0:4 HIZ~ 125
25 28 C0:5 RTS2/RSTO~ 133
26 26 C0:6 RSTI~ 59
27 24 C0:7 CLK 135
28 22 C1:0 BR~ 66
29 20 C1:1 BD~ 67
30 18 C1:2 BG~ 68
31 16 C1:3 R/W~ 54
32 14 C1:4 TT0 47
33 12 C1:5 TT1 49
34 10 C1:6 ATM= 50
35 8 C1:7 DRAMW~ 78
AMP
Mictor A
pin number
LA channel MCF5206 signal name
MCF5206
pin number
TMS 222 MCF5206/5206E Microprocessor Support
1–17
Getting Started
T able 1–11: CPU to Mictor connections for Mictor C pins (cont.)
Tektronix
Mictor C
pin number
36 6 NC NC NC
37 4 NC NC NC
38 2 NC NC NC
39 39 GND GND NC
40 40 GND GND NC
41 41 GND GND NC
42 42 GND GND NC
43 43 GND GND NC
= Double probe
AMP
Mictor A
pin number
MCF5206 signal nameLA channel
T able 1–12: CPU to Mictor connections for Mictor D pins
Tektronix
Mictor D
pin number
1 1 NC NC NC
2 3 NC NC NC
3 5 NC NC NC
4 7 D3:7 D31 79
5 9 D3:6 D30 80
6 11 D3:5 D29 81
7 13 D3:4 D28 83
8 15 D3:3 D27 84
9 17 D3:2 D26 85
10 19 D3:1 D25 87
11 21 D3:0 D24 88
12 23 D2:7 D23 89
13 25 D2:6 D22 91
14 27 D2:5 D21 92
15 29 D2:4 D20 93
16 31 D2:3 D19 95
17 33 D2:2 D18 96
18 35 D2:1 D17 97
19 37 D2:0 D16 99
AMP
Mictor A
pin number
LA channel
MCF5206
signal name
MCF5206
pin number
MCF5206
pin number
1–18
TMS 222 MCF5206/5206E Microprocessor Support
T able 1–12: CPU to Mictor connections for Mictor D pins (cont.)
Getting Started
Tektronix
Mictor D
pin number
20 38 D0:0 D0 120
21 36 D0:1 D1 119
22 34 D0:2 D2 117
23 32 D0:3 D3 116
24 30 D0:4 D4 115
25 28 D0:5 D5 113
26 26 D0:6 D6 112
27 24 D0:7 D7 111
28 22 D1:0 D8 109
29 20 D1:1 D9 108
30 18 D1:2 D10 107
31 16 D1:3 D11 105
32 14 D1:4 D12 104
33 12 D1:5 D13 103
34 10 D1:6 D14 101
35 8 D1:7 D15 100
36 6 CLOCK:2 A2= 4
37 4 NC NC NC
38 2 NC NC NC
39 39 GND GND NC
40 40 GND GND NC
41 41 GND GND NC
42 42 GND GND NC
43 43 GND GND NC
= Double probe
AMP
Mictor A
pin number
LA channel
MCF5206
signal name
MCF5206
pin number
TMS 222 MCF5206/5206E Microprocessor Support
1–19
Getting Started
Table 1–13 lists the MCF5206 signals that are not required by the Clocking State
Machine (CSM) or the disassembler. The signals that are not required can be
removed from their default connections and re-connected to other signals of
interest. This is not possible with Mictor connectors on the probe adapter.
T able 1–13: Signals not required for clocking or disassembly
Section:channel MCF5206 signal name
C3:5 TA~
C3:4 CAS2~
C3:0 CAS1~
C2:6 CAS3~
C2:5 ATA~
C2:4 CAS0~
C1:0 BR~
C0:7 CLK
C0:5 RTS2/RSTO~
1–20
TMS 222 MCF5206/5206E Microprocessor Support
Operating Basics
Setting Up the Support
The information in this section is specific to the operations and functions of the
TMS 222 MCF5206 support on any Tektronix logic analyzer for which it can be
purchased.
Before you acquire and disassemble data, you need to load the support and
specify setups for clocking and triggering as described in the information on
basic operations. The support provides default values for each of these setups,
but you can change them as needed.
Channel Groups
The software automatically defines channel groups for the support. The channel
groups for the TMS 222 MCF5206 support are listed in the channel assignment
tables beginning on page 1–9.
Custom Clocking
A special clocking program is loaded to the module every time the TMS 222
support is loaded. When “Custom” is selected, the sub-title “MCF5206
Microprocessor Clocking Support” will be added, and the clocking options will
be displayed.
Clocking Options
The TMS 222 support has one mode of acquisition clocking called “DRAM
TYPE”.
If the DRAM memory is Extended Data out (EDO) type the option “EDO
DRAM” is selected.
If the DRAM memory is not Extend Data out (EDO) type the option “NON EDO
DRAM” is selected as the default.
TMS 222 MCF5206/5206E Microprocessor Support
2–1
Setting Up the Support
CLK
TS
A [ 27:0 ]
R/W~
TT [1:0 ]
ATM
SIZ [ 1:0 ]
D [31:16 ]
CS~
$addr
$0
$1
Data
ATM_TS ADC ADC
M
2–2
Figure 2–1: Byte Write Transfer from an 8-bit port.
TMS 222 MCF5206/5206E Microprocessor Support
CLK
TS
D_RAS~
Setting Up the Support
A [ 27:0 ]
D_CAS~
DRAMW~
ROW ADDR
ATM_TS
ADC,
DRAM
M
Column address
DATA
ADC
DRAM
Figure 2–2: Byte Read transfer in normal mode with 8-bit NON EDO Dram
CLK
TS
D_RAS~
M
A [ 27:0 ]
D_CAS~
DRAMW~
Figure 2–3: Byte Read transfer in normal mode with 8-bit EDO Dram
TMS 222 MCF5206/5206E Microprocessor Support
ROW ADDR
ATM_T
S
ADC,
DRAM
M
Column address
DATA
ADC
DRAM
M
2–3
Setting Up the Support
Symbols
The TMS 222 support supplies symbol table files. Each file replaces specific
channel group values with symbolic values when Symbolic is the radix for the
channel group.
Symbol tables are generally not for use in timing or 5206_T support disassembly.
Table 2–1 lists the name and bit pattern for the symbols in the file 5206_Ctrl, the
Control channel group symbol table.
T able 2–1: Control group symbol table definitions
Symbol
MASTER RESET
NORMAL RESET
AL TERNATE BUS MASTER
TRANSFER ERROR
DRAM ROW ADDRESS
SUP CODE
FETCH/READ
DRAM SUP CODE
DRAM FETCH/READ
SUP CODE – DEBUG
FETCH/READ – DEBUG
DRAM SUP CODE – DEBUG
DRAM FETCH/READ – DEBUG
SUP READ
DRAM SUP READ
SUP READ – DEBUG
DRAM SUP READ – DEBUG
SUP WRITE
WRITE
DRAM SUP WRITE
DRAM WRITE
SUP WRITE – DEBUG
WRITE – DEBUG
DRAM SUP WRITE – DEBUG
TS~ ATM= TT0 RSTI~
D_RAS~ R/W~ BG~ HIZ~
XX XXXX XXXX XX00
XX XXXX XXXX XX01
XX XXXX XXXX 1X11
XX XXXX XXXX X011
X0 1XXX XXXX 0111
01 1111 X00X 0111
11 1XX1 X00X 0111
0X 011X 100X 0111
1X 0XXX 100X 0111
01 1111 X10X 0111
11 1XX1 X10X 0111
0X 011X 110X 0111
1X 0XXX 110X 0111
01 1011 X00X 0111
0X 001X 100X 0111
01 1011 X10X 0111
0X 001X 110X 0111
01 1010 X00X 0111
11 1XX0 X00X 0111
0X 001X 000X 0111
1X 0XXX 000X 0111
01 1010 X10X 0111
11 1XX0 X10X 0111
0X 001X 010X 0111
Control group value
D_CAS~ DRAMW~ BD~
ATM TT1 TEA~
2–4
TMS 222 MCF5206/5206E Microprocessor Support
T able 2–1: Control group symbol table definitions (cont.)
D_CAS~ DRAMW~ BD~
ATM TT1 TEA~
Symbol
DRAM WRITE – DEBUG
USER CODE
DRAM USER CODE
USER CODE – DEBUG
DRAM USER CODE – DEBUG
USER READ
DRAM USER READ
USER READ – DEBUG
DRAM USER READ – DEBUG
USER WRITE
DRAM USER WRITE
USER WRITE – DEBUG
DRAM USER WRITE– DEBUG
MOVEC INST READ
DRAM MOVEC INST READ
uP SPACE/ACK.
DRAM uP SPACE/ACK.
MOVEC INST WRITE
DRAM MOVEC INST WRITE
WRITE – uP SPACE/ACK.
DRAM WRITE – uP SPACE/ACK.
READ – ACK.
DRAM READ – ACK.
WRITE – ACK.
DRAM WRITE – ACK.
RESERVED ACCESS
TS~ ATM= TT0 RSTI~
D_RAS~ R/W~ BG~ HIZ~
1X 0XXX 010X 0111
01 1101 X00X 0111
0X 010X 100X 0111
01 1101 X10X 0111
0X 010X 110X 0111
01 1001 X00X 0111
0X 000X 100X 0111
01 1001 X10X 0111
0X 000X 110X 0111
01 1000 X00X 0111
0X 000X 000X 0111
01 1000 X10X 0111
0X 000X 010X 0111
01 1001 X11X 0111
0X 000X 111X 0111
11 1XX1 X11X 0111
1X 0XXX 111X 0111
01 1000 X11X 0111
0X 000X 011X 0111
11 1XX0 X11X 0111
1X 0XXX 011X 0111
01 1101 X11X 0111
0X 010X 011X 0111
01 1100 X11X 0111
0X 010X 011X 0111
XX XXXX X01X 0111
Setting Up the Support
Control group value
TMS 222 MCF5206/5206E Microprocessor Support
2–5
Setting Up the Support
Table 2–2 lists the name and bit pattern for the file 5206_Dsiz, and the symbols
in the DataSize group symbol table.
T able 2–2: DataSize group symbol table definitions
DataSize group value
Symbol
SIZ1
SIZ0
LONG
BYTE
WORD
LINE
2–6
TMS 222 MCF5206/5206E Microprocessor Support
Acquiring And Viewing Disassembled Data
Acquiring Data
Once you load the MCF5206 support, choose a clocking mode, and specify the
trigger, you are ready to acquire and disassemble
If you have any problems acquiring data, refer to information on basic operations
in your online help or Appendix A: Error Messages and Disassembly Pr oblems in
the basic operations user manual.
Viewing Disassembled Data
You can view disassembled data in six display formats: Timing, State, Hardware,
Software, Control Flow, and Subroutine.
The information on basic operations describes how to select the disassembly
display formats.
NOTE. Selections in the Disassembly property page (the Disassembly Format
Definition overlay) must be set correctly for acquired data to be disassembled
correctly. Refer to Changing How Data is Displayed on page 2–12.
data.
The default display format shows the Address, Data, and Control channel group
values for each sample of acquired data.
The disassembler displays special characters and strings in the instruction
mnemonics to indicate significant events. Table 2–3 shows these special
characters and strings, and gives a description of what they represent.
T able 2–3: Description of special characters in the display
Character or string displayed Description
>> The instruction was manually marked as a program fetch
**** Indicates there is insufficient data available for complete
disassembly of the instruction: the number of asterisks
indicates the width of the data that is unavailable. Each two
asterisks represent one byte.
# Indicates an immediate value
t Indicates the number shown is in decimal, such as #12t
TMS 222 MCF5206/5206E Microprocessor Support
2–7
Acquiring and Viewing Disassembled Data
Timing Display Format
State Display Format
Hardware Display Format
A Timing-Waveform display file format is provided with this support. The
Timing-Waveform display file format will set up the display and show the
following waveforms:
CLK TS~ Address (busform)
Data (busform) D_RAS~ D_CAS~
D_CS~ DataSize (busform) ATM
R/W~ DRAMW~ TT1
TT0 BR~ BG~
BD~ TEA~ RSTI~
HIZ~ TA~ ATA~
In State-Listing display, all bus cycles are displayed, but not disassembled.
Except for the group name, default group order, and default radix, the
State-Listing display is unaffected by the support software.
Data searching (not microprocessor-specific instruction) is supported by the
State-Listing display
In Hardware display format, the disassembler displays certain cycle type labels in
parentheses. Table 2–4 shows these cycle type labels and gives a definition of the
cycle they represent. Reads to interrupt and exception vectors will be labeled
with the vector name.
T able 2–4: Cycle type definitions
Cycle type label Definition
( MASTER RESET ) Master Reset of the microprocessor
( NORMAL RESET ) Normal Reset of the microprocessor
( ALTERNATE BUS MASTER ) Alternate Bus Master cycle
( TRANSFER ERROR ) Transfer Error
( DRAM ROW ADDRESS ) DRAM Row Address
( SUP CODE ) Code
( FETCH/READ ) Code/Data
( DRAM SUP CODE ) DRAM Supervisor Code
( DRAM FETCH/READ ) DRAM Code/READ
( SUP CODE – DEBUG ) Supervisor Code in Debug Mode
( FETCH/READ – DEBUG ) Code/Data in Debug mode
( DRAM SUP CODE – DEBUG ) DRAM Supervisor code in Debug mode
( DRAM FETCH/READ – DEBUG ) DRAM Code/Data in Dbug mode
2–8
TMS 222 MCF5206/5206E Microprocessor Support
Acquiring and Viewing Disassembled Data
T able 2–4: Cycle type definitions (cont.)
Cycle type label Definition
( SUP READ ) Supervisor Data DataRead
( DRAM SUP READ ) DRAM Supervisor Data Read
( SUP READ – DEBUG ) Supervisor Data Read in Debug mode
( DRAM SUP READ – DEBUG ) DRAM Supervisor Data Read in Debug mode
( SUP WRITE ) Supervisor Data Write
( WRITE ) Data Write
( DRAM SUP WRITE ) DRAM Supervisor Data Write
( DRAM WRITE ) DRAM Data Write
( SUP WRITE – DEBUG ) Supervisor Data Write in Debug mode
( WRITE – DEBUG ) Data Write in Debug mode
( DRAM SUP WRITE – DEBUG ) DRAM Supervisor Data Write in Debug mode
( DRAM WRITE – DEBUG ) DRAM Data Write in Debug mode
( USER CODE ) User Code
( DRAM USER CODE ) DRAM User Code
( USER CODE – DEBUG ) User Code in Debug mode
( DRAM USER CODE – DEBUG ) DRAM User Code in Debug mode
( USER READ ) User Data Read
( DRAM USER READ ) DRAM User Data Read
( USER READ – DEBUG ) User Data Read in Debug mode
( DRAM USER READ – DEBUG ) DRAM User Data Read in Debug mode
( USER WRITE ) User Data Write
( DRAM USER WRITE ) DRAM User Data Write
( USER WRITE – DEBUG ) User Data Write in Debug mode
( DRAM USER WRITE – DEBUG ) DRAM User Data W rite in Debug mode
( MOVEC INST READ ) Movec Instruction Data Read
( DRAM MOVEC INST READ ) DRAM Movec Instruction Data Read
( uP SPACE/ACK ) CPU space/Intruupt Acknowledge
( DRAM uP SPACE/ACK ) CPU space/Interrupt Acknowledge
( MOVEC INST WRITE ) Movec Instruction Write
( DRAM MOVEC INST WRITE ) DRAM Movec Instruction Write
( WRITE – uP SPACE/ACK ) Write CPU space/Interrupt Acknowledge
( DRAM WRITE – uP SPACE/ACK ) DRAM Write CPU space/Interrupt Acknowledge
( READ – ACK ) Data Read / Interrupt Acknowledge
TMS 222 MCF5206/5206E Microprocessor Support
2–9
Acquiring and Viewing Disassembled Data
T able 2–4: Cycle type definitions (cont.)
Cycle type label Definition
( DRAM READ – ACK ) DRAM Data Read / Interrupt Acknowledge
( WRITE – ACK ) Data Write / Interrupt Acknowledge
( DRAM WRITE – ACK ) DRAM Data Write / Interrupt Acknowledge
( RESERVED ACCESS ) Reserved access
( UNKNOWN ) The combination of control bits unrecognized
( EXTENSION ) w
( FLUSH ) w
( READ ) w
Extension part of the Instruction
Instruction Fetch not executed
Data Read
w Computed cycle types.
Figure 2–4 shows an example of the Hardware display.
1 2 3 4
Sample Address Data Mnemonic
-------------------------------------------------------------------------------108 00040132 44FC MOVE.W #001F,CCR >
109 00040134 001F ( EXTENSION ) >
110 00040136 642A BCC.B 00040162 >
111 00040138 44FC MOVE.W #0000,CCR >
112 0004013A 0000 ( EXTENSION ) >
113 0004013C 6524 BCS.B 00040162 >
114 0004013E 6722 BEQ.B 00040162 >
115 00040140 44FC MOVE.W #0003,CCR >
116 00040142 0003 ( EXTENSION ) >
117 00040144 6C1C BGE.B 00040162 >
118 00040146 6E1A BGT.B 00040162 >
119 00040148 6218 BHI.B 00040162 >
120 0004014A 44FC MOVE.W #0000,CCR >
121 0004014C 0000 ( EXTENSION ) >
122 0004014E 6F12 BLE.B 00040162 >
123 00040150 6310 BLS.B 00040162 >
124 00040152 6D0E BLT.B 00040162 >
125 00040154 6B0C BMI.B 00040162 >
126 00040156 44FC MOVE.W #001F,CCR >
127 00040158 001F ( EXTENSION ) >
128 0004015A 6606 BNE.B 00040162 >
129 0004015C 6A04 BPL.B 00040162 >
130 0004015E 6802 BVC.B 00040162 >
2–10
Figure 2–4: Hardware display format
1
Sample Column. Lists the memory locations for the acquired data.
TMS 222 MCF5206/5206E Microprocessor Support
Acquiring and Viewing Disassembled Data
2
Address Group. Lists data from channels connected to the MCF5206
address bus.
3
Data Group. Lists data from channels connected to the MCF5206 data bus.
4
Mnemonics Column. Lists the disassembled instructions and cycle types.
Software Display Format
Control Flow Display
Format
The Software display format shows only the first fetch of executed instructions.
Flushed cycles and extensions are not shown, even though they are part of the
executed instruction. Read extensions will be used to disassemble the instruction,
but will not be displayed as a separate cycle in the Software display format. Data
reads and writes are not displayed.
The Control Flow display format shows only the first opcode fetch of instructions that cause a branch in the addressing will be displayed.
If a conditional branch branches to an address that is reaches sequentially, it
might be impossible to determine if the branch was taken or not taken. In this
instance the branch will not be displayed in the Control Flow display, and no
flushing will be done.
Unconditional branches are always displayed whether or not the destination
address is seen on the bus.
Instructions that unconditionally generate a change in the flow of control in the
MCF5206 microprocessor are:
BRA BSR JMP JSR
RTE RTS STOP TRAP
Instructions that conditionally generate a change in the flow of control in the
MCF5206 microprocessor are:
Bcc
Subroutine Display
Format
The Subroutine display format shows only the first fetch of subroutine call and
return instructions. It will display conditional subroutine calls if they are
considered to be taken.
Instructions that unconditionally generate a subroutine call or a return in the
MCF5206 microprocessor are:
BSR JSR RTE
RTS STOP TRAP
TMS 222 MCF5206/5206E Microprocessor Support
2–11
Acquiring and Viewing Disassembled Data
The following special cycles will also be displayed:
H Bus Error Cycles
H Reads from the interrupt table that appear due to servicing interrupts will be
displayed (VBR must be set in the format overlay)
H Illegal instructions will be displayed
H ( UNKNOWN ) cycle types – the disassembler does not recognize the
control group value
Signals On The Probe
Adapter But Not Acquired
The following signals are present on the probe adapter, but not acquired by the
disassembler software:
IRQ7~/IPL2~ IRQ4~/IPL1~ IRQ1~/IPLO~ TDI/DSI
TCK TDO/DSO SCL TRST~/DSCLK
CTS2~ RXD2 TXD2 SDA
CTS1~ RXD1 TXD1 RTS1~
TIN0 TIN1 TOUT0 TOUT1
PP7/PST3 PP6/PST2 PP5/PST1 PP4/PST0
PP3/DDATA3 PP2/DDATA2 PP1/DDATA1 PP0/DDATA0
TMS/BKPT~ MTMOD
To view these signals, an alternate probing method must be used.
Changing How Data is Displayed
There are common fields and features that allow you to further modify displayed
data to suit your needs. You can make common and optional display selections in
the Disassembly property page (the Disassembly Format Definition overlay).
You can make selections unique to the MCF5206 support to do the following
tasks:
2–12
H Change how data is displayed across all display formats
H Change the interpretation of disassembled cycles
H Display exception vectors
TMS 222 MCF5206/5206E Microprocessor Support
Acquiring and Viewing Disassembled Data
Disassembly Display
Options
Optional Display
Selections
The TLA 700 Series supports the following disassembly display options:
H Show: Hardware (default)
Software
Control Flow
Subroutine
H Highlight: Software (default)
Control Flow
Subroutine
None
The fields corresponding to the CS[0-7]~ Base Addresses and the DRAM Bank1
and Bank0 base addresses appear to be different on the TLA 700 Series then on
the DAS 9200 Series because the TLA 700 Series has a user interface that can
accommodate more than 13 fields.
You can make optional selections for disassembled data. In addition to the
common selections (described in the information on basic operations), you can
configure the data display for the following microprocessor specific fields:
Write Enable, Chip Select, or Address Line. Table 2–5 lists the configuration
options for configuring the pins as address pins, chip select pins, or write enable
pins.
The selections are:
W,W,W,W W,W,C,C W,W,C,A W,W,A,A
W,C,C,C W,C,C,A W,C,A,A W,A,A,A
C,C,C,C C,C,A,A C,A,A,A A,A,A,A
Where:
W the pin is used as a write enable
C the pin is used as a chip select
A the pin is used as an address line
T able 2–5: Address, Chip Select, or Write Enable Matrix
PAR[3-0] A27/CS7/WE0 A26/CS6/WE1 A25/CS5/WE2 A24/CS4/WE3
0000 WE0 WE1 WE2 WE3
0001 WE0 WE1 CS5 CS4
0010 WE0 WE1 CS5 A24
001 1 WE0 WE1 A25 A24
0100 WE0 CS6 CS5 CS4
0101 WE0 CS6 CS5 A24
TMS 222 MCF5206/5206E Microprocessor Support
2–13
Acquiring and Viewing Disassembled Data
T able 2–5: Address, Chip Select, or Write Enable Matrix (cont.)
PAR[3-0] A24/CS4/WE3A25/CS5/WE2A26/CS6/WE1A27/CS7/WE0
01 10 WE0 CS6 A25 A24
01 11 WE0 A26 A25 A24
1000 CS7 CS6 CS5 CS4
1001 CS7 CS6 CS5 A24
1010 CS7 CS6 A25 A24
101 1 CS7 A26 A25 A24
1100 A27 A26 A25 A24
1101 Reserved
1110 Reserved
1111 Reserved
DefaultMem Port Size. The DefaultMem Port Size selection indicates the port size
of the default memory region. Select one of the following options:
32-bit
8-bit
16-bit
Bank0 Page, Port Size. There are nine different DRAM PortSize and PageSize
combinations available. The combinations are listed for DRAM Bank0. Select
one of the following selections:
512 Byte,32-bit
512 Byte,16-bit
512 Byte,8-bit
1 KB,32-bit
1 KB,16-bit
1 KB,8-bit
2 KB,32-bit
2 KB,16-bit
2 KB,8-bit
2–14
TMS 222 MCF5206/5206E Microprocessor Support
Acquiring and Viewing Disassembled Data
Bank1 Page, Port Size. There are nine different DRAM PortSize and PageSize
combinations available. The combinations are listed for DRAM Bank1. Select
one of the following selections:
512 Byte,32-bit
512 Byte,16-bit
512 Byte,8-bit
1 KB,32-bit
1 KB,16-bit
1 KB,8-bit
2 KB,32-bit
2 KB,16-bit
2 KB,8-bit
Bank[1-0] BaseAddr. This is a eight digit hexadecimal fill-in field. Enter the base
address of the region controlled by RAS1~ and RAS0~ chip enables here.
The first four digits constitute the most significant 16-bits of the RAS1~ base
address, and the next four digits constitute the most significant 16-bits of the
RAS0~ base address.
NOTE. For the BaseAddr fields only the most significant 16-bits matter. Bits 15-0
are taken to be zeroes.
VBR. The TMS 222 will support interpretation of accesses to the vector table by
labeling cycles according to the vector table accessed. If the vector table has been
relocated, enter the new address of the vector table in this field.
Enter the hexadecimal base address of the vector table in this eight digit fill-in
field to allow the TMS 222 software to locate the vector base register.
The default hexadecimal vector table base address is: 00000000
Vector Table Size. This is a 12-bit fill-in field that contains the value of the
interrupt table. The value of the interrupt table will be used in computing the
name of the interrupt whenever an exception occurs. The vector table size value
must be divisible by four. The range of values are:
Maximum value: 400
Minimum value: 8
Default value: 400
CS[7-0]~ Port Size. The CS[7-0]~ port size is an eight digit hexadecimal fill-in
field. The CS[7-0]~ port size field contains the port sizes of the regions con-
TMS 222 MCF5206/5206E Microprocessor Support
2–15
Acquiring and Viewing Disassembled Data
trolled by the chip selects 7-0. Enter the value for each digit with a value of 0, 1,
or 2, where:
0 Long port (32-bit)
1 Byte port (8-bit)
2 Word port (16-bit)
Example: Entering a value of 00011122 would mean that CS7, CS6 and CS5 are
32-bit ports; CS4, CS3 and CS2 are 8-bit ports; and CS1 and CS0 are 16-bit
ports.
CS[1-0]~ BaseAddr. The CS[1-0]~ BaseAddr is an eight digit hexadecimal fill-in
field. The CS[1-0]~ BaseAddr field contains the BaseAddr of the regions
controlled by CS1~ and CS0~. Enter the value for each digit where the first four
digits constitute the most significant 16-bits of the CS1~ base address, and the
next four digits constitute the most significant 16-bits of the CS0~ base address.
CS[3-2]~ BaseAddr. The CS[3-2]~ BaseAddr is an eight digit hexadecimal fill-in
field. The CS[3-2]~ BaseAddr field contains the BaseAddr of the regions
controlled by CS3~ and CS2~. Enter the value for each digit where the first four
digits constitute the most significant 16-bits of the CS3~ base address, and the
next four digits constitute the most significant 16-bits of the CS2~ base address.
Marking Cycles
CS[5-4]~ BaseAddr. The CS[5-4]~ BaseAddr is an eight digit hexadecimal fill-in
field. The CS[5-4]~ BaseAddr field contains the BaseAddr of the regions
controlled by CS5~ and CS4~. Enter the value for each digit where the first four
digits constitute the most significant 16-bits of the CS5~ base address, and the
next four digits constitute the most significant 16-bits of the CS4~ base address.
CS[7-6]~ BaseAddr. The CS[7-6]~ BaseAddr is an eight digit hexadecimal fill-in
field. The CS[7-6]~ BaseAddr field contains the BaseAddr of the regions
controlled by CS7~ and CS6~. Enter the value for each digit where the first four
digits constitute the most significant 16-bits of the CS7~ base address, and the
next four digits constitute the most significant 16-bits of the CS6~ base address.
The TMS 222
read extensions and flush cycles). If the cursor is placed on any other cycle type,
no cycle marks will be available.
TLA 700 Series. Marks are placed by using the Mark Opcode button. The Mark
Opcode button is always be available. If the sample being marked is not an
instruction fetch cycle, the Mark Opcode selections will be replaced by a note
indicating that “An Opcode Mark cannot be placed at the selected data sample.”
will only allow marking of instruction fetch cycles (which include
2–16
TMS 222 MCF5206/5206E Microprocessor Support
Acquiring and Viewing Disassembled Data
When a cycle is marked, the character “>>” is displayed immediately to the left
of the Mnemonics column. Cycles can be unmarked by using the “Undo Mark”
selection, which will remove the character “>>”.
DAS 9200 Series. Marks are placed by using the F4 key: Mark Data function key.
The Mark Data function key is always be available. If the cursor is not on an
instruction fetch cycle, then no microprocessor cycle marks will be available
when the key is pressed.
When a cycle is marked, the letter “m” is displayed immediately to the left of the
Sequence column. Cycles can be unmarked by using the “Undo Mark” selection,
which will remove the letter “m”.
Cycle Marking. The following marks will be available for instruction fetch cycles:
The selections for 32-bit transfer are:
Opcode Anything
Opcode Opcode
Opcode Flush
Flush Flush
Flush Opcode
Extension Extension
Extension Opcode
Extension Flush
Undo Mark Remove all marks from the current sequence.
Displaying Exception
Vectors
The selections for 8-bit and 16-bit transfers are:
Opcode
Extension
Flush
Undo Mark Remove all marks from the current sequence.
The disassembler can display exception vectors.
You can relocate the table by entering the starting address in the Vector Base
Register field. The Vector Base Register field provides the disassembler with the
offset address. Enter an eight-digit hexadecimal value corresponding to the offset
of the base address of the exception table. The Vector Table Size field lets you
specify a three-digit hexadecimal size for the table.
These fields are located in the Disassembly property page (Disassembly Format
Definition overlay).
Table 2–6 lists the MCF5206 exception vectors.
TMS 222 MCF5206/5206E Microprocessor Support
2–17
Acquiring and Viewing Disassembled Data
T able 2–6: Exception vectors
Exception
number
0 000 ( INITIAL STACK POINTER )
1 004 ( INITIAL PROGRAM COUNTER )
2 008 ( ACCESS ERROR VECTOR )
3 00C ( ADDRESS ERROR VECTOR )
4 010 ( ILLEGAL INSTRUCTION VECTOR )
5 014 ( RESERVED VECT OR #14H )
6 018 ( RESERVED VECT OR #18H )
7 01C ( RESERVED VECT OR #1CH )
8 020 ( PRIV VIOLATION VECTOR )
9 024 ( TRACE VECTOR )
10 028 ( UNIMPLEMENTED LINE–A OPCODE )
11 02C ( UNIMPLEMENTED LINE–F OPCODE )
12 030 ( DEBUG INTERRUPT VECTOR )
13 034 ( RESERVED VECTOR #34H )
14 038 ( FORMA T ERROR VECT OR )
15 03C ( UNINIT INTERRUPT VECTOR )
16-23 040-05C ( RESERVED VECTOR #40H #5CH )
24 060 ( SPURIOUS INTERRUPT VECTOR )
25-31 064-07C ( ILP 1-7 AUTOVECTOR )
32-47 080-08C ( TRAP #0t-#15t VECTOR )
48-63 0C0-0FC ( RESERVED VECTOR #C0-#FC )
64-255 100-3FC ( USER INT VECTOR #64t-#255t )
Location in table
(in hexadecimal)
Displayed exception name
2–18
TMS 222 MCF5206/5206E Microprocessor Support
Specifications
Specifications
Specification Tables
These specifications are for a probe adapter connected between a compatible
Tektronix logic analyzer and a SUT. Table 3–1 shows the electrical requirements
the SUT must produce for the support to acquire correct data. Table 3–2 shows
the environmental specifications.
Figure 3–1 shows the dimensions of the probe adapter. Figure 3–1 shows the
dimensions of the test clip.
T able 3–1: Electrical specifications
Characteristics Requirements
SUT DC power requirements
Voltage MCF5206 4.75–5.25 V
Current MCF5206 I
Voltage MCF5206E 3.0–3.6 VDC
Current MCF5206E I
SUT clock rate
MCF5206
Maximum specified clock rate 33.33 MHz
maximum
I
typical
minimum
150 mA
150 mA
1.5 mA
Tested clock rate 25 MHz
MCF5206E
Maximum specified clock rate 54 MHz
Tested clock rate 54 MHz
Minimum setup time required 2.5 ns
Minimum hold time required 0 ns
Typical signal loading
MICTOR load (ML) w 20 KW in parallel with 2 pF
Podlet load (CL) w 20 KW in parallel with 2 pF
Characteristics Specification
Measured typical SUT signal loading AC load DC load
A18, A21, SIZ0, SIZ1, D28, D27,
D25, D24, D15, D7, D6, D5, D4, D3,
D1, D0
TMS 222 MCF5206/5206E Microprocessor Support
2 pF + 1 ML 1 ML
3–1
Specifications
T able 3–1: Electrical specifications (cont.)
Characteristics Requirements
R/W~, TA~, TS~, BD~, BG~, D18,
D14, D13, D12, D11, D10, D9, D8,
D2
BR~, D22, D16 4 pF + 1 ML 1 ML
D23, D19, HIZ~ 5 pF + 1 ML 1 ML
TT0, TT1, CAS2~, DRAMW~, D26,
D20, RTS2~/RTS0~
3 pF + 1 ML 1 ML
6 pF + 1 ML 1 ML
A4, A10, A11, A20, A22, A23, D29,
D21
A5, A6, A12, A13, A14, A15, A19,
RSTI~
A3, A7, A8, A16, TEA~, D13 9 pF + 1 ML 1 ML
A9, A17 10 pF + 1 ML 1 ML
A24/CS4~/WE3~ 12 pF + 1 ML 1 ML
CS0~ 10 pF + 1 ML 1 IC*
CAS2~, TT0 6 pF + 1 ML 1 IC*
A26/CS6~/WE1~ 8 pF + 1 ML 1 IC*
A27/CS7~/WE0~, CAS3~ 9 pF + 1 ML 1 IC*
A25/CS5~/WE2~, RAS0~, CAS1~ 10 pF + 1 ML 1 IC*
CAS0~ 11 pF + 1 ML 1 IC*
A24/CS4~/WE3~, RAS1~ 12 pF + 1 ML 1 IC*
CS2~, CS3~ 14 pF + 1 ML 1 IC*
CS1~ 16 pF + 1 ML 1 IC*
A0, A1, A2 19 pF + 1 ML + 1 CL 1 ML + 1 CL
CLK 17 pF + 1 ML + 1 CL 1 ML + 1 CL
ML is Mictor load, CL is clock load.
7 pF + 1 ML 1 ML
8 pF + 1 ML 1 ML
3–2
* MCF5206 IC is PALCE22V10
MCF5206E IC is GAL22LV10
TMS 222 MCF5206/5206E Microprocessor Support
T able 3–2: Environmental specifications*
Characteristic Description
Temperature
Specifications
Maximum operating
Minimum operating 0° C (+32° F)
Non-operating –55° C to +75° C (–67° to +167° F)
Humidity 10 to 95% relative humidity
Altitude
Operating 4.5 km (15,000 ft) maximum
Non-operating 15 km (50,000 ft) maximum
Electrostatic immunity The probe adapter is static sensitive
* Designed to meet Tektronix standard 062-2847-00 class 5.
[
Not to exceed MCF5206 microprocessor thermal considerations. Forced air cooling
might be required across the CPU.
+50° C (+122° F)[
TMS 222 MCF5206/5206E Microprocessor Support
3–3
Specifications
76 mm
(3.000 in)
38 mm
(1.500 in)
8 mm
(.300 in)
Pin 1
51 mm
(2.00 in)
81 mm
(3.200 in)
102 mm
(4.000 in)
9mm (.350 in)
71 mm
(2.800 in)
Pin 1
25mm
(.675 in)
3–4
Figure 3–1: Dimensions of the probe adapter
TMS 222 MCF5206/5206E Microprocessor Support
WARNING
The following servicing instructions are for use only by qualified personnel. To
avoid injury, do not perform any servicing other than that stated in the operating
instructions unless you are qualified to do so. Refer to all Safety Summaries
before performing any service.
Maintenance
Maintenance
Probe Adapter Description
The probe adapter is nonintrusive hardware that allows the logic analyzer to
acquire data from a microprocessor in its own operating environment with little
or no effect on that system. Information on basic operations contains a figure
showing the logic analyzer connected to a typical probe adapter. Refer to that
figure while reading the following description.
The probe adapter consists of a circuit board and four connectors that interface
with the supplied test clip. The test clip connects to the MCF5206
microprocessor located on your SUT. Signals from the microprocessor-based
system flow from the probe adapter to the channel groups and through the probe
signal leads to the module.
The probe adapter accommodates the Motorola MCF5206 microprocessor in a
160-pin TQFP package.
At reset time, pins A[27-24]/CS[7-4]~/WE[3-0]~ can be configured as either
Address pins, ChipSelect pins, or WriteEnable pins. To find out whether these
pins are being used as ChipSelects, there is an eight position DIP switch S[7-0].
If any of the pins are being used as ChipSelects, the corresponding DIP switch is
connected to the ON position. For example, if the A27/CS3~/WE3~ pin is
configured as CS3~, switch S3 will be set to the ON position.
Test Clip Inspection
CS0~ is the chip enable for the boot region. There is a maximum of eight
possible ChipSelects: CS[7-4]~, CS[3-0]~ A signal derived from the ChipSelects
will be used as a qualifier. All the pins that are being used as ChipSelects are
logically ANDed, and the output is used as the qual(D_CS~). If any of the pins
are configured as CS it must be connected to the circuit by enabling the switch.
There are two RowAddressStrobe signals: RAS1~ and RAS0~. The derived
common RowAddressStrobe signal is called D_RAS~ by logically ANDing the
RAS1~ and RAS0~ signals.
There are four ColumnAddressStrobe signals: CAS[3-0]~. The derived common
ColumnAddressStrobe signal is called D_CAS~ by logically ANDing the
CAS[3-0]~ signals.
The probe adapter will meet LASI IV specifications.
Carefully inspect the test clip before each use. Inspect the contacts and verify that
they are free of debris, and that none of the contacts are bent.
TMS 222 MCF5206/5206E Microprocessor Support
4–1
Maintenance
4–2
TMS 222 MCF5206/5206E Microprocessor Support
Replaceable Electrical Parts
Replaceable Electrical Parts
This chapter contains a list of the replaceable electrical components for the
TMS 222 MCF5206 and the MCF5206E microprocessor support. Use this list to
identify and order replacement parts.
Parts Ordering Information
Replacement parts are available through your local Tektronix field office or
representative.
Changes to Tektronix products are sometimes made to accommodate improved
components as they become available and to give you the benefit of the latest
improvements. Therefore, when ordering parts, it is important to include the
following information in your order:
H Part number
H Instrument type or model number
H Instrument serial number
H Instrument modification number, if applicable
If you order a part that has been replaced with a different or improved part, your
local Tektronix field office or representative will contact you concerning any
change in part number.
Change information, if any, is located at the rear of this manual.
Using the Replaceable Electrical Parts List
The tabular information in the Replaceable Electrical Parts List is arranged for
quick retrieval. Understanding the structure and features of the list will help you
find all of the information you need for ordering replacement parts. The
following table describes each column of the electrical parts list.
TMS 222 MCF5206/5206E Microprocessor Support
5–1
Replaceable Electrical Parts
Parts list column descriptions
Column Column name Description
1 Component number The component number appears on diagrams and circuit board illustrations, located in the diagrams
section. Assembly numbers are clearly marked on each diagram and circuit board illustration in the
Diagrams section, and on the mechanical exploded views in the Replaceable Mechanical Parts list
section. The component number is obtained by adding the assembly number prefix to the circuit
number (see Component Number illustration following this table).
The electrical parts list is arranged by assemblies in numerical sequence (A1, with its subassemblies
and parts, precedes A2, with its subassemblies and parts).
Chassis-mounted parts have no assembly number prefix, and they are located at the end of the
electrical parts list.
2 Tektronix part number Use this part number when ordering replacement parts from Tektronix.
3 and 4 Serial number Column three indicates the serial number at which the part was first effective. Column four indicates
the serial number at which the part was discontinued. No entry indicates the part is good for all serial
numbers.
5 Name & description An item name is separated from the description by a colon (:). Because of space limitations, an item
name may sometimes appear as incomplete. Use the U.S. Federal Catalog handbook H6-1 for
further item name identification.
6 Mfr. code This indicates the code number of the actual manufacturer of the part.
7 Mfr. part number This indicates the actual manufacturer’s or vendor’s part number.
Abbreviations
Component Number
List of Assemblies
Chassis Parts
Mfr. Code to Manufacturer
Cross Index
Abbreviations conform to American National Standard ANSI Y1.1–1972.
Component number
A23A2R1234 A23 R1234
Assembly number Circuit number
Read: Resistor 1234 (of Subassembly 2) of Assembly 23
A2
Subassembly number
(optional)
A list of assemblies is located at the beginning of the electrical parts list. The
assemblies are listed in numerical order. When a part’s complete component
number is known, this list will identify the assembly in which the part is located.
Chassis-mounted parts and cable assemblies are located at the end of the
Replaceable Electrical Parts List.
The table titled Manufacturers Cross Index shows codes, names, and addresses of
manufacturers or vendors of components listed in the parts list.
5–2
TMS 222 MCF5206/5206E Microprocessor Support
Replaceable Electrical Parts
Manufacturers cross index
Mfr.
code
00779 AMP INC. CUSTOMER SERVICE DEPT
01KV9 MERIX CORP 1521 POPLAR LANE
04222 A VX/KYOCERA PO BOX 867 MYRTLE BEACH, SC 29577
09353 C & K COMPONENTS CORP 57 STANLEY AVE WA TERTOWN, MA 02172–4802
53387 3M COMPANY ELECTRONICS PRODUCTS DIV
57924 BOURNS INC INTEGRATED TECHNOLOGY DIV.
60381 PRECISION INTERCONNECT CORP. 16640 SW 72ND AVE PORTLAND, OR 97224
85480 BRADY USA NAMEPLATE DIVISION
TK0198 HAMILTON HALLMARK 9750 SW NIMBUS AVE BEAVERT ON, OR 97005
TK0198 AVNET INC AVNET ELECTRONICS MKTG, AMERICA
Manufacturer Address City , state, zip code
PO BOX 3608
PO BOX 3000
3M AUSTIN CENTER
1400 NORTH 1000 WEST
P O BOX 571
346 ELIZABETH BRADY RD
15580 SW JAY STREET
HARRISBURG, PA 17105–3608
FOREST GROVE, OR 97116
AUSTIN, TX 78769–2963
LOGAN, UT 84321
HILLSBOROUGH, NC 27278
BEAVERT ON, OR 97006
TMS 222 MCF5206/5206E Microprocessor Support
5–3
Replaceable Electrical Parts
Replaceable electrical parts list
Component
number
– 006–2153–00 MARKER,IDENT:BRADY SPL B–969,FOR NO.00 0.093 X
– 105–1089–00 LATCH ASSY :LATCH HOUSING ASSY,VERTICAL
– 131–5132–00 CONN,BOX:PCB,FEMALE,STR,2 X 20,0.1 CTR,0.325 H X
– 131–5267–00 CONN,HDR:PCB,MALE,STR,2 X 40,0.1 CTR,0.235 MLG
– 131–6134–01 CONN,RCPT :SMD,MICT OR,FEMALE,STR,38 POS,0.025
– 163–1109–00 * IC,DIGITIAL:PRGM
–
– 260–5000–00 SWITCH,SLIDE:SPST,DIP8 POSITION,GOLD OVER
– 283–5114–00 CAP ,FXD,CERAMIC:MLC,0.1UF,10%,50V,X7R,1206,SMD,
– 307–5041–01 RES,NTWK,FXD,FI:15,4.7K OHM,2%,PIN 16
Tektronix
part number
163–1348–00
[
Serial no.
effective
Serial no.
discont’d
Name & description Mfr. code Mfr. part number
0.125,96 PER CARD
MOUNT,0.48 H X 1.24 L,W/PCB SINGLE CLIP,P6434
0.125 TAIL,10 GOLD,
X 0.110 T AIL,30GOLD, HIGH TEMP,
CTR,0.240 H,W/0.108 PCB HOLD DOWNS.PALLADIUM
156–7407–00:CMOS,PLD,EEPLD,22V10,140MA,5NS,520
6,22V10–5,PLCC28–1,TUBE
IC,DIGITIAL:PRGM
156–8320–00,CMOS,PLD:EEPLD,22LV10,130MA,4NS,3.3
VCC:22LV10–4,PLCC28,TUBE
NICKEL,3A,2PF ,SEALED,90HBW08S,44MM T&R
8MM T&R
COMMON,0.08W EA,1.2W
PKG,50PPM,SMD,SO16.200,T&R
* In the MCF5206 only
[ In the MCF5206E only
85480 ORDER BY
DESCRIPTION
60381 105–1089–00
53387 929852–01–20–10
00779 104326–4
00779 767054–1
TK0198 163–1109–00
TK0198 163–1348–00
09353 LD08HOSK1
04222 12065C104KAT(1A
OR 3A)
57924 4816P–002–472
5–4
TMS 222 MCF5206/5206E Microprocessor Support
Diagrams and Circuit Board Illustrations
diagram, and corresponding component locator illustration. The Replaceable Electrical
Parts list is arranged by assembly in numerical sequence; the components are listed by
component number.
Symbols
Component Values
This section contains the troubleshooting procedures, block diagrams, circuit board
illustrations, component locator tables, waveform illustrations, and schematic diagrams.
Graphic symbols and class designation letters are based on ANSI Standard Y32.2-1975.
Abbreviations are based on ANSI Y1.1-1972.
Logic symbology is based on ANSI/IEEE Standard 91-1984 in terms of positive logic.
Logic symbols depict the logic function performed and can differ from the manufacturer’s
data.
The tilde (~) preceding a signal name indicates that the signal performs its intended
function when in the low state.
Other standards used in the preparation of diagrams by Tektronix, Inc., include the
following:
H Tektronix Standard 062-2476 Symbols and Practices for Schematic Drafting
H ANSI Y14.159-1971 Interconnection Diagrams
H ANSI Y32.16-1975 Reference Designations for Electronic Equipment
H MIL-HDBK-63038-1A Military Standard Technical Manual Writing Handbook
Locator Grid
Function Block Title
Internal Screw Adjustment
Onboard Jumper
Digital Ground
Refer to Assembly
& Diagram Number
Offboard Connector
Active Low Signal
Signal From
Another Diagram,
Same Board
A
B
12 3 4
Component Locator Diagrams
The schematic diagram and circuit board component location illustrations have grids
marked on them. The component lookup tables refer to these grids to help you locate a
component. The circuit board illustration appears only once; its lookup table lists the
diagram number of all diagrams on which the circuitry appears.
Some of the circuit board component location illustrations are expanded and divided into
several parts to make it easier for you to locate small components. To determine which
part of the whole locator diagram you are looking at, refer to the small locator key shown
below. The gray block, within the larger circuit board outline, shows where that part fits
in the whole locator diagram. Each part in the key is labeled with an identifying letter that
appears in the figure titles under component locator diagrams.
Power Termination
Component on back of board
Strap
Panel Control
Female Coaxial
Connector
Heat Sink
Decoupled Voltage
Diagram Number
Assembly Number
Diagram Name
Electrical components shown on the diagrams are in the following units unless noted
otherwise:
Capacitors: Values one or greater are in picofarads (pF).
Values less than one are in microfarads (mF).
Resistors: Values are in Ohms (W).
Graphic Items and Special Symbols Used in This Manual
Each assembly in the instrument is assigned an assembly number (for example A5). The
assembly number appears in the title on the diagram, in the lookup table for the schematic
TMS 222 MCF5206/5206E Microprocessor Support
Section of Circuit
Board Shown
A B
DC
5–5
C200
J136
C136
R232
C321
R320
J326
Front
J134
U239
J248J228
C331
C334
J115J345
5–6
J227
Back
TMS 222 MCF5206/5206E Microprocessor Support
TMS 222 MCF5206/5206E Microprocessor Support
5–7
5–8
TMS 222 MCF5206/5206E Microprocessor Support
TMS 222 MCF5206/5206E Microprocessor Support
5–9
5–10
TMS 222 MCF5206/5206E Microprocessor Support
Replaceable Mechanical Parts
Replaceable Mechanical Parts
This chapter contains a list of the replaceable mechanical components for the
TMS 222 MCF5206 and MCF5206E microprocessor support. Use this list to
identify and order replacement parts.
Parts Ordering Information
Replacement parts are available through your local Tektronix field office or
representative.
Changes to Tektronix products are sometimes made to accommodate improved
components as they become available and to give you the benefit of the latest
improvements. Therefore, when ordering parts, it is important to include the
following information in your order:
H Part number
H Instrument type or model number
H Instrument serial number
H Instrument modification number, if applicable
If you order a part that has been replaced with a different or improved part, your
local Tektronix field office or representative will contact you concerning any
change in part number.
Change information, if any, is located at the rear of this manual.
Using the Replaceable Mechanical Parts List
The tabular information in the Replaceable Mechanical Parts List is arranged for
quick retrieval. Understanding the structure and features of the list will help you
find all of the information you need for ordering replacement parts. The
following table describes the content of each column in the parts list.
TMS 222 MCF5206/5206E Microprocessor Support
6–1
Replaceable Mechanical Parts
Parts list column descriptions
Column Column name Description
1 Figure & index number Items in this section are referenced by figure and index numbers to the exploded view illustrations
that follow.
2 Tektronix part number Use this part number when ordering replacement parts from Tektronix.
3 and 4 Serial number Column three indicates the serial number at which the part was first effective. Column four
indicates the serial number at which the part was discontinued. No entries indicates the part is
good for all serial numbers.
5 Qty This indicates the quantity of parts used.
6 Name & description An item name is separated from the description by a colon (:). Because of space limitations, an
item name may sometimes appear as incomplete. Use the U.S. Federal Catalog handbook H6-1
for further item name identification.
7 Mfr. code This indicates the code of the actual manufacturer of the part.
8 Mfr. part number This indicates the actual manufacturer’s or vendor’s part number.
Abbreviations
Chassis Parts
Mfr. Code to Manufacturer
Cross Index
Abbreviations conform to American National Standard ANSI Y1.1–1972.
Chassis-mounted parts and cable assemblies are located at the end of the
Replaceable Electrical Parts List.
The table titled Manufacturers Cross Index shows codes, names, and addresses of
manufacturers or vendors of components listed in the parts list.
6–2
TMS 222 MCF5206/5206E Microprocessor Support
Replaceable Mechanical Parts
Manufacturers cross index
Mfr.
code
00779 AMP INC. CUSTOMER SERVICE DEPT
53387 3M COMPANY ELECTRONICS PRODUCTS DIV
05276 ITT POMONA ELECTRONICS 1500 E NINTH ST POMONA, CA 91766–3835
09353 C & K COMPONENTS CORP 15 RIVERDALE AVENUE NEWTON, MA 02158
60381 PRECISION INTERCONNECT CORP. 16640 SW 72ND AVE PORTLAND, OR 97224
80009 TEKTRONIX INC 14150 SW KARL BRAUN DR
04222 A VX/KYOCERA PO BOX 867 MYRTLE BEACH, SC 29577
57924 BOURNS INC INTEGRATED TECHNOLOGY DIV.
TK0198 AVNET INC AVNET ELECTRONICS MKTG, AMERICA
Manufacturer Address City , state, zip code
PO BOX 3608
3M AUSTIN CENTER
PO BOX 500
1400 NORTH 1000 WEST
15580 SW JAY STREET
HARRISBURG, PA 17105–3608
AUSTIN, TX 78769–2963
BEAVERT ON, OR 97077–0001
LOGAN, UT 84321
BEAVERT ON, OR 97006
Replaceable parts list
Fig. &
index
number
6–1–0 010–0620–00 1 ADAPTER, PROBE: 5206, QFP–160 PIN, TMS222
–1 671–4398–00 1 CIRCUIT BD ASSY: 5206, PQFP–160 SOLDERED,
–0 010–0634–00 1 ADAPTER, PROBE: 5206E, QFP–160 PIN, TMS222
–1 671–5012–00 1 CIRCUIT BD ASSY: 5206E, PQFP–160 SOLDERED,
–2 131–6134–01 3 CONN, RCPT: SMD, MICTOR, PCB, STR, 38 POS,
–3 105–1089–00 3 LATCH ASSY: LATCH HOUSING ASSY, VERTICAL
–4 260–5000–00 1 SWITCH, SLIDE: SPST, DIP8 POSITION, GOLD OVER
–5 131–5267–00 1 CONN, HDR: PCB, MALE, STR, 2 X 40,0.1 CTR, 0.235
–6 131–5132–00 4 CONN, BOX:PCB, FEMALE, STR, 2 X 20, 0.1 CTR,
–7 103–0408–00 1 ADAPTER, QFP:ADAPTER, QFP, 160 POS, 0.65MM
Tektronix
part number
Serial no.
effective
Serial no.
discont’d
Qty Name & description Mfr. code Mfr. part number
OPT 01
TMS222 01
OPT 02
TMS222 OPT 02
FEMALE, 0.025 CTR, 0.240 H, W/0.108 PCB HOLD
DOWNS. PALLAD
MOUNT, 0.48 H X 1.24 L, W/PCB SINGLE CLIP, P6434
NICKEL, 3A, 2PF , SEALED
MLG X 0.110 TAIL, 30GOLD, HIGH TEMP
0.325 H X 0.125 TAIL, 10 GOLD
CTR, EIAJ QFP TO 0.25 SQ, 2X20 HDRS, TEST CLIP,
31.2MM L
05276 010–0620–00
80009 671–4398–00
80009 010–0634–00
80009 671–5012–00
00779 767054–1
60381 105–1089–00
09353 LD08HOSK1
00779 104326–4
53387 929852–01–20–10
05276 5645–2
TMS 222 MCF5206/5206E Microprocessor Support
6–3
Replaceable Mechanical Parts
Replaceable parts list (cont.)
Fig. &
index
number
Tektronix
part number
071–0149–01 1 MANUAL, TECH: INSTRUCTIONS, 5206/5602E, TMS
P6434 3 P6434 MASS TERMINATION PROBE 80009 ORDER BY
Serial no.
effective
Serial no.
discont’d
Mfr. part numberMfr. codeName & descriptionQty
80009 071–0149–01
222
OPTIONAL ACCESSORIES
DESCRIPTION
6–4
TMS 222 MCF5206/5206E Microprocessor Support
Replaceable Mechanical Parts
3
2
1
4
5
6
7
Figure 6–1: MCF5206 probe adapter exploded view
TMS 222 MCF5206/5206E Microprocessor Support
6–5
Replaceable Mechanical Parts
6–6
TMS 222 MCF5206/5206E Microprocessor Support
Index
Index
A
about this manual set, ix
acquiring data, 2–7
Address group
channel assignments, 1–9
display column, 2–11
address hold, 1–2
address line, 2–13
Alternate Bus Master Cycles, 1–2
application, logic analyzer configuration, 1–1
B
background debug mode connector, J136 pinout, 1–13
Bank[1-0] BaseAddr, 2–15
Bank0 Page, 2–15
Bank1 Page, 2–15
basic operations, where to find information, ix
BDM connector pinout, 1–13
Big-Endian byte ordering, 1–2
bus cycles, displayed cycle types, 2–8
byte ordering, 1–2
byte port, 2–16
C
cache, 1–2
channel assignments
Address group, 1–9
clocks, 1–13
Control group, 1–11
Data group, 1–10
DataSize group, 1–12
DramEnbl group, 1–12
Misc group, 1–12
channel groups, 2–1
chip select, 2–13, 2–16
byte port, 2–16
long port, 2–16
port size, 2–16
word port, 2–16
clock channel assignments, 1–13
clock rate, 1–2
SUT, 3–1
clocking, custom, 2–1
clocking options
Default, 2–1
Mode, 2–1
component locator diagrams, 5–5
connections
CPU to Mictor, 1–15
P6434 probes, 1–6
probe adapter to SUT, QFP, 1–4
without probe adapter, 1–8
channel probes, 1–8
contacting T ektronix, x
Control Flow display format, 2–11
Control group
channel assignments, 1–11
symbol table, 2–4
CPU to Mictor connections, 1–15
custom clocking, 2–1
cycle marking, 2–17
cycle types, 2–8
D
data
acquiring, 2–7
disassembly formats
Control Flow, 2–11
Hardware, 2–8
Software, 2–11
State, 2–8
Subroutine, 2–11
Timing, 2–8
data display , changing, 2–12
Data group
channel assignments, 1–10
display column, 2–11
data reads and writes, 1–2
DataSize, symbol table, 2–6
DataSize group, channel assignments, 1–12
Default clocking option, 2–1
DefaultMem port size, 2–14
diagrams and circuit board illustrations, 5–5–5–6
dimensions, probe adapter, 3–4
DIP switch
configuring, 1–3
example, 1–3
settings, 1–3
disassembled data
cycle type definitions, 2–8
viewing, 2–7
disassembler
definition, ix
logic analyzer configuration, 1–1
TMS 222 MCF5206/5206E Microprocessor Support
Index–1
Index
setup, 2–1
disassembly display options, 2–13
disasm across gaps, 2–13
display mode, 2–13
highlight, 2–13
highlight gaps, 2–13
show , 2–13
timestamp, 2–13
Disassembly Format Definition overlay, 2–13
Disassembly property page, 2–13
display format
Control Flow, 2–11
Control flow, 2–7
Hardware, 2–7, 2–8
Listing, 2–8
Software, 2–7, 2–11
special characters, 2–7
State, 2–7, 2–8
Subroutine, 2–7, 2–11
Timing, 2–7, 2–8
Waveform, 2–8
DramEnbl group, channel assignments, 1–12
E
electrical specifications, 3–1
clock rate, 3–1
loading, 3–1
electrostatic immunity, 3–3
environmental specifications, 3–3
altitude, 3–3
humidity , 3–3
temperature, 3–3
exception vectors, 2–18
J
J136 pinout, 1–13
L
Listing display format, 2–8
loading, 3–1
signal, 3–1
logic analyzer
configuration for disassembler, 1–1
configuration for the application, 1–1
with a DAS 9200 series, 1–1
with a TLA 700 series, 1–1
definition, x
software compatibility, 1–1
long port, 2–16
M
manual
conventions, ix
how to use the set, ix
marking cycles, 2–17
microprocessor functionality not supported
address hold, 1–2
Alternate Bus Master Cycles, 1–2
cache, 1–2
Mictor to CPU connections, 1–15
Misc group, channel assignments, 1–12
Mnemonics display column, 2–11
Mode clocking option, 2–1
O
H
Hardware display format, 2–8
cycle type definitions, 2–8
hold time, minimum, 3–1
I
information on basic operations, definition, ix
inspection, test clip, 4–1
inspection and cleaning
microcontroller, 1–6
QFP test clip, 1–6
Internal cache, 1–2
Index–2
optional display selections
address line, 2–13
Bank[1-0] BaseAddr, 2–15
Bank0 Page, 2–15
Bank1 Page, 2–15
chip select, 2–13
CS[1-0]~ port size, 2–16
CS[3-2]~ port size, 2–16
CS[5-4]~ port size, 2–16
CS[7-0]~ port size, 2–16
CS[7-6]~ port size, 2–17
DefaultMem port size, 2–14
Port Size, 2–15
VBR, 2–15
TMS 222 MCF5206/5206E Microprocessor Support
Index
vector base register, 2–15
vector table size, 2–16
write enable, 2–13
P
MCF5206, definition, ix
P6434 probes, connecting. See connections
package, QFP, 1–1
Port Size, 2–15
power requirements, SUT , 3–1
probe adapter
chip select switch, 1–3
DIP switch settings, 1–3
example settings, 1–3
circuit description, 4–1
clearance, dimensions, 3–4
configuring the DIP switch, 1–3
example, 1–3
connecting the P6434 probes, 1–5
hardware description, 4–1
how to unlock test clip, 1–8
inspection and cleaning, 1–6
not using one, 1–8
removing, 1–8
Q
QFP package, 1–1
QFP test clip, 1–5
attaching to microcontroller, 1–7
attaching to probe adapter, 1–5
inspection and cleaning, 1–6
special characters displayed, 2–7
specifications, 3–1
channel assignments, 1–9
electrical, 3–1
environmental, 3–3
mechanical (dimensions), 3–4
State display format, 2–8
static discharge
caution statement, 1–4
how to discharge, 1–4
Subroutine display format, 2–11
support setup, 2–1
supported package style, 1–1
SUT, probe adapter connection procedure, 1–4
SUT hardware Reset, 1–2
symbol table
Control channel group, 2–4
DataSize, 2–6
system clock rate, 1–2
T
terminology, ix
test clip
connecting to probe adapter, 1–5
how to lock, 1–7
how to unlock, 1–8
inspection and cleaning, 1–6
installing, 1–5
QFP, 1–5
removing, 1–8
test clip inspection, 4–1
Timing display format, 2–8
typical signal loading, 3–1
R
reference material, 1–1
Reset, SUT hardware, 1–2
restrictions, 1–1
S
set up time, minimum, 3–1
setups, disassembler, 2–1
signal loading, 3–1
signals, active low sign, x
signals not acquired, 2–12
signals not required, 1–20
Software display format, 2–11
TMS 222 MCF5206/5206E Microprocessor Support
V
VBR, 2–15
vector base register, 2–15
vector table size, 2–16
maximum value, 2–16
minimum value, 2–16
viewing disassembled data, 2–7
W
Waveform display format, 2–8
word port, 2–16
write enable, 2–13
Index–3
Index
Index–4
TMS 222 MCF5206/5206E Microprocessor Support
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