Agilent Technologies Switch 01664 97005 User Manual

Service Guide  
Publication number 01664-97005  
Second edition, January 2000  
For Safety information, Warranties, and Regulatory  
information, see the pages at the end of the book.  
Copyright Agilent Technologies 1987–2000  
All Rights Reserved.  
Agilent Technologies 1664A Logic  
Analyzer  
Download from Www.Somanuals.com. All Manuals Search And Download.  
The Agilent Technologies 1664A Logic Analyzer  
iii  
Download from Www.Somanuals.com. All Manuals Search And Download.  
In This Book  
This book is the service guide for the 1664A Logic Analyzers and is divided into eight chapters.  
Chapter 1 contains information about the logic analyzer and includes accessories,  
specifications and characteristics, and equipment required for servicing.  
Chapter 2 tells how to prepare the logic analyzer for use.  
Chapter 3 gives instructions on how to test the performance of the logic analyzer.  
Chapter 4 contains calibration instructions for the logic analyzer.  
Chapter 5 contains self-tests and flowcharts for troubleshooting the logic analyzer.  
Chapter 6 tells how to replace assemblies of the logic analyzer and how to return them to  
Agilent Technologies.  
Chapter 7 lists replaceable parts, shows an exploded view, and gives ordering information.  
Chapter 8 explains how the logic analyzer works and what the self-tests are checking.  
iv  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Table of Contents  
1 General Information  
Accessories 1–2  
Specifications 1–3  
Characteristics 1–3  
Supplemental Characteristics 1–4  
Recommended Test Equipment 1–8  
2 Preparing for Use  
To inspect the logic analyzer 2–2  
Ferrites 2–3  
To apply power 2–4  
To operate the user interface 2–4  
To set the line voltage 2–4  
To degauss the display 2–5  
To clean the logic analyzer 2–5  
To test the logic analyzer 2–5  
3 Testing Performance  
To perform the self-tests 3–3  
To make the test connectors 3–6  
To test the threshold accuracy 3–8  
Set up the equipment 3–8  
Set up the logic analyzer 3–9  
Connect the logic analyzer 3–9  
Test the TTL threshold 3–10  
Test the ECL threshold 3–12  
Test the User threshold 3–13  
Test the + User threshold 3–14  
Test the 0 V User threshold 3–15  
Test the next pod 3–16  
To test the glitch capture 3–17  
Set up the equipment 3–17  
Set up the logic analyzer 3–18  
Connect the logic analyzer 3–18  
Test the glitch capture on the connected channels 3–20  
Test the next channels 3–22  
To test the single-clock, single-edge, state acquisition 3–23  
Set up the equipment 3–23  
Set up the logic analyzer 3–24  
Connect the logic analyzer 3–26  
Verify the test signal 3–27  
Check the setup/hold combination 3–29  
v
Download from Www.Somanuals.com. All Manuals Search And Download.  
Contents  
To test the multiple-clock, multiple-edge, state acquisition 1–34  
Set up the equipment 1–34  
Set up the logic analyzer 1–35  
Connect the logic analyzer 1–37  
Verify the test signal 1–38  
Check the setup/hold with single clock edges, multiple clocks 1–40  
To test the single-clock, multiple-edge, state acquisition 1–45  
Set up the equipment 1–45  
Set up the logic analyzer 1–46  
Connect the logic analyzer 1–48  
Verify the test signal 1–49  
Check the setup/hold combination 1–51  
To test the time interval accuracy 1–54  
Set up the equipment 1–54  
Set up the logic analyzer 1–55  
Connect the logic analyzer 1–57  
Acquire the data 1–58  
Performance Test Record 3–59  
4 Calibrating and Adjusting  
Logic analyzer calibration 4–2  
Set up the equipment 4–2  
To adjust the CRT monitor alignment 4–3  
To adjust the CRT intensity 4–5  
5 Troubleshooting  
To use the flowcharts 5–2  
To check the power-up tests 5–15  
To run the self-tests 5–16  
To test the power supply voltages 5–21  
To test the CRT monitor signals 5–23  
To test the keyboard signals 5–24  
To test the disk drive voltages 5–25  
To perform the BNC test 5–27  
To test the logic analyzer probe cables 5–28  
To test the auxiliary power 5–32  
6 Replacing Assemblies  
To remove and replace the handle 6–5  
To remove and replace the feet and tilt stand 6–5  
To remove and replace the cover 6–5  
To remove and replace the disk drive 6–6  
To remove and replace the power supply 6–7  
vi  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Contents  
To remove and replace the Main Circuit board 6–7  
To remove and replace the switch actuator assembly 6–8  
To remove and replace the rear panel assembly 6–9  
To remove and replace the front panel and keyboard 6–10  
To remove and replace the intensity adjustment 6–10  
To remove and replace the monitor 6–11  
To remove and replace the handle plate 6–11  
To remove and replace the fan 6–12  
To remove and replace the line filter 6–12  
To remove and replace the optional GPIB and RS-232C cables 6–13  
To return assemblies 6–14  
7 Replaceable Parts  
Replaceable Parts Ordering 7–2  
Exploded View 7–3  
Replaceable Parts List 7–4  
Power Cables and Plug Configurations 7–8  
8 Theory of Operation  
Block-Level Theory 8–3  
The 1664A Logic Analyzer 8–3  
The Logic Acquisition Circuitry 8–6  
Self-Tests Description 8–9  
Power-up Self-Tests 8–9  
System Tests (System PV) 8–10  
Analyzer Tests (Analy PV) 8–13  
GPIB (Optional) 8–15  
RS-232C(Optional) 8–16  
Centronix 8–17  
vii  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Contents  
viii  
Download from Www.Somanuals.com. All Manuals Search And Download.  
1
Accessories 1-2  
Specifications 1-3  
Characteristics 1-3  
Supplemental Characteristics 1-4  
Recommended Test Equipment 1-8  
General Information  
Download from Www.Somanuals.com. All Manuals Search And Download.  
General Information  
This chapter lists the accessories, the specifications and characteristics, and the  
recommended test equipment.  
Accessories  
The following accessories are supplied with the 1664A Logic Analyzers.  
Accessories  
SuppliedPart  
Number Qty  
01650-61608  
cables16550-61601  
5090-4356  
Probe ground (5 per pack) 5959-9334  
Probe tip assemblies  
Probe  
2
1
2
2
1
1
1
Grabbers (20 per pack)  
User’s Reference  
Accessories Pouch  
HIL Mouse  
01660-90904  
01660-84501  
A2838A  
Accessories Available  
Other accessories available for the 1664A Logic Analyzer are listed in the Accessories for  
Agilent Logic Analyzers brochure. The table below lists additional documentation that is  
available from your nearest Agilent Technologies sales office for use with your logic analyzer.  
Accessories Available  
Demo Training Kit  
Programming Reference  
Service Guide  
Part Number  
E2433-60007  
01660-90933  
01664-97005  
1–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
General Information  
Specifications  
Specifications  
The specifications are the performance standards against which the product is tested.  
Maximum State Speed  
50 MHz  
3.5 ns  
Minimum State Clock Pulse Width*  
Minimum Master to Master Clock Time*  
Minimum Glitch Width*  
20.0 ns  
3.5 ns  
Threshold Accuracy  
(100 mV + 3% of  
threshold setting)  
Setup/Hold Time:*  
Single Clock, Single Edge  
0.0/3.5 ns through 3.5/0.0 ns,  
adjustable in 500-ps increments  
Single  
Clock,  
Multiple  
Edges0.0/4.0  
ns th  
adjustable in 500-ps increments  
Multiple Clocks, Multiple Edges  
0.0/4.5 ns through 4.5/0.0 ns,  
adjustable in 500-ps increments  
* Specified for an input signal VH = -0.9 V, VL = -1.7 V, slew rate = 1 V/ns, and threshold = -1.3 V.  
Characteristics  
These characteristics are not specifications, but are included as additional information.  
Full Channel  
50 MHz  
250 MHz  
125 MHz  
N/A  
Half Channel  
50 MHz  
500 MHz  
250 MHz  
125 MHz  
8K*  
Maximum State Clock Rate  
Maximum Conventional Timing Rate  
Maximum Transitional Timing Rate  
Maximum Timing with Glitch Rate  
Memory Depth  
4K  
Channel Count:  
34  
17  
* For all modes except glitch.  
1–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
General Information  
Supplemental Characteristics  
Supplemental Characteristics  
Probes  
Input Resistance  
100 k, 2%  
Input Capacitance  
Minimum Voltage Swing  
Threshold Range  
~ 8 pF  
500 mV, peak-to-peak  
6.0 V, adjustable in 50-mV increments  
State Analysis  
State/Clock  
Qualifiers6  
Time Tag Resolution*  
8 ns or 0.1%, whichever is greater  
Maximum Time Count  
Between  
States34 econds  
s
Maximum State Tag Count* 4.29 x 109  
Timing Analysis  
Sample Period Accuracy 0.01 % of sample period  
Channel-to-Channel Skew 2 ns, typical  
Time Interval Accuracy  
[sample period + channel-to-channel skew  
+(0.01%)(time reading)]  
Triggering  
Sequencer Speed  
125 MHz, maximum  
Levels12  
State  
Sequence  
Sequence  
Timing  
Levels10  
Maximum Occurrence Counter  
Value  
1,048,575  
Pattern  
Recognizers10  
34 channels  
Recognizers2  
Maximum Pattern Width  
Range  
Range Width  
32 bits each  
Timers2  
Timer Value Range  
Glitch/Edge  
400 ns to 500 seconds  
Recognizers2  
(timing  
only)  
Maximum Glitch/Edge Width  
34 channels  
*Maximum state clock rate with time or state tags on is 50 MHz. When all pods are assigned to a state or timing  
machine, time or state tags halve the memory depth.  
1–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
General Information  
Supplemental Characteristics  
Measurement and Display Functions  
Displayed Waveforms 24 lines maximum, with scrolling across 96 waveforms.  
Measurement Functions  
Run/Stop Functions Run starts acquisition of data in specified trace mode.  
Stop In single trace mode or the first run of a repetitive acquisition, Stop halts  
acquisition and displays the current acquisition data. For subsequent runs in repetitive  
mode, Stop halts acquisition of data and does not change the current display.  
Trace Mode Single mode acquires data once per trace specification. Repetitive mode  
repeats single mode acquisitions until Stop is pressed or until the time interval between  
two specified patterns is less than or greater than a specified value, or within or not within  
a specified range.  
Indicators  
Activity Indicators Provided in the Configuration and Format menus for identifying  
high, low, or changing states on the inputs.  
Markers Two markers (X and O) are shown as vertical dashed lines on the display.  
Trigger Displayed as a vertical dashed line in the Timing Waveform display and as line 0  
in the State Listing display.  
Data Entry/Display  
Labels Channels may be grouped together and given a 6-character name. Up to  
126 labels in each analyzer may be assigned with up to 32 channels per label.  
Display Modes State listing, State Waveforms, Chart, Compare Listing, Compare  
Difference Listing, Timing Waveforms, and Timing Listings. State Listing and Timing  
Waveforms can be time-correlated on the same displays.  
Timing Waveform Pattern readout of timing waveforms at X or O marker.  
Bases Binary, Octal, Decimal, Hexadecimal, ASCII (display only), Two’s Complement,  
and User-defined symbols.  
Symbols 1,000 maximum. Symbols can be downloaded over RS-232 or GPIB.  
1–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
General Information  
Supplemental Characteristics  
Marker Functions  
Time Interval The X and O markers measure the time interval between a point on a  
timing waveform and the trigger, two points on the same timing waveform, two points on  
different waveforms, or two states (time tagging on).  
Delta States (state analyzer only) The X and O markers measure the number of  
tagged states between one state and trigger or between two states.  
Patterns The X and O markers can be used to locate the nth occurrence of a specified  
pattern from trigger, or from the beginning of data. The O marker can also find the nth  
occurrence of a pattern from the X marker.  
Statistics X and O marker statistics are calculated for repetitive acquisitions. Patterns  
must be specified for both markers, and statistics are kept only when both patterns can be  
found in an acquisition. Statistics are minimum X to O time, maximum X to O time,  
average X to O time, and ratio of valid runs to total runs.  
Auxiliary Power  
Power  
Through  
Cables1/3  
amp  
at  
5
Operating Environment  
Temperature  
Instrument, 0 °C to 55 °C (+32 °F to 131 °F).  
Probe lead sets and cables,  
0 °C to 65 °C (+32 °F to 149 °F).  
Humidity  
Instrument, probe lead sets, and cables, up to  
95% relative humidity at +40 °C (+122 °F).  
Altitude  
To 4600 m (15,000 ft).  
Vibration  
Operating: Random vibration 5 to 500 Hz,  
10 minutes per axis, 0.3 g (rms).  
Non-operating: Random vibration 5 to 500 Hz,  
10 minutes per axis, 2.41 g (rms);  
and swept sine resonant search, 5 to 500 Hz,  
0.75 g (0-peak), 5 minute resonant dwell  
at 4 resonances per axis.  
Dimensions  
1–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
General Information  
Supplemental Characteristics  
Product Regulations  
Safety  
IEC 348  
UL 1244  
CSA Standard C22.2 No.231 (Series M-89)  
EMC  
This product meets the requirement of the European  
Communities (EC) EMC Directive 89/336/EEC.  
Emissions  
Immunity  
EN55011/CSIPR 11 (ISM, Group1,Class A equipment)  
SABS RAA Act No. 24(1990)  
EN50082-1  
Code1 Notes2  
IEC 801-2 (ESD)4kV CD, 8kV AD  
IEC 801-3 (Rad.) 3V/m  
IEC 801-4 (EFT) 1kV  
2
1
2
1Performance Codes:  
1 PASS - Normal operations, no effect.  
2 PASS - Temporary degradation, self recoverable.  
3 PASS - Temporary degradation, operator intervention required.  
4 FAIL - Not recoverable, component damage.  
2Notes: (None)  
1–7  
Download from Www.Somanuals.com. All Manuals Search And Download.  
General Information  
Recommended Test Equipment  
Recommended Test Equipment  
Equipment Required  
Equipment  
Critical Specifications  
Recommended  
Model/Part  
Use*  
Pulse Generator  
100 MHz, 3.5 ns pulse width,  
< 600 ps rise time  
Agilent 8131A Option 020 P,T  
Digitizing Oscilloscope  
Function Generator  
Agilent 54121T  
P
6 GHz bandwidth, < 58 ps rise time  
Accuracy (5)(106) × frequency,  
Agilent 3325B Option 002 P  
DC offset voltage 6.3 V  
Digital Multimeter  
BNC-Banana Cable  
BNC Tee  
0.1 mV resolution, 0.005% accuracy  
Agilent 3458A  
P
Agilent 11001-60001  
Agilent 1250-0781  
Agilent 8120-1840  
Agilent 8120-4948  
Agilent 1250-1200  
Agilent 1250-2015  
Agilent 1250-0216  
Agilent 54006A  
P
BNC (m)(f)(f)  
P
P,T  
P
P, T  
P
P, T  
P
P
Cable  
BNC (m)(m) 48 inch > 2GHz bandwidth  
18 GHz bandwidth  
SMA(m)-BNC(f)  
SMA Coax Cable (Qty 3)  
Adapter (Qty 4)  
Adapter  
SMA(f)-BNC(m)  
BNC (m)(m)  
Coupler (Qty 4)  
20:1 Probes (Qty 2)  
BNC Test Connector, 17x2  
(Qty 1)**  
BNC Test Connector, 6x2  
P,T  
(Qty 4)**  
Digitizing Oscilloscope  
BNC Shorting Cap  
BNC-Banana Adapter  
Light Power Meter  
Alignment Tool  
> 100 MHz Bandwidth  
Agilent 54600A  
Agilent 1250-0074  
Agilent 1251-2277  
United Detector 351  
8710-1300  
T
T
T
A
A
*A = Adjustment  
P = Performance Tests  
T = Troubleshooting  
**Instructions for making these test connectors are in chapter 3, "Testing Performance."  
1–8  
Download from Www.Somanuals.com. All Manuals Search And Download.  
2
To inspect the logic analyzer 2-2  
Ferrites 2-3  
To apply power 2-4  
To operate the user interface 2-4  
To set the line voltage 2-4  
To degauss the display 2-5  
To clean the logic analyzer 2-5  
To test the logic analyzer 2-5  
Preparing for Use  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Preparing For Use  
This chapter gives you instructions for preparing the logic analyzer for use.  
Power Requirements  
The logic analyzer requires a power source of either 115 Vac or 230 Vac, –22 % to  
+10 %, single phase, 48 to 66 Hz, 200 Watts maximum power.  
Operating Environment  
The operating environment is listed in chapter 1. Note the noncondensing humidity  
limitation. Condensation within the instrument can cause poor operation or  
malfunction. Provide protection against internal condensation.  
The logic analyzer will operate at all specifications within the temperature and  
humidity range given in chapter 1. However, reliability is enhanced when operating  
the logic analyzer within the following ranges:  
Temperature: +20 °C to +35 °C (+68 °F to +95 °F)  
Humidity: 20% to 80% noncondensing  
Storage  
Store or ship the logic analyzer in environments within the following limits:  
Temperature: -40 °C to + 75 °C  
Humidity: Up to 90% at 65 °C  
Altitude: Up to 15,300 meters (50,000 feet)  
Protect the logic analyzer from temperature extremes which cause condensation on  
the instrument.  
To inspect the logic analyzer  
1 Inspect the shipping container for damage.  
If the shipping container or cushioning material is damaged, keep them until you have  
checked the contents of the shipment and checked the instrument mechanically and  
electrically.  
2 Check the supplied accessories.  
Accessories supplied with the logic analyzer are listed in "Accessories" in chapter 1.  
3 Inspect the product for physical damage.  
Check the logic analyzer and the supplied accessories for obvious physical or mechanical  
defects. If you find any defects, contact your nearest Agilent Technologies Sales Office.  
Arrangements for repair or replacement are made, at Agilent Technologies’ option, without  
waiting for a claim settlement.  
2–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Preparing for Use  
Ferrites  
Ferrites  
Ferrites are included in the 1664A accessory pouch for the logic analyzer cable. When  
properly installed, the ferrites reduce RFI emissions from the logic analyzer.  
In order to ensure compliance of the 1664A Logic Analyzer to the CISPR11 Class A radio  
frequency interference (RFI) limits, you must install the ferrite to absorb radio frequency  
energy.  
Note: Adding or removing the ferrite will not affect the normal operation of the analyzer.  
Ferrite Installation Instructions  
Use the following steps to install the ferrite on the logic analyzer cable.  
1 Place the ferrite halves and spacer on the logic analyzer cable like a clamshell  
around the whole cable. The ferrite should be 10 cm (about 4 in) from the the end of  
the cable shell as shown.  
2 Insert the clamps onto the ends of the ferrites. The locking tab should fit cleanly in  
the ferrite grooves.  
When properly installed, the ferrite should appear on the logic analyzer cable as shown.  
2–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Preparing for Use  
To apply power  
To apply power  
Electrostatic discharge can damage electronic components. Use grounded wriststraps and  
mats when performing any service to the logic analyzer.  
C AU T I O N  
1 Check that the line voltage selector, located on the rear panel, is on the correct  
setting and the correct fuse is installed.  
See also, "To set the line voltage" on this page.  
2 Connect the power cord to the instrument and to the power source.  
This instrument is equipped with a three-wire power cable. When connected to an  
appropriate ac power outlet, this cable grounds the instrument cabinet. The type of power  
cable plug shipped with the instrument depends on the country of destination. Refer to  
chapter 7, "Replaceable Parts," for option numbers of available power cables and plug  
configurations.  
3 Turn on the instrument power switch located on the front panel.  
To operate the user interface  
To select a field on the logic analyzer screen, use the arrow keys to highlight the  
field, then press the Select key. For more information about the logic analyzer  
interface, refer to the Agilent Technologies 1660 Series Logic Analyzer User’s  
Reference.  
To set the GPIB address or to configure for RS-232C, refer to the Agilent  
Technologies 1660 Series Logic Analyzer User’s Reference.  
To set the line voltage  
When shipped from the factory, the line voltage selector is set and an appropriate fuse is  
installed for operating the instrument in the country of destination. To operate the  
instrument from a power source other than the one set, perform the following steps.  
2–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Preparing for Use  
To degauss the display  
1 Turn the power switch to the Off position, then remove the power cord from the  
instrument.  
2 Remove the fuse module by carefully prying at the top center of the fuse module  
until you can grasp it and pull it out by hand.  
3 Reinsert the fuse module with the arrow for the appropriate line voltage aligned  
with the arrow on the line filter assembly switch.  
4 Reconnect the power cord. Turn on the instrument by setting the power switch to  
the On position.  
To degauss the display  
If the logic analyzer has been subjected to strong magnetic fields, the CRT might  
become magnetized and display data might become distorted. To correct this  
condition, degauss the CRT with a conventional external television type degaussing  
coil.  
To clean the logic analyzer  
With the instrument turned off and unplugged, use mild soap and water to clean the  
front and cabinet of the logic analyzer. Harsh soap might damage the water-base  
paint.  
To test the logic analyzer  
If you require a test to verify the specifications, start at the beginning of chapter 3,  
"Testing Performance."  
If you require a test to initially accept the operation, perform the self-tests in  
chapter 3.  
If the logic analyzer does not operate correctly, go to the beginning of chapter 5,  
"Troubleshooting."  
2–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
2–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
3
To perform the self-tests 3-3  
To make the test connectors 3-6  
To test the threshold accuracy 3-8  
To test the glitch capture 3-17  
To test the single-clock, single-edge, state acquisition 3-23  
To test the multiple-clock, multiple-edge, state acquisition 3-34  
To test the single-clock, multiple-edge, state acquisition 3-45  
To test the time interval accuracy 3-54  
Performance Test Record 3-59  
Testing Performance  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
This chapter tells you how to test the performance of the logic analyzer against the  
specifications listed in chapter 1. To ensure the logic analyzer is operating as  
specified, you perform software tests (self-tests) and manual performance tests on  
the analyzer. The logic analyzer is considered performance-verified if all of the  
software tests and manual performance tests have passed. The procedures in this  
chapter indicate what constitutes a "Pass" status for each of the tests.  
The Logic Analyzer Interface  
To select a field on the logic analyzer screen, use the arrow keys to highlight the field,  
then press the Select key. For more information about the logic analyzer interface,  
refer to the Agilent Technologies 1660 Series Logic Analyzer User’s Reference.  
Test Strategy  
For a complete test, start at the beginning with the software tests and continue  
through to the end of the chapter. For an individual test, follow the procedure in the  
test. The examples in this chapter were performed using an 1664A.  
The performance verification procedures starting on page 3–8 are each shown from  
power-up. To exactly duplicate the set-ups in the tests, save the power-up  
configuration to a file on a disk, then load that file at the start of each test.  
If a test fails, check the test equipment set-up, check the connections, and verify  
adequate grounding. If a test still fails, the most probable cause of failure would be  
the main circuit board.  
Test Interval  
Test the performance of the logic analyzer against specifications at two-year intervals  
or if it is replaced or repaired.  
Performance Test Record  
A performance test record for recording the results of each procedure is located at  
the end of this chapter. Use the performance test record to gauge the performance  
of the logic analyzer over time.  
Test Equipment  
Each procedure lists the recommended test equipment. You can use equipment that  
satisfies the specifications given. However, the procedures are based on using the  
recommended model or part number. Before testing the performance of the logic  
analyzer, warm-up the instrument and the test equipment for 30 minutes.  
3–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To perform the self-tests  
The self-tests verify the correct operation of the logic analyzer. Self-tests can be  
performed all at once or one at a time. While testing the performance of the logic  
analyzer, run the self-tests all at once.  
1 Disconnect all inputs, insert the boot disk, then turn on the power switch. Wait until  
the power-up tests are complete.  
2 Press the System key. Select the field next to System, then select Test in the pop-up  
menu then press the Select key.  
3 Select the box labeled Load Test System then press the Select key. Load the disk  
containing the performance verification (self-tests) into the disk drive (normally the  
same as the boot disk).  
4 Select the box labeled Continue and press the Select key.  
5 After the test files have been loaded, the Analy PV menu is displayed. Select All  
Analyzer Tests.  
You can run all tests at one time, except for the Data Input Inspection, by running All  
Analyzer Tests. To see more details about each test when troubleshooting failures, you can  
run each test individually. This example shows how to run all tests at once.  
When the tests finish, the status for each test shows Passed or Failed, and the status  
for the All Analyzer Tests changes from Untested to Tested.  
6 Select Analy PV, then select Sys PV in the pop-up menu.  
3–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To perform the self-tests  
7 Select the Printer/Controller field next to Sys PV, then select System Test in the  
pop-up menu then press the Select key.  
8 Install a formatted disk that is not write protected into the disk drive. If the 1664A  
has the RS-232C option (020), connect an RS-232C loopback connector onto the  
RS-232C port.  
9 Select All System Tests.  
You can run all tests at one time, except for the Front Panel Test and Display Test, by running  
All System Tests. To see more details about each test when troubleshooting failures, you can  
run each test individually. This example shows how to run all tests at once.  
When the tests finish, the status for each test shows Passed or Failed, and the status for the  
All System Tests changes from Untested to Tested. Note that the Front Panel Test and  
Display Test remain Untested, and the RS-232C Test will display FAILED if option 020 is not  
installed.  
10 Select the Front Panel Test.  
A screen duplicating the front panel appears on the screen.  
a Press each key on the front panel. The corresponding key on the screen will change  
from a light to a dark color. Test the knob by turning it in both directions.  
b Note any failures, then press the Done key a second time to exit the Front Panel Test.  
The status of the test changes from Untested to Tested.  
3–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To perform the self-tests  
11 Select the Display Test.  
A white grid pattern is displayed. These display screens are not normally used, but can be  
used to adjust the display. Refer to chapter 4, "Calibrating and Adjusting" for display  
adjustments.  
a Select Continue and the screen changes to full bright.  
b Select Continue and the screen changes to half bright.  
c Select Continue and the test screen shows the Display Test status changed to Tested.  
12 Record the results of the tests on the performance test record at the end of this  
chapter.  
13 To exit the test system, press the System key, then select Exit Test in the pop-up  
menu and press the Select key. Reinstall the disk containing the operating system,  
then select Exit Test System and press the Select key.  
3–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To make the test connectors  
The test connectors connect the logic analyzer to the test equipment.  
Materials Required  
Description  
Recommended Part  
Qty  
BNC (f) Connector  
Agilent 1250-1032  
Agilent 0698-7212  
5
8
100 1% resistor  
Berg Strip, 17-by-2  
Berg Strip, 6-by-2  
20:1 Probe  
1
4
2
Agilent 54006A  
Jumper wire  
1 Build four test connectors using BNC connectors and 6-by-2 sections of Berg strip.  
a Solder a jumper wire to all pins on one side of the Berg strip.  
b Solder a jumper wire to all pins on the other side of the Berg strip.  
c Solder two resistors to the Berg strip, one at each end between the end pins.  
d Solder the center of the BNC connector to the center pin of one row on the Berg strip.  
e Solder the ground tab of the BNC connector to the center pin of the other row on the  
Berg strip.  
f On two of the test connectors, solder a 20:1 probe. The probe ground goes to the  
same row of pins on the test connector as the BNC ground tab.  
3–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To make the test connectors  
2 Build one test connector using a BNC connector and a 17-by-2 section of Berg strip.  
a Solder a jumper wire to all pins on one side of the Berg strip.  
b Solder a jumper wire to all pins on the other side of the Berg strip.  
c Solder the center of the BNC connector to the center pin of one row on the Berg strip.  
d Solder the ground tab of the BNC connector to the center pin of the other row on the  
Berg strip.  
3–7  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To test the threshold accuracy  
Testing the threshold accuracy verifies the performance of the following specification:  
Clock and data channel threshold accuracy.  
These instructions include detailed steps for testing the threshold settings of pod 1.  
After testing pod 1, connect and test pod 2. To test pod 2, follow the detailed steps  
for pod 1, substituting the pod 2 for pod 1 in the instructions.  
Each threshold test tells you to record the voltage reading in the performance test  
record located at the end of this chapter. To check if each test passed, verify that the  
voltage reading you record is within the limits listed on the performance test record.  
Equipment Required  
Equipment  
Critical Specifications  
Recommended Model/Part  
Digital Multimeter  
Function Generator  
0.1 mV resolution, 0.005% accuracy  
DC offset voltage 6.3 V  
Agilent 3458A  
Agilent 3325B Option 002  
BNC-Banana Cable  
BNC Tee  
Agilent 11001-60001  
Agilent 1250-0781  
Agilent 8120-1840  
BNC Cable  
BNC Test Connector, 17x2  
Set up the equipment  
1 Turn on the equipment required and the logic analyzer. Let them warm up for  
30 minutes before beginning the test.  
2 Set up the function generator.  
a Set up the function generator to provide a DC offset voltage at the Main Signal output.  
b Disable any AC voltage to the function generator output, and enable the high voltage  
output.  
c Monitor the function generator DC output voltage with the multimeter.  
3–8  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
Set up the logic analyzer  
1 Press the Config key. Assign all pod fields to Machine 1. To assign the pod fields,  
select the pod fields, then select Machine 1 in the pop-up menu.  
2 In the Analyzer 1 box, select the Type field. Select Timing in the pop-up menu.  
Connect the logic analyzer  
1 Using the 17-by-2 test connector, BNC cable, and probe tip assembly, connect the  
data and clock channels of pod 1 to one side of the BNC Tee.  
2 Using a BNC-banana cable, connect the voltmeter to the other side of the BNC Tee.  
3 Connect the BNC Tee to the Main Signal output of the function generator.  
3–9  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
Test the TTL threshold  
1 Press the Format key. Select the field to the right of Pod 1, then select TTL in the  
pop-up menu.  
2
On the function generator front panel, enter 1.647 V 1 mV DC offset. Use the  
multimeter to verify the voltage.  
The activity indicators for pod 1 should show all data channels and the J-clock channel at a  
logic high.  
3 Using the Modify down arrow on the function generator, decrease offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels at a logic  
low. Record the function generator voltage in the performance test record.  
3–10  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
4 Using the Modify up arrow on the function generator, increase offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels at a logic  
high. Record the function generator voltage in the performance test record.  
3–11  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
Test the ECL threshold  
1 Select the field to the right of Pod 1, then select ECL in the pop-up menu.  
2
On the function generator front panel, enter 1.160 V 1 mV DC offset. Use the  
multimeter to verify the voltage.  
The activity indicators for pod 1 should show all data channels and the J-clock channel at a  
logic high.  
3 Using the Modify down arrow on the function generator, decrease offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels are at a  
logic low. Record the function generator voltage in the performance test record.  
4 Using the Modify up arrow on the function generator, increase offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels are at a  
logic high. Record the function generator voltage in the performance test record.  
3–12  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
Test the User threshold  
1 Move the cursor to the field to the right of Pod 1. Type –6.00, then use the left and  
right cursor control keys to highlight V. Press the Select key.  
2
On the function generator front panel, enter 5.718 V 1 mV DC offset. Use the  
multimeter to verify the voltage.  
The activity indicators for pod 1 should show all data channels and the J-clock channel at a  
logic high.  
3 Using the Modify down arrow on the function generator, decrease offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels at a logic  
low. Record the function generator voltage in the performance test record.  
4 Using the Modify up arrow on the function generator, increase offset voltage in  
1-mV increments until all activity indicators show the channels at a logic high.  
Record the function generator voltage in the performance test record.  
3–13  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
Test the + User threshold  
1 Move the cursor to the field to the right of Pod 1. Type +6.00, then use the left and  
right cursor control keys to highlight V. Press the Select key.  
2
On the function generator front panel, enter +6.282 V 1 mV DC offset. Use the  
multimeter to verify the voltage.  
The activity indicators for pod 1 should show all data channels and the J-clock channel at a  
logic high.  
3 Using the Modify down arrow on the function generator, decrease offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels at a logic  
low. Record the function generator voltage in the performance test record.  
4 Using the Modify up arrow on the function generator, increase offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels at a logic  
high. Record the function generator voltage in the performance test record.  
3–14  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
Test the 0 V User threshold  
1 Move the cursor to the field to the right of Pod 1. Type 0, then press the Select key.  
2
On the function generator front panel, enter +0.102 V 1 mV DC offset. Use the  
multimeter to verify the voltage.  
The activity indicators for pod 1 should show all data channels and the J-clock channel at a  
logic high.  
3 Using the Modify down arrow on the function generator, decrease offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels at a logic  
low. Record the function generator voltage in the performance test record.  
4 Using the Modify up arrow on the function generator, increase offset voltage in  
1-mV increments until all activity indicators for pod 1 show the channels at a logic  
high. Record the function generator voltage in the performance test record.  
3–15  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the threshold accuracy  
Test the next pod  
1 Using the 17-by-2 test connector and probe tip assembly, connect the data and clock  
channels of pod 2 to the output of the function generator.  
2
Start with "Test the TTL threshold" on page 3−10, substituting pod 2 for pod 1.  
3–16  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To test the glitch capture  
Testing the glitch capture verifies the performance of the following specification:  
Minimum detectable glitch.  
This test checks the minimum detectable glitch on sixteen data channels at a time.  
Equipment Required  
Equipment  
Critical Specifications  
Recommended Model/Part  
Pulse Generator  
100 MHz 3.5 ns pulse width, < 600 ps rise time  
6 GHz bandwidth , < 58 ps rise time  
18 GHz bandwidth  
Agilent 8131A Option 020  
Agilent 54121T  
Agilent 8120-4948  
Digitizing Oscilloscope  
SMA Coax  
(Qty 3)  
Adapter (Qty 4)  
Coupler (Qty 4)  
BNC Test Connector, 6x2 (Qty 4)  
SMA(m)-BNC(f)  
BNC (m)(m)  
Agilent 1250-1200  
Agilent 1250-0216  
Set up the equipment  
1 Turn on the equipment required and the logic analyzer. Let them warm up for  
30 minutes before beginning the test if you have not already done so.  
2 Set up the pulse generator.  
Pulse Generator Setup  
Channel 1  
Channel 2  
Period  
Delay: 0 ps  
Delay : 0 ps  
22.0 ns  
Width: 3.5 ns  
Width: 3.5 ns  
High: 0.9 V  
Low: 1.7 V  
High: 0.9 V  
Low: 1.7 V  
3–17  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the glitch capture  
3 Set up the oscilloscope.  
Oscilloscope Setup  
Time Base  
Display  
Delta V  
Delta T  
Time/Div: 1.00 ns/div  
delay: 17.7000 ns  
mode: avg  
V markers on  
T markers on  
# of avg: 16  
screens: dual  
marker 1 position: Chan 1  
marker 2 position: Chan 2  
start on: Pos Edge 1  
stop on: Pos Edge 1  
Channel  
Channel 1  
Channel 2  
on  
on  
Display  
20.00  
20.00  
Probe Atten  
Volts/Div  
Offset  
400 mV  
400 mV  
1.3000 V  
1.3000 V  
Set up the logic analyzer  
1 Press the Config key. Assign all pod fields to Machine 1. To assign the pod fields,  
select the pod fields, then select Machine 1 in the pop-up menu.  
2 In the Analyzer 1 box, select the Type field. Select Timing in the pop-up menu.  
Connect the logic analyzer  
1 Using SMA cables, connect the oscilloscope to the pulse generator channel 1  
Output, channel 2 Output, and Trig Output.  
2 Using the 6-by-2 test connectors, connect the first combination of logic analyzer  
clock and data channels listed in the table to the pulse generator.  
You will repeat this test for the remaining combinations.  
3–18  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the glitch capture  
Connect the Logic Analyzer to the Pulse Generator  
Testing  
Combinations  
To Agilent 8131A  
Channel 1 Output  
To 8131A Channel  
1 Output  
To 8131A Channel  
2 Output  
To 8131A Channel  
2 Output  
1
Pod 1  
ch 0, 2, 4, 6,  
J-clock  
Pod 1  
ch 1, 3, 5, 7  
Pod 1  
ch 8, 10, 12, 14  
Pod 1  
ch 9, 11, 13, 15  
2
Pod 2  
ch 0, 2, 4, 6,  
K-clock  
Pod 2  
ch 1, 3, 5, 7  
Pod 2  
ch 8, 10, 12, 14  
Pod 2  
ch 9, 11, 13, 15  
3–19  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the glitch capture  
Test the glitch capture on the connected channels  
1 Set up the Format menu.  
a Press the Format key.  
b Select the field to the right of the pod, then select ECL in the pop-up menu. Use the  
arrow keys to access pods not shown on the screen (select the Pods field and push  
Select).  
c Select Timing Acquisition Mode, then select Glitch Half Channel 125 MHz.  
2 Turn on the channels that correspond to the channels being tested.  
The channels being tested are the channels connected to the pulse generator in "Connect the  
logic analyzer."  
a Select the pod field, then select one of the two pods in the pop-up. Move the cursor to  
the channel assignment field of the pod and press the Clear entry key until all  
channels of the pod are assigned (all asterisks). Press the Done key.  
b Turn on the clock/data channels that correspond to the clocks being tested. Turn off  
the data channels and clock/data channels that are not being tested.  
3–20  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the glitch capture  
3 Set up the Trigger menu.  
a Press the Trigger key.  
b Select Modify Trigger, then Clear Trigger, then select All in the pop-up menus.  
4 Using the Precision Edge Find in the Delta T menu of the oscilloscope, verify that  
the pulse widths of the pulse generator channels 1 and 2 are 3.450 ns, +50 ps or 100  
ps. If necessary, adjust the pulse widths of the pulse generator channels 1 and 2.  
5 Set up the Waveform menu to view all the channels.  
a Select one of the Glitch labels, then select Delete All in the pop-up menu.  
b Select All, then select continue.  
c Press the Select key, then select Insert in the pop-up menu.  
d Press the Select key, then select Sequential in the pop-up menu.  
3–21  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the glitch capture  
6 On the logic analyzer, press the Run key. The display should be similar to the figure  
below.  
7 On the pulse generator, enable Channel 1 and Channel 2 COMP (with the LED on).  
8 On the logic analyzer, press the Run key. The display should be similar to the figure  
below. Record Pass or Fail in the performance test record.  
Test the next channels  
Return to "Connect the logic analyzer" on page 3–18 and connect and test the next  
combination of data and clock channels until all pods are tested.  
To access pod 2 in the Format menu, select pod 1 field, then select pod 2 in the pop-up menu.  
3–22  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To test the single-clock, single-edge, state acquisition  
Testing the single-clock, single-edge, state acquisition verifies the performance of the  
following specifications:  
Minimum master to master clock time.  
Maximum state acquisition speed.  
Setup/Hold time for single-clock, single-edge, state acquisition.  
Minimum clock pulse width.  
This test checks the data channels using a single-edge clock at three selected  
setup/hold times.  
Equipment Required  
Equipment  
Critical Specifications  
Recommended Model/Part  
Pulse Generator  
100 MHz 3.5 ns pulse width, < 600 ps rise time  
Agilent 8131A option 020  
Agilent 54121T  
Agilent 1250-1200  
Agilent 8120-4948  
Agilent 8120-1840  
Agilent 1250-0216  
Digitizing Oscilloscope  
6 GHz bandwidth, < 58 ps rise time  
SMA(m)-BNC(f)  
18 GHz bandwidth  
BNC(m)(m) 48 in. >2 GHz bandwidth  
BNC(m)(m)  
Adapter  
SMA Coax Cable (Qty 3)  
BNC Cable  
Coupler  
BNC Test Connector,  
6x2 (Qty 4)  
Set up the equipment  
1 Turn on the equipment required and the logic analyzer. Let them warm up for  
30 minutes before beginning the test if you have not already done so.  
2 Set up the pulse generator.  
a Set up the pulse generator according to the following table.  
Pulse Generator Setup  
Channel 1  
Channel 2  
Period  
Delay: 0 ps  
Width: 3.5 ns  
High: -0.9 V  
Low: -1.7 V  
Doub: 20.0 ns  
Width: 3.5 ns  
High: -0.9 V  
Low: -1.7 V  
40 ns  
b Disable the pulse generator channel 2 COMP (with the LED off).  
3–23  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
3 Set up the oscilloscope.  
Oscilloscope Setup  
Time Base  
Display  
Delta V  
Delta T  
Time/Div: 1.00 ns/div  
avg  
V markers on  
T markers on  
# of avg: 16  
screen: dual  
marker 1 position: Chan 1  
marker 2 position: Chan 1  
start on: Pos Edge 1  
stop on: Neg Edge 1  
Channel  
Channel 1  
Channel 2  
on  
on  
Display  
20.00  
20.00  
Probe Atten  
Offset  
1.3 V  
1.3 V  
400 mV  
400 mV  
Volts/Div  
Set up the logic analyzer  
1 Set up the Configuration menu.  
a Press the Config key.  
b In the Configuration menu, assign all pods to Machine 1. To assign the pods, select  
the pod fields, then select Machine 1 in the pop-up menu.  
c Select the Type field in the Analyzer 1 box, then select State.  
3–24  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
2 Set up the Format menu.  
a Press the Format key. Select State Acquisition Mode, then select Full Channel/4K  
Memory/50MHz.  
b Select the field to the right of each pod, then select ECL in the pop-up menu.  
3 Set up the Trigger menu.  
a Press the Trigger key. Select Modify Trigger, then Clear Trigger, then select All in the  
pop-up menus.  
b Select Count Off. Press Select again, then select Time in the pop-up menu. Select  
Done to exit the menu.  
c Select the field labeled 1 under the State Sequence Levels. Select the field labeled  
"anystate," then select "no state." Select Done to exit the State Sequence Levels menu.  
d Select the field next to "a," under the label Lab1. Type "000A", then press the Select  
key.  
3–25  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
Connect the logic analyzer  
1 Using the 6-by-2 test connectors, connect the logic analyzer clock and data channels  
listed in the following table to the pulse generator. Install a BNC cable between the  
pulse generator channel 2 output and the 6x2 test connector with the logic analyzer  
clock leads.  
2 Using SMA cables, connect the oscilloscope to the pulse generator channel 1  
Output, channel 2 Output, and Trig Output.  
Connect the 1664A Logic Analyzer to the Pulse Generator  
Testing  
Combination  
Connect to  
Agilent 8131A  
Channel 1 Output  
Connect to  
Agilent 8131A  
Channel 1 Output  
Connect to  
Agilent 8131A  
Channel 2 Output  
1
Pod 1, channel 3  
Pod 2, channel 3  
Pod 1, channel 11  
Pod 2, channel 11  
J-clock  
3 Activate the data channels that are connected according to the previous table.  
a Press the Format key.  
b Select the field showing the channel assignments for one of the pods being tested,  
then press the Clear entry key. Using the arrow keys, move the selector to the data  
channels to be tested, then press the Select key. An asterisk means that a channel is  
turned on. When all the correct channels of the pod are turned on, press the Done  
key. Follow this step for the remaining pods.  
3–26  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
c Press the Trigger key. Make sure pattern term a is "A". If not, select the field next to  
"a" under the label Lab1. Type "A", then press the Select key.  
Verify the test signal  
1 Check the clock pulse width. Using the oscilloscope, verify that the clock pulse  
width is 3.50 ns, +0 ps or 100 ps.  
a Enable the pulse generator channel 1 and channel 2 outputs.  
b In the oscilloscope Timebase menu, select Delay. Using the oscilloscope knob,  
position the clock waveform so that the waveform is centered on the screen.  
c In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 2, then set  
Marker 1 at 1.3000 V. Set Marker 2 Position to Chan 2, then set Marker 2 at  
1.3000 V.  
d In the oscilloscope Delta T menu, select Start On Pos Edge 1. Select Stop on Neg  
Edge 1.  
e If the pulse width is outside the limits, adjust the pulse generator channel 2 width and  
select the oscilloscope Precision Edge Find until the pulse width is within limits.  
2 Check the clock period. Using the oscilloscope, verify that the clock period is 20 ns,  
+0 ps or 250 ps.  
a In the oscilloscope Timebase menu, select Sweep Speed 4.00 ns/div.  
b Select Delay. Using the oscilloscope knob, position the clock waveform so that a  
rising edge appears at the left of the display.  
3–27  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
c In the oscilloscope Measure menu, select Measure Chan 2, then select Period. If the  
period is more than or equal to 20.000 ns, go to step 4. If the period is less than 20.000  
ns but greater than 19.75 ns, go to step 3.  
d In the oscilloscope Timebase menu, add 10 ns to the delay.  
e In the oscilloscope Measure menu, select Period. If the period is more than or equal to  
20.000 ns, decrease the pulse generator Chan 2 Doub in 100-ps increments until one of  
the two periods measured is less than 20.000 ns but greater than 19.75 ns.  
3 Check the data pulse width. Using the oscilloscope, verify that the data pulse width  
is 3.50 ns, +0 ps or 100 ps.  
a Enable the pulse generator channel 1 and channel 2 outputs. Leave channel 2 output  
disabled.  
b In the oscilloscope Timebase menu, select Sweep Speed 1.00 ns/div.  
c Select Delay. Using the oscilloscope knob, position the data waveform so that the  
waveform is centered on the screen.  
d In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set Marker  
1 at 1.3000 V. Set the Marker 2 Position to Chan 1, then set Marker 2 at 1.3000 V.  
e In the oscilloscope Delta T menu, select Start On Pos Edge 1. Select Stop on Neg  
Edge 1.  
f Select Precision Edge Find.  
g If the pulse width is outside the limits, adjust the pulse generator channel 1 width and  
select the oscilloscope Precision Edge Find until the pulse width is within limits.  
3–28  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
Check the setup/hold combination  
1 Select the logic analyzer setup/hold time.  
a In the logic analyzer Format menu, select Master Clock.  
b Select the Setup/Hold field, then select the setup/hold combination to be tested for all  
pods. The first time through this test, use the top combination in the following table.  
Setup/Hold Combinations  
3.5/0.0 ns  
0.0/3.5 ns  
1.5/2.0 ns  
c Select Done to exit the setup/hold combinations.  
2 Disable the pulse generator channel 2 COMP (with the LED off).  
3 Using the Delay mode of the pulse generator channel 1, position the pulses  
according to the setup time of the setup/hold combination selected, +0.0 ps or 100  
ps.  
a In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set  
Marker 1 at 1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at  
1.3000 V.  
b In the oscilloscope Delta T menu, select Start on Pos Edge 1. Select Stop on Pos  
Edge 1.  
3–29  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
c Adjust the pulse generator channel 1 Delay, then select Precision Edge Find in the  
oscilloscope Delta T menu. Repeat this step until the pulses are aligned according to  
the setup time of the setup/hold combination selected, +0.0 ps or 100 ps.  
4 Select the clock to be tested.  
a In the Master Clock menu, select the clock field to be tested, then select the clock  
edge as indicated in the table. The first time through this test, use the top clock and  
edge in the following table.  
Clocks  
J↑  
K↑  
b Connect the clock to be tested to the pulse generator channel 2 output.  
c Select Done to exit the Master Clock menu.  
3–30  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
5 Note: This step is only done the first time through the test, to create a Compare file.  
For subsequent runs, go to step 6. Use the following to create a Compare file:  
a Press Run. The display should show a checkerboard pattern of alternating As and 5s.  
Verify the pattern by scrolling through the display.  
b Press the List key. In the pop up menu, use the RPG knob to move the cursor to  
Compare. Press Select.  
c In the Compare menu, move the cursor to Copy Listing to Reference, then select  
Execute in the pop-up menu and press the Select key.  
d Move the cursor to Specify Stop Measurement and press the Select key. Press Select  
again to turn on Compare. At the pop up menu, select Compare. Move the cursor to  
the Equal field and press the Select key. At the pop up menu, select Not Equal. Press  
Done.  
e Move the cursor to the Reference Listing field and select. The field should toggle to  
Difference Listing.  
6 Press the blue shift key, then press the Run key. If 2 - 4 acquisitions are obtained  
without the "Stop Condition Satisfied" message appearing, then the test passes.  
Press Stop to halt the acquisition. Record the Pass or Fail results in the  
performance test record.  
7 Test the next clock.  
a Press the Format key, then select Master Clock.  
b Turn off and disconnect the clock just tested.  
c Repeat steps 4, 6, and 7 for the next clock edge listed in the table in step 4, until all  
listed clock edges have been tested.  
8 Enable the pulse generator channel 2 COMP (with the LED on).  
9 Check the clock pulse width.  
a Enable the pulse generator channel 1 and channel 2 outputs.  
b In the oscilloscope Timebase menu, select Delay. Using the oscilloscope knob,  
position the clock waveform so that the waveform is centered on the screen.  
c In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 2, then set  
Marker 1 at 1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at  
1.3000 V.  
d In the oscilloscope Delta T menu, select Start On Neg Edge 1. Select Stop on Pos  
Edge 1.  
e If the pulse width is outside the limits, adjust the pulse generator channel 2 width and  
select the oscilloscope Precision Edge Find until the pulse width is within limits.  
3–31  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, single-edge, state acquisition  
10 Using the Delay mode of the pulse generator channel 1, position the pulses  
according to the setup/hold combination selected, +0.0 ps or 100 ps.  
a In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set  
Marker 1 at 1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at  
1.3000 V.  
b In the oscilloscope Delta T menu, select Start on Pos Edge 1. Select Stop on Neg  
Edge 1.  
c Adjust the pulse generator channel 1 Delay, then select Precision Edge Find in the  
oscilloscope Delta T menu. Repeat this step until the pulses are aligned according to  
the setup time of the setup/hold combination selected.  
11 Select the clock to be tested.  
a In the Master Clock menu, select the clock field to be tested, then select the clock  
edge as indicated in the table. The first time through this test, use the top clock and  
edge.  
Clocks  
J↓  
K↓  
b Connect the clock to be tested to the pulse generator channel 2 output.  
c Select Done to exit the Master Clock menu (see illustration).  
3–32  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
12 Press the blue shift key, then press the Run key. If 2 - 4 acquisitions are obtained  
without the "Stop Condition Satisfied" message appearing, then the test passes.  
Press Stop to halt the acquisition. Record the Pass or Fail results in the  
performance test record.  
13 Test the next clock.  
a Press the Format key, then select Master Clock.  
b Turn off and disconnect the clock just tested.  
c Repeat steps 11, 12, and 13 for the next clock edge listed in the table in step 10, until  
all listed clock edges have been tested.  
14 Test the next setup/hold combination.  
a In the logic analyzer Format menu, press Master Clock.  
b Turn off and disconnect the clock just tested.  
c Repeat steps 1 through 14 for the next setup/hold combination listed in step 1 on  
page 3–29, until all listed setup/hold combinations have been tested.  
When aligning the data and clock waveforms using the oscilloscope, align the waveforms  
according to the setup time of the setup/hold combination being tested, +0.0 ps or 100 ps.  
3–33  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To test the multiple-clock, multiple-edge, state acquisition  
Testing the multiple-clock, multiple-edge, state acquisition verifies the performance  
of the following specifications:  
Minimum master to master clock time.  
Maximum state acquisition speed.  
Setup/Hold time for multiple-clock, multiple-edge, state acquisition.  
Minimum clock pulse width.  
This test checks data using multiple clocks at three selected setup/hold times.  
Equipment Required  
Equipment  
Critical Specifications  
Recommended  
Model/Part  
Pulse Generator  
100 MHz 3.5 ns pulse width, < 600 ps rise time  
Agilent 8131A option 020  
Agilent 54121T  
Agilent 1250-1200  
Agilent 8120-4948  
Agilent 8120-1840  
Agilent 1250-0216  
Digitizing Oscilloscope  
6 GHz bandwidth, < 58 ps rise time  
SMA(m)-BNC(f)  
18 GHz bandwidth  
BNC(m)(m) 48 in. >2 GHz bandwidth  
BNC(m)(m)  
Adapter  
SMA Coax Cable (Qty 3)  
BNC Cable  
Coupler  
BNC Test Connector,  
6x2 (Qty 4)  
Set up the equipment  
1 Turn on the equipment required and the logic analyzer. Let them warm up for  
30 minutes before beginning the test if you have not already done so.  
2 Set up the pulse generator.  
a Set up the pulse generator according to the following table.  
Pulse Generator Setup  
Channel 1  
Channel 2  
Period  
Delay: 0 ps  
Doub: 20.0 ns  
Width: 3.5 ns  
40 ns  
Width: 4.5 ns  
High: 0.9 V  
Low: 1.7 V  
High: 0.9 V  
Low: 1.7 V  
b Disable the pulse generator channel 2 COMP (with the LED off).  
3–34  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
3 Set up the oscilloscope.  
Oscilloscope Setup  
Time Base  
Display  
Delta V  
Delta T  
Time/Div: 1.00 ns/div  
avg  
V markers on  
T markers on  
# of avg: 16  
screen: dual  
marker 1 position: Chan 1  
marker 2 position: Chan 1  
start on: Pos Edge 1  
stop on: Neg Edge 1  
Channel  
Channel 1  
Channel 2  
on  
on  
Display  
20.00  
20.00  
Probe Atten  
Offset  
1.3 V  
1.3 V  
400 mV  
400 mV  
Volts/Div  
Set up the logic analyzer  
1 Set up the Configuration menu.  
a Press the Config key.  
b Assign all pods to Machine 1. To assign pods, select the pod fields, then select  
Machine 1.  
c In the Analyzer 1 box, select the Type field, then select State.  
3–35  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
2 Set up the Format menu.  
a Press the Format key. Select State Acquisition Mode, then select Full Channel/4K  
Memory/50MHz.  
b Select the field to the right of each Pod field, then select ECL.  
3 Set up the Trigger menu.  
a Press the Trigger key. Select Clear Trigger, then select All.  
b Select the Count Off field, then select Time in the pop-up menu. Select Done to exit  
the menu.  
c Select the field labeled 1 under the State Sequence Levels. Select the field labeled  
"anystate", then select "no state." Select Done to exit the State Sequence Levels menu.  
d Select the field next to the pattern recognizer "a," under the label Lab1. Type "000A" ,  
then press Select.  
3–36  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
Connect the logic analyzer  
1 Using the 6-by-2 test connectors, connect the logic analyzer clock and data channels  
listed in the following table to the pulse generator. Install a BNC cable between the  
pulse generator channel 2 output and the 6x2 test connector with the logic analyzer  
clock leads.  
2 Using SMA cables, connect channel 1, channel 2, and trigger of the oscilloscope to  
the pulse generator.  
Connect the 1664A Logic Analyzer to the Pulse Generator  
Testing  
Combination  
Connect to  
Agilent 8131A  
Channel 1 Output  
Connect to  
Agilent 8131A  
Channel 1 Output  
Connect to  
Agilent 8131A  
Channel 2 Output  
1
Pod 1, channel 3  
Pod 2, channel 3  
Pod 1, channel 11  
Pod 2, channel 11  
J-clock  
K-clock  
3 Activate the data channels that are connected according to the previous table.  
a Press the Format key.  
b Select the field showing the channel assignments for one of the pods being tested.  
Press the Clear entry key. Using the arrow keys, move the selector to the data  
channels to be tested, then press the Select key. An asterisk means that a channel is  
turned on. When all the correct channels of the pod are turned on, press the Done  
key. Follow this step for the remaining pods.  
3–37  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
c Press the Trigger key. Make sure pattern term a is "A". If not, select the field next to  
"a" under the label Lab1. Type "A" then press the Select key.  
Verify the test signal  
1 Check the clock pulse width. Using the oscilloscope, verify that the clock pulse  
width is 3.50 ns, +0 ps or 100 ps.  
a Enable the pulse generator channel 1 and channel 2 outputs (with the LED off).  
b In the oscilloscope Timebase menu, select Delay. Using the oscilloscope knob,  
position the clock waveform so that the waveform is centered on the screen.  
c In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 2, then set Marker  
1 at 1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at 1.3000 V.  
d In the oscilloscope Delta T menu, select Start On Pos Edge 1. Select Stop On Neg  
Edge 1.  
e If the pulse width is outside of the limits, adjust the pulse generator channel 2 width  
and select the oscilloscope Precision Edge Find until the pulse width is within limits.  
2 Check the clock period. Using the oscilloscope verify that the clock period is 20 ns,  
+0 ps or 250 ps.  
a In the oscilloscope Timebase menu, select Sweep Speed 4.00 ns/div.  
b Select Delay. Using the oscilloscope knob, position the clock waveform so that a  
rising edge appears at the left of the display.  
3–38  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
c In the oscilloscope Measure menu, select Measure Chan 2, then select Period. If the  
period is more than or equal to 20.000 ns, go to step 4. If the period is less than 20.000  
ns but greater than 19.75 ns, go to step 3.  
d In the oscilloscope Timebase menu, add 10 ns to the Delay.  
e In the oscilloscope Measure menu, select Period. If the period is more than or equal to  
20.000 ns, decrease the pulse generator Chan 2 DOUB in 100 ps increments until one  
of the two periods measured is less than 20.000 ns but greater than 19.75 ns.  
3 Check the data pulse width. Using the oscilloscope verify that the data pulse width  
is 4.450 ns, +50 ps or 100 ps.  
a In the oscilloscope Timebase menu, select Sweep Speed 1.00 ns/div.  
b Select Delay. Using the oscilloscope knob, position the data waveform so that the  
waveform is centered in the screen.  
c In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set Marker  
1 at 1.3000 V. Set the Marker 2 Position to Chan 1, then set Marker 2 at 1.3000 V.  
d In the oscilloscope Delta T menu, select Start On Pos Edge 1. Select Stop on Neg  
Edge 1.  
e If the pulse width is outside of the limits, adjust the pulse generator channel 1 width  
and select the oscilloscope Precision Edge Find until the pulse width is within limits.  
3–39  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
Check the setup/hold with single clock edges, multiple clocks  
1 Select the logic analyzer setup/hold time.  
a In the logic analyzer Format menu, select Master Clock.  
b Select and activate any two clock edges.  
c Select the Setup/Hold field and select the setup/hold to be tested for all pods. The first  
time through this test, use the top combination in the following table.  
Setup/Hold Combinations  
4.5/0.0 ns  
0.0/4.5 ns  
2.0/2.5 ns  
d Select Done to exit the setup/hold combinations.  
2 Disable the pulse generator channel 2 COMP (with the LED off).  
3 Using the Delay mode of the pulse generator channel 1, position the pulses  
according to the setup time of the setup/hold combination selected, +0.0 ps or 100  
ps.  
a In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set  
Marker 1 at 1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at  
1.3000 V.  
b In the oscilloscope Delta T menu, select Start on Pos Edge 1. Select Stop on Pos  
Edge 1.  
3–40  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
c Adjust the pulse generator channel 1 Delay, then select Precision Edge Find in the  
oscilloscope Delta T menu. Repeat this step until the pulses are aligned according to  
the setup time of the setup/hold combination selected, +0.0 ps or 100 ps.  
4 Select the clocks to be tested.  
a
Select the clock field to be tested and then select J+ Kas the clock edges.  
b Select Done to exit the Master Clock menu.  
3–41  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
5 If you have not already created a Compare file for the previous test (single-clock,  
single-edge state acquisition, page 3-31), use the following steps to create one. For  
subsequent passes through this test, skip this step and go to step 6.  
a Press Run. The display should show a checkerboard pattern of alternating As and 5s.  
Verify the pattern by scrolling through the display.  
b Press the List key. In the pop up menu, use the RPG knob to move the cursor to  
Compare. Press Select.  
c In the Compare menu, move the cursor to Copy Listing to Reference, then select  
Execute from the pop-up menu and press the Select key.  
d Move the cursor to Specify Stop Measurement and press the Select key. Press Select  
again to turn on Compare. At the pop up menu, select Compare. Move the cursor to  
the Equal field and press the Select key. At the pop up menu, select Not Equal. Press  
Done.  
e Move the cursor to the Reference Listing field and select. The field should toggle to  
Difference Listing.  
6 Press the blue shift key, then press the Run key. If 2 - 4 acquisitions are obtained  
without the "Stop Condition Satisfied" message appearing, then the test passes.  
Press Stop to halt the acquisition. Record the Pass or Fail results in the  
performance test record.  
7 Enable the pulse generator channel 2 COMP (with the LED on).  
8 Check the clock pulse width.  
a Enable the pulse generator channel 1 and channel 2 outputs (with the LED off).  
b In the oscilloscope Timebase menu, select Delay. Using the oscilloscope knob,  
position the clock waveform so that the waveform is centered on the screen.  
c In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 2, then set  
Marker 1 at 1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at  
1.3000 V.  
d In the oscilloscope Delta T menu, select Start On Neg Edge 1. Select Stop On Pos  
Edge 1.  
e If the pulse width is outside of the limits, adjust the pulse generator channel 2 width  
and select the oscilloscope Precision Edge Find until the pulse width is within limits.  
3–42  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
9 Using the Delay mode of the pulse generator channel 1, position the pulses  
according to the setup time of the setup/hold combination selected, +0.0 ps or 100  
ps.  
a In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set  
Marker 1 at 1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at  
1.3000 V.  
b In the oscilloscope Delta T menu, select Start On Pos Edge 1. Select Stop on Neg  
Edge 1.  
c Adjust the pulse generator channel 1 Delay, then select Precision Edge Find in the  
oscilloscope Delta T menu. Repeat this step until the pulses are aligned according to  
the setup time of the setup/hold combination selected, +0.0 ps or 100 ps.  
10 Select the clocks to be tested.  
a
Select the clock field to be tested, then select J+ Kas the clock edges.  
b Select Done to exit the Master Clock menu.  
3–43  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the multiple-clock, multiple-edge, state acquisition  
11 Press the blue shift key, then press the Run key. If 2 - 4 acquisitions are obtained  
without the "Stop Condition Satisfied" message appearing, then the test passes.  
Press Stop to halt the acquisition. Record the Pass or Fail results in the  
performance test record.  
12 Test the next setup/hold combination.  
a In the logic analyzer Format menu, select Master Clock.  
b Turn off and disconnect the clocks just tested.  
c Repeat steps 1 through 12 for the next setup/hold combination listed in step 1 on  
page 3-40, until all listed setup/hold combinations have been tested.  
When aligning the data and clock waveforms using the oscilloscope, align the waveforms  
according to the setup time of the setup/hold combination being tested, +0.0 ps or 100 ps.  
hen continue through the complete test.  
3–44  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To test the single-clock, multiple-edge, state acquisition  
Testing the single-clock, multiple-edge, state acquisition verifies the performance of  
the following specifications:  
Minimum master to master clock time.  
Maximum state acquisition speed.  
Setup/Hold time for single-clock, multiple-edge, state acquisition.  
This test checks data channels using a multiple-edge single clock at three selected  
setup/hold times.  
Equipment Required  
Equipment  
Critical Specifications  
Recommended  
Model/Part  
Pulse Generator  
100 MHz 3.5 ns pulse width, < 600 ps rise time  
Agilent 8131A option 020  
Agilent 54121T  
Agilent 1250-1200  
Agilent 8120-4948  
Agilent 8120-1840  
Agilent 1250-0216  
Digitizing Oscilloscope  
6 GHz bandwidth, < 58 ps rise time  
SMA(m)-BNC(f)  
18 GHz bandwidth  
BNC(m)(m) 48 in. >2 GHz bandwidth  
BNC(m)(m)  
Adapter  
SMA Coax Cable (Qty 3)  
BNC Cable  
Coupler  
BNC Test Connector,  
6x2 (Qty 4)  
Set up the equipment  
1 Turn on the equipment required and the logic analyzer. Let them warm up for  
30 minutes before beginning the test if you have not already done so.  
2 Set up the pulse generator according to the following table.  
Pulse Generator Setup  
Channel 1  
Channel 2  
Period  
Doub: 0 ps  
Delay: 0 ps  
Dcyc: 50%  
40 ns  
Width: 4.0 ns  
High: 0.9 V  
Low: 1.7 V  
High: 0.9 V  
Low: 1.7 V  
COMP: Disabled  
(LED off)  
COMP: Disabled  
(LED off)  
3–45  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
3 Set up the oscilloscope.  
Oscilloscope Setup  
Time Base  
Display  
Delta V  
Delta T  
Time/Div: 1.00 ns/div  
avg  
V markers on  
T markers on  
# of avg: 16  
screen: dual  
marker 1 position: Chan 1  
marker 2 position: Chan 1  
start on: Neg Edge 1  
stop on: Neg Edge 2  
Channel  
Channel 1  
Channel 2  
on  
on  
Display  
20.00  
20.00  
Probe Atten  
Offset  
1.3 V  
1.3 V  
400 mV  
400 mV  
Volts/Div  
Set up the logic analyzer  
1 Set up the Configuration menu.  
a Press the Config key.  
b Assign all pods to Machine 1. To assign all pods, select the pod fields, then select  
Machine 1.  
c Select the Type field in the Analyzer 1 box, then select State.  
3–46  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
2 Set up the Format menu.  
a Press the Format key. Select State Acquisition Mode, then select Full Channel/4K  
Memory/50MHz.  
b Select the field to the right of each pod field, then select ECL.  
3 Set up the Trigger menu.  
a Press the Trigger key. Select Clear Trigger, then select All.  
b Select the Count Off field, then select Time in the pop-up menu. Select Done to exit  
the menu.  
c Select the field labeled 1 under the State Sequence Levels. Select the field labeled  
"anystate", then select "no state." Select Done to exit the State Sequence Levels menu.  
d Select the field next to the pattern recognizer "a," under the label Lab1. Type "000A" ,  
then press Select.  
3–47  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
Connect the logic analyzer  
1 Using the 6-by-2 test connectors, connect the logic analyzer clock and data channels  
listed in the following table to the pulse generator. Install a BNC cable between the  
pulse generator channel 2 output and the 6x2 test connector with the logic analyzer  
clock leads.  
2 Using SMA cables, connect channel 1, channel 2, and trigger of the oscilloscope to  
the pulse generator.  
Connect the 1664A Logic Analyzer to the Pulse Generator  
Testing  
Combination  
Connect to  
Agilent 8131A  
Channel 1 Output  
Connect to  
Agilent 8131A  
Channel 1 Output  
Connect to  
Agilent 8131A  
Channel 2 Output  
1
Pod 1, channel 3  
Pod 2, channel 3  
Pod 1, channel 11  
Pod 2, channel 11  
J-clock  
3 Activate the data channels that are connected according to the previous tables.  
a Press the Format key.  
b Select the field showing the channel assignments for one of the pods being tested.  
Press the Clear entry key. Using the arrow keys, move the selector to the data  
channels to be tested, then press the Select key. An asterisk means that a channel is  
turned on. When all the correct channels of the pod are turned on, press the Done  
key. Follow this step for the remaining pods.  
3–48  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
c Press the Trigger key. Make sure pattern term a is "A". If not, select the field next to  
"a" under the label Lab1. Type "A" then press the Select key.  
Verify the test signal  
1 Check the clock period. Using the oscilloscope, verify that the clock period is 20 ns,  
+0 ps or 250 ps.  
a In the oscilloscope Timebase menu, select Sweep Speed 4.00 ns/div.  
b Select Delay. Using the oscilloscope knob, position the clock waveform (Channel 2)  
so that a rising edge appears at the left of the display.  
c In the oscilloscope Measure menu, select Measure Chan 2, then select +Width. If the  
positive-going pulse width is more than 20.000 ns, go to step d. If the pulse width is  
less than or equal to 20.000 ns, go to step 2.  
d In the oscilloscope Measure menu, select -Width. If the negative-going pulse width is  
less than or equal to 20.000 ns but greater than 19.75 ns, go to step 2.  
e Decrease the pulse generator Period in 100 ps increments until the oscilloscope  
Measure +Width or Measure -Width reads less than or equal to 20.000 ns, but greater  
than 19.75 ns.  
3–49  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
2 Check the data pulse width. Using the oscilloscope, verify that the data pulse width  
is 4.000 ns, +0 ps or 100 ps.  
a In the oscilloscope Timebase menu, select Sweep Speed 1.00 ns/div.  
b Select Delay. Using the oscilloscope knob, position the data waveform (Channel 1) so  
that the waveform is centered on the screen.  
c In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set Marker  
1 at 1.3000 V. Set the Marker 2 Position to Chan 1, then set Marker 2 at 1.3000 V.  
d In the oscilloscope Delta T menu, select Start On Pos Edge 1. Select Stop on Neg  
Edge 1. Select Precision Edge Find.  
e If the pulse width is outside of the limits, adjust the pulse generator channel 1 width  
and select the oscilloscope Precision Edge Find until the pulse width is within limits.  
3–50  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
Check the setup/hold combination  
1 Select the logic analyzer setup/hold time.  
a In the logic analyzer Format menu, select Master Clock.  
N O T E  
The first time through this test, assign the clocks according to the first testing combination in  
step 3 of these procedures.  
b In the Master Clock menu, select Setup/Hold.  
c In the Setup/Hold menu, select the setup/hold field, then select for all pods the  
setup/hold combination to be tested. The first time through this test, use the top  
combination in the following table.  
Setup/Hold Combinations  
4.0/0.0 ns  
0.0/4.0 ns  
2.0/2.0 ns  
d Select Done to exit the setup/hold combinations.  
2 Using the Delay mode of the pulse generator Channel 2, position the pulses  
according to the setup time of the setup/hold combination selected, +0.0 ps or  
-100.0 ps.  
a In the oscilloscope Delta V menu, set the Marker 1 Position to Chan 1, then set Marker  
1 at -1.3000 V. Set the Marker 2 Position to Chan 2, then set Marker 2 at -1.3000 V.  
b In the oscilloscope Delta T menu, select Start on Pos Edge 1. Select Stop on Pos  
Edge 1. Select Precision Edge Find.  
3–51  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
c Adjust the pulse generator channel 2 Delay, then select Precision Edge Find in the  
oscilloscope Delta T menu. Repeat this step until the pulses are aligned according to  
the setup time of the setup/hold combination selected, +0.0 ps or 100 ps.  
N O T E  
If the rising clock edge does not appear on the oscilloscope display, then add 20.0 ns to the  
oscilloscope Timebase Delay.  
3 Select the clock to be tested.  
a In the Master Clock menu, select the clock field to be tested, then select the clock  
edge as indicated in the table. The first time through this test, use the top clock and  
edge in the following table.  
Clocks  
J  
K↕  
b Select Done to exit the Master Clock menu.  
4 If a Compare file was not created during the single-clock, single-edge test, then the  
first time through this test, create a Compare file.  
a Press Run. The display should show a checkerboard pattern of alternating A and 5.  
Scroll through the display to verify.  
b Press the List key. In the pop up menu, use the RPG knob to move the cursor to  
Compare. Press Select.  
c In the Compare menu, move the cursor to Copy Listing to Reference, then press the  
Select key.  
d Move the cursor to Specify Stop Measurement and press the Select key. Press Select  
again to turn on Compare. At the pop up menu, select Compare. Move the cursor to  
the Equal field and press the Select key. At the pop up menu, select Not Equal. Press  
Done.  
e Move the cursor to the Reference Listing field and select. The field should toggle to  
Difference Listing.  
5 Press the blue shift key, then press the Run key. If 2 - 4 acquisitions are obtained  
without the "Stop Condition Satisfied" message appearing, then the test passes.  
Press Stop to halt the acquisition. Record the Pass or Fail results in the  
performance test record.  
3–52  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the single-clock, multiple-edge, state acquisition  
6 Test the next clock.  
a Press the Format key, then select Master Clock.  
b Turn off and disconnect the clock just tested.  
c Repeat steps 3 and 5 for the next clock listed in the table in step 3, until all listed clock  
edges have been tested.  
7 Test the next setup/hold combination. a Press the Format key, then select Master  
Clock and turn off the clock just tested. b Repeat steps 1 through 7 for the next  
setup/hold combination listed in step 1, until all listed setup/hold combinations have  
been tested.  
When aligning the data and clock waveforms using the oscilloscope, align the waveforms  
according to the setup time of the setup/hold combination being tested, +0.0 ps or -100.0 ps.  
3–53  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To test the time interval accuracy  
Testing the time interval accuracy does not check a specification, but does check the  
following:  
125 MHz oscillator  
This test verifies that the 125 MHz timing acquisition synchronizing oscillator is  
operating within limits.  
Equipment Required  
Equipment  
Critical Specifications  
Recommended  
Model/Part  
Pulse Generator  
100 MHz 3.5 ns pulse width, < 600 ps rise time  
Accuracy (5)(106) × frequency  
Agilent 8131A Option 020  
Agilent 3325B Option 002  
Function Generator  
SMA Cable  
Adapter  
Agilent 8120-4948  
Agilent 1250-2015  
BNC(m)-SMA(f)  
BNC Test Connector,  
6x2  
Set up the equipment  
1 Turn on the equipment required and the logic analyzer. Let them warm up for  
30 minutes if you have not already done so.  
2 Set up the pulse generator according to the following table.  
Pulse Generator Setup  
Channel 1  
Period  
Mode  
EXT TRIG  
Delay: 0 ps  
5 us  
TRIG  
Slope: Positive  
THRE: 1.0 V  
Width: 2.5 us  
High: 0.9 V  
Low: 1.7 V  
COMP: Disabled  
(LED off)  
3–54  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the time interval accuracy  
3 Set up the function generator according to the following table.  
Function Generator Setup  
Freq: 200 000 . 0 Hz  
Amptd: 3.000 V  
Phase: 0.0 deg  
DC Offset: 0.0 V  
Main Function: Square wave  
High Voltage: Disabled (LED Off)  
Set up the logic analyzer  
1 Set up the Configuration menu.  
a Press the Config key.  
b In the Configuration menu, assign Pod 1 to Machine 1. To assign Pod 1, select the  
Pod 1 field, then select Machine 1.  
c In the Analyzer 1 box, select the Type field, then select Timing.  
3–55  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the time interval accuracy  
2 Set up the Format menu.  
a Press the Format key. Select Timing Acquisition Mode, then select Transitional Full  
Channel 125 MHz.  
b Select the field to the right of the Pod 1 field, then select ECL.  
c Select the field showing the channel assignments for Pod 1. Deactivate all channels by  
pressing the Clear entry key. Using the arrow keys, move the selector to Channel 0.  
Press the Select key to put an asterisk in the channel position, activating the channel,  
then press the Done key.  
3 Press the Trigger key. Select Modify Trigger, then Clear Trigger and All from the  
pop-up menus.  
3–56  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the time interval accuracy  
4 Set up the Waveform menu.  
a Press the Waveform key.  
b
Move the cursor to the sec/Div field, then use the RPG knob to dial in 2.00 µs.  
c Select the Markers Off field, then select Pattern.  
d Select the Specify Patterns field. Select X entering 1 and O entering 1.  
e Select Done to exit the Specify Patterns menu.  
f Move the cursor to the X-pat field. Type 1, then press Done.  
g Move the cursor to the O-pat field. Type 20, then press Done.  
h Select the Markers Patterns field, then select Statistics. Select Reset Statistics to  
initialize the statistics fields.  
Connect the logic analyzer  
1 Using a 6-by-2 test connector, connect channel 0 of Pod 1 to the pulse generator  
channel 1 output.  
2 Using the SMA cable and the BNC adapter, connect the External Input of the pulse  
generator to the Main Signal of the function generator.  
3–57  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Testing Performance  
To test the time interval accuracy  
Acquire the data  
1 Enable the pulse generator channel 1 output (with the LED off).  
2 Press the blue key, then press the Run key to select Run-Repetitive. Allow the logic  
analyzer to acquire data for at least 100 valid runs as indicated in the pattern  
statistics field.  
3 When the logic analyzer has acquired at least 100 valid runs, touch Stop. The  
Min X-O field in the logic analyzer Pattern Statistics menu should read  
94.99–95.00 µs. The Max X-O field should read 95.00 95.01 µs. The Avg X-O field  
should read 94.99–95.01 µs. Record the results in the performance test record.  
3–58  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Performance Test Record  
Performance Test Record  
1664A Logic Analyzer_______  
Serial No.______________________  
Work Order No.___________________  
Date___________________  
Recommended Test Interval - 2 Year/4000 hours  
Recommended next testing___________________  
Temperature___________________  
Test  
Settings  
Results  
Pass/Fail  
________  
Self-Tests  
Threshold  
Accuracy  
(100 mV + 3% of  
threshold setting)  
Limits  
Measured  
Pod 1  
TTL VL  
+1.355 V  
+1.645 V  
-1.439 V  
-1.161 V  
-6.280 V  
-5.720 V  
+5.720 V  
+6.280 V  
-100 mV  
+100 mV  
________  
________  
________  
________  
________  
________  
________  
________  
________  
________  
TTL, 145 mV  
ECL, 139 mV  
-User, 280 mV  
+User, 280 mV  
TTL VH  
ECL VL  
ECL VH  
-User VL  
- User VH  
+ User VL  
+ User VH  
0 V User VL  
0 V User VH  
0 V, 100 mV  
Pod 2  
TTL VL  
+1.355 V  
+1.645 V  
-1.439 V  
-1.161 V  
-6.280 V  
-5.720 V  
+5.720 V  
+6.280 V  
-100 mV  
+100 mV  
________  
________  
________  
________  
________  
________  
________  
________  
________  
________  
TTL, 145 mV  
TTL VH  
ECL VL  
ECL VH  
ECL, 139 mV  
-User, 280 mV  
+User, 280 mV  
0 V, 100 mV  
-User VL  
- User VH  
+ User VL  
+ User VH  
0 V User VL  
0 V User VH  
Minimum Detectable  
Glitch 3.5 ns  
Pass/Fail  
Glitch Capture  
Pod 1  
Pod 2  
________  
________  
3–59  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Performance Test Record (continued)  
Test  
Settings  
Results  
Pass/Fail  
Pass/Fail  
Single-Clock,  
Single-Edge  
Acquisition  
Setup/Hold Time  
Setup/Hold Time  
Setup/Hold Time  
3.5/0.0 ns  
0.0/3.5 ns  
1.5/2.5 ns  
________  
________  
________  
________  
J↑  
K↑  
J↓  
K↓  
________  
________  
________  
________  
J↑  
K↑  
J↓  
K↓  
________  
________  
________  
________  
J↑  
K↑  
J↓  
K↓  
Multiple-Clock,  
Multiple-Edge  
Acquisition  
Pass/Fail  
Pass/Fail  
Setup/Hold Time  
Setup/Hold Time  
Setup/Hold Time  
4.5/0.0 ns  
0.0/4.5 ns  
2.0/2.5 ns  
________  
________  
J+ K↑  
J+ K↑  
J+ K↑  
JÅ + K↓  
JÅ + K↓  
JÅ + K↓  
________  
________  
________  
________  
Single-Clock,  
Multiple-Edge  
Acquisition  
Pass/Fail  
Setup/Hold Time  
4.0/0.0 ns  
_______  
_______  
J↕  
K↕  
Setup/Hold Time  
Setup/Hold Time  
0.0/4.0 ns  
2.0/2.0 ns  
_______  
_______  
J↕  
K↕  
_______  
_______  
J↕  
K↕  
Measured  
Time Interval  
Accuracy  
min X-0  
max X-0  
avg X-0  
_________  
_________  
_________  
94.99-95.00 µs  
95.00-95.01 µs  
94.99-95.01 µs  
3–60  
Download from Www.Somanuals.com. All Manuals Search And Download.  
4
Logic analyzer calibration 4-2  
To adjust the CRT monitor alignment 4-3  
To adjust the CRT intensity 4-5  
Calibrating and Adjusting  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Calibrating and Adjusting  
This chapter gives you instructions for calibrating and adjusting the logic analyzer.  
Adjustments to the logic analyzer include adjusting the CRT monitor assembly.  
To periodically verify the performance of the analyzer, refer to "Testing Performance"  
in chapter 3.  
Logic analyzer calibration  
The logic analyzer circuitry of the 1664A Logic Analyzer does not require an  
operational accuracy calibration. To test the logic analyzer circuitry against  
specifications (full calibration), refer to chapter 3, Testing Performance.  
Set up the equipment  
Turn on the logic analyzer. Let it warm up for 30 minutes if you have not already done so.  
4–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To adjust the CRT monitor alignment  
Do not touch the CRT monitor sweep board. High voltages exist on the sweep board that can  
cause personal injury.  
W AR N I N G  
Equipment Required  
Equipment  
Critical Specification  
Recommended  
Model/Part  
Alignment Tool  
1
8710-1300  
1 Turn off the logic analyzer, then disconnect the power cord. Remove the cover.  
Refer to chapter 6, "Replacing Assemblies," for instructions to remove the cover.  
2 Connect the power cord, insert the operating system disk into the disk drive, then  
turn on the logic analyzer.  
3 Insert the disk containing the functional performance verification tests (normally  
the same disk) into the disk drive, then load the functional performance verification  
operating system into the logic analyzer (refer to Chapter 3, To Perform Self Tests).  
4–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Calibrating and Adjusting  
To adjust the CRT monitor alignment  
4 Enter the Sys PV tests, then enter the Display Test.  
A grid pattern should appear.  
5 If the display is tilted (rotated), adjust the CRT yoke by rotating it to straighten the  
display.  
Yoke  
6 If the grid pattern is not centered horizontally, adjust the H-Hold.  
7 If you need to adjust the intensity, go to the next page.  
If you are finished with the adjustments, turn off the instrument, then remove the  
power cord. Install the cover on the instrument.  
4–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
To adjust the CRT intensity  
Do not touch the CRT monitor sweep board. High voltages exist on the sweep board that can  
cause personal injury.  
W AR N I N G  
Equipment Required  
Equipment  
Critical Specification  
Recommended  
Model/Part  
Alignment Tool  
1
8710-1300  
Light Power Meter  
United Detector 351  
1 Turn off the logic analyzer, then disconnect the power cord. Remove the cover.  
Refer to chapter 6, "Replacing Assemblies," for instructions to remove the cover.  
2 Connect the power cord, insert the operating system disk, then turn on the logic  
analyzer.  
3 Access the Display Test.  
If you just finished adjusting the CRT monitor alignment, go to step 4.  
To Access the Display Test, perform the following steps.  
a Insert the disk containing the functional performance verification tests (normally the  
same disk) into the disk drive, then load the functional performance verification  
operating system into the logic analyzer (refer to Chapter 3, To Perform The Self  
Tests).  
b Enter the Sys PV tests and enter the Display Test. A grid pattern should appear.  
4 Press the front panel Select key.  
The display should show a full bright test screen.  
5 Turn the rear panel intensity adjustment to full bright.  
6 Place the light power meter against the display at center screen.  
4–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Calibrating and Adjusting  
To adjust the CRT intensity  
Do not touch the CRT monitor sweep board. High voltages exist on the sweep board that can  
cause personal injury.  
W AR N I N G  
2
7 The light power meter should read 137-154 cd/m . If the measurement is out of this  
range, use the adjustment tool to adjust the Contrast potentiometer on the monitor  
driver board.  
8 Press the front panel Select key.  
The display should show a half bright test screen.  
9 Place the light power meter against the display at center screen. The light power  
2
meter should read 5-27 cd/m .  
If the reading is not correct, try adjusting the contrast in step 7 closer to the limit.  
10 Press the front panel Select key.  
The logic analyzer should exit the Display Test.  
11 Place the light power meter against the display at center screen. Adjust the rear  
2
panel intensity adjustment until the light power meter reads 45-55 cd/m .  
12 Exit the functional performance verification tests.  
13 Turn off the instrument, then remove the power cord. Install the cover on the  
instrument.  
4–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
5
To use the flowcharts 5-2  
To check the power-up tests 5-15  
To run the self-tests 5-16  
To test the power supply voltages 5-21  
To test the CRT monitor signals 5-23  
To test the keyboard signals 5-24  
To test the disk drive voltages 5-25  
To perform the BNC test 5-27  
To test the logic analyzer probe cables 5-28  
To test the auxiliary power 5-32  
Troubleshooting  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
This chapter helps you troubleshoot the logic analyzer to find defective assemblies.  
The troubleshooting consists of flowcharts, self-test instructions, and tests. This  
information is not intended for component-level repair.  
If you suspect a problem, start at the top of the first flowchart. During the  
troubleshooting instructions, the flowcharts will direct you to perform other tests.  
The service strategy for this instrument is the replacement of defective assemblies.  
This instrument can be returned to Agilent Technologies for all service work,  
including troubleshooting. Contact your nearest Agilent Technologies Sales Office for  
more details.  
Electrostatic discharge can damage electronic components. Use grounded wriststraps and  
mats when you perform any service to this instrument or to the cards in it.  
C AU T I O N  
To use the flowcharts  
Flowcharts are the primary tool used to isolate defective assemblies. The flowcharts refer to  
other tests to help isolate the trouble. The circled letters on the charts indicate connections  
with the other flowcharts. Start your troubleshooting at the top of the first flowchart.  
5–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 1  
5–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 2  
5–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 3  
5–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 4  
5–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 5  
5–7  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 6  
5–8  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 7  
5–9  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 8  
5–10  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 9  
5–11  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 10  
5–12  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 11  
5–13  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To use the flowcharts  
Troubleshooting Flowchart 12  
5–14  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To check the power-up tests  
To check the power-up tests  
The logic analyzer automatically performs power-up tests when you apply power to the  
instrument (during the boot-up sequence). The revision number of the operating system  
shows in the upper-right corner of the screen during these power-up tests. As each test  
completes, either "passed" or "failed" prints on the screen in front of the name of each test.  
1 Disconnect all inputs, then insert the operating system disk into the disk drive.  
2 Let the instrument warm up for a few minutes, then cycle power by turning off then  
turning on the power switch.  
If the instrument is not warmed up, the power-up test screen will complete before you can  
view the screen.  
3 As the tests complete, check if they pass or fail.  
Performing Power-Up Self-Tests  
passed  
passed  
passed  
passed  
passed  
passed  
No Disk  
ROM text  
RAM test  
Interrupt test  
Display test  
HIL Controller test  
HIL Devices test  
Front Disk test  
5–15  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To run the self-tests  
To run the self-tests  
Self-tests identify the correct operation of major functional areas of the instrument. You can  
run all self-tests without accessing the interior of the instrument. If a self-test fails, the  
troubleshooting flowcharts instruct you to change a part of the instrument.  
1 If you just did the power-up self-tests, go to step 2.  
If you did not just do the power-up self-tests, disconnect all inputs, insert the  
operating system disk, then turn on the power switch. Wait until the power-up tests  
are complete.  
2 Press the System key, then select the field next to System. Select Test in the pop-up  
menu and then press the Select key.  
3 Select the box labeled Load Test System then press the select key. Insert the disk  
containing the performance verification tests (self-tests) into the disk drive  
(normally the same as the boot disk).  
4 Select the box labeled Continue and press the Select key. After the test files have  
been loaded, and Analy menu is displayed.  
You can run all the analyzer tests at one time by selecting All Analyzer Tests. To see more  
details about each test, you can run each test individually.  
5
Select the Chip 5 Tests menu and press the Select key.  
5–16  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To run the self-tests  
6 Select Run, then select Single. The test runs one time, then the screen shows the  
results. When the test is finished, select Done.  
To run a test continuously, select Repetitive. Select Stop to halt a Run Repetitive.  
7 Select Board Tests, then select Run. When the Board Tests are finished, select Done.  
8 Select Data Input Inspection. All lines should show activity. Select Done to exit the  
Data Input Inspection.  
9 Select Analy PV, then select Sys PV PV in the pop up menu and press the Select key.  
5–17  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To run the self-tests  
10 Select the Printer/Controller field next to Sys PV. Select System Test and press the  
Select key to access the system tests.  
You can run all tests at one time by running All System Tests. To see more details about each  
test, you can run each test individually. This example shows how to run an individual test.  
11 Select ROM Test. The ROM Test screen is displayed.  
12 Select Run, then select Single.  
To run a test continuously, select Repetitive. Select Stop to halt a repetitive test.  
5–18  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To run the self-tests  
For a Single run, the test runs one time, and the screen shows the results.  
13 To exit the ROM Test, select Done. Note that the status changes to Passed or Failed.  
14 Install a formatted disk that is not write protected into the disk drive. If option 020  
is installed, connect an RS-232C loopback connector onto the RS-232C port. Run the  
remaining System Tests in the same manner.  
If option 020 is not installed in the 1664A, the RS-232C test will return a FAILED status.  
15 Select the Front Panel Test.  
A screen duplicating the front-panel appears on the screen.  
a Press each key on the front panel. The corresponding key on the screen will change  
from a light to a dark color.  
b Test the knob by turning it in both directions.  
c Note any failures, then press the Done key a second time to exit the Front Panel Test.  
The test screen shows the Front Panel Test status changed to Tested.  
16 Select the Display Test.  
A white grid pattern is displayed. These display screens can be used to adjust the display.  
a Select Continue and the screen changes to full bright.  
b Select Continue and the screen changes to half bright.  
c Select Continue and the test screen shows the Display Test status changed to Tested.  
5–19  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To run the self-tests  
17 To exit the tests, press the System key, then select Exit Test in the pop-up menu  
and press the select key. Reinstall the disk containing the operating system, then  
select Exit Test System and press the select key.  
If you are performing the self-tests as part of the troubleshooting flowchart, return to the  
flowchart.  
5–20  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the power supply voltages  
To test the power supply voltages  
To check the voltages, the power supply must be loaded by either the acquisition board or  
with an added resistor.  
Refer to chapter 6, "Replacing Assemblies," for instructions to remove or replace covers and  
assemblies.  
Hazard voltages exist on the power supply, the CRT, and the CRT driver board. This  
procedure is to be performed by service-trained personnel aware of the hazards involved,  
such as fire and electrical shock.  
W AR N I N G  
Loaded by the acquisition board  
1 Turn off the instrument, then remove the power cable. Remove the cover of the  
instrument.  
2 Connect the power plug, then turn on the instrument.  
3 Check for the +5 V, as indicated by the figure below.  
Loaded by the added resistor  
1 Turn off the instrument, then remove the power cable. Remove the cover of the  
instrument and the disk drive assembly.  
2 Remove the power supply far enough to disconnect the power supply cable from the  
acquisition board. Bring the end of the cable up and out of the instrument.  
Use the disconnected cable to load the supply and to make measurements.  
3
Load the +5.00 V supply with a 2 , 25 watt resistor.  
a With a jumper wire, connect one end of the resistor to one of the 5.00 V pins (pins 1  
through 4) on the supply cable.  
b With another jumper wire, connect the other end of the resistor to one of the ground  
pins (pins 5 through 7) on the supply cable.  
4 Connect the power plug, then turn on the instrument.  
5 Check for the +5 V as indicated by the figure below.  
5–21  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the power supply voltages  
6 Check for the voltages on the power supply cable using the values in the following  
table.  
Signals on the Power Supply Cable  
Pin  
Signal  
Pin  
Signal  
1
+5.00 V  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
5.20 V  
2
+5.00 V  
Ground  
3
+5.00 V  
+12 V  
4
+5.00 V  
Ground  
5
Ground (Digital)  
Ground (Digital)  
Ground (Digital)  
Ground (Display)  
+3.50 V  
12 V  
6
Ground  
7
+12 V (Display)  
5.20 V  
8
9
+15 V (Fan)  
Ground (Fan)  
10  
Ground  
5–22  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the CRT monitor signals  
To test the CRT monitor signals  
Refer to chapter 6, "Replacing Assemblies," for instructions to remove or replace covers and  
assemblies.  
Hazard voltages exist on the power supply, the CRT, and the CRT driver board. This  
procedure is to be performed by service-trained personnel aware of the hazards involved,  
such as fire and electrical shock.  
W AR N I N G  
1 Remove the cover of the instrument.  
2 Check the CRT monitor input cable for the signals and the power supplies listed in  
the table below. The cable is the wide ribbon cable connecting the monitor to the  
acquisition board.  
CRT Monitor Cable Signals  
Pin  
Signal  
Pin  
Signal  
1
NC  
2
+12 V  
Ground  
Ground  
Ground  
HSYNC  
+12 V  
3
Ground  
+12 V  
4
5
6
7
+12 V  
8
9
+12 V  
10  
12  
14  
16  
18  
20  
11  
13  
15  
17  
19  
VSYNC  
Ground  
Ground  
Ground  
Ground  
Ground  
Video  
NC  
NC  
5–23  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the keyboard signals  
To test the keyboard signals  
Refer to chapter 6, "Replacing Assemblies," for instructions to remove covers and assemblies.  
Hazard voltages exist on the power supply, the CRT, and the CRT driver board. This  
procedure is to be performed by service-trained personnel aware of the hazards involved,  
such as fire and electrical shock.  
W AR N I N G  
1 Turn off the instrument and remove the power cable.  
2 Without disconnecting the keyboard cable, follow the keyboard removal procedure  
to loosen the keyboard. Leave the keyboard in place in front of the instrument.  
3 Reconnect the power cable, install the operating system disk, then turn on the  
instrument.  
4 Run the Front Panel Test, pressing all of the keys.  
5 If a random key is not operating, then go to the next step.  
If a group of keys do not work, then check the keyboard voltages and signals.  
Keyboard Connector Signals  
Pin  
Signal  
Pin  
Signal  
1
Keyboard Return  
13  
14  
15  
16  
17  
18  
19  
20  
21  
22  
23  
24  
Keyboard Scan  
2
"
"
3
"
"
4
"
"
5
"
"
6
"
"
7
"
LED  
8
"
+5 V  
Ground  
Knob  
Ground  
Knob  
9
Keyboard Scan  
10  
11  
12  
"
"
"
6 Allow the keyboard assembly to fall forward from the front panel. Separate the  
elastomeric keypad and keyboard panel from the PC board.  
7 Using a paper clip or screwdriver, short the PC board trace of the non-operating key  
and look for an appropriate response on the display.  
8 If the display responds as if the key were pressed, replace the elastomeric keypad.  
If the display does not respond as if the key were pressed, replace the keyboard.  
9 Check the RPG connector.  
The RPG connector has a TTL pulse on pins 22 and 24 when the knob is being turned. Pin 20  
of the connector is +5 V.  
5–24  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the disk drive voltages  
To test the disk drive voltages  
Refer to chapter 6, "Replacing Assemblies," for instructions to remove or replace covers and  
assemblies.  
This procedure is to be performed by service-trained personnel aware of the hazards  
involved, such as fire and electrical shock.  
W AR N I N G  
Equipment Required  
Equipment  
Critical Specification  
Recommended  
Model/Part  
Digitizing Oscilloscope  
> 100 MHz Bandwidth  
Agilent 54600A  
1 Turn off the instrument, then remove the power cable. Remove the instrument  
cover and the disk drive.  
2 Reconnect the disk drive cable to the rear of the disk drive. Turn the disk drive over  
so that the solder connections of the cable socket are accessible.  
3 Connect the power cable, insert the operating system disk, then turn on the  
instrument.  
4 Insert the disk that contains the functional performance verification software and  
enter the test operating system.  
5 In the Sys PV menu select the Disk test. Insert a disk that has enough available  
bytes to run the test in the disk drive, then select Run-Repetitive.  
5–25  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the disk drive voltages  
6 Check for the following voltages and signals using an oscilloscope.  
Disk Drive Voltages  
Pin  
Signal Description  
Pin  
Signal Description  
1
NC  
2
Disk Change  
High Density  
NC  
3
NC  
4
5
NC  
6
7
+5 V  
8
Index  
9
+5 V  
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
Drive Select  
NC  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
+5 V  
Ground  
Ground  
Ground  
Ground  
Ground  
Ground  
Ground  
Ground  
Ground  
Ground  
Ground  
NC  
Motor On  
Direction  
Step  
Write Data  
Write Gate  
Track 00  
Write Protect  
Read Data  
Side Select  
Ready  
7 Select Stop, and turn off the logic analyzer. Remove the power cable.  
8 Disconnect the disk drive cable and re-install the disk drive in the logic analyzer.  
9 Reconnect the disk drive cable and install the cover on the logic analyzer.  
5–26  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To perform the BNC test  
To perform the BNC test  
Equipment Required  
Equipment  
Critical Specification  
100 MHz Bandwidth  
Recommended  
Model/Part  
Digitizing Oscilloscope  
BNC Shorting Cap  
BNC Cable  
Agilent 54600A  
1250-0074  
Agilent 10503A  
1251-2277  
BNC-Banana Adapter  
1 Press the Config key.  
2 Assign pods 1 and 2 to Machine 1.  
To assign the pod field, select the pods 1 and 2 field, then select Machine 1 in the po p-up  
menu.  
3 In the Analyzer 1 box, select the Type field. Select Timing in the pop-up menu.  
4 Set up the trigger menu.  
a Press the Trig key. Select Clear Trigger All.  
b Select Arming Control. In the Arming Control pop-up menu, select the field labeled  
Run, then select Port In. Press the Done key.  
5 Attach a BNC shorting cap to the External Trigger Input on the rear panel of the  
logic analyzer.  
6 Using a BNC cable, connect the External Trigger output to the oscilloscope  
channel 1 input. Set the oscilloscope to Trigger On and measure TTL voltage levels.  
7 Press the RUN front panel key.  
The warning "MACHINE 1 Waiting on level 1" will appear.  
8 Remove the shorting cap from the rear panel External Trigger input BNC.  
9 The warning will go away and the oscilloscope will display a positive-going TTL  
pulse.  
5–27  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the logic analyzer probe cables  
To test the logic analyzer probe cables  
This test allows you to functionally verify the probe cable and probe tip assembly of any of the  
logic analyzer pods. Only one probe cable can be tested at a time. Repeat this test for each  
probe cable to be tested.  
Equipment Required  
Equipment  
Critical Specification  
Recommended  
Model/Part  
Pulse Generator  
100 MHz, 3.5 ns pulse width,  
< 600 ps rise time  
Agilent 8131A Option 020  
Adapter (Qty 4)  
SMA (m) - BNC (f)  
BNC (m)(m)  
Agilent 1250-1200  
Agilent 1250-0216  
Coupler (Qty 4)  
6x2 Test Connectors (Qty 4)  
1 Turn on the equipment required. Insert the operating system disk and turn on the  
logic analyzer.  
2 Set up the pulse generator.  
a Set up the pulse generator according to the following table.  
Pulse Generator Setup  
Channel 1  
Channel 2  
Period  
Delay: 0 ps  
Dty: 50%  
Delay: 0 ps  
Dty: 50%  
100 ns  
High: 3.00 V  
Low: 0.00 V  
High: 3.00 V  
Low: 0.00 V  
b Enable the pulse generator channel 1 and channel 2 outputs (with the LEDs off).  
3 Set up the logic analyzer Configuration menu.  
a Press the Config key.  
b In the Analyzer 1 box, select the field to the right of Type, then select State.  
5–28  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the logic analyzer probe cables  
4 Set up the Format menu.  
a Press the Format key.  
b Move the cursor to the field showing the channel assignments for the pod under test.  
Press the Clear Entry key until the pod channels are all assigned (all asterisks (*)).  
Press the Done key.  
c Select Master Clock, then select a double edge for the clock of the pod under test.  
Turn off the other clocks.  
d In the Master Clock menu, select Setup/Hold, then select 4.0/0.0 ns for the pod being  
tested. Select Done. Select Done again to exit the Master Clock menu.  
5–29  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the logic analyzer probe cables  
e Select the field to the right of the pod being tested, then select TTL.  
5 Set up the Trigger menu.  
a Press the Trigger key.  
b Select Clear Trigger, then select All.  
6 Set up the Listing menu.  
a Press the List key.  
b Select the field to the right of Base, then select Binary.  
5–30  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the logic analyzer probe cables  
7 Using four 6-by-2 test connectors, four BNC Couplers, and four SMA (m) - BNC (f)  
Adapters, connect the logic analyzer to the pulse generator channel outputs. To  
make the test connectors, see chapter 3, "Testing Performance."  
a Connect the even-numbered channels of the lower byte of the pod under test to the  
pulse generator channel 1 Output and J-clock.  
b Connect the odd-numbered channels of the lower byte of the pod under test to the  
pulse generator channel 1 Output.  
c Connect the even-numbered channels of the upper byte of the pod under test and the  
clock channel to the pulse generator channel 2 Output.  
d Connect the odd-numbered channels of the upper byte of the pod under test to the  
pulse generator channel 2 Output.  
8 On the logic analyzer, press Run. The display should look similar to the figure below.  
9 If the display looks like the figure, then the cable passed the test.  
If the display does not look similar to the figure, then there is a possible problem  
with the cable or probe tip assembly. Causes for cable test failures include the  
following:  
open channel.  
channel shorted to a neighboring channel.  
channel shorted to either ground or a supply voltage.  
Return to the troubleshooting flowchart.  
5–31  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Troubleshooting  
To test the auxiliary power  
To test the auxiliary power  
The +5 V auxiliary power is protected by a current overload protection device. If the current  
on pins 1 and 39 exceed 0.33 amps, the circuit will open. When the short is removed, the  
circuit will reset in approximately 1 minute. There should be +5 V after the 1 minute reset  
time.  
Equipment Required  
Equipment  
Critical Specifications  
Recommended  
Model/Part  
Digital Multimeter  
0.1 mV resolution, better than Agilent 3478A  
0.005% accuracy  
Using the multimeter, verify the +5 V on pins 1 and 39 of the probe cables.  
5–32  
Download from Www.Somanuals.com. All Manuals Search And Download.  
6
To remove and replace the  
Handle 6-5  
Feet and tilt stand 6-5  
Cover 6-5  
Disk drive 6-6  
Power supply 6-7  
Main circuit board 6-7  
Switch actuator assembly 6-8  
Rear panel assembly 6-9  
Front panel and keyboard 6-10  
Intensity adjustment 6-10  
Monitor 6-11  
Handle plate 6-11  
Fan 6-12  
Line filter 6-12  
Optional GPIB and/or RS-232C cables 6-13  
To return assemblies 6-14  
Replacing Assemblies  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
This chapter contains the instructions for removing and replacing the assemblies of  
the logic analyzer. Also in this chapter are instructions for returning assemblies.  
Hazardous voltages exist on the power supply, the CRT, and the CRT driver board. To avoid  
electrical shock, disconnect the power from the instrument before performing the following  
procedures. After disconnecting the power, wait at least three minutes for the capacitors on  
the power supply board and the CRT driver board to discharge before servicing the  
instrument.  
W AR N I N G  
C AU T I O N  
Damage can occur to electronic components if you remove or replace assemblies when the  
instrument is on or when the power cable is connected. Never attempt to remove or install  
any assembly with the instrument on or with the power cable connected.  
Replacement Strategy  
These replacement procedures are organized as if disassembling the complete  
instrument, from the first assembly to be removed to the last. Some procedures say  
to remove other assemblies of the instrument, but do not give complete instructions.  
Refer to the procedure for that specific assembly for the instructions. Use the  
exploded view of the instrument on the next page as a reference during the  
replacement procedures.  
Electrostatic discharge can damage electronic components. Use grounded wriststraps and  
mats when performing any service to this logic analyzer.  
C AU T I O N  
Tools Required  
#10 TORX screwdriver  
#15 TORX screwdriver  
#1 Posidrive screwdriver  
3/16 inch (5 mm) nut driver  
9/32 inch (7 mm) nut driver  
6–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
Exploded View  
Listing  
A1  
A2  
A3  
A4  
A5  
A6  
A7  
A8  
A9  
Main circuit board  
Keyboard  
Switch actuator  
Probe cable  
Probe tip  
MP3  
MP4  
MP5  
MP6  
Fan guard  
Rear panel  
Line filter  
Handle plate  
Ground bracket  
Cabinet  
Cover  
Rear feet  
Mounting plate  
Insulator  
Trim strip  
MP32  
MP33  
Spacer  
Label  
W1  
W2  
W3  
W4  
W5  
W6  
W7  
W8  
W9  
Fan cable  
MP7  
Disk drive cable  
Jumper cable-orange  
Jumper cable-white  
Power supply cable  
Front panel cable  
Monitor sweep cable  
GPIB cable  
Power supply  
Disk drive  
Monitor assembly  
Fan  
MP8  
MP9  
MP15  
MP18  
MP19  
MP20  
MP21  
MP22  
MP23  
MP24  
MP25  
MP26  
H2  
H3  
H4  
H22  
Ground spring  
Locking pin  
Label  
RS-232C cable  
BNC connector  
Cable retaining screw  
Label  
Elastomeric keypad  
RPG knob  
Keyboard panel  
Keyboard spacer  
MP1  
MP2  
Intensity adjustment  
Disk drive bracket  
6–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
Exploded View of the 1664A  
6–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the handle  
To remove and replace the handle  
Remove the two screws in the endcaps, then lift off the handle.  
To remove and replace the feet and tilt stand  
1 Remove the screws connecting the four rear feet to the instrument.  
2 Separate the rear feet from the instrument to remove them.  
3 Press the locking tab on the bottom feet, then remove them.  
4 Remove the tilt stand from the bottom front feet by lifting the stand up and out of  
the foot.  
5 Reverse this procedure to install the feet and tilt stand.  
To remove and replace the cover  
1 Disconnect the logic analyzer cables from the rear panel.  
2 Using the previous procedures, remove the handle and the four rear feet.  
3 Remove the seven screws from the front molding, then slide the molding forward to  
remove it.  
4 Remove the cover.  
To remove the cover, set the instrument upright and facing toward you. Slide the chassis  
toward the front, out of the cover, and set it on a static-safe work area.  
5 Reverse this procedure to install the cover.  
Check that all assemblies are properly installed before installing the cover.  
When installing the chassis in the cover, check that the tabs located at the bottom, rear of the  
cover align with the holes in the rear panel.  
6–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the disk drive  
To remove and replace the disk drive  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
2 Disconnect the disk drive cable from the rear of the disk drive.  
3 Remove the two screws that attach the disk drive bracket to the power supply.  
4 Slide the disk drive toward the rear of the instrument, then lift it up and out.  
5 Remove the disk drive bracket.  
To remove the disk drive bracket, remove the four screws that attach the disk drive bracket to  
the disk drive.  
6 Reverse this procedure to install the disk drive.  
Check that the following assemblies are properly installed before installing the disk drive:  
Monitor  
Front Panel  
Switch Actuator  
Main Circuit Board  
Power Supply  
6–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the power supply  
To remove and replace the power supply  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Disk Drive  
Hazardous voltages exist on the power supply. To avoid electrical shock, disconnect the  
power from the instrument before performing the following procedures. After disconnecting  
the power, wait at least three minutes for the capacitors to discharge before servicing the  
instrument.  
W AR N I N G  
2 Lift the PCB locking pins out of the chassis.  
3 Slide the power supply out far enough to reach the power supply cables, then  
disconnect them from the power supply.  
4 Slide the power supply the rest of the way out the side of the instrument.  
5 Reverse this procedure to install the power supply.  
Check that the following assemblies are properly installed before installing the power supply:  
Monitor  
Front Panel  
Switch Actuator  
Main Circuit Board  
To remove and replace the Main Circuit board  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Panel  
Cover  
Disk Drive  
Power Supply  
2 Disconnect the GPIB and RS-232C cables from the Main Circuit board.  
3 Disconnect the front panel cable from the Main Circuit board.  
4 Disconnect the monitor board cable from the Main Circuit board.  
5 Slide the board out the rear of the instrument.  
6 Reverse this procedure to install the Main Circuit board.  
Check that the following assemblies are properly installed before installing the Main Circuit  
board:  
Monitor  
Front Panel  
Switch Actuator  
6–7  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the switch actuator assembly  
To remove and replace the switch actuator assembly  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Disk Drive  
Power Supply  
Main Circuit board  
2 Make sure the power switch is in the off position.  
3 Disconnect the switch actuator from the line filter.  
a Slide the clamp off of the outer casing far enough to release the switch actuator  
assembly.  
If the wire in the switch actuator is bent, the complete assembly must be replaced. Refer to  
chapter 5, "Replaceable Parts" for the part number.  
C AU T I O N  
b Without bending the wire, gently pry the nipple out of the switch plunger.  
c Slide the cable out of the switch assembly.  
4 Remove the switch actuator assembly from the front of the cabinet.  
To remove, depress the retaining ears on both sides of the assembly next to the front panel  
and push the assembly out the front.  
5 Install the new switch actuator assembly. Make sure that the line filter switch is in  
the off position.  
a Route the cable through the front panel, then snap the pushbutton into the front panel.  
b Snap the nipple into the switch plunger.  
c Position the free end of the outer casing into the switch mounting chassis. The edge  
of the outer casing should be all the way against the inner edge of the switch mounting  
chassis.  
d Close the clamp by pushing it into the switch assembly until the clamp is seated.  
6 Verify the push-on, push-off action of the assembly.  
6–8  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the rear panel assembly  
To remove and replace the rear panel assembly  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
2 Remove the switch actuator cable from the line filter according to "To remove and  
replace the switch actuator assembly."  
3 Disconnect the BNC In/Out and fan cables on the Main Circuit board.  
4 Disconnect the RS-232C an GPIB cables from the Main Circuit board.  
5 Remove the two standoffs connecting the parallel printer connector socket to the  
rear panel.  
6 Remove the two screws connecting the keyboard connector socket to the rear panel.  
7 Remove the six rear panel screws.  
8 Lift the rear panel away from the chassis.  
9 Reverse this procedure to install the rear panel.  
Check that the following assemblies are properly installed before installing the rear panel:  
Monitor  
Main Circuit Board  
When installing the rear panel, check that the connectors on the main circuit board are lined  
up with the corresponding holes in the rear panel.  
6–9  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the front panel and keyboard  
To remove and replace the front panel and keyboard  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Disk Drive  
Power Supply  
Main Circuit board  
2 Remove the four screws connecting the front panel.  
3 Slide the front panel assembly out the front of the instrument.  
4 Slide the spacers out the front of the instrument to remove them.  
Be careful not to lose the copper ground strips on the spacer.  
When installing the spacer, insert the pins of the spacer in the appropriate holes in the  
chassis. You can hold the spacer in place while installing the front panel by holding it with  
your finger through the disk drive mounting slot in the chassis.  
5 Remove the RPG knob by pulling the knob off the RPG shaft.  
6 Disassemble the front panel assembly by lifting the keyboard circuit board away  
from the front panel.  
7 Lift the elastomeric keypad out of the front panel.  
8 Reverse this procedure to assemble and install the front panel assembly.  
When assembling the front panel, check that the holes in the elastomeric keypad and the  
keyboard circuit board align with the pins on the front panel.  
To remove and replace the intensity adjustment  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Rear Panel  
2 Disconnect the intensity adjustment cable from the CRT driver board.  
3 Using a nut driver, remove the hex nut attaching the intensity adjustment to the  
chassis.  
4 Slide the intensity adjustment assembly toward the front and up out of the  
instrument.  
5 Reverse this procedure to install the intensity adjustment.  
When installing the intensity adjustment, check that the keying tab on the adjustment aligns  
with the keying hole in the chassis.  
6–10  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the monitor  
To remove and replace the monitor  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Disk Drive  
Power Supply  
Main Circuit board  
Rear Panel  
Hazardous voltages exist on the CRT and the CRT driver board. To avoid electrical shock,  
disconnect the power from the instrument before performing the following procedures. After  
disconnecting the power, wait at least three minutes for the capacitors to discharge before  
servicing the instrument.  
W AR N I N G  
2 Disconnect the cable from the rear of the CRT.  
3 Disconnect the yoke cable and intensity cable from the CRT driver board.  
4 Disconnect the high voltage lead from the bell of the CRT.  
5 Slide the CRT driver board up out of the chassis.  
6 Using a nut driver, remove the three hex nuts attaching the monitor and ground  
bracket to the chassis, then remove the screw.  
7 Slide the monitor assembly and ground bracket to the rear and up out of the chassis.  
8 Reverse this procedure to install the monitor.  
When installing the CRT driver board, check that the board is properly inserted in the circuit  
board tracks.  
To remove and replace the handle plate  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
2 Remove the four screens that attach the handle plate to the chassis.  
3 Remove the handle plate.  
To remove the handle plate, align the plate toward the front of the instrument, then move it  
up and out of the instrument.  
4 Reverse this procedure to install the handle plate.  
6–11  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the fan  
To remove and replace the fan  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Disk Drive  
Power Supply  
Rear Panel  
2 Disconnect the fan cable from the main circuit board.  
3 Remove the four fan screws.  
4 Lift the fan away from the rear panel.  
5 Lift the fan guard away from the rear panel.  
6 Reverse this procedure to install the fan.  
When installing the fan, verify the correct orientation of the fan. If you mount the fan  
backwards, the instrument will overheat. Also, check the correct polarity of the fan cable.  
To remove and replace the line filter  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Disk Drive  
Power Supply  
Rear Panel  
2 Unsolder the ground wire from the lug on the rear panel.  
3 Disconnect the line filter cable from the power supply.  
4 Remove the two screws attaching the line filter to the rear panel.  
5 Slide the line filter assembly out toward the rear.  
6 Reverse this procedure to install the line filter.  
6–12  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To remove and replace the optional GPIB and RS-232C cables  
To remove and replace the optional GPIB and RS-232C cables  
1 Using previous procedures, remove the following assemblies:  
Handle  
Rear Feet  
Cover  
Disk Drive  
Power Supply  
Rear Panel  
2 Disconnect interface cables from the main circuit board.  
3 Remove the two hex standoffs connecting the GPIB cable, then slide the GPIB cable  
forward and out of the rear panel.  
4 Remove the two hex standoffs connecting the RS-232C cable, then slide the RS-232C  
cable forward and out of the rear panel.  
5 Reverse this procedure to install the GPIB and RS-232C cables.  
6–13  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replacing Assemblies  
To return assemblies  
To return assemblies  
Before shipping the logic analyzer or assemblies to Agilent Technologies, contact your nearest  
Agilent Technologies sales office for additional details.  
1 Write the following information on a tag and attach it to the part to be returned.  
Name and address of owner  
Model number  
Serial number  
Description of service required or failure indications  
2 Remove accessories from the logic analyzer.  
Only return accessories to Agilent Technologies if they are associated with the failure  
symptoms.  
3 Package the logic analyzer.  
You can use either the original shipping containers, or order materials from an Agilent  
Technologies sales office.  
For protection against electrostatic discharge, package the logic analyzer in electrostatic  
material.  
C AU T I O N  
4 Seal the shipping container securely, and mark it FRAGILE.  
6–14  
Download from Www.Somanuals.com. All Manuals Search And Download.  
7
Replaceable Parts Ordering 7–2  
Exploded View 7–3  
Replaceable Parts List 7–4  
Power Cables and Plug Configurations 7–8  
Replaceable Parts  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replaceable Parts  
This chapter contains information for identifying and ordering replaceable parts for  
your logic analyzer.  
Replaceable Parts Ordering  
Parts listed  
To order a part on the list of replaceable parts, quote the Agilent Technologies part number,  
indicate the quantity desired, and address the order to the nearest Agilent Technologies Sales  
Office.  
Parts not listed  
To order a part not on the list of replaceable parts, include the model number and serial  
number of the module, a description of the part (including its function), and the number of  
parts required. Address the order to your nearest Agilent Technologies Sales Office.  
Direct mail order system  
To order using the direct mail order system, contact your nearest Agilent Technologies Sales  
Office.  
Within the USA, Agilent Technologies can supply parts through a direct mail order system.  
The advantages to the system are direct ordering and shipment from the Agilent Technologies  
Part Center in Mountain View, California. There is no maximum or minimum on any mail  
order. (There is a minimum amount for parts ordered through a local Agilent Technologies  
Sales Office when the orders require billing and invoicing.) Transportation costs are prepaid  
(there is a small handling charge for each order) and no invoices.  
In order for Agilent Technologies to provide these advantages, a check or money order must  
accompany each order. Mail order forms and specific ordering information are available  
through your local Agilent Technologies Sales Office. Addresses and telephone numbers are  
located in a separate document at the back of the service guide.  
Exchange Assemblies  
Some assemblies are part of an exchange program with Agilent Technologies.  
The exchange program allows you to exchange a faulty assembly with one that has been  
repaired and performance verified by Agilent Technologies.  
After you receive the exchange assembly, return the defective assembly to Agilent  
Technologies. A United States customer has 30 days to return the defective assembly. If you  
do not return the defective assembly within the 30 days, Agilent Technologies will charge you  
an additional amount. This amount is the difference in price between a new assembly and  
that of the exchange assembly. For orders not originating in the United States, contact your  
nearest Agilent Technologies Sales Office for information.  
See Also  
"To return assemblies," in chapter 6.  
7–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replaceable Parts  
Exploded View  
Exploded View  
Exploded view of the 1664A logic analyzer.  
7–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replaceable Parts  
Replaceable Parts List  
Replaceable Parts List  
The replaceable parts list is organized by reference designation and shows exchange  
assemblies, electrical assemblies, then other parts.  
The exploded view does not show all of the parts in the replaceable parts list.  
Information included for each part on the list consists of the following:  
Reference designator  
Agilent Technologies part number  
Total quantity included with the instrument (Qty)  
Description of the part  
Reference designators used in the parts list are as follows:  
A Assembly  
E Miscellaneous Electrical Part  
F Fuse  
H Hardware  
MP Mechanical Part  
W Cable  
7–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replaceable Parts  
Replaceable Parts List  
1664A Replaceable Parts  
Ref.  
Des.  
Agilent  
Part  
Number  
Qty  
Description  
Exchange Board  
01664-69501  
Exchange main circuit assembly  
Replacement Parts  
Main circuit assembly  
A1  
A2  
A3  
A4  
A5  
01664-66501  
01660-66502  
01660-61901  
01660-61605  
01650-61608  
1
1
1
1
2
Board assembly-keyboard  
Switch actuator  
Probe Cable  
Probe tip assembly  
A6  
A7  
A8  
A9  
A10  
0950-2261  
0950-2169  
2090-0304  
3160-0829  
1150-1922  
1
1
1
1
1
Power supply  
Disk drive  
Monitor assembly  
Fan-tubeaxial  
Three-button mouse  
E1  
E2  
E3  
E4  
5959-9333  
5959-9334  
5959-9335  
5090-4356  
Replacement probe leads (5 per package)  
Replacement probe grounds (5 per package)  
Replacement pod grounds (5 per package)  
Grabber kit assembly (20 grabbers per package)  
F1  
2110-0055  
1 Fuse (4 A, 250V)  
H1  
H2  
H3  
H4  
H5  
1400-0611  
1
Clamp-cable  
01660-09101  
01650-46101  
01660-67601  
0515-1363  
1
Ground spring  
2
2
10  
Locking pin PCB  
BNC connector assembly  
MS 3.0 5 TH T10 (disk drive, handle plate)  
H6  
H7  
H8  
0515-0680  
0380-1858  
0515-0430  
2
MS 3.0 6 PH T10 (rear panel to HIL connector)  
Jackscrew with lock (printer port to rear panel)  
MS M3.0X0.5X6MM PH T10 (main circuit assembly, rear panel  
to chassis , RS-232C/GPIB cover plate)  
MS M3.0X0.50X14MM LG (trim strip cover to cabinet)  
MSFH M3 8 T10 (line filter)  
2
11  
H9  
H10  
0515-2349  
0515-1035  
5
2
H11  
H12  
H13  
H14  
H15  
0515-1103  
0515-0664  
2950-0072  
2950-0001  
0535-0056  
2
4
1
2
3
MSFH M3 10 T10 (trim strip cover to cabinet)  
MSPH M3 12 SMS10 (rear feet to cabinet)  
NUTH 1/4-32 .062 (intensity adjustment)  
NUTH 3/8-32 .093 (BNC trigger ports)  
NUT-HEX (monitor assembly)  
H16  
H17  
H18  
H19  
H20  
0515-0382  
0515-1349  
3050-0010  
2190-0027  
2190-0016  
3
4
4
1
2
SM ASSY M4X0.7 12MM LG (monitor assembly, handle)  
SM M3X0.5 30MM LG (front panel assembly)  
WFL.147 .312 .03 (rear feet)  
WIL.256 .478 .02 (intensity adjustment)  
WIL.377 .507 .02 (BNC trigger ports)  
H21  
H22  
H23  
H24  
0515-1031  
0515-2306  
2510-0332  
1252-2218  
4
2
4
2
MSFH M3 6 T10 (accessory pouch)  
Screw Sems M3 X0.5X10mm (Cable Retaining Screw)  
SCR-MACH 8-32 (Fan)  
Cable Retaining Clip-20-pin connector (Monitor sweep cable)  
7–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replaceable Parts  
Replaceable Parts List  
1664A Replaceable Parts  
Ref.  
Des.  
Agilent  
Part  
Number  
Qty  
Description  
H25  
1252-2220  
1
Cable Retaining Clip-34-pin connector (Disk drive cable)  
MP1  
MP2  
MP3  
MP4  
MP5  
01660-61606  
01660-01203  
3160-0092  
01664-00201  
54501-62702  
1
1
1
1
1
Intensity adjustment assembly  
Bracket-disk drive  
Fan guard  
Rear panel  
Line filter/cable assembly  
MP6  
MP7  
MP8  
MP9  
MP10  
01660-01202  
01650-01202  
01660-60001  
01660-04102  
54542-44901  
1
1
1
1
1
Handle plate  
Ground bracket  
Cabinet assembly  
Cover assembly  
Handle vinyl grip  
MP11  
MP12  
MP13  
MP14  
MP15  
35672-21703  
35672-45004  
5041-8801  
2
2
2
2
4
Strap retainer  
Handle end cap  
Foot  
1460-1345  
Tilt Stand  
01660-40501  
Rear foot  
MP16  
MP17  
MP18  
MP19  
MP20  
5041-8822  
2
1
1
1
1
Non-skid foot  
01660-45401  
01660-01201  
01660-84501  
01660-40502  
Circuit board insulator  
Circuit board mounting plate  
Accessory pouch  
Trim strip  
MP21  
MP22  
MP23  
MP24  
MP25  
01664-94301  
01660-94302  
01660-41901  
01660-47401  
01660-60002  
1
1
1
1
1
ID label (1664A)  
Line switch label  
Elastomeric keypad  
RPG knob  
Assembled keyboard panel and label  
01660-45201  
01660-94303  
01660-44703  
01660-44702  
01660-94306  
0
0
1
1
Keyboard panel-replacement  
Keyboard label-replacement  
Keyboard spacer  
MP26  
MP27  
MP28  
Front panel spacer  
Keyboard template, enter (accessory)  
MP29  
MP30  
MP31  
MP32  
MP33  
01660-94305  
01664-04101  
16555-60001  
01664-44701  
01660-94304  
Keyboard template, F1-F8 (accessory)  
Rear panel cover plate (RS-232, GPIB)  
Ferrite Core Assembly  
1
1
1
1
Rubber Spacer (Ferrite)  
Label-Pods and Cable  
W1  
W2  
W3  
W4  
W5  
01650-61616  
01660-61603  
01660-61607  
01660-61608  
54503-61606  
1
1
1
1
1
Fan cable  
Disk drive cable  
Jumper cable assembly-orange  
Jumper cable assembly-white  
Power supply cable  
W6  
01664-61601  
1
Front Panel Cable Extender  
7–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replaceable Parts  
Replaceable Parts List  
1664A Replaceable Parts  
Ref.  
Des.  
Agilent  
Part  
Number  
Qty  
Description  
W7  
01650-61601  
1
Monitor sweep cable  
Option #020  
E5  
01650-63202  
0380-1482  
2190-0009  
0380-1858  
1258-0141  
1
2
2
2
1
RS-232 loopback connector  
Hex standoff (GPIB Cable)  
WIL.168 .340 .02 (GPIB Cable)  
Jackscrew with lock (RS-232 Cable)  
Removable jumper  
H26  
H27  
H28  
MP34  
W8  
W9  
01650-61613  
01660-61601  
1
1
GPIB Cable  
RS-232C Cable  
Power Cords  
W10  
8120-1521  
8120-0696  
8120-1692  
8120-2296  
8120-2957  
8120-4600  
8120-4754  
1
1
1
1
1
1
1
Power Cord: United Kingdow (#900)  
Power Cord: Australia (#901  
Power Cord: Europe (#902)  
Power Cord: Switzerland (#906)  
Power Cord: Denmark (#912)  
Power Cord: Africa (#917)  
Power Cord: Japan (#918)  
7–7  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Replaceable Parts  
Power Cables and Plug Configurations  
Power Cables and Plug Configurations  
This instrument is equipped with a three-wire power cable. The type of power cable plug  
shipped with the instrument depends on the country of destination. The W10 reference  
designators (table, previous page) show option numbers of available power cables and plug  
configurations.  
7–8  
Download from Www.Somanuals.com. All Manuals Search And Download.  
8
Block-Level Theory 8-3  
The 1660 Series Logic Analyzer 8-3  
The Logic Acquisition Circuitry 8-6  
Self-Tests Description 8-9  
Power-up Self-Tests 8-9  
System Tests (System PV) 8-10  
Analyzer Tests (Analy PV) 8-13  
GPIB 8-15  
RS-232C 8-16  
Centronix 8-17  
Theory of Operation  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
This chapter tells the theory of operation for the logic analyzer and describes the  
self-tests. The information in this chapter is to help you understand how the logic  
analyzer operates and what the self-tests are testing. This information is not  
intended for component-level repair.  
8–2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Block-Level Theory  
The block-level theory is divided into two parts: theory for the logic analyzer and  
theory for the main circuit board. A block diagram is shown with each theory.  
The 1664A Logic Analyzer  
The 1664A logic analyzer  
8–3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
The 1664A Logic Analyzer  
1664A Theory  
CPU  
Located on the main circuit board, the microprocessor is a Motorola 68EC020 running at  
25 MHz. The microprocessor controls all of the functions of the logic analyzer including  
processing and storing data, displaying data, and configuring the acquisition ICs to obtain and  
store data.  
System Memory  
The system memory is made up of both read-only memory (ROM) and random access memory  
(RAM). A single 128Kx8 EPROM is used as a boot ROM (boot-up requires operating system  
on disk loaded in the disk drive). Four 1Mx4 DRAMS are configured to provide a 1Mx16  
DRAM space.  
On power-up, instructions in the boot ROM command the instrument to execute its boot  
routine, which loads the operating system from disk. The boot routine (on disk) includes  
power-up operation verification of the instrument subsystems and entering the operating  
system. The CPU searches for the operating system on disk.  
The DRAM stores the instrument configuration, acquired data to be processed, and any  
inverse assembler loaded in the instrument by the user.  
CRT Controller and Display RAM  
A Brooktree BT476KPJ66 RAMDAC color palette and a National Semiconductor LM1882CM  
video frame generator control the CRT. One of the RGB outputs of the color palette provides  
the eight-shade grey scale display. The video frame generator provides the horizontal and  
vertical synchronization timing signals.  
The display RAM is made up of two 256Kx4 DRAMS configured as 256Kx8 and stores all of  
the pixel information used by the color palette. A serial address counter and an address  
multiplexer control the DRAM addressing. At the conclusion of each video frame the vertical  
sync signal from the video generator resets the serial address counter and a new frame is  
generated.  
Disk Drive Controller  
The disk drive controller consists of a single floppy drive controller IC. The floppy drive  
controller provides all signals to the disk drive including read and write data, read and write  
signals, write gate, and step signal. The floppy drive controller also reads status signals from  
the disk drive, including a track 00 signal, disk ready, and disk change signal.  
Keypad and Knob Interface  
The front panel keypad is scanned directly from the microprocessor address bus during the  
video blanking cycle of the CRT. When a front panel key is pressed the associated address  
bits are fed to the data bus through the pressed key and read by the microprocessor.  
The rotary pulse generator (RPG) knob is part of the HIL circuitry. Pulses and direction of  
rotation information are directed to an RPG interface IC and then to the HIL loop. The  
microprocessor then reads and interprets the RPG signals and performs the desired tasks.  
8–4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
The 1664A Logic Analyzer  
External Keyboard Interface  
Agilent proprietary ICs make up the external keyboard interface. The ICs establish a link with  
the controller IC on the external keyboard. The keyboard signals are routed through the  
acquisition circuit board to the CPU board. The microprocessor then reads and interprets the  
external keyboard and mouse information and performs the desired tasks.  
Centronix Interface  
The instrument parallel printer interface is compatible with industry standard Centronix  
protocol. The interface consists of a controller, and drivers/receivers. The controller  
conditions parallel data from the microprocessor for transmission. At the same time the  
controller also receives status information for the microprocessor. Data flow, status, and  
handshaking control are also provided by the controller.  
Optional GPIB Interface  
The instrument interfaces to GPIB as defined by IEEE Standard 488.2. The interface consists  
of an GPIB controller and two octal drivers/receivers. The microprocessor routes GPIB data  
to the controller. The controller then buffers the 8-bit GPIB data bits and generates the bus  
handshaking signals. The data and handshaking signals are then routed to the GPIB bus  
through the octal line drivers/receivers. The drivers/receivers provide data and control signal  
transfer between the bus and controller.  
Optional RS-232C Interface  
The instrument RS-232C interface is compatible with standard RS-232C protocol. The  
interface consists of a controller, and drivers/receivers. The controller serializes parallel data  
from the microprocessor for transmission. At the same time the controller also receives serial  
data and converts the data to parallel data characters for the microprocessor.  
The controller contains a baud rate generator that can be programmed from the logic analyzer  
front panel for one of eight baud rates. Other RS-232C communications parameters can also  
be programmed from the logic analyzer front panel.  
The drivers/receivers interface the instrument with data communications equipment. Slew  
rate control is provided on the ICs eliminating the need for external capacitors.  
CRT Monitor Assembly  
The CRT Monitor Assembly consists of a monochrome CRT and a monitor driver board. The  
monitor driver board provides the biasing and control signals for the CRT. Pixel information  
is stored in the display RAM on the CPU board and is routed to the monitor driver board  
through the acquisition board and the sweep cable.  
Disk Drive  
The disk drive assembly is a high density disk drive that formats double-sided, double-density  
or high density disks in LIF or DOS format. A disk drive controller on the CPU board controls  
the disk drive. Signals are routed directly to the disk drive through the disk drive cable.  
Power Supply  
A low voltage power supply provides all DC voltages needed to operate the logic analyzer.  
The power supply also provides the +5 Vdc voltage to the probe cables to power logic analyzer  
accessories and preprocessors.  
Unfiltered voltages of +12 V, -12 V, +5 V, -5.2 V, and +3.5 V are supplied to the acquisition  
board where they are filtered and distributed to the CPU board, CRT Monitor Assembly, and  
probe cables.  
8–5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
The Logic Acquisition Circuitry  
The Logic Acquisition Circuitry  
The Main Circuit Board Logic Acquisition Circuitry  
8–6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
The Logic Acquisition Circuitry  
Main Circuit Board Logic Acquisition Theory  
Probing  
The probing circuit includes the probe cable and terminations. The probe cable consists of  
two 17-channel pods which are connected to the circuit board using a high-density connector.  
Sixteen single-ended data channels and one single-ended clock/data channel are passed to the  
circuit board per pod.  
If the clock/data channel is not used as a state clock in state acquisition mode, it is available as  
a data channel. The clock/data channel is also available as a data channel in timing acquisition  
mode. Two clock/data channels are available as data channels, and all clock data channels  
available can be assigned as clock channels.  
The cables use nichrome wire woven in polyarmid yarn for reliability and durability. The pods  
also include one ground path per channel in addition to a pod ground. The channel grounds  
are configured such that their electrical distance is the same as the electrical distance of the  
channel.  
The probe tip assemblies and termination modules connected at the end of the probe cables  
have a divide-by-10 RC network that reduces the amplitude of the data signals as seen by the  
circuit board. This adds flexibility to the types of signals the circuit board can read in addition  
to improving signal integrity.  
The terminations on the circuit board are resistive terminations that reduce transmission line  
effects on the cable. The terminations also improve signal integrity to the comparators by  
matching the impedance of the probe cable channels with the impedance of the signal paths of  
the circuit board. All 17 channels of each pod are terminated in the same way. The signals  
are still reduced by a factor of 10.  
Comparators  
Two proprietary 9-channel comparators per pod interpret the incoming data and clock signals  
as either high or low depending on where the user-programmable threshold is set. The  
threshold voltage of each pod is individually programmed, and the voltage selected applies to  
the clock channel as well as the data channels of each pod.  
Each of the comparator ICs has a serial test input port used for testing purposes. A test bit  
pattern is sent from the Test and Clock Synchronization Circuit to the comparator. The  
comparators then propagate the test signal on each of the nine channels of the comparator.  
Consequently, all data and clock channel pipelines on the circuit board can be tested by the  
operating system software from the comparator.  
Acquisition  
The acquisition circuit is made up of a single Agilent Technologies proprietary ASIC. Each  
ASIC is a 34-channel state/timing analyzer, and one such ASIC is included for every two logic  
analyzer pods. All of the sequencing, pattern/range recognition, and event counting functions  
are performed on board the IC.  
In addition to the storage qualification and counting functions, the acquisition ASICs also  
perform master clocking functions. All six state acquisition clocks are fed to each IC, and the  
ICs generate their own sample clocks. Every time you select RUN, the ICs individually  
perform a clock optimization before data is stored.  
8–7  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
The Logic Acquisition Circuitry  
Clock optimization involves using programmable delays on board the IC to position the master  
clock transition where valid data is captured. This procedure greatly reduces the effects of  
channel-to-channel skew and other propagation delays.  
In the timing acquisition mode, an oscillator-driven clock circuit provides a four-phase,  
100-MHz clock signal to each of the acquisition ICs. For high speed timing acquisition  
(100 MHz and faster), the sample period is determined by the four-phase, 100-MHz clock  
signal.  
For slower sample rates, one of the acquisition ICs divides the 100-MHz clock signal to the  
appropriate sample rate. The sample clock is then fed to all acquisition ICs.  
Threshold  
A precision octal DAC and precision op amp drivers make up the threshold circuit. Each of  
the eight channels of the DAC is individually programmable which allows you to set the  
thresholds of the individual pods. The 16 data channels and the clock channel of each pod are  
all set to the same threshold voltage.  
Test and Clock Synchronization Circuit  
ECLinPS (TM) ICs are used in the Test and Clock Synchronization Circuit for reliability and  
low channel-to-channel skew. Test patterns are generated and sent to the comparators during  
software operation verification. The test patterns are propagated across all data and clock  
channels and read by the acquisition ASIC to ensure both the data and clock pipelines are  
operating correctly.  
The Test and Clock Synchronization Circuit also generates a four-phase, 100-MHz  
sample/synchronization signal for the acquisition ICs operating in the timing acquisition  
mode. The synchronizing signal keeps the internal clocking of the individual acquisition  
ASICs locked in step with the other ASICs at fast sample rates. At slower sample rates, one of  
the acquisition ICs divides the 100-MHz clock signal to the appropriate sample rate. The slow  
speed sample clock is then used by all acquisition ICs.  
8–8  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Self-Tests Description  
The self-tests identify the correct operation of major functional areas in the logic  
analyzer. The self-tests are not intended for component-level diagnostics.  
Three types of tests are performed on the 1664A logic analyzer: the power-up  
self-tests, the functional performance verification self-tests, and the parametric  
performance verification tests.  
The power-up self-tests are performed when power is applied to the instrument.  
The functional performance verification self-tests are run using a separate operating  
system, the performance verification (PV) operating system. The PV operating  
system resides on a separate disk that must be inserted in the disk drive when  
running the functional performance verification self-tests. The system and analyzer  
tests are functional performance verification tests.  
Parametric performance verification requires the use of external test equipment that  
generates and monitors test data for the logic analyzer to read. The performance  
verification procedures in chapter 3 of this service guide make up the parametric  
performance verification for the logic analyzer. Refer to chapter 3, "Testing  
Performance," for further information about parametric performance verification.  
Power-up Self-Tests  
The power-up self-tests are divided into two parts. The first part is the system memory tests  
and the second part is the microprocessor interrupt test. The system memory tests are  
performed before the logic analyzer actually displays the power-up self-test screen. Both the  
system ROM and RAM are tested during power-up. The interrupt test is performed after the  
power-up self-test screen is displayed.  
The following describes the power-up self-tests:  
ROM Test  
The ROM test performs several checksum tests on various read only memory elements,  
including the system ROM as well as the various software modules present in flash ROM.  
Passing the ROM test implies that the microprocessor can access each ROM memory address  
and that each ROM segment provides checksums that match previously calculated values.  
8–9  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
System Tests (System PV)  
RAM Test  
The RAM test checks the video RAM (VRAM), system dynamic RAM (DRAM), and static RAM  
memory within the real time clock IC. The microprocessor first performs a write/read in each  
memory location of the VRAM. At each VRAM memory location a test pattern is written, read,  
and compared. An inverse test pattern is then written, read, and compared. After verifying  
correct operation of the VRAM, the System RAM and real time clock RAM are tested in a  
similar fashion.  
Passing the RAM test implies that the microprocessor can access each VRAM memory location  
and that each VRAM memory location can store a logical "1" or a logical "0." If the VRAM is  
functioning properly, the logic analyzer can construct a correct, undistorted display. Passing  
the RAM test also implies that the memory locations of system RAM can be accessed by the  
microprocessor and the data in RAM is intact, and that the memory locations inside the real  
time clock IC can store a logical "1" or a logical "0."  
Interrupt Test  
The Interrupt Test checks the microprocessor interrupt circuitry. With all interrupts disabled  
from their source, the microprocessor waits for a short period of time to see if any of the  
interrupt lines are asserted. An asserted interrupt line during the wait period signifies  
incorrect functioning of the device generating the interrupt or the interrupt circuitry itself.  
Those interrupts that can be asserted under software control are exercised to verify  
functionality.  
Passing the Interrupt Test implies that the interrupt circuitry is functioning properly. Passing  
the Interrupt Test also implies that the interrupt generating devices are also functioning  
properly and not generating false interrupts. This means that the microprocessor can execute  
the operating system code and properly service interrupts generated by pressing a front panel  
key or receiving an GPIB or RS-232C command.  
System Tests (System PV)  
The system tests are functional performance verification tests. The following describes the  
system tests:  
ROM Test  
The ROM test performs several checksum tests on various read only memory elements,  
including the system ROM.  
Passing the ROM test implies that the microprocessor can access each ROM memory address  
and that each ROM segment provides checksums that match previously calculated values.  
RAM Test  
The RAM test performs a write/read operation in each memory location in system dynamic  
RAM (DRAM). The video RAM in the display subsystem and the acquisition RAM in the data  
acquisition subsystem are not tested as part of the RAM test and are tested elsewhere. At  
each DRAM memory location, the code that resides at that location is stored in a  
microprocessor register. A test pattern is then stored at the memory location, read, and  
compared. An inverse test pattern is then stored, read, and compared. The original code is  
then restored to the memory location. This continues until all DRAM memory locations have  
been tested. The static RAM in the real time clock chip is also tested in a similar fashion.  
Passing the RAM test implies that all RAM memory locations can be accessed by the  
microprocessor and that each memory location can store a logical "1" or a logical "0."  
8–10  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
System Tests (System PV)  
GPIB Test  
The GPIB test performs a write/read operation to each of the registers of the GPIB IC. A test  
pattern is written to each register in the GPIB IC. The pattern is then read and compared  
with a known value. The GPIB test will return a valid "Pass" or "Fail" status even if option 020  
is not installed.  
Passing the GPIB test implies that the read/write registers in the GPIB IC can store a logical  
"1" or a logical "0," and that the GPIB IC is functioning properly. Incoming and outgoing GPIB  
information will not be corrupted by the GPIB IC.  
RS-232C Test  
This test checks the basic interface functions of the RS-232C port. Both internal and external  
portions of the port circuitry are tested. In order for the RS-232C test to pass, option 020  
must be installed and the RS-232C loopback connector must be installed on the RS-232C  
connector.  
HIL Test  
The HIL test exercises both the HIL circuitry internal to the logic analyzer and the HIL  
interface between the logic analyzer and external keyboard, if an external keyboard is  
connected. First, a read/write operation is performed to each of the registers of the HIL IC. A  
test pattern is written to each memory location, read, and compared with a known value.  
Second, if an external keyboard is connected to the HIL port, the keyboard controller that  
resides in the keyboard is polled by the microprocessor. A test pattern is sent to the keyboard  
controller and returned to the microprocessor by the keyboard controller. The test pattern is  
then compared with a known value.  
Passing the HIL test implies that the read/write registers in the HIL IC can store a logical "1" or  
a logical "0," and that the HIL IC is functioning properly. Also, passing the HIL test implies  
that the HIL pathway to the external keyboard is functioning and that the keyboard controller  
can communicate with the microprocessor in the logic analyzer. Incoming HIL information  
from the external keyboard will not be corrupted by the pathway between the keyboard  
controller and microprocessor.  
Disk Test  
The disk test exercises the disk controller circuitry by performing a read/write on a disk.  
Either an LIF formatted disk with 20 sectors available space or a DOS formatted disk with 5K  
available space is required and should be inserted in the disk drive. When the disk test is  
executed, the disk is checked sector by sector to find any bad sectors. If no bad sectors are  
found, a test file is created on the disk and test data is written to the file. Then, the file is  
read and the test data is compared with known values. At the conclusion of the test, the test  
file is erased.  
Passing the disk test implies that the disk controller circuitry in the logic analyzer and the disk  
read/write circuitry in the disk drive are functioning properly. The disk drive can read and  
write to a LIF or DOS formatted disk, and the data will not be corrupted by the disk drive  
circuitry.  
8–11  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
System Tests (System PV)  
Perform Test All  
Selecting Perform Test All will initiate all of the previous functional verification tests in the  
order they are listed. The failure of any or all of the tests will be reported in the test menu  
field of each of the tests. The Perform All Test will not initiate the Front Panel Test or the  
Display Test.  
Front Panel Test  
A mock-up of the logic analyzer front panel is displayed on the CRT when the Front Panel  
Test is initiated. The operator then pushes each front panel button and turns the RPG (rotary  
pulse generator) knob to toggle the corresponding fields from light to dark on the front panel  
mock-up. Successively pushing any front panel key will cause the corresponding field to  
toggle back and forth between light and dark. An exception is the Done key. Pressing the  
Done key a second time will cause an exit of this test.  
The Front Panel Test passes when all of the key fields in the front panel mock-up on the CRT  
can be toggled by pressing the corresponding front panel key, and the two RPG fields can be  
toggled by turning the knob. The Front Panel Test is not called when Perform Test All is  
selected.  
Display Test  
When initiated, the display test will cause three test screens to be displayed sequentially. The  
first test screens is a test pattern used to align the CRT. The second two screens verify  
correct operation of the color palette by displaying first a full bright screen and then a half  
bright screen.  
The pass or fail status of the display test is determined by the operator. The Display Test  
passes when all three test screens are displayed according to chapter 4, "Calibrating and  
Adjusting." The display test is not used when Perform Test All is selected.  
8–12  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
Analyzer Tests (Analy PV)  
Analyzer Tests (Analy PV)  
The analyzer tests are functional performance verification tests. There are three types of  
analyzer tests: the Board Test, the Chip Test, and the Data Input Inspection. The following  
describes the analyzer self-tests:  
Board Test  
The Board Test functionally verifies the two oscillators and the 9-channel comparators on the  
circuit board. First, the oscillators are checked using the event counter on one of the  
acquisition ICs. The event counter will count the number of oscillator periods within a  
pre-determined time window. The count of oscillator periods is then compared with a known  
value.  
The comparators are then checked by varying the threshold voltage and reading the state of  
the activity indicators. The outputs of the octal DAC are set to the upper voltage limit and the  
activity indicators for all of the pod channels are read to see if they are all in a low state.  
The octal DAC outputs are then set to the lower voltage limit, and the activity indicators are  
read to see if they are in a high state. The DAC outputs are then set to 0.0 V, allowing the  
comparators to recognize the test signal being routed to the test input pin of all of the  
comparators. Consequently, the activity indicators are read to see if they show activity on all  
channels of all of the pods.  
Chip Tests  
During the Chip Tests, six tests are performed on the acquisition ICs. The tests are the  
Communications, Memory, Encoder, Resource, Sequencer, and Clock Generation Tests.  
Communications Test The communications test verifies that communications pipeline  
between the various subsystems of the IC are operating. Checkerboard patterns of "1s"  
and "0s" are routed to the address and data buses and to the read/write registers of each  
chip. After verifying the communications pipelines, the acquisition clock synchronization  
signals that are routed from IC to IC are checked. Finally, the IC master clock  
optimization path is checked and verified.  
Passing the communications test implies that the communications pipelines running from  
subsystem to subsystem on the acquisition IC are functioning and that the clock optimization  
circuit on the IC is functioning. Also, passing this test implies that the acquisition clock  
synchronization signals are functioning and appear at the synchronization signal output pins  
of the acquisition IC.  
Memory Test Acquisition RAM is checked by filling the IC RAM with a checkerboard  
pattern of "1s" and "0s," then reading each memory location and comparing the test  
pattern with known values. Then, the IC RAM is filled with an inverse checkerboard  
pattern, read, and compared with known values.  
Passing the memory test implies that the acquisition IC RAM is functioning and that each  
memory location bit can hold either a logical "1" or logical "0."  
Encoder Test The encoder in the FISO front end is tested and verified using a walking  
"1" and walking "0" pattern. The walking "1" and "0" is used to stimulate all of the encoder  
output pins which connect directly to the FISO memory cells. Additionally, the post-store  
counter in each of the acquisition ICs is tested.  
Passing the encoder test implies that the FISO encoder is functioning and can properly route  
the acquired data to the acquisition memory FISO RAM. Also, passing this test implies that  
the post-store counter on the acquisition ICs is functioning.  
8–13  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Theory of Operation  
Analyzer Tests (Analy PV)  
Resource Test The pattern, range, edge, and glitch recognizers are tested and verified.  
First, the test register is verified for correct operation. Next, the pattern comparators are  
tested to ensure that each bit in the recognizer memory location as well as the logic  
driver/receiver are operating. The edge and glitch pattern detectors are then verified in a  
similar manner. The range detectors are verified with their combinational logic to ensure  
that the in- and out-of-range conditions are recognized.  
Passing the resource test implies that all of the pattern, range, edge, and glitch resources are  
operating and that an occurrence of the pattern, edge, or glitch of interest is recognized. Also,  
passing this test implies that the range recognizers will detect and report in- and out-of-range  
acquisition data to the sequencer or storage qualifier. The drivers and receivers at the  
recognizer input and output pins of the acquisition IC are also checked to be sure they are  
functioning.  
Sequencer Test The sequencer, the state machine that controls acquisition storage, is  
tested by first verifying that all of the sequencer registers are operating. After the  
registers are checked, the combinational logic of the storage qualification is verified.  
Then, both the occurrence counter and the sequencer level counter are checked.  
Passing the sequencer test implies that all 12 available sequence levels are functioning and  
that all possible sequence level jumps can occur. Also, passing this test implies that  
user-defined ANDing and ORing of storage qualified data patterns will occur, and that the  
occurrence counter that appears at each sequence level is functioning.  
Clock Generator Test The master clock generator on the acquisition ICs is tested by  
first checking the operation of the clock optimization circuit. The state acquisition clock  
paths are then checked to ensure that each state clock and clock qualifier are operating  
by themselves and in all possible clock and qualifier combinations. The timing acquisition  
optimization circuit is then operationally verified. Finally, the timing acquisition  
frequency divider (for slower timing sample rates) is checked.  
Passing the clock generator test implies that each acquisition IC can generate its own master  
clock whether the clock is generated using a combination of external clocking signals (state  
mode) or internal sample clock signals (timing mode).  
Data Input Inspection  
The data input inspection allows a user to verify that all of the data and clock/data pipelines  
are operational. When the data input inspection test is selected, a test signal is fed to the test  
input pins of all 9-channel comparators. The test menu displays the activity indicators for all  
data and clock/data channels, which should show transitioning data signals on all channels.  
The data input inspection is not an active part of the performance verification. However, the  
test is useful for identifying failed channels in order to temporarily work around the problem  
until the logic analyzer module can be sent to an Agilent Technologies service center for  
repair.  
8–14  
Download from Www.Somanuals.com. All Manuals Search And Download.  
GPIB (Optional)  
The General Purpose Interface bus (GPIB) is Agilent Technologies’ implementation  
of IEEE Standard 488-1978, "Standard Digital Interface for Programming  
Instrumentation." GPIB is a carefully defined interface that simplifies the integration  
of various instruments and computers into systems. The interface makes it possible  
to transfer messages between two or more GPIB compatible devices. GPIB is a  
parallel bus of 16 active signal lines divided into three functional groups according to  
function.  
Eight signal lines, called data lines, are in the first functional group. The data lines  
are used to transmit data in coded messages. These messages are used to program  
the instrument function, transfer measurement data, and coordinate instrument  
operation. Input and output of all messages, in bit parallel-byte serial form, are also  
transferred on the data lines. A 7-bit ASCII code normally represents each piece of  
data.  
Data is transferred by means of an interlocking "Handshake" technique which permits  
data transfer (asynchronously) at the rate of the slowest active device used in that  
transfer. The data byte control lines coordinate the handshaking and form the  
second functional group.  
The remaining five general interface management lines (third functional group) are  
used to manage the devices connected to the GPIB. This includes activating all  
connected devices at once, clearing the interface, and other operations.  
The following figure shows the connections to the GPIB connector located on the  
rear panel.  
GPIB Interface Connector  
8–15  
Download from Www.Somanuals.com. All Manuals Search And Download.  
RS-232C(Optional)  
The logic analyzer interfaces with RS-232C communication lines through a standard  
25 pin D connector. The logic analyzer is compatible with RS-232C protocol. When a  
hardwire handshake method is used, the Data Terminal Ready (DTR) line, pin 20 on  
the connector, is used to signal if space is available for more data in the logical I/O  
buffer. Pin outs of the RS-232C connectors are listed in the following table.  
RS-232C Signal Definitions  
Pin  
Number  
Function  
RS-232C  
Standard  
Signal Direction and Level  
1
2
Protective Ground  
AA  
BA  
Not applicable  
Transmitted Data (TD)  
Data from Mainframe  
High = Space = "0" = +12 V  
Low = Mark = "1" = 12 V  
3
4
5
6
Received Data (RD)  
Request to Send (RTS)  
Clear to Send (CTS)  
Data Set Ready (DSR)  
BB  
CA  
CB  
CC  
Data to Mainframe  
High = Space = "0" = +3 V to +25 V  
Low = Mark = "1" = 3 V to 25 V  
Signal from Mainframe  
High = ON = +12 V  
Low = OFF = 12 V  
Signal to Mainframe  
High = ON = +3 V to +12 V  
Low = OFF = 3 V to 25 V  
Signal to Mainframe  
High = ON = +3 V to +25 V  
Low = OFF = 3 V to 25 V  
7
8
Signal Ground  
AB  
CF  
Not applicable  
Data Carrier Detect (DCD)  
Signal to Mainframe  
High = ON = +3 V to +25 V  
Low = OFF = 3 V to 25 V  
20  
23  
Data Terminal Ready (DTR)  
Data Signal Rate Selector  
CD  
Signal from Mainframe  
High = ON = +12 V  
Low = OFF = 12 V  
CH/CI  
Signal from Mainframe  
Always High = ON = +12 V  
8–16  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Centronix  
The logic analyzer interfaces with Centronix (parallel printer) communication lines  
through a standard 25 pin D connector. The logic analyzer is compatible with  
Centronix protocol. BUSY is used to indicate when data can be transfered from the  
logic analyzer to the printer. DATASTROBE is used to synchronize data  
transmissions. Pin outs of the Centronix connector are listed in the following table.  
Centronix Signal Definitions  
Pin  
Number  
Function  
Centronix  
Standard  
1
Synchronous signal that is used for data transfer  
Logic analyzer data (LSB)  
STROBE  
DATA0  
DATA1  
DATA2  
DATA3  
DATA4  
DATA5  
DATA6  
DATA7  
ACKNLG  
BUSY  
2
3
Logic analyzer data  
4
Logic analyzer data  
5
Logic analyzer data  
6
Logic analyzer data  
7
Logic analyzer data  
8
Logic analyzer data  
9
Logic analyzer data (MSB)  
10  
11  
12  
13  
14  
15  
16  
17  
18 - 25  
Signal used to indicate that data has been received  
Signal used to indicate that the printer is busy  
Signal used to indicate that the printer is out of paper  
Signal that indicates that the printer is on-line  
Signal used to select the autofeed function  
Signal that indicates command or data error  
Signal used to initialize the printer  
Signal used to select the direction of the bi-directional bus  
Ground  
PERROR  
SELECT  
AUTOFD  
FAULT  
INIT  
SELECTIN  
GND  
8–17  
Download from Www.Somanuals.com. All Manuals Search And Download.  
8–18  
Download from Www.Somanuals.com. All Manuals Search And Download.  
DECLARATION OF CONFORMITY  
according to ISO/IEC Guide 22 and EN 45014  
Agilent Technologies  
Manufacturer’s Name:  
1900 Garden of the Gods Road  
Colorado Springs , CO 80901  
U.S.A.  
Manufacturer’s Address:  
Declares, That the product  
Product Name:  
Logic Analyzer  
1664A  
Model Number(s):  
Product Options:  
All  
Conforms to the following Product Specifications:  
IEC 348 / HD 401  
Safety:  
UL 1244  
CSA - C22.2 No. 231 Series M-89  
CISPR 11:1990 /EN 55011 (1991): Group 1 Class A  
IEC 801-2:1991 /EN 50082-1 (1992): 4 kV CD, 8 kV AD  
IEC 801-3:1984 /EN 50082-1 (1992): 3 V/m  
EMC:  
IEC 801-4:1988 /EN 50082-1 (1992): 1 kV  
Supplementary Information:  
The product herewith complies with the requirements of the Low Voltage  
Directive 73/23/EEC and the EMC Directive 89/336/EEC.  
Colorado Springs, Sept 16, 1994  
John Strathman, Quality Manager  
European Contact: Your local Agilent Technologies Sales and Service Office or Agilent Technologies GmbH,  
Department ZQ / Standards Europe, Herrenberger Strasse 130, 71034 Böblingen Germany (FAX: +49-7031-143143)  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Safety  
Safety Symbols  
Copyright Agilent Technologies  
Service instructions are for  
trained service personnel. To avoid  
dangerous electric shock, do not  
perform any service unless  
1987–2000  
This apparatus has been designed  
and tested in accordance with IEC  
Publication 348, Safety  
All Rights Reserved.  
Instruction manual symbol: the  
product is marked with this symbol  
when it is necessary for you to  
refer to the instruction manual in  
order to protect against damage to  
the product.  
qualified to do so. Do not attempt  
internal service or adjustment  
unless another person, capable of  
rendering first aid and  
Requirements for Measuring  
Apparatus, and has been supplied  
in a safe condition. This is a Safety  
Class I instrument (provided with  
terminal for protective earthing).  
Before applying power, verify that  
the correct safety precautions are  
taken (see the following warnings).  
In addition, note the external  
markings on the instrument that  
are described under "Safety  
Reproduction, adaptation, or  
translation without prior written  
permission is prohibited, except as  
allowed under the copyright laws.  
resuscitation, is present.  
If you energize this instrument  
by an auto transformer (for voltage  
reduction), make sure the common  
terminal is connected to the earth  
terminal of the power source.  
Document Warranty  
The information contained in this  
document is subject to change  
without notice.  
Hazardous voltage symbol.  
Agilent Technologies makes no  
warranty of any kind with  
regard to this material,  
including, but not limited to,  
the implied warranties or  
merchantability and fitness for  
a particular purpose.  
Agilent Technologies shall not be  
liable for errors contained herein  
or for incidental or consequential  
damages in connection with the  
furnishing, performance, or use of  
this material.  
Complete product warranty  
information is given at the end of  
this manual.  
Whenever it is likely that the  
ground protection is impaired, you  
must make the instrument  
inoperative and secure it against  
any unintended operation.  
Symbols."  
Warning  
Earth terminal symbol: Used to  
indicate a circuit common  
connected to grounded chassis.  
Before turning on the  
instrument, you must connect the  
protective earth terminal of the  
instrument to the protective  
conductor of the (mains) power  
cord. The mains plug shall only be  
inserted in a socket outlet  
Do not operate the instrument  
in the presence of flammable  
gasses or fumes. Operation of any  
electrical instrument in such an  
environment constitutes a definite  
safety hazard.  
W A R N I NG  
The Warning sign denotes a  
hazard. It calls attention to a  
procedure, practice, or the like,  
which, if not correctly performed  
or adhered to, could result in  
personal injury. Do not proceed  
beyond a Warning sign until the  
indicated conditions are fully  
understood and met.  
provided with a protective earth  
contact. You must not negate the  
protective action by using an  
extension cord (power cable)  
without a protective conductor  
(grounding). Grounding one  
conductor of a two-conductor  
outlet is not sufficient protection.  
Do not install substitute parts or  
perform any unauthorized  
modification to the instrument.  
Capacitors inside the instrument  
may retain a charge even if the  
instrument is disconnected from  
its source of supply.  
Only fuses with the required  
rated current, voltage, and  
specified type (normal blow, time  
delay, etc.) should be used. Do not  
use repaired fuses or  
short-circuited fuseholders. To do  
so could cause a shock of fire  
hazard.  
Use caution when exposing or  
handling the CRT. Handling or  
replacing the CRT shall be done  
only by qualified maintenance  
personnel.  
C A U T I O N  
The Caution sign denotes a hazard.  
It calls attention to an operating  
procedure, practice, or the like,  
which, if not correctly performed  
or adhered to, could result in  
damage to or destruction of part or  
all of the product. Do not proceed  
beyond a Caution symbol until the  
indicated conditions are fully  
understood or met.  
Agilent Technologies  
P.O. Box 2197  
1900 Garden of the Gods Road  
Colorado Springs, CO 80901  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Product Warranty  
Exclusive Remedies  
About this edition  
The following list of pages gives  
the date of the current edition and  
of any changed pages to that  
edition.  
This Agilent Technologies product  
has a warranty against defects in  
material and workmanship for a  
period of one year from date of  
shipment. During the warranty  
period, Agilent Technologies will,  
at its option, either repair or  
replace products that prove to be  
defective.  
The remedies provided herein are  
the buyer’s sole and exclusive  
remedies. Agilent Technologies  
shall not be liable for any direct,  
indirect, special, incidental, or  
consequential damages, whether  
based on contract, tort, or any  
other legal theory.  
This is the first edition of the  
Agilent Technologies 1664A  
Logic Analyzer Service Guide.  
All pages original edition.  
Publication number 01664-97005  
Printed in USA.  
Edition dates are as follows:  
Second edition, January 2000  
First edition, August 1994  
Assistance  
For warranty service or repair, this  
product must be returned to a  
service facility designated by  
Agilent Technologies.  
Product maintenance agreements  
and other customer assistance  
agreements are available for  
Agilent Technologies products.  
New editions are complete  
revisions of the manual. Update  
packages, which are issued  
between editions, contain  
additional and replacement pages  
to be merged into the manual by  
you. The dates on the title page  
change only when a new edition is  
published.  
For products returned to Agilent  
Technologies for warranty service,  
the Buyer shall prepay shipping  
charges to Agilent Technologies  
and Agilent Technologies shall pay  
shipping charges to return the  
product to the Buyer. However,  
the Buyer shall pay all shipping  
charges, duties, and taxes for  
products returned to Agilent  
For any assistance, contact your  
nearest Agilent Technologies Sales  
Office.  
Certification  
Agilent Technologies certifies that  
this product met its published  
specifications at the time of  
shipment from the factory. Agilent  
Technologies further certifies that  
its calibration measurements are  
traceable to the United States  
National Institute of Standards and  
Technology, to the extent allowed  
by the Institute’s calibration  
A software or firmware code may  
be printed before the date. This  
code indicates the version level of  
the software or firmware of this  
product at the time the manual or  
update was issued. Many product  
updates do not require manual  
changes; and, conversely, manual  
corrections may be done without  
accompanying product changes.  
Therefore, do not expect a  
Technologies from another country.  
Agilent Technologies warrants that  
its software and firmware  
designated by Agilent  
Technologies for use with an  
instrument will execute its  
programming instructions when  
properly installed on that  
instrument. Agilent Technologies  
does not warrant that the  
operation of the instrument  
software, or firmware will be  
uninterrupted or error free.  
facility, and to the calibration  
facilities of other International  
Standards Organization members.  
one-to-one correspondence  
between product updates and  
manual updates.  
Limitation of Warranty  
The foregoing warranty shall not  
apply to defects resulting from  
improper or inadequate  
maintenance by the Buyer,  
Buyer-supplied software or  
interfacing, unauthorized  
modification or misuse, operation  
outside of the environmental  
specifications for the product, or  
improper site preparation or  
maintenance.  
No other warranty is expressed or  
implied. Agilent Technologies  
specifically disclaims the implied  
warranties or merchantability and  
fitness for a particular purpose.  
Download from Www.Somanuals.com. All Manuals Search And Download.  

2Wirer HDCR 1230G User Manual
Acoustic Research Radio ARIR150 User Manual
Acoustic Research Radio ARIR201 User Manual
Adaptec Network Card Wireless Access Point User Manual
Aiphone Intercom System JA DGV User Manual
Altec Lansing Speaker System ACS21W User Manual
AMX Network Card TX CTB User Manual
ATI Technologies Stereo Amplifier ATP 8500 User Manual
Axis Communications Security Camera dual ptz network camera User Manual
Barco Network Router DVI 16X16 User Manual