E8770-90030
Contents
1. PACKARD ES H H Packard Multicom 111 5 Ins computer shelf HP 40101A e HE O HP 34401 HP 33120 9 Dmm 06 oo aeoosuga 4 99 sosbess au 9 sesases 8 00 8 lol HP1135cPpu 00 H E6198A EFT Switch Unit 15 Flat Panel Display ae HP E6198 Switch Load Unit 2 0000 Keyboard Tray gt EFT Switch Unt HP E6198 Switch Load Unit 1 gt Express Connect o HP E8401 VXI Mainframe 0 HP E8401A 4 lo VXI mainframe o reme 8 888 959 9 000 OO0 po v messy COO o 000 000 Power Supply OOQ L 4 9 000 000 Q I J U y J Front view Rear View Figure 1 2 Typical Agilent E8786B System Chapter 1 System Introduction 13 System Software 14 System Introduction The Agilent TS 5400 Series IIB system controller uses the Microsoft Windows XP9 operating system and Agilent TestExec SL software which is pre installed on your system controller Refer to the Agilent TS 5400 Online Help and the TestExec SL Online Help both available from the TestExec SL help m2. Series Multicom III s computer shelf Agilent 40101A a oo 9 Agilent 34401 5 Agilent 33120 m Agent 1 1520 90 oo 9 esesese 8 09 LB a Flat Panel 3 9 Displ 2 splay O 4 O fase i Keyboard Tray o E6198A ues 5 EFE Swich Unit gt Agilent E6198A Switch Load Unit Agilent Technologies Soros Test Systom 18200 Agilent 40107A E8401A VXI mainframe Agilent E8401 VXI mainframe lO 9 5 8 E IO OOO 0 Em Power Supply 000 000 000 000 000 lO Power Supply 000 000 000 000 n 000 000 g U U Front view Rear View Figure 1 1 Typical Agilent E8780B System 12 System Introduction Chapter 1 UE TS 5400 Cu
3. P2 Aux1 2 Auxi Row1 Aux2 Aux2 Row2 Aux3 Aux3 Row3 Aux4 Aux4 Row4 96 Pin DIN C Rear Aux Access J2 Aux30 2 Aux30 Row30 Aux31 Aux31 Row31 Aux32 Aux32 Row32 UUT Common 32 x 4 Measurement Matrix Matrix Relay Detail Column M r Row Figure 1 6 Agilent E8793A Pin Matrix Module Chapter 1 96 Pin DIN C Row Aux amp UUT Common To UUT System Introduction 21 Load Cards Agilent E6175A 8 Channel High Current Load Card Agilent E6176A 16 Channel High Current Load Card Agilent E6177A 24 Channel Medium Current Load Card Agilent E6178A 8 Channel Heavy Duty Load Card 22 System Introduction The Agilent TS 5400 Series test systems provide modular design and flexible load switching capabilities Available Agilent load cards installed in the Switch Load Unit are Agilent E6175A 8 Channel High Current Load Card Agilent E6176A 16 Channel High Current Load Card Agilent E6177A 24 Channel Medium Current Card Agilent E6178A 8 Channel Heavy Duty Load Card The Agilent E6175A with current sensing is intended to be used with loads mounted inside the switch load unit This card provides 8 high current load connections Current sense resistors are supplied with customer installable LEM current sense capability as an option Bridge load configurations are supported with thi
4. 85 E6170 61615 DAC to Custom Card Cable seen 86 E6189 61600 Power Supply Power 87 E6230 61603 Heavy Duty Load Card 88 E6247 61601 Cable Digitizer 56 89 E8770 61601 External Power 1 90 Chapter 5 System Diagnostics REC 91 Chapter Contents due Re etie eee aa a 91 SUpPOLt Strategy cis ener equ nt uu eet ide Base e 91 Di gnostics Strategy GI po pedes 92 Using Agilent TestExec SL to Run the 93 Executing the Testplan i133 inii eee 93 Hardware Configuration Details 93 Test Exec tion Details i um E RE eie e 95 Chapter 6 Calibration and Preventive Maintenance eere eee esee eene 97 Calibration OVErview 25 niea ette nenne ER ert deta apd setae tap A ie eed e teet 97 Products Requiring Calibration 97 System Adjustments oiii fee tre eet teret He HEC EHE 98 Proc dure Heg ter dee 98 AutoAdj Test Codes and 104 Verification Procedures ete HERR deos 107 Append
5. 66 E3750 61612 2x1 Coax to 2x1 Drain Hi 67 E3750 61613 Serial Interface Cable eese 68 E3750 61614 8 Channel Load Card 69 E3750 61615 16 Channel Load Card Cable eee 70 E3750 61621 E6170 61612 Male BNC Coax to 3x1 Isolated Instrument Cable 71 E3750 61624 8 Channel Heavy Duty Load Card Cable 30A 72 E3750 61625 24 Channel Medium Power Load Card Cable 73 E3750 61626 Dual 24 Channel Load Card 75 E3750 61627 Power Supply 2 77 E3751 61601 E6170 61610 64 Conductor Twisted Pair 78 E3857 61613 Rack On Off Switch to PDU Cable 79 E6170 61603 E8792 93 to MAC Panel 80 E6170 61604 E8794 to Mac Panel or Express Connect and SLU Interconnect Cable81 E6170 61606 Power Bus Jumper Cable seen 82 E6170 61609 External Power Cable 6653 6673 83 E6170 61611 SLU to UUT Low Current Power Supply Cable 6628 6643 84 E6170 61613 DAC to Pin Card Aux
6. E3750 61625 24 Medium Power Load Cable NOILISOd YOLISNNOD e qeo 96919 08453 WIX 032 Vd 335 EM y MJA SIHL 30 3953 SI dOl 3LON 73 System Cables and Connectors Chapter 4 Continued on next page E3750 61625 Continued Chapter 4 9 peo jauueu2 pz 87 52919 06 ES 97 3 v18 Sy 77 7 32 18 0EY 27 923 17 922 07 82v 6E gad 923 gE 92 LE 3 v18 92 723 SE NMOS 72 7E 32v 18 day 223 ZE NMO X9 222 be DE 934 023 62 NMONS 02 92 02v 42 913 92 9 2 52 32919 gv 72 9 3 9 2 44 3 v18 919 12 713 02 7 2 32v18 YW 8 034 2 3 LV 219 9 21 18 ev SL 013 71 0 2 EL 32v 18 oiv 83 LL 8 OL 22 18 9v 60 933 93 184355 31872 80 93 1130 40 9v 90 73 50 NMONS 72 70 3 v18 7y 23 20 22 0 18941 50103 9
7. 7 7 7 7 7 7 7 7 77 7 7 7 7 7 7 7 7 77 7777 7 7 7 7 7 Figure 2 4 Agilent E1418A Terminal Module Connector Pinout 38 System Instrument Configuration Chapter 2 VXI Tec hnology The Agilent E6183A contains an VXI Technology E1563A Digitizer and cables The E1563A Digitizer has two channels that allows simultaneous E1563A 2 Channel measurements of two waveforms for example the voltage and current 800 ka s Digitizer waveform of the load signal In the factory default configuration Channel 1 provides direct access to the attenuator output Connecting the digitizer to ADC Module this input allows the user to digitize a high voltage like an inductive flyback while maintaining the resolution to also measure the driver s saturation voltage all in a single measurement cycle for high throughput testing Channel 2 input is connected to the interconnection column ABus Connecting the digitizer to this input allows it to be routed to any input of the UUT Switch Jumper Settings Figure 2 5 shows the E1563A logical address switch with the switch shown in the factory setting Set the logical address to match the VXI mainframe slot number for a one mainframe system For a two mainframe system set to the slot number plus 16 if in mainfra
8. 1410008 31V2IQNI 9 QN3S 01 315 N3S 01 1S3n03N 13S QNNOYD 1 915 AQV34 190 3 13238 LIWSNVUL 123130 33198 1 0 141 842530 12V1NO2 CQ f Chapter 4 68 System Cables and Connectors E3750 61614 8 Channel Load Card Cable pe peo 9 M 71919 09 23 S E 219 9499 MJA SIHL JO 3015 NO 51 801 SLON 69 System Cables and Connectors Chapter 4 E3750 61615 16 Channel Load Card Cable ee Chapter 4 70 System Cables and Connectors E3750 61621 E6170 61612 Male BNC Coax to 3x1 Isolated Instrument Cable Isolated Instruments BNC E3750 61621 1200mm E6170 61612 2000mm DRAIN H SIGNAL T 3 E 1 NO CONNECT 4 System Cables and Connectors 71 E3750 61624 8 Channel Heavy Duty Load Card Cable 30A e lt E o z OF THIS VIEW E3750 61624 30 Amp Load Card Cable SD nf x Orcrrrrrig Zooococoocotou REMOTE SEI REMOTE SENSE PWR SUPPLY 72 System Cables and Connectors Chapter 4
9. eene 52 Connecting Instrument Input s to the Measurement Control Module 53 Customizing the Agilent TestExec SL Software to Accommodate Additional Instrumentation ci eno eid he eri en ee EQ EP ute ure dE Ree 54 Installing Optional Switching 54 Adding Instruments to the system ust 55 Modifying the system ust 55 Using the System Configuration 55 Using the Topology Editor 55 Instrument Reset 57 Reset Invocation ri efte erre t dae eeu 57 Specifying a Reset Routine 57 Instrument cete ae te te tee 59 Standard Functions in Instrument Handlers 59 Naming Conventions Used in Instrument Handlers 61 Chapter 4 System Cables and Connectors 63 Chapter Contents en eret ore tere ree E b e et a ta tret 63 Cable Identification uie e Cb 63 1066 61620 E3750 61603 Twinax 3x1 to 64 E1072 61620 E3750 61602 Twinax 3x1 to 3x1 esee 64 E1400 61605 1x6 ABus Ribbon Cable eee 64 E3750 61604 E6170 61614 Male BNC Coax to 3x1 65 E3750 61608 96 Pin 64 Conductor to 96 Pin DIN
10. 5555599099509 0000005099000 0900006000900 9909000000000 2 5505000000000 9900090969090 Q 3 0000006000000 0000005090000 E 0990000000990 0000000000000 E 2559955099969 2 lt monuuOr xaxz ooo 123456 128456 128456 128456 Test Connectors TC2 123456 monuu 123456 LICICIDCICICICICICICICICI 000000000 monuu 000000000000 5000000000000 0000000000000 5400 Il Test System Interface Series Connections to Pin Matrix Modules Power Supplies and other instruments o 2 E D lt Connection for 8 Channel Heavy Duty Load Cards Figure 1 7 Express Connect Test System Interface 24 System Introduction Chapter 1 Mass Interconnect Mac Panel To optional MCM Automotive Serial Protocol and Load Box To Pin Matrix The Mac Panel Mass Interconnect uses a high point count mass interconnect fixture Agilent E3722A and interchangeable Interface Test Adapter panels Figure 1 8 shows the Mac Panel Mass Interconnect features Refer to the Agilent E6170 Mass Interconnect System User s Manual supplied with your system for detailed information To Agilent E1418A A D Converter 16 Channel Load C
11. NO 011 201 IJYIM 74 System Cables and Connectors E3750 61626 Dual 24 Channel Load Card Cable peo1Jewog jauueuo gr 96919 09453 i W130 303 2 39Vd 335 e NOILISOd 11508 023NN02 0123NN02 8 3787 1ueujeoe daJ 10 Wed y 5 o qeo siu jeued DYN 941 jauueuo pz S JO9UUOD 9ejqeo siu 91oN MJA SIHL 40 5 NO SI 401 3LON Continued on next page 75 System Cables and Connectors Chapter 4 E3750 61626 Continued ued peo Jewog j ouueu2 gp 95919 06483 ATdW3sSV 318 2 97 034 17 NMO g 97 32v18 57 034 083 77 0682 7 v18 otv 44 9823 17 2 25 922 07 82 923 8E 922 LE 2v18 9cv 9E 039 723 SE NMONS 702 7 v18 038 203 NMONH 22 eov 0 034 053 6c NMO g 022 82 2v18 ozv 42 034 8 3 92 NM
12. Table 2 1 Two VXI Mainframe Algorithm Instrument Module Slot LADD Agilent E1411B Digital Multimeter 11 27 Agilent E6173A Arbitrary Waveform Generator 10 26 optional Agilent E6174A Event Detector optional 9 25 Agilent E1418A 16 Channel D A Converter optional 8 24 VXI Technology E1563A 2 Channel A D Converter 7 23 optional Agilent E1333A 3 Channel Counter or other optional 6 22 module if slot is empty Mainframe 2 IEEE 1394 VXI Interface Card Firewire 0 32 Agilent E3173A Arbitrary Waveform Generator 1 33 optional Agilent E6174A Event Detector optional 2 34 Agilent E1418A 16 Channel D A Converter optional 3 35 VXI Technology E1563A 2 Channel A D Converter 4 36 optional Agilent E1333A 3 Channel Counter or other optional 5 37 The optional modules for mainframe 1 are loaded right to left with no blank slots between the modules the optional modules for mainframe 2 are loaded left to right with no blank slots between the modules Same type multiple modules to be loaded adjacent to one another Optional module types not present are to be replaced with the next lower priority module use the following order to add optional modules Agilent E6173A Arbitrary Waveform Generator Agilent E6174A Event Detector Agilent E1418A 16 Channel D A Converter VXI Technology E1563A 2 Channel A D Converter Agile
13. Glossary 133 at a certain predetermined voltage Multiplex A more restricted version of a matrix Any row relay can be connected to any column but only one can be connected at a time Multiplexed Detectors And Sources This consists of the E6171A Measurement Control Module the 32 Pin Switching Cards and assorted GPIB or VXIbus based instruments and detectors The Measurement Control Module switches the various instruments into and out of the test circuits as necessary to perform the appropriate measurements with each clock cycle of a test Multiple V XIbus extender MXIbus modules which allow addressing more than VXI mainframe a system N Normally Closed switch contacts A Form C Single Pole Double Throw switch has two possible states The default or unpowered state is its normal state The two terminals on the switch are therefore called normally open or normally closed Normally Open switch contacts See NC Node OAR Any electrical point in the topology Each node has a name or label See alias See Open Relays 134 Glossary One shot Mode The Measurement Control Module MCM has an internal timer counter that is primarily used to time the open close of the MCM relays It can also be used as a trigger source As a trigger it can either in either of two modes it can run continuously or it can be set to generate a single or one shot p
14. Inst4 D p 1 1 2 Inst5 me 1 i 7 Inst6 1 i Inst7 I I I I i i Inst8 T T Er Inst9 rt I I i 1 Inst10 f D P1 Instt1 Decoding and Driver Inst12 Circuits Inst13 I I Inst14 i I I I Lj i 2 115115 p gd 1 l n i i Inst16 D 1 Ls i i n 2 092209204 J3 1 Abus2 4 Abusi Abus3 lt Disconnect Relays c Bypass Relays 1 esc A Rowi Aux2 i Aux2 i 1 2 Aux3 Aux3 i Aux4 2 4 ___ 4 i P2 J2 1 3 i i Aux30 Aux30 Row30 Aux31 ___ 1 i Row31 Aux32 i 1 Aux32 __ 32 UUT Common Matrix Relay Detail Column Figure 1 5 E8792A Pin Matrix Module Row 96 Pin DIN C Backplane Access To Switch Load Unit 96 Pin DIN C Row Aux amp UUT Common To UUT System Introduction 19 Agilent E8793A 32 Pin Matrix Module 20 System Introduction Note For applications requiring more than 32 channels the E8793A Pin Matrix card contains a 4x32 switching matrix no instrument matrix and may be used for increasing channels in increments of 32 The Analog Bus is daisy chained from card to card to route the measuring and source instruments to N
15. manual entry in the AutoAdj action in the Parameters section of the autoadj tpa testplan form 3 Set manual to 0 default to only perform the system wide adjustment set manual to 1 to perform both the system wide adjustment AND the Agilent E6171A B manual adjustments 4 When the autoadj tpa testplan executes the Test AutoAdj Query test the system prompts for a YES or NO response Enter YES to execute the Test Auto Adjust action Remove any test fixture before running autoadj tpa or the autoadj action action is part of autoad j tpa 98 Calibration and Preventive Maintenance Chapter 6 Adjustment Procedure 1 Agilent E6171A modules require the simple calibration fixture shown for Agilent E6171A in Figure 6 1 Build the test fixture by adding leads to an Agilent Modules 0699 4532 resistor as shown The resistor is a 1000 0 1 tolerance 4 Watt low temperature coefficient precision resistor Adding the extra leads allows for 4 Wire Ohms resistance measurements Keep all lead lengths as short as possible HP Part Number 0699 4532 1000 0 196 4 W Precision Resistor Tay Test System Poner ue e 2 7 SND Ribbon Cable X P Figure 6 1 Agilent E6171A Calibration Fixture 2 When instructed by the autoadj tpa testplan remove the ribbon cable from the J2 connector on the front of the Agilent E6171A module Connect the test fixture ribbon cable to the J2 connector on t
16. Information defined at the fixture layer includes Definitions of wires in the fixture Definitions for the names of any edge connectors Definitions for any electronics inside the fixture that is a part of your switching strategy Glossary 139 Information defined at the layer includes e Definitions of convenient aliases for test points on DUT such as TP1 U Unit Under Test UUT The automotive module or printed circuit board being tested Also known as Device Under Test DUT UUT Common A fifth column alongside the ABus in the Measurement Control Module and 32 Pin Matrix Module that connects to the UUT common V An acronym for the concept of sourcing voltage and measuring the resulting current or conversely sourcing a current and measuring the resulting voltage VISrcHi and VISrcLo VISrcHi is the signal side of the V I Source in the Measurement Control module to the ABus and VISrcLo is the ABus path to ground The amplifier is an isolated source Variant A mechanism that lets you specify which named variation on a test is executed when you run a test plan Each variant lets you Use the same sequence of tests with different parameters and limits For example you may want to specify different limits for various temperatures at which the tests are exe cuted Control which set of tests is executed for a given test plan For example the set of tests used by Quali
17. Testplan Editor DgnS2Mcm Dg bel Listing Profiler Results gt Symbol Tables Test Execution Details Instrument Panels Problem List test Relays 2 2 test Matrix 1 relay paths test Matrix 1 shorted relays test Matrix 2 relay paths test Matrix 2 shorted relays test Matrix relay paths test Matrix shorted relay 3 Click on Hardware Configuration Actions Symbol T ables Testplan Audit Testplan Tests Adjacencies Node Labels Instruments Hardware Configuration gt est Parameters cumentation Actions for Test System Re Sivitches globalReset 4 Click on System Layer Figure 5 1 Selecting the system ust Listing Chapter 5 System Diagnostics 93 Agilent TestExec SL Listing File Edi Insert View Debug Options Window Help Wire ABus4 Description Fourth analog bus Connects to mem ABus4 Connects to matrixi iBus4 Module Description ame Location of DLL used Module Name MODULES po um for the Module Module Description HP E6171 Measurement Control Module in s 1 at address 17 DLL C Program ead Tae SL bin hwhmem dll VXI Mainframe Number Parameters VXI Cagef 1 VXI Slot 1 lt __ Location of Module in Mainframe Logical ddress 17 p SkipGlobalReset Module s Logical Address Module drm Description
18. M Loads o Relays shown energized Appendix A Isense Isense Isense Isense J1 Power Return xz Power Source Simplified Load Card Figure A 1 DC Voltage Accuracy and Driver Saturation Test Capability Example Test Capabilities and System Requirements 111 System Capability The system capability output driver current leakage test uses the Agilent i E6171 Measurement Control Module Force Voltage Measure Current Driver Current functionality As shown in Figure 2 the DvmHi input is connected Leakage Sample through a disconnect relay to the V I source The output of the V I source is connected through ABus4 and the Agilent E6172A 32 Pin Matrix Module row 32 The output driver transistor is biased open turned off and the expected leakage is less than 1 milliampere The accuracy of the Agilent E6171 Measurement Control module may be determined from the Agilent E6171 Measurement Control Module User s Manual Appendix A Using the section headings identify the module subfunction Voltage Source Low Voltage Force V measure I Current Sense accuracy 2 mA range That Agilent E6171 specification is 0 3 of reading 0007 mA The voltmeter accuracy is included in the preceding specification and does not need to be added in the following calculated system accuracy capability calculation The calculated system accura
19. of this manual The TS 5400 system can contain either one or two VXI mainframes The following list shows the slot and logical addresses LADD for one V XI mainframe slots O to 12 as numbered from left to right Slot 0 E8491 firewire or VXI MXI 2 LADD default Slot 1 E6171B Measurement Control Module LADD 17 Slots 11 2 optional instruments LADD c slot ff Optional Instruments are loaded right to left starting in slot 11 without blanks according to the One Mainframe Optional Instrument Priority Chart below For these instruments the LADD is set to the slot number Multiple modules of the same type are loaded adjacent to one another Instrument types not present in the following list are replaced with the next instrument on the priority list E1411B DMM E6173A Arbitrary Waveform Generator E1418A 8 16 Channel DAC E1563A 2 Channel Digitizer E6174A Event Detector E1333A Counter Other optional VXI instrumentation RUD Table 2 1 shows the slot and logical address LADD algorithm for two VXI mainframes slots 0 to 13 as numbered from left to right The second mainframe contains only optional instruments modules Table 2 1 Two VXI Mainframe Algorithm Instrument Module Slot LADD Mainframe 1 IEEE 1394 VXI Interface Card Firewire or 0 16 VXI MXI 2 Agilent E6171B Measurement Control Module 1 17 32 System Instrument Configuration Chapter 2
20. 0 Generate Wires And Aliases Cancel 4 Click on OK New Open 5 Click on Save to save the file Save As 2 Click on the InGlobalReset value and change the value to 1 to enable the reset routine or 0 to disable the routine Settings to save the file under a different name and or directory Figure 3 1 Enabling Global Reset Using the System Configuration Editor 58 Customizing the System Chapter 3 Instrument Handlers Note Standard Functions Chapter 3 in Instrument Handlers Instrument Handlers are a layer of software between Agilent TestExec SL and standard instrument drivers see Figure 3 2 In general Instrument Handlers are designed to be called from C C code action Instrument Handler Driver Figure 3 2 Software Layers Instrument handlers contain functions written in C code that are organized by instrument type and function and require parameters relevant to the function For example the call to set up triggering for a voltmeter is dmmConfTrigIn dmm trigselect count delay Function dmmConfTrigIn accepts four parameters dmm trigselect count and delay The generic name of the function is Conf TrigIn and the name of the instrument in this case dmm is added as a prefix to form the full specific name of the function Instrument handlers are maintained constant in different TS 5400 software releases which
21. 1 or to the slot number plus 32 if in mainframe 2 Refer to VXI Module Locations And Logical Addresses on page 32 The Interrupt Priority is always set to 1 mE zs 000000 Logical Address Switch 00000000 s 000000 Logical Address Factory Default 48 shown TS 5430 5450 One Mainframe Slot TS 5450 Two Mainframes Slot 16 or Slot 32 if in Mainframe 0 OPEN EIS nn OPEN Switch Set to 0 Off CLOSED Switch Set to 1 On 1 CLOSED E Figure 2 1 Agilent E1333A Universal Counter Module and Cables Chapter 2 System Instrument Configuration 35 Agilent E1411B Digital Multimeter Module Switch Jumpers Settings The Agilent E1411B Digital Multimeter DMM Module comes standard with the Agilent TS 5400 System The DMM measures dc voltage ac rms voltage and ohms including 4 wire ohms It can also measure temperature by using thermistors In addition to test measurements the DMM serves as the system reference and is used to calibrate the V I functions The DMM input is balanced and differential Figure 2 2 shows the Agilent E1411B logical address switch with the switch shown in the factory setting Set the logical address to match the VXI mainframe slot number for a one mainframe system For a two mainframe system set to the slot number plus 16 if in mainframe 1 or to the slot number plus 32 if in mainframe 2 Refer
22. 3x1 to Banana E1066 61620 2000mm E3750 61603 1200mm Low High High 27 27 Drain E gt Low E1072 61620 E3750 61602 Twinax 3x1 to 3x1 Twinax 3x1 to 3x1 E1072 61620 2000mm E3750 61602 1200mm LOW d E LOW HIGH HIGH DRAIN 2 8 E DRAIN E1400 61605 1x6 ABus Ribbon Cable E1400 61605 PIN 1 64 System Cables and Connectors Chapter 4 E3750 61604 E6170 61614 Male BNC to 3x1 Cable Coax 3x1 to BNC E3750 61604 1200mm E6170 61614 2000mm NO CONNECT E TR SIGNAL 39 2 EY DRAIN Chapter 4 System Cables and Connectors 65 E3750 61608 96 Pin 64 Conductor to 96 Pin DIN Cable E3750 61612 2x1 Coax to 2x1 Drain Hi Cable 1200 25mm gt NO CONNECT SIGNAL DRAIN b 2t B Chapter 4 4 LT NO CONNECT SIGNAL DRAIN System Cables and Connectors 67 E3750 61613 Serial Interface Cable 61919 09283 LX 01 q ans 4 519 951 8 0 0 8 7 310 8 9 usq E 9 95 2 ay B 901
23. 63 There are two male BNC coax to 3x1 connectors of which the Agilent E3750 61621 supports isolated instruments as shown in Chapter 4 on page 63 The red tag and red shrink tubing are used to identify the isolated instruments cable System Instrument Configuration 45 Agilent E6173A Arbitrary Waveform Generator ARB Module Switch Jumper Settings The Agilent E6173A Arbitrary Waveform Generator formerly the Agilent Z2471A comes with Agilent E3750 61621 BNC Coax to 3X1 Cables The Agilent E6173A Arbitrary Waveform Generator is a register based two channel isolated both between channels and from ground waveform generator Channel one is connected to the Agilent E6171 Measurement Control Module in the factory default configuration of the Agilent TS 5400 System The isolated inputs J1 pins 5 6 may be amplified and used with the V I amp as an amplifier current sensor Channel two may be connected by the customer directly to a UUT pin or it can be routed though the Agilent E6171 Measurement Control Module using one of the unassigned inputs Figure 2 9 shows the Agilent E6173A logical address switch with the switch shown in the factory setting Set the logical address to match the VXI mainframe slot number for a one mainframe system For a two mainframe system set to the slot number plus 16 if in mainframe 1 or to the slot number plus 32 if in mainframe 2 Refer to VXI Module Locations And Logical Addresses on page 32 The Interru
24. Calibration and Preventive Maintenance Chapter 6 Appendix Test Capabilities and System Requirements Appendix Contents This appendix lists the test capabilities of the Agilent TS 5400 System and the physical and electrical requirements to operate the system This appendix is separated as follows Test Capabilities Measurement Sample Methods page 109 System 5 page 114 Miscellaneous Specifications page 117 Electromagnetic Compatibility Requirements page 117 Test Capabilities Measurement Sample Methods Appendix A The following test capabilities calculations help you determine if the Agilent TS 5400 Test System can meet your Device Under Test DUT test requirements The test capabilities of the Agilent TS 5400 system include the specifications of the V XI modules see Chapter 1 on page 11 used in the test s and the offsets in the system environment due to the measurement paths The largest contributors to measurement variations are the VXI instruments and the relays in the paths The process for determining system capabilities is 1 Determine the accuracy required to test the For example particular output driver test measurement requires a measurement of 12 5 volts 10 mV 2 Determine the path including the number of relays to the DUT from the Agilent E1411B DMM 3 Determine the specification of t
25. E6171A module until the red vertical bar is centered in the white segment of the measurement range See Figure 6 3 Adjust R196 Upper When device is adjusted so that the red bar is in the white section select DK If adjustment cannot be obtained select Cancel to terminate adjustment Current 0 008214 Value e 22 Pp Adjust R196 on the Agilent E6171A front panel until the red bar is centered in the white space Low Limit High Limit 0 007868 0 008468 Figure 6 3 Typical Prompt Box to Adjust Potentiometer R196 on the Agilent E6171A Module 8 Select the OK button in the adjustment box Note select the CANCEL button if you are unable to center the vertical bar 9 When prompted by the autoadj testplan adjust potentiometer R 197 front panel of the Agilent E6171A module until the red vertical bar is centered in the white segment of the measurement range See Figure 6 4 m Adjust R197 Lower When device is adjusted so that the red bar is in the white section select OK If adjustment cannot be obtained select Cancel to terminate adjustment Adjust R197 on the Agilent E6171A front panel until the red Current 0 07141 _ 18 centered in the white space Value ER 4 7 _ E Low Limit High Limit 0 07378 0 06978 Figure 6 4 Typical Prompt Box to Adjust Potentiometer R197 on the Agilent E6171A Module 1 Potentiometers R196 and R197 are very sensitive Typically you s
26. ER eee gr page 11 System see ee edens page 14 Conceptual Block page 15 System Hardware page 17 Typical System A typical Agilent Functional Test System for High Pin Count Devices includes an Agilent E6198 Switch Load Unit an Agilent E8792A 32 Pin Matrix and Instrument Multiplexer Module an E8401A 13 slot V XI mainframe an E1411B Digital Multimeter DMM an E6171A Measurement Control Module MCM an Industrial PC system controller One or more Agilent E6175A E6176A E6177A and or E6178A Load Cards One or more power supplies Test System Interface or Mass Interconnect Other optional GPIB instruments such as the Agilent 33120 Arbitrary Waveform Generator Other optional V XI instruments such as an E1563A 2 Channel Digitizer or E1418A 8 Channel DAC Figure 1 1 shows a typical Agilent E8780B Medium Pin Count System and Figure 1 2 shows an Agilent E8786B Large Pin Count System Chapter 1 System Introduction 11 Me Agilent Technologies TS 5400
27. Function Arbitrary Waveform Generator User s Guide The Agilent E6247A contains an VXI Technology E1563A 2 Channel A D Converter Digitizer or ADC and cables The E15634A has two differential channels that allow simultaneous measurements of two waveforms for example the voltage and current waveform of the load signal In the factory default configuration Channel 1 Adc1Hi Adc1Lo input provides direct access to the Agilent E6171B s attenuator output Connecting the digitizer allows you to digitize a high voltage like an inductive flyback while maintaining the resolution to also measure the driver s saturation voltage all in a single measurement cycle for high throughput testing Channel 2 input Adc2Hi Adc2Lo is connected to the interconnection column ABus Connecting the Digitizer to this way allows it to be routed to any input of the UUT For additional information refer to the Agilent E11563A 2 Channel A D Converter User s Manual Several of the VXI modules supported by the Agilent TS 5400 System are not multiplexed through a pin matrix card but directly connected to the Test System Interface or Mass Interconnect These optional products include the Agilent E6174A Event Detector and the Agilent E1418A 16 Channel DAC Module The Agilent E6174A Event Detector formerly Agilent Z2902 provides the capability to analyze 32 channel input event states and timings The events are stored in memory on the board then the events c
28. NO 027 028 029 030 031 032 CO NONA LU NJ b25 b26 b27 b28 b29 b30 b31 b32 n NO SO NO NJ SJ ISO ISO SO SJ SJ SJ ISO ISO SJ SJ DY ISO SJ DO SD UJ UJ UJ LU UJ UJ UJ UJ UJ UJ LU UJ UJ UJ LU UJ LJ UJ UU LU UJ LU LU UJ LJ LJ UJ LJ LU OUT TABLE TO ND ON A UD ND eau NN gt 022 NN 025 026 027 028 029 a30 a31 vd5 MO CO LU ND ANANANANANANN PY IP REP SJ SJ CON UI LU No 27 28 c29 c30 c31 ESE e mo Co LU NJ n FEX Y NJ SJ gt 625 C26 27 28 E29 c30 c31 C32 SO NJ SO DIDDY NID ISO SO SJ SJ SJ ISO SJ SJ DY DO SD SD UJ UJ UJ LU UJ UJ UJ UJ UJ UJ LU UJ UJ UJ LU UJ LU UJ LU LU UJ LU LU UJ LJ LJ LJ UJ LJ LJ ND ON UU ND nnnrnnnun SD ND c21 22 23 224 E25 26 027 c28 c29 c30 c31 37 80 System Cables and Connectors NO CONNECT
29. Unit and special power supply cabling Chapter 1 Test System Interface or Mass Interconnect Test System Interface Express Connect Chapter 1 The Test System Interface or Mass Interconnect connects the test system to your test fixture The test fixture then connects to the Unit Under Test UUT Standard connector blocks allow you to use general purpose connectors designed for low power and high power connections as needed The system can be configured with either one of two mass interconnects Test System Interface Express Connect for low cost medium duty applications Mass Interconnect Mac Panel for very high pin count and or high duty cycle applications The Test System Interface Express Connect provides two 156 pin detachable Test Connectors TC1 TC2 for connecting to the test fixture These connectors have connections for two Agilent E8793 32 Pin Matrix Modules two load cards includes connections to the current sensing circuitry on the load cards and power supplies The Test System Interface also has two high power connectors for a single 8 Channel Heavy Duty Load Card The Test System Interface can be expanded from two to eight test connectors and high power connectors Figure 1 7 shows a Test System Interface with the maximum available connectors Refer to the Agilent TS 5400 Series IIB Express Connect Test System Interface Wiring Guide supplied with your system for detailed information System Intro
30. functions executed in memory not output to device Conf lt xxx gt ConfCal ConfSync ConfSample ConfTrigOut ConfTrigIn ConfInControls ConfOutControls Return xxx Configure specified information Select mode based on calibration constants such as 50 60 Hz Enables synchronization of multiple instruments on a given interface if allowed by the instruments For example a card containing dual arbitrary waveform generators could be set up to generate simultaneous output from both generators Sets up sample parameters Sets up the trigger output parameters Sets up the trigger input parameters Sets input related switches such as filters and attenuators Sets output related switches such as the output impedance Returns specified data from memory Chapter 3 Naming Conventions Used Chapter 3 in Instrument Handlers Instrument handlers follow these naming conventions 1 Routine names begin with the lowercase name of the instrument type Note that this is not a specific device but a generic one For example use dmm instead of dmm1411 This lets handlers be expanded to handle more than one type of similar instrument in the future There are no underscores separating parts of a function name Rather upper and lower cases are used Functionality that is unique to an instrument has a name that matches the function For example to source DC current the handler for ins
31. gt Regulatory Markings ce The CE mark is a registered trademark of the European Community The CSA mark is a registered trademark of the Canadian Standards Association The C tick mark is a registered trademark of the Spectrum Management Agency of Australia This signifies compliance with the Australian EMC Framework regulations under the terms of the Radio Communications Act of 1992 YNi0149 ISM 1 A This text indicates that the product is an Industrial Scientific and Medical Group 1 Class A product CISPR 11 Clause 4 Safety and Support Information 5 Service and Support 6 Any adjustment maintenance or repair of this product must be performed by qualified personnel Contact your customer engineer through your local Agilent Technologies Service Center Agilent on the Web You can find information about technical and professional services product support and equipment repair and service on the Web http www agilent com Click the link to Test amp Measurement Select your country from the drop down menus The Web page that appears next has contact information specific for your country Agilent by Phone If you do not have access to the Internet call one of the numbers in Table 2 Table2 Agilent Call Centers and Regional Headquarters United States and Canada Test and Measurement Call Center 800 452 4844 toll free in US Europe 41 22 780 8111 Japan Measure
32. installed See Figure A 3 for an illustration of the site calculations To obtain the necessary attenuation at the customer s site perform these calculations if the calculated site attenuation A is less than 10 dB contact the Technical Regulatory Support Engineer TRSE in your country 1 The attenuation of a concrete wall W without any openings 10 dB 2 The distance D the distance from the equipment to the exterior wall plus 30 meters increases the attenuation by X and can be calculated as X 20 log D 30 where X attenuation in dB D distance in meters 3 total attenuation A 15 calculated as A n W Xwhere A total attenuation in dB n number of concrete walls within distance D W 10 dB Appendix A Test Capabilities and System Requirements 117 Building in which the equipment is installed Measuring Point Figure A 3 Electromagnetic Compatibility Calculation Illustration 118 Test Capabilities and System Requirements Appendix A Appendix B Parts Lists Appendix Contents This appendix lists the system level replaceable parts for the Agilent TS 5400 System The appendix is separated as follows Identifying and Ordering 5 page 119 Replaceable Parts page 119 Recommended Spare 5 page 124 Identifying and Ordering Parts System
33. is not the case with the drivers Thus use instrument handlers for actions whenever possible The names of the standard functions used in instrument handlers appear below Note that not all handler routines will have all of these routines List of Immediate execution functions input output to device when executed Get lt xxx gt prefix is used for any routine that returns data of any kind GetResults Returns results of a reading optionally triggering it first Set Outputs current config to device Customizing the System 59 60 Customizing the System Set xxx Reset Clear Initiate Trigger IsSet Connect Connect xxx Disconnect Disconnect lt xxx gt Set prefix is used to set up given configuration to the device Resets instrument s to their power on state Clears errors and output buffers Puts instrument in wait for trigger state Necessary for external trigger modes requiring continuation of the program after this command is issued to generate the trigger May also be used to start an immediate reading cycle to be followed by a GetResults call Generates a software trigger immediately Returns true or false regarding the busy ready state of the instrument This may or may not be blocking depending upon the capability of the given instrument Connects output relays Connects a specific relay Disconnects output relays Disconnects a specific relay List of Setup
34. named group of symbols or parameters whose usage has a specific scope For example The symbol table named TestPlanGlobals contains symbols whose scope is global to the test plan Thus variables defined in it can be used to pass values between tests because the variables are visible throughout the test plan The symbol table named TestStepLocals contains symbols whose scope is limited to that test The symbol table named hwconfig contains symbols associated with the hardware defined for use with the Test Executive The symbol table named system contains symbols associated with the testing environ ment such as the user id test system id and serial number of the DUT T Test Group A named sequence of tests that has an associated list of one or more setup actions that must be executed before any of the tests in the group A test group is bounded by testgroup lt name gt and end testgroup statements inside a test plan Test groups can be nested inside test groups 138 Glossary Test Limits The acceptable boundaries for a test If the results from a test are less than the lower limit or greater than the upper limit the test fails A test can have more than one set of limits where each set is associated with a named variant such as Hot or Cold Test Executive Test A software tool used to develop tests assemble them into a testplan and run the testplan A sequence of actions executed
35. the NO or NC terminals on a load card K Keyword An identifier used to restrict the number of matches found when searching for a specific item Keywords often describe the item for example suitable keywords for an action might be trigger or range to identify what the action does or how it is used L LADDR Logical Address The address set on a VXIbus module that is unique to that system In the TS 5400 system this usually corresponds to its slot number If the module goes in the second mainframe of a two mainframe system then the LADDR would be the slot number plus 128 LEM module A current transducer which measures currents with galvanic isolation between the primary and the analog output signal The LEM module tested with the TS 5400 has multiple primary coil taps that allows it to be set for five different current levels Library A collection of related code stored in one or more directories Agilent TestExec SL supports libraries of actions and libraries of tests Organizing actions and tests into libraries makes it easier to find and manage existing code so you can reuse it Load Card C sized card designed to fit in the Switch Load Unit that provides switching for the various loads and provisions for either internal load mounting or connections for external load mounting Load cards 132 Glossary provide two level card ID card type and load configuration ID Load Switching A load that can be switch
36. the instrument The system ust file was originally created at the factory and lists describes each instrument alias and wire node in the system as shipped from the factory You should make a back up copy of the original system ust as a reference copy before making any modifications The system ust file can be modified in one oftwo ways using the System Configuration Editor or the TestExec SL Topology Editor The System Configuration Editor is the recommended method and easier to use since it automatically generates wires and aliases whenever a module instrument is added The System Configuration Editor is available from the TestExec SL toolbar and as a shortcut in the Desktop of the system controller When the editor is opened it automatically selects the system ust file in the default bin directory Use the open file function to open a different system ust file The Topology Editor Is invoked when you purposely open the system ust file or another ust file from TestExec SL Refer to the TestExec SL Online Help for details on using the Topology Editor The following guidelines are for use in modifying the system ust file using the TestExec Topology Editor Nodes are associated with a module for example External Trigger or External Clock or individual channels on a module for example mcm VISrcHi and mcm VISrcLo The nodes can be added or deleted independently After specifying an instrument you must save the system ust
37. the max imum extent permitted by applicable law Agilent disclaims all warran ties either express or implied with regard to this manual and any infor mation contained herein including but not limited to the implied warran ties of merchantability and fitness for a particular purpose Agilent shall not be liable for errors or for incidental or consequential damages in connection with the furnishing use or perfor mance of this document or of any information contained herein Should Agilent and the user have a separate written agreement with warranty terms covering the material in this document that conflict with these terms the warranty terms in the sep arate agreement shall control Technology Licenses The hardware and or software described in this document are furnished under a license and may be used or copied only in accordance with the terms of such license Restricted Rights Legend If software is for use in the performance of a U S Government prime contract or sub contract Software is delivered and licensed as Commercial computer soft ware as defined in DFAR 252 227 7014 June 1995 or as a commercial item as defined in FAR 2 101 a or as Restricted computer software as defined in FAR 52 227 19 June 1987 or any equivalent agency regulation or contract clause Use duplication or disclosure of Software is subject to Agilent Technologies standard commercial license terms and non DOD Departments and
38. v NOTE IS FARSIDE J2 NO CONNECT TO CENTER ROW J3 W TAN 32C TAN m o dc i 0955 ICI DODE 1A RED 32A BRN E6170 61603 Chapter 4 E6170 61604 E8794 to Mac Panel Express Connect and SLU Interconnect Cable 4 E Hm E6170 61606 Power Bus Jumper Cable PB1 PB2 PB3 PB4 6170 61606 High Current Jumper PB1 PB2 PB3 82 System Cables and Connectors Chapter 4 E6170 61609 External Power Cable 6653 6673 E6170 61609 External Power Cable 6653 6673 Chapter 4 System Cables and Connectors 83 E6170 61611 SLU to UUT Low Current Power Supply Cable 6628 6643 E6170 61611 External Power Cable 6628 6643 84 System Cables and Connectors Chapter 4 E6170 61613 DAC to Pin Card Aux Cable 4 A NO CONNECT TO ROW A 328 TAN MDDLE ROW 32C REDNI 324 324 E6170 61615 DAC to Custom Card Cable NO CON
39. 2 15 inch Flat Panel Service Replacement Kit Includes required sheet metal for mounting the monitor PC Plug in Cards 0960 1284 Intel 10 LAN Card HP Vectra PCs only E6196 66512 PCA 8 Channel RS 232 Rocket Port PC I O GPIB IEEE 1394 VXI 82350 66501 E2078 62101 E8491 66503 E8491 61613 E8491B 8121 0078 PCI GPIB Card For Firewire Systems GPIB Extender IEEE 1394 PCI Card Power adapter cable IEEE 1394 VXI Interconnect IEEE 1394 VXI Interconnect cable 2m PC I O VXI Agilent E8786B 0960 1028 E6196 67501 E6196 67502 E6196 61611 National Instruments ISA GP IB Interface For MXI II Systems NI MXI 2 PC plug in card NI MXI 2 VXI Slot 0 Module MXI 2 Cable VXI Hardware E8401A 13 Slot VXI Mainframe for Series IIB Systems E8401 69276 Rebuilt 600W VXI Mainframe Power Supply E6182A E1333A Counter with E1403B Adapter Cables and Manuals E1333 69201 Exchange Assembly for the E1333A Counter E1403 66501 B size to C size VXI adapter card E1411 66221 E1411B DMM exchange assembly MCM VI E6171 69201 E6171B vi exchange assembly 2110 0516 Fuse 1 Amp front panel 0490 1839 Relay Matrix and Control 120 Parts Lists Appendix B Table 6 3 E8780B E8786B Replaceable Parts Part Number Description Pin Matrix E8792 66201 E8792A Pin Matrix card
40. 32 channels where N represents the number of Pin Matrix cards including the E8792A The E8793A 32 Pin Matrix Module compliments the E8792A 32 Pin Matrix and Instrument Multiplexer Module by multiplexing the four wire Analog Bus ABus1 ABus4 to 32 pins for UUT The 32 matrix is a matrix with series disconnect and bypass relays as shown in Figure 1 6 The default mode for each column has a 200 2 protection resistor in series with each column with the parallel bypass relay open This provides relay protection while allowing two wire ohms measurements when the parallel relay is closed The disconnect relay switches reduce the parasitic capacitance on the bus when open The auxiliary Aux relays allow a switchable path from a node on the UUT to one of the Direct Connect ICA Detectors Sources which are also terminated on the mass interconnect Typical uses forthe Aux relays include connecting an optional DAC Digital I O or other system resources such as the Agilent EI418A DAC For additional information on the Agilent E8792A 8793A refer to the Agilent E6198Switch Load Unit User s Manual Chapter 1 Abus Connector J3 Abus2 Abus4 Abus 1 Abus3 Decoding and Driver Circuits Disconnect Relays Bypass Relays P1 96 Pin DIN C Backplane Access To Switch Load Unit
41. ABC CH 4 MODE JMPR CH3LS CH 9 MODE JMPR CH 4 HS 1 CH 10MODE JMPR CH4HI CH 11 MODE JMPR CH4LO CH 12 MODE JMPR CH4LS CH9HS GND GND CH 9 HI GND CH9LO GND CH9LS GND CH 10 HS GND CH 10 HI GND CH 10 LO GND CH 10 LS GND CH 11 HS EXT TRIGn CH11 HI GND CH 11 LO CAL HS CH 11 LS CAL HI CH 12 HS CAL LO CH12 HI CH 12 LO CALLS 32 GND CH 12LS 7 7 7 7 7 7 7 7 7 77 7 7 7 7 7 7 7 7 7 7 7 777747 77 7 7 7 7 7 7 77 777 777777 0000000000000000000000000000000 amp 00000000000000000000000000000000 TERMINAL ID 1 1 TERMINAL ID 2 TERMINAL ID 3 GND GND GND GND GND GND GND GND GND GND GND GND GND CH 5 PROG JMPR CH 6 PROG JMPR CH 7 PROG JMPR CH 8 PROG JMPR 32 CH 13 PROG JMPR CH 14 PROG JMPR CH 15 PROG JMPR CH 16 PROG JMPR CH 5 MODE JMPR CH 6 MODE JMPR CH 7 MODE JMPR CH 8 MODE JMPR CH 13 MODE JMPR CH 14 MODE JMPR CH 15 MODE JMPR CH 4 MODE JMPR
42. Agencies of the U S Gov ernment will receive no greater than Restricted Rights as defined in FAR 52 221 19 c 1 2 June 1987 U S Govern ment users will receive no greater than Limited Rights as defined in FAR 52 227 14 June 1987 or DFAR 252 227 7015 b 2 November 1995 as applicable in any technical data Safety Notices Caution A Caution notice denotes a hazard It calls attention to an operating procedure practice or the like that if not correctly performed or adhered to could result in damage to the product or loss of important data Do not proceed beyond a Caution notice until the indicated conditions are fully understood and met WARNING A WARNING notice denotes a hazard It calls attention to an operating procedure practice or the like that if not correctly per formed or adhered to could result in personal injury or death Do not proceed beyond a WARNING notice until the indicated condi tions are fully understood and met Safety Summary The following general safety precautions must be observed during all phases of operation of this system Failure to comply with these precautions or with specific warnings elsewhere in this manual violates safety standards of design manufacture and intended use of the system Agilent Technologies Inc assumes no liability for the customer s failure to comply with these requirements General This product is provided with a protective earth termin
43. Agilent TS 5400 Functional Test System Series IIB System Integrator s Manual Manual Part Number 8770 90030 E Agilent Technologies Notices Agilent Technologies Inc 1999 2003 No part of this manual may be reproduced in any form or by any means including electronic storage and retrieval or transla tion into a foreign language without prior agreement and written consent from Agi lent Technologies Inc as governed by United States and international copyright laws Documentation History All Editions and Updates of this manual and their creation date are listed below The first Edition of the manual is Edition 1 The Edition number increments by 1 whenever the manual is revised Updates which are issued between Editions contain replace ment pages to correct or add additional information to the current Edition of the manual Whenever a new Edition is cre ated it will contain all of the Update infor mation for the previous Edition Each new Edition or Update also includes a revised copy of this documentation history page Edition 1 E8770 90000 July 1999 Edition 2 E8770 90020 September 2000 Edition 3 E8770 90030 August 2003 Manual Part Number E8770 90030 Printed in USA Agilent Technologies Inc 1601 California Street Palo Alto CA 94304 USA Warranty The material contained in this docu ment is provided as is and is sub jectto being changed without notice in future editions Further to
44. HP E1411 5 1 2 Digit Multim DLL C Program Files HP TestExec SL bin hw er in slot 11 at address 11 dll Parameters 0 reset when sending a Global Reset VXI Cage 1 E 8 1 Resets when sending a Global Reset Logical ddress 8 SkipGlobalReset 1 Module matrixi Description HP E6172 Pin Matrix Card slot 2 addr 2 DLL C Program Files HP TestExec SLYibin hwhpm dll Parameters Figure 5 2 Typical Hardware Configuration 94 System Diagnostics Chapter 5 Test Execution The Test Execution Details query allows you to see the execution order and Details the actions used in a test sequence This allows you to check and see if the correct tests are performed Figure 5 3 shows a typical test sequence 1 Click on View Agilent _ Testplan Editor DgnS2Mcm File Edit Insert Debug Options Window Help v Toolbar Listing Profiler Results Symbol Tables Test Execution Details Testplan Ed Testplan Sequer H est 5 Instrument Panels 8 Problem List test V 2 Click on Test Execution Details Test Execution Details Ed SETUP OR EXECUTE Action Routine Arb Select Waveform Arb Select waveform Switching Switching Config 1 Chan AdcConfiglCh Analyze Wave ave CLEANUP Action Routine Switching Switching EL Figure 5 3 Test Execution Details Actions i
45. ICA Floating Inputs See Isolated inputs Glossary 129 Flyback Protection Device Any device that controls the magnitude of positive or negative going voltage spikes on a channel Flyback Voltage The voltage surge experienced when current flow through a coil is abruptly stopped or started Form C Relay Standard terminology for Single Pole Double Throw SPDT relay contacts Functional Test A test that simulates the actual operating conditions of the Device Under Test DUT G Glitch An unexpected or unplanned event or occurrence Abrupt termination of tests is usually due to a software glitch GP Acronym for General Purpose The relays on the E6177A 24 Channel medium current Load card can be configured as GP relays GPIB A parallel interface that complies with IEEE Standard 488 1978 Hardware Configuration The physical and functional arrangement of the system components with respect to each other Refers to the relative placement of modules in the V XI mainframe and load cards in the Switch Load unit and connections from the system components to the ICA The hardware configuration is defined in the hwconfig cpp file 130 Glossary HV Interlock High Voltage Interlock interrupt that disables the high voltage amplifier of the Measurement Control module ICA Interface Connector Assembly The system half of the mass interconnect May also be called the receiver or fixture receiver Interface Conne
46. NECT TO ROW A 328 TAN MIDDLE ROW 32C RED 324 2 324 E6189 61600 Power Supply Power Cable 2 o 22 om 2 5 n BROWN WIRE BLUE WIRE GREEN YELLOW WIRE Chapter 4 System Cables and Connectors 87 E6230 61603 Heavy Duty Load Card Cable qi NIE B E6230 61603 Heavy Duty Load Card Cable REMOTE SENSE PWR SUPPLY 88 System Cables and Connectors Chapter 4 E6247 61601 Cable Digitizer E1563A E6247 61601 1200mm BLACK DRAIN BLACK LOW CLEAR SHIELD EN d BLACK ICLEAR Chapter 4 System Cables and Connectors 89 E8770 61601 External Power Cable E8770 61601 External Power Cable 90 System Cables and Connectors Chapter 4 Chapter 5 System Diagnostics Chapter Contents This chapter has information to perform System Diagnostics and Service Diagnostics on the TS 5400 System The chapter is separated as follows Support Strategy page 91 Diagnostics 5 page 92 Using Agilent TestExec SL to Run the Testplan page 93 Support Strategy Confirmation and diagnostics software is provided in the system software to repair and troubleshoot the system and to verify that the system is wired correctly The Diagnostics are designed to isolate the cause of a failure to a field replaceable u
47. Note Note rates up to 13 kHz Measurements for this DMM include Vdc ac 2 and 4 wire ohms offset compensated ohms and temperature from thermocouples thermistors and RTDs The Agilent 34401 Digital Multimeter DMM measures dc voltage ac rms voltage and ohms including 4 wire ohms It can also measure temperature by using thermistors The input to the DMM is balanced and differential For additional information refer to the Agilent 34401 Digital Multimeter User s Guide The Agilent 53131 Universal Counter performs frequency time interval period and totalize measurements It is connected to the UUT through the Agilent E8792A 32 Pin Matrix and Instrument Multiplexer Module but uses only one row of the matrix module connector since the counter inputs are referenced to system ground Instead of using the 53131 Counter you can use an Agilent E6182A Agilent E1333A Universal Counter This counter is a single slot B size VXI counter that requires an Agilent E1403B B size to C size Active Adapter Module and cables and a C size VXI mainframe For additional information refer to the Agilent 53131 Universal Counter Programming Guide The Agilent 33120 Arbitrary Waveform Generator Arb provides the means to generate arbitrary waveform besides providing standard functions like sine square etc Itis connected to the UUT through the Agilent E8792A 32 Pin Matrix and Instrument Multiplexer Module but since its output
48. O3g 842 Sc 2v18 81 72 034 9 3 92 3 v18 91 IZ 034 0c 6023 7 2 6b v18 717 8 039 NMO g 2 9L v18 45 SL 034 0 3 vb NMO3N8 012 EL 2v18 oly 034 83 NMD3G 95 OL v18 9v 60 agy 93 90 NMO 38 92 40 2v18 9v 90 038 73 50 NMONS 72 70 32v18 7 0 039 23 20 NMO3N8 2 v18 138 1 90102 9 WALI NO 011 201 Chapter 4 76 System Cables and Connectors E3750 61627 Power Supply Cable E3750 61627 6628 Power Supply Cable WHT YEL Chapter 4 System Cables and Connectors 77 E3751 61601 E6170 61610 64 Conductor Twisted Pair Cable TO CENTER ROW NO CONNEC TAN 63000164 BRN Wi Pin Matrix Cable E3751 61601 1016mm E6170 61610 1500mm T RED 1 TAN BRN 63 78 System Cables and Connectors Chapter 4 E3857 61613 Rack On Off Switch to PDU Cable T oc RACK ON OFF SWITCH Bum MEN iQ GREEN E3857 61613 Rack On Off Switch to PDU Cable Chapter 4 System Cables and Connectors 79 E6170 61603 E8792 93 to MAC Panel Cable CONNECTOR PI LU ND ooo oo CON UI UJ
49. V System Capabilit The output driver transistor saturation sample uses the same setup as the dc p p p i i accuracy sample shown in Figure 1 The only difference is that when the Driver Saturation output driver transistor base voltage is biased to force saturation the Sample collector voltage is expected to be 0 4 Therefore the Agilent E1411B DMM 5 5 voltage range will be changed to the 1 volt range The calculated system capability accuracy on the 1 volt range using 16 7 20 millisecond aperture range when using the Agilent E1411B within its defined accuracy conditions is DC Accuracy offset offset DvmHi to Abus4 offset Series Disconnect Relay offset Protection Disconnect Relay offset Row 32 Matrix Relay offset DvmLo to DUTCommon equals 5 relay offsets of 30 each Calculated system capability 0 023 0 4 V 15 0 uV 5 30 uV 257 110 Test Capabilities and System Requirements Appendix A 12 5 Unit Under Test UUT Interface Test Adapter ITA or Fixture Interface Connector Adapter ICA or Fixture Receiver Interconnection Column ABus Backpl TTL VXI Close these Switches Trigger Multiplexer ane _ iss bend 2 Y system Gnd E6171 Measurement Control Module 9 VM Agilent E1 DM 411
50. VCI 200m Offset 988 6e 3 1 065 0 915 16 LVCI 20m Offset 98 86e 3 0 104 0 094 17 LVCI 2m Offset 9 886e 3 0 0104 0 0094 18 LVCI 200u Offset 988 6e 6 0 00104 0 00094 19 HVCI Offset 1 0 1 05 0 95 20 Comp200V Offset 237 5 255 0 220 0 21 Comp20V Offset 23 75 24 5 23 0 22 LV ClampDac Offset 0 7 0 6 2 4 23 HV ClampDac Offset 2 0 3 3 11 0 24 LV 10 10 0 10 0 12 5 25 LV 100 100 0 100 0 102 5 26 LV 1K 1000 0 990 0 1010 0 27 LV 10K 10000 0 9988 0 10018 0 28 HV 100 100 0 100 0 102 5 29 DRCI 200m 0 0 0 05 0 45 30 DRCI 20m 0 0 0 5 0 9 31 DRCI 2m 0 0 5 0 5 0 32 DRCI HV20m 0 0 0 5 0 9 33 DRFVMI 200m 0 0 0 05 0 45 34 DRFVMI 20m 0 0 0 5 0 9 35 DRFVMI 2m 0 0 5 0 5 0 Calibration and Preventive Maintenance 105 Table 6 2 Parameter ID Numbers and Types ID Nominal Low High Value Value Value 36 DRFVMI HV20m 0 0 0 5 0 9 37 AttnCalHigh Gain 0 051 0 049 0 053 38 AttnCalHigh Offset 2 40 2 25 2 55 39 AttnCalMid Gain 0 982 0 972 0 991 40 AttnCalMid Offset 0 0 0 003 0 003 41 AttnCalLo Gain 0 051 0 049 0 053 42 AttnCalLo Offset 2 40 2 55 2 25 106 Calibration and Preventive Maintenance Chapter 6 Verification Procedures Functional and Performance Verification procedures for the individual V XI modules and the power supplies are found in the respective module s Service Manual Chapter 6 Calibration and Preventive Maintenance 107 108
51. ac line voltage input by changing wire and jumper locations on the ac input of the main power transformer Refer to the Agilent 6652A Power Supply User Manual for specific information The Agilent 6653A DC Power Supply is a 1 output 0 35 volt 0 15 A GPIB supply The supply can be set to accept 100 volts 120volts 220 volts and 240 volts ac line voltage input by changing wire and jumper locations on the ac input of the main power transformer Refer to the Agilent 6653A Power Supply User Manual for specific information The Agilent 6672A DC Power Supply is a 1 output 0 20 volt 0 100A GPIB supply It is not switchable to multiple line voltages it is set up for 220 240 volts and is connected to the Agilent E1135A PDU The maximum current draw capability of the Agilent 6672A exceeds the breaker size 15A on the Agilent TS 5400 system and the design specifications of the load cards Do not use the maximum capabilities of the Agilent 6672A through the Switch Load Unit 48 System Instrument Configuration Chapter 2 Agilent 6673A DC Agilent 6673A DC Power Supply is a 1 output 0 35 volt 0 60A GPIB supply It is not switchable to multiple line voltages If an Agilent 6673A Power Supply power option is not specified then it is set up for 220 240 volts and is connected to the Agilent E1135A PDU Caution The maximum current draw capability of the Agilent 6673A exceeds the breaker size 15A on the Agilent TS 5400 system and t
52. address switch with the switch shown in the factory setting The logical address for both a one mainframe system and a two mainframe system is the factory default setting of 17 Refer to V XI Module Locations And Logical Addresses on page 32 The Interrupt Priority is always set to 1 E i HiG z Access O mac OPEN Switch Set to 0 Off CLOSED Switch Set 1 On 2 je js Factory Default 17 shown TS 5430 5450 One Mainframe 17 E61718 TS 5450 Two Mainframes 17 Logical Address uS Row 1 E Location Row 5 4 Row 11 8 IN Row 13 r Row 17 16 Row 20 32 Row 24 64 Row 28 128 Row 32 TUE O O o Ml y SS p Ermm Figure 2 8 Agilent E6171B Measurement Control Module Cabling Cable Pinouts Chapter 2 Figure 2 8 shows the Agilent E6171 Measurement Control module cabling The rows are the three wide sets of pins that the 3x1 cables plug onto J1 is made up of individual cables which connect to the system instrumentation J2 is the interconnection column ABus to the 32 Pin Matrix Modules See Chapter 4 on page 63 for the pinouts of cables which terminate on the Measurement Control module The cables which connect the Measurement Control Module connector J1 to the VXI instrumentation are shown in Chapter 4 on page
53. al The protective features of this product may be impaired if it is used in a manner not specified in the operation instructions WARNING NOT OPERATE IN AN EXPLOSIVE ATMOSPHERE Do not operate the system in the presence of flammable gases or flames If the equipment in this system is used in a manner not specified by Agilent Technologies the protection provided by the equipment may be impaired Cleaning Instructions Clean the system cabinet using a soft cloth dampened in water Safety and Support Information WARNING NOT REMOVE ANY SYSTEM COVER Operating personnel must not remove system covers Component replacement and internal adjustments must be made only by qualified service personnel Equipment that appears damaged or defective should be made inoperative and secured against unintended operation until they can be repaired by qualified service personnel Environmental Conditions Unless otherwise noted in the specifications this system is intended for indoor use in an installation category II pollution degree 2 environment It is designed to operate at a maximum relative humidity of 80 and at altitudes of up to 2000 meters Refer to the specifications tables for the ac mains voltage requirements and ambient operating temperature range Before applying power Verify that all safety precautions are taken Note the external markings described in Safety Symbols and Regulatory Markings o
54. ame 2 Refer to VXI Module Locations And Logical Addresses on page 32 The Interrupt Priority is always set to 1 Logical DEvecTOR Address Logical Address Switch Location E3750 61604 11 to Factory Default 8 shown Be E6171 Measurement TS 5430 5450 One Mainframe Slot Control Module Row 30 TS 5450 Two Mainframes Slot 16 or Slot 32 if in mainframe 2 E3750 61604 11 to Mass Interconnect Connector 1A Row 14 H IRQ Location s odiis Channel 31 system ground CLOSED Switch Set to 1 OPEN Switch Set to 0 Off E3750 61601 9 to Interrupt Request Mass Interconnect Factory Default IRQ and See section ICA Connector TS 5450 One Block Locations for factory default location Channel 0 d Channel 0 system ground Input Figure 2 10 Agilent E6174A Event Detector Module Cabling Agilent E6174A Event Detector is directly connected to the mass interconnect Placement of the connector is based on the algorithm described in Direct Connect ICA Detector Sources in Chapter 4 on page 63 The Agilent E3751 61601 Twisted Pair cable 9 is used as shown in Chapter 4 on page 63 Chapter 2 System Instrument Configuration 47 Programmable Power Supplies GPIB Address Selection Agilent 6642A DC Power Supply Agilent 6643A DC Power Supply Agilent 6652A DC Power Supply Agilent 6653A DC Power Su
55. an be read back by the controller for event analysis Either the Agilent E6174A s internal sampling clock may be used or an external clock can be selected to expand the measurement time For specific information refer to the Agilent E6174A 32 Channel Event Detector User s Manual The Agilent E1418A is an 8 or 16 channel digital to analog converter module Each channel can be configured for either voltage or current output mode When configured for voltage output voltages in the range of 16 0 to 16 0 Volts can be set When configured for current output currents in the range of 0 02 to 0 02 Amps can be set The channel output mode be programmatically set or it can be forced to either voltage or current by mechanical jumpers on the terminal block The E1418A can be configured System Introduction 27 for Isolated or Non Isolated channels Note For additional information refer to the Agilent E1418A 8 16 Channel D A Converter Module User s Manual and SCPI Programming Guide 28 System Introduction Chapter 1 Programmable Power Supplies Chapter 1 Table 1 1 lists the Agilent TS 5400 power supply product numbers Option 014 to any of the product numbers includes cables and rack mount rails for example E6187A 014 Each of these GPIB programmable power supplies can operate in either a constant voltage or constant current mode over the specified output range Table 1 1 also lists nominal voltage and current values fo
56. analog signal Datalogging The process of collecting data about tests when the test plan runs Subsequent study of this data can aid you in improving the processes associated with manufacturing and testing Debug Panel On the front panel of the TS 5400 system there is a test point for each ABus column four total These test points allow monitoring the bus status during troubleshooting operations Device Under Test DUT The automotive module or printed circuit board being tested Also know as Unit Under Test UUT Digitizer Analog to digital converter Converts an analog signal to a digital signal at a multiple sample per second rate DLL Dynamic Link Library A library of code that is automatically loaded and unloaded as needed Duty Cycle That portion of a cycle when components are actually being used For example A component that can carry 10A with a 1046 duty cycle and with a cycle equal to 1 second could carry 10A for 100ms then OA for 900ms E Event Detector An instrument that simultaneously compares the values of up to 32 synchronous input channels between two consecutive clock cycles If there is a change on any channel the new state is stored in a set of FIFO first in first out registers along with a time stamp to allow determining the relative time span between recorded events Up to 1024 events can be recorded at one time 128 Glossary Exception An error that occurs during testing For example
57. anization are calibrated The following VXI modules require periodic calibration Calibration information is provided in the module s respective service manuals Calibration Product Cycle Agilent E1411B Digital Multimeter 1 year VXI Technology E1563A Digitizer 1 year Agilent E1418A D A Converter Module 1 year Agilent E1333A Universal Counter 1 year Agilent E6173A 72471 Arbitrary Waveform 1 year Generator Agilent 6642A 6643A 6652A 6653A and 6673A 1 year Power Supplies Calibration and Preventive Maintenance 97 System Adjustments Procedure Note Agilent E6171A B Measurement Control Module adjustment must be done in the Agilent TS 5400 Test System where the E6171A B module resides Agilent E6171A B specific measurement constants are stored in the PC controller as part of the TestExec SL software A soft or system wide adjustment can be done at any time The TestExec SL software notifies you if 30 days have expired since the last system wide adjustment A complete module calibration should be performed annually or when anything in the system changes for example moving the system to a new location changing any VXI module Agilent E6171A B or EI411B DMM etc The Agilent E1411B in the test system is the reference and must be calibrated first Do the following 1 Select and run the autoadj tpa testplan to perform the system wide adjustment 2 Locate the
58. annel cards or 1 16 amp 2 8 channel cards E3750 61615 MAC Panel Cable for the 16 channel cards E3750 66503 8 channel Load card E6175A option 120 Express Connect Cable one 16 or 8 ch load card to one TC slot E3750 61614 MAC Panel Cable for the 8 channel cards E3750 66206 8 channel Heavy Duty Load card E6178B 0490 1945 Relay for 8 channel heavy duty 2110 0998 30 Amp Fuse E6178B option 120 Express Connect Cable one load card to one High Power slot E6178B option 110 MAC Panel Cable for the 8 channel heavy duty cards 30Amp 122 Parts Lists Appendix B Table 6 3 E8780B E8786B Replaceable Parts Part Number Description Serial Communication E6170 66002 Serial Protocol Adapter Multicom 111 E6249 80005 Rocket Port Serial Card Appendix B Parts Lists 123 Recommended Spare Parts Table 6 4 E8780B E8786B Recommended Spare Parts Part Number Description Qty per Number Systems E8792A SLU Pin Card with instrumentation matrix 1 2 E8793A SLU Pin Card no instrumentation matrix 1 2 E6171 69201 E6171B Measurement Control Module rebuilt 1 4 Z2471 69201 E6173A Arbitrary Function Generator rebuilt 1 4 E6170 66502 E6198A SLU backplane board 1 2 0950 3625 E6198A SLU power supply 110 E1418 69201 8 channel DAC 1 4 E1418 69502 8 cha
59. ards 24 Channel Load Cards 8 Channel Modules Load Cards Slot Agile hnologies Q 11 12 15 14 15 16 17 18419 20 Q 1 O O O 36 o 11 15 15 i4 15 1617 18 18 20 21 5 6 9 ee Multiplexed Instruments Digital Multimeter DMM Agilent E1411B Digital Multimeter Chapter 1 Figure 1 8 Mac Panel Mass Interconnect Instruments are multiplexed to the Analog Bus using the Agilent E6171B Measurement and Control Module s 4x16 instrument matrix and or the Agilent E8792A 32 Pin Matrix 4x16 instrument matrix Either the Agilent E1411B 34401 Digital Multimeter DMM can be used as the system DMM In addition to test measurements the DMM serves as the system reference and is used to adjust other modules and instruments The Agilent E1411B 5 5 Digit DMM is a C size 1 slot register based VXI module You can use its integrating A D to make 5 5 digit low noise measurements or switch to the sampling A D to make 14 bit readings at System Introduction 25 Agilent 34401 Digital Multimeter Note Agilent 53131 Universal Counter Agilent 33120 Arbitrary Waveform Generator 26 System Introduction
60. as a group to do some form of test As a minimum each test must contain an execute action It also can contain one or more optional setup or cleanup actions To be meaningful most tests have a limits checking feature that determines if the Unit Under Test passed or failed the test Also most tests use a data logging feature to store information collected during the test Testplan A named sequence of tests that is executed as a group to test a specific device or Unit Under Test A test plan also can be further divided into groups of tests called test groups Topology A combination of physical and logical descriptions that define the switching configuration and interconnections between resources and the DUT which includes definitions for the modules wires switches and buses of the test system These definitions map a logical view of your system s hardware onto its physical reality and add a level of abstraction Topology Layer Topology is defined in three layers system fixture and DUT The first layer defines the system hardware the second defines one or more fixtures used with the system hardware and the third defines one or more DUTS used with a given fixture Information defined at the system layer includes Definitions for any cards or modules used in the system A definition of the cabling that connects the cards or modules Definitions of convenient names i e aliases for system resources such as DvmHi
61. at 128 128 base address Slot 0 Stand off Voltage The maximum voltage differential an open relay can tolerate without arcing across the contacts Switch Handler Software that enhances Agilent TestExec SL s interaction with a switching module such as a relay matrix When you use a switch handler with a switching module you can use the Switching Configuration Editor to define your test system s topology and then use the Switch Path Editor to conveniently control switch paths during a test Glossary 137 Switch Path A connection between nodes needed to make a test For example a switch path might connect the output from a power supply to a pin on the unit under test Example FuncGen SrcBus Dvm MeasBus In the example the source bus of the function generator is connected to the measurement bus of the digital voltmeter when the switch path is closed Switching Configuration Editor A software tool used to define topology Switching Setup A special kind of setup action that sets up connections such as switch paths made with relays at the beginning of a test and controls the status of those connections when the test ends Unlike other kinds of actions you do not use the Action Definition Editor to create switching setups Switching Voltage The nominal voltage differential across a relay s contacts at which it can be switched The switching voltage is typically much less than the standoff voltage Symbol Table A
62. ation is used for each row on instrument MUX connector J1 1 15 an abbreviation for the concept of sourcing a voltage and measuring the resulting current or conversely sourcing a current and measuring the resulting voltage It sometimes generically refers to the Agilent E6171 Measurement Control Module 2 A Variable Reluctance Sensor VRS is an automotive sensor whose output is proportional to speed It generates an ac signal whose frequency and amplitude vary with speed Chapter 2 System Instrument Configuration 43 Isolated Source The programmable current and voltage source are similarly multiplexed to the interconnection column ABus The V I HiV and LoV amplifiers allow the user to source a voltage and measure the current or source a current and measure the voltage The V I amplifier is fully isolated The output is fused Agilent p n 2110 0516 at 1 amp It may be referenced internally to UUT Common through a relay or used differentially Isolation is possible because the parallel data from the V XI backplane is converted to a serial bit stream in a programmable logic array passed though an optical isolator and then converted back to parallel data to control the V I amplifier DACs The V I uses two separate amplifiers a low voltage amplifier LoV 16 V at 200 milliamp and a high voltage amplifier HiV 100 volt at 20 milliamp The high voltage amplifier is powered from a dc to dc converter that has a safety inte
63. contain a single entry point and typically perform a single action such as measuring a pulse Setup Cleanup routines can consist of a single Setup routine a single Cleanup routine or a paired Setup and Cleanup routine Paired Setup Cleanup routines contain two entry points and typically bracket an Execute action or series of actions For example a Setup routine might put the DUT into a particular mode Setup action an Execute routine could then make a measurement Execute action then a Cleanup routine would return the DUT to idle mode Cleanup action Sense resistor 136 Glossary SCPI Acronym for Standard Commands for Programmable Instruments Safety Shroud A cover for the DUT that protects personnel from possible contact with dangerous voltages on the DUT The shroud should be physically connected to a NO normally Open safety switch that is closed only when the shroud is in place The switch is wired across the two interlock pins on J3 of the Measurement Control Module These pins are wired to 1A13 and 1A15 of the ITA Self test A test executed by an instrument or system on itself to verify the functionality of the instrument or system Sense See Current sensing Serial Card A device to allow serial one wire communications between computers Slot Address The slot number a VXI module occupies in a single mainframe system In the case of a two mainframe system the slot addresses for the second mainframe begin
64. ctor Blocks The connectors between the ICA and the ITA Instrument Handler An additional layer of software between Agilent TestExec SL and a device driver By providing a set of well known functions through which the Test Executive software communicates with device drivers an instrument handler enhances Agilent TestExec SL s ability to control devices Interlock Event An interrupt generated when the high voltage safety interlock circuit is opened ISA Standard PC data bus Isense and Isense The Switch Load Unit has a two line current sense bus along the its backplane This Current sense bus can be broken into as many as four discrete buses by removing jumper plugs on JP1 JP2 and Current sensing is performed on any load card channel across a four terminal current sense resistor Two load cards are designed to connect to the current sense bus in the Switch Load Unit The 8 Channel and 16 Channel High Current Load Cards Each channel s current sense lines are multiplexed so that on each card only one channel at a time can be connected to the Switch Load Unit current sense bus Isolated Inputs Inputs that have the common connected to system ground Glossary 131 Interface Test Assembly The half of the mass interconnect It is the base of the test fixture J Jumper Comb A comb shaped shorting bar with a plastic covering over the metal spine of the comb It is used to jumper together some or all
65. cy capability is 0 3 of reading of 1 mA 0 0007 mA 0 003 1 0 0007 0 0037 mA 112 Test Capabilities and System Requirements Appendix A 12 5 Unit Under Test UUT Interface Test Adapter ITA or Fixture Interface Connector Adapter ICA or Fixture Receiver TTL VXI Close these Switches Interconnectionl Column ABus Trigger Multiplexer 2 Channels Tout Tin 9 VM Agilent E1411 DMM Appendix A Note A second load card should be used for the power return or the parallel sense resistors included in the calculations Figure A 2 Isense bead Isense Isense J1 Power Return Loads gt Relays shown energized Simplified Load Card Test Capabilities and System Requirements Output Driver Saturation Capability Sample 113 System Requirements Anti Static Surface Ramp Requirements Hallway and Door Width Requirements Environmental Requirements The approximate weight of a fully loaded two V XI mainframe system with one Agilent 6673A power supply is 350 kilograms 750 pounds or 400 kilograms 900 pounds including the pallet and all included material the pallet weighs approximately 50 k
66. ddress by i e address value of 2 and so on The instruments are prioritized in the following order Agilent 34401 Digital Multimeter Agilent 33120 Arbitrary Waveform Generator Agilent 53131 Universal Counter The first instrument is always address 1 If the Agilent 34401 is not installed then the next instrument would be the Agilent 33120 with an address of 1 the next has an address of 2 and so on Power Supplies Locations and GPIB Addresses Chapter 2 The TS 5400 System uses one or more of the Agilent 6642A 6643A 6652A 6653A 6672A or 6673A Power Supplies The supplies are located in the in the lower front part of the system and numbered from bottom to top The lowest mounted power supply is PS1 Power Supply 1 the next higher is PS2 Power Supply 2 and so on The GPIB address of the lowest Power Supply PS1 is 5 with the address of each additional Power Supply incremented by 1 for example PS2 has a GPIB address of 5 1 6 System Instrument Configuration 31 VXI Module Locations And Logical Addresses One VXI Mainframe Algorithm Notes One Mainframe Optional Instrument Priority List Two VXI Mainframe Algorithm Refer to VXI Modules on page 34 for information on how to set the Logical Addresses of the modules For additional specific information about a particular VXI module refer to that module s user manual For cabling information refer to Chapter 4 System Cables and Connectors on page 63
67. do not work with this system With the new handlers you will be able to send and receive messages and data to the added devices Instrument Handlers on page 59 explains how to write custom handlers for new instrumentation If the additional instrumentation is the same kind as what is already in the system then no additional handler routines need to be written 3 Modify the system topology file Use the Switch Configuration Editor to add the new instrumentation to the system topology file SYSTEM UST See Modifying the system ust File on page 55 for specifics Installing Optional Using another vendor s switching module will require incorporating the product information in the appropriate software files System configuration Switching Modules file switch handler routines and the system topology files 54 Customizing the System Chapter 3 Adding Instruments to the system ust File Modifying the system ust File Using the System Configuration Editor Using the Topology Editor General Guidelines Chapter 3 The Agilent TS 5400 Test System provides a standard set of pre installed instruments or modules These instruments are identified to the test system in the factory provided system ust file This file also lists the aliases and wire nodes used in the system as shipped from the factory When instruments are added to the system you must add them to the system ust file so that the software can recognize and use
68. duction 23 Connectors se 58 8 25 Connectors High Power Connectors Open RF Connectors High Power Connectors 2 2 5 5 Test Connectors TC7 123456 Test Connectors TC4 128456 moouuOr x mo gt 2 8 0000000000000 0000000009000 000000000 0000000000000 0000000000004 0000000000000 3000000000000 0000000000000 DDODDDDDODOODCCC 0000000000000 0000000000000 0000000000000 monuu gt 5 8 ooo 0000000000000 2000000000000 0000000000 0000000000000 0000000000000 0000000000000 naaaaaoaoannd 0000000000000 000000000000 0000000000000 2000000000000 0000000000000 monu ooo ooo 0000000000000 5000000009000 00000000000 0000000000000 0000000000000 00060000009800 0000000000000 0000000000001 00000000000 0000000000000 0000000000000 0000000000000 4monuu rov azz mo 0000000000000 00000000000 0000000000009 0000000090009 0000000000000 2000000000000 monuuOr x zz 0600000000000 0000000000000 mo gt 288 0000000000000 0000000000000 0000000000000
69. e instrument This includes setting the logical addresses LADDR IRQs and jumpers 2 Installing the instrument in the VXI mainframe or rack 3 Installing all needed cabling connections from the new instrument to the mass interconnect GPIB and Measurement Control module 4 Installing connections from the mass interconnect to the UUT Once the hardware configuration and wiring assignments have been made the files documenting the system configuration and topology must be edited as well as the files that allow the added instrumentation to interact with the Agilent TestExec SL program This includes 1 Modifying the SYSTEM UST file See Modifying the system ust File on page 55 for more information Customizing the System 51 2 Writing and compiling the necessary instrument handler or series of handler action routines for the instrument and placing them in a DLL See Instrument Handlers on page 59 for more information 3 Writing a self test for the instrument Configuring and Installing Additional VXI Modules VXI compatible modules can be installed in the VXI mainframe If the addition of another module requires expansion of the system to another VXI mainframe see VXI Module Locations and Logical Addresses for suggested VXI module placement The Agilent TS 5400 is set up to interface with SCPI compiled SCPI and register based devices Each device added to the VXI mainframe will need a unique Logical Addres
70. e and performs self tests and communications tests on the system instrumentation Cedgn tpa requires an optional test fixture and performs more extensive loopback testing on the system Both testplans are located in C Program Files Agilent TS 5400 System Software testplan dgn Chapter 5 Using Agilent TestExec SL to Run the Testplan Use TestExec SL to select and run the following testplan to perform the system diagnostics C Program Files Agilen TS 5400 System Software testplan dgn D gn tpa Executing the To Execute testplan select Debug then or press F5 or press Testpl an Diagnostics will begin executing and report any errors it finds Answer any questions as appropriate to continue execution Hardware system diagnostic test generates a hardware failure the problem may be i i caused by an unrecognized module in the system You can use the Configu ration system ust file to determine which hardware is recognized in the Details system This file also lists aliases and wiring descriptions To select the file select View Listing Hardware Configuration and System Layer as shown in Figure 5 1 See Figure 5 2 for typical hardware listings Note that the listing includes the module description location logical address and other pertinent information Use this data to determine that all modules in the system are recognized 1 Click on View 2 Click on Listing ec SL
71. e problem is probably the module If the LED comes on during operation it may mean 5 Vcc is not stable glitching low or high which will cause the control circuitry to become unstable The Vcc monitor circuit will reset the circuitry disable the board and turn on the Fail LED If the Fail LED is on you cannot access the module and you will need to troubleshoot the cause of the Fail LED being on Green IRQ Means that there is an interrupt pending that has not been serviced If you are not using interrupts and the IRQ LED is on that is an indication of a problem Red Interlock Safety Interlock is open That means that you cannot close any relays or turn on the high voltage on the amplifier until the event has been cleared One cause for this may be that the UUT fixture is removed opening the high voltage safety interlock 44 System Instrument Configuration Chapter 2 Switch Jumper Settings E3750 01203 0515 0430 E1400 61605 cable 6 to 32 Pin Matrix Module To E1411B DMM To E6173A Arb To E1563A Digitizer 11 To E1333A Counter 11 To Mux Unassigned 8 or 32 Not Available To Debug Panel 27 ABus1 ABus2 ABus3 ABus4 To Trig Mux 32 Trig 1 through Trig 4 To Trig5 amp 6 Instruments 32 To Trig7 Event Detector 11 To Trig7 Debugln 11 Interlock 8 10 27 Figure 2 8 shows the Agilent E6171B logical
72. ed in or out of a power supply circuit on command MAC Panel Mass interconnect panel marketed by Agilent Mass Interconnect The main connection panel for connecting the test system to the test fixture The mass interconnect consists of an ICA Interface Connector Assembly on the system side and an ITA Interface Test Assembly on the test fixture side Matrix A relay switch configuration that allows any column to connect to any row and also allows multiple columns to be connected to multiple rows simultaneously Contrast to Multiplex Master Keyword Master keywords are keywords stored on a predefined list in the Action Definition Editor s initialization file Keywords on the master keyword list are listed below the new keyword box in the Keywords portion of the Action Definition window You can add a master keyword to any action MCM Measurement Control Module A V XIbus card specifically designed to multiplex the measurement lines and the measuring devices available Up to 16 signals can be multiplexed to the 4 wire interconnection column ABus and DUT Common It provides an isolated V I programmable voltage and current source bidirectional trigger multiplexing and several other supporting functions Module A hardware resource in the system As used in this manual specifically a V XIbus compatible module instrument MOV Metal Oxide Varistor An electronic component whose characteristic resistance changes dramatically
73. electronic components have an identifying part or model number If the part you need is part of a system instrument for example the E1411B DMM the part may be listed in the hardware manual for that instrument If the part you want is not identified in any manual you can call Agilent for help see Service and Support on page 6 of this manual When ordering a part please have the following information ready Part or model number and description example Agilent E6174A 32 Channel Event Detector Serial number example 1234456789 if applicable Quantity needed Table 6 3 lists the replaceable parts for Agilent E8780B and E8786B systems Cable drawings and part numbers are shown in Chapter 4 of this manual Replaceable Parts Table 6 3 E8780B E8786B Replaceable Parts Part Number Description PC Kits E8770 80026 850 MHz Industrial PC Advantech 5065 6663 Keyboard 1150 7970 Mouse 1150 7913 Plain Shelf E3666A Windows NT 4 0 Recovery Package E8770 68002 Appendix B Parts Lists 119 Table 6 3 E8780B E8786B Replaceable Parts Part Number Description Advantech Industrial PC Components 850 MHz 0960 2282 0950 4396 0950 4395 3160 4160 0950 4345 0950 2656 0950 4407 1818 8888 Single board computer PC Backplane Power Supply Fan CD ROM Drive 3 5 Floppy Drive 40GB Hard Disk Drive Memory 256 MB Monitors E8770 8070
74. enu for software information Chapter 1 Conceptual Block Diagram Figure 1 3 shows is a simplified TS 5400 system block diagram showing the key system hardware components The system hardware components are described in detail following the figure Chapter 1 System Introduction 15 sng Ajddng XEN V 64983 4 es 5 peor Ajddng sng 6 JoMOd sng Jewod 5 V86193 Hed XUN zE inn 591 gt 159 3 BIHBON S w __ VcC6Z83 94x9 2129 jeuondo ue5 uonound 0515 jeuondo V96193 10 1 2 ssaJdx3 10 OVIN 5 6 159 sng Bojeuy WING V 1066 jeuondo XEN 91 9 Jeznifig v 4193 jeuondo WOW 10433002 pue 5 91 193 WING eysa 911713 9 IXA Figure 1 3 Agilent TS 5400 System Simplified Block D
75. erter 27 E3751 61601 78 Digitizer E3857 61613 79 E1563A 39 E6170 61603 80 Direct Connect Instruments 27 E6170 61604 81 Driver Current Leakage E6170 61606 82 System 112 E6170 61609 83 Driver Saturation E6170 61610 78 system 110 E6170 61611 84 E6170 61612 71 E E6170 61613 85 E1066 61620 cable 64 E6170 61614 65 E1072 61620 64 E6170 61615 86 E1400 61605 64 E6189 61600 87 E3750 61602 64 E6230 61603 88 E3750 61603 cable 64 E6247 61601 89 E3750 61604 65 E3750 61608 66 E3750 61612 67 E3750 61613 68 E3750 61614 69 E8770 61601 90 Calibration Overview 97 Conceptual Block Diagram 15 Conti guration 3750 61615 70 mass interconnect 23 E3750 61621 71 Configuring additional GPIB Instruments 52 E3750 6162 d 72 Connecting E3750 61625 73 Instrument Input s to the Measurement E3750 61626 75 Control Module 53 E3750 61627 77 Connectors And Cables 63 E3751 61601 78 Counter E3857 61613 79 Agilent E1333A 35 E6170 61603 80 Current Leakage E6170 61604 81 system driver 112 E6170 61606 82 Customizing the Agilent TestExec SL Software 54 E6170 61609 83 Customizing the Agilent TestExec SL Software to E6170 61610 78 Accommodate Additional E6170 61611 84 Instrumentation 54 E6170 61612 71 Customizing the System 51 E6170 61613 85 E6170 61614 65 D E6170 61615 86 D A Converter E d E6230 61603 88 E6247 61601 89 E8770 61601 90 Pr Electromagnetic Compatibility Requirements 117 Description Environ
76. est System Interface or Mass Interconnect The 32 pin matrix is a 4 x 32 matrix with series disconnect and bypass relays as shown in Figure 1 5 The default mode for each column has 2000 protection resistor in series with each column with the parallel bypass relay open This provides relay protection while allowing two wire ohms measurements when the parallel relay is closed The disconnect relay switches reduce the parasitic capacitance on the bus when open The auxiliary Aux relays allow a switchable path from a node on the UUT to one of the Direct Connect ICA Detectors Sources Test System Interface or Mass Interconnect Typical uses for the Aux relays include connecting an optional DAC Digital I O or other system resources such as the Agilent E1418A DAC Chapter 1 96 Pin DIN C To Instruments Abus Access 1 Abus Access 2 Abus Connector 96 Pin DIN C Rear Aux Access Chapter 1 16 x 5 Instrument Matrix Insti iL DAC2 Inst2 i rh I I Dg DACCOM Inst3 1
77. file close the file and then reopen the file to view all of the aliases channels and wire connections associated with the newly installed module For those instruments that can be directly connected to the Agilent E6171 Measurement Control Module the system asks if the instrument to be installed is to be connected to the first MCM before it automatically wires the module If it is the first instrument then wiring is generated to connect to the MCM If it is not the first instrument no automatic wiring is generated and you must specify the wiring Customizing the System 55 56 Customizing the System Some instruments require an Agilent model number in the Name field For example the Agilent E6176 is the model number for the 16 Channel High Current Load Card Agilent 6643A is the model number for the Dual output GPIB Power Supply do not use E6187A which is the Agilent TS 5400 Series Product Number for the power supply Do not attempt to expand channel nodes that is do not double click on individual channel nodes You cannot change the parameters When a module is installed channel modules are generated when appropriate Refer to the Agilent TestExec SL Online Help for specific instructions on how to add a module to the system ust file Chapter 3 Instrument Reset Management Reset Invocation Specifying a Reset Routine Specifying a Reset Routine Using the System Configuration Chapter 3 Ed
78. hannel 1 E3750 61621 Row 7 E1563 Channel 1 Row 9 E1563 Channel 2 E6247 61601 Row 11 E1333 Channel 1 Row 12 E1333 Channel 2 E3750 61604 Row 20 Abus 1 Row 2 Abus 2 E1072 61620 From the E8792 Pin Matrix rows 20 23 in that Row 22 Abus 3 order Row 23 Abus 4 Row 24 Extriq jumper 1 Row 25 Extriq jumper 2 E3750 61612 From ICA IA rows 16 19 in that order Row 26 Extriq jumper 3 Row 27 Extriq jumper 4 Row 30 E6174 Gate E3750 61604 Rows 31 Debug Trig E6170 61614 From Debug Trig coax connection on monitor rack mount Row 32 Interlock E3750 61602 If connecting additional instrumentation to the MCM module rows 13 16 on JI may be available Optionally if some of the factory default modules are NOT included in your system some of rows 1 12 may also be available Chapter 3 Customizing the System Customizing the Agilent TestExec SL Software to Accommodate Additional Instrumentation Each added instrument or altered configuration will require some or all of the following files to be written or modified 1 A modified SYsTEM UST file See Modifying the system ust File on page 55 for details 2 An instrument handler routine Each instrument type requires a piece of software called an instrument handler be written for it so the instrument can communicate with the Agilent TS 5400 system You will have to write handlers for these additional devices The handlers written for Lab Windows National Instrument s Labview and Agilent VEE
79. hannel Universal Counter Module 35 Agilent E1411B Digital Multimeter Module 36 Agilent E1418A 8 16 Channel Digital Analog Converter Module 37 VXI Technology E1563A 2 Channel 800 ka s Digitizer ADC Module 39 40 Agilent E8491B PC Link to VXI Interconnect 40 VXI MXI 2 Interface Mod le 2 42 Agilent E6171B Measurement Control Module 43 Agilent E6173A Arbitrary Waveform Generator ARB Module 46 Agilent E6174A 32 Channel Event Detector Module 47 Programmable Power 48 GPIB Address Selection pend attente een 48 Agilent 6642A DC Power Supply 48 Agilent 6643A DC Power Supply eese eene 48 Agilent 6652A DC Power Supply 48 Agilent 6653A DC Power Supply 48 Agilent 6672A DC Power Supply 48 Contents 7 8 Contents Agilent 6673A DC Power Supply 49 Chapter 3 CustOmiZing the 51 Chapter Contents ice ec een ea eae ou a ee dea aca E 51 Customizing the System us edad tee d teet aie en tote totes 51 Configuring and Installing Additional VXI 52 Configuring and Connecting GPIB Instruments
80. he autoadj tpa testplan adjust potentiometer R 197 front panel of the Agilent 6171 module to match the indicated reading See Figure 6 4 Select the OK button in the adjustment box Note select the CANCEL button if you are unable to center the vertical bar System adjustment is complete 1 Potentiometers R196 and R197 are very sensitive Typically you should rotate the controls only a slight amount Rotating clockwise moves the bar to the right rotating counterclockwise moves the bar to the left Chapter 6 Calibration and Preventive Maintenance 103 AutoAdj Test Codes and Types The following are some of the codes that shows the mapping between the test number ID in auto adjust and what part of the Measurement Control Module was measured Some of the acronyms used to identify the different parts of the MCM in Table 6 1 Use the acronyms to determine the part of the MCM was measured for troubleshooting purposes Table 6 1 Acronyms and MCM Circuitry Locations Acronyms MCM Part LVxx Low Voltage source HVxx High Voltage xxCV Constant Voltage xxCl Constant Current Comp Comparator Xfrm transformer DRxx Delta Resistance resistance differences between A Buses FVMI Force Voltage Measure Current an MCM internal setup Attn Attenuator There are 43 parameters measured ID 0 to 42 as listed in Table 6 2 You can use the values li
81. he 1st SLU 0950 3625 SLU Power Supply 70 W Appendix B Parts Lists 121 Table 6 3 E8780B E8786B Replaceable Parts Part Number Description 3160 0928 SLU Fan DC 12V E6170 66502 SLU Backplane E8792A E8793A See above at Pin Matrix E8794 66201 E8794A Series IIB Custom Card Load Cards E1300 45101 Top Handle for Load cards and SLU cards E3750 84105 Bottom Handle for Load cards and SLU cards E3750 66505 24 channel Load card E6177A 0490 1774 Relay for 24 channel Card E6177A option 120 Express Connect Cable one loadcard to one TC slot E6177A option 005 General Purpose MAC connector block ICA Can connect up to 4 E6177A load cards to one MAC slot E6177A option 110 MAC Panel Cable Connects 1 loadcard to 5 of option 005 E3750 61626 MAC Panel Cable Connects 2 loadcards to of option 005 Recommend Replacement Part for ANY 24 channel MAC replacement cable E3750 66504 16 channel Load card E6176A 0490 1587 Channel Relay ST1 DC12V 0490 1839 Sense Relay for 16 channel Card 2110 0882 Fuse 5 Amp 250 for 16 channel Card E6176A option 120 Express Connect Cable one 16 or 8 ch load card to one TC slot E6176A option 005 MAC Block MAC Panel connector block Green Used for the E6176A E6175A and E6178B Loadcards In a standard configuration the connector block can be used for 2 16 channel cards 4 8 ch
82. he Agilent E6171A Refer to Figure 6 2 Chapter 6 Calibration and Preventive Maintenance 99 wie UAR MEASUREMENT CONTROL MODULE O access O trick EG B J1 LI AO piss R197 227 S 7S COM m 1 CAL 2 RES 3 ABus 4 Nan S S Connect 4 Ribbon Cable to Connector J2 Figure 6 2 Installing the Calibration Fixture on an Agilent E6171A Measurement Control Module 3 Select the OK button in the prompt box Note if you select the CANCEL button this portion of the Agilent E6171A calibration is not performed When prompted by the autoadj tpa testplan remove the test fixture ribbon cable and reconnect the ribbon cable from the E6172A Matrix Module Select the OK button in the prompt box The autoadj tpa testplan prompts with a box asking if you are ready to adjust potentiometers R196 and 197 These two adjustments are located on the front panel of the Agilent E6171A module Select OK to proceed with the adjustments If you select CANCEL the final manual adjustments to the module are not made 100 Calibration and Preventive Maintenance Chapter 6 7 When prompted by the autoadj testplan adjust potentiometer R196 front panel of the Agilent
83. he design specifications of the load cards Do not use the maximum capabilities of the Agilent 6673A through the Switch Load Unit Chapter 2 System Instrument Configuration 49 50 System Instrument Configuration Chapter 2 Chapter 3 Customizing the System Chapter Contents This chapter discusses steps for installing additional instrumentation and overviews information for common optional products Additional instrumentation may be incorporated by adding cards to the V XI Mainframe or adding GPIB controlled external rack and stack instruments Chapter contents are Customizing the page 51 Configuring and Installing Additional VXI Modules page 52 Connecting Instrument Input s to the Measurement Control Module page 53 Customizing the Agilent TestExec SL Software to Accommodate Additional page 54 Adding Instruments to the system ust page 55 Instrument Reset page 57 Instrument Handlers page 59 Customizing the System Chapter 3 Before adding an instrument to the system read through all of the following steps Gather the information required for each step before beginning the customization process The steps for customizing the system include 1 Setting all internal or hardware selected configurations for th
84. he instrument from the module manual specifications section usually in Appendix A for the particular range which will be used for the test 4 Calculate the sum of the accuracy uncertainty due to V XI modules specifications and system switch paths and compare it to accuracy required by the DUT Test Capabilities and System Requirements 109 System Capability A simplified dc accuracy sample test shown in Figure A 1 including DC Accu racy numbered offsets is used as an example Every relay in the measurement path needs to be included in the algorithm for calculating the system level Sample capability The source voltage of 12 5 volts is supplied by Power Supply 1 through the load card The 1 year Accuracy vs Aperture of reading volts specification of the Agilent E1411B DMM for dc voltage on the 64 volt range for 16 7 20 milliseconds is 0 025 1 0 millivolt The relays are all the same part number and are specified at 30 microvolts offset The calculated system capability accuracy on the 64 volt range using 16 7 20 millisecond aperture range when using the Agilent EI411B within its defined accuracy conditions is DC Accuracy offset offset DvmHi to Abus4 offset Series Disconnect Relay offset Protection Disconnect Relay offset Row 32 Matrix Relay offset DvmLo to DUTCommon equals 5 relay offsets of 30 each Calculated system capability 0 025 12 5 1 0 mV 54 30 uV 4 28 m
85. hould rotate the controls only a slight amount Rotating clockwise moves the bar to the right rotating counterclockwise moves the bar to the left Chapter 6 Calibration and Preventive Maintenance 101 10 Select the OK button in the adjustment box Note select the CANCEL button if you are unable to center the vertical bar 11 System adjustment is complete Adjustment Procedure Agilent E6171 Revision B Modules have the resistor standard built into the for Agilent E6171B module no test fixture is required Modules Remove the 4 ribbon cable from the J2 connector on the front of the Agilent 61718 module Fold and connect the ribbon cable to the J2 connector on the Agilent E6171B See Figure 6 5 102 Calibration and Preventive Maintenance MEASUREMENT CONTROL MODULE access m M COME RES 3 X 3 7 4Bus 4 a a 4 slom E M d Connect 4 Ribbon Cable HP 6471 Figure 6 5 Agilent E6171B Calibration Setup Chapter 6 Run autoadj tpa testplan When prompted by the autoadj tpa testplan adjust potentiometer R196 front panel of the Agilent E6171B module to match the indicated reading See Figure 6 3 Select the OK button in the adjustment box Note select the CANCEL button if you are unable to center the vertical bar When prompted by t
86. iagram Chapter 1 16 System Introduction System Hardware The Agilent TS 5400 systems contain all of the GPIB and or VXI instrumentation needed to test most electronics modules You may add additional GPIB instruments and or V XI modules and cabling to increase the test capabilities of the system If adding VXI modules when currently no VXI modules are present requires a VXI Mainframe The locations of the GPIB instruments and VXI modules in the VXI mainframe s and the test system interface or mass interconnect are standardized as much as possible Because the Agilent TS 5400 Series uses open system standards and is configurable by the system integrator systems at your site may be different from the factory configurations WARNING Debug Panel Analog Bus 1 ABus4 connectors are not intended for operator use On some Agilent TS 5400 Test Systems the Debug connector s common connection BNC outer connection is isolated from system ground and can have hazardous voltage and current during Agilent TS 5400 operation Refer to the Debug Panel s silk screen to determine if the Debug connector s common connection are floating Voltages greater than 30Vrms 42Vpk or 60Vdc are considered hazardous voltages Current greater than 8A or energy greater than 150VA is also considered hazardous Agilent E6171B powerful card contributes to the versatility of the system providing its own 4x16 matrix to connect instr
87. ich can be connected to the four analog buses or to the UUT common ground bus The UUT common ground bus may be an isolated ground return or switched through separate relays to V I ground It can be connected to system ground for diagnostic purposes The inputs for isolated instruments such as the Agilent E1411B Multimeter occupy two instrument channels Single ended instruments like the Agilent E1333A Counter occupy one instrument channel and are referenced to earth ground Rows one through ten are assigned to specific instruments The Agilent E1411B DMM must always be attached to rows one through four DvmHi DvmLo DVMISrcHi DVMISrcLo If an ARB is used with the system to source current or voltage it must be connected to inputs five and six If a Digitizer Analog to Digital Converter ADC is used with the system it must be connected to rows seven and eight for port 3 differential input if the attenuator Attn is used The factory default is to use rows nine and ten for the Digitizer port 4 differential input Ports 1 and 2 on the digitizer are the single ended inputs The counter channel one goes to row eleven and channel two to row twelve Rows thirteen through sixteen can be used for additional instrumentation The Debug Panel ports are connected directly to interconnect columns one through four and are referenced to system ground If any of the above instruments are not used in a specific system a recommended factory default configur
88. if an instrument that is supposed to make a measurement times out before returning a reading an exception has occurred Expander Block Provides various configurations of screw terminals There are two types of expander blocks currently used on the TS 5400 mass interconnect 4 Terminal Expander Block This is a four screw terminal block All four connection points are common 1 1 2 Expander Block This is a four screw terminal block but only two screws are con nected together Each of the other two screws acts as an isolated connection point F Factory Default Algorithm A systematic instrument and ICA configuration of the Agilent TS 5400 used by Agilent for shipping systems that do not have a customer specified instrument configuration This allows the re use of system topology data that describes the mapping of the system ICA connections Factory Default Configuration Standardized instrument locations switch and jumper settings and ICA connector locations used by the factory when assembling a TS 5400 system The default configuration differs between a one and two mainframe system Fixture An interface consisting of an Interface Test Adapter ITA fixture frame general purpose connectors high power coax connectors expander blocks blank slot covers and wires to a DUT connector This interface connects to the matching Interface Connector Assembly ICA of the mass interconnect See ITA Fixture Receiver See
89. ilograms 110 pounds and manuals etc account for the remaining weight Static electricity is destructive to your production process and your Agilent TS 5400 Test System Careless handling and poor planning can cost you yield and system reliability The test system may not be as easily damaged as the modules you will be testing but good anti static planning will ensure high reliability This is not the place to make an exhaustive description of anti static precautions but as a reminder as you plan your system area here are some suggestions Anti static flooring Plan for foot straps in conjunction with anti static flooring and wrist straps for system operators The cabinet has external connectors for wrist straps Grounding straps Plan to use an anti static floor covering or mats Anti static DUT storage Plan for anti static tote bins for your unit under test and storage for anti static bags Anti static hardware Consider the use of any devices that will help you maintain a static free environment Examples are wrist strap testers and ion generators It is a good idea to take a look at your current static conditions before planning the installation of your system When moved on its casters the cabinet will negotiate ramps with inclines up to 8 percent before the leveling feet drag on the floor Make sure that all doors elevators and passageways leading to the site are large enough to allow passage If you cannot move the s
90. is floating it requires two connections to the matrix module Instead of using the Agilent 33120 Arb you can use the Agilent E6173A Arbitrary Waveform Generator formerly Agilent Z2471A This is a register based two channel isolated both between channels and from ground waveform generator Channel one is connected to the Agilent 8792 32 Pin Matrix and Instrument Multiplexer Module Channel two may be connected by the customer directly to a UUT pin or the pin matrix module using an unassigned connector pin Since this is a C size single slot VXI module it requires a C size VXI Mainframe For additional information refer to the Agilent 33120 Arbitrary Waveform Generator User s Guide Chapter 1 Agilent 33220 Function Arbitrary Waveform Generator Agilent E6247A VXI Technology E1563A 2 Channel 800kSa s A D Digital Converter Digitizer or ADC Note Direct Connect Instruments Agilent E6174A 32 Channel Event Detector Note Agilent E1418A 16 Channel Digital Analog Converter Chapter 1 Module The Agilent 33220A function arbitrary waveform generator uses direct digital synthesis DDS techniques to create stable low distortion output signals The 33220A provides easy access to standard sine square ramp triangle and pulse waveforms plus you can create custom waveforms using the 50 MSa s 14 bit 64 K point arbitrary waveform function For additional information refer to the Agilent 33220
91. itor The Agilent TS 5400 system provides an automatic module instrument reset scheme to help ensure that all modules instruments are placed into a known safe state before executing a testplan in the event of a problem The modules instruments are configured in the system ust file for the reset operation instrument reset routines are automatically called when The system is started Agilent TS 5400 system controller detects an exception error and an error sequence is not defined You insert the predefined global reset action discussed below into a testplan or the error sequence If all reset routines execute without raising any exceptions the system then resets all registered switching modules loadcards and pin matrix modules Note that a reset function is only registered for instruments with a sub instrument number of zero This is because only a single reset is needed per instrument even if the instrument has sub instruments The Agilent TS 5400 system comes with a predefined action called globalReset which you can enter into the error sequence or any test This action executes all existing instrument reset routines The action definition file glbreset umd is located in this directory ProgramFiles Agilent TestExec SL actions handlers Refer to the Agilent TestExec SL online help for more information about error handling There are two different ways to specify a reset routine in a mod
92. ix A Test Capabilities and System Requirements 1 21 109 Appendix Contents nm RD tini ee iius 109 Test Capabilities Measurement Sample 109 System Capability DC Accuracy Sample 110 System Capability Driver Saturation Sample 110 System Capability Driver Current Leakage Sample 112 System Requirements 114 Anti Static Surface id Eee ee er dep 114 Environmental Requirements 114 Temperature Requirements 115 Miscellaneous Specifications eese ener 117 Electromagnetic Compatibility Requirements esee 117 Appendix B Parts Lists R 119 et ettet oneal nee ei nee nee deat 119 Identifying and Ordering Parts 119 tee ede ERI be 119 Replaceable Parts REED e fede eq Hd 119 Recommended Spare Parts 124 Contents 9 10 Contents Chapter 1 System Introduction Chapter Contents This chapter gives an introduction to the Agilent TS 5400 Functional Test System Chapter contents are Typical System ep hk Rae
93. k The E1418A can be configured for Isolated or Non Isolated channels Switch Jumpers Figure 2 3 shows the Agilent E1418BA logical address switch with the switch shown in the factory setting Set the logical address to match the VXI mainframe slot number for a one mainframe system For a two mainframe system set to the slot number plus 16 if in mainframe 1 or to the slot number plus 32 if in mainframe 2 Refer to VXI Module Locations And Logical Addresses on page 32 The Interrupt Priority is always set to 1 Keep the other switches in the default position as shown Logical Address Factory Default 72 shown TS 5430 5450 One Mainframe Slot TS 5450 Two Mainframes Slot 16 or Slot 32 if in mainframe 2 CAL Store Enable Jumper Secured Cal Figure 2 3 Agilent E1418A DAC Module Chapter 2 System Instrument Configuration 37 Cabling Figure 2 4 shows the wiring for the Agilent 1418 DAC Module using the terminal module connector Two Agilent E3750 61608 cables connect the module to the mass interconnect the mass interconnect connector has the same pin out as the module Refer to Chapter 4 on page 63 for wiring information on the cable CH 1 PROG JMPR CH 1 HS CH 2 PROG JMPR CH 1HI CH 3 PROG JMPR CH1LO CH 4 PROG JMPR CH1LS CH 9 PROG JMPR CH2HS CH 10 PROG JMPR CH 2HI CH 11 PROG JMPR CH2LO CH 12 PROG JMPR CH2LS CH 1 MODE JMPR CH3HS CH 2 MODE JMPR CH 3 HI CH 3 MODE JMPR CH3LO
94. me 1 or to the slot number plus 32 if in mainframe 2 Refer to VXI Module Locations And Logical Addresses on page 32 The Interrupt Priority is always set to 1 Both the servant area and bus request factory defaults are correct Logical Address Switch Location Logical Address Factory Default 40 shown TS 5430 5450 One Mainframe Slot TS 5450 Two Mainframes Slot 16 or Slot 32 if in mainframe 2 00 s 32 o E e 128 Figure 2 5 E1563A Digitizer Switch and Jumper Settings Chapter 2 System Instrument Configuration 39 Agilent E8491B The E8491B interconnect links the IEEE 1394 bus to the backplane of the i VXI mainframe The E8491B is a C size device with VXI Resource Link to VXI Manager and Slot 0 capability Interconnect There are no configuration switches on the E8491B The device s logical address is 0 and it provides the system s resource manager functionality via software that is part of the Agilent I O Libraries Its VXI servant area is 255 therefore it is the interface to all VXI devices with logical addresses between and 255 The E8491B is normally but not required to be installed in mainframe slot 0 Installing the E8491B following installation steps are referenced to Figure 2 6 into the VXI Mainframe 1 If power is applied to the VXI mainframe remove power to the VXI mainframe and disconnect all power sources that may be applied to any inst
95. ment Assistance Center 81 0426 56 7832 Latin America 305 269 7548 Asia Pacific 85 22 599 7777 Safety and Support Information Contents Chapter 1 rubi pet 11 Chapter 11 sade rp oerte eti peto bre 11 System sob emt ed epe ite 14 Conceptual Block 15 System Hardware need E RETI 17 Agilent E6171B Measurement and Control Module 17 Agilent E6198A Switch Load Unit 18 Agilent E8792A and E8793A Pin Matrix Cards 18 koad Cards tidie Hee eren Qt ee ea 22 Test System Interface or Mass Interconnect 23 Multiplexed Instruments 2 ederet eni 25 Direct Connect 27 Programmable Power Supplies 2 29 Chapter 2 System Instrument Configuration 31 Chapter Contents e tee eee 31 GPIB Instrument Locations And Addresses 31 Power Supplies Locations and GPIB Addresses 31 VXI Module Locations And Logical Addresses eee 32 One VXI Mainframe Algorithm 32 Two VXI Mainframe Algorithm eese 32 VXI Modules e aeter edente i npe ee ER e eet 34 Agilent E1333A 3 C
96. mental Requirements 114 hardware 17 Event Detector system 14 Agilent E6174A 27 47 Diagnostics Strategy 92 Exchange Assemblies 91 Diagnostics Tests 95 system 95 Agilent E1418A 37 DC Accuracy 110 Debug Panel 17 144 Index General Guidelines system customization 55 Glossary 125 GPIB Addresses instruments 31 GPIB Instrument Locations 31 GPIB Instrument Locations And Addresses 31 GPIB Instruments installing additional 52 GPIB Addresses power supplies 31 H Handlers instrument Handlers module 59 Hardware description 17 ICA 23 Installation VXI module 32 Installing additional GPIB Instruments 52 Installing Optional Switching Modules 54 Instrument Handler Clear 60 Conf 60 ConfCal 60 ConfInControls 60 ConfOutControls 60 ConfSample 60 ConfSync 60 ConfTrigIn 60 ConfTrigOut 60 Connect 60 Disconnect 60 Get 59 GetResults 59 Initiate 60 IsSet 60 Reset 60 Return 60 Set 59 Trigger 60 Instrument Handlers 59 61 standard functions 59 Instrument Reset 57 Instrument Reset Management 57 Instruments GPIB addresses 31 Interface Connector Adapter ICA 23 Interface Test Adapter ITA 23 Invoke reset on instrument 57 reset on modules 57 ITA 23 J Jumper Settings 34 L LADDR 34 LEDs Agilent E6171 44 Measurement Control Module 44 Load Card Agilent E6175A 22 Agilent E6176A 22 Agilent E6177A 22 Load card 22 Location VXI module 32 Location
97. n a Test Chapter 5 System Diagnostics 95 96 System Diagnostics Chapter 5 Chapter 6 Calibration and Preventive Maintenance Calibration Overview Products Requiring Calibration Chapter 6 Calibration is recommended for VXI modules or individual instruments on an annual basis Typically this requires removing the V XI module s or instruments from the system for calibration The Agilent E6171A B Measurement Control Module is automatically adjusted by the system software When the Agilent TestExec SL software is started the automatic adjustment constants are down loaded and the time stamp is checked If there has been more then 30 days since the last time the automated adjust has been run a dialog box will ask you if you would like to run the automatic adjustment This adjustment should be run whenever the system configuration changes the E6171A B is replaced another VXI module has been replaced there is a greater then 5 C temperature change or every 30 days The adjustment procedure uses the Agilent E1411B to determine the correction constants Customers have the choice of having the VXI modules except the Agilent E6171A B which must be calibrated as part of the system or instruments calibrated before leaving the factory or upon installation Either service is available at an extra charge This service will need to be quoted by the local Agilent Field office Exchange V XI assemblies from Agilent s Support Materials Org
98. n page 4 4 Ground the System To minimize shock hazard the system chassis must have a hard wired connection to an electrical protective earth ground The system must also be connected to the ac power mains through a power cable that includes a protective earth conductor The power cable ground wire must be connected to an electrical ground safety ground at the power outlet Any interruption of the protective grounding will cause a potential shock hazard that could result in personal injury Fuses Use only fuses with the required rated current voltage and specified type normal blow time delay Do not use repaired fuses or short circuited fuse holders To do so could cause a shock or fire hazard Operator Safety Information MODULE CONNECTORS AND TEST SIGNAL CABLES CONNECTED TO THEM CANNOT BE OPERATOR ACCESSIBLE Cables and connectors are considered inaccessible if a tool e g screwdriver wrench socket etc or a key equipment in a locked cabinet is required to gain access to them Additionally the operator cannot have access to a conductive surface connected to any cable conductor High Low or Guard Safety and Support Information ASSURE THE EQUIPMENT UNDER TEST HAS ADEQUATE INSULATION BETWEEN THE CABLE CONNECTIONS AND ANY OPERATOR ACCESSIBLE PARTS DOORS COVERS PANELS SHIELDS CASES CABINETS ETC Verify there are multiple and sufficient protective means rated for the voltages yo
99. nit FRU which is usually a VXI module cable or a relay All FRUs are listed in Appendix B Parts Lists Rebuilt exchange assemblies are available for many Agilent VXI modules However there are no exchange assemblies available for the load cards If a load card fails you have two choices purchase a new load card or troubleshoot the problem and repair it If the problem is a relay and you can determine which relay is defective you can repair the module The relays are through hole technology and easy to replace Service manuals for most system instruments are installed on the system computer and can be accessed from Test Exec SL by clicking Tools TS 5400 Online Manuals WARNING troubleshooting the system voltages capable of causing bodily injury or death may be encountered Troubleshooting must be performed only by service trained personnel Chapter 5 System Diagnostics 91 AVERTISSEMENT Lors du d pannage il est probable que des tensions pouvant Caution causer des blessures ou la mort soient pr sentes Le d pannage ne doit tre confi qu un personnel d entretien qualifi To prevent electrostatic discharge ESD from damaging sensitive system components always wear a grounded anti static wrist strap when working on the system Diagnostics Strategy 92 System Diagnostics Two diagnostic testplans were developed for your test system at the factory Dgn tpa does not require a test fixtur
100. nnel expander board for 16 channels 1 4 E3750 66206 E6178B 8 channel Heavy Duty Load Card rebuilt 1 2 E6170 66002 Serial Protocol Adapter Multicom 111 1 4 124 Parts Lists Appendix B Glossary 2x1 A single conductor cable with a shield return See the Measurement Control Module instrumentation cabling diagrams in Chapter 4 System Cables and Connectors on page 63 3x1 A twinax 2 conductor cable with a shield See the Measurement Control Module instrumentation cabling diagrams in Chapter 4 System Cables and Connectors on page 63 5x1 Multiplexing Refers to the four channel ABus and the single channel DUT Device Under Test Common ground A ABus Acronym for Analog Bus The four bus lines plus the DUT Device Under Test Common bus that make up the interconnection column of the relay matrix in the Measurement Control Module and 32 pin Matrix Module AComp Acronym for Analog Comparator It is the comparator input to Measurement Control Module Action The smallest component of a test An action is a routine or set of routines that do something useful such as making a measurement action has a name library name author and associated keywords documented with it The types of actions are execute setup and cleanup Execute actions are used to make measurements while setup and cleanup actions are used to do some task before and after an execute action respectively Actions
101. nt E1333A 3 Channel Counter Chapter 2 System Instrument Configuration 33 VXI Modules This section describes the individual VXI modules used in an Agilent TS 5400 system the switch and jumper settings and cabling to the modules For additional information on any of these modules refer to the user s manual included with each module Before installing a new or replacement VXI module in a mainframe verify that its switches or jumpers are set as shown in this section DO NOT assume that the factory settings are correct you may have to change the factory settings for this application in the Agilent TS 5400 system Note Inthe following descriptions the factory default Logical Address is the address that an exchange module or new non system integrated module is normally set to The Agilent TS 5400 Logical Address is the logical address of a module installed in a Agilent TS 5400 system The following modules are included or are optional Agilent E1333A 3 Channel Universal Counter Module page 35 Agilent EI411B Digital Multimeter Module page 36 Agilent E1418A 8 16 Channel Digital Analog Converter Module page 37 VXI Technology E1563A 2 Channel 800 ka s Digitizer ADC Module tie REV RR ENS page 39 VXI MXI 2 Interface Module page 42 Agilent E6171B Measurement Control Module page 43 Agilent E6173A Arbitrary Waveform Generator ARB Mod
102. nts applicable to more than one instrument and other common information Common functions used by many types of instruments use consistent names Although the parameters used by these routines may vary by instrument type the names themselves are consistent Because of system buffering no command can be assumed to have been actually sent to the instrument until a Set statement has been issued and the IsSet routine has returned true Customizing the System 61 62 Customizing the System Chapter 3 Chapter 4 System Cables and Connectors Chapter Contents This chapter shows all possible cables used in Agilent E8780 and E8786 Systems These cables are for all systems no one system will contain all of these cables Cables are listed by part number as follows E1066 61620 E3750 61603 Twinax 3x1 to Banana page 64 E1072 61620 E3750 61602 Twinax 3x1 to 3x1 page 64 E1400 61605 1x6 ABus Ribbon page 64 E3750 61604 E6170 61614 BNC Coax to 3x1 Cable page 65 E3750 61608 96 Pin 64 Conductor to 96 Pin DIN Cable page 66 E3750 61612 2x1 Coax to 2x1 Drain Hi Cable page 67 E3750 61613 Serial Interface page 68 E3750 61614 8 Channel Load Card page 69 E3750 61615 16 Channel Load Card Cable page 70 E3750 61621 E6170 61612 Male BNC Coax to 3x1 Isolated Instrument Cable euer there
103. or Twisted Pair Cable 47 Agilent E6171 Measurement Control Module 43 LEDs 44 Agilent E6171A Modules adjustment procedure 99 Agilent E6171B Modules adjustment procedure 102 Agilent E6172A 32 Pin Matrix Module 20 Agilent E6173A Arbitrary Waveform Generator 46 Agilent E6174A 32 Channel Event Detector 27 47 Agilent E6175A 8 Channel High Current Load Card 22 Agilent E6176A 16 Channel High Current Load Card 22 Agilent E6177A 24 Channel Medium Current Card 22 Agilent E6186A Power Supply 29 Agilent E6187A Power Supply 29 Agilent E6188A Power Supply 29 Agilent E6189A Power Supply 29 Agilent TestExec SL Software customizing 54 Agilent TestExec SL software 14 Agilent TS 5400 Customizing the System 51 Agilent Z2471A Arbitrary Waveform Generator 46 Agilent Z2902A 32 Channel Event Detector 27 47 Anti Static Surface 114 ARB Agilent E6173A 46 ARB Agilent Z2471A 46 Assemblies rebuilt or exchange 91 AUX Relays 18 20 B Block Diagram conceptual 15 Block Diagram system 15 C Cabinet Size 11 Cable Agilent E3751 61601 Twisted Pair Matrix 47 E3750 61621 46 Cables 63 E1066 61620 64 E1072 61620 64 E1400 61605 64 E3750 61602 64 E3750 61603 64 E3750 61604 65 E3750 61608 66 E3750 61612 67 E3750 61613 68 E3750 61614 69 E3750 61615 70 E3750 61621 71 E3750 61624 72 Index 143 E3750 61625 73 Digital Multimeter E3750 61626 75 Agilent E1411B 26 36 E3750 61627 77 Digital Analog Conv
104. page 71 E3750 61624 8 Channel Heavy Duty Load Card Cable 30A page 72 E3750 61625 24 Channel Medium Power Load Card Cable page 73 E3750 61626 Dual 24 Channel Load Card Cable page 75 E3750 61627 Power Supply page 77 E3751 61601 E6170 61610 64 Conductor Twisted Pair Cable page 78 E3857 61613 Rack On Off Switch to PDU Cable page 79 E6170 61603 E8792 93 to MAC Panel Cable page 80 E6170 61604 E8794 to Mac Panel or Express Connect and SLU Interconnect Cable page 81 E6170 61606 Power Bus Jumper Cable page 82 E6170 61609 External Power Cable 6653 6673 page 83 E6170 61611 SLU to UUT Low Current Power Supply Cable 6628 6043 sR etu eee page 84 E6170 61613 DAC to Pin Card Aux Cable page 85 E6170 61615 DAC to Custom Card page 86 E6189 61600 Power Supply Power Cable page 87 E6230 61603 Heavy Duty Load Card Cable page 88 6247 61601 Cable Digitizer E1563A page 89 E8770 61601 External Power page 90 Cable Identification Each cable in your system has an identifying Agilent part number on the Chapter 4 cable Use that part number to reference cable drawings in this chapter System Cables and Connectors 63 E1066 61620 3750 61603 Twinax 3x1 to Banana Twinax
105. pply Agilent 6672A DC Power Supply Caution The programmable power supplies or UUT power supplies include the Agilent 6642A 6643A 6652A 6653A 66724 and 6673A power supplies These supplies provide power to the unit under test The first UUT power supply in the system should have a GPIB address number 5 The second power supply should be set to GPIB address 6 and the third power supply to address 7 If you need to change the power supply s address refer to user manual for that power supply You must add the address information to the SYSTEM UST configuration file Refer to Adding Instruments to the system ust File on page 55 for specific information on updating the configuration file The Agilent 6642A DC Power Supply is a 1 output 0 20 volt 0 10 A GPIB supply You can set the supply to 100 volts 120volts 220 volts and 240 volts ac line voltage input by setting the line voltage select switches Refer to the Agilent 6642A Power Supply User Manual for specific information The Agilent 6643A DC Power Supply is a 1 output 0 35 volt 0 6 A GPIB supply You can set the supply to 100 volts 120volts 220 volts and 240 volts ac line voltage input by setting the line voltage select switches Refer to the Agilent 6643A Power Supply User Manual for specific information The Agilent 6652A DC Power Supply is a 1 output 0 20 volt 0 25 A GPIB supply The supply can be set to accept 100 volts 120volts 220 volts and 240 volts
106. pt Priority is always set to 1 Logical Address Factory Default 80 shown TS 5430 5450 One Mainframe Slot TS 5450 Two Mainframes Slot 16 or Slot 32 if in mainframe 2 Note See the section Cabling Diagrams or the E6170 90101 cable drawing for Cable ID XX cross references E3750 61621 27 to E6171 Measurement Control Module Row 5 E3750 61621 27 to Mass Interconnect Connector 1A Row 12 46 System Instrument Configuration IRQ Factory Default and TS 5450 1 Figure 2 9 Agilent E6173A ARB Module Chapter 2 Agilent E6174A 32 Channel Event Detector Module Switch Jumper Settings The Agilent E6174A 32 Channel Event Detector formerly the Agilent Z2902A comes with cables and an Agilent 91421B ICA connector The Event Detector provides the capability to analyze 32 channel input event states and timings The events are stored in memory on the board then the events can be read back by the controller for event analysis Either the Agilent E6174A s internal sampling clock may be used an external clock can be selected to expand the measurement time Figure 2 10 shows the Agilent E6174A logical address switch with the switch shown in the factory setting Set the logical address to match the VXI mainframe slot number for a one mainframe system For a two mainframe system set to the slot number plus 16 if in mainframe 1 or to the slot number plus 32 if in mainfr
107. r External PC controller Refer to the Getting Started Guide that came with the VXI MXI 2 module for installation information Backplane Connector Note Install the VXI MXI 2 Module into Slot 0 Agilent E1401 Refer to the Getting Started Guide Mainframe for the VXI MXI 1 Module to configure the module 4 2 VXI MXI 2 Cable VXI MXI 2 Module Figure 2 7 Installing the VXI MXI 2 Interface Module 42 System Instrument Configuration Chapter 2 Agilent E6171B Agilent E6171A B Measurement Control Module MCM also known as the VI card in the Agilent TS 5400 Action documentation provides four Measurement primary functions Control Module 1 It provides a 16x5 matrix used to expand the four columns from the 32 Pin Matrix Module s and UUT Common to access up to 16 external instruments 2 It provides an isolated programmable voltage and current source with internal wiring that allows the external Agilent EI411B DMM to measure the sourced voltage or current The isolated V I amplifier may also be used to amplify signals from the Arbitrary Function Generator ARB and attenuate signals for digitizing 3 It routes triggers bi directionally between the UUT and external instruments 4 It provides a step up transformer to amplify the ARB s signal on VISrcHi to 80 volts peak to simulate VRS signals 16x5 Matrix The instrument matrix provides 16 external connections wh
108. r each of these power supplies For additional information refer to the respective power supply s user manual s supplied with your Agilent TS 5400 System Table 1 1 Agilent TS 5400 Programmable Power Supplies Agilent TS 5400 Product Number Contains Voltage Current Agilent E6187A Agilent 6643A Power Supply 0 35 V 0 6A Agilent E6188A Agilent 6653A Power Supply 0 35 0 15A Agilent E6189A Agilent 6673A Power Supply 0 35 0 60 Agilent E6238A Agilent 6672A Power Supply 0 20 V 0 100 Agilent E6242A Agilent 6652A Power Supply 0 20 V 0 25A Agilent E6248A Agilent 6642A Power Supply 0 20 V 0 10A System Introduction 29 30 System Introduction Chapter 1 Chapter 2 System Instrument Configuration Chapter Contents This chapter shows how to configure the different V XI and GPIB modules and instruments in the system Chapter contents are VXI Module Locations And Logical Addresses page 32 Power Supplies Locations and GPIB Addresses page 31 VXI Modules viz page 34 Programmable Power page 48 GPIB Instrument Locations And Addresses The TS 5400 System supports an Agilent 34401A Digital Multimeter 33120A Arbitrary Waveform Generator and 53131A Universal Counter The GPIB address always starts with a 1 on the first GPIB instrument The next instrument increments the a
109. rlock to shut it down if the UUT fixture is removed The V I amplifiers have three other functions The ARB can use the V I source as an amplifier and current sensor The ARB output can be amplified through a transformer to high voltages The programmable attenuator Attn can adjust the input levels for digitizing It can be used to linearly scale HiV UUT signals for digital testing This allows very high flyback signals to be measured without damaging the components in the V I amplifier The programmable comparator and open collector digital trigger allow triggering between system instruments referenced to ground and the floating UUT Trigger Multiplexer The trigger multiplexer consists of two independent bi directional multiple sources and multiple destination demultiplexer multiplexer channels for routing trigger signals to and from trigger resources Trigger resources include eight bidirectional TTL Trig In Out from the VXI backplane and eight bidirectional external trigger in lines The triggers can also be controlled by the Timer Counter Status LEDs Table 2 2 Agilent E6171 Measurement Control Module LEDs Color Name Meaning when on Green Access The VXIbus is reading from or writing to the module The only time it will stay on is if you are repeatedly addressing the module Red Fail If the LED remains on after the VXI mainframe is powered on it means that the module didn t power up correctly and th
110. ruments 2 Insert the E8491B into mainframe slot 0 by aligning the module with the guides inside the mainframe Figure 2 6 Slowly push the module into the slot until it seats in the backplane connectors It may be necessary to pull out not remove the retaining screws in order to seat the device securely in the connectors 3 Tighten the retaining screws on the top and bottom of the module 4 Connect the interface cable from the host adapter to E8491B port A B or C The ports are identical and unused ports are available to connect additional E8491Bs and other IEEE 1394 devices in a daisy chain or tree configuration Refer to the E8491B User Manual for more information 40 System Instrument Configuration Chapter 2 X Retaining Screws N f gt Seat module by pushing in the extraction levers SS M 9999 70 Slide the module into the mainframe until it plugs into the backplane connectors Figure 2 6 Installing the E8491B VXI Interface Card System Instrument Configuration 41 Chapter 2 VXI MXI 2 Interface The 2 Interface module provides communication between one Module VXI mainframe and an external controller PC Refer to Figure 2 7 The VXI MXI 1 module must be installed in slot 0 of your VXI mainframe Refer to the Getting Started Guide that came with the module for installation information Install the PCI MXI 2 Board into you
111. s LADDR set on the address switch before installation in the VXI mainframe The algorithm for the LADDR is the slot number of the instrument in the first VXI mainframe Configuring and Connecting GPIB Instruments 52 Customizing the System GPIB instrumentation can be added to the system by connecting the instruments s GPIB input to the system GPIB bus at either the system controller or at the power supplies Use any standard GPIB cable such as the Agilent 8120 3446 two meter GPIB cable GPIB compatible instruments require a unique GPIB address for each instrument Set the address on the instrument and then enter the address in the SYSTEM UST file editor See Modifying the system ust File on page 55 for more information Chapter 3 Connecting Instrument Input s to the Measurement Control Module Depending on the device connect the inputs to the UUT either through the Measurement Control Module or directly through the mass interconnect Table 4 12 lists instrument connector cables to connect the instrumentation inputs to the Agilent E6171 module For additional information on cables and connectors refer to Chapter 4 on page 63 Table 3 1 MCM Module Cabling 53 E6171B Instruments Cables to use for 6171B Connector Row Row 1 E1411 DVM E3750 61603 Grounds take up 2 middle posts DVM on top Row 3 E1411 Current Source Row 5 E6173 C
112. s GPIB Instruments 31 power supplies 31 Logical Address 32 M Mass Interconnect 23 Matrix Module Agilent E6172A 20 Measurement Control Module connecting instruments 53 LEDs 44 Minimum System Configuration 11 Modifying the system ust File 55 Module VXI installation 32 VXI location 32 Module Handlers standard functions 59 Module Instrument Handlers 59 Multimeter Index 145 Agilent E1411B 26 36 Multiplexed Instruments 25 N Naming Conventions 61 instrument handlers 61 module handlers 61 Optional Switch Modules installing 54 Options Rack 11 Ordering Parts 119 Overview calibration 97 system 14 P Panel debug 17 Parts ordering 119 Power Supplies Agilent 6628A 29 Agilent 6643A 29 Agilent 6653A 29 Agilent 6672A 29 Agilent 6673A 29 Agilent E6186A 29 Agilent E6187A 29 Agilent E6188A 29 Agilent E6189A 29 GPIB addresses 31 Power Supplies Locations 31 Power Supplies Locations And GPIB Addresses 31 Power Supply 29 Procedure system adjustments 98 Procedures verification 107 Product Version Capability using the 59 R Rack Mounting Options 11 Rebuilt exchange assemblies 91 Reset 146 Index instrument 57 instrument management 57 Reset Invocation 57 Reset Routine specifying 57 5 Settings switch and jumper 34 Software Agilent TestExec SL 14 system 14 Specifications 109 Specifying a Reset Routine 57 Specifying a Reset Routine Using the Sy
113. s card A nine inch by four inch area of sheet metal is left open on the front of the card to allow room for mounting loads The card requires two slots in the Agilent E6198 Switch Load Unit The Agilent E6176A provides 16 externally mounted loads The single slot design offers high load density for high current loads where LEM modules and bridge drive configurations are not required The customer determines where and how the loads are mounted externally Two load connectors J1 and J2 are used with loads one through eight on J1 and the remainder on J2 The flyback protection is connected from both the normally open NO and normally closed NC power switch connections The Agilent E6177A is used with loads mounted inside the Switch Load Unit A nine inch by four inch area of sheet metal is left open on the front of the card to allow room for mounting loads The card is one slot wide Each channel is capable of up to two amperes continuous carry current There are a variety of ways the pull up pull down capability of the card may be used One example is to pull input pins on the module to desired test states and test for the desired result Another common use would be to control an attenuator by switching in loads The Agilent E6178A provides current carrying capability of up to 30 amps per channel Loads are mounted externally and special power supply and load wiring cables are used The card requires two slots in the Agilent E6198 Switch Load
114. s that plug into the Switch Load Unit There are two types of pin matrix cards and four types of load cards described below These cards consist of a 32x4 matrix which provides fast connections into or out of the system for 32 rows into 4 columns plus a fifth column for UUTCOM The four columns are collectively referred to as the Analog Bus High reliability switching is assured through jumper removable protection resistors on the cards Additional pin matrix cards may be added to increase the system pin count capabilities 32 Measurement Channels 32 Measurement Channels 32 Measurement Channels To From UUT To From UUT To From UUT 16 Instrument Channels Measurement Measurement Measurement Matrix Matrix Matrix Agilent E8793 Agilent E8793 Pin Matrix Card 1 Pin Matrix Card n Agilent E8792 Pin Matrix Card Figure 1 4 Pin Matrix Cards Conceptual Block Diagram Agilent E8792A 32 Pin Matrix and Instrument Multiplexer Module 18 System Introduction This module provides connections of up to 16 instruments and modules to the Analog Bus and to the 32 pin matrix connections to the T
115. sted in the table to determine where the failure is located The most likely failures are the following 39 AttnCalMid Gain The AutoAdj action has a parameter called Adc present that should be set to 0 zero if no adc is present in the system The default is 1 24 28 Shunt resistors If all these tests fail make sure the test fixture is removed from the system or check for shorts between the Analog Bus ABus1 to ABus4 connector grounds and UUT Common Table 6 2 Parameter ID Numbers and Types ID Nominal Low High Type Value Value Value 0 LVCV Gain 603 3e 6 0 00045 0 00075 1 HVCV Gain 3 357e 3 0 0031 0 0035 2 LVCI 200m Gain 30 17e 6 27 2e 6 33 2e 6 3 LVCI 20m Gain 3 017e 6 2 92e 6 3 12e 6 4 LVCI 2m Gain 301 7e 9 292 0e 9 312 0e 9 5 LVCI 200u Gain 30 17e 9 29 2e 9 31 2e 9 104 Calibration and Preventive Maintenance Chapter 6 Chapter 6 Table 6 2 Parameter ID Numbers and Types ID Nominal Low High Value Value Value 6 HVCI Gain 30 52e 6 30 0e 6 31 0e 6 7 Comp200V Gain 1 848 1 75 2 05 8 Comp20V Gain 0 1848 0 175 0 205 9 LV ClampDac Gain 78 13e 3 0 065 0 09 10 HV ClampDac Gain 430 0e 3 0 30 0 55 11 Arb MDac Gain 7 723 3 0 005 0 009 12 Arb Xfrm Gain 38 62e 3 0 025 0 050 13 LVCV Offset 19 77 21 0 18 5 14 HVCV Offset 110 0 125 0 105 0 15 L
116. stem Configuration Editor 57 Specifying a Reset Routine Using the Topology Editor 59 Standard Functions in Instrument Handlers 59 Status LEDs Agilent E6171 44 Structural Requirements 114 Support Strategy 91 Switch Modules installing optional 54 Switch Settings 34 System 14 Customizing the 51 System Adjustments 98 System Adjustments Procedure 98 System Block Diagram 15 System Capabilities 109 System Configuration Editor specifying a reset routine 57 using 55 System Customization General Guidelines 55 System DC Accuracy 110 System Description 11 System Diagnostics Tests 95 System Driver Current Leakage 112 System Driver Saturation 110 System File 55 modifying 55 System Overview 14 System Requirements 114 System Software 14 System Specifications 109 System Weight 114 SYSTEM UST File 55 modifying 55 System ust File modifying 55 T Temperature Requirements 115 Test diagnostics 95 Test Capabilities 109 Test System Interface or Mass Interconnect 23 TestExec SL software 14 Tests system diagnostics 95 Topology Editor specifying a reset routine 50 using 55 U Universal Counter Agilent E1333A 35 Using the Product Version Capability 59 Using the System Configuration Editor 55 Using the Topology Editor 55 V Verification Procedures 107 VXI Modules 34 47 VXI Technology E1563A 2 Channel Digitizer 39 W Weight system 114 Index 147 148 Index
117. sy bit or status bit generated by each load card when its relays are switched halts further test actions until the relay timer has timed out This allows the slowest relay on a card to complete opening closing before continuing a test action This feature is not implemented in TestExec SL software release A 01 00 The timing is controlled by the PC Remote Sensing Monitoring the voltage output of a power supply can be done either at the inputs to the Switch Load Unit locally or at the inputs to the DUT remotely Remote sensing guarantees the voltage value set will be applied at the sense point and losses in the system will be compensated for For example If the DUT requires precisely 12 vdc applied to it and there is a 0 5 vdc drop between the power supply and the DUT due to system and cable losses setting the voltage sense to remote and thereby monitoring the power supply output at the DUT will compensate for the voltage drops between the power supply and the DUT Repetitive Mode The Measurement Control Module MCM has an internal timer counter that is primarily used to time the open close of the MCM relays It can also be used as a trigger source As a trigger it can either in either of two modes it can generate a single shot pulse or it can generate a continuous stream of trigger pulses repetitive mode Routine Type Rs You can specify either Setup Cleanup a combination of the two or Execute routines Execute routines
118. thods and the techniques that must be used for their removal are complex and costly If the source of corrosive contaminants cannot be eliminated the system should be installed in an enclosed environment with a fresh air supply at positive pressure Particulate contaminants hard particles consist of smoke dust hair lint fibers and miscellaneous organic and inorganic materials The presence of these contaminants in the air can cause system degradation especially where disk drives test fixtures and low impedance interfaces are concerned Particulate contaminants can be filtered from the air and appropriate filters should be included with any air conditioning installation Also consider installing Smoking signs in the area Tobacco smoke is a well known factor in fixture contact contamination It causes false failures leading to unnecessary DUT repairs and higher production costs Viscid contaminants are oily or sticky airborne substances that can be deposited on the system s electronic and mechanical parts Besides contributing directly to system degradation viscid contaminants collect and hold particulate contaminants and make cleaning very difficult Viscid contaminants can be removed from the air by filtration but the elimination of their source if possible is preferable The Agilent TS 5400 system is designed to operate in the range from 5 C to 40 C 41 F to 104 F The TS 5400 system cabinet comes equipped with
119. to VXI Module Locations And Logical Addresses on page 32 The Interrupt Priority is always set to 1 Logical Address Factory Default 24 shown TS 5430 5450 One Mainframe Slot TS 5450 Two Mainframes Slot 16 or Slot 32 if in mainframe 2 Logical Address Switch Location a SINL ox Note See the section Cabling Diagrams or the E6170 90101 cable drawing for Cable ID XX cross references E3750 61603 10 to E6171 Measurement Control Module Row 1 Observe Ground Polarity E3750 61603 10 to E6171 Measurement Control Module Row 3 Figure 2 2 Agilent E1411B DMM Module and Cables 36 System Instrument Configuration x 0 765432 OPEN Switch Set to 0 SO CLOSED Switch Set to 1 On Interrupt Priority Jumpers IRQ Location Chapter 2 e Agilent is an 8 or 16 channel digital to analog converter Agilent 1418 The Agilent E1418A is an 8 or 16 channel digital log x module Each channel can be configured for either voltage or current output 8 16 Channel mode When configured for voltage output voltages in the range of 16 0 to Digital An alog 16 0 Volts can be set When configured for current output currents in the range of 0 02 to 0 02 Amps can be set The channel output mode can be Converter Module programmatically set or it can be forced to either voltage or current by mechanical jumpers on the terminal bloc
120. trument vi is named viConfSourceDCI The name of the instrument is always the first parameter and it is of type HINSTR which is a handle to the given instrument When the system software begins to run the hardware configuration table hwconfig is constructed Every action routine that uses an instrument must have the handle to that instrument passed to it If multiple instruments exist on a card or logical unit they are assigned different instrument names They are generated by the handler from parameters in pblock and appear as separate modules For example the Agilent E6173A Arbitrary Waveform Generator module actually has two separate generators on it These would typically be named arb1 and arb2 Multiple instruments on a card are not completely separate therefore some commands affect both instruments For example reset cannot reset just one of the generators Any of the instrument names on a card can be used and you must remember that all subinstruments will be affected Header files exist for each instrument type and they define the function calls available for that handler Also constants specific to that instrument are contained in the header file constants prefaced by the letters FT_ for Functional Test to avoid conflicts with user defined symbols in action routines Thus you should avoid using the FT prefix on user defined constants File handler h contains consta
121. two 200 240 volt extractor fans which draw air primarily through the opening at the bottom of the rear door and exhaust it through the vented top of the cabinet In a fully loaded TS 5400 system the fans must be operational to prevent unacceptable heat rise inside the cabinet The Agilent TS 5400 system is designed to operate in the range from 5 percent to 80 percent relative humidity non condensing If the system is subjected to condensation as if moved from a cold loading dock into a warm and damper environment allow at least 24 hours for the Test Capabilities and System Requirements 115 system to recover before powering up 116 Test Capabilities and System Requirements Appendix A Miscellaneous Specifications Acoustic Noise lt 604 am Arbeitsplatz normaler Betrieb nach EN27779 1991 ac Power Over voltage Category Category III Pollution Degree Degree 2 IEC 664 Electromagnetic Compatibility Requirements The Agilent TS 5400 Test System complies with EN 55011 CISPR 11 Group 1 Class A for conducting emissions The product exceeds the EN 55011 CISPR 11 Group 1 Class A limit for radiated emissions by less than 10 dB when measured on a test site at a distance of 30 meters Therefore some site preparations may have to be done in order to comply with the Class A limit in the frequency range of 30 MHz to 1 GHz for radiated emissions at 30 meters from the exterior wall of a building in which the equipment is
122. ty Control may be a superset of the tests used by Production Change the testing algorithm as desired For example a testing algorithm used by Qual ity Control may need greater precision than a testing algorithm used by Production The name of the default variant is Normal Other typical variants might be named Hot or Cold Vua The voltage measured at the battery s terminals ignoring cabling losses 140 Glossary VCC Refers to the semiconductor component s supply voltage The voltage measured at the load under test ignoring cabling losses VME Computer backplane architecture standard VXI Computer backplane architecture standard that incorporates both the VMEbus and GPIB communications features W Wire A bus or other connection in the topology Glossary 141 142 Glossary Index Numerics 32 Channel Event Detector 27 32 Pin Matrix Module 20 A Accommodate Additional Instrumentation 54 Accuracy system DC 110 ADC Digitizer VXI Technology E1563A 39 Adding GPIB instruments 52 optional switch modules 54 Address logical 32 Adjustment Procedure for Agilent E6171A Modules 99 Adjustment Procedure for Agilent E6171B Modules 102 Adjustments system 98 Agilent E1333A 3 Channel Universal Counter 35 Agilent EI411B Digital Multimeter 26 36 Agilent E1418A 16 Channel Digital Analog Converter 27 37 Agilent E3750 61621 Isolated BNC Coax Cable 46 Agilent E3751 61601 64 Conduct
123. u are applying to assure the operator will NOT come into contact with any energized conductor even if one of the protective means fails to work as intended For example the inner side of a case cabinet door cover or panel can be covered with an insulating material as well as routing the test cables to the module s front panel connectors through non conductive flexible conduit such as that used in electrical power distribution Safety Symbols and Regulatory Markings Symbols and markings on the system in manuals and on instruments alert you to potential risks provide information about conditions and comply with international regulations Table 1 defines the symbols and markings you may encounter Table1 Safety Symbols and Markings Safety symbols Warning risk of electric shock Caution refer to accompanying documents Alternating current Both direct and alternating current Earth ground terminal Protective earth ground terminal Frame or chassis terminal Terminal is at earth potential Used for measurement and control circuits designed to be operated with one terminal at earth potential Switch setting indicator Off On Standby supply units with this symbol are not completely disconnected from ac mains when this switch is off To completely disconnect the unit from ac mains either disconnect the power cord or have a qualified electrician install an external switch SIO lO
124. uire calibration the DVM and the Frequency Counter and shipping them to an Agilent bench site for calibration Card As used in this manual refers to printed circuit boards that are not installed VXI mainframes See module Column Disconnect Relay A series relay on each of the four lines of the ABus that can be controlled either automatically or manually In automatic mode the default mode if any relay in the column is closed then the column disconnect relay is also closed otherwise it is open Common Line This refers to the power bus side of a load on the 24 Channel Load Card A line is run back up to the DUT load side of the card and jumpering a channel s internal load terminals allows the user to utilize the load switch as a GP relay Configurable An instrument capable of having its values or performance modified to accommodate system requirements Counter A frequency counter specifically the Agilent E1333A Universal Counter CtrCh1 and CtrCh2 CtrChl is the signal between the E1333A Counter Channel 1 and J3 row 11 of the Measurement Control module CtrCh2 is the signal between the E1333A Counter Channel 2 and J3 row 12 of the Measurement Control module Current Sensing Determining the current through a fixed known value resistor using the four wire measurement method and deriving the current in amperes via the equation I E R Glossary 127 DAC Digital to Analog Converter Converts a digital signal to an
125. ule instrument One way uses the System Configuration Editor the other way uses the Agilent TestExec SL Topology Editor The routine is specified in the system ust file The following example shows how to specify the reset routine using the System Configuration Editor the recommended method You can also enable the reset routine for a module by changing the value of InGlobalReset to 1 Refer to the TestExec SL Online Help for instructions for the Topology Editor Run Agilent TestExec SL and load the System Configuration Editor using the procedure in Using the System Configuration Editor on page 55 Use the procedure in Figure 3 1 to specify a reset routine Customizing the System 57 1 Double click on the module instrument to be edited click on the name and then on Edit Current Module Configuration System Topology 6 Show All Modules 2 Edit Delete C how Enabled Modules Only Et Bee Enabled DMM E1411 0 511 11 yes PinCard1 E87324 SWITCHO_S20 yes PinCard2 E87934 SWITCHO_S21 yes SwitchBox0 E61984 SWITCHO_S 1 yes Configure Module x Module Name DMM Enabled Description E1411 51 2 Digit Multimeter in slot 11 at address 11 Keywords Parameter Block Value Device ID E1411 23 0 23 X1 Slottt 11 123 LogicalAddress 11 LineFreq 50 InGlobalReset 1 RizalRaise On Timeout
126. ule page 46 Agilent E6174A Event Detector Module page 47 Refer to Chapter 4 on page 63 for wiring and cable pinout diagrams Refer also to the mass interconnect manual supplied with your test system WARNING To prevent electric shock hazard the module face plate must be securely fastened to the mainframe 34 System Instrument Configuration Chapter 2 Agilent E1333A 3 Channel Universal Counter Module Switch Jumper Settings Agilent E1403 VXIbus B size to C size Active Adapter Module E3750 61604 11 to E6171 Measurement Control Module Row 11 E3750 61604 11 to E6171 Measurement Control Module Row 12 Note See the section Cabling Diagrams or the E6170 90101 cable drawing for Cable ID XX cross references The Agilent E6182A contains an Agilent E1333A B Size Universal Counter with the Agilent E1403B B size to C size Active Adapter Module and cables The Agilent E1333A Counter performs frequency time interval period and totalize measurements The counter is connected to the UUT through the Agilent E6171 Measurement Control Module The counter uses only one row on J1 since the counter inputs are referenced to earth ground Figure 2 1 shows the Agilent E1333A logical address switch with the switch shown in the factory setting Set the logical address to match the VXI mainframe slot number for a one mainframe system For a two mainframe system set to the slot number plus 16 if in mainframe
127. ulse Open Relays A command that immediately opens all the relays both columns and rows on a module Open System Standard Refers to the TS 5400 Functional Test System s use of the industry standard V XIbus and a C size V XI mainframe as its primary organizational unit Operator Interface A customizable user interface through which production operators interact with the Test Executive Because it is customizable we say the Test Executive can have multiple personalities Optical Isolator A digital device that electronically isolates a signal from its source by converting the input signal to a light source usually laser or LED and reconverts the signal to an electronic signal using a photoelectric device P Parameter Block A list of parameters stored in a uniquely named group or block When you need to use the list of parameters you specify a handle name to the parameter block instead of specifying the full list of parameters Parasitic Capacitance Capacitance caused by the close proximity of adjacent components pins or bus lines Programmable Array Logic A semiconductor consisting of an array of generic logic elements that with the aid of a programming device is capable of having these elements arranged into a variety of functional elements Glossary 135 Receiver See ICA Relay Sequencing The process of ensuring relay switching has fully completed before continuing a test action A bu
128. uments to the Analog Bus Twelve of these Measurement and sixteen lines are typically used for the Counter 2 channel isolated Arbitrary Control Module waveform Generator Digitizer and DMM The MCM card adds other MCM important capabilities to the system as well these are An isolated voltage source An isolated current source with a programmable voltage limit 16 X 5 instrument multiplexer that multiplexes four analog buses plus Unit Under Test UUT common Multiplexing for eight external triggers and eight V XIbus TTL triggers to and from each other or to and from the DUT An analog comparator with programmable thresholds whose output connects to the trigger multiplexer A programmable high voltage attenuator A amplifier with programmable gain that can amplify the output of an Agilent E6173A Arbitrary Function Generator module formerly the Agilent Z2471A via a step up transformer to provide output for simulating VRS Variable Reluctance Sensors signals A Programmable IRQ A programmable general purpose timer whose output also can be used Chapter 1 System Introduction 17 Agilent 6198 Switch Load Unit Agilent E8792A and E8793A Pin Matrix Cards to generate interrupts trigger delays and pacing The 21 slot Switch Load Unit SLU holds the pin matrix cards and the load cards Test system instrumentation loads and power supplies are routed to the UUT through the pin matrix cards and load card
129. usually are written in C and have the action code stored in a DLL dynamic link library Action Definition Editor A software tool used to create actions which are the building blocks used to create tests Glossary 125 ADC Acronym for Analog to Digital Converter See Digitizer ADC1Hi and ADC1Lo Differential input to ADC channel 1 from Measurement Control module J3 rows 7 and 8 respectively ADC2Hi and ADC2Lo Differential input to ADC channel 2 from Measurement Control module J3 rows 9 and 10 respectively Adjustment An adjustment is an action performed in the field to modify an instrument s response to some input It can usually be performed by the user on site Alias An alternate name for an item Aliases let you use convenient names when defining topology for example you could assign node MCM Inst1 1 an alias that is easier to remember such as CtrCh1 or if desired Chl Each node can have one more aliases You cannot use aliases for the names of modules ARB See Arbitrary Waveform Generator Arbitrary Waveform Generator A programmable function generator whose output can be programmed to generate any waveform B Bused A collection of parallel electronic signal paths that originate and terminate as a group 126 Glossary Calibration A standardized maintenance procedure designed to ensure system accuracy In this manual it refers to removing those items that req
130. with instrument multiplexer E8793 66201 E8793A Pin Matrix Card E8794 66201 Switch Load Unit Custom Card 0490 1838 Relay 8 pack Replacement Relays for the E8792 and E8793 cards E6173A Z2471A Arbitrary Waveform Generator E6173A E6173A with cables and manual 22471 66201 New Arb Module 22471 69201 Exchange Module E6174A Z2902A Event Detector E6174A E6174A with cables and manual 22902 66201 E6174A Module only 22902 69201 E6174A Exchange Module only E1328A DAC E1328A E1328A with E1403A adapter cables and manual E1328 69201 E1328A exchange module only E1418A 8 16 Channel DAC E1418 69201 8 channel DAC E1418 69502 8 channel Expander board for 16 channels E1418 66503 Isolated plug on assembly qty 16 or remove from existing board E1418 66504 Non isolated plug on assembly qty 16 or remove from existing board E1429A B Digitizer E1429 69201 2 Channel 20 MSa s Digitizer Note limited availability for use as a replacement in TS 5400 Series systems only E1563A E1564A 2 4 Channel E1563A 64A 2 4 channel 800 kSa s Digitizer For repair contact VXI Technology 949 955 1894 E6198A Switch Load Unit E8770 80701 E6198A Switch Load Unit Service Replacement E6170 66501 Parallel Interface for the 1st SLU E6198A option 001 E6170 61604 Cable for connecting the 2nd SLU to t
131. ystem pallet all the Way you must remove it from its pallet in a receiving area and push it on its casters to the destination The air quality temperature humidity and electromagnetic interference requirements for the Agilent TS 5400 System are described below 114 Test Capabilities and System Requirements Appendix A Air Quality Requirements Corrosive Contaminants Particulate Contaminants Viscid Contaminants Temperature Requirements Cooling Requirements Humidity Requirements Appendix A As a rule good air quality is as important for the reliability of your Agilent TS 5400 system as it is for your production process Three types of airborne contaminants are discussed below The presence of any of these contaminants at the site will contribute to system degradation resulting in lower reliability and higher operating costs Corrosion is a complex form of material deterioration or destruction by chemical or electrochemical reaction The presence of corrosive contaminants gases in the atmosphere is very common in industrial environments If ignored corrosion can eventually degrade system performance by its effects on high impedance circuits and low impedance interfaces It can also deteriorate most plastics including software storage media The effects of corrosive contaminants are usually accelerated at high humidities or high temperatures Corrosives generally cannot be filtered out of the air by normal filtration me
Download Pdf Manuals
Related Search
E8770 90030