Agilent Technologies 668xA, 665xA, 664xA Including Common Commands, Scpi Queries, Value Coupling

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Note The SCPI parser traverses the command tree as described in Appendix A of the IEEE 488.2 standard. The "Enhanced Tree Walking Implementation" given in that appendix is not implemented in the power supply.

The following message shows how to combine commands from different subsystems as well as within the same subsystem (see Figure 3-2):

VOLTAGE:LEVEL 7;PROTECTION 8;:CURRENT:LEVEL 50;PROTECTION ON

Note the use of the optional header LEVEL to maintain the correct path within the voltage and current subsystems and the use of the root specifier to move between subsytems.

Including Common Commands

You can combine common commands with system commands in the same message. Treat the common command as a message unit by separating it with the message unit separator. Common commands do not affect the active header path; you may insert them anywhere in the message.

VOLT:TRIG 7.5;INIT;*TRG

OUTP OFF;*RCL 2;OUTP ON

SCPI Queries

Observe the following precautions with queries:

Remember to set up the proper number of variables for the returned data.

Set the program to read back all the results of a query before sending another command to the power supply. Otherwise, a Query Interrupted error will occur and the unreturned data will be lost.

Value Coupling

Value coupling results when a command directed to send one parameter also changes the value of a second parameter. There is no direct coupling among any power supply SCPI commands. However, be aware that until they are programmed, uninitialized trigger levels will assume their corresponding immediate levels. For example, if a power supply is powered up and VOLT:LEV is programmed to 6, then VOLT:LEV:TRIG will also be 6 until you program it to another value. Once you program VOLT:LEV:TRIG to another value, it will remain at that value regardless of how you subsequently reprogram VOLT:LEVEL.

SCPI Data Formats

All data programmed to or returned from the power supply is ASCII. The data may be numerical or character string.

Numerical Data

Table 2-1 and Table 2-2 summarize the numerical formats.

Table 2-1. Numerical Data Formats

Symbol

Data Form

 

 

Talking Formats

 

<NR1>

Digits with an implied decimal point assumed at the right of the least-significant

 

digit. Examples: 273 0273

 

<NR2>

Digits with an explicit decimal point. Example: 273.

.0273

<NR3>

Digits with an explicit decimal point and an exponent.

Example: 2.73E+2 273.0E-2

 

 

 

14 Remote Programming

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Contents Programming Guide Gpib DC Power Supplies Agilent Part No Microfiche Part No JulySafety Guidelines Printing HistoryContents Current Subsystem Description of Subsystem CommandsSystem Commands Display SubsystemVoltage Subsystem Command Summary Programming ParametersPower Supply Status Structure Operation Status Group Questionable Status GroupPage Documentation Summary General InformationAbout this Guide User’s GuideDownloading and Installing the Driver Prerequisites for Using this GuideVXIplug&play Power Product Instrument Drivers Accessing Online HelpIntroduction To Scpi Gpib Capabilities Of The Power SupplyRemote Programming ConventionsStructure of a Scpi Message Types of Scpi CommandsScpi Messages Voltlev 4.5PROT 4.8CURR?NLVoltlev 4.5 Prot 4.8 CURR? Parts of a Scpi MessageVolt LEV Prot Curr Message Unit Separator Traversing the Command TreeQuery Indicator Root SpecifierOutputprotectionclear STATUSOPERATIONCONDITION? Effect of Optional HeadersMoving Among Subsystems OUTPUTPROTECTIONCLEARSTATUSOPERATIONCONDITION?Value Coupling Including Common CommandsScpi Queries Scpi Data FormatsExamples Controlling the Output Programming Status Saving and Recalling StatesWriting to the Display Gpib Address System ConsiderationsProgramming the Digital I/O Port DigdataAction Display Shows Assigning the Gpib Address In ProgramsAgilent Basic Controllers Error HandlingDOS Drivers Sample Program CodeProgramming Some Power Supply Functions Iout = OUTPUTS2Call Ioenter PS,OEVENT SPOL%=O While C O Language Dictionary IntroductionDescription Of Common Commands Common Commands Syntax DiagramCLS ESEOPC ESR?IDN? PSC OPC?OPT? PSC 0 *PSCRCL Command Syntax RCL NRf Parameters ExampleQuery Syntax None Related Commands PSC *RST *SAVSAV RSTSAV STB? Bit Configuration of Status Byte RegisterSRE SREWAI TRGTST? Abor Description of Subsystem CommandsCalibration Commands AborCurrprotstat Current SubsystemCurr Currtrig Disp Display SubsystemDigdata Digdata 7 DigitaldatavalueDisptext Disptext DefaultmodeDispmode Dispmode Norm Displaymode Normal Displaywindowmode TextInit Initcont Initiate SubsystemMeasure Subsystem MEASCURR? MEASVOLT?Outpprotcle Outpprotdel Output SubsystemOutp Outprel 1 Outprel OFF OutprelOutprelpol Outprelpol NormStatus Operation Registers Status SubsystemStatpres STATOPER?Statoper NTR Statoper PTR STATUSOPERATIONENABLE?Statoperenab Statoperenab 1312 StatoperenabSTATQUESCOND? Status Questionable RegistersSTATQUES? StatquesenabStatques NTR Statques PTR System CommandsSYSTERR? SYSTEMERROR? SYSTERR?SYSTVERS? Trigger SubsystemSystlang TrigVolt Volttrig Voltage SubsystemTrigsour Trigsour BUS Triggersource BUSCommand Parameters Subsystem Commands Command SummaryCommand Summary VoltprotCommand Parameters Common Commands ParametersVoltlevtrig MAX Programming ParametersCurrlevtrig MAX Voltprot MAXPage Status Reporting Power Supply Status StructureRegister Commands Operation Status GroupUNR CALWTG OPCStandard Event Status Group Status Questionable Commands Register Query Cleared ByQuestionable Status Group STATQUESNTR?Status Byte Register Service Request Enable RegisterInitial Conditions At Power On Output QueueDefault Power On Register States Condition Caused By PON Power-On BitServicing an Operation Status Mode Event StatpreServicing Questionable Status Events Monitoring Both Phases of a Status TransitionAdding More Operation Events RI Remote Inhibit Scpi Command CompletionDFI Discrete Fault Indicator WAIPage Calibration Error Messages Error MessagesPower Supply Hardware Error Messages System Error MessagesSummary of System Error Messages Error Error String Description/Explanation/Examples NumberScpi Conformance Information Scpi Confirmed Commands1Scpi Approved Commands Scpi VersionNON-SCPI Commands1 Compatibility Language Compatibility LanguageParallel Polling VSET? VoltCurr ISET? CURR? VOUT?Hold Hold OFFVolttrig CurrtrigSRQ OFF FAULT?UNMASK? SRQIndex IndexOperation status group, 51 optional header Trig SOUR, 46 VOLT, 46 Volt PROT, 47 Volt Trig Europe Asia Pacific United States Latin AmericaCanada Australia/New Zealand Japan
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668xA, 669xA, 667xA, 664xA, 665xA specifications

Agilent Technologies has long been a pioneer in the production of high-performance electronic test and measurement instruments, particularly in the field of power sources. Among its notable offerings are the Agilent 667xA, 669xA, 665xA, 664xA, and 668xA series of power supplies. These instruments are designed to provide stable, reliable power for a variety of applications, including electronic testing, industrial processes, and research laboratories.

The Agilent 667xA series is characterized by its programmability and advanced measurement functions. These power supplies support a wide range of output voltages and currents, allowing for flexible configurations that cater to different testing needs. The built-in measurement capabilities enable users to monitor the voltage, current, and power with high precision, which is essential for ensuring optimal performance in electronic applications.

The Agilent 669xA series stands out with its high-power outputs, making it suitable for demanding applications. These power supplies deliver high voltage and current levels, making them ideal for testing high-performance devices, such as power amplifiers and motor drives. Additionally, the 669xA series includes features such as overvoltage protection and complex output sequencing to enhance the safety and reliability of the testing process.

The Agilent 665xA and 664xA series focus on delivering high accuracy and excellent regulation. These models are particularly known for their low noise operation, which is critical for sensitive applications where precision is paramount. The integrated programming capabilities allow users to automate testing sequences, thus improving efficiency in research and development settings.

The 668xA series features advanced digital signal processing that enhances the precision and stability of the output. Users benefit from features like remote sensing and monitoring, allowing feedback adjustments that maintain output accuracy despite cable losses. Furthermore, the 668xA models can integrate seamlessly with various test environments thanks to their LAN, GPIB, and USB connectivity options.

Overall, the Agilent 667xA, 669xA, 665xA, 664xA, and 668xA power supplies provide a comprehensive range of solutions for diverse electronic testing needs. With their advanced features, superb measurement capabilities, and robust performance, these instruments empower engineers and researchers to conduct their work with confidence, precision, and efficiency.