Agilent Technologies 6634B, 6633B, 6632B Pulse Measurement Example Agilent 66312A, 66332A only

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3 - Programming the DC Source

Pre-event and Post-event Triggering (Agilent 66312A, 66332A Only)

When a measurement is initiated, the dc source continuously samples either the instantaneous output voltage or current. As shown in figure 3-6, you can move the block of data being read into the acquisition buffer with reference to the acquisition trigger. This permits pre-event or post-event data sampling.

OFFSET = -4096

 

4096 DATA POINTS

 

OFFSET = -2048

 

4096 DATA POINTS

 

OFFSET = 0

 

4096 DATA POINTS

 

OFFSET = 0 to 2 9

4096 DATA POINTS

TIME

 

ACQUISITION

 

TRIGGER

 

Figure 3-6. Pre-event and Post-event Triggering

To offset the beginning of the acquisition buffer relative to the acquisition trigger, use:

SENSe:SWEep:OFFSet:POINts <offset>

The range for the offset is -4096 to 2,000,000,000 points. As shown in the figure, when the offset is negative, the values at the beginning of the data record represent samples taken prior to the trigger. When the value is 0, all of the values are taken after the trigger. Values greater than zero can be used to program a delay time from the receipt of the trigger until the data points that are entered into the buffer are valid. (Delay time = Offset X Sample period)

Pulse Measurement Example (Agilent 66312A, 66332A only)

The following program illustrates how to make a pulse measurement over the GPIB. The measurement function is set to ACDC, which gives the best results for current waveforms that have ac content. The measurement incorporates 100 readings taken at time intervals of 20 microseconds, for a total measurement time of 2 milliseconds. The trigger point for the pulse measurement occurs at 0.1 amperes on the positive slope of the current pulse. The measurement offset is programmed so that 20 measurement points prior to the trigger are also returned as part of the measurement sample.

Because measurement triggers are initiated by the current pulse, a FETCh command is used to return the measurement data. FETCh commands are also used to return the MAXimum, MINimum, HIGH, and LOW values of the measurement.

NOTE: MEASure commands cannot be used to return data in this example because they always acquire NEW measurement data each time they are used.

The program can be run on any controller operating under Agilent BASIC. To generate output pulses, an electronic load is programmed to generate 3-ampere pulses with a duty cycle of 100 microseconds at 1000 Hz. The power supply address is 705, and the load address is 706. If required, change these parameters in the appropriate statements.

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Contents Programming Guide Safety Guidelines Printing HistoryTable of Contents Language Dictionary Internally Triggered MeasurementsOutput Commands Compatibility Language Error MessagesScpi Conformance Information Example ProgramsAbout this Guide Documentation SummaryExternal References Gpib ReferencesScpi References Supported Applications VXIplug&play Power Products Instrument DriversDownloading and Installing the Driver System RequirementsRS-232 Capabilities of the DC Source Accessing Online HelpGpib Capabilities of the DC Source Gpib AddressRS-232 Flow Control RS-232 Programming ExampleBaud Rate Conventions Used in This Guide RS-232 TroubleshootingIntroduction to Scpi Boldface fontTypes of Scpi Commands Multiple Commands in a MessageTypes of Scpi Messages Including Common CommandsUsing Queries Moving Among SubsystemsHeaders Query IndicatorMessage Unit Message Unit SeparatorSuffixes and Multipliers Scpi Data FormatsNumerical Data Formats Response Data TypesScpi Command Completion Using Device ClearPage Programming the Output Power-on InitializationIntroduction Enabling the OutputMaximum Voltage Output VoltageOutput Current Maximum CurrentScpi Triggering Nomenclature Setting the Voltage or Current Trigger LevelsTriggering Output Changes Output Trigger System ModelInitiating the Output Trigger System Generating TriggersMaking Measurements Voltage and Current MeasurementsDC Measurements RMS Measurements Agilent 66312A, 66332A Only Current RangesInternally Triggered Measurements Measurement Trigger System ModelSequence Form Alias SEQuence2 ACQuire Generating Measurement Triggers Agilent 66312A, 66332A Only BUSTrigger Commands Used to Measure Output Pulses Measuring Output Pulses Agilent 66312A, 66332A Only Current DetectorPulse Measurement Queries Controlling Measurement Samples Varying the Voltage or Current Sampling RateMultiple Measurements Agilent 66312A, 66332A Only Pulse Measurement Example Agilent 66312A, 66332A only Pre-event and Post-event TriggeringOption Base Power-On Conditions Programming the Status RegistersOperation Status Group Questionable Status Group Standard Event Status GroupStatus Byte Register MSS Bit Determining the Cause of a Service InterruptServicing Operation Status and Questionable Status Events RQS BitDiscrete Fault Indicator DFI Inhibit/Fault IndicatorMonitoring Both Phases of a Status Transition Remote Inhibit RIDFI Programming Example Using the Inhibit/Fault Port as a Digital I/OBit Weight PinPage Subsystem Commands Language DictionarySubsystem Commands Syntax DFI ALCSubsystem Commands Syntax Programming Parameters Common CommandsCommon Commands Syntax Output Programming ParametersCALibrateCURRentNEGative Calibration CommandsCALibrateCURRent CALibrateCURRentMEASureLOWRangeCALibrateDATA CALibratePASSwordCommand Syntax CALibrateSAVE Parameters None Examples CALibrateLEVelCALibrateVOLTagePROTection CALibrateSTATeCALibrateVOLTage Query Syntax CALibrateSTATe?MEASureARRayVOLTage? FETChARRayVOLTage? Measurement CommandsMEASureARRayCURRent? FETChARRayCURRent? Query SyntaxMEASureCURRentHIGH? FETChCURRentHIGH? MEASureCURRent? FETChCURRent?MEASureCURRentACDC? FETChCURRentACDC? FETChCURRent? applies to Agilent 66312A, 66332A OnlyMEASureCURRentLOW? FETChCURRentLOW? MEASureCURRentMAXimum? FETChCURRent MAXimum?MEASureCURRentMINimum? FETChCURRentMINimum? MEASureVOLTageHIGH? FETChVOLTageHIGH? MEASureVOLTage? FETChVOLTage?MEASureVOLTageACDC? FETChVOLTageACDC? FETChVOLTage? applies to Agilent 66312A, 66332A OnlyMEASureVOLTageLOW? FETChVOLTageLOW? MEASureVOLTageMAXimum? FETChVOLTageMAXimum?MEASureVOLTageMINimum? FETChVOLTageMINimum? Unit a amperes *RST Value MAX high range SENSeCURRentRANGeSENSeCURRentDETector Returned Parameters NR3SENSeSWEepPOINts SENSeFUNCtionSENSeSWEepOFFSetPOINts SENSeSWEepTINTervalRECTangular SENSeWINDowHANNing Returned Parameters CRDOUTPutDFI Output CommandsOUTPut OUTPutDFISOURceOUTPutPROTectionDELay OUTPutPONSTATeOUTPutPROTectionCLEar OUTPutRIMODE OUTPutRELayOUTPutRELayPOLarity Query Syntax OUTPputRELayPOLarity?SOURceCURRentTRIGger Default SuffixSOURceCURRent SOURceCURRentPROTectionSTATeSOURceVOLTage SOURceDIGitalDATASOURceDIGitalFUNCtion Query Syntax SOURceDIGitalDATA?SOURceVOLTagePROTection SOURceVOLTageALCBANDwidth? SOURceVOLTageALCBWIDth?SOURceVOLTageTRIGger Agilent 66332A, 6631B, 6632B, 6633B and 6634B OnlySTATusOPERation? Status CommandsSTATusPRESet STATusOPERationCONDition?Parameters Preset Value STATusOPERationENABleQuery Syntax STATusOPERationENABle? STATusOPERationNTR STATusOPERationPTRSTATusQUEStionableENABle STATusQUEStionable?STATusQUEStionableCONDition? CLS Command Syntax *CLS Parameters NoneSTATusQUEStionableNTR STATusQUEStionablePTR STATQUESNTR?STATQUESPTR?ESR? Bit Configuration of Standard Event Status Enable RegisterESE OPCPSC on PSCSRE ExampleWAI Bit Configuration of Status Byte RegisterSTB? NR1 register binary valueDISPlayMODE System CommandsDISPlay DISPlayTEXTSYSTemVERSion? SYSTemERRor?SYSTemLANGuage Parameters none Returned Parameters NR2SYSTemRWLock SYSTemLOCalSYSTemREMote IDN?RCL Command Syntax RCL NRf Parameters ExampleOPT? RSTSAV RST SettingsCommand Syntax SAV NRf Parameters Example TST?INITiateSEQuence INITiateNAME Trigger CommandsABORt INITiateCONTinuousSEQuence1 INITiateCONTinuousNAMETRIGgerSEQuence2 TRIGgerACQuire TRIGgerTRIGgerSOURce Abor Currtrig Init *TRG VolttrigParameters RST Value Examples TRIGgerSEQuence2COUNtCURRent TRIGgerACQuireCOUNtCURRentTRIGgerSEQuence2COUNtVOLTage TRIGgerACQuireCOUNtVOLTage TRIGSEQ2COUNCURR 5 TrigacqcouncurrTRIGSEQ2HYSTVOLT TRIGSEQ2LEVCURR TRIGSEQ2HYSTCURR TRIGSEQ2LEVVOLTTRIGSEQ2LEVVOLT TRIGSEQ2HYSTCURR TRIGgerSEQuence2LEVelCURRent TRIGgerACQuireLEVelCURRentTRIGgerSEQuence2LEVelVOLTage TRIGgerACQuireLEVelVOLTage TRIGSEQ2LEVCURR TRIGSEQ2HYSTVOLTTRIGgerSEQuence2SLOPeCURRent TRIGgerACQuireSLOPeCURRent TRIGgerSEQuence2SLOPeVOLTage TRIGgerACQuireSLOPeVOLTageTRIGSEQ2SLOPVOLT TRIGgerSEQuence1DEFine TRIGgerSEQuence2DEFine Parameters None Related CommandsTRIGgerSEQuence2SOURce TRIGgerACQuireSOURce TRGPage Scpi Confirmed Commands Non-SCPI CommandsScpi Version Page Table B-1. COMPatibility Power-on Settings Command Command SettingSimilar Scpi Command Table B-2. COMPatibility Commands CompatibilityERR? FAULT? ID? IOUT? ASTS? CLRCompatibility Command Table B-2. COMPatibility Commands Description Similar ScpiThese commands determine the conditions that will set bits Table B-2. COMPatibility CommandsCompatibility Description Command ErrorNorm Fast INH ERR UNR +CC RQS ERR RDYFAU Page Error Number List Bit Set Error Number Error Code Error TypeTable C-1. Error Numbers Error Number Page Agilent 82335A Driver Assigning the Gpib Address in ProgramsTypes of DOS Drivers National Instruments Gpib DriverError Handling Basic ControllersExample Programs D Example 2. IBM Controller Using National Interface Call IBCLRPS%CODES$=*CLS Example 3. Controller Using Basic Option BaseIndex Index 100101 Scpi102 Manual Updates
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6613C, 66312A, 6631B, 6611C, 6614C specifications

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