Agilent Technologies 6613C, 6634B, 66332A, 6633B, 6632B, 6614C manual Esr?, Cls *Ese *Ese? *Opc

Page 65

Language Dictionary - 4

*ESE

This command programs the Standard Event Status Enable register bits. The programming determines which events of the Standard Event Status Event register (see *ESR?) are allowed to set the ESB (Event Summary Bit) of the Status Byte register. A "1" in the bit position enables the corresponding event. All of the enabled events of the Standard Event Status Event Register are logically ORed to cause the Event Summary Bit (ESB) of the Status Byte Register to be set. The query reads the Standard Event The query reads the Standard Event Status Enable register.

Table 4-6. Bit Configuration of Standard Event Status Enable Register

Bit Position

7

6

Bit Name

PON

0

Bit Weight

128

64

PON = Power-on has occurred CME = Command error

EXE = Execution error

Command Syntax

Parameters

Power-On Value

Examples

Query Syntax

Returned Parameters

Related Commands

5

4

3

2

1

0

CME

EXE

DDE

QUE

0

OPC

32

16

8

4

2

1

DDE = Device-dependent error

QUE = Query error

OPC = Operation complete

*ESE <NRf> 0 to 255 (See *PSC) *ESE 129 *ESE? <NR1>(Register value) *ESR? *PSC *STB?

CAUTION: If *PSC is programmed to 0, the *ESE command causes a write cycle to nonvolatile memory. Nonvolatile memory has a finite maximum number of write cycles. Programs that repeatedly cause write cycles to nonvolatile memory can eventually exceed the maximum number of write cycles and cause the memory to fail.

*ESR?

This query reads the Standard Event Status Event register. Reading the register clears it. The bit configuration is the same as the Standard Event Status Enable register (see *ESE).

Query Syntax

*ESR?

Parameters

None

Returned Parameters

<NR1>(Register binary value)

Related Commands

*CLS *ESE *ESE? *OPC

*OPC

This command causes the instrument to set the OPC bit (bit 0) of the Standard Event Status register when the has completed all pending operations. (See *ESE for the bit configuration of the Standard Event Status register.) Pending operations are complete when:

υall commands sent before *OPC have been executed. This includes overlapped commands. Most commands are sequential and are completed before the next command is executed. Overlapped commands are executed in parallel with other commands. Commands that affect output voltage, current or state, relays, and trigger actions are overlapped with subsequent commands sent to the dc source. The *OPC command provides notification that all overlapped commands have been completed.

υall triggered actions are completed

65

Image 65
Contents Programming Guide Printing History Safety GuidelinesTable of Contents Internally Triggered Measurements Language DictionaryOutput Commands Scpi Conformance Information Error MessagesCompatibility Language Example ProgramsDocumentation Summary About this GuideScpi References External ReferencesGpib References Downloading and Installing the Driver VXIplug&play Power Products Instrument DriversSupported Applications System RequirementsGpib Capabilities of the DC Source Accessing Online HelpRS-232 Capabilities of the DC Source Gpib AddressBaud Rate RS-232 Flow ControlRS-232 Programming Example Introduction to Scpi RS-232 TroubleshootingConventions Used in This Guide Boldface fontMultiple Commands in a Message Types of Scpi CommandsUsing Queries Including Common CommandsTypes of Scpi Messages Moving Among SubsystemsMessage Unit Query IndicatorHeaders Message Unit SeparatorNumerical Data Formats Scpi Data FormatsSuffixes and Multipliers Response Data TypesUsing Device Clear Scpi Command CompletionPage Introduction Power-on InitializationProgramming the Output Enabling the OutputOutput Current Output VoltageMaximum Voltage Maximum CurrentTriggering Output Changes Setting the Voltage or Current Trigger LevelsScpi Triggering Nomenclature Output Trigger System ModelGenerating Triggers Initiating the Output Trigger SystemDC Measurements Making MeasurementsVoltage and Current Measurements Current Ranges RMS Measurements Agilent 66312A, 66332A OnlySequence Form Alias SEQuence2 ACQuire Internally Triggered MeasurementsMeasurement Trigger System Model BUS Generating Measurement Triggers Agilent 66312A, 66332A OnlyTrigger Commands Used to Measure Output Pulses Pulse Measurement Queries Measuring Output Pulses Agilent 66312A, 66332A OnlyCurrent Detector Multiple Measurements Agilent 66312A, 66332A Only Controlling Measurement SamplesVarying the Voltage or Current Sampling Rate Pre-event and Post-event Triggering Pulse Measurement Example Agilent 66312A, 66332A onlyOption Base Programming the Status Registers Power-On ConditionsOperation Status Group Status Byte Register Questionable Status GroupStandard Event Status Group Servicing Operation Status and Questionable Status Events Determining the Cause of a Service InterruptMSS Bit RQS BitMonitoring Both Phases of a Status Transition Inhibit/Fault IndicatorDiscrete Fault Indicator DFI Remote Inhibit RIBit Weight Using the Inhibit/Fault Port as a Digital I/ODFI Programming Example PinPage Language Dictionary Subsystem CommandsSubsystem Commands Syntax ALC DFISubsystem Commands Syntax Common Commands Syntax Common CommandsProgramming Parameters Output Programming ParametersCALibrateCURRent Calibration CommandsCALibrateCURRentNEGative CALibrateCURRentMEASureLOWRangeCommand Syntax CALibrateSAVE Parameters None Examples CALibratePASSwordCALibrateDATA CALibrateLEVelCALibrateVOLTage CALibrateSTATeCALibrateVOLTagePROTection Query Syntax CALibrateSTATe?MEASureARRayCURRent? FETChARRayCURRent? Measurement CommandsMEASureARRayVOLTage? FETChARRayVOLTage? Query SyntaxMEASureCURRentACDC? FETChCURRentACDC? MEASureCURRent? FETChCURRent?MEASureCURRentHIGH? FETChCURRentHIGH? FETChCURRent? applies to Agilent 66312A, 66332A OnlyMEASureCURRentMINimum? FETChCURRentMINimum? MEASureCURRentLOW? FETChCURRentLOW?MEASureCURRentMAXimum? FETChCURRent MAXimum? MEASureVOLTageACDC? FETChVOLTageACDC? MEASureVOLTage? FETChVOLTage?MEASureVOLTageHIGH? FETChVOLTageHIGH? FETChVOLTage? applies to Agilent 66312A, 66332A OnlyMEASureVOLTageMINimum? FETChVOLTageMINimum? MEASureVOLTageLOW? FETChVOLTageLOW?MEASureVOLTageMAXimum? FETChVOLTageMAXimum? SENSeCURRentDETector SENSeCURRentRANGeUnit a amperes *RST Value MAX high range Returned Parameters NR3SENSeSWEepOFFSetPOINts SENSeFUNCtionSENSeSWEepPOINts SENSeSWEepTINTervalHANNing SENSeWINDowRECTangular Returned Parameters CRDOUTPut Output CommandsOUTPutDFI OUTPutDFISOURceOUTPutPROTectionCLEar OUTPutPROTectionDELayOUTPutPONSTATe OUTPutRELayPOLarity OUTPutRELayOUTPutRIMODE Query Syntax OUTPputRELayPOLarity?SOURceCURRent Default SuffixSOURceCURRentTRIGger SOURceCURRentPROTectionSTATeSOURceDIGitalFUNCtion SOURceDIGitalDATASOURceVOLTage Query Syntax SOURceDIGitalDATA?SOURceVOLTageTRIGger SOURceVOLTageALCBANDwidth? SOURceVOLTageALCBWIDth?SOURceVOLTagePROTection Agilent 66332A, 6631B, 6632B, 6633B and 6634B OnlySTATusPRESet Status CommandsSTATusOPERation? STATusOPERationCONDition?Query Syntax STATusOPERationENABle? STATusOPERationENABleParameters Preset Value STATusOPERationNTR STATusOPERationPTRSTATusQUEStionableCONDition? STATusQUEStionableENABleSTATusQUEStionable? STATusQUEStionableNTR STATusQUEStionablePTR Command Syntax *CLS Parameters NoneCLS STATQUESNTR?STATQUESPTR?ESE Bit Configuration of Standard Event Status Enable RegisterESR? OPCSRE PSCPSC on ExampleSTB? Bit Configuration of Status Byte RegisterWAI NR1 register binary valueDISPlay System CommandsDISPlayMODE DISPlayTEXTSYSTemLANGuage SYSTemERRor?SYSTemVERSion? Parameters none Returned Parameters NR2SYSTemREMote SYSTemLOCalSYSTemRWLock IDN?OPT? Command Syntax RCL NRf Parameters ExampleRCL RSTCommand Syntax SAV NRf Parameters Example RST SettingsSAV TST?ABORt Trigger CommandsINITiateSEQuence INITiateNAME INITiateCONTinuousSEQuence1 INITiateCONTinuousNAMETRIGgerSOURce TRIGgerTRIGgerSEQuence2 TRIGgerACQuire Abor Currtrig Init *TRG VolttrigTRIGgerSEQuence2COUNtVOLTage TRIGgerACQuireCOUNtVOLTage TRIGgerSEQuence2COUNtCURRent TRIGgerACQuireCOUNtCURRentParameters RST Value Examples TRIGSEQ2COUNCURR 5 TrigacqcouncurrTRIGSEQ2HYSTCURR TRIGSEQ2LEVVOLT TRIGSEQ2HYSTVOLT TRIGSEQ2LEVCURRTRIGgerSEQuence2LEVelVOLTage TRIGgerACQuireLEVelVOLTage TRIGgerSEQuence2LEVelCURRent TRIGgerACQuireLEVelCURRentTRIGSEQ2LEVVOLT TRIGSEQ2HYSTCURR TRIGSEQ2LEVCURR TRIGSEQ2HYSTVOLTTRIGSEQ2SLOPVOLT TRIGgerSEQuence2SLOPeCURRent TRIGgerACQuireSLOPeCURRentTRIGgerSEQuence2SLOPeVOLTage TRIGgerACQuireSLOPeVOLTage TRIGgerSEQuence2SOURce TRIGgerACQuireSOURce Parameters None Related CommandsTRIGgerSEQuence1DEFine TRIGgerSEQuence2DEFine TRGPage Scpi Version Scpi Confirmed CommandsNon-SCPI Commands Page Command Setting Table B-1. COMPatibility Power-on Settings CommandERR? FAULT? ID? IOUT? Table B-2. COMPatibility Commands CompatibilitySimilar Scpi Command ASTS? CLRTable B-2. COMPatibility Commands Description Similar Scpi Compatibility CommandCompatibility Description Command Table B-2. COMPatibility CommandsThese commands determine the conditions that will set bits ErrorFAU Norm Fast INH ERR UNR +CCRQS ERR RDY Page Bit Set Error Number Error Code Error Type Error Number ListTable C-1. Error Numbers Error Number Page Types of DOS Drivers Assigning the Gpib Address in ProgramsAgilent 82335A Driver National Instruments Gpib DriverBasic Controllers Error HandlingExample Programs D Call IBCLRPS% Example 2. IBM Controller Using National InterfaceCODES$=*CLS Option Base Example 3. Controller Using BasicIndex 100 IndexScpi 101102 Manual Updates
Related manuals
Manual 82 pages 25.5 Kb Manual 83 pages 60.43 Kb

6613C, 66312A, 6631B, 6611C, 6614C specifications

Agilent Technologies, a leader in electronic test and measurement solutions, offers a range of power supplies designed to meet various application needs. Notable models include the 6632B, 6634B, 66332A, 6633B, and 6612C. Each of these units provides unique features and technologies that cater to researchers, engineers, and technicians in the industry.

The Agilent 6632B is a single-output DC power supply that delivers up to 30V and 3A. It is known for its excellent load regulation and low noise, making it ideal for sensitive electronic testing. The model includes built-in voltage and current measurement capabilities, allowing users to monitor output conditions in real time. The 6632B is commonly used in laboratory environments, educational institutions, and manufacturing lines.

Moving to the 6634B, this model offers dual-output capabilities with a maximum output of 30V and 6A. This versatility enables simultaneous powering of two different devices or circuit sections. It also features parallel and series operation options, allowing users to create a custom power supply configuration for specific applications. With a programmable interface, the 6634B simplifies test automation, ensuring efficiency in extensive testing scenarios.

The Agilent 66332A stands out with its precision and high performance. This power supply provides three outputs—two programmable and one fixed—yielding flexible power configurations. Its intuitive user interface allows easy adjustment of voltage and current settings. The device is equipped with extensive protection features to safeguard both the power supply and the connected load against faults. It is an excellent choice for complex testing setups that require reliable power.

The 6633B model offers a high-performance power supply with dual outputs, similar to the 6634B but with enhanced specifications. It can provide up to 40V and 2A per channel, delivering precision for demanding applications. This model is particularly suited for industries focused on high-reliability applications, such as telecommunications and aerospace.

Lastly, the Agilent 6612C is a compact and lightweight power supply providing single-output up to 60V and 2A. This model is designed for simplicity and ease of use, making it an excellent choice for portable applications. The 6612C’s unique characteristics include a compact design and user-friendly controls, which facilitate operation in field settings.

In summary, Agilent Technologies’ power supply models—6632B, 6634B, 66332A, 6633B, and 6612C—offer an array of features that cater to a wide range of testing and research needs, ensuring reliable power delivery in various contexts.