Agilent Technologies 8164A, B Parameters None Response Identification terminated by END, Power-on

Page 59

IEEE-Common Commands

Instrument Setup and Status

command:

*IDN?

 

 

 

syntax:

*IDN?

 

description:

The IDeNtification query *IDN? gets the instrument identification over the interface.

parameters:

none

 

response:

The identification terminated by <END>:

 

For example.

 

 

Agilent Technologies

manufacturer

 

mmmm

instrument model number (for example 8164B)

 

ssssssss

serial number

 

rrrrrrrrrr

firmware revision level

example:

*IDN? → Agilent Techologies,mmmm,ssssssss,rrrrrrrrrr<END>

N O T E

The Agilent 8163A, Agilent 8164A, and Agilent8166A will always return Agilent Technologies as the

 

manufacturer. This will not be affected by the transition of these instruments to Agilent Technologies. This will

 

allow programs that use this string to continue functioning.

 

See “:SLOT[n]:HEAD[n]:IDN?” on page 82 for information on module identity strings.

 

 

 

command:

*OPC

syntax:

*OPC

description:

The instrument parses and executes all program message units in the input queue and

 

sets the operation complete bit in the standard event status register (SESR). This com-

 

mand can be used to avoid filling the input queue before the previous commands have fin-

 

ished executing.

 

Some module firmware includes commands that set a "StatNOPC" flag during execution

 

to indicate that the module is busy. *OPC blocks the GPIB bus to all commands until every

 

module hosted by the instrument is no longer busy.

 

The following actions cancel the *OPC command (and put the instrument into Operation

 

Complete, Command Idle State):

 

Power-on

 

• the Device Clear Active State is asserted on the interface.

 

*CLS

 

*RST

parameters:

none

response:

none

example:

*OPC

 

 

 

Agilent 8163A/B, 8164A/B & 8166A/B Mainframes, Fifth Edition

59

Image 59
Contents Agilent Technologies Warn in G WA R N I N G Japan 0120 421 0120 421 678 FAX Mexico 5081 Agilent Technologies Sales and Service OfficesThis manual is divided into 5 parts Structure of this ManualConventions used in this Manual T E Related ManualsTable of Contents Signal Conditioning Specific Command SummaryRoot Layer Command Signal Generation The SOURce SubsystemError Handling Installing the Agilent 816x Instrument DriverUsing Visual Programming Environments Features of the Agilent 816x Instrument DriverObsolete Commands Compatibility IssuesPreset Defaults Removed CommandAgilent 8163A/B, 8164A/B & 8166A/B Mainframes, Sixth Edition Operational/Questionable Status System forAgilent 8163A/B, 8164A/B & 8166A/B Mainframes, Sixth Edition List of Tables Agilent 8163A/B, 8164A/B & 8166A/B Mainframes, Sixth Edition Introduction to Programming Scpi Consortium Office Bode Enterprise Gpib InterfaceCamino del Rio South, Suite 340 San Diego, CA Introduction to ProgrammingMnemonic Function Gpib Interface If the instrument is in remote control, a screen resemblingReturning the Instrument to Local Control Message Queues Message QueuesClearing the Input Queue How the Input Queue WorksOutput Queue Is placed as the last message in the queue Error QueueIf no error has occurred, the error queue contains If more than 29 errors are put into the queue, the messageCrlf Command message is ended by a line feed character LF orProgramming and Syntax Diagram Conventions Statoperenab StatusoperationenableShort Form and Long Form Is in long form Short form of this message isString Value Wsp Command and Query SyntaxUnit Default Allowed Mnemonics UnitsSlot and Channel Numbers Data TypesLaser Selection Numbers 112, Input to your Return Loss module for the following commandsCommon Commands Common CommandsParameter Function Common Command SummaryGives a summary of the common commands Common Status Information ESE sets the Standard Event Status Enable MaskAll bits shown as are unused Event Status Enable Mask T E Status Registers Status ModelStatus Model Slot Status Condition Status System for 8163A/B & 8164A/BSlot Status Event Status System for 8166A/B Operation/Questionable Status Summary AnnotationsStatus Byte Register Standard Event Status RegisterQuestionable Slot Status Register Operation/Questionable Status Summary RegisterOperation/Questionable Slot Status Operation Slot Status RegisterStatus Model Long Status Command SummaryOPT? WAI IDN? Other CommandsIntroduction to Programming Specific Commands WAVelengthREFerence/? Specific Command SummarySpecific Commands Command DescriptionINPUTnCHANnelm Command Description DISPlayFETChnCHANnelmSCALar INITiatenCHANnelmROUTen PATH/?Terminals READnCHANnelmSENSenCHANnelmFUNCtion SENSenCHANnelmPOWerSLOTn Command Description SENSenCHANnelmPOWerReferenceSENSenCHANnelmRETurnlossCALibration SENSenCHANnelmRETurnlossCORRectionSOURcenCHANnelmAM SOURcenCHANnelmPOWerSOURcenCHANnelmPOWerATTenuationl SOURcenCHANnelmSOURcenCHANnelmWAVelengthREFerence SOURcenCHANnelmWAVelengthCORRectionSOURcenCHANnelmWAVelengthSWEepSTEP Command Description SOURcenCHANnelmWAVelengthSWEepSTATusnOPERation Command Description SPECialSTATusn STATusOPERationSYSTemCOMMunicateGPIB Command Description STATusnQUEStionableSlot n SYSTemSpecific Commands Instrument Setup and Status Instrument Setup and Status IEEE-Common CommandsStatus byte register STB Error queueAt power-on By sending a value of zero Standard event status register SesrBit Mnemonic Decimal Value ESE?Agilent Technologies Manufacturer Complete, Command Idle StatePower-on Parameters None Response Identification terminated by ENDExample OPT? → 81682A , , 81533B, 81532A, END Plete, Command Idle StateLead to useful gains in program execution efficiency Slot 1 for the Agilent 8163A/B and Agilent 8166A/BFollowing are not changed Error queueSelftest failed on Mainframe Bits MnemonicPending operations, are completed during the wait period WAIAgilent 8163A/B Agilent 8164A/B Agilent 8166A/B Status Reporting The STATus SubsystemSTATusOPERationEVENtLEVel0? Bits MnemonicsSTATusOPERationCONDitionLEVel0? Status Reporting The STATus SubsystemBits Mnemonics Decimal Value Agilent 8166A/B STATusOPERationENABleLEVelSTATusOPERationENABleLEVel0? STATusOPERationEVENtLEVel1?STATusOPERationCONDitionLEVel1? STATusOPERationENABleLEVel1Syntax STATusOPERationENABleLEVel1wspvalue Description STATusOPERationENABleLEVel1?STATus nOPERationCONDition? OffsetExtrapolated values STATus nOPERationEVENt?STATusPRESet STATusnOPERationENABleSTATusnOPERationENABlewspvalue STATusnOPERationENABle?Statques? → +0END STATusQUEStionableEVENtLEVel0?Agilent 8163A/B Agilent 8164A/B STATusQUEStionableCONDitionLEVel0? STATusQUEStionableEVENtLEVel1? STATusQUEStionableENABleLEVelSTATusQUEStionableENABleLEVel0? Syntax STATusQUEStionableCONDitionLEVel 1? Description Syntax STATusQUEStionableENABleLEVel 1wspvalue DescriptionSTATusQUEStionableENABleLEVel1? STATusQUEStionableCONDitionLEVel 1?STATusnQUEStionableCONDition? STATusnQUEStionableEVENt?Syntax STATusnQUEStionableEVENt? Description 11-15 Not UsedSTATusnQUEStionableENABle? STATusnQUEStionableENABleSTATusnQUEStionableENABlewspvalue SYSTemDATE? SYSTemERRor?SYSTemDATE Backlight and contrast of the display Output and error queuesStandard Event Status Enable Mask SESEM, Gpib interface stateSystcommgpibaddr SYSTemTIME?SYSTemVERSion? SYSTemCOMMunicateGPIBSELFADDRessMeasurement Operations & Settings LOCK? Root Layer CommandMeasurement Operations & Settings Slot nIDN? Agilent Technologies as the manufacturerManufacturer Slot nEMPTy?SLOTnHEADnIDN? SLOTnTST?SLOTnHEADnEMPTy? Syntax SLOTnHEADmWAVelengthRESPonse? Description SLOTnHEADmOPTions?SLOTnHEADmTST? SLOTnHEADmWAVelengthRESPonse?SLOTnHEADmWAVelengthRESPonseSIZE? SPECialREBootSLOTnHEADmWAVelengthRESPonseCSV? Measurement Functions The SENSe Subsystem CommandMeasurement Functions SENSe Subsystem Agilent 81635A and Agilent 81619A Master Slave ChannelsSENSenCHANnelmPOWerUNIT/? SENSenCHANnelmPOWerWAVelength/? FETChnCHANnelmSCAlarRETurnloss? FETChnCHANnelmSCAlarPOWerDC?INITiatenCHANnelmCONTinuous FETChnCHANnelmSCAlarMONitor?INITiatenCHANnelmIMMediate INITiate nCHANnel mCONTinuous? Read nCHANnel mSCALarPOWerALL?Member of the pair represents the channel number Read nCHANnel mPOWerALLCONFig?READnCHANnelmSCALarPOWerDC? BerREADnCHANnelmSCALarRETurnloss? READnCHANnelmSCALarMONitor?SENSenCHANnelmCORRectionCOLLectZERO SENSe nCHANnel mCORRectionLOSSINPutMAGNitudeSENSenCHANnelmCORRectionLOSSINPutMAGNitude? SENSenCHANnelmCORRectionCOLLectZEROALL SENSe nCHANnel mCORRectionCOLLectZERO?Operation SENSenCHANnelmFUNCtionPARameterLOGGing? SENSenCHANnelmFUNCtionPARameterLOGGingAveraging Time Wind SENSenCHANnelmFUNCtionPARameterMINMaxSENSenCHANnelmFUNCtionPARameterMINMax? ContResponse Example Affects Dual sensors SENSenCHANnelmFUNCtionPARameterSTABilityPeriod time Averaging Time Period TimeReturn Loss modules SENSenCHANnelmFUNCtionPARameterSTABility?SENSenCHANnelmFUNCtionRESult? Sens1funcres? →SENSe nCHANnel mFUNCtionRESultMAXBlocksize? SENSe nCHANnel mFUNCtionRESultBLOCk?SENSenCHANnelmFUNCtionRESultMONitor? SENSenCHANnelmFUNCtionSTATe? 100SENSenCHANnelmFUNCtionSTATe SENSenCHANnelmFUNCtionTHReshold? SENSenCHANnelmPOWerATIMe101 SENSenCHANnelmFUNCtionTHReshold102 SENSenCHANnelmPOWerATIMe?SENSenCHANnelmPOWerRANGeUPPer Range Upper Linear Power LimitRange Upper Linear SENSenCHANnelmPOWerRANGeUPPer?SENSenCHANnelmPOWerRANGeMONitorUPPer 103SENSenCHANnelmPOWerRANGeAUTO? SENSenCHANnelmPOWerRANGeMONitorUPPer?SENSenCHANnelmPOWerRANGeAUTO Ment. Otherwise, it must be set by the sensnpowrang commandDB if you use TOMODule or Reference mode using the command105 You must append a unit type106 SENSenCHANnelmPOWerREFerenceDISPlaySENSenCHANnelmPOWerREFerenceSTATe SENSenCHANnelmPOWerREFerenceSTATe?To the channel for the second value SENSe nCHANnel mPOWerREFerenceSTATeRATioSENSenCHANnelmPOWerREFerenceSTATeRATio? 107108 SENSe nCHANnel mPOWerUNITSENSenCHANnelmPOWerUNIT? SENSenCHANnelmPOWerWAVelengthSENSenCHANnelmRETurnlossCALibrationFACTory SENSenCHANnelmPOWerWAVelength?109 SENSenCHANnelmRETurnlossCALibrationFACTorySENSe nCHANnel mRETurnlossCALibrationTERMination? 110SENSe nCHANnel mRETurnlossCALibrationCOLLectTERMination Defined termination reference measurement. SeeSENSenCHANnelmRETurnlossCORRectionFPDeltal? 111SENSenCHANnelmRETurnlossCORRectionFPDeltal Lower wavelength source is denoted by 112SENSe nCHANnel mRETurnlossCORRectionREFLectance l DB referenceOUTPutnCHANnelmCONNection? Signal Generation The SOURce Subsystem113 OUTPutnCHANnelmCONNectionOUTPutnCHANnelmSTATe 114OUTPutnCHANnelmPATH? SOURcenCHANnelmAMINTernalFREQuencyl? 115SOURcenCHANnelmAMINTernalFREQuencyl INTINT1INT2COHCAEXTEXTDEXTWVLLBACK012356 116SOURcenCHANnelmAMSOURcel Syntax SOURcenCHANnelmAMSOURcelwspWavelength source is denoted by 117SOURcenCHANnelmAMSTATel SOURcenCHANnelmAMSTATel?SOURcenCHANnelmFMSOURcel 118SOURce nCHANnel mAMCOHCtrlCOHLevel l SOURcenCHANnelmAMCOHCtrlCOHLevell?SOURcenCHANnelmFMSTATel? 119SOURce nCHANnel mFMSOURce l? SOURcenCHANnelmFMSTATelSOURcenCHANnelmFMSBSCtrlFREQuencyl? 120SOURcenCHANnelmFMSBSCtrlFREQuencyl MhzkhzhzminmaxdefSOURcenCHANnelmMODout? 121SOURcenCHANnelmFMSBSCtrlLevell? SOURcenCHANnelmMODout122 SOURcenCHANnelmPOWerATTenuationl?This command is available in Attenuation Mode Only SOURcenCHANnelmPOWerATTenuationlAUTOSOURcenCHANnelmPOWerATTenuationlAUTO? SOURcenCHANnelmPOWerATTenuationlDARK124 SOURcenCHANnelmPOWerATTenuationlDARK?SOURcenCHANnelmPOWerLEVelIMMediateAMPLitudel Also allowed MIN minimum amplitude level SOURcenCHANnelmPOWerLEVelIMMediateAMPLitudel?125 126 SOURcenCHANnelmPOWerLEVelRISetimelSOURcenCHANnelmPOWerLEVelRISetimel? SOURcenCHANnelmPOWerUNIT? SOURce nCHANnel mPOWerSTATeSOURcenCHANnelmPOWerSTATe? SOURcenCHANnelmPOWerUNIT128 SOURcenCHANnelmPOWerWAVelengthSOURcenCHANnelmPOWerWAVelength? SOURce nCHANnel mREADoutDATABLOCk? 129SOURce nCHANnel mREADoutDATA? PmaxSOURcenCHANnelmWAVelengthCWlFIXEDl 130SOURcenCHANnelmWAVelengthCWlFIXEDlwspvalue SOURcenCHANnelmREADoutPOINts?SOURcenCHANnelmWAVelengthCORRectionARA 131SOURcenCHANnelmWAVelengthCWlFIXEDl? 81989A, 81949A 132SOURce nCHANnel mWAVelengthCORRectionARAALL SOURce nCHANnel mWAVelengthCORRectionAUTocalibSOURcenCHANnelmWAVelengthCORRectionZEROALL 133SOURce nCHANnel mWAVelengthCORRectionZERO Thzghzmhzkhzhz 134SOURcenCHANnelmWAVelengthCORRectionZEROAUTO SOURcenCHANnelmWAVelengthFREQuencylSOURcenCHANnelmWAVelengthREFerenceDISPlay 135SOURcenCHANnelmWAVelengthFREQuencyl? SOURcenCHANnelmWAVelengthREFerencel?Message 136SOURcenCHANnelmWAVelengthSWEepCHECkparams? SOURce nCHANnel mWAVelengthSWEepCYCLes? 137ValueMINMAXDEF0 SOURce nCHANnel mWAVelengthSWEepCYCLesSOURcenCHANnelmWAVelengthSWEepEXPectedtriggers? 138SOURce nCHANnel mWAVelengthSWEepDWELl SOURce nCHANnel mWAVelengthSWEepDWELl?Start Sweep waiting for trigger Trigger → 139SOURcenCHANnelmWAVelengthSWEepFLAG? Sweep stateSOURcenCHANnelmWAVelengthSWEepLLOGgingwspOFFON01 Following settings are the prerequisites for Lambda Logging140 SOURcenCHANnelmWAVelengthSWEepLLOGgingSOURcenCHANnelmWAVelengthSWEepPMAX? 141SOURcenCHANnelmWAVelengthSWEepMODE SOURcenCHANnelmWAVelengthSWEepMODE?SOURcenCHANnelmWAVelengthSWEepREPeat? 142SOURcenCHANnelmWAVelengthSWEepREPeat SOURcenCHANnelmWAVelengthSWEepSPEed? 143SOURce nCHANnel mWAVelengthSWEepSOFTtrigger SOURcenCHANnelmWAVelengthSWEepSPEedSOURcenCHANnelmWAVelengthSWEepSTOP 144SOURce nCHANnel mWAVelengthSWEepSTARt SOURcenCHANnelmWAVelengthSWEepSTARt?SOURcenCHANnelmWAVelengthSWEepSTATe If you enable lambda logging see145 SOURcenCHANnelmWAVelengthSWEepSTOP?SOURcenCHANnelmWAVelengthSWEepSTEPPREVious 146SOURcenCHANnelmWAVelengthSWEepSTATe? SOURcenCHANnelmWAVelengthSWEepSTEPNEXTSOURce nCHANnel mWAVelengthSWEepSTEPWIDTh? 147INPut nCHANnel mATTenuation Signal ConditioningINPut and OUTput commands 148INPutnCHANnelmOFFSetDISPlay 149INPutnCHANnelmOFFSet INPutnCHANnelmOFFSet?INPutnCHANnelmATTenuationSPEed? INPutnCHANnelmOFFSetPOWermeter150 INPutnCHANnelmATTenuationSPEedINPutnCHANnelmWAVelength? 151INPutnCHANnelmWAVelength MAX DEFOUTPut nCHANnel mAPMode? OUTPutnCHANnelmPOWerOUTPutnCHANnelmPOWer? 152153 OUTPutnCHANnelmPOWerREFerenceOUTPutnCHANnelmPOWerREFerence? OUTPutnCHANnelmPOWerREFerencePOWermeter154 OUTPutnCHANnelmPOWerOFFSetOUTPutnCHANnelmPOWerOFFSet? OUTPutnCHANnelmPOWerOFFSetPOWermeter155 OUTPut nCHANnel mPOWerCONTRolOUTPutnCHANnelmPOWerCONTRol? OUTPutnCHANnelmPOWerUNitOUTPut nCHANnel mSTATe OUTPut nCHANnel mPOWerUNit?OUTPutnCHANnelmSTATeAPOWeron 156OUTPutnCHANnelmATIMe? OUTPutnCHANnelmSTATeAPOWeron?157 OUTPutnCHANnelmATIMeOUTPCORRCOLLZER0? → 0END 158OUTPutnCHANnelmCORRectionCOLLectionZEROALL 159 Table of wavelength-dependent offsetsCONF1OFFSWAVSTAT on CONFigurenCHANnelmOFFSetWAVelengthSTATeCONFigurenCHANnelmOFFSetWAVelengthSTATe? 160CONF1OFFSWAVREF 4,2 CONFigurenCHANnelmOFFSetWAVelengthVALueCONFigurenCHANnelmOFFSetWAVelengthREFerence 161162 CONFigurenCHANnelmOFFSetWAVelengthREFerence?CONFigurenCHANnelmOFFSetWAVelengthVALueWAVelength? CONFigurenCHANnelmOFFSetWAVelengthVALueOFFSet?163 CONFigurenCHANnelmOFFSetWAVelengthVALuePAIR?CONFigurenCHANnelmOFFSetWAVelengthVALueDELete CONFigurenCHANnelmOFFSetWAVelengthVALueDELeteALLCONF1OFFSWAVTABSIZE? → CONFigurenCHANnelmOFFSetWAVelengthTABle?CONFigurenCHANnelmOFFSetWAVelengthTABleSIZE? 164165 When the attenuator is hosted in SlotTIP Query the Scpi error queue using SYSTERR? Slot Numbers166 Command Semantic167 Display and System CommandsIeee Commands 168 Status CommandsUser Calibration Data ROUTe nCHANnel m Signal RoutingSwitch modules 169170 ROUTenCHANnelmCONFig?Syntax ROUTenCHANnelmCONFig? Description ROUTenCHANnelmCONFigROUTe?Software Triggering Data Acquisition Functions Sensfuncstat Triggering The TRIGger Subsystem171 HardwareSoftware Triggering Data Acquisition Functions Generating Output Triggers from Power MeasurementsDISabled An output trigger will never be generated AVGover 172173 TRIGgernCHANnelmINPutREARm 174TRIGgernCHANnelmINPut? TRIGgernCHANnelmOFFSet value 175TRIGger nCHANnel mINPutREARm? TRIGgernCHANnelmOFFSetContinuous mode, wavswestepwidt is used for triggering, see 176TRIGger nCHANnel mOUTPut Return loss modulesTRIGger nCHANnel mOUTPutREARm Output triggers using power measurementsTRIGgerCONFiguration 177178 TRIGgerCONFiguration?TRIGgerCONFigurationFPEDal TRIGgerCONFigurationFPEDal?Bit unsigned integer , see below Extended Trigger Configuration179 TRIGger180 Extended Trigger Configuration181 Node a Input ConfigurationNode B Input Configuration 182 Extended Trigger Configuration ExampleOutput Trigger Connector or Individual module slots Output Matrix ConfigurationSequence starts again at and continues until the sweep ends 183Trigconfext #H2,#H0,#H0 is described by -1 and sets one bit 184 185 Mass Storage, Display, and Print FunctionsDisplay Display OperationsDISPlay Subsystem 186DISPlayBRIGhtness? DISPlayENABleDISPlayENABle? 187DISPlayLOCKout? 188Mass Storage, Display, and Print Functions CD-ROM 08164-90BC4 Instrument using Visa library calls189 Same programVisa Programming Examples How to Use Visa Calls190 191 How to Use Visa Calls192 How to Set up a Fixed Laser Source193 How to Set up a Fixed Laser Source194 195 How to Measure Power using FETCh and ReadHow to Measure Power using FETCh and Read 196 197 198 199 How to Co-ordinate Two ModulesHow to Co-ordinate Two Modules 200 201 202 203 How Power Varies with WavelengthHow Power Varies with Wavelength 204 205 206 207 How to Log ResultsHow to Log Results 208 209 210 211 212 213 Agilent 816x VXIplug&play Instrument DriverAgilent 816x VXIplug&play Instrument Driver 214215 Installing the Agilent 816x Instrument Driver216 Program Folder Item Options 217218 Using Visual Programming EnvironmentsGetting Started with Agilent VEE Gpib Interfacing in Agilent VEESelect hp816X from the Plug&play Driver Name drop-down list Using Visual Programming Environments219 Enter the following information Name enter hp816X220 This folder contains a subfolder named instr.lib Getting Started with LabView221 FP Conversion Options Box 222Instrument Driver with LabView 223LabView is a trademark of National Instruments Corporation 224 Getting Started with LabWindows225 Features of the Agilent Instrument DriverFeatures of the Agilent 816x Instrument Driver 226 Directory StructureOpening an Instrument Session Opening an Instrument Session227 Successful completion of this function returns Visuccess228 Closing an Instrument SessionVisa Data Types and Selected Constant Definitions 229ViStatus errStatus Error HandlingCheck for an error or event after each function 230231 Error HandlingDevelopment Environments Introduction to ProgrammingExample Programs VISA-Specific Information233 Microsoft Visual Basic 4.0 or higherAgilent VEE 5.01 or higher LabWindows CVI/ R 4.0 or higherLatest copy of this driver can be downloaded via Online Information234 Lambda Scan Applications Lambda Scan Applications235 236 Equally Spaced Datapoints237 How to Perform a Lambda Scan ApplicationPrepare Lambda Scan Function Get Lambda Scan Parameters Get Lambda Scan Parameters FunctionExecute Lambda Scan Function 238239 How to Perform a Multi-Frame Lambda Scan Application8164A or B Power Power 8163A or B240 Equally Spaced Datapoints FunctionRegister Mainframe Function Unregister Mainframe Function241 Prepare Multi Frame Lambda Scan Function242 Get MF Lambda Scan Parameters FunctionExecute Multi Frame Lambda Scan Function Get Lambda Scan Result FunctionMaximum number of channels that may be specified is Get Number of PWM Channels FunctionGet Channel Location Function 243244 257 Error Codes258 Gpib Error StringsSuffix too long 259Program mnemonic too long 260 New 201 261New 185 Standard 200Old 213 262Old 211 Old 212Standard 222 263Old 221 264 265 266 267 268 To -499 Query ErrorsStandard 440 269Standard 420 Standard 430Overview for Unsupported Strings 270245 Gpib Command Compatibility ListGpib Bus Compatibility Compatibility IssuesThese commands are incompatible Command Change Affects247 248 Preset DefaultsPreset defaults are different 249 Removed Command250 Obsolete CommandsOld Command New Command Affects Dispbrig Changed Parameter Syntax Semantics251 SOURAMFREQ/?SENSPOWUNIT? Changed Query Result Values252 TSTChange Affects Timing Behavior253 Details the ways in which timing behavior is differentFLT/DBLMAX 254Returned Value Affects 255 Command OrderCommand Order 256 Instrument Status Settings271 IndexSlot 272Page  Agilent Technologies, Deutschland GmbH 08164-90B64
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