Agilent Technologies 66311B, D, 66309B Measuring Circuits Floating with Respect to the Main Output

Page 41

Installation - 3

You cannot measure voltages greater than +25 Vdc with respect to the negative terminal of the main output. A situation where this could occur is illustrated by R1 in figure 3-8, which has only a 12 Vdc drop across it but is 36 Vdc + Vlead with respect to the negative terminal of the main output.

You cannot measure voltages less than 4.5 Vdc with respect to the negative terminal of the main output. A situation where this could occur is illustrated by R6 in figure 3-8, which has only a 2 Vdc drop across it but is 6 Vdc + Vlead with respect to the negative terminal of the main output.

When calculating the common mode voltage between the point that you wish to measure and the negative terminal of the main output, you must also include any voltage drop in the negative load lead. For example, in figure 3-8, if the voltage drop in the negative load lead is 2 V, you would not be able to correctly measure the 12 Vdc drop across R2. This is because when the voltage drop in the load lead is added to the voltage drops across R2 and R3, the resultant voltage is 26 Vdc, which exceeds the +25 Vdc common mode rating of the DVM.

Measuring Circuits that are Floating with Respect to the Main Output

In the example shown in figure 3-9, the common mode voltage between the DVM inputs and the minus terminal of the main output (output 1) includes an undefined floating voltage that may result in incorrect readings due to clipping by the internal DVM measurement circuits. This will occur when the 4.5 Vdc to + 25 Vdc common mode voltage range is exceeded.

The solution to this problem would be to provide a known or controlled common mode voltage by connecting a jumper wire from the floating voltage to be measured to the main output. In this example, the main output is set to 5V, the ac voltage to be measured is approximately 6 Vac (±8.5 Vpeak), and a jumper wire connects one side of the bias transformer to the + main output terminal. This stabilizes the common mode voltage and offsets it by the output voltage value (5 V). The peak common mode voltage is now:

+8.5V + 5 V = +13.5 V on the positive side, and 8.5V + 5 V = 3.5 V on the negative side;

with both voltages now being within the common mode range of the DVM.

 

 

 

6 V Bias

 

 

 

Transformer

 

 

 

winding capacitance

Agilent 66309D

 

 

AC

Agilent 66311D

 

 

 

 

 

DVM INPUT

 

TO

6 Vac;

 

8.5 Vpk

 

 

DVM

 

 

 

 

jumper wire

ACC

 

 

 

 

 

winding capacitance

OUTPUT 1

+

 

 

 

+ 5 V

 

stray

 

 

 

 

 

capacitance

 

GND

GND

GND

Typically, low voltage with respect to GND due to internal bypass capacitors.

Undefined float voltage with respect to GND due to capacitive currents. Could be tens of volts ac or more.

Figure 3-9. Measuring Circuits Floating with Respect to the Main Output

41

Page 40 Page 42
Image 41
Page 40 Page 42
Contents USER’S Guide Certification Warranty InformationGeneral Safety SummarySafety Symbols EMC DeclarationDeclaration of Conformity Printing History Acoustic Noise InformationTable of Contents VXIplug&play Power Products Instrument Drivers Checkout Procedure Case of TroubleTypes of Scpi Commands DVM ConnectionsScpi Data Formats Types of Scpi MessagesIntroduction Programming the Output Triggering Output ChangesCalibration Commands 100 Inhibit/Fault IndicatorDisplay Commands 103 Measurement Commands 104Status Commands 121 Output Commands 114System Commands 125 Trigger Commands 126Additional Commands Common CommandsSpecifications 143 Supplemental Characteristics 144 Performing the Calibration Procedure 154Introduction 165 Error Number List 161Basic Introduction 177Front Panel At a Glance Quick ReferenceRear Panel At a Glance Instrument ConfigurationUse the front panel Address key to configure the interface Use the Function keys and Entry keys to enter a new value Front Panel Number EntryImmediate Action Keys Front Panel AnnunciatorsFront Panel Menus At a Glance ABORt CALibrate Scpi Programming Commands At a GlanceUsing the programming interface Using the front panelProgramming the unit using Scpi COMPatibility commands Installing the VXIplug&play instrument driverOptions and Accessories Safety ConsiderationsOption DescriptionAgilent Description and Model DifferencesAgilent 66309B Agilent 66309DRemote Programming Common CapabilitiesFront Panel Controls Dc Source Output 1 Characteristic Output 1 CharacteristicOutput 2 Characteristic Output 2 CharacteristicOption 521 Relay Modes Option 521 Factory SettingsOption 521 Description Agilent 66309B/D only Page Check the Operating Settings and Conditions Installation and Operation ChecklistAdditional Agilent 66311/66309 Operating Settings Checks Check the Phone ConnectionsInspection CleaningLocation Damage Packaging MaterialInput Connections Connect the Power CordBench Operation Rack MountingOutput Connections Turn the unit off before connecting any wiresOutput Current RatingsRemote Sense Connections Remote Sense ConnectionsRemote Sense Connections with External Relays Maintaining Stability while Remote Sensing Load Regulation and Voltage Drop in the Remote Sense LeadsOpen Sense Lead Protection Message Description Local SensingOutput Compensation OVP Considerations DVM ConnectionsMeasuring Circuits Not Powered by the Main Output Measuring Circuits that are Not Powered by the Main OutputMeasuring Circuits Floating with Respect to the Main Output 10. FLT/INH Examples External Protection ConnectionsDigital I/O Connections FLT/INH DIGital I/O ConnectorComputer Connections Gpib InterfacePin Input/Output Description RS-232 InterfaceProcedure Display Explanation Checkout ProcedurePress Output On/Off Press ProtectProcedure Display Explanation Case of Trouble Selftest Error MessagesPress Shift, Channel Enter Number 12, Enter Press Output On/OffPower-On Selftest Errors Runtime Error MessagesRuntime Error Messages Line FuseFront Panel Description IntroductionFront Panel Operation OFF Display Command FunctionSystem Keys Scrolling Keysq Function KeysImmediate Action Keys Display Measurement Metering KeysOver Current Output Control KeysEntry Keys Entry KeysExamples of Front Panel Programming Using the Front Panel DisplaySelecting an output on Agilent 66309B/D units Selecting the DVM on Agilent 66311D/66309D unitsSet the output current limit Set the output voltageSet the output compensation Typecap HighSet the output 2 voltage Enable the outputSet the output 2 current limit Keypad, press Enter Number, 7, EnterDisable Overvoltage Protection as follows Querying and Clearing Output Protection and ErrorsQuery and Clear Errors as follows OvercurrentUse the Meter menu for making front panel measurements Making Basic Front Panel MeasurementsMaking Enhanced Front Panel Measurements Default Front Panel Measurement ParametersUse the Meter menu for making DVM measurements Making DVM Measurements Agilent 66311D/66309D onlyCurrrang Auto Currdet AcdcTo configure the Ridfi mode of the port, proceed as follows Setting the Gpib Address and Programming LanguageTo configure the Digio mode of the port, proceed as follows Set the Gpib address as followsStoring and Recalling Instrument States Scpi 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 Introduction to ScpiRS-232 Flow Control Boldface font Types of Scpi CommandsConventions Used in This Guide Moving Among Subsystems Multiple Commands in a MessageIncluding Common Commands Types of Scpi Messages Using QueriesMessage Unit HeadersScpi Data Formats Suffixes and Multipliers Scpi Command CompletionResponse Data Types Class Suffix Unit Unit with MultiplierScpi Conformed Commands Using Device ClearNon-SCPI Commands Scpi Conformance InformationEnabling the Output Power-on InitializationProgramming the Output Output Current Output VoltageTriggering Output Changes Setting the Voltage or Current Transient LevelsScpi Triggering Nomenclature Output Trigger ModelSelecting the Output Trigger Source Enabling the Output Trigger SystemGenerating Triggers Single TriggerControlling Measurement Samples Making Basic MeasurementsAverage Measurements Window Functions Making Enhanced MeasurementsRMS Measurements Current Ranges and Measurement DetectorHigh/Low Measurements Pulse MeasurementsMinimum and Maximum Measurements Returning All Measurement Data From the Data Buffer Making DVM MeasurementsSequence Form Alias SEQuence2 ACQuire Triggered MeasurementsMeasurement Trigger Model Selecting the Measurement Trigger Source Enabling the Measurement Trigger SystemSelecting the Sensing Function INTernalSingle Triggers Generating Measurement TriggersTrigacqcouncurr number or Trigacqcounvolt number Pre-trigger and Post-trigger Data Acquisition Programming the Status RegistersDC Source Status Model Power-On ConditionsOperation Status Group Bit Configurations of Status RegistersQuestionable Status Group PON Power On BitStandard Event Status Group Status Byte RegisterServicing Operation Status and Questionable Status Events Determining the Cause of a Service InterruptMSS Bit RQS BitRemote Inhibit RI Inhibit/Fault IndicatorMonitoring Both Phases of a Status Transition Using the Inhibit/Fault Port as a Digital I/O Discrete Fault Indicator DFIBit Weight PinSubsystem Commands Subsystem Commands Syntax Language Dictionary Language Dictionary Programming Parameters Common CommandsCALibrateCURRent Calibration CommandsCALibrateCURRent2 CALibrateCURRentMEASureLOWRangeCALibrateDATA CALibratePASSwordCALibrateDATE CALibrateDVMCALibrateSTATe CALibrateSAVECALibrateVOLTage CALibrateVOLTage2DISPlay Display CommandsDISPlayCHANnel DISPlayMODE104 Measurement CommandsFORMat MEASureARRayCURRent? FETChARRayCURRent? FORMatBORDerMEASureARRayVOLTage? FETChARRayVOLTage? Query SyntaxMEASureCURRent2? MEASureCURRent? FETChCURRent?MEASureCURRentACDC? FETChCURRentACDC? NR3MEASureCURRentLOW? FETChCURRentLOW? MEASureCURRentHIGH? FETChCURRentHIGH?MEASureCURRentMAXimum? FETChCURRent MAXimum? 107MEASureDVM? FETChDVM? MEASureCURRentMINimum? FETChCURRentMINimum?MEASureDVMACDC? FETChDVMACDC? MEASureVOLTage? FETChVOLTage?MEASureVOLTageACDC? FETChVOLTageACDC? MEASureVOLTage2MEASureVOLTageHIGH? FETChVOLTageHIGH? 109MEASureVOLTageMAXimum? FETChVOLTageMAXimum? MEASureVOLTageLOW? FETChVOLTageLOW?MEASureVOLTageMINimum? FETChVOLTageMINimum? 110SENSeCURRentRANGe SENSeCURRentDETectorQuery Syntax SENSeCURRentDETector? 111SENSePROTectionSTATe SENSeFUNCtionSENSeSWEepOFFSetPOINts SENSeSWEepPOINtsSENSeWINDow SENSeSWEepTINTervalQuery Syntax SENSeSWEepTINTerval? Query Syntax SENSeWINDowTYPE?INSTrumentCOUPleOUTPutSTATe Output CommandsOUTPut1 OUTPut1 2RELayMODEOUTPutDFISOURce OUTPutDFIOUTPutPONSTATe 115OUTPutPROTectionCLEar OUTPutPROTectionDELayOUTPutRIMODE OUTPutTYPE117 SOURceCURRentSOURceCURRent2 SOURceCURRentPROTectionSTATe Command Syntax Parameters RST Value ExamplesSOURceCURRentTRIGger SOURceCURRent2TRIGgerSOURceDIGitalFUNCtion SOURceDIGitalDATASOURceVOLTage 119SOURceVOLTagePROTection SOURceVOLTage2SOURceVOLTagePROTectionSTATe 120STATusPRESet Status CommandsSOURceVOLTageTRIGger SOURceVOLTage2TRIGgerBit Configuration of Operation Status Registers STATusOPERationENABleSTATusOPERation? STATusOPERationCONDition?Bit Configuration of Questionable Status Registers Parameters Preset ValueSTATusOPERationNTR STATusOPERationPTR STATusQUEStionable?STATusQUEStionableCONDition? STATusQUEStionableENABleSTATusQUEStionableNTR STATusQUEStionablePTR 124SYSTemERRor? System CommandsSYSTemLANGuage SYSTemVERSion?Related Commands Trigger CommandsABORt INITiateSEQuence INITiateNAME127 TRIGgerTRIGgerSOURce TRIGgerSEQuence2COUNtCURRent TRIGgerACQuireCOUNtCURRent TRIGgerSEQuence2 TRIGgerACQuireTRIGgerSEQuence2COUNtDVM TRIGgerACQuireCOUNtDVM 128129 TRIGgerSEQuence2COUNtVOLTage TRIGgerACQuireCOUNtVOLTageUnit 130 TRIGgerSEQuence2HYSTeresisDVM TRIGgerACQuireHYSTeresisDVM131 TRIGgerSEQuence2LEVelCURRent TRIGgerACQuireLEVelCURRentTRIGgerSEQuence2LEVelDVM TRIGgerACQuireLEVelDVM TRIGgerSEQuence2SLOPeCURRent TRIGgerACQuireSLOPeCURRent TRIGgerSEQuence2LEVelVOLTage TRIGgerACQuireLEVelVOLTageReturned Parameters 132133 TRIGgerSEQuence2SLOPeDVM TRIGgerACQuireSLOPeDVMTRIGgerSEQuence2SLOPeVOLTage TRIGgerACQuireSLOPeVOLTage 134 TRIGgerSEQuence2SOURce TRIGgerACQuireSOURceTRIGgerSEQuence1DEFine TRIGgerSEQuence2DEFine Command Syntax *CLS Parameters None Common CommandsBit Configuration of Standard Event Status Enable Register 135136 Field InformationExample RCL NRf Query Syntax *OPT? Returned Parameters AardParameters Example 137RST Settings Command Syntax *SAV NRfExample *SAV Related Commands *RCL *RST 138 Bit Configuration of Status Byte Register Power-on ValueQuery Syntax *STB? 139Query Syntax TST? Returned Parameters NR1 TRGAdditional Commands VOLTageLIMitHIGH? CURRentPROTectionTRIPped?VOLTageLIMitLOW? VOLTagePROTectionTRIPped?143 SpecificationsTable A-1. Performance Specifications Table A-2. Supplemental Characteristics Supplemental Characteristics144 Agilent 66309B/D145 146 Table A-4. Agilent 66309B/D Option 521 CharacteristicsEquipment Required Test Setup147 Table B-1. Equipment Required148 Performing the Verification TestsTurn-On Checkout Current Programming and Measurement Accuracy Voltage Programming and Measurement AccuracyOutput terminals on both outputs 1 Steps 6-10 apply to Agilent 66309B/D output 2 only150 Steps 7-11 apply to Agilent 66309B/D output 2 onlyCurrent Sink Measurement 151 DVM Measurement Accuracy152 DVM Voltage Measurement Agilent 66309D only 153154 Performing the Calibration ProcedureFront Panel Calibration Menu Check the Language Setting Front Panel Calibration ProcedureEnable Calibration Mode Voltage Programming and Measurement CalibrationOvervoltage Protection Calibration Steps 11-16 apply to Agilent 66309B/D output 2 onlyCurrent Programming and High-Range Measurement Calibration 156Calcurrmeas AC Steps 27-32 apply to Agilent 66309B/D output 2 only157 DVM Calibration applies to Agilent 66311D, 66309D only Restore the Language SettingSaving the Calibration Constants 158Changing the Calibration Password Calibration Error MessagesTable B-3. Gpib Calibration Error Messages Calibration Over the GpibPage 161 Error Number ListTable C-1. Error Numbers 162 Error Messages163 Error Messages CPage 165 Assigning the Gpib Address in ProgramsNational Instruments Gpib Driver 166 Error HandlingExample 1. National Instruments Interface Example Example Programs D 167168 Example 2. Controller Using Basic169 Example 3. Current Pulse Measurement Using Basic170 171 172 173 Example 5. DFI Example Using BasicDFI Programming Example Page Install the Correct Line Fuse Configure the Power TransformerOpen the Unit Close the Unit176 Figure E-1, Power Transformer AC Input Connections177 Command SettingTable F-1. COMPatibility Power-on Settings Similar Scpi Command Compatibility CommandTable F-2. COMPatibility Commands 178179 NumberError String Description/Explanation/Examples ErrorTable F-3. COMPatibility Errors 180181 Table F-5. Bit Configuration of Serial Poll RegisterPage 183 Index184 Index185 186 OVERTEMPERATURE, 47 OVERVOLTAGE, 47 OVLD, 47, 60, 61187 Subsystem commands syntax, 96 suffixesType CAP 188Canada Australia/New Zealand United States Latin AmericaEurope Asia Pacific JapanManual Updates
Related manuals
Manual 8 pages 56.17 Kb

66111A, 66309B, 66311B, D specifications

Agilent Technologies D,c,83440b is an advanced electronic measurement solution designed for engineers and scientists who require precise and reliable performance in their testing environments. This modular test system offers a comprehensive suite of features that cater to a wide range of applications, from high-frequency testing to complex signal analysis.

One of the main features of the D,c,83440b is its impressive frequency range, allowing users to conduct tests across a wide spectrum of signals. The system is capable of handling frequencies up to 26.5 GHz, making it ideal for RF and microwave applications. This broad range ensures that users can work with a variety of devices, including communication systems, radar, and satellite technology.

In addition to its frequency capabilities, Agilent Technologies has engineered the D,c,83440b with exceptional dynamic range and low noise figures. This ensures that even the smallest signals can be accurately measured, allowing for greater precision in testing. The full spectrum analysis feature enables users to capture transient events and analyze them in real-time, which is crucial for troubleshooting and performance evaluations.

The D,c,83440b is built on a modular platform, allowing users to customize their systems according to specific testing needs. This modularity not only enhances flexibility but also simplifies maintenance and upgrades. Users can easily swap out different modules without the need for extensive system reconfiguration, which can significantly reduce downtime in testing environments.

Another standout characteristic of the D,c,83440b is its user-friendly interface. With a large, high-resolution display and intuitive controls, engineers can quickly navigate through settings and data, streamlining the testing process. This ease of use is complemented by powerful software solutions that can automate test sequences, aiding in efficiency and accuracy.

The integration of advanced digital signal processing technologies further enhances the capabilities of the D,c,83440b. These technologies enable more sophisticated measurements and improved signal integrity, which is essential for modern communication systems.

In summary, the Agilent Technologies D,c,83440b is a multifaceted electronic measurement solution that boasts a wide frequency range, excellent dynamic range, modular design, and user-friendly interface. This combination of features makes it suitable for various applications, ensuring that engineers and scientists have the tools they need to succeed in their testing and measurement endeavors.
Top Page Image Contents