Agilent Technologies E9300 manual Getting Started, Initial Inspection

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Getting Started

Getting Started

Initial Inspection

Inspect the shipping container for damage. If the shipping container or packaging material is damaged, it should be kept until the contents of the shipment have been checked mechanically and electrically. If there is mechanical damage, notify the nearest Agilent Technologies office. Keep the damaged shipping materials (if any) for inspection by the carrier and a Agilent Technologies representative. If required, you can find a list of Agilent Technologies Sales and Service offices on page -70.

Checking Power Meter Firmware and DSP Revision

Before proceeding, first ensure your Agilent EPM series power meter has both the required firmware and DSP revisions for the correct operation of your Agilent EPM series power meters.

On the power meter press System , More , Service , Version .

Inputs

Firmware Revision

Code (dual channel)

DSP Revision

Code

Figure 3 Power Meter Firmware Version Screen

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Contents Operating and Service Guide Copyright 1999 Agilent Technologies Legal Information WarrantyCertification Limitation of Warranty Exclusive RemediesGeneral Safety Information Sound EmissionPower Meter Front Panel Operation SafetyConventions Sensors Covered by Manual DocumentationRelated Publications Documentation Table of Contents Standing Wave Ratio SWR and Reflection Coefficient Rho Per Introduction Typical HP E-series E9300 power sensors Power Meter Requirements General InformationAgilent E-Series E9300 Power Sensors in Detail Simplified Block Diagram of Diode Pair/Attenuator/Diode PairGeneral Information Getting Started Checking Power Meter Firmware and DSP RevisionInitial Inspection Interconnections and Calibration Specifications Making Measurements What You’ll Find This Chapter Power Meter Configuration Changes Auto-averaging SettingsMeasuring Spread Spectrum and Multitone Signals Spread Spectrum SignalCdma Signal Measurements Cdma IS-95A 9Ch FwdMultitone Signal Measurements 90 % Frequency GHz Typical Lower Range Calibration FactorPower Meter and Sensor Operation Measuring Tdma SignalsAchieving Stable Results with Tdma Signals Achieving Stable Results with GSM Signals Input Settings , MoreElectromagnetic Compatibility EMC Measurements Setting the Range Measurement Accuracy and SpeedMeasurement Considerations AccuracySpeed and Averaging SummarySpecifications and Characteristics Sensor Low Power Path High Power Path IntroductionConnector Type E9300/1/4/A Power Sensor SpecificationsMaximum SWR 0C to +55C Maximum Power Maximum DC VoltagePower Linearity ± 2.5%Typical Power Linearity at 25C, after zero Additional Power Switching Point Zero Set Zero Drift Measurement NoiseSettling Time Time E4418B E4419BX2 Mode Calibration Factor and Reflection CoefficientCal Factor Uncertainty General E9300/1B and H Power Sensor Specifications Frequency RangeE9300B Typical SWR 25C ± 10C E9300H Typical SWR 10 MHz to 18 GHz 25C ± 10C Maximum Power Sensor To 35 C To 55 C GHz E9300/1B To 0 dBm To 10 dBm 10 to 20 dBm 20 to 26 dBm For larger changes refer to the following table E9300/1H DBm to 0 dBm +44 +30 dBm E9300/1B Conditions Zero Set Zero Drift2 Measurement Settling Time Typical Cal Factor Uncertainty Low Power Path Cal Factor Uncertainty High Power Path References Storage and Shipment EnvironmentE9300/1B and H Power Sensor Specifications Service Cleaning Connector CleaningPerformance Test Frequency System Rho Actual Maximum Uncertainty MeasurementPerformance Test Replaceable Parts Is the illustrated parts breakdown IPB that identifies allIllustrated Parts Break down Reference Agilent Part Qty Description Designation Number LABEL, ID E9301B Service Principles of OperationDisassembly Procedure TroubleshootingRepair of Defective Sensor Reassembly Procedure Removing Power Sensor ShellSales and Service Offices Asia PacificEurope