Measure Frequency on Keysight 532xx Frequency Counter Using the IVI-C Driver
This example shows how to initialize the driver, read a few properties of the driver and measure frequency using Keysight™ Technologies 532xx Frequency Counter and output the result in MATLAB®.
Requirements
This example requires the following:
Keysight IO libraries version 17.1 or newer
Keysight 532xx Frequency Counter IVI driver version 1.0.11.0 or newer
Enumerate Available IVI-C Drivers On The Computer
This enumerates the IVI drivers that have been installed on the computer.
IviInfo = instrhwinfo('ivi');
IviInfo.Modules
ans = Columns 1 through 6 'Ag33220' 'Ag3352x' 'Ag34410' 'Ag34970' 'Ag532xx' 'AgAC6800' Columns 7 through 11 'AgE36xx' 'AgInfiniiVision' 'AgMD1' 'AgRfSigGen' 'AgXSAn' Columns 12 through 13 'KtRFPowerMeter' 'rsspecan'
Create MATLAB Instrument Driver And Connect To The Instrument
% Create the MATLAB instrument driver makemid('Ag532xx','Ag532xx.mdd') % Use icdevice with the MATLAB instrument driver name and instrument's % resource name to create a device object. In this example the instrument % is connected by GPIB at board index 0 and primary address 1. myInstrument = icdevice('Ag532xx.mdd', 'GPIB0::01::INSTR','optionstring','simulate=true'); % Connect driver instance connect(myInstrument);
Attributes and Variables Definition
% These values are defined in the driver's header file 'Ag532xx.h'
AG532XX_VAL_SLOPE_POSITIVE = 1;
AG532XX_VAL_TRIGGER_SOURCE_IMMEDIATE = 0;
AG532XX_VAL_ARM_MEASUREMENT_TYPE_FREQUENCY = 0;
AG532XX_VAL_ARM_SOURCE_ADVANCED = 3;
AG532XX_VAL_IMMEDIATE_ARM_TYPE = 1;
AG532XX_VAL_DELAY_HOLD_OFF_SOURCE_TIME = 1;
Get General Device Properties
Query information about the driver and instrument
InherentIviAttributesDriverIdentification = get(myInstrument,'Inherentiviattributesdriveridentification'); InherentIviAttributesInstrumentIdentification = get(myInstrument,'Inherentiviattributesinstrumentidentification'); Utility = get(myInstrument, 'Utility'); Revision = invoke(Utility, 'revisionquery'); Vendor = get(InherentIviAttributesDriverIdentification, 'Specific_Driver_Vendor'); Description = get(InherentIviAttributesDriverIdentification, 'Specific_Driver_Description'); InstrumentModel = get(InherentIviAttributesInstrumentIdentification, 'Instrument_Model'); FirmwareRev = get(InherentIviAttributesInstrumentIdentification, 'Instrument_Firmware_Revision'); % Print the queried driver properties fprintf('Revision: %s\n', Revision); fprintf('Vendor: %s\n', Vendor); fprintf('Description: %s\n', Description); fprintf('InstrumentModel: %s\n', InstrumentModel); fprintf('FirmwareRev: %s\n', FirmwareRev); fprintf(' \n');
Revision: 1.0.11.0 Vendor: Agilent Technologies Description: IVI Driver for Agilent 532xx family of Counters. [Compiled for 64-bit.] InstrumentModel: 53230A FirmwareRev: Sim1.0.11.0
Basic Frequency Measurement
fprintf('\nBasic Frequency Measurement \n'); % Configure the counter for a frequency measurement on the specified % channel InstrumentSpecificFrequency = get(myInstrument,'Instrumentspecificfrequency'); invoke(InstrumentSpecificFrequency, 'frequencyconfigure', 1E6,1E-4,1); % Sets the number of triggers that will be accepted by the instrument % before returning to the "idle" trigger state InstrumentSpecificTrigger = get(myInstrument,'Instrumentspecifictrigger'); set(InstrumentSpecificTrigger, 'Trigger_Count', 1); % Sets trigger source for measurements. % IMMediate (continuous) source immediately issues the trigger set(InstrumentSpecificTrigger, 'Trigger_Source', AG532XX_VAL_TRIGGER_SOURCE_IMMEDIATE); % Sets slope of the trigger signal on the rear-panel Trig In BNC set(InstrumentSpecificTrigger, 'Trigger_Slope', AG532XX_VAL_SLOPE_POSITIVE); % Initiates a measurement based on the current configuration. MeasurementLowLevelMeasurement = get(myInstrument,'Measurementlowlevelmeasurement'); invoke(MeasurementLowLevelMeasurement, 'initiate'); % Does not return until previously started operations complete or more % MaxTimeMilliseconds milliseconds of time have expired. InstrumentSpecificSystem = get(myInstrument,'Instrumentspecificsystem'); invoke(InstrumentSpecificSystem, 'systemwaitforoperationcomplete', 10000); % Retrieves the result from a previously initiated measurement. RetVal = invoke(MeasurementLowLevelMeasurement, 'fetch'); fprintf('Data: %0.15g\n', RetVal);
Basic Frequency Measurement Data: 0
Measure Frequency With Averaging Function
Gets the mathematical average (mean) of all measurements taken since the last time statistics were cleared. The purpose of using averaging function is to increase the reliability and signal-to-noise ratio of the measurements.
fprintf('\nAveraging \n'); % Configures the counter for a frequency measurement on the specified % channel invoke(InstrumentSpecificFrequency, 'frequencyconfigure', 1E6,1E-4,1); % Sets the number of triggers that will be accepted by the instrument % before returning to the "idle" trigger state set(InstrumentSpecificTrigger, 'Trigger_Count', 1); % Sets trigger source for measurements. % Immediate (continuous) source immediately issues the trigger set(InstrumentSpecificTrigger, 'Trigger_Source', AG532XX_VAL_TRIGGER_SOURCE_IMMEDIATE); % Sets the number of measurements samples the instrument will take per trigger set(InstrumentSpecificTrigger, 'Trigger_Sample_Count', 3); % Sets slope of the trigger signal on the rear-panel Trig In BNC set(InstrumentSpecificTrigger, 'Trigger_Slope', AG532XX_VAL_SLOPE_POSITIVE); % Enables all calculate commands InstrumentSpecificMath = get(myInstrument, 'Instrumentspecificmath'); set(InstrumentSpecificMath, 'Math_Enabled', true); % Enables statistics computation InstrumentSpecificMathStatistics = get(myInstrument,'Instrumentspecificmathstatistics'); set(InstrumentSpecificMathStatistics, 'Statistics_Enabled', true); % Initiates a measurement based on the current configuration. invoke(MeasurementLowLevelMeasurement, 'initiate'); % Does not return until previously started operations complete or more % MaxTimeMilliseconds milliseconds of time have expired. invoke(InstrumentSpecificSystem, 'systemwaitforoperationcomplete', 10000); % Gets the mathematical average (mean) of all measurements taken since % the last time statistics were cleared Average = get(InstrumentSpecificMathStatistics, 'Statistics_Average'); fprintf('Average : %0.15g \n', Average);
Averaging Average : 1000000
Measure Time Stamp
Time stamp measurements record frequency signal edges as they occur on the counter input channels
fprintf('\nTime Stamp Measurement \n'); % Set all measurement parameters and trigger parameters to default % values selectively for timestamp measurements, then immediately % trigger a measurement. InstrumentSpecificTimeStamp = get(myInstrument,'Instrumentspecifictimestamp'); % [VAL,VALACTUALSIZE] = INVOKE(OBJ,'timestampmeasure',COUNT,CHANNEL,VALBUFFERSIZE,VAL) [Val, ValActualSize] = invoke(InstrumentSpecificTimeStamp, 'timestampmeasure', 10,1,10,zeros(10)); fprintf('%d Data Points: \n',ValActualSize); for i= 1:ValActualSize fprintf('%0.15g\t\n', Val(i)); end
Time Stamp Measurement 10 Data Points: 0 1e-06 2e-06 3e-06 4e-06 5e-06 6e-06 7e-06 8e-06 9e-06
Measure Time Interval Between Two Channels
The measurement starts on a positive (rising) edge on channel 1, and stops on a positive edge on channel 2.
fprintf('\nTime Intervals Measurement with delay \n'); % Configures instrument for a time interval measurement on the specified % channels InstrumentSpecificTimeInterval = get(myInstrument,'Instrumentspecifictimeinterval'); invoke(InstrumentSpecificTimeInterval, 'timeintervalconfigure', 1,2); % Set the gate source for frequency measurement InstrumentSpecificArm = get(myInstrument,'Instrumentspecificarm'); invoke(InstrumentSpecificArm, 'armsetsource', AG532XX_VAL_ARM_MEASUREMENT_TYPE_FREQUENCY,AG532XX_VAL_ARM_SOURCE_ADVANCED); % Configures the Start Arm for armed measurements. Configuration = get(myInstrument,'Configuration'); invoke(Configuration, 'configurestartarm', AG532XX_VAL_IMMEDIATE_ARM_TYPE); % Set the source used to delay the arm start InstrumentSpecificArmStartExternal = get(myInstrument,'Instrumentspecificarmstartexternal'); set(InstrumentSpecificArmStartExternal,'Start_External_Delay_Source', AG532XX_VAL_DELAY_HOLD_OFF_SOURCE_TIME); % Set the delay, in seconds, used after an external armed measurement % has been armed. Arming = get(myInstrument,'Arming'); set(Arming, 'External_Start_Arm_Delay', 0.1); % Configure the Stop Arm for armed measurements. invoke(Configuration, 'configurestoparm', AG532XX_VAL_IMMEDIATE_ARM_TYPE); % Set the source used to hold off enabling the stop Arm source InstrumentSpecificArmStopExternal = get(myInstrument,'Instrumentspecificarmstopexternal'); set(InstrumentSpecificArmStopExternal, 'Stop_External_Hold_Off_Source', AG532XX_VAL_DELAY_HOLD_OFF_SOURCE_TIME); % Specify the delay, in seconds, after the External Arm Stop event % has occurred until the measurement stops. set(Arming, 'External_Stop_Arm_Delay', 0.25); % Sets the number of triggers that will be accepted by the instrument % before returning to the "idle" trigger state set(InstrumentSpecificTrigger, 'Trigger_Count', 1); % Sets the number of measurements samples the instrument will take per trigger set(InstrumentSpecificTrigger, 'Trigger_Sample_Count', 3); % Initiates a measurement based on the current configuration. invoke(MeasurementLowLevelMeasurement, 'initiate'); % Wait until initialization operation complete or 50000 milliseconds % of time have expired invoke(InstrumentSpecificSystem, 'systemwaitforoperationcomplete', 50000); % Retrieves the result from a previously initiated measurement. RetVal = invoke(MeasurementLowLevelMeasurement, 'fetch'); fprintf('Data: %0.15g\n', RetVal); fprintf('\n');
Time Intervals Measurement with delay Data: 0
Display Any Errors From The Driver
% If there are any errors, query the driver to retrieve and display them. ErrorNum = 1; while (ErrorNum ~= 0) [ErrorNum, ErrorMsg] = invoke(Utility, 'errorquery'); fprintf('ErrorQuery: %d, %s\n', ErrorNum, ErrorMsg); end
ErrorQuery: 0, No error.
Disconnect Device Object and Clean Up
disconnect(myInstrument);
% Remove instrument objects from memory.
delete(myInstrument);
Additional Information:
This example shows the setup and acquisition of frequency from a Counter using the IVI driver. Once the measured frequency is retrieved from the instrument, MATLAB can be used to visualize and perform analyses on the data using the rich library of functions in the Signal Processing Toolbox™ and Communications Systems Toolbox™. Using Instrument Control Toolbox™, it is possible to automate control of instruments, and, build test systems that use MATLAB to perform analyses that may not be possible using the built-in capability of the hardware.