System Verification


The performance of the network analyzer is specified in two ways: system specifications, and instrument specifications. It is the end user’s responsibility to determine which set of specifications is applicable to their use of the analyzer.

A network analyzer measurement “system” includes the analyzer, calibration kit, test cables, and any necessary adapters. The system verification software in the analyzer is used to verify the system’s conformance to the “system” specifications. A “pass” result demonstrates that the analyzer, test cables, and adapters, perform correctly as a system. It DOES NOT demonstrate that any one component performs according to its individual specifications. A change to any part of this measurement system requires a re-verification of the system.

Instrument specifications specify the network analyzer’s uncorrected measurement port characteristics and its output and input behavior. The analyzer performance tests are used to verify the analyzer’s conformance to “instrument” specifications.

The system verification utility verifies the analyzer system specifications by automatically measuring the magnitude and phase for all four S-parameters for each verification device, and comparing the values against the following:

System Verification requires the use of a calibration kit and verification kit which has been certified within the past 12 months by Keysight. System Verification can NOT be used to perform this kit certification.

Operator's Check should also be performed to verify the basic operation of the analyzer.

Notes

  • Although the performance for all S-parameters is measured, the S-parameter phase uncertainties are less important for verifying system performance. Therefore, the limit lines will not appear on the printouts.

  • System Verification can NOT be run with a Multiport test set enabled. However, you can run a performance check as described in the Test Set User's Guide. See the N44xx User's Guide.

Equipment Used in the System Verification

VNA Models with 3.5 mm test ports

Equipment Type

3.5 mm

Type-N

Calibration kit
or

ECAL Module

85052B/C/D

N4691A

85054B/D

N4690A

Verification kit

85053B

85055A

RF Cable(s)

Single: 85131C/E
Pair: 85131D/F

Single: 85132C/E
Pair: 85132D/F

Adapters

None

Single: 85130C and one 7mm-to-Type-N from 85054B cal kit
Pair:
Two 7mm-to-Type-N from 85054B cal kit

VNA Models with 2.4 mm test ports

Equipment Type

2.4 mm

3.5 mm

Type-N

Calibration kit
or

ECAL Module

85056A/D

N4693A

85052B/C/D

N4691A

85054B/D

N4690A

Verification kit

85057B

85053B

85055A

RF Cable(s)

Single: 85133C/E
Pair: 85133D/F

Single: 85134C/E
Pair: 85134D/F

Single: 85135C/E
Pair: 85135D/F

Adapters

None

Single: 85130F
Pair:
None

Single: 85130E and two 7mm-to-Type-N from 85054B cal kit
Pair:
Two 7mm-to-Type-N from 85054B cal kit

VNA Models with 1.85 mm test ports

Equipment Type

1.85 mm

2.4 mm
3.5 mm
Type-N

Calibration kit
or

ECAL Module

85058B

N4694A

See 2.4 mm test port table above

Verification kit

85058V

See 2.4 mm test port table above

RF Cable(s)

Single: N4697E
Pair: N4697F

See 2.4 mm test port table above

Adapters

None

See 2.4 mm test port table above

Cable Substitution

The test port cables specified for the analyzer have been characterized for connector repeatability, magnitude and phase stability with flexing, return loss, insertion loss, and aging rate. Since test port cable performance is a significant contributor to the system performance, cables of lower performance will increase the uncertainty of your measurement. It is highly recommended that the test port cables be regularly tested.

If the system verification is performed with a non-Keysight cable, ensure that the cable meets or exceeds the operation of the specified cable. Refer to the cable User's Guide for specifications.

Cable Flex Factor

Flex Factor determines how much of the cable phase uncertainty to include in determining the limit lines.  

Calibration Kit Substitution

Non-Keysight calibration kits are not recommended nor supported.

Precautions for Handling Airlines

When you are using the airlines in the verification kit, observe the following practices to ensure good measurement techniques.

Flow Diagram of Procedure

The operational flow of the software is depicted by the flowchart shown below.

Procedure for System Verification

  1. If you want printed test outputs, connect a printer to the analyzer. Let the analyzer warm up for at least 30 minutes.

  2. Insert the verification kit floppy disk into the analyzer disk drive.

  3. On the System (or Utility) menu, point to Service, and click System Verification. The System Verification window similar to this will be displayed.

System Verification Dialog

  1. In the Calibration Kit box, select the calibration kit or ECal module that is being used. The corresponding verification kit to use appears in the Verification Kit box.

  2. Under Printer Output click on any of the following options.

Note: If you want printed output, it is assumed you have already installed the Windows driver for your particular printer, and have tested that you can print to the printer from the network analyzer. This software is designed to print to whichever printer is currently set as the Default printer (see Printers in the Windows Control Panel).

  1. To modify the number of ports to be verified, to change the number of devices to measure, or to use a previously stored verification calibration, click on the Configure tab and make the desired selections.

  2. Click Run.

  3. Follow the instructions on the analyzer for performing the system verification, inserting the verification devices as prompted.

Note for 3 Port analyzer:
The System Verification Procedure is repeated three times. The first time, Ports 1 and 2 are measured as a pair; then Ports 1 and 3 are measured; and lastly, Ports 2 and 3 are measured.

Note for 4 Port analyzer:
The System Verification Procedure is repeated two times. The first time, Ports 1 and 2 are measured as a pair, then Ports 3 and 4 are measured.

Step-by-Step Process Description

  1. Depending upon the selected choice in the Calibration submenu of the Configure menu, the user is either prompted to recall a previous calibrated instrument state, or is guided through a full 2-port calibration using the selected calibration kit. For ECal, the ECal module is connected just once; a standby message is posted while the software is performing the calibration.

  2. The user is prompted to connect the first verification device.

  3. The software reads the factory measured data for that device and uncertainty values for that data (CITIfiles) from the floppy disk supplied with the verification kit.

  4. The software sends the factory measured data, calibration kit and instrument state information to the uncertainty calculator DLL, which generates uncertainty values specific to the analyzer.

  5. The analyzer first sets up for magnitude measurements of all four S-parameters, each parameter in a separate window (lin mag for S11 and S22, log mag for S21 and S12). Each of the factory measured S-parameters are fed to the appropriate window as a memory trace. Limit line offsets are calculated as the sum of the factory measured data uncertainties and analyzer uncertainties reported by the DLL. Upper and lower limits are displayed (factory measured data + uncertainty sum, factory measured data - uncertainty sum). The analyzer takes a sweep, limit test is turned on and PASS/FAIL status is reported in each of the four windows.

  6. The user clicks a button when ready to view phase measurements. The four windows get updated for phase format, phase memory traces, phase limits and PASS/FAIL result.

  7. If the limit test of any of the four S-parameters (magnitude or phase) indicates a FAIL status, the software suggests troubleshooting tips and asks if the user would like to repeat measurement of that device or proceed to the next device. If proceeding to the next device, the factory measured data and uncertainties for the next device are read from floppy, the uncertainty DLL gets called with this next set of factory measured data, and the four measurement windows get updated for magnitude measurement of the next device.

  8. The software follows this same process until all selected devices have been measured, at which point a summary window is displayed containing the set of PASS/FAIL results for all four parameters of each device.

If the System Fails the Verification Test

IMPORTANT: Inspect all connections. Do not remove the cable from the analyzer test port. This will invalidate the calibration that you have done earlier.

  1. Repeat this verification test. Make good connections with correct torque specifications for each verification device.

  2. Disconnect, clean and reconnect the device that failed the verification test. Then measure the device again.

  3. If the analyzer still fails the test, check the measurement calibration by viewing the error terms as described in "Front Panel Access to Error Terms" on page 4-7 of the Service Guide.

  4. Refer to the graphic below, for additional troubleshooting steps.

Verification Fails Flowchart

Interpreting the Verification Results

The graphic below shows an example of typical verification results with Tabular Data selected in the Printer Output area of the System Verification window. A graphic later in this topic shows an example of typical verification results with Measurement Plots selected in the Printer Output area of the System Verification windows. These printouts include a comparison of the data from your measurement results with the traceable data and corresponding uncertainty specifications. Use these printouts to determine whether your measured data falls within the total uncertainty limits at all frequencies.

The tabular data consists of:

Printout of Tabular Verification Results

 

The printed graphical results show:

Printout of Graphical Verification Results