Chapter 8: Difference between revisions

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In this window the operator can select which lines have to be measured. The operator can either select to measure just one LINE at a time (and have the possiblity to put them in a sequence) or select two or more lines in the same test.
In this window the operator can select which lines have to be measured. The operator can either select to measure just one LINE at a time (and have the possiblity to put them in a sequence) or select two or more lines in the same test.


When two or more LINES are selected in the same test, all data will be displayed in one graph thus loosing information. However the peak list table will show on which LINE a peak was measured.
When two or more LINES are selected in the same test, all data will be displayed in one graph thus loosing information. However the peak list table will show on which LINE a peak was measured.


If the emission graphs of  all separate LINES are required, separate tests must be configured for each LINE. These tests can be put in a sequence, eliminating the need for a user intervention.
If the emission graphs of  all separate LINES are required, separate tests must be configured for each LINE. These tests can be put in a sequence, eliminating the need for a user intervention.

Revision as of 09:18, 30 August 2008

Conducted Emission[edit]

Introduction[edit]

The conducted emission measurements can be performed with a Line Impedance Stabilisation Network (L.I.S.N.) on power supply cables, or with an absorbing clamp, on power supply cables and/or I/O cables). Automotive standards use a Line Impedance Stabilisation Network to measure the conducted emission on 12V and 24V board voltages.

RadiMation® supports the use of 1, 2, 3 and 4 phase, Line Impedance Stabilisation networks. Generally 1 phase LISN’s are used for measurements on DC lines, as is the case during automotive measurements. 2 phase LISN’s are normally used to measure conducted emission on single-phase mains supplies (in this case the emission on Phase and Neutral are measured separately). 3 and 4 phase LISN’s are used to measured conducted emissions on 3 phase mains supplies (in this case the emission on L1, L2, L3 and, if applicable, N are measured).

Conducted emission tests can either be performed with a measurement receiver, or a spectrum analyser. For full compliant conduced emission tests, the measurement receiver, or spectrum analyser must be CISPR 16-1 compliant. This standard describes the dynamic range, input, sensitivity, needed filters and accuracy of the measuring device.

Warning-48px.png
Warning: Extreme care should be taken when the LISN measuring output is switched from one phase to the other. The measurement output of the LISN is capacitive coupled to the mains line and therefore switching between Phase and Neutral will cause a voltage transient of 310 V at the input of the receiver. When no extra protection is used, this transient can easily destroy the mixer diode(s) of the measuring device.

We recommend to use a transient limiter or to disconnect the receiving device when the LISN is switched on or off. The used LISN, spectrum analyser and/or measurement receiver can be selected under the configuration, tests site pull down menu. The measuring device can be configured for the desired test through the Attenuator, RBW, VBW and sweep time settings.

Measurements can be performed in peak, average and quasi peak mode. For Peak mode tests, the number of sweeps to be made, can be selected. For Quasi Peak and Average measurements, the number of points can be entered on which the QP and average measurements are made. The QP and average measurements are made on the highest emission points as measured during the peak sweeps. RadiMation® automatically selects the highest peaks from the peak measurement file and performs the QP measurements on these peaks.


When the measurements must be repeated on more than one phase, simply select all phases to measure. The configured test can be saved as a T.S.F. file for use at a later time. When conducted emission tests must be performed in different frequency bands, several T.S.F. files can be placed in a sequence file. The next chapters explain in depth how a test should be configured.

LISN measurements[edit]

The test engineer can configure a complete conducted emission test in the Conducted Emission configuration menu. To enter this menu, please select Tests > Conducted emission > LISN.


The next paragraphs describe all configuration field of this window.

Frequency window[edit]

In the frequency window, the operator can enter a frequency range to be measured or select a frequency list.


When the Frequency range is selected, the following items can be entered:

Start : Sets start frequency Stop : Sets stop frequency

When the frequency list is selected the operator can select a frequency list file by browsing to the file location. With the start-stop frequency the software searches for the peaks, while with a frequency list the frequencies on the list are measured.

LISN line window[edit]

In this window the operator can select which lines have to be measured. The operator can either select to measure just one LINE at a time (and have the possiblity to put them in a sequence) or select two or more lines in the same test.

When two or more LINES are selected in the same test, all data will be displayed in one graph thus loosing information. However the peak list table will show on which LINE a peak was measured.

If the emission graphs of all separate LINES are required, separate tests must be configured for each LINE. These tests can be put in a sequence, eliminating the need for a user intervention.

Receiver settings[edit]

Reference level : Sets the reference level of the receiver Attenuator : Sets the receiver attenuator level RBW : Sets the Resolution BandWidth filter VBW : Sets the Video BandWidth filter Sweep : Sets the sweep time of the receiver Pre-amp : Sets the pre-amp gain Step frequency : Sets the frequency step size of the receiver Measure time : Sets the measure time of the receiver


When a parameter is set to auto, RadiMation will determine the most optimum settings for this parameter. If the parameter is set to coupled, the parameter will be set to automatic internally in the receiver.


Max. hold measurements[edit]

In this window the number op peak hold sweeps for each measurement can be selected. If this value is set to, for example 10, the software will measure the frequency band 10 times for each turntable and antenna tower position. This value will normally be set to 1 for measurement receivers while a higher value is used for spectrum analysers. The amount of required peak sweeps is depending on the type of signal and the setting of the sweepspeed. For spectrum analysers and CW signals you can use a relatively low amount of peaksweeps, for example 10. But when you have discontinues signals like a spark bridge, you may need 100 peaksweeps or more. A good indication if you are using enough peak sweeps is to look at the envelope of the frequency spectrum. When it has gaps or jumps then you are not using enough sweeps to determine a correct signal envelope.

Traces window[edit]

In the traces window, the test engineer can select a maximum of four traces which can be measured and displayed at the same time.

Detectors window[edit]

In the detectors window the test engineer can configure the detectors used during the emission measurements. The first value is the time constant of the detector while the second value is used for the measure time at each frequency point for this detector.

Peak detection window[edit]

All peaks above “xx” below the limit lines

In the peak detection window, the test engineer can configure which signal peaks must be detected. If the operator selects a value of 6 dB, the software will detect all peaks, which are higher than 6 dB below the limit line.

Max. Peaks

Under max. peaks, the user can limit the number of peak signals the software will detect and re-measure.

Test site window[edit]

Test equipment

In the test site window the test engineer can select which equipment list will be used during this test.


Test engineer[edit]

In the test engineer window, the test engineer can select its own name. The test engineer name will be stored by the test results.

Equipment icon

By clicking on the equipment icon, the equipment list can be viewed and edited.

Limit lines window[edit]

In the limit line window the operator select one or more limit lines to be used during the test.

Test options window[edit]

In the test options window the operator can select whether all RAW data must be stored or only the measurement results are stored. It should be noted that for full tracebility, all test data should be stored. 8.2.11 Test site information


Device name Tab in Radimation configuration window Spectrum analyser Standard 2 Pre amplifier Standard 2 Lisn Standard 2

Cables

  1. Device name Tab in Radimation configuration window

1 Pre amp->Spectrum Cables 2 Ant->Pre amp Cables

Note: Usage of cable correction factors is not mendatory. However, using correction factors will increase measurement accuraccy during emission measurements. When in doubt contact your reseller.

Absorbing clamp measurements[edit]

Absorbing clamp measurements can be performed full automatically when a clamp positioner is used. The test engineer can configure a complete absorbing clamp test in the Conducted Emission-Absorbing clamp configuration menu. To enter this menu, please select Tests > Conducted emission > Absorbing clamp.



Frequency window[edit]

In the frequency window, the operator can enter a frequency range to be measured or select a frequency list.

When the Frequency range is selected, the following items can be entered:

Start : Sets start frequency Stop : Sets stop frequency

When the frequency list is selected the operator can select a frequency list file by browsing to the file location.

Clamp movement window[edit]

In this window the operator can select the start and stop position of the clamp and the number of steps for the clamp.

Max. distance : Sets the maximum clamp position Min distance : Sets the minimum clamp position

  1. : Number op steps between max. distance and min. distance

Peak search : The software will automatically detect on which angle maximum emission will occur.


When peak search is selected, the user can configure the way a peak search is performed. In the peak search configuration window, the following configurations can be made:

Area : Range over which the peak search will be performed (for example 0 to 5 meter). Step size : The step size for each clamp movement. Threshold : This value determines the acceptance criteria for a peak. Mode : The mode setting determines the way a peak is detected. The following modes are available: - Intelligent - Complete area


Receiver settings[edit]

Reference level : Sets the reference level of the receiver Attenuator : Sets the receiver attenuator level RBW : Sets the Resolution BandWidth filter VBW : Sets the Video BandWidth filter Sweep : Sets the sweep time of the receiver Pre-amp : Sets the pre-amp gain Step frequency : Sets the frequency step size of the receiver Measure time : Sets the measure time of the receiver


When a parameter is set to auto, RadiMation will determine the most optimum settings for this parameter. If the parameter is set to coupled, the parameter will be set to automatic internally in the receiver.

Max. hold measurements[edit]

In this window the number op peak hold sweeps for each measurement can be selected. If this value is set to, for example 10, the software will measure the frequency band 10 times for each turntable and antenna tower position. This value will normally be set to 1 for measurement receivers while a higher value is used for spectrum analysers. The amount of required peak sweeps is depending on the type of signal and the setting of the sweepspeed. For spectrum analysers and CW signals you can use a relatively low amount of peaksweeps, for example 10. But when you have discontinues signals like a spark bridge, you may need 100 peaksweeps or more. A good indication if you are using enough peak sweeps is to look at the envelope of the frequency spectrum. When it has gaps or jumps then you are not using enough sweeps to determine a correct signal envelope.

Traces window[edit]

In the traces window, the test engineer can select a maximum of four traces which can be measured and displayed at the same time.

Detectors window[edit]

In the detectors window the test engineer can configure the detectors used during the emission measurements. The first value is the time constant of the detector while the second value is used for the measure time at each frequency point for this detector.


Peak detection window[edit]

All peaks above “xx” below the limit lines

In the peak detection window, the test engineer can configure which signal peaks must be detected. If the operator selects a value of 6 dB, the software will detect all peaks, which are higher than 6 dB below the limit line.

Max. Peaks[edit]

Under max. peaks, the user can limit the number of peak signals the software will detect and re-measure.

Test site window[edit]

Test equipment

In the test site window the test engineer can select which equipment list will be used during this test.

Test engineer

In the test engineer window, the test engineer can select its own name. The test engineer name will be stored by the test results.

Equipment icon

By clicking on the equipment icon, the equipment list can be viewed and edited.

Limit lines window[edit]

In the limit line window the operator select one or more limit lines to be used during the test.

Test options window[edit]

In the test options window the operator can select whether all RAW data must be stored or only the measurement results are stored. It should be noted that for full tracebility, all test data should be stored.

Test site information[edit]

Device name Tab in Radimation configuration window Spectrum analyser Standard 2 Pre amplifier Standard 2 Current sensor Standard 2

Cables

  1. Device name Tab in Radimation configuration window

1 Pre amp->Spectrum Cables 2 Ant->Pre amp Cables

Note: Usage of cable correction factors is not mendatory. However, using correction factors will increase measurement accuraccy during emission measurements. When in doubt contact your reseller.

Starting a test[edit]

Loading a TSF file[edit]

To start a conducted emission test, an EUT file must be defined first. From the EUT file, select “Tests > Conducted emission > CISPR LISN. A list of Technical Setup Files (TSF files) will be displayed. The test engineer can select one of these TSF files to load all parameters from a previously defined emission test or press cancel to define a new emission test.

The figure below shows the TSF window.


After the TSF file has been selected, the emission configuration window will appear.

When a TSF file is loaded, all test parameters will be already configured and pressing the start button on the right side of the screen can start the test.

When no TSF file is loaded (by pressing Cancel in the TSF selection window) all parameters will be at zero and can be configured by the operator.

Test initialisation and self test[edit]

When the start button is pressed, the software first runs a number of checks.

  1. The presence of a valid software key is checked.
  2. The software settings are checked (i.e. is all test equipment used within its parameters?)
  3. The presence of all test equipment is checked.
  4. All relevant equipment will be initialized.


When one or more of the above tests fail, an error message is displayed.


Manual mode[edit]

For product improvements, it quit often is required to operate the test setup in manual mode. This can be done either by operating the measurement receiver (or spectrum analyser) manually or by the RadiMation® software. In our opinion it is no use to take over the buttons of the receiver without adding any extra functionality. For this reason a number of handsome futures are included in manual mode.

Receiver settings[edit]

The receiver settings menu allows the operator to configure the measurement receiver. The following parameters can be configured:

Start : Sets start frequency Stop : Sets stop frequency Reference : Sets the reference level of the receiver Attfsenuator : Sets the receiver attenuator level RBW : Sets the Resoution Band Width filter VBW : Sets the Video Band Width filter Sweep : Sets the sweep time of the receiver Pre-amp : Sets the pre-amp gain

When a parameter is set to auto, RadiMation will determine the most optimem settings for this parameter. If the parameter is set to coupled, the parameter will be set to automatic internally in the receiver.

The left column in the receiver settings menu shows the parameters as configured by the test engineer while the right column shows the actual receiver configuration.



The figure below shows the receiver settings menu.


Data correction[edit]

The manual mode of RadiMation® uses the PC screen to display the emission data real time on the computer screen. However the measured data is corrected for antenna factors and cable losses.

Peak menu[edit]

Search peak

RadiMation can detect peaks automatically. From the “peaks” TAB, choose “Search peak” to detect the maximum signal. The software will measure the detected peak.

Add peak

The measured values can be added to the peak list by pressing the “Add Peak” button.

Search angle


By pressing the “Search Angle” button, the software starts a turntable scan to determine at which turn table angle maximum emission takes place. Search Height

By pressing the “Search Height” button, the software starts an antenna height scan to determine at which antenna height maximum emission takes place.

The picture below shows the “manual mode” peak list option.


Traces menu[edit]

Traces

In the “traces” menu, a maximum off four traces can be switched on. Each trace can be appointed to be a Max hold trace, Average trace, Write trace or be switched either to View mode or just left Blank.

The figure below shows the traces menu:




Detectors

In the traces menu, The following detectors can be switched on and off:

- Peak detector - Average detector - Quasi peak detector - RMS detector

LISN line selection

In this window the operator can select which line will be monitored. In manual mode only one line at a time can be selected.

Zoom function

When the operator wants to “zoom in” on a certain signal just use the mouse to drag a box around the signal of interest. The RadiMation® software will fully automatic zoom in to this signal. The screen, as well as the measurement receiver will be zoomed. This reduces the number of actions for the operator significantly.

The figure below shows how to drag a box to zoom into a graph, while the second graph shows the zoomed graph.

The following options are possible for the automatic zooming function:

X-axis, When this option is switched on, the frequency settings of the receiver and the graph will be automatically adjusted when the user zooms in to the graph.

Y-axis, When this option is switched on, the amplitude settings of the receiver and the graph will be automatically adjusted when the user zooms in to the graph.

Under the “traces” TAB, the user can select two different ways of zooming:

X-axis, When this option is switched on, the frequency settings of the receiver and the graph will be automatically adjusted when the user zooms in to the graph.

Y-axis, When this option is switched on, the amplitude settings of the receiver and the graph will be automatically adjusted when the user zooms in to the graph.


Limit lines[edit]

Under the TAB “limit lines”, limit lines can be added to and removed from graphs. The limit lines must be previously defined (See also creating new limit line files).


Short cut keys[edit]

The following short cut keys can be used during manual mode. Key Function F3 Turn engine of the clampmover left, full speed. F4 Turn engine of the clampmover left, quarter speed. F5 Turn engine of the clampmover right, quarter speed. F6 Turn engine of the clampmover right, full speed. F7 Frequency offset down. F8 Frequency offset up. F9 Center frequency down. F10 Center frequency up.

Export menu[edit]

Data from the graphs and peak list can be exported to the clip board by pressing the corresponding icons in the export menu. From the clip board, the graph (or table) can be pasted in to any windows application.




Merge function[edit]

The merge function is used to merge separate emission graphs to one graph.

The figure below shows the merge window. All emission tests, carried out on the Equipment Under Test, will be shown in this menu. The operator can select which emission measurements have to be merged together.

The results of the merge action will be stored in the EUT window, together with all other test results.




X+k*S berekeningen[edit]

The X+k*S function is a statistic calculation method used when a number of the same measurements are made to the same type of EUT.

The figure below shows the X+k*S function window. All emission tests, carried out on the Equipment Under Test, will be shown in this menu. The operator can select on which emission measurements the calculations have to be performed.

The results of the X+k*S function will be stored in the EUT window, together with all other test results.

Measurement of peak amplitude and peak frequency[edit]

When using a spectrum analyser for emission measurements, Radimation first performs a full span max. hold measurement with a peak detector. The number of max. hold peak sweeps can be defined by the user. From the obtained max hold graph, Radimation determines a number of peaks, which will be further investigated. The number of peak signals to be measured can be defined by the user. For each peak from the graph, Radimation will zoom in, by reducing the span in several steps. This must be done while span inaccuracy of the analyser in large frequency spans will give slightly incorrect frequency information. After the exact peak frequency is determined, Radimation will perform Peak,Quasi peak, Average and / or RMS measurements. Due to the above, the finally measured frequency and amplitude of a peak can slightly differ from the max hold graph. This is not an error, but merely an indication that the final measurements are more accurate. The peak table always shows the final measured values (most accurate).