RadiMation Application Note 138: Difference between revisions

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__NOTOC__
__NOTOC__
= How to perform magnetic field close proximity tests =
= How to perform a magnetic field close proximity test =
This {{RadiMation}} application note explains how the close proximity radiated immunity magnetic field tests can be performed with {{RadiMation}}. These tests are described in several standards, including the [[IEC 61000-4-39]]:2017 and the [[MIL-STD-461]] RS101.
This {{RadiMation}} application note explains how the close proximity radiated immunity magnetic field test can be performed with {{RadiMation}}. This test is described in several standards, including the [[IEC 61000-4-39]]:2017 (section 8.5.1) and the [[MIL-STD-461]] RS101.
 
A very similar test for the generation of magnetic field can also be done where the levelling is done on the forward power. Application Note 139: "[[RadiMation Application Note 139|How to perform a magnetic field close proximity test using forward power levelling]]" describes how that test can be performed.


== Magnetic field tests ==
== Magnetic field tests ==
For the generation of the magnetic field, loop antennas are used, with the exact specifications of wire thickness and number of windings, as specified in the used standard. Several [[:Category:Equipment_Manufacturer|manufacturers]] are providing loop antennas based on these specifications.
For the generation of the magnetic field, loop antennas are used, with the exact specifications of wire thickness and number of windings, as specified in the applicable standard. Several [[:Category:Equipment_Manufacturer|manufacturers]] are providing loop antennas based on these specifications.


The current flowing through the loop antenna is a one on one relation to the generated magnetic field. For the measurement of the current, different measurement methods are available that can be used in combination with {{RadiMation}}. It can be measured using a shunt resistor, or a current sensor. To characterise and validate the generated magnetic field, first a calibration is needed which is using another magnetic field monitoring loop connected to a frequency selective powermeter to verify the generated magnetic field. The result of that calibration can then also be used during the actual substitution test.
The current flowing through the loop antenna is a one on one relation to the generated magnetic field. For the measurement of the current, different measurement methods are available that can be used in combination with {{RadiMation}}. It can be measured using a shunt resistor, or a current sensor. To characterise and validate the generated magnetic field, first a calibration is needed to determine the required amount of current through the loop antenna. The actually generated magnetic field is measured using another magnetic field monitoring loop connected to a frequency selective powermeter. The result of that calibration can then also be used during the actual substitution test.


== Necessary equipment ==
== Necessary equipment ==
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* Signal generator
* Signal generator
* Amplifier
* Amplifier
* Transmitting loop antenna (according the specifications of the used standard)
* Transmitting loop antenna (according the specifications of the applicable standard)
* Cables
* Cables


Line 21: Line 23:


For the calibration of the magnetic field two additional test and measurement devices are also needed:
For the calibration of the magnetic field two additional test and measurement devices are also needed:
* Receiving loop antenna (according the specifications of the used standard)
* Receiving loop antenna (according the specifications of the applicable standard)
* Measurement receiver
* Measurement receiver


== Calibration ==
== Calibration ==
During the calibration the magnetic field transmitting loop and magnetic field monitoring loop are positioned close to each other, with a specified distance. The current through the magnetic field transmitting loop is then increased until the desired magnetic field level. The magnetic field monitoring loop connected to the spectrum analyser is used to measure the actually generated magnetic field.
During the calibration the magnetic field transmitting loop and magnetic field monitoring loop are positioned close to each other, with a specified distance. The current through the magnetic field transmitting loop is then increased until the desired magnetic field level has been reached. The magnetic field monitoring loop connected to the measurement receiver is used to measure the actually generated magnetic field.


[[File:MagneticFieldSystemCalibration.png]]
[[File:MagneticFieldSystemCalibration.png]]
The configuration of the testsite should then contain the following devices:
{|class="wikitable"
!# || Device name || Tab in testsite configuration window || note
|-
| || Signal Generator || Devices 1 ||
|-
| || Amplifier || Devices 1 ||
|-
| || Antenna || Devices 1 || For the magnetic field generation loop antenna
|-
| || Calibration Antenna || Devices 1 || For the magnetic field monitoring loop antenna. A {{ScreenElement|Magnetic field factor (dBpT/μV)}} correction file should be attached to the used antenna device. See [[Chapter_14#Antenna:_Magnetic_Field_Factor_.28dBpT.2FuV.29_correction| Magnetic Field Factor correction]] in [[Chapter 14]]
|-
| || Current sensor || Devices 2 || A transfer impedance correction file should be attached to the used current sensor device. See [[Chapter_14#Current_sensor:_impedance| Current sensor impedance correction]] in [[Chapter 14]]
|-
| || Sensor powermeter || Devices 2 ||
|-
| || Spectrum analyser || Devices 2 || For the measurement of the magnetic field monitoring antenna
|-
!colspan="4"|Cables
|-
|① || Cable SG -> amplifier || Cables || Optional to correct for the cable loss between the signal generator and the amplifier
|-
|② || Cable current -> power meter || Cables || Optional to correct for the cable loss between the current sensor and the sensor power meter
|-
|③ || Cable antenna -> preamp || Cables || Optional to correct for the cable loss between the calibration antenna and the spectrum analyser
|}


Instead of using a current sensor and powermeter, it is also possible to use a shunt resistor and a multimeter, or use the oscilloscope instead of the multimeter
Instead of using a current sensor and powermeter, it is also possible to use a shunt resistor and a multimeter, or use the oscilloscope instead of the multimeter


[[File:MagneticFieldShuntResistor.png]]
[[File:MagneticFieldShuntResistor.png]]
The configuration of the testsite should then contain the following devices:
{|class="wikitable"
! # || Device name || Tab in testsite configuration window || note
|-
| || Signal Generator || Devices 1 ||
|-
| ||  Amplifier || Devices 1 ||
|-
| || Antenna || Devices 1 || For the magnetic field generation loop antenna
|-
| || Calibration Antenna || Devices 1 || For the magnetic field monitoring loop antenna. A {{ScreenElement|Magnetic field factor (dBpT/μV)}} correction file should be attached to the used antenna device. See [[Chapter_14#Antenna:_Magnetic_Field_Factor_.28dBpT.2FuV.29_correction| Magnetic Field Factor correction]] in [[Chapter 14]]
|-
| || Resistor || Devices 1 || The actual resistor value should be specified in the advanced settings of the used resistor device.
|-
| || Multimeter || Devices 1 || Only needed if a multimeter is used for the measurement of the voltage over the resistor
|-
| || Oscilloscope || Devices 1 || Only needed if an oscilloscope is used for the measurement of the voltage over the resistor
|-
| || Spectrum analyser || Devices 2 || For the measurement of the magnetic field monitoring antenna
|-
!colspan="4"|Cables
|-
|① || Cable SG -> amplifier || Cables || Optional to correct for the cable loss between the signal generator and the amplifier
|-
|② || Cable current -> power meter || Cables || Optional to correct for the cable loss between the current sensor and the sensor power meter
|-
|③ || Cable antenna -> preamp || Cables || Optional to correct for the cable loss between the calibration antenna and the spectrum analyser
|}


The Magnetic field calibration can be started in {{RadiMation}} by selecting from the menu:
The Magnetic field calibration can be started in {{RadiMation}} by selecting from the menu:
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[[File:RadiatedImmunityMilStdCalibrationConfiguration.png]]
[[File:RadiatedImmunityMilStdCalibrationConfiguration.png]]


In the Mil Std Calibration dialog, the required settings can be configured. The used standard often specifies most of these settings.
In the Mil Std Calibration dialog, the required settings can be configured. The applicable standard often specifies most of these settings.
{{ScreenElementDescriptionStart}}
{{ScreenElementDescriptionStart}}
{{ScreenElementDescription|Start|The start frequency of the calibration. For example 9 kHz.}}
{{ScreenElementDescription|Start|The start frequency of the calibration. For example 9 kHz.}}
Line 46: Line 108:
{{ScreenElementDescription|Test level|The desired magnetic field testlevel that should be calibrated. For example 82 dBpT.}}
{{ScreenElementDescription|Test level|The desired magnetic field testlevel that should be calibrated. For example 82 dBpT.}}
{{ScreenElementDescription|Tolerance|The tolerance (specified in dB) that should be used for the accuracy of the regulated testlevel. For example: 0.2 dB.}}
{{ScreenElementDescription|Tolerance|The tolerance (specified in dB) that should be used for the accuracy of the regulated testlevel. For example: 0.2 dB.}}
{{ScreenElementDescription|Coupling device|Which device is used for the measurement of the current. This can be {{ScreenElement|Current Sensor}} or {{ScreenElement|Resistor}}.}}
{{ScreenElementDescription|Calibration method|The power level(s) (signal power, forward power or netto power) that should be measured and stored in the calibration file.}}
{{ScreenElementDescription|Measurement device|The device that is used for the measurement of the selected coupling device. This can be {{ScreenElement|Multimeter}}, {{ScreenElement|Powermeter}} or {{ScreenElement|Oscilloscope}}.}}
{{ScreenElementDescription|Measuring device|The device that is used for the measurement of the selected coupling device. This can be {{ScreenElement|Multimeter and Resistor}}, {{ScreenElement|Powermeter and Current sensor}} or {{ScreenElement|Oscilloscope and Resistor}}.}}
{{ScreenElementDescription|Test equipment|The name of the testsite that should be used. This testsite should at least have all the required equipment.}}
{{ScreenElementDescription|Test equipment|The name of the testsite that should be used. This testsite should at least have all the required equipment.}}
{{ScreenElementDescription|Test engineer|The name of the engineer who is performing the calibration.}}
{{ScreenElementDescription|Test engineer|The name of the engineer who is performing the calibration.}}
{{ScreenElementDescriptionEnd}}
{{ScreenElementDescriptionEnd}}


The {{ScreenElement|Coupling Device}} and the {{ScreenElement|Measuring Device}} allow to select the measurement equipment that are used to measure the current through the magnetic field generation loop.
Depending on the applicable standard, the test level is often specified in dBpT, dBμA/m or A/m. The {{ScreenElement|Units}} button can be used to change which unit should be used for the {{ScreenElement|Magnetic Field}} to specify the {{ScreenElement|Test level}}.
If the {{ScreenElement|Power Meter}} is selected for the {{ScreenElement|Measuring device}}, the actually used powermeter should be selected in the testsite as the {{ScreenElement|Sensor powermeter}}.
The magnetic field generation loop antenna should be selected in the testsite as the {{ScreenElement|Antenna}}.


The magnetic field monitoring antenna should be selected in the testsite as the {{ScreenElement|Calibration antenna}}. This antenna device driver should have a {{ScreenElement|Magnetic Field Factor (dBpT/uV)}} correction file selected as the third correction file in the device driver settings of the antenna device driver.  ( also see [[Chapter_14#Antenna:_Magnetic_Field_Factor_.28dBpT.2FuV.29_correction| Magnetic Field Factor correction]] in [[Chapter 14]] of the manual)
When this calibration is started, the signal generator will generate every frequency, and the current through the loop antenna is regulated to the desired magnetic field level as it is measured by the {{ScreenElement|Spectrum Analyser}} and the {{ScreenElement|Calibration antenna}}. Once the desired magnetic field is regulated, the current through the magnetic field generation loop is measured, which will also stored together with the power level in the calibration. At the end of the system calibration a 'Save Calibration As' dialog is shown, which allows to save the result of the calibration to a .CAL calibration file.
The measurement receiver connected to the field monitoring antenna should be selected in the testsite as the {{ScreenElement|Spectrum Analyzer}}.
 
When this calibration is started, the signal generator will generate every frequency, and the power level is regulated to the desired magnetic field level as it is measured by the {{ScreenElement|Spectrum Analyser}} and the {{ScreenElement|Calibration antenna}}. At the end of the system calibration a 'Save Calibration As' dialog is shown, which allows to save the result of the calibration to a .CAL calibration file.
It is advised to specify a useful location and filename for this magnetic field calibration file.
It is advised to specify a useful location and filename for this magnetic field calibration file.


Line 85: Line 142:
{{ScreenElementDescription|Test equipment|The name of the testsite that should be used. This testsite should at least have all the required equipment.}}
{{ScreenElementDescription|Test equipment|The name of the testsite that should be used. This testsite should at least have all the required equipment.}}
{{ScreenElementDescription|Location type|The type of test that should be used. For a magnetic field test use {{ScreenElement|Antenna height, distance, polarization and angle}}.}}
{{ScreenElementDescription|Location type|The type of test that should be used. For a magnetic field test use {{ScreenElement|Antenna height, distance, polarization and angle}}.}}
{{ScreenElementDescription|Antenna distance|The used distance between the antenna and the EUT. For example 10 cm.}}
{{ScreenElementDescription|Antenna distance|The used distance between the antenna and the EUT. For example 5 cm.}}
{{ScreenElementDescription|Antenna polarisation|The polarisation of the antenna related to the EUT. For a loop antenna, just specify {{ScreenElement|Horizontal}}.}}
{{ScreenElementDescription|Antenna polarisation|The polarisation of the antenna related to the EUT. For a loop antenna, just specify {{ScreenElement|Horizontal}}.}}
{{ScreenElementDescription|Antenna tower|The minimum, maximum and number of heights that should be moved with an automated antenna tower.}}
{{ScreenElementDescription|Antenna tower|The minimum, maximum and number of heights that should be moved with an automated antenna tower.}}
Line 105: Line 162:
{{ScreenElementDescription|Tolerance|The tolerance (specified in dB) that should be used for the accuracy of the regulated testlevel. For example: 0.3 dB.}}
{{ScreenElementDescription|Tolerance|The tolerance (specified in dB) that should be used for the accuracy of the regulated testlevel. For example: 0.3 dB.}}
{{ScreenElementDescriptionEnd}}
{{ScreenElementDescriptionEnd}}
Depending on the applicable standard, the test level is often specified in dBpT, dBμA/m or A/m. The {{ScreenElement|Units}} button can be used to change which unit should be used for the {{ScreenElement|Magnetic Field}} to specify the {{ScreenElement|Testlevel constant field}}.


The requested test level doesn't need to be the same as the calibrated magnetic field, as {{RadiMation}} will automatically calculate the corresponding current if another testlevel is specified.  
The requested test level doesn't need to be the same as the calibrated magnetic field, as {{RadiMation}} will automatically calculate the corresponding current if another testlevel is specified.  
Line 112: Line 171:




The magnetic field transmitting loop should be located close to the EUT itself. If the EUT is larger than the illumination area of the transmitting loop, the same magnetic field test has to be repeated for example for every 50cm x 50cm area of the EUT. Also all sides of the have to be tested. This can be easily done by repositioning the loop antenna, and starting the same test in {{RadiMation}} again.
The magnetic field transmitting loop should be located close to the EUT itself. If the EUT is larger than the illumination area of the transmitting loop, the same magnetic field test has to be repeated for example for every 50cm x 50cm area of the EUT. Also all sides of the EUT have to be tested. This can be easily done by repositioning the loop antenna, and starting the same test in {{RadiMation}} again.
 
<!--
=== Closed loop regulation ===
Optionally also a {{ScreenElement|Magnetic Flux Density}} correction file can be selected as the second correction file in the device driver settings of the magnetic field generating loop antenna. The correction file should include a frequency column and a correction column, where the values in the correction column are expressed in 'pT/A'. (also see: [[Chapter_14#Antenna:_Magnetic_Flux_Density_.28pT.2FA.29_correction|Magnetic Flux Density correction file]] in [[Chapter 14]] of the manual). In the [[MIL-STD-461]], this correction value is specified as 9.5x10^7 pT/A. This {{ScreenElement|Magnetic Flux Density}} value is used to determine the calculated magnetic field based on the measurement of the current flowing through the magnetic field generation loop antenna.
-->


== Conclusion ==
== Conclusion ==

Latest revision as of 12:25, 29 August 2024

How to perform a magnetic field close proximity test[edit]

This RadiMation® application note explains how the close proximity radiated immunity magnetic field test can be performed with RadiMation®. This test is described in several standards, including the IEC 61000-4-39:2017 (section 8.5.1) and the MIL-STD-461 RS101.

A very similar test for the generation of magnetic field can also be done where the levelling is done on the forward power. Application Note 139: "How to perform a magnetic field close proximity test using forward power levelling" describes how that test can be performed.

Magnetic field tests[edit]

For the generation of the magnetic field, loop antennas are used, with the exact specifications of wire thickness and number of windings, as specified in the applicable standard. Several manufacturers are providing loop antennas based on these specifications.

The current flowing through the loop antenna is a one on one relation to the generated magnetic field. For the measurement of the current, different measurement methods are available that can be used in combination with RadiMation®. It can be measured using a shunt resistor, or a current sensor. To characterise and validate the generated magnetic field, first a calibration is needed to determine the required amount of current through the loop antenna. The actually generated magnetic field is measured using another magnetic field monitoring loop connected to a frequency selective powermeter. The result of that calibration can then also be used during the actual substitution test.

Necessary equipment[edit]

The following test and measurement devices are needed:

  • Signal generator
  • Amplifier
  • Transmitting loop antenna (according the specifications of the applicable standard)
  • Cables

The current flowing through the loop antenna can be measured by one of the following methods, and depending on the used method, those additional test and measurement devices are also needed:

  • Current sensor and powermeter
  • Resistor and multimeter
  • Resistor and oscilloscope

For the calibration of the magnetic field two additional test and measurement devices are also needed:

  • Receiving loop antenna (according the specifications of the applicable standard)
  • Measurement receiver

Calibration[edit]

During the calibration the magnetic field transmitting loop and magnetic field monitoring loop are positioned close to each other, with a specified distance. The current through the magnetic field transmitting loop is then increased until the desired magnetic field level has been reached. The magnetic field monitoring loop connected to the measurement receiver is used to measure the actually generated magnetic field.

MagneticFieldSystemCalibration.png

The configuration of the testsite should then contain the following devices:

# Device name Tab in testsite configuration window note
Signal Generator Devices 1
Amplifier Devices 1
Antenna Devices 1 For the magnetic field generation loop antenna
Calibration Antenna Devices 1 For the magnetic field monitoring loop antenna. A Magnetic field factor (dBpT/μV) correction file should be attached to the used antenna device. See Magnetic Field Factor correction in Chapter 14
Current sensor Devices 2 A transfer impedance correction file should be attached to the used current sensor device. See Current sensor impedance correction in Chapter 14
Sensor powermeter Devices 2
Spectrum analyser Devices 2 For the measurement of the magnetic field monitoring antenna
Cables
Cable SG -> amplifier Cables Optional to correct for the cable loss between the signal generator and the amplifier
Cable current -> power meter Cables Optional to correct for the cable loss between the current sensor and the sensor power meter
Cable antenna -> preamp Cables Optional to correct for the cable loss between the calibration antenna and the spectrum analyser


Instead of using a current sensor and powermeter, it is also possible to use a shunt resistor and a multimeter, or use the oscilloscope instead of the multimeter

MagneticFieldShuntResistor.png

The configuration of the testsite should then contain the following devices:

# Device name Tab in testsite configuration window note
Signal Generator Devices 1
Amplifier Devices 1
Antenna Devices 1 For the magnetic field generation loop antenna
Calibration Antenna Devices 1 For the magnetic field monitoring loop antenna. A Magnetic field factor (dBpT/μV) correction file should be attached to the used antenna device. See Magnetic Field Factor correction in Chapter 14
Resistor Devices 1 The actual resistor value should be specified in the advanced settings of the used resistor device.
Multimeter Devices 1 Only needed if a multimeter is used for the measurement of the voltage over the resistor
Oscilloscope Devices 1 Only needed if an oscilloscope is used for the measurement of the voltage over the resistor
Spectrum analyser Devices 2 For the measurement of the magnetic field monitoring antenna
Cables
Cable SG -> amplifier Cables Optional to correct for the cable loss between the signal generator and the amplifier
Cable current -> power meter Cables Optional to correct for the cable loss between the current sensor and the sensor power meter
Cable antenna -> preamp Cables Optional to correct for the cable loss between the calibration antenna and the spectrum analyser


The Magnetic field calibration can be started in RadiMation® by selecting from the menu:

   Menu.svg Calibration
      Menu.svg System Calibration
         Menu.svg Radiated Immunity
            Menu.svg Mil Std Calibration

RadiatedImmunityMilStdCalibrationConfiguration.png

In the Mil Std Calibration dialog, the required settings can be configured. The applicable standard often specifies most of these settings.

ScreenElementDescription.svg Start The start frequency of the calibration. For example 9 kHz.
ScreenElementDescription.svg End The end frequency of the calibration. For example 150 kHz.
ScreenElementDescription.svg Step Fixed The frequency step that should be used to increment the frequency. For example 10 kHz.
ScreenElementDescription.svg Step Logarithmic The percentage of the frequency that should used to increment the frequency. For example 1 %.
ScreenElementDescription.svg Test level The desired magnetic field testlevel that should be calibrated. For example 82 dBpT.
ScreenElementDescription.svg Tolerance The tolerance (specified in dB) that should be used for the accuracy of the regulated testlevel. For example: 0.2 dB.
ScreenElementDescription.svg Calibration method The power level(s) (signal power, forward power or netto power) that should be measured and stored in the calibration file.
ScreenElementDescription.svg Measuring device The device that is used for the measurement of the selected coupling device. This can be Multimeter and Resistor, Powermeter and Current sensor or Oscilloscope and Resistor.
ScreenElementDescription.svg Test equipment The name of the testsite that should be used. This testsite should at least have all the required equipment.
ScreenElementDescription.svg Test engineer The name of the engineer who is performing the calibration.


Depending on the applicable standard, the test level is often specified in dBpT, dBμA/m or A/m. The Units button can be used to change which unit should be used for the Magnetic Field to specify the Test level.

When this calibration is started, the signal generator will generate every frequency, and the current through the loop antenna is regulated to the desired magnetic field level as it is measured by the Spectrum Analyser and the Calibration antenna. Once the desired magnetic field is regulated, the current through the magnetic field generation loop is measured, which will also stored together with the power level in the calibration. At the end of the system calibration a 'Save Calibration As' dialog is shown, which allows to save the result of the calibration to a .CAL calibration file. It is advised to specify a useful location and filename for this magnetic field calibration file.

EUT measurement[edit]

Once the system calibration has been performed, the EUT can be installed and prepared. Also open an EUT file in RadiMation® to store the measurement results of the tests. The equipment configuration that is needed for the actual test is very similar to the calibration setup.

MagneticFieldTestConnections.png

To perform the real magnetic field close proximity test, the earlier created calibration file can be used to generate the requested magnetic field. Just use a Radiated Immunity Multiband test by selecting from the menu:

   Menu.svg Tests
      Menu.svg Radiated Immunity
         Menu.svg Multiband

All the desired test parameters can be set in this configuration window:

RadiatedImmunityMultibandMagneticSubstitutionConfiguration.png


ScreenElementDescription.svg Start The start frequency of the test. For example 9 kHz.
ScreenElementDescription.svg Stop The stop frequency of the test. For example 150 kHz.
ScreenElementDescription.svg Frequency step The frequency step that should be used to increment the frequency. For example 10 kHz.
ScreenElementDescription.svg Dwell time The dwell time that should be used at every frequency. For example 2 seconds.
ScreenElementDescription.svg Frequency change mode The mode that should be used to change from one frequency to the next frequency.
ScreenElementDescription.svg Modulation The modulation that should be applied during the dwell time at each frequency.
ScreenElementDescription.svg Test equipment The name of the testsite that should be used. This testsite should at least have all the required equipment.
ScreenElementDescription.svg Location type The type of test that should be used. For a magnetic field test use Antenna height, distance, polarization and angle.
ScreenElementDescription.svg Antenna distance The used distance between the antenna and the EUT. For example 5 cm.
ScreenElementDescription.svg Antenna polarisation The polarisation of the antenna related to the EUT. For a loop antenna, just specify Horizontal.
ScreenElementDescription.svg Antenna tower The minimum, maximum and number of heights that should be moved with an automated antenna tower.
ScreenElementDescription.svg Turn table The start and end angle and how many angles should be measured with an automated turntable.
ScreenElementDescription.svg Test level The configuration of the testlevels and limits that should be used during the regulation of the test.
ScreenElementDescription.svg Inputs The configuration of additional inputs that should be measured during the test.


In the test configuration a Magnetic Field substitution method testlevel can be added. In the Magnetic Field substitution method testlevel configuration the .CAL file can be selected again, and the requested testlevel can be specified. In this configuration dialog, also the levelling method can be selected, which also has the option to regulate on the current flowing through the magnetic field generation loop.

MagneticFieldSubstitutionTestlevelConfiguration.png


ScreenElementDescription.svg Description Specifies the name that should be used for this testlevel.
ScreenElementDescription.svg Calibration file The calibration file which is the result of the system calibration, and which is now used to regulate to the desired testlevel.
ScreenElementDescription.svg Testlevel constant field The desired testlevel for the magnetic field.
ScreenElementDescription.svg Testlevel variable field A correction file that should be used to for a frequency depending testlevel, which allows to do variation of the magnetic field strength over the frequency.
ScreenElementDescription.svg Levelling method Which device combination should be used to regulate the power and/or current, and thus also the magnetic field.
ScreenElementDescription.svg Tolerance The tolerance (specified in dB) that should be used for the accuracy of the regulated testlevel. For example: 0.3 dB.


Depending on the applicable standard, the test level is often specified in dBpT, dBμA/m or A/m. The Units button can be used to change which unit should be used for the Magnetic Field to specify the Testlevel constant field.

The requested test level doesn't need to be the same as the calibrated magnetic field, as RadiMation® will automatically calculate the corresponding current if another testlevel is specified.

When this test is started, the signal generator will be set to every frequency again, and the current flowing through the transmitting loop antenna will be regulated to the current that is determined during the calibration, which correlates to the requested magnetic field. Once the EUT test is finished, the results of this test is stored in the EUT file, and available as one of the performed Tests in the EUT file. Selecting the corresponding test result and pressing on Info will show the test results again.


The magnetic field transmitting loop should be located close to the EUT itself. If the EUT is larger than the illumination area of the transmitting loop, the same magnetic field test has to be repeated for example for every 50cm x 50cm area of the EUT. Also all sides of the EUT have to be tested. This can be easily done by repositioning the loop antenna, and starting the same test in RadiMation® again.

Conclusion[edit]

The RadiMation® Radiated Immunity Mil Std calibration can be used to characterise the generated magnetic field by measuring the current through the transmitting loop, and storing it in a calibration file. The Multiband Radiated Immunity test can then use the calibration file to re-apply the required current (and thus the desired magnetic field) again. This test can then be used to test if the EUT is not influenced by the generated magnetic field.