16.11.2021 | Latest

Neuer EMV-Testplatz bei Ginzinger

Neuer EMV Testplatz bei Ginzinger

kürzeres Time-to-Market für Kundenprodukte

This year, the development department at Ginzinger electronic systems acquired new and extensive equipment for measuring the electromagnetic compatibility (EMC) of assemblies and electronic devices.

It is done: The development is finished, the product is as good as ready and ripe for the market. Although the project has already been delayed due to some necessary changes, it is now entering the final spurt. The only thing left to do is to go to the EMC measurement lab for the outstanding approvals. Since they are always very busy, a missed deadline for EMC testing and approval would become a bottleneck in the development project that would ultimately make developers and project managers sweat.

What is EMC?

Electromagnetic compatibility (EMC) refers to the ability of a technical device not to interfere with other devices through unwanted electrical or electromagnetic effects. This also applies in the opposite sense: that new products are not disturbed by other technical devices.  

This unwanted, mutual interference has not only a technical but also a legal aspect. Every electronic device must be able to withstand defined interference, but at the same time must not exceed defined limits, otherwise other devices will be disturbed.

Dangerous situations can also arise: Devices could malfunction due to interference and endanger people and goods.

Conducted and field-bound interference

In EMC, a basic distinction is made between conducted and field-bound or radiated interference. Conducted interference is transmitted directly via supply or signal lines. In practice, this "phenomenon" is well known, for example, when an iron is switched on, i.e. the temperature is readjusted, and a crackling noise is heard on the radio.  

Field-bound interference refers to the influence of electromagnetic fields that are emitted by conductive surfaces, lines or similar devices and thus affect other devices. In practice, this is mainly known as the influence of smartphones on loudspeakers. The familiar noise is heard in the loudspeaker.

Standards and limits

Many national and European standards define requirements for devices and specify limit values that must not be exceeded.  The fulfillment of harmonized EMC standards is also a prerequisite for devices to be placed on the market at all (for example, fundamental to fulfill for CE conformity). EMC measurements are therefore an essential part of the development of electronic devices.

Compliance with the required limits must be verified. This is done in specially equipped EMC laboratories. If problems or violations of the limits are encountered, improvements must be made. Valuable time is lost in this process, since good EMC laboratories are usually booked up well in advance.  

To avoid unnecessary loops, EMC pre-tests or pre-compliance measurements are carried out during development. These are based on the applicable standards, but usually do not meet them 100%. Often cheaper measuring devices are used. If these tests are successfully completed, the visit to the EMC laboratory is also more relaxed.  

EMC test lab versus in-house EMC test

The advantages of in-house EMC testing are obvious at first glance:

    Changes to the test object can be carried out easily at any time
    Measurements can be performed during development
    Redesigns can be checked without the need for an external laboratory

However, standard-compliant measurement setups are difficult to achieve. Since the extensive EMC tests also require expensive and comprehensive equipment and competent manpower, a trip to the EMC test laboratory is unavoidable in most cases, despite internal preliminary measurements.

New EMC test station at Ginzinger

###IMAGE5## Ginzinger electronic systems has had a small EMC laboratory for many years in order to carry out conducted measurements in-house. This has now been expanded with a new test system for conducted RF injection. This system can generate interference in the frequency range from 150 kHz to 230 Mhz with a power of up to 80W.

The necessary coupling and decoupling devices have also been expanded. As a result, the development team can now perform not only pre-compliance but also all standard measurements "compliant" in the conducted area when developing new electronic products.

The specially equipped EMC laboratory in development makes this possible. The equipment is extensive and consists of:  

  •     Interference measuring receiver
  •     Network simulations
  •     Test system for conducted immunity
  •     Burst, surge and voltage interruption generator
  •     ESD gun
  •     Various coupling and decoupling devices

The test station is a standard-compliant test station. This means that even before visiting the EMC laboratory, you can be sure that there will be no surprises in the conducted measurements and that you can concentrate fully on radiated measurements. Since the conducted RF coupling takes a lot of time, you can save valuable time in the EMC laboratory in advance, which you can use for the measurement of radiated disturbances. Any problems can thus still be rectified directly in the external laboratory.

Ing. Stefan Kinzlbauer

Ing. Stefan Kinzlbauer

Stefan Kinzlbauer, hardware development at Ginzinger, comments: "With our EMC measuring station, we now have the opportunity to carry out various measurements directly on our premises in accordance with the standards. We also carry out these measurements during development.

This means that there are fewer surprises later on in external laboratories. There is clear added value for the customer, as time and costs can be saved."

The equipment of the in-house EMC laboratory is rounded off by spectrum analyzer, probes, RF current clamps, etc., for measuring high-frequency radiated interference. These probes are especially helpful in optimizing already found interferences. Thus, weak points can be further analyzed and eliminated.


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