I've attached a few pictures showing the LISN and DSA in use testing a buck/boost LED driver. The driver is mounted to the back of an MCPCB with 6 XML running 3A a piece, so about 60W to the LEDs.
The picture below shows the noise levels with power turned off. The small peaks are FM stations being received via the DUT power cable. The rectangular aluminium plate is to prevent the LEDs from burning spots in my antistatic mat
The next picture shows the driver powered up and the conducted noise on the power leads to the driver. This noise level is a lot lower than with the original driver that did not have a common mode choke at the input (the black rectangle to middle/right on the PCB).
The next picture has the same setup, but a 0.1uF capacitor is making contact between the IN- of the LED driver board and the aluminium of the MCPCB. Noise levels are much reduced and you can see some of the FM radio station peaks showing through. Noise is now essentially below the FM received strength using the power leads as an antenna
At this level practical tests show the driver (in a housing with the LEDs and longer power leads) will not interfere with FM radio reception even if the power lead is wound around the vehicle antenna - good enough!
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So, this is an example of reducing emissions and being able to observe changes in real time by making changes to filtering and ground paths etc. It's not testing for compliance, but testing for a design that is proven to not interfere in the real world on an actual vehicle.
I am currently working to bring another design through FCC qualification at a local EMC lab. Our first run through had issues and based on what we did in the lab to identify the actual sources we discovered that one of the HDMI cables we used had huge leakage at the connector end (likely not shielded in the connector end where the cables are then soldered) and also that the AC/DC adapter we were using had nasty broadband noise in the 30MHz - 70MHz range.
I then brought my DSA to work along with my LISN and also a beehive probe. The LISN showed the same broadband noise shape with the AC/DC adapter plugged into the DUT end of the LISN. I could then apply a load at the Power supply end of the LISN to see how the noise of the adapter increased. Then we tried various other adapters and found one that was actually FCC approved having essentially no noise emissions. This proved that the LISN does a great job of identifying conducted noise that will then radiate (as measured by the antenna/emi receiver setup at the EMC lab). I then used the beehive (nearfield probe) and probed various HDMI cables and confirmed all were quiet at the cable and connectors, EXCEPT for the 'bad' HDMI cable.
It has been a learning experience, but with several real world check points between the LISN/DSA and the Beehive, I am becoming confident in what my setup shows and how the unit will behave with nearby radios etc. The test lab results add a lot of credibility and correlation between my setup and their measurements. Certainly these tools allow for pre-compliance testing to at least identify things that will surely cause you to fail.
cheers,
george.
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