When designing an EMI/EMC filter the orientation relative to source and victim is critical for high effectiveness. Can you save components in your filters?
Consider you have an EMI problem or you are failing in EMC conducted or radiated emissions tests and you will try to design a filter to solve the problem.
First question: Are you sure?
Remember: if you try to design a filter it is because you will not try to kill the source. Please, be sure this is your final decision. Usually to kill the source is my preferred option for any EMI/EMC problem.
But sometimes, as in our example, we cannot remove the source of the problem so we will try a filter. And, in EMI/EMC, we use low pass filters to avoid high frequency energy arriving to the victim.
Usually you will start with one component (cheaper, smaller, etc.) filter: a shunt capacitor or a series inductor (Figure 1).
Note from general theory that you will obtain -20dB/dec (or -6dB/oct) in attenuation for each component included in your filter.
But, when to use the capacitor instead of the inductor?
With reactive components you are trying to filter using mismatching: you choose the capacitor to be low impedance and the inductor to be high impedance at EMI frequencies COMPARED with ZS and ZL terminal impedances.
So, the capacitor option will be especially effective if terminal impedances are high and the inductor will be effective if terminal impedances are low.
Let me show you this idea with an example.
Think your terminal impedances are resistive ZS=5ohm and ZL=100ohm. You need to design a low pass filter with order 2 (-40dB/dec) so you will use an inductor and a capacitor.
How to orientate the filter?
Following the previous idea, you will use the shunt component (capacitor) in parallel with the higher impedance (ZL) and the series component (inductor) in series with the smaller impedance (ZS).
In Figure 2 we compare insertion losses with good vs bad orientation. More than 20dB in difference while slope in attenuation band is -40dB/dec for
both solutions!
I have seen the importance of this idea many times while reviewing designs in real products for companies or teaching.
For example, in Figure 3, the conducted emissions from a coffee machine were measured without filter between 100 kHz and 30 MHz (red color). The original filter from this company was an LC network with 30uH in the LISN side and 100nF shunt capacitance in the DUT side.
The results were not as expected because EMI was over the limit in all the frequency range of interest (green color) in left side of Figure 3.
When obtaining the result in the left, a typical decision is to add components to the filter (additional inductors and capacitors) trying to increase the insertion losses (remember 20dB/dec for each added component). In doing this, the filter will be bigger, more expensive, etc. (sometimes this is not possible because available space and limited budget).
But, note what happen when I rotate 180º the filter as in right side of Figure 3. With the same components and a good orientation, the product is now complying with regulations. Great!
Have you tried this idea in your products?
Perhaps your filter is more complex than necessary?
Finally, an important idea: for EMI engineers, terminal impedances are usually unknown so, if you have no experience with the product perhaps you will need to try both orientations to find the appropriate solution.
Homework:
- in our example, what is bigger, the output impedance of the coffee machine or the input impedance of the LISN?
- when will you use a T-network (LCL) versus a PI- network (CLC)?
