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Parasitic Oscillations and EMI Emissions

Parasitic oscillations are one of the four typical causes for emissions in EMI/EMC problems. Try to reduce the gain or break the feedback and the problem could be solved at low cost.

When failing in radiated or conducted emissions the origin of the undesired emissions is usually one of four possibilities:

  1. main frequency (or harmonics) from oscillators, clocks or switching circuits in the design,
  2. non-linear combinations (mixing effects) of several frequencies used in your circuit,
  3. ringing in underdamped parasitic resonant circuits, and,
  4. parasitic oscillations

A parasitic oscillator is an undesired oscillator. RF amplifier designers know a lot about this subject when trying to design stable amplifiers (remember “Amplifiers will, oscillators won’t”).

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Why can a circuit oscillate?

To create an oscillation you need two important conditions: gain and feedback (Figure 1).

Figure 1: Theory for electronic oscillators.

At the frequency where you have gain and the appropriated feedback, the circuit will oscillate.

Condition for oscillation is OPEN LOOP GAIN (A·F) equal or greater than one:

|A·F|=1 and Phase(A·F)=0°

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So, because when designing a circuit, many blocks analog or digital, low or high in power can offer gain at some frequencies, if a parasitic or undesired feedback is created (i.e. with the layout of the circuit), the unexpected high frequency signal will be created.

The signal can then be injected in mains or power system (conducted emissions) or radiated by cables or any other metal structure.

That is because the layout of input and output pins in components or circuits must be avoided.

To discover the parasitic oscillator, we can use a set of near field probes. Then, the gain and feedback must be located typically using the schematic and PCB layout of the circuit.

The solution is usually to reduce gain with ferrites or resistors in the gain path (Figure 2 left) or opening the loop to remove feedback (Figure 2 right).

Figure 2: How to kill an undesired oscillation.

Recently I was involved in a radiated problem at 3 meters (Figure 3). Emissions in the VHF range (close to 155MHz) were related with a frequency not related with those in the nominal design (clock, harmonics, etc.).

Figure 3: Damping effects in the high quality Lo-Co filter.

Using the near field probe I found the area of the PCB where the signal had higher amplitudes: the hot area.

The area was related with a small DC/DC converter switching in the kHz range. The radiated signal was not any harmonic of the converter. No ringing in that frequency was found in the circuit so a parasitic oscillation was considered as a possible culprit for this problem.

In Figure 4 left, the schematic of the DC/DC converter is included.

Figure 4: The DC/DC converter schematic (left) and PCB layout (right).

A +24Vdc level is converted to +5V with a TPS5410D IC. The layout of input and output signals to the converter is marked in color.

Note the proximity between traces red and green for the +24V (input) and +5V (output) to the converter. The proximity was considered as a possibility for an undesired I/O feedback.

The parasitic feedback was confirmed with a small knife, cutting the +5V trace and connecting it using a separated wire far from the +24V signal.

As you can see in Figure 5, the oscillation was removed and the radiated test was passed.

Figure 5: Emissions are below the limits with the modified layout.

Note other options as a small series ferrite with IC output could be tried as an alternative trying to reduce the undesired gain of our oscillator.

A final advice: be careful with the layout of input and output signals to any IC or electronic circuit to avoid parasitic oscillations.

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