Electronic – How Do Intermodulation Products Manifest in Transmitting Equipment

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What I Understand Already:

  1. Intermodulation products manifest in receiving equipment as a result of several near-by transmitters, each operating at different carrier frequencies, mixing at the receiving antenna.
  2. The signal sensed at the receiving antenna produces an alternating current that contains a mix of each carrier frequency (plus harmonics thereof, for each carrier).
  3. Presuming that frequency selective components before the RF amplifier don't attenuate the power at each carrier too much, non-linearities in the RF amplifier will produce intermodulation products at frequencies which are linear combinations of each input carrier.
  4. Some of these intermodulation products fall near the receiver's tuned bandwidth, creating undesired power in the side-band (which is why it's worth modeling intermodulation effects).

But…

However, I've learned that transmitter intermodulation products can be important to model as well. How do these intermodulation products manifest themselves in a victim transmitter?

Let's consider a two-carrier mix at the input of the RF amplifier (block diagram shown below).

Block Diagram of a Transmitter

The first carrier is easy to explain: it is passed through the IF-stage into the RF-stage, to the input of the RF amplifier. However, there are only two possible routes for the second carrier to be passed to this victim transmitter's RF amplifier:

  • The second carrier penetrates the victim transmitter's casing (seems nearly impossible, saying that a Faraday cage sole purpose is to attenuate external radio signals)
  • The second carrier impinges on the victim transmitter's antenna, producing an alternating current that is passed through the output of the amplifier into its input (seems more likely, since there wouldn't be any protective casing over an antenna)

producing an alternating current that is passed through the output of the amplifier into its input

So far, I've accepted this as an explanation for how these IMPs manifest themselves in a victim transmitter. But, I realize that it's very hand-wavy. Can some provide a more technical explanation of this, if my understanding is even correct?

Best Answer

There are essentially two mechanisms:

  1. Internal nonlinearities, arising from non-ideal behaviour of mixers and amplifiers.

When passed through a nonlinear device, a modulating signal containing F_1 & F_2 can produce an output signal with side bands located at: $$\{F_1, F_2,\\ (F_1+F_2), (F_1-F_2),\\ 2*F_1, 2*F_2,\\ 2*F_1+F_2, 2*F_2+F_1,\\ 2*F_1-F_2, 2*F_2-F_1,\\ 3*F_1, 3*F_2\\ ...\}$$ Even though we want mixers that are multipliers they're often closer to Taylor series, and only approach being multipliers for a given signal domain. We also want linear amplifiers, but we also want them to be efficient and cheap... that is a tricky, tricky mix.

  1. Effects due to externally applied RF.

Power amplifiers are sensitive to energy applied to the output and particularly when operated close to or in saturation, they can look an awful lot like a switching mixer if you squint just right, so again you can get sum and difference series produced. This is an especially good party trick on a shared mast with multiple co-located services where adding a transmitter can cause one that YOU do NOT own, to interfere with another receiver that you ALSO do not own... That can get amusingly political. I have had LOTS of fun with this when co-locating low band VHF kit.

Power amplifiers are sensitive to energy applied to the output.

To expand on this detail (from discussion in comments): It all boils down to the non-linear curve that describes the input-output relationship of an amplifier. When a voltage is introduced at the output, you're modifying that relationship. Thus, the resulting inter-modulation products observed at the output contain the sum & difference of every multiple of the frequencies introduced at either the input or output.

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