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In a previous question, I had asked Why can't I simply negate the source time domain amplitude values to produce a destructive noise signal?

One of the posters said that while simply producing a inverses polarity (negated) signal will work in theory, in practice it is not possible

So I am asking, what is the fundamental approach (in a sort of semi technical way) to active noise cancellation?

Secondly, why are most literature on this topic in frequency domain?

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up vote 8 down vote accepted

It's rather simple.

By the time you send your inverted signal, the noise has already been heard.

You need to look at what frequencies are being generated, and then produce the appropriate inverted signals of those to cancel them out.

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Why do I need to do it in frequency domain instead of doing the same thing in time domain? If it has already been heard, how does doing it in a different domain matter? – user605957 Apr 24 '12 at 4:27
You have already lost in the time domain. Your only hope is to work in the frequency domain and hope that the frequencies don't change too much, or that you can keep up enough. – Ignacio Vazquez-Abrams Apr 24 '12 at 4:28
Excellent. For the first time, I somewhat understand. Now my question is, what is the equivalent of producing an inverse in frequency domain? In time domain I can simply negate the values. IN frequency domain, what do I do to each frequency mathematically? – user605957 Apr 24 '12 at 4:38
Shift the phase by 180 degrees. – Ignacio Vazquez-Abrams Apr 24 '12 at 4:40
Because of this. Try a different phase shift; shifting phase is just rotating the complex number around the origin. – Ignacio Vazquez-Abrams Apr 24 '12 at 5:03

Noise cancellation is prediction. Your algorithm has to predict what the sound of the noise will be at some time in the future (that time given by the system and audio time latencies), and then predict what signal will produce the opposite sound at that same point in the future (which your system will distort and delay, so you have to figure in the opposite distortion and delay).

You might be able to use several successive FFTs to determine which frequencies in the noise are not changing, and assume or calculate some probability that they will continue for a short time into the future.

If you know the frequency response curve of the speaker, you might be able to figure out the frequency amplitudes of a signal needed to match some predicted noise spectrum. The phase angle of a sinusoid will change with time. If you know the time delay of your output signal, you might be able to calculate the phase of a sinusoid at some point in the future. If you have a predicted phase of a particular frequency of noise at some time and location, you can add π to that phase angle to estimate the noice-cancelling signal.

If you don't know the frequency response and delay of your system, then you won't know what frequencies, amplitudes or phases of signal to create for cancellation. You might well end up amplifying the noise instead of cancelling it.

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