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I've researched fast fourier transforms and have not been able to see a way for them to decode multiple frequencies from one signal. Is there a way to decompose the result of an fft calculation so that we can see individual pitches in a chord, or maybe to calculate the most likely chord based on the result of the fft?

If not, is there another method of pitch detection that can detect multiple pitches in a live setting yet?

EDIT: I am trying to do no more than six pitches at a time, as the software I am writing deals with guitars; in the offhand chance that the program user has a seven string guitar, it would need to be able to pick up seven pitches max.

That being the case, is an FFT (or some other method) able to handle this from a single microphone signal or do I have to make a guitar pickup that reads each string individually?

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How many tones or sine waves are we talking about in the original signal? If it's just a few (such as the 2 core tones in a DTMF signal), the FFT would likely work. Just search for the peaks. Otherwise, for music, this is generally known to be a hard problem in computer science and signal processing. You could do an Internet search on "automatic music transcription" and you might find some software programs or code that attempt to do this. –  selbie Mar 8 '12 at 6:50
There's a famous piece of software called Melodyne that can do it for complex sounds. –  cmannett85 Mar 8 '12 at 7:45
Possible duplicate of this question: stackoverflow.com/questions/4337487/chord-detection-algorithms/… –  hotpaw2 Mar 8 '12 at 8:22

2 Answers 2

up vote 1 down vote accepted

There are two well known statistical techniques for parametric spectral estimation. One is MUSIC and the other one is ESPRIT. If you can express your signal as sum of weighted complex exponentials (i.e. sinusoidals) you can apply either of them. Moreover, the eigendecomposition of the correlation matrix will also tell you the number of frequencies in the signal so you are not even supposed to know that. ESPRIT is better than MUSIC since you are not supposed to do any search for peaks in frequency domain. The frequencies are given you directly as a result. However, MUSIC is known to be more robust.

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This is pretty much what I'm looking for; is it fast enough to produce live results (i.e. give live feedback to a guitarist)? –  Adam Mar 14 '12 at 15:58
Depending on your size of data. I like ESPRIT more, and in that case you are supposed to do two eigendecompositions. For an M by M autocorrelation matrix, this corresponds to M^3 operations. The thing is that your M is supposed to be bigger than K (K is the number of frequencies in your signal). So I do not think it would be a huge problem in your case, as you do not have too many frequencies. –  YBE Mar 14 '12 at 19:09
@YBE : MUSIC and ESPRIT are reported to perform poorly when one doesn't know the exact number of exponentials involved, and guitars can produce some large and varying number of overtones for each string (can be dozens), some of them potentially slightly inharmonic. –  hotpaw2 Apr 3 '12 at 20:01
@hotpaw2, you are right about not knowing the number of exponentials, however, the eigendecomposition of the autocorrelation matrix also tells some about number of components involved. There should be a significant drop at some point in the eigenspectrum as signal eigenvalues are bigger than noise eigenvalues. Although, in the case of heavily noisy observations, noise eigenvalues will be comparable to signal eigenvalues. There is one other technique called as Annihilating Filter Method that is used with Cadzow's Iterative Denoising which is claimed to be robust. –  YBE Apr 3 '12 at 22:05

A guitar pick-up that isolates each string may be necessary. Otherwise unmixing all the overtones might be a very difficult problem.

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