# Autocorrelation Heuristics for a Tuner

I've implemented a simple autocorrelation routine against some audio samples at a rate of 44100.0 with a block size of 2048.

The general formula I am following looks like this:

``````r[k] = a[k] * b[k] = ∑ a[n] • b[n + k]
``````

and I've implemented it in a brute-force nested loop as follows:

``````for k = 0 to N-1 do
for n = 0 to N-1 do
if (n+k) < N
then r[k] := r[k] + a(n)a(n+k)
else
break;
end for n;
end for k;
``````

I look for the max magnitude in r and determine how many samples away it is and calculate the frequency.

To help temper the tuner's results, I am using a circular buffer and returning the median each time.

The brute force calculations are a bit slow - is there a well-known, faster way to do them?

Sometimes, the tuner just isn't quite as accurate as is needed. What type of heuristics can I apply here to help refine the results?

Sometimes the OCTAVE is incorrect - is there a way to hone in on the correct octave a bit more accurately?

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What are * and •? Multiplication? Convolution? Dot product? –  Jean-François Corbett Sep 20 '11 at 18:50
a[k] * b[k] is the dot product while inside the summation, a[n] • b[n+k] is multiplication. –  Luther Baker Oct 3 '11 at 16:01
Hard to choose an answer as at least two have been helpful. –  Luther Baker Oct 3 '11 at 16:01

One simple way to improve this "brute force" autocorrelation method is to limit the range of k and only search for lags (or pitch periods) near the previous average period, say within +-0.5 semitones at first. If you don't find a correlation, then search a slightly wider range, say, a within a major third, then search a wider range but within the expected frequency range of the instrument being tuned.

You can get higher frequency resolution by using a higher sample rate (say, upsampling the data before the autocorrelation if necessary, and with proper filtering).

You will get autocorrelation peaks for the pitch lag (period) and for multiples of that lag. You will have to eliminate those subharmonics somehow (maybe as impossible for the instrument, or perhaps as an unlikely pitch jump from the previous frequency estimations.)

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Regarding the phrase "find a correlation", I'm generally looking for the "max" - and that is it, I don't actually compare or test whatever the max summation is. Using the modification you suggest, would I return the resulting "max" > 0 ... or do I need some logic to know that I went from a bad to a valid correlation. –  Luther Baker Sep 22 '11 at 22:55
For instance, would I want to make sure I get a summation < 0 - and then look for the max up to the next value < 0 so I know that? Is that what would help me decide if I need to try against a wider range? I guess, fundamentally, what makes a correlation valid or not - if I'm simply looking for the max value from 'k' to 'n' where k is my 5 semitones less than my previous freq? –  Luther Baker Sep 22 '11 at 22:56

The efficient way to do autocorrelation is with an FFT:

• FFT the time domain signal
• convert complex FFT output to magnitude and zero phase (i.e. power spectrum)
• take inverse FFT

This works because autocorrelation in the time domain is equivalent to power spectrum in the frequency domain.

Having said that, bare bones autocorrelation is not a great way to implement (accurate) pitch detection in general, so you might want to have a rethink about your whole approach.

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Do the results of the final inverse FFT give me a period length in samples? –  Luther Baker Sep 20 '11 at 22:11
No, the final output of the IFFT is just the autocorrelation - you would still need to identify the pitch period within this. –  Paul R Sep 21 '11 at 6:54
``````(0.1 * 4 + 0.9 * 5 + 0.8 * 6) / (0.1 + 0.9 + 0.8) = 5.39