I have an array of doubles containing audio samples coming directly from a microphone at a sampling rate of 44100. I want to get the fundamental frequency (the samples contain the amplitudes). On wikipedia in the autocorrelation page I found the description of the solution based on the Wiener-Khinchin theorem, I completed the algorithm with some more research over the internet and eventually I wrote the following code, but I am not sure whether it is correct:

```
private double determineFrequency(double[] signal) {
//Get a FastFourierTransformer instance (Apache library)
FastFourierTransformer fft = new FastFourierTransformer(DftNormalization.STANDARD);
//The size of the array used by the fft must be a power of two, wrapping
//the original array in a bigger one padded to zero
//NOTE: Here I assume that the input array is smaller than 8192
double[] paddedSignal = new double[8192];
System.arraycopy(signal, 0, paddedSignal, 0, signal.length);
//First fft (forward) to switch from amplitude domain to the frequency domain
Complex[] transformed = fft.transform(paddedSignal, TransformType.FORWARD);
// Calculate the conjugate of the complex array
for (int i=0; i<transformed.length; i++)
transformed[i] = transformed[i].conjugate();
//Second fft (inverse) to complete the autocorrelation
transformed = fft.transform(transformed, TransformType.INVERSE);
//Calculate the array of corresponding real values to switch
// from the frequency domain to the amplitude domain
double[] autocorrelationMatrix = new double[transformed.length];
for (int i=0; i<transformed.length; i++) {
if (Double.isNaN(transformed[i].abs()) || Double.isInfinite(transformed[i].abs()))
autocorrelationMatrix[i] = 0;
else
autocorrelationMatrix[i] = transformed[i].abs();
}
//Get the index of the max amplitude
Integer indexOfMax = Utils.indexOfMax(autocorrelationMatrix);
return transformed[indexOfMax].getReal()*audioFormat.getSampleRate()/transformed.length;
}
```