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I am currently creating a C code, which takes as an input a wav file (specifically just one channel of the original wav file), and it performs the short-time Fourier transform. The main part of the code is this one:

stft_data = (fftw_complex*)(fftw_malloc(sizeof(fftw_complex)*windowSize));

fft_result= (fftw_complex*)(fftw_malloc(sizeof(fftw_complex)*windowSize));

storage = (fftw_complex*)(fftw_malloc(sizeof(fftw_complex)*storage_capacity));

//define the fftw plane
fftw_plan plan_forward;
plan_forward = fftw_plan_dft_1d(windowSize, stft_data, fft_result, FFTW_FORWARD, FFTW_ESTIMATE);

//integer indexes
int i,counter ;
counter = 0 ;
//create a Hamming window
double hamming_result[windowSize];
hamming(windowSize, hamming_result);

//implement the stft position indexes
int chunkPosition = 0; //actual chunk position
int readIndex ; //read the index of the wav file

while (chunkPosition < wav_length ){
    //read the window
    for(i=0; i<windowSize; i++){

      readIndex = chunkPosition + i;

      if (readIndex < wav_length){
        stft_data[i] = wav_data[readIndex]*hamming_result[i]*_Complex_I  + 0.0*I;
      }
      else{
        //if we are beyond the wav_length
        stft_data[i] = 0.0*_Complex_I + 0.0*I;//padding
        break;
      }
    }
    //compute the fft
    fftw_execute(plan_forward);
    //store the stft in a data structure
    for (i=0; i<windowSize;i++)
    {
      //printf("RE: %.2f  IM: %.2f\n", creal(fft_result[i]),cimag(fft_result[i]));
      storage[counter] = creal(fft_result[i]) + cimag(fft_result[i]);
      counter+=1;
    }

    //update indexes
    chunkPosition += hop_size;
    printf("Chunk Position %d\n", chunkPosition);
    printf("Counter position %d\n", counter);
    printf("Fourier transform done\n");

}  

Once the FFT has been computed onto the selected window, I am storing the FFT real and imaginary part into a storage variable.

After that I would like to compute the cross correlation among the data points in each of the N windows I have in the end. As an example, I would like to compute the correlation between the first data point of the first window ( storage[0] ) with the first element of the second window (storage[windowSize+1]). However, I am facing some problems and I don't have reasonable values. According to what I studied, the correlation in the Fourier space it is just the complex multiplication between two Fourier terms. Thus, what I am doing is something like :

correlation = storage[0]*conj(storage[windowSize+1]);

However, I got very huge values, which makes me wonder if I am really computing a correlation.

Where am I wrong? How should I scale my correlation results? How should I compute the correlation with the Fourier values? and then, how should I plot the Fourier values I have from FFTW3 calculations? should I shift all the values or are they already shifted?

Thanks very much

  • 1
    storage[windowSize+1] is the second element of the next window – doug Jun 13 '18 at 12:58
  • Hi @doug you're right. However, this is just an example of a possible cross-correlation I would like to compute, namely between the first element of the first window and the second one of the next window – Stefano Jun 13 '18 at 13:29
  • Could it be that you are looking for normalized cross-correlation ? This is generally closer to what I would expect in physics, a value in [-1, 1] instead of arbitrarily large. I'm not versed in any way in signal processing, though, so I simply don't know what the unnormalized correlation is good for. – GeckoGeorge Jun 13 '18 at 13:41
  • Oh, also, shouldn't it be the SUM of multiplication between fourier terms? Something like cor[n] = SUM( storage[m] * conj(storage(windowSize+m+n))) ? – GeckoGeorge Jun 13 '18 at 13:43
  • Hi @GeckoGeorge , normalized cross-correlation is exactly what I want. I did not try as you said, summing up all the contributions, I am going to see – Stefano Jun 13 '18 at 13:57
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The line storage[counter] = creal(fft_result[i]) + cimag(fft_result[i]); makes storage purely real. Since computing correlation = storage[0]*conj(storage[windowSize+1]); is the next step in the computation of the cross correlation, there is a problem. Indeed, there is no point in conjugating a real number.

Trying storage[counter] = fft_result[i]; could partly resolve the issue. In addition, correlation = storage[0]*conj(storage[windowSize+1]); should be modified to correlation = storage[0]*conj(storage[windowSize]);

By performing correlation = storage[0]*conj(storage[windowSize]);, the magnitude of index [0] of the DFT of the correlation is obtained. Indeed, storage[0] corresponds to the average of the first frame, while storage[windowSize] corresponds to the average of the second frame. It is not equal to the averages, but much larger, as it is scaled by the length of the frame windowSize.

To compute the correlation between the two signals, the next step should be:

for (i=0; i<windowSize;i++)
{
    dftofcorrelation[i]=storage[i]*conj(storage[i+windowSize]
}

Then, the inverse DFT must be applied to the array dftofcorrelation to get the correlation as an array. It must be kept in mind that neither the forward nor the backward DFT of FFTW include any scaling, see what FFTW really computes:

fftw_execute(plan_backward);

If two scalars are to be retained of this correlation array, it's its maximum (high if the signal are similar up to a delay) and the index of the maximum, that is the estimated time offset between the two signals.

The overall scaling induced by FFTW is a power of windowSize (windowSize^3?). It can be checked by computing the autocorrelation of a uniform signal (which is uniform).

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