I have recorded an array[1024] of data from my mic on my Android phone, passed it through a 1D forward DFT of the real data (setting a further 1024 bits to 0). I saved the array to a text file, and repeated this 8 times.

I got back 16384 results. I opened the text file in Excel and made a graph to see what it looked like(x=index of array, y=size of number returned). There are some massive spikes (both positive and negative) in magnitude around 110, 232, and small spikes continuing in that fashion until around 1817 and 1941 where the spikes get big again, then drop again.

My problem is that wherever I look for help on the topic it mentions gettng the real and imaginary numbers, I only have a 1D array, that I got back from the method I used from Piotr Wendykier's class:

DoubleFFT_1D.realForwardFull(audioDataArray); // from the library JTransforms.

My question is: What do I need to do to this data to return a frequency? The sound recorded was me playing an 'A' on the bottom string (5th fret) of my guitar (at roughly 440Hz) .

  • I thought we covered this in your previous question: JTransforms FFT in Android from PCM data ? – Paul R Oct 6 '11 at 13:42
  • I'm wondering what of the results I should be looking at, do I need further calculating? Surely everything would have been handled inside the realFullForward() method? I followed the code through in his class but struggled to see what he was doing to the data (no comments, methods named strangley etc). – Ben Taliadoros Oct 6 '11 at 13:49
  • You haven't actually said what you are trying to achieve, or what the nature of the input signal is, but the FFT is usually just one step in the process, e.g. of generating a power spectrum or spectrogram. – Paul R Oct 6 '11 at 13:54
  • @hotpaw2 also answered this in another of your previous, similar questions: stackoverflow.com/questions/7651633/using-fft-in-android - you do actually read the answers that people give you, I hope ? – Paul R Oct 6 '11 at 13:55
  • Of course I do but I was confused by the idea I was finding Magnitude, relating that to frequency. – Ben Taliadoros Oct 6 '11 at 14:07
up vote 47 down vote accepted

The complex data is interleaved, with real components at even indices and imaginary components at odd indices, i.e. the real components are at index 2*i, the imaginary components are at index 2*i+1.

To get the magnitude of the spectrum at index i, you want:

re = fft[2*i];
im = fft[2*i+1];
magnitude[i] = sqrt(re*re+im*im);

Then you can plot magnitude[i] for i = 0 to N / 2 to get the power spectrum. Depending on the nature of your audio input you should see one or more peaks in the spectrum.

To get the approximate frequency of any given peak you can convert the index of the peak as follows:

freq = i * Fs / N;

where:

freq = frequency in Hz
i = index of peak
Fs = sample rate (e.g. 44100 Hz or whatever you are using)
N = size of FFT (e.g. 1024 in your case)

Note: if you have not previously applied a suitable window function to the time-domain input data then you will get a certain amount of spectral leakage and the power spectrum will look rather "smeared".


To expand on this further, here is pseudo-code for a complete example where we take audio data and identify the frequency of the largest peak:

N = 1024          // size of FFT and sample window
Fs = 44100        // sample rate = 44.1 kHz
data[N]           // input PCM data buffer
fft[N * 2]        // FFT complex buffer (interleaved real/imag)
magnitude[N / 2]  // power spectrum

capture audio in data[] buffer
apply window function to data[]

// copy real input data to complex FFT buffer
for i = 0 to N - 1
  fft[2*i] = data[i]
  fft[2*i+1] = 0

perform in-place complex-to-complex FFT on fft[] buffer

// calculate power spectrum (magnitude) values from fft[]
for i = 0 to N / 2 - 1
  re = fft[2*i]
  im = fft[2*i+1]
  magnitude[i] = sqrt(re*re+im*im)

// find largest peak in power spectrum
max_magnitude = -INF
max_index = -1
for i = 0 to N / 2 - 1
  if magnitude[i] > max_magnitude
    max_magnitude = magnitude[i]
    max_index = i

// convert index of largest peak to frequency
freq = max_index * Fs / N
  • 1
    Thanks so much Paul, I see where that was in previous answers now, I got to run some tests now! thanks – Ben Taliadoros Oct 6 '11 at 13:55
  • by index of peak, do you mean the index of the output array, where the peak in the graph lies? – Ben Taliadoros Oct 6 '11 at 14:08
  • 1
    Yes, you only want N/2 magnitudes, from N/2 complex values. – Paul R Oct 6 '11 at 15:00
  • 1
    And no, the fft array in the example above is the output of your FFT routine. The magnitude array is a second array in which you are calculating the magnitudes from the complex FFT output values. – Paul R Oct 6 '11 at 15:01
  • 3
    Great - well done – Paul R Oct 8 '11 at 19:47

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