I am currently trying to write some fourier transform algorithm. I started with a simple DFT algorithm as described in the mathematical definition:

public class DFT {
    public static Complex[] Transform(Complex[] input) {
        int N = input.Length;

        Complex[] output = new Complex[N];

        double arg = -2.0 * Math.PI / (double)N;
        for (int n = 0; n < N; n++) {
            output[n] = new Complex();
            for (int k = 0; k < N; k++)
                output[n] += input[k] * Complex.Polar(1, arg * (double)n * (double)k);
        return output;

So I tested this algorithm with the following code:

    private int samplingFrequency = 120;
    private int numberValues = 240;

    private void doCalc(object sender, EventArgs e) {
        Complex[] input = new Complex[numberValues];
        Complex[] output = new Complex[numberValues];

        double t = 0;
        double y = 0;
        for (int i = 0; i < numberValues; i++) {
            t = (double)i / (double)samplingFrequency;
            y = Math.Sin(2 * Math.PI * t);
            input[i] = new Complex(y, 0);

        output = DFT.Transform(input);


The transformation works fine, but only if numberValues is a multiple number of the samplingFrequency (in this case: 120, 240, 360,...). Thats my result for 240 values:

The transformation just worked fine.

If i am trying to calculate 280 values I get this result:

Why I am getting a incorrect result if I change the number of my calculated values? I am not sure if my problem here is a problem with my code or a misunderstanding of the mathematical definition of the DFT. In either way, can anybody help me with my problem? Thanks.

  • Can you let me know why the input for your Transform function is a complex array? Surely if you're converting from a standard sound wave (time-domain), it'd be a single double array? – Dan W Jun 21 '12 at 22:37
  • 2
    Okay, I get it - the imaginary part is set at 0, so it's essentially equal to if it were just a single double. By the way in your code, 'Complex.Polar' should be 'Complex.FromPolarCoordinates'. – Dan W Jun 22 '12 at 3:02
  • 2
    what do you use for plots? – GorillaApe Aug 17 '14 at 13:31
  • that was a small C# solution which I wrote myself. There are probably better libraries out there :) – Marcel Aug 27 '14 at 12:09

What you are experiencing is called Spectral Leakage.

This is caused because the underlying mathematics of the Fourier transform assumes a continuous function from -infinity to + infinity. So the range of samples you provide is effectively repeated an infinite number of times. If you don't have a complete number of cycles of the waveform in the window the ends won't line up and you will get a discontinuity which manifests its self as the frequency smearing out to either side.

The normal way to handle this is called Windowing. However, this does come with a downside as it causes the amplitudes to be slightly off. This is the process of multiply the whole window of samples you are going to process by some function which tends towards 0 at both ends of the window causing the ends to line up but with some amplitude distortion because this process lowers the total signal power.

So to summarise there is no error in your code, and the result is as expected. The artefacts can be reduced using a window function, however this will effect the accuracy of the amplitudes. You will need to investigate and determine what solution best fits the requirements of your project.


You are NOT getting the incorrect result for a non-periodic sinusoid. And they are not just "artifacts". Your result is actually the more complete DFT result which you don't see with a periodic sinusoid. Those other non-zero values contain useful information which can be used to, for example, interpolate the frequency of a single non-periodic-in-aperture sinusoid.

A DFT can be thought of as convolving a rectangular window with your sine wave. This produces (something very close to) a Sinc function, which has infinite extent, BUT just happens to be zero at every DFT bin frequency other than its central DFT bin for any sinusoid centered exactly on a DFT bin. This happens only when the frequency is exactly periodic in the FFT aperture, not for any other. The Sinc function has lots of "humps" which are all hidden in your first plot.

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