# How do I obtain the frequencies of each value in an FFT?

I have an FFT result. These are stored in two `double` arrays: a real part array and an imaginary part array. How do I determine the frequencies that correspond to each element in these arrays?

In other words, I would like have create an array that stores the frequencies for each real and imaginary component of my FFT.

• I do it in C#.net. Can you help me? Dec 6 '10 at 17:55
• If you don't understand the relevance of the real and imaginary parts of an FFT then you aren't going to get any meaningful results, so you should hunt out some FFT and signal processing tutorials to understand how to interpret the results. I think it's quite likely that whatever you're using it for, you are wanting the magnitude of the FFT or the Power Spectral Density. Dec 6 '10 at 23:28
• Thank you! I want to get peak frequencies of each frame (frame length depend in Window Length and Shift Length) Dec 7 '10 at 3:45

The first bin in the FFT is DC (0 Hz), the second bin is `Fs / N`, where `Fs` is the sample rate and `N` is the size of the FFT. The next bin is `2 * Fs / N`. To express this in general terms, the nth bin is `n * Fs / N`.

So if your sample rate, `Fs` is say 44.1 kHz and your FFT size, `N` is 1024, then the FFT output bins are at:

``````  0:   0 * 44100 / 1024 =     0.0 Hz
1:   1 * 44100 / 1024 =    43.1 Hz
2:   2 * 44100 / 1024 =    86.1 Hz
3:   3 * 44100 / 1024 =   129.2 Hz
4: ...
5: ...
...
511: 511 * 44100 / 1024 = 22006.9 Hz
``````

Note that for a real input signal (imaginary parts all zero) the second half of the FFT (bins from `N / 2 + 1` to `N - 1`) contain no useful additional information (they have complex conjugate symmetry with the first `N / 2 - 1` bins). The last useful bin (for practical aplications) is at `N / 2 - 1`, which corresponds to 22006.9 Hz in the above example. The bin at `N / 2` represents energy at the Nyquist frequency, i.e. `Fs / 2` ( = 22050 Hz in this example), but this is in general not of any practical use, since anti-aliasing filters will typically attenuate any signals at and above `Fs / 2`.

• Note -- the answer is slightly wrong -- the 512th bucket contains the level for 22050, the nyquist limit. The bins 0 to N/2 inclusive contain useful values. Aug 19 '12 at 20:31
• Thanks for the edit & clarification... I guess this is where I reveal some lack of practicality. Me: But master, FFT's work up to the nyquist! You: Padawan, you really should filter that out. Aug 22 '12 at 0:16
• I wish I could star answers. This answer is even better than the original question! Sep 14 '13 at 2:26
• @PaulR - I wanted to thank you for this wonderful answer that has served me over the years. I would visit this answer before I had a StackOverflow account, and I actually forgot about thanking you once I signed up. I was recently taking a look at FFT stuff and I remembered your answer and just visited it now. Once I got here, I remembered to thank you... so thank you! Whenever I have a debate with someone on interpreting what the each point on the horizontal axis of the FFT is, I just point them to this link. Jan 30 '15 at 21:21
• @rayryeng: thank you so much - I think that's the nicest acknowledgement I've ever had in ~5 years of answering questions here on SO! Jan 30 '15 at 22:17

Take a look at my answer here.

The FFT actually calculates the cross-correlation of the input signal with sine and cosine functions (basis functions) at a range of equally spaced frequencies. For a given FFT output, there is a corresponding frequency (F) as given by the answer I posted. The real part of the output sample is the cross-correlation of the input signal with `cos(2*pi*F*t)` and the imaginary part is the cross-correlation of the input signal with `sin(2*pi*F*t)`. The reason the input signal is correlated with `sin` and `cos` functions is to account for phase differences between the input signal and basis functions.

By taking the magnitude of the complex FFT output, you get a measure of how well the input signal correlates with sinusoids at a set of frequencies regardless of the input signal phase. If you are just analyzing frequency content of a signal, you will almost always take the magnitude or magnitude squared of the complex output of the FFT.

• The real and Imaginary part are FFT's result that used for? Please explain for me. Thank you Dec 6 '10 at 17:59
• Could it be that the magnitude of the complex outputs has to be doubled each? (if I restrict my interpretation to the lower half)
– Wolf
Jan 21 '16 at 11:31

I have used the following:

``````public static double Index2Freq(int i, double samples, int nFFT) {
return (double) i * (samples / nFFT / 2.);
}

public static int Freq2Index(double freq, double samples, int nFFT) {
return (int) (freq / (samples / nFFT / 2.0));
}
``````

The inputs are:

• `i`: Bin to access
• `samples`: Sampling rate in Hertz (i.e. 8000 Hz, 44100Hz, etc.)
• `nFFT`: Size of the FFT vector
• People cannot exactly know what you represent with `samples` or `nFFT`. So please make it more explanatory. Aug 20 '12 at 16:16
• The accepted answer says this should be `i * samples / nFFT`. Why is the extra `2` there? Am I missing something? May 14 '14 at 9:38

The FFT output coefficients (for complex input of size N) are from 0 to N - 1 grouped as [LOW,MID,HI,HI,MID,LOW] frequency.

I would consider that the element at k has the same frequency as the element at N-k since for real data, FFT[N-k] = complex conjugate of FFT[k].

The order of scanning from LOW to HIGH frequency is

``````0,

1,
N-1,

2,
N-2

...

[N/2] - 1,
N - ([N/2] - 1) = [N/2]+1,

[N/2]
``````

There are [N/2]+1 groups of frequency from index i = 0 to [N/2], each having the `frequency = i * SamplingFrequency / N`

So the frequency at bin FFT[k] is:

``````if k <= [N/2] then k * SamplingFrequency / N
if k >= [N/2] then (N-k) * SamplingFrequency / N
``````

Your kth FFT result's frequency is 2*pi*k/N.

• I guess this will be in radians Aug 11 '14 at 20:54