# how to extract frequency associated with fft values in python

I used `fft` function in numpy which resulted in a complex array. How to get the exact frequency values?

`np.fft.fftfreq` tells you the frequencies associated with the coefficients:

``````import numpy as np

x = np.array([1,2,1,0,1,2,1,0])
w = np.fft.fft(x)
freqs = np.fft.fftfreq(len(x))

for coef,freq in zip(w,freqs):
if coef:
print('{c:>6} * exp(2 pi i t * {f})'.format(c=coef,f=freq))

# (8+0j) * exp(2 pi i t * 0.0)
#    -4j * exp(2 pi i t * 0.25)
#     4j * exp(2 pi i t * -0.25)
``````

The OP asks how to find the frequency in Hertz. I believe the formula is `frequency (Hz) = abs(fft_freq * frame_rate)`.

Here is some code that demonstrates that.

First, we make a wave file at 440 Hz:

``````import math
import wave
import struct

if __name__ == '__main__':
# http://stackoverflow.com/questions/3637350/how-to-write-stereo-wav-files-in-python
# http://www.sonicspot.com/guide/wavefiles.html
freq = 440.0
data_size = 40000
fname = "test.wav"
frate = 11025.0
amp = 64000.0
nchannels = 1
sampwidth = 2
framerate = int(frate)
nframes = data_size
comptype = "NONE"
compname = "not compressed"
data = [math.sin(2 * math.pi * freq * (x / frate))
for x in range(data_size)]
wav_file = wave.open(fname, 'w')
wav_file.setparams(
(nchannels, sampwidth, framerate, nframes, comptype, compname))
for v in data:
wav_file.writeframes(struct.pack('h', int(v * amp / 2)))
wav_file.close()
``````

This creates the file `test.wav`. Now we read in the data, FFT it, find the coefficient with maximum power, and find the corresponding fft frequency, and then convert to Hertz:

``````import wave
import struct
import numpy as np

if __name__ == '__main__':
data_size = 40000
fname = "test.wav"
frate = 11025.0
wav_file = wave.open(fname, 'r')
wav_file.close()
data = struct.unpack('{n}h'.format(n=data_size), data)
data = np.array(data)

w = np.fft.fft(data)
freqs = np.fft.fftfreq(len(w))
print(freqs.min(), freqs.max())
# (-0.5, 0.499975)

# Find the peak in the coefficients
idx = np.argmax(np.abs(w))
freq = freqs[idx]
freq_in_hertz = abs(freq * frate)
print(freq_in_hertz)
# 439.8975
``````
• @~unutbu:But can I get the frequency values in Hertz?I want to make wav files. – ria Sep 12 '10 at 18:29
• @ria: `freq` as defined by `np.fft.fft` is unitless, and always in the interval [-1/2, 1/2]. I believe to convert to Hertz, you multiply by the frame rate and take the absolute value. – unutbu Sep 12 '10 at 19:32
• @PavelShvechikov: Oops, yes. You are absolutely right. Thanks for the correction. – unutbu Nov 28 '14 at 13:27
• I found it. Basically my data is 2 channel data but your code may not working for me. – AQU Jun 14 '16 at 11:49
• I made the wav generation script channels to 2 and then with the script I am getting the freq specified in the wav generation script. But when I record the same. I am getting exactly half of the peak frequency value. What may I go wrong. Thanks in advance – AQU Jun 14 '16 at 12:26

# Frequencies associated with DFT values (in python)

By fft, Fast Fourier Transform, we understand a member of a large family of algorithms that enable the fast computation of the DFT, Discrete Fourier Transform, of an equisampled signal.

A DFT converts a list of N complex numbers to a list of N complex numbers, with the understanding that both lists are periodic with period N.

Here we deal with the `numpy` implementation of the fft.

In many cases, you think of

• a signal x defined in the time domain of length N, sampled at a constant interval dt,
• its DFT X (here specifically `X = np.fft.fft(x)`), whose elements are sampled on the frequency axis with a sample rate dw.

### Some definition

• the period (aka duration) of the signal `x`, sampled at `dt` with `N` samples is is

``````T = dt*N
``````
• the fundamental frequencies (in Hz and in rad/s) of `X`, your DFT are

``````df = 1/T
dw = 2*pi/T # =df*2*pi
``````
• the top frequency is the Nyquist frequency

``````ny = dw*N/2
``````

(and it's not `dw*N`)

## The frequencies associated with a particular element in the DFT

The frequencies corresponding to the elements in `X = np.fft.fft(x)` for a given index `0<=n<N` can be computed as follows:

``````def rad_on_s(n, N, dw):
return dw*n if n<N/2 else dw*(n-N)
``````

or in a single sweep

``````w = np.array([dw*n if n<N/2 else dw*(n-N) for n in range(N)])
``````

if you prefer to consider frequencies in Hz, `s/w/f/`

``````f = np.array([df*n if n<N/2 else df*(n-N) for n in range(N)])
``````

### Using those frequencies

If you want to modify the original signal `x` -> `y` applying an operator in the frequency domain in the form of a function of frequency only, the way to go is computing the `w`'s and

``````Y = X*f(w)
y = ifft(Y)
``````

## Introducing `np.fft.fftfreq`

Of course `numpy` has a convenience function `np.fft.fftfreq` that returns dimensionless frequencies rather than dimensional ones but it's as easy as

``````f = np.fft.fftfreq(N)*N*df
w = np.fft.fftfreq(N)*N*dw
``````

Because `df = 1/T` and `T = N/sps` (`sps` being the number of samples per second) one can also write

``````f = np.fft.fftfreq(N)*sps
``````

The frequency is just the index of the array. At index n, the frequency is 2πn / the array's length (radians per unit). Consider:

``````>>> numpy.fft.fft([1,2,1,0,1,2,1,0])
array([ 8.+0.j,  0.+0.j,  0.-4.j,  0.+0.j,  0.+0.j,  0.+0.j,  0.+4.j,
0.+0.j])
``````

the result has nonzero values at indices 0, 2 and 6. There are 8 elements. This means

``````       2πit/8 × 0       2πit/8 × 2       2πit/8 × 6
8 e           - 4i e           + 4i e
y ~ ———————————————————————————————————————————————
8
``````
• I'm sorry. But I couldn't get it clearly.Can you tell me what are 't' and 'e' above? why did you introduce 'i*t' in the equation 2πn/8, Is there a function in SciPy doing this calculation? – ria Sep 12 '10 at 15:48
• @ria: e is 2.71828.... See en.wikipedia.org/wiki/Euler%27s_formula. t is the index of the original array, e.g. t=0 -> 1, t=1 -> 2, t=2 -> 1, etc. Basically, if you want to get the frequency, they are just 0/8, 1/8, 2/8, ..., 7/8. – kennytm Sep 12 '10 at 16:05
• @ KennyTM:I see,the exponent 'e'.I understood. – ria Sep 12 '10 at 18:30
• This is incorrect – the output of the FFT is not in normal frequency order. See docs.scipy.org/doc/numpy-1.10.0/reference/… – jakevdp Nov 22 '15 at 11:51
• Non-version specific link to numpy FFT documentation: numpy.org/doc/stable/reference/routines.fft.html – Chris Apr 27 at 4:35