I have a handful of wav files. I'd like to use SciPy FFT to plot the frequency spectrum of these wav files. How would I go about doing this?

10Try googling each step (reading in a wav file, using FFT on the data). It should not be hard at all, come back here if you get stuck. – MattG Apr 30 '14 at 0:48
Python
provides several api to do this fairly quickly. I download the sheepbleats wav file from this link. You can save it on the desktop and cd
there within terminal. These lines in the python
prompt should be enough: (omit >>>
)
import matplotlib.pyplot as plt
from scipy.fftpack import fft
from scipy.io import wavfile # get the api
fs, data = wavfile.read('test.wav') # load the data
a = data.T[0] # this is a two channel soundtrack, I get the first track
b=[(ele/2**8.)*21 for ele in a] # this is 8bit track, b is now normalized on [1,1)
c = fft(b) # calculate fourier transform (complex numbers list)
d = len(c)/2 # you only need half of the fft list (real signal symmetry)
plt.plot(abs(c[:(d1)]),'r')
plt.show()
Here is a plot for the input signal:
Here is the spectrum
For the correct output, you will have to convert the xlabel
to the frequency for the spectrum plot.
k = arange(len(data))
T = len(data)/fs # where fs is the sampling frequency
frqLabel = k/T
If you are have to deal with a bunch of files, you can implement this as a function:
put these lines in the test2.py
:
import matplotlib.pyplot as plt
from scipy.io import wavfile # get the api
from scipy.fftpack import fft
from pylab import *
def f(filename):
fs, data = wavfile.read(filename) # load the data
a = data.T[0] # this is a two channel soundtrack, I get the first track
b=[(ele/2**8.)*21 for ele in a] # this is 8bit track, b is now normalized on [1,1)
c = fft(b) # create a list of complex number
d = len(c)/2 # you only need half of the fft list
plt.plot(abs(c[:(d1)]),'r')
savefig(filename+'.png',bbox_inches='tight')
Say, I have test.wav
and test2.wav
in the current working dir, the following command in python
prompt interface is sufficient:
import test2
map(test2.f, ['test.wav','test2.wav'])
Assuming you have 100 such files and you do not want to type their names individually, you need the glob
package:
import glob
import test2
files = glob.glob('./*.wav')
for ele in files:
f(ele)
quit()
You will need to add getparams
in the test2.f if your .wav files are not of the same bit.

4Good answer! You may want to remove the
>>>
so the OP and others can copy and paste. Also I've found it helps the answer if you include a picture if your code makes a plot. – Hooked Apr 30 '14 at 2:54 

1How would you concatenate multiple wav files? I have a lot of small wav files. – user1802143 Apr 30 '14 at 6:38

I have on the order of a few hundred small wave files. So I need an efficient way to do it. – user1802143 Apr 30 '14 at 6:44

2
You could use the following code to do the transform:
#!/usr/bin/env python
# * coding: utf8 *
from __future__ import print_function
import scipy.io.wavfile as wavfile
import scipy
import scipy.fftpack
import numpy as np
from matplotlib import pyplot as plt
fs_rate, signal = wavfile.read("output.wav")
print ("Frequency sampling", fs_rate)
l_audio = len(signal.shape)
print ("Channels", l_audio)
if l_audio == 2:
signal = signal.sum(axis=1) / 2
N = signal.shape[0]
print ("Complete Samplings N", N)
secs = N / float(fs_rate)
print ("secs", secs)
Ts = 1.0/fs_rate # sampling interval in time
print ("Timestep between samples Ts", Ts)
t = scipy.arange(0, secs, Ts) # time vector as scipy arange field / numpy.ndarray
FFT = abs(scipy.fft(signal))
FFT_side = FFT[range(N/2)] # one side FFT range
freqs = scipy.fftpack.fftfreq(signal.size, t[1]t[0])
fft_freqs = np.array(freqs)
freqs_side = freqs[range(N/2)] # one side frequency range
fft_freqs_side = np.array(freqs_side)
plt.subplot(311)
p1 = plt.plot(t, signal, "g") # plotting the signal
plt.xlabel('Time')
plt.ylabel('Amplitude')
plt.subplot(312)
p2 = plt.plot(freqs, FFT, "r") # plotting the complete fft spectrum
plt.xlabel('Frequency (Hz)')
plt.ylabel('Count dblsided')
plt.subplot(313)
p3 = plt.plot(freqs_side, abs(FFT_side), "b") # plotting the positive fft spectrum
plt.xlabel('Frequency (Hz)')
plt.ylabel('Count singlesided')
plt.show()