# How do I get the values of a specific frequency range

I have a .wav file, I load it and I get the next spectrogram showing the spectrum in dB

http://i.stack.imgur.com/22TjY.png

Now I would like to know these values exactly because I want to compare with other wav file, for recognizing if these 4 values are there.

http://i.stack.imgur.com/Jun25.png

The source to generate that pictures (taken from other stackoverflow example)

``````## some stuff here

for i in range(0, int(RATE / CHUNK_SIZE * RECORD_SECONDS)):
# little endian, signed shortdata_chunk
if byteorder == 'big':
data_chunk.byteswap()
data_all.extend(data_chunk)

## some stuff here

Fs = 16000
f = np.arange(1, 9) * 2000
t = np.arange(RECORD_SECONDS * Fs) / Fs
x = np.empty(t.shape)
for i in range(8):
x[i*Fs:(i+1)*Fs] = np.cos(2*np.pi * f[i] * t[i*Fs:(i+1)*Fs])

w = np.hamming(512)
Pxx, freqs, bins = mlab.specgram(data_all, NFFT=512, Fs=Fs, window=w,
noverlap=464)

#plot the spectrogram in dB
Pxx_dB = np.log10(Pxx)

pyplot.subplot(211)
ex1 = bins[0], bins[-1], freqs[0], freqs[-1]
pyplot.imshow(np.flipud(Pxx_dB), extent=ex1)
pyplot.axis('auto')
pyplot.axis(ex1)
pyplot.xlabel('time (s)')
pyplot.ylabel('freq (Hz)')
``````

I "think" that the information is in Pxx but I don't know how to get it.

-

Then find the 4 maxima. Unfortunately, each of those 4 frequencies has a finite width, so simply looking for the top 4 maxima will nog be as easy. However, assuming your signal is quite clean, there's a function in `scipy.signal` that will list all local extrema: argrelmax. You could play with the `order` argument of that function to reduce your search space.
With the values returned from that function, you could get the frequencies like this: `freqs[those_4_indices]`.
Sorry, that was a bad assumption on my part. As I have no idea how long `data_all` is, I created a (random) array, which in my case turned out to give a 2D array with 512 columns (lucky shot). It's best that you obtain the shape of your `Pxx` with `Pxx.shape` of course. Then take a slice about 20% through, because that's where (in your image) the signals have started. Also, even if your signal is noisy, using `argrelmax` will work, although you might have to help it by cutting your specgram up in slices (similar to your 2nd image). –  Oliver W. Apr 7 '14 at 19:18