### Forewords

As `xdurch0`

pointed out, you are reading a kind of index instead of a frequency. If you are about to make all computation by yourself you need to compute you own frequency vector before plotting if you want to get consistent result. Reading this answer may help you towards the solution.

The frequency vector for FFT (half plane) is:

```
f = np.linspace(0, rate/2, N_fft/2)
```

Or (full plane):

```
f = np.linspace(-rate/2, rate/2, N_fft)
```

On the other hand we can delegate most of the work to the excellent `scipy.signal`

toolbox which aims to cope with this kind of problems (and many more).

### MCVE

Using `scipy`

package it is straight forward to get the desired result for a simple `WAV`

file with a single frequency (source):

```
import numpy as np
from scipy import signal
from scipy.io import wavfile
import matplotlib.pyplot as plt
# Read the file (rate and data):
rate, data = wavfile.read('tone.wav') # See source
# Compute PSD:
f, P = signal.periodogram(data, rate) # Frequencies and PSD
# Display PSD:
fig, axe = plt.subplots()
axe.semilogy(f, P)
axe.set_xlim([0,500])
axe.set_ylim([1e-8, 1e10])
axe.set_xlabel(r'Frequency, $\nu$ $[\mathrm{Hz}]$')
axe.set_ylabel(r'PSD, $P$ $[\mathrm{AU^2Hz}^{-1}]$')
axe.set_title('Periodogram')
axe.grid(which='both')
```

Basically:

This outputs:

### Find Peak

Then we can find the frequency of the first highest peak (`P>1e-2`

, this criterion is subject to tuning) using `find_peaks`

:

```
idx = signal.find_peaks(P, height=1e-2)[0][0]
f[idx] # 440.0 Hz
```

Putting all together it merely boils down to:

```
def freq(filename, setup={'height': 1e-2}):
rate, data = wavfile.read(filename)
f, P = signal.periodogram(data, rate)
return f[signal.find_peaks(P, **setup)[0][0]]
```

### Handling multiple channels

I tried this code with my wav file, and got the error for the line
axe.semilogy(f, Pxx_den) as follows : ValueError: x and y must have
same first dimension. I checked the shapes and f has (2,) while
Pxx_den has (220160,2). Also, the Pxx_den array seems to have all
zeros only.

Wav file can hold multiple channels, mainly there are mono or stereo files (max. `2**16 - 1`

channels). The problem you underlined occurs because of multiple channels file (stereo sample).

```
rate, data = wavfile.read('aaaah.wav') # Shape: (46447, 2), Rate: 48 kHz
```

*It is not well documented*, but the method `signal.periodogram`

also performs on matrix and its input is not directly consistent with `wavfile.read`

output (they perform on different axis by default). So we need to carefully orient dimensions (using `axis`

switch) when performing PSD:

```
f, P = signal.periodogram(data, rate, axis=0, detrend='linear')
```

It also works with Transposition `data.T`

but then we need to back transpose the result.

Specifying the axis solve the issue: frequency vector is correct and PSD is not null everywhere (before it performed on the `axis=1`

which is of length `2`

, in your case it performed 220160 PSD on 2-samples signals we wanted the converse).

The `detrend`

switch ensure the signal has zero mean and its linear trend is removed.

### Real application

This approach should work for real chunked samples, provided chunks hold enough data (see Nyquist-Shannon sampling theorem). Then data are sub-samples of the signal (chunks) and rate is kept constant since it does not change during the process.

Having chunks of size `2**10`

seems to work, we can identify specific frequencies from them:

```
f, P = signal.periodogram(data[:2**10,:], rate, axis=0, detrend='linear') # Shapes: (513,) (513, 2)
idx0 = signal.find_peaks(P[:,0], threshold=0.01, distance=50)[0] # Peaks: [46.875, 2625., 13312.5, 16921.875] Hz
fig, axe = plt.subplots(2, 1, sharex=True, sharey=True)
axe[0].loglog(f, P[:,0])
axe[0].loglog(f[idx0], P[idx0,0], '.')
# [...]
```

At this point, the trickiest part is the fine tuning of `find-peaks`

method to catch desired frequencies. You may need to consider to pre-filter your signal or post-process the PSD in order to make the identification easier.

`dt`

the sample lasts (for`N`

observations), then you can assess its frequency:`len(x)/dt`

.`RATE/CHUNK*INDEX`

where index is the "10" I get here (ie argmax)? <br/> Thank you both for your comments.