# Scipy Spectrogram vs. multiple Numpy FFT's

I'm attempting to optimize some code I was given wherein the FFT is taken of a sliding window over a time series (given as a list) and each result is accumulated into a list. The original code is as follows:

``````def calc_old(raw_data):
FFT_old = list()

for i in range(0, len(raw_data), bf.WINDOW_STRIDE_LEN):
if (i + bf.WINDOW_LEN) >= len(raw_data):
# Skip the windows that would extend beyond the end of the data
continue

data_tmp = raw_data[i:i+bf.WINDOW_LEN]
data_tmp -= np.mean(data_tmp)
data_tmp = np.multiply(data_tmp, np.hanning(len(data_tmp)))
fft_data_tmp = abs(fft_data_tmp[:int(len(fft_data_tmp)/2)])**2
FFT_old.append(fft_data_tmp)
``````

And the new code:

``````def calc_new(raw_data):
data = np.array(raw_data)  # Required as the data is being handed in as a list
f, t, FFT_new = spectrogram(data,
fs=60.0,
window="hann",
nperseg=bf.WINDOW_LEN,
noverlap=bf.WINDOW_OVERLAP,
scaling='spectrum')
``````

In summary, the old code windows the time series, removes the mean, applies a Hann windowing function, takes the FFT (while zero-padding, as `ZERO_PAD_LEN>WINDOW_LEN`), and then takes the absolute value of the real half and squares it to produce a power spectrum (Units of V**2). It then shifts the window by the `WINDOW_STRIDE_LEN`, and repeats the process until the window would extend beyond the end of the data. This has an overlap of `WINDOW_OVERLAP`.

The spectrogram, so far as I can tell, should do the same thing with the arguments I have given. However, the resulting dimensions of the FFT's differ by 1 for each axis (e.g. old code is MxN, new code is (M+1)x(N+1)) and the value in each frequency bin is massively different -- several orders of magnitude, in some cases.

What am I missing here?

• Is one result a scaled version of the other? There could be a difference in normalization. But that is not important, it is the shape of the output that matters. Aug 17, 2018 at 16:49

Scaling

The implementation in `calc_old` uses the output from `np.fft.fft` directly without any scaling.

On the other hand the implementation `calc_new` uses `scipy.signal.spectrogram` which ultimately uses `np.fft.rfft` but also scales the results based on the received `scaling` and `return_onesided` arguments. More specifically:

• For the default `return_onesided=True` (since you haven't provided an explicit value in `calc_new`), the value of each bin is doubled to count the total energy including the symmetric bin.
• For the provided `scaling='spectrum'`, the values are further scaled by the factor `1.0/win.sum()**2`. For the selected Hann window, that correspond to `4/N**2` where `N=bf.WINDOW_LEN` is the window length.

You may thus expect the new implementation `cald_new` to give you a result that is scaled by an overall factor of `8/bf.WINDOW_LEN**2` compared with `calc_old`. Alternatively if you want your second implementation to give the same scaling as `calc_old` you should multiply the result of `scipy.signal.spectrogram` by `0.125 * bf.WINDOW_LEN**2`.

Number of frequency bins

Given an even number of points `nperseg`, your initial implementation `calc_old` keeps only `nperseg//2` frequency bins.

On the other hand the complete non-redundant half spectrum should give you `nperseg//2 + 1` frequency bin (there are `nperseg-2` bins with corresponding symmetry plus 2 asymmetric bins at 0Hz and the Nyquist rate, so keeping the non-redundant part leave you with `(nperseg-2)//2 + 2 == nperseg//2 + 1`). That is what `scipy.signal.spectrogram` returns.

In other words your initial implementation `calc_old` is missing the Nyquist frequency bin.

Number of time steps

The implementation in `calc_old` skips the last time step if there are less than `bf.WINDOW_LEN` samples left for the last time step computation. It would not skip these samples only occurs whenever `len(raw_data)-bf.WINDOW_STRIDE_LEN` is an exact multiple of `bf.WINDOW_LEN`. I'm guessing that isn't the case with your specific input sequence.

In contrast, `scipy.signal.spectrogram` pads the data with extra samples if required such that all inputs samples are used during the spectrogram computation, and that may result in one extra time step compared with your `calc_old` implementation.

• This confirms everything my coworker and I suspected and were looking into, especially the time step padding, which I don't see as documented anywhere? We're now getting matching results (and much faster), thanks! Aug 20, 2018 at 15:51

Probably someone could know the reason, why I get a little discrepancy when comparing spectrogram results with manual FFT?

``````# Parametrs of signal and its preprocessing
sample_rate = 4
window_size = 512 * sample_rate
detrend = 'linear'
tukey_alpha = 0.25
[![enter image description here][1]][1]
# Spectrogram
f, t, S = scipy.signal.spectrogram(signal, sample_rate, nperseg=window_size, noverlap=sample_rate, scaling='spectrum', mode='magnitude', detrend=detrend)

# FFT on the leftmost window of signal
windowed_signal = signal[:window_size]
windowed_signal = scipy.signal.detrend(windowed_signal, type=detrend)
windowed_signal *= scipy.signal.windows.tukey(window_size, tukey_alpha)
A = np.fft.rfft(windowed_signal)
freqs = np.fft.rfftfreq(window_size) * sample_rate
positive_freqs_n = int(np.ceil(window_size / 2.))
freqs_slice = slice(0, positive_freqs_n)
magnitudes = np.abs(A)[freqs_slice] / window_size

# Plotting
plt.plot(f, S.T[0], label='First window from scipy.signal.spectrogram')
plt.plot(freqs[freqs_slice], magnitudes, alpha=0.5, label='np.fft on first window')
plt.yscale('log')
plt.xscale('log')
plt.legend()
plt.xlabel('Frequency, Hz')
plt.ylabel('Magnitude')
``````

Where this small vertical disagreement could result from? Thank you!