# Computing STFT - Can't find where I'm going wrong

I'm attempting to write an algorithm to compute the STFT (Short-time Fourier transform) in C++ and plot the results in `matplotlib` in Python. I'm really struggling to see where it is I am actually going wrong, so I'm going to include all of the code that I have written.

First off, I'm calculating the STFT by the following steps:

1) Split the signal into overlapping blocks (NFFT = 256 overlap = 128)

2) Compute the FFT for each of these blocks

3) Calculate the magnitude for each block: `10 * log10(sqrt(re*re + im*im);`

This gives me a 2D vector of doubles with the results. Now, here is what the results look like:

(For now, just ignore the 'amplitudes' on the Y axis, have not plotted them yet)..

Here is the spectrogram of the same signal, but using `matplotlib`:

Notice, that I am doing something right. The energy in both charts match, it's just the in-between that is not right, also the representation.

The problem is, the spectrogram generated in the `matplotlib` file is from the library itself. The one I'm writing is from C++ and is ported through a .txt file and then plotted. This could be a potential reason why such results are being displayed.

Here is my code (note, there are a few functions, ignore the bad styling - This is a rough implementation):

``````std::vector<std::vector<double> > frame(std::vector<double> &signal, int N, int M)
{
unsigned int n = signal.size();
unsigned int num_blocks = n / N;

unsigned int maxblockstart = n - N;
unsigned int lastblockstart = maxblockstart - (maxblockstart % M);
unsigned int numbblocks = (lastblockstart)/M + 1;

std::vector<std::vector<double> > blocked(numbblocks);

for(unsigned i=0; (i < numbblocks); i++)
{
blocked[i].resize(N);

for(int j=0; (j < N); j++)
{
blocked[i][j] = signal[i*M+j];
}
}

return blocked;
}

void ComputeHanning(std::vector<double> &vect)
{
std::vector<double> hanning(vect.size());

for(unsigned i=0; (i < vect.size()); i++)
{
double value = 0.5 * (1 - cos(2 * PI * i / (vect.size() - 1)));
vect[i] = vect[i] * value;
}

}

std::vector<std::vector<Complex::complex> > ComputeSTFT(std::vector<double> &vals,
std::size_t NFFT, std::size_t overlap)
{
std::vector<std::vector<double> > temp_vars = frame(vals, NFFT, overlap);

std::for_each(temp_vars.begin(), temp_vars.end(), ComputeHanning);

std::vector<std::vector<Complex::complex> > STFT(temp_vars.size());

for(unsigned i=0; (i < temp_vars.size()); i++)
{
FFT f(temp_vars[i].begin(), temp_vars[i].end(),
temp_vars[i].size());
std::vector<Complex::complex> temp_fft = f.transformed();

STFT[i] = temp_fft;

temp_fft.empty();

}

return STFT;
``````

}

In my main I also have the following:

``````std::vector<std::vector<Complex::complex> > v = ComputeSTFT(sig, 256, 128);

std::vector<std::vector<double> > mags_of_stft(v.size());

for(unsigned i=0; (i < v.size()); i++)
{
mags_of_stft[i].resize(v[i].size());
for(unsigned j=0; (j < v[i].size()); j++)
{
mags_of_stft[i][j] = (10 * log10(sqrt(v[i][j].re * v[i][j].re + v[i]
[j].im * v[i][j].im)));
}
}
``````

The FFT is my own implementation, this works as I have tested it using a Htz algorithm, the right results came back.

Ok, now for some data.. The first block in my own STFT contains the following:

``````26.9287 26.7964 26.4222 25.9362 25.3529 24.5413 23.3444 22.6159 23.3474 24.2482 24.7409
24.8523 24.8117 24.7454 24.4842 24.1252 23.6378 22.963 22.1107 21.2459 20.559 18.9037
19.1357 22.9382 25.2215 26.4729 27.0497 27.1323 26.8312 26.1089 24.8411 22.3591 19.2829
....,
....
``````

Whereas, in the Matplotlib example, the following data is shown:

`````` 6.44554713e-04   2.26979569e-02   1.48395306e-02   1.39560086e-02
1.70585613e-02   4.24042116e-04   4.10722082e-04   1.77314474e-02
5.48046037e-03   6.86724979e-03   1.33342952e-02   5.45918807e-04
``````

I can't seem to figure out where it is exactly I'm going wrong. How these results are so different from the ones that I have. Any ideas?

Any help would be greatly appreciated.

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