# Preface

Sorry, I don’t have whichever 💸-toolbox-💰 that Mathworks puts `spectrogram`

in, but here’s some code that I put in the public domain that does the job for me.

It’s more hands-on than `spectrogram`

but has many of the latter’s features, as I’ll demonstrate using the `handel`

audio clip that comes with Matlab (‘Hallelujah!’).

# Setup

I won’t assume you’re familiar with git or Matlab namespaces.

- Create a directory called
`+arf`

somewhere in your Matlab path (e.g., `~/Documents/MATLAB`

or even your current code directory).
- Download
`stft.m`

and put it in `+arf/`

.
- Also download
`partition.m`

into `+arf/`

.

This creates an `arf`

namespace inside which are the `arf.stft`

and `arf.partition`

functions (the latter is used by `arf.stft`

).

# Code

```
clearvars
% Load data: this is an audio clip built into Matlab.
handel = load('handel');
% To hear this audio clip, run the following:
% >> soundsc(handel.y, handel.Fs)
% STFT parameters.
% 1000 samples is roughly 1/8th of a second. A reasonable chunk size.
samplesPerChunk = 1000;
% Overlap a lot between chunks to see a smooth STFT.
overlapSamples = round(samplesPerChunk * 0.9);
% Generate STFT
[stftArr, fVec, tVec] = arf.stft(handel.y, ...
samplesPerChunk, ...
'noverlap', overlapSamples, ...
'fs', handel.Fs);
% Plot results
figure('color', 'white');
imagesc(fVec / 1e3, tVec, 20 * log10(abs(stftArr)).');
axis xy
colorbar
xlabel('frequency (KHz)')
ylabel('time (s)')
caxis(max(caxis) - [40 0])
title('`handel` spectrogram via STFT, top 40 dB')
```

The code above

- loads the
`handel`

audio clip that’s packaged into Matlab (this is a nine-second clip from George Frideric Handel’s *Messiah*),
- defines some parameters for the STFT,
- evaluates the STFT with
`arf.stft()`

, and
- plots the STFT.

Hint: after you run the code above, or just that `load`

line, you can listen to the original clip with `soundsc(handel.y, handel.Fs)`

.

# Results

In the spectrogram, you can clearly see the first two long Hallelujah’s, then the two shorter ones, and then finally the last long one. Time runs along the y-axis as you wished.

The code demonstrates how to specify the chunk length (here, 1000 samples, or ≈⅛ seconds) and the amount of overlap (90% of the chunk length, so 900 samples of overlap). Note:

- Larger chunk length will result in less resolution in time (but greater resolution in frequency).
- The less overlap, the more jaggedy and less smooth the STFT appears along time (and the less computational/memory overhead you pay). The amount of overlap must be between 0 (no overlap between chunks) and
`chunk size - 1`

.

If you just play around with the chunk length, you’ll get a feel for the main knob the STFT gives you to tune. Usually one picks overlap between 25% or 50% of chunk size for reasonably-smooth spectrograms without a huge amount of computational overhead.

N.B. You can increase smoothness along the *frequency* dimension by passing in an extra argument to `arf.stft`

, specifically, `arf.stft( ..., 'nfft', 2^nextpow2(samplesPerChunk * 8))`

. This explicitly sets the number of frequency bins to create (eventually, an FFT of this size is evaluated). The default is equivalent to `2^nextpow2(samplesPerChunk)`

, so multiplying it by eight will upsample the spectrum for each chunk eight-fold.

`windowSize`

. 256 samples even at 8 KHz is just 30 milliseconds. Try enough samples for 1–3 seconds, that’s closer to what the second “authoritative” spectrogram uses.