pyaudioclassification

Dead simple audio classification


Keywords
simple, audio, classification, audio-classification, audio-processing, keras, neural-network
License
MIT
Install
pip install pyaudioclassification==0.1.9

Documentation

pyAudioClassification

Dead simple audio classification

PyPI - Python Version PyPI

Who is this for? 👩‍💻 👨‍💻

People who just want to classify some audio quickly, without having to dive into the world of audio analysis. If you need something a little more involved, check out pyAudioAnalysis or panotti

Quick install

pip install pyaudioclassification

Requirements

  • Keras
  • Tensorflow
  • librosa
  • NumPy
  • Soundfile
  • tqdm

Quick start

from pyaudioclassification import feature_extraction, train, predict
features, labels = feature_extraction(<data_path>)
model = train(features, labels)
pred = predict(model, <data_path>)

Or, if you're feeling reckless, you could just string them together like so:

pred = predict(train(feature_extraction(<training_data_path>)), <prediction_data_path>)

A full example with saving, loading & some dummy data can be found here

Read below for a more detailed look at each of these calls.

Detailed Guide

Step 1: Preprocessing 🐶 🐱

First, add all your audio files to a directory in the following structure

data/
├── <class_name>/
│   ├── <file_name>
│   └── ...
└── ...

For example, if you were trying to classify dog and cat sounds it might look like this

data/
├── cat/
│   ├── cat1.ogg
│   ├── cat2.ogg
│   ├── cat3.wav
│   └── cat4.wav
└── dog/
    ├── dog1.ogg
    ├── dog2.ogg
    ├── dog3.wav
    └── dog4.wav

Great, now we need to preprocess this data. Just call feature_extraction(<data_path>) and it'll return our input and target data. Something like this:

features, labels = feature_extraction('/Users/mac2015/data/')

(If you don't want to print to stdout, just pass verbose=False as a argument)


Depending on how much data you have, this process could take a while... so it might be a good idea to save. You can save and load with NumPy

np.save('%s.npy' % <file_name>, features)
features = np.load('%s.npy' % <file_name>)

Step 2: Training 💪

Next step is to train your model on the data. You can just call...

model = train(features, labels)

...but depending on your dataset, you might need to play around with some of the hyper-parameters to get the best results.

Options

  • epochs: The number of iterations. Default is 50.

  • lr: Learning rate. Increase to speed up training time, decrease to get more accurate results (if your loss is 'jumping'). Default is 0.01.

  • optimiser: Choose any of these. Default is 'SGD'.

  • print_summary: Prints a summary of the model you'll be training. Default is False.

  • loss_type: Classification type. Default is categorical for >2 classes, and binary otherwise.

You can add any of these as optional arguments, for example train(features, labels, lr=0.05)


Again, you probably want to save your model once it's done training. You can do this with Keras:

from keras.models import load_model

model.save('my_model.h5')
model = load_model('my_model.h5')

Step 3: Prediction 🙏 🙌

Now the fun part- try your trained model on new data!

pred = predict(model, <data_path>)

Your <data_path> should point to a new, untested audio file.

Binary

If you have 2 classes (or if you force selected 'binary' as a type), pred will just be a single number for each file.

The closer it is to 0, the closer the prediction is for the first class, and the closer it is to 1 the closer the prediction is to the second class.

So for our cat/dog example, if it returns 0.2 it's 80% sure the sound is a cat, and if it returns 0.8 it's 80% sure it's a dog.

Categorical

If you have more than 2 classes (or if you force selected 'categorical' as a type), pred will be an array for each sound file.

It'll look something like this

[[1.6454633e-06 3.7017996e-11 9.9999821e-01 1.5900606e-07]]

The index of each item in the array will correspond to the prediction for that class.


You can pretty print the predictions by showing them in a leaderboard, like so:

print_leaderboard(pred, <training_data_path>)

It looks like this:

1. Cow 100.0% (index 2)
2. Rooster 0.0% (index 0)
3. Frog 0.0% (index 3)
4. Pig 0.0% (index 1)

References