A Python based library for processing audio data into features (GFCC, MFCC, spectral, chroma) and building Machine Learning models.
This was initially written using Python 3.7
, and updated several times using Python 3.8
and Python 3.9
, and has been tested to work with Python >= 3.6, <3.10.
- One way to install pyAudioProcessing and it's dependencies is from PyPI using pip
pip install pyAudioProcessing
To upgrade to the latest version of pyAudioProcessing, the following pip command can be used.
pip install -U pyAudioProcessing
- Or, you could also clone the project and get it setup
git clone [email protected]:jsingh811/pyAudioProcessing.git
cd pyAudioProcessing
pip install -e .
You can also get the requirements by running
pip install -r requirements/requirements.txt
Data structuring
Feature and Classifier model options
Pre-trained models
Extracting numerical features from audio
Building custom classification models
Audio cleaning
Audio format conversion
Audio visualization
Please refer to the Wiki for more details.
Using pyAudioProcessing in your research? Please cite as follows.
Singh, J. (2022). pyAudioProcessing: Audio Processing, Feature Extraction, and Machine Learning Modeling. In Proceedings of the Python in Science Conference. Python in Science Conference. SciPy. https://doi.org/10.25080/majora-212e5952-017
Bibtex
@InProceedings{ jyotika_singh-proc-scipy-2022,
author = { {J}yotika {S}ingh },
title = { py{A}udio{P}rocessing: {A}udio {P}rocessing, {F}eature {E}xtraction, and {M}achine {L}earning {M}odeling },
booktitle = { {P}roceedings of the 21st {P}ython in {S}cience {C}onference },
pages = { 152 - 158 },
year = { 2022 },
doi = { 10.25080/majora-212e5952-017 }
}
To cite the software version
Jyotika Singh. (2021, July 22). jsingh811/pyAudioProcessing: Audio processing, feature extraction and classification (Version v1.2.0). Zenodo. http://doi.org/10.5281/zenodo.5121041
Bibtex
@software{jyotika_singh_2021_5121041,
author = {Jyotika Singh},
title = {{jsingh811/pyAudioProcessing: Audio processing,
feature extraction and classification}},
month = jul,
year = 2021,
publisher = {Zenodo},
version = {v1.2.0},
doi = {10.5281/zenodo.5121041},
url = {https://doi.org/10.5281/zenodo.5121041}
}
You can choose between features gfcc
, mfcc
, spectral
, chroma
or any combination of those, example gfcc,mfcc,spectral,chroma
, to extract from your audio files for classification or just saving extracted feature for other uses.
You can choose between svm
, svm_rbf
, randomforest
, logisticregression
, knn
, gradientboosting
and extratrees
.
Hyperparameter tuning is included in the code for each using grid search.
The library works with data structured as per this section or alternatively with taking an input dictionary object specifying location paths of the audio files.
Let's say you have 2 classes that you have training data for (music and speech), and you want to use pyAudioProcessing to train a model using available feature options. Save each class as a directory and all the training audio .wav files under the respective class directories. Example:
.
├── training_data
├── music
│ ├── music_sample1.wav
│ ├── music_sample2.wav
│ ├── music_sample3.wav
│ ├── music_sample4.wav
├── speech
│ ├── speech_sample1.wav
│ ├── speech_sample2.wav
│ ├── speech_sample3.wav
│ ├── speech_sample4.wav
Similarly, for any test data (with known labels) you want to pass through the classifier, structure it similarly as
.
├── testing_data
├── music
│ ├── music_sample5.wav
│ ├── music_sample6.wav
├── speech
│ ├── speech_sample5.wav
│ ├── speech_sample6.wav
If you want to classify audio samples without any known labels, structure the data similarly as
.
├── data
├── unknown
│ ├── sample1.wav
│ ├── sample2.wav
There are three models that have been pre-trained and provided in this project. They are as follows.
music genre
: Contains pre-trained SVM classifier to classify audio into 10 music genres - blues, classical, country, disco, hiphop, jazz, metal, pop, reggae, rock. This classifier was trained using MFCC, GFCC, spectral, and chroma features.
musicVSspeech
: Contains pre-trained SVM classifier that classifying audio into two possible classes - music and speech. This classifier was trained using MFCC, spectral, and chroma features.
musicVSspeechVSbirds
: Contains pre-trained SVM classifier that classifying audio into three possible classes - music, speech and birds. This classifier was trained using GFCC, spectral, and chroma features.
There are three ways to specify the data you want to classify.
- Classifying a single audio file specified by input
file
.
from pyAudioProcessing.run_classification import classify_ms, classify_msb, classify_genre
# musicVSspeech classification
results_music_speech = classify_ms(file="/Users/xyz/Documents/audio.wav")
# musicVSspeechVSbirds classification
results_music_speech_birds = classify_msb(file="/Users/xyz/Documents/audio.wav")
# music genre classification
results_music_genre = classify_genre(file="/Users/xyz/Documents/audio.wav")
- Using
file_names
specifying locations of audios as follows.
# {"audios_1" : [<path to audio>, <path to audio>, ...], "audios_2": [<path to audio>, ...],}
# Examples.
file_names = {
"music" : ["/Users/abc/Documents/opera.wav", "/Users/abc/Downloads/song.wav"],
"birds": [ "/Users/abc/Documents/b1.wav", "/Users/abc/Documents/b2.wav", "/Users/abc/Desktop/birdsound.wav"]
}
file_names = {
"audios" : ["/Users/abc/Documents/opera.wav", "/Users/abc/Downloads/song.wav", "/Users/abc/Documents/b1.wav", "/Users/abc/Documents/b2.wav", "/Users/abc/Desktop/birdsound.wav"]
}
The following commands in Python can be used to classify your data.
from pyAudioProcessing.run_classification import classify_ms, classify_msb, classify_genre
# musicVSspeech classification
results_music_speech = classify_ms(file_names=file_names)
# musicVSspeechVSbirds classification
results_music_speech_birds = classify_msb(file_names=file_names)
# music genre classification
results_music_genre = classify_genre(file_names=file_names)
- Using data structured as specified in structuring guidelines and passing the parent folder path as
folder_path
input.
The following commands in Python can be used to classify your data.
from pyAudioProcessing.run_classification import classify_ms, classify_msb, classify_genre
# musicVSspeech classification
results_music_speech = classify_ms(folder_path="../data")
# musicVSspeechVSbirds classification
results_music_speech_birds = classify_msb(folder_path="../data")
# music genre classification
results_music_genre = classify_genre(folder_path="../data")
Sample results look like
{'../data/music': {'beatles.wav': {'probabilities': [0.8899067858599712, 0.011922234412695229, 0.0981709797273336], 'classes': ['music', 'speech', 'birds']}, ...}
Audio data can be trained, tested and classified using pyAudioProcessing. Please see feature options and classifier model options for more information.
Sample spoken location name dataset for spoken instances of "london" and "boston" can be found here.
Code example of using gfcc,spectral,chroma
feature and svm
classifier.
There are 2 ways to pass the training data in.
-
Using locations of files in a dictionary format as the input
file_names
. -
Passing in a
folder_path
containing sub-folders and audio. Please refer to the section on Training and Testing Data structuring to use your own data instead.
from pyAudioProcessing.run_classification import classify, train
# Training
train(
file_names={
"music": [<path to audio>, <path to audio>, ..],
"speech": [<path to audio>, <path to audio>, ..]
},
feature_names=["gfcc", "spectral", "chroma"],
classifier="svm",
classifier_name="svm_test_clf"
)
Or, to use a directory containing audios organized as in structuring guidelines, the following can be used
train(
folder_path="../data", # path to dir
feature_names=["gfcc", "spectral", "chroma"],
classifier="svm",
classifier_name="svm_test_clf"
)
The above logs files analyzed, hyperparameter tuning results for recall, precision and F1 score, along with the final confusion matrix.
To classify audio samples with the classifier you created above,
# Classify a single file
results = classify(
file = "<path to audio>",
feature_names=["gfcc", "spectral", "chroma"],
classifier="svm",
classifier_name="svm_test_clf"
)
# Classify multiple files with known labels and locations
results = classify(
file_names={
"music": [<path to audio>, <path to audio>, ..],
"speech": [<path to audio>, <path to audio>, ..]
},
feature_names=["mfcc", "gfcc", "spectral", "chroma"],
classifier="svm",
classifier_name="svm_test_clf"
)
# or you can specify a folder path as described in the training section.
The above logs the filename where the classification results are saved along with the details about testing files and the classifier used if you pass in logfile=True into the function call.
If you cloned the project via git, the following command line example of training and classification with gfcc,spectral,chroma
features and svm
classifier can be used as well. Sample data can be found here. Please refer to the section on Training and Testing Data structuring to use your own data instead.
Training:
python pyAudioProcessing/run_classification.py -f "data_samples/training" -clf "svm" -clfname "svm_clf" -t "train" -feats "gfcc,spectral,chroma"
Classifying:
python pyAudioProcessing/run_classification.py -f "data_samples/testing" -clf "svm" -clfname "svm_clf" -t "classify" -feats "gfcc,spectral,chroma" -logfile "../classifier_results"
Classification results get saved in ../classifier_results_svm_clf.json
.
This feature lets the user extract aggregated data features calculated per audio file. See feature options for more information on choices of features available.
Code example for performing gfcc
and mfcc
feature extraction can be found below.
from pyAudioProcessing.extract_features import get_features
# Feature extraction of a single file
features = get_features(
file="<path to audio>",
feature_names=["gfcc", "mfcc"]
)
# Feature extraction of a multiple files
features = get_features(
file_names={
"music": [<path to audio>, <path to audio>, ..],
"speech": [<path to audio>, <path to audio>, ..]
},
feature_names=["gfcc", "mfcc"]
)
# or if you have a dir with sub-folders and audios
# features = get_features(folder_path="data_samples/testing", feature_names=["gfcc", "mfcc"])
# features is a dictionary that will hold data of the following format
"""
{
music: {file1_path: {"features": <list>, "feature_names": <list>}, ...},
speech: {file1_path: {"features": <list>, "feature_names": <list>}, ...},
...
}
"""
To save features in a json file,
from pyAudioProcessing import utils
utils.write_to_json("audio_features.json", features)
If you cloned the project via git, the following command line example of for gfcc
and mfcc
feature extractions can be used as well. The features argument should be a comma separated string, example gfcc,mfcc
.
To use your own audio files for feature extraction, pass in the directory path containing .wav files as the -f
argument. Please refer to the format of directory data_samples/testing
or the section on Training and Testing Data structuring.
python pyAudioProcessing/extract_features.py -f "data_samples/testing" -feats "gfcc,mfcc"
Features extracted get saved in audio_features.json
.
You can convert you audio in .mp4
, .mp3
, .m4a
and .aac
to .wav
. This will allow you to use audio feature generation and classification functionalities.
In order to convert your audios, the following code sample can be used.
from pyAudioProcessing.convert_audio import convert_files_to_wav
# dir_path is the path to the directory/folder on your machine containing audio files
dir_path = "data/mp4_files"
# simply change audio_format to "mp3", "m4a" or "acc" depending on the format
# of audio that you are trying to convert to wav
convert_files_to_wav(dir_path, audio_format="mp4")
# the converted wav files will be saved in the same dir_path location.
To remove low-activity regions from your audio clip, the following sample usage can be referred to.
from pyAudioProcessing import clean
clean.remove_silence(
<path to wav file>,
output_file=<path where you want to store cleaned wav file>
)
To see time-domain view of the audios, and the spectrogram of the audios, please refer to the following sample usage.
from pyAudioProcessing import plot
# spectrogram plot
plot.spectrogram(
<path to wav file>,
show=True, # set to False if you do not want the plot to show
save_to_disk=True, # set to False if you do not want the plot to save
output_file=<path where you want to store spectrogram as a png>
)
# time-series plot
plot.time(
<path to wav file>,
show=True, # set to False if you do not want the plot to show
save_to_disk=True, # set to False if you do not want the plot to save
output_file=<path where you want to store the plot as a png>
)
Jyotika Singh
https://twitter.com/jyotikasingh_/
https://www.linkedin.com/in/jyotikasingh/