A machine learning interface for isolated sequence classification algorithms in Python.
Project description
A machine learning interface for isolated sequence classification algorithms in Python.
Introduction
Sequential data is often observed in many different forms such as audio signals, stock prices, and even brain & heart signals. Such data is of particular interest in machine learning, as changing patterns over time naturally provide many interesting opportunities and challenges for classification.
Sequentia is a Python package that implements various classification algorithms for sequential data.
Some examples of how Sequentia can be used in isolated sequence classification include:
- determining a spoken word based on its audio signal or some other representation such as MFCCs,
- identifying potential heart conditions such as arrhythmia from ECG signals,
- predicting motion intent for gesture control from electrical muscle activity,
- classifying hand-written characters according to their pen-tip trajectories,
- classifying hand or head gestures from rotation or movement signals,
- classifying the sentiment of a phrase or sentence in natural language from word embeddings.
Build status
master |
dev |
---|---|
Features
Sequentia provides the following algorithms, all supporting multivariate sequences with different durations.
Classification algorithms
- Hidden Markov Models (via
hmmlearn
)
Learning with the Baum-Welch algorithm [1]- Gaussian Mixture Model emissions
- Linear, left-right and ergodic topologies
- Multi-processed predictions
- Dynamic Time Warping k-Nearest Neighbors (via
dtaidistance
)- Sakoe–Chiba band global warping constraint
- Dependent and independent feature warping (DTWD & DTWI)
- Custom distance-weighted predictions
- Multi-processed predictions
- DeepGRU: Deep Gesture Recognition Utility [2]
- Deep recurrent neural network with multiple GRU layers
- Faster training than LSTM-based networks
- Attention module for learning sub-sequence importance
Example of a classification algorithm (HMM sequence classifier)
Preprocessing methods
- Centering, standardization and min-max scaling
- Decimation and mean downsampling
- Mean and median filtering
Installation
You can install Sequentia using pip
.
pip install sequentia
Note: All tools under the sequentia.classifiers.rnn
module (i.e. DeepGRU
and collate_fn
) require a working installation of torch
(>= 1.8.0), and Sequentia assumes that you already have this installed.
Since there are many different possible configurations when installing PyTorch (e.g. CPU or GPU, CUDA version), we leave this up to the user instead of specifying particular binaries to install alongside TorchFSDD.
You can use the following if you really wish to install a CPU-only version of
torch
together with Sequentia.pip install sequentia[torch]
Click here for installation instructions for contributing to Sequentia or running the notebooks.
If you intend to help contribute to Sequentia, you will need some additional dependencies for running tests, notebooks and generating documentation.
Depending on what you intend to do, you can specify the following extras.
-
For running tests in the
/lib/test
directory:pip install sequentia[test]
-
For generating Sphinx documentation in the
/docs
directory:pip install sequentia[docs]
-
For running notebooks in the
/notebooks
directory:pip install sequentia[notebooks]
-
A full development suite which installs all of the above extras:
pip install sequentia[dev]
Documentation
Documentation for the package is available on Read The Docs.
Tutorials and examples
For detailed tutorials and examples on the usage of Sequentia, see the notebooks here.
Below are some basic examples of how univariate and multivariate sequences can be used in Sequentia.
Univariate sequences
import numpy as np, sequentia as seq
# Generate training observation sequences and labels
X, y = [
np.array([1, 0, 5, 3, 7, 2, 2, 4, 9, 8, 7]),
np.array([2, 1, 4, 6, 5, 8]),
np.array([5, 8, 0, 3, 1, 0, 2, 7, 9])
], ['good', 'good', 'bad']
# Create and fit the classifier
clf = seq.KNNClassifier(k=1, classes=('good', 'bad'))
clf.fit(X, y)
# Make a prediction for a new observation sequence
x_new = np.array([0, 3, 2, 7, 9, 1, 1])
y_new = clf.predict(x_new)
Multivariate sequences
import numpy as np, sequentia as seq
# Generate training observation sequences and labels
X, y = [
np.array([[1, 0, 5, 3, 7, 2, 2, 4, 9, 8, 7],
[3, 8, 4, 0, 7, 1, 1, 3, 4, 2, 9]]).T,
np.array([[2, 1, 4, 6, 5, 8],
[5, 3, 9, 0, 8, 2]]).T,
np.array([[5, 8, 0, 3, 1, 0, 2, 7, 9],
[0, 2, 7, 1, 2, 9, 5, 8, 1]]).T
], ['good', 'good', 'bad']
# Create and fit the classifier
clf = seq.KNNClassifier(k=1, classes=('good', 'bad'))
clf.fit(X, y)
# Make a prediction for a new observation sequence
x_new = np.array([[0, 3, 2, 7, 9, 1, 1],
[2, 5, 7, 4, 2, 0, 8]]).T
y_new = clf.predict(x_new)
Acknowledgments
In earlier versions of the package (<0.10.0), an approximate dynamic time warping algorithm implementation (fastdtw
) was used in hopes of speeding up k-NN predictions, as the authors of the original FastDTW paper [3] claim that approximated DTW alignments can be computed in linear memory and time - compared to the O(N^2) runtime complexity of the usual exact DTW implementation.
However, I was recently contacted by Prof. Eamonn Keogh (at University of California, Riverside), whose recent work [4] makes the surprising revelation that FastDTW is generally slower than the exact DTW algorithm that it approximates. Upon switching from the fastdtw
package to dtaidistance
(a very solid implementation of exact DTW with fast pure C compiled functions), DTW k-NN prediction times were indeed reduced drastically.
I would like to thank Prof. Eamonn Keogh for directly reaching out to me regarding this finding!
References
Contributors
All contributions to this repository are greatly appreciated. Contribution guidelines can be found here.
Edwin Onuonga ✉️ 🌍 |
Prhmma |
---|
Sequentia © 2019-2022, Edwin Onuonga - Released under the MIT License.
Authored and maintained by Edwin Onuonga.
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