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Enhancing Home Physiotherapy: Machine Learning for Exercise Recognition and Error Detection

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Enhancing Home Physiotherapy: Machine Learning for Exercise Recognition and Error Detection

Project Overview

Building upon David Rode’s research in Markerless Motion Capturing and Pose Estimation for therapeutic applications.

Project Goals

  1. Correctly guess performed exercises based on joint positions over time.
  2. Detect potential mistakes in exercise executions.
  3. Investigate influencing factors on prediction errors.

Project structure

The repository is organized as follows. You can find descriptions of each section below.

  • The core project with preprocessing.ipynb, Main_model.ipynb and ethics_MLP.ipynb
  • Folder Other_models with notebooks for each remaining model (take them out of the folder before running them)
  • Folder paths where you will find the main trained models
  • A helpers.py with few methods to make notebooks clearer.

Downloads

Reproduce results by downloading datasets from this link.

Reproducing the Models

We will describe how to reproduce our results for the main models. If you are only interested in our best result, you can ignore the following subsections: Other MLP models, CNNs, RNN/LSTM and Decision trees.

Preprocessing

If you want to reproduce our preprocessing, you should download the file dataset.parquet, and follow the steps of this section. Otherwise you can directly download the preprocessed datasets called train_set_augmented.parquet & test_set.parquet.

  • Open the notebook preprocessing.ipynb.
  • Change the local_path variable to the path of dataset.parquet.
  • Run every cell

This will:

  • Crop first 2 seconds of each video, and last second of the videos.
  • Erase rows consisting of more than 20 consecutive Nans, as explained in the report.
  • Linearly interpolate rows consisting of less the 20 consecutive Nans, to predict these missing values.
  • Split the dataset into unbiased train and test sets. 20% of participants are taken in test set.
  • Perform data augmentation of train set to rebalance the train set, and make it robut to noisy data.

Exercise predictions

For this part, you will need to download test_set.parquet and train_set_augmented.parquet.

For the first task of predicting exercises, we used mlp3x256. To reproduce it:

  • Open Main_model.ipynb.
  • Change train_path and test_path to your path to train_set_augmented.parquet and test_set.parquet, respectively.
  • Set train_eval to True for retraining, False for evaluation.
  • Set is_augmented to False if you want to train our model without data augmentation in train set.
  • Run cells in "First section" and "Training the model to predict exercises to train or evaluate (print accuracies)

Error Set Predictions

PhysioMLP - Best Model

For the second task, we created a model called PhysioMLP. To reproduce it:

  • Open Main_model.ipynb.
  • Change train_path and test_path to your path to train_set_augmented.parquet and test_set.parquet, respectively.
  • Set train_eval to True for retraining, False for evaluation.
  • Set is_augmented to False if you want to train our model without data augmentation in train set.
  • Run cells in "First section" and "Training the model to predict sets" to train or evaluate (print accuracies)

Other MLP models

In this section we have many other MLP models that we tested, to reproduce them:

  • Open MLP_training.ipynb.
  • Change train_path and test_path to your path to train_set_augmented.parquet and test_set.parquet, respectively.
  • Set is_augmented to False if you want to train our model without data augmentation in train set.
  • Depending on what MLP model you want to train, you might need to change the model variable with your desired MLP model.
  • Run every cell, and it will train the model.
CNNs

To reproduce this model:

  • Open CNN_training.ipynb.
  • Change train_path and test_path to your path to train_set_augmented.parquet and test_set.parquet, respectively.
  • Set is_augmented to False if you want to train our model without data augmentation in train set.
  • Depending on what CNN model you want to train, you might need to change the model variable from get_cnn2b() to get_cnn3b()
  • Run every cell, and it will train the model.

RNN/LSTM

To reproduce this model:

  • Open RNN_LSTM.ipynb.
  • Change train_path and test_path to your path to train_set_augmented.parquet and test_set.parquet, respectively.
  • Run the notebook, the test accuracy will be printed in the last cell.

Random Forest

To reproduce this model:

  • Open Random_Forest.ipynb.
  • Change prep_path to your path to prep_dataset.parquet.
  • Change train_path and test_path to your path to train_set_augmented.parquet and test_set.parquet, respectively.
  • Run cells in "Import and paths" and "Machine Learning" to both train and evaluate the model

Ethical Study

To reproduce the results of this part, you will need to download slow_test.parquet, fast_test.parquet.

  • Open ethics_MLP.ipynb.
  • Change paths for ethical study.
  • Run every cell for displaying accuracies.

External Libraries Used

Library Version Purpose
Numpy 1.25.2 Algebra
Pandas 2.0.3 Data Manipulation
Seaborn 0.12.2 Plot
Matplotlib 3.7.2 Plot
PyTorch 2.0.1 Neural Networks
Keras 2.10.0 LSTM Model
Scikit-learn 1.3.0 Random Forest and ML Classics

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