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Electromyography pattern-recognition based prosthetic limb control using various machine learning techniques.

Sushil Ghildiyal1, Geetha Mani1, Ruban Nersisson1

  • 1School of Electrical Engineering, Vellore Institute of Technology, Vellore, India.

Journal of Medical Engineering & Technology
|April 20, 2022
PubMed
Summary
This summary is machine-generated.

This study introduces a machine learning approach to predict the necessary force for controlling prosthetic limbs, enhancing amputee independence. The Random Forest model demonstrated superior accuracy in force prediction for prosthetic control.

Keywords:
Electromyographymachine learningprosthetic limbservomotors

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Area of Science:

  • Biomedical Engineering
  • Rehabilitation Technology
  • Machine Learning Applications

Background:

  • Upper extremity amputation affects a significant portion of the population, impacting daily life and independence.
  • Current prosthetic limb control relies on muscle contractions, lacking precise force feedback for object manipulation.
  • Existing methods may require invasive surgical procedures for prosthetic integration.

Purpose of the Study:

  • To develop a non-invasive method for predicting the required force for prosthetic limb control.
  • To enhance the self-reliance and quality of life for individuals with amputations.
  • To utilize machine learning regression models for accurate force prediction in prosthetic applications.

Main Methods:

  • Implementation of Machine Learning (ML) regression models, including Support Vector Regressor (SVR), Linear Regression, and Random Forest.
  • Training and evaluation of models to predict the force needed to regulate voltage for servomotors in prosthetic limbs.
  • Comparative analysis of model performance for force requirement prediction.

Main Results:

  • The Random Forest model achieved highly accurate predictions for the force required to control servomotor voltage.
  • All tested ML models showed potential in predicting force requirements for prosthetic control.
  • The study highlights the efficacy of ML in improving prosthetic functionality.

Conclusions:

  • Machine learning, particularly the Random Forest model, offers a promising solution for precise force control in prosthetic limbs.
  • This approach can mitigate the limitations of current prosthetic control systems by providing better force regulation.
  • The developed method has the potential to significantly improve the user experience and functional capabilities of prosthetic devices.