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Locomotion Decoding (LocoD): An Open-Source and Modular Platform for Researching Control Algorithms for Lower Limb

Bahareh Ahkami1,2, Kirstin Ahmed1,3,4,5, Morten B Kristoffersen1,6,7

  • 1Center for Bionics and Pain Research, Gothenburg, Sweden.

Applied Bionics and Biomechanics
|January 7, 2026
PubMed
Summary
This summary is machine-generated.

We developed LocoD, an open-source software platform for decoding prosthetic leg control using bioelectric signals like EMG. Combining EMG with nonbiological sensors significantly improves locomotion mode prediction accuracy.

Keywords:
biomedical signal processingelectromyogramlower limb prosthetic controlopen-source softwareprostheses

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Area of Science:

  • Biomedical Engineering
  • Rehabilitation Technology
  • Signal Processing

Background:

  • Current motorized prosthetic legs rely on nonbiological signals, limiting natural control.
  • Decoding biological signals (e.g., EMG) from residual limbs offers potential for more intuitive prosthetic control.
  • Lack of standardized methods hinders research in decoding algorithms for bioelectric signals.

Purpose of the Study:

  • To introduce LocoD, an open-source software platform for unified recording and processing of bioelectric (EMG) and nonbiological sensor data.
  • To enable research and benchmarking of control algorithms for prosthetic leg applications.
  • To validate the platform's functionality in decoding locomotion modes.

Main Methods:

  • Developed LocoD, an open-source platform for EMG and nonbiological signal processing (preprocessing, feature extraction, classification).
  • Recorded EMG, IMU, and pressure sensor data from 21 able-bodied participants during various locomotion tasks (walking, stairs, ramps).
  • Compared classification accuracy of locomotion modes using three sensor combinations: EMG+IMU+pressure sensor, EMG alone, and IMU+pressure sensor alone.

Main Results:

  • The combination of EMG, IMU, and pressure sensors achieved the highest locomotion mode prediction accuracy (93.4% ± 3.9%).
  • EMG alone resulted in lower accuracy (74.56% ± 5.8%), while IMU+pressure sensors yielded 90.77% ± 4.6%.
  • The superiority of the combined sensor approach was statistically significant (p < 0.001).

Conclusions:

  • LocoD is a validated, open-source, and modular platform for researching prosthetic leg control algorithms.
  • The platform facilitates the integration and analysis of bioelectric and nonbiological signals.
  • Findings demonstrate the enhanced accuracy of combined sensor approaches for prosthetic leg control.