Frontiers in Neuroscience (Sep 2024)

iP3T: an interpretable multimodal time-series model for enhanced gait phase prediction in wearable exoskeletons

  • Hui Chen,
  • Hui Chen,
  • Hui Chen,
  • Xiangyang Wang,
  • Xiangyang Wang,
  • Yang Xiao,
  • Yang Xiao,
  • Beixian Wu,
  • Beixian Wu,
  • Zhuo Wang,
  • Zhuo Wang,
  • Zhuo Wang,
  • Yao Liu,
  • Yao Liu,
  • Yao Liu,
  • Peiyi Wang,
  • Chunjie Chen,
  • Chunjie Chen,
  • Chunjie Chen,
  • Xinyu Wu,
  • Xinyu Wu,
  • Xinyu Wu

DOI
https://doi.org/10.3389/fnins.2024.1457623
Journal volume & issue
Vol. 18

Abstract

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IntroductionWearable exoskeletons assist individuals with mobility impairments, enhancing their gait and quality of life. This study presents the iP3T model, designed to optimize gait phase prediction through the fusion of multimodal time-series data.MethodsThe iP3T model integrates data from stretch sensors, inertial measurement units (IMUs), and surface electromyography (sEMG) to capture comprehensive biomechanical and neuromuscular signals. The model's architecture leverages transformer-based attention mechanisms to prioritize crucial data points. A series of experiments were conducted on a treadmill with five participants to validate the model's performance.ResultsThe iP3T model consistently outperformed traditional single-modality approaches. In the post-stance phase, the model achieved an RMSE of 1.073 and an R2 of 0.985. The integration of multimodal data enhanced prediction accuracy and reduced metabolic cost during assisted treadmill walking.DiscussionThe study highlights the critical role of each sensor type in providing a holistic understanding of the gait cycle. The attention mechanisms within the iP3T model contribute to its interpretability, allowing for effective optimization of sensor configurations and ultimately improving mobility and quality of life for individuals with gait impairments.

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