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Main Authors: Marquardt, Charlotte, Schulz, Arne, Dezman, Miha, Kurz, Gunther, Stein, Thorsten, Asfour, Tamim
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.11061
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author Marquardt, Charlotte
Schulz, Arne
Dezman, Miha
Kurz, Gunther
Stein, Thorsten
Asfour, Tamim
author_facet Marquardt, Charlotte
Schulz, Arne
Dezman, Miha
Kurz, Gunther
Stein, Thorsten
Asfour, Tamim
contents The online adaptation of exoskeleton control based on muscle activity sensing offers a promising approach to personalizing exoskeleton behavior based on the user's biosignals. While electromyography (EMG)-based methods have demonstrated improvements in joint torque estimation, EMG sensors require direct skin contact and extensive post-processing. In contrast, force myography (FMG) measures normal forces resulting from changes in muscle volume due to muscle activity. We propose an FMG-based method to estimate knee and ankle joint torques by integrating joint angles and velocities with muscle activity data. We learn a model for joint torque estimation using Gaussian process regression (GPR). The effectiveness of the proposed FMG-based method is validated on isokinetic motions performed by ten participants. The model is compared to a baseline model that uses only joint angle and velocity, as well as a model augmented by EMG data. The results indicate that incorporating FMG into exoskeleton control can improve the estimation of joint torque for the ankle and knee joints in novel task characteristics within a single participant. Although the findings suggest that this approach may not improve the generalizability of estimates between multiple participants, they highlight the need for further research into its potential applications in exoskeleton control.
format Preprint
id arxiv_https___arxiv_org_abs_2409_11061
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Force Myography based Torque Estimation in Human Knee and Ankle Joints
Marquardt, Charlotte
Schulz, Arne
Dezman, Miha
Kurz, Gunther
Stein, Thorsten
Asfour, Tamim
Robotics
The online adaptation of exoskeleton control based on muscle activity sensing offers a promising approach to personalizing exoskeleton behavior based on the user's biosignals. While electromyography (EMG)-based methods have demonstrated improvements in joint torque estimation, EMG sensors require direct skin contact and extensive post-processing. In contrast, force myography (FMG) measures normal forces resulting from changes in muscle volume due to muscle activity. We propose an FMG-based method to estimate knee and ankle joint torques by integrating joint angles and velocities with muscle activity data. We learn a model for joint torque estimation using Gaussian process regression (GPR). The effectiveness of the proposed FMG-based method is validated on isokinetic motions performed by ten participants. The model is compared to a baseline model that uses only joint angle and velocity, as well as a model augmented by EMG data. The results indicate that incorporating FMG into exoskeleton control can improve the estimation of joint torque for the ankle and knee joints in novel task characteristics within a single participant. Although the findings suggest that this approach may not improve the generalizability of estimates between multiple participants, they highlight the need for further research into its potential applications in exoskeleton control.
title Force Myography based Torque Estimation in Human Knee and Ankle Joints
topic Robotics
url https://arxiv.org/abs/2409.11061