Estimation of Joint Angle From sEMG and Inertial Measurements Based on Deep Learning Approach

Continuous kinematics estimation from surface electromyography (sEMG) allows more natural and intuitive human-machine collaboration. Recent research has suggested the use of multimodal inputs (sEMG signals and inertial measurements) to improve estimation performance. This work focused on assessing t...

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Main Authors: Delgado, Alfredo Lobaina, Da Rocha, Adson F., Leon, Alexander Suarez, Ruiz-Olaya, Andres, Montero, Klaus Ribeiro, Delis, Alberto Lopez
Format: Conference Proceeding
Language:English
Subjects:
Angle estimation
angular velocity
Deep Learning
Electromyography
Estimation
Grasping
Hand
Humans
inertial measurements
Kinematics
Muscle, Skeletal
Neural Networks, Computer
recurrent and convolutional neural networks (RCNN)
Recurrent neural networks
surface electromyography (sEMG)
Transfer learning
transfer learning (TL)
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container_volume 2021
creator Delgado, Alfredo Lobaina
Da Rocha, Adson F.
Leon, Alexander Suarez
Ruiz-Olaya, Andres
Montero, Klaus Ribeiro
Delis, Alberto Lopez
description Continuous kinematics estimation from surface electromyography (sEMG) allows more natural and intuitive human-machine collaboration. Recent research has suggested the use of multimodal inputs (sEMG signals and inertial measurements) to improve estimation performance. This work focused on assessing the use of angular velocity in combination with myoelectric signals to simultaneously and continuously predict 12 joint angles in the hand. Estimation performance was evaluated for five functional and grasping movements in 20 subjects. The proposed method is based on convolutional and recurrent neural networks using transfer learning (TL). A novel aspect was the use of a pretrained deep network model from basic joint hand movements to learn new patterns present in functional motions. A comparison was carried out with the traditional method based solely on sEMG. Although the performance of the algorithm slightly improved with the use of the multimodal combination, both strategies had similar behavior. The results indicated a significant improvement for a single task: opening a bottle with a tripod grasp.
doi_str_mv 10.1109/EMBC46164.2021.9630609
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source IEEE Xplore All Conference Series
subjects Angle estimation
angular velocity
Deep Learning
Electromyography
Estimation
Grasping
Hand
Humans
inertial measurements
Kinematics
Muscle, Skeletal
Neural Networks, Computer
recurrent and convolutional neural networks (RCNN)
Recurrent neural networks
surface electromyography (sEMG)
Transfer learning
transfer learning (TL)
title Estimation of Joint Angle From sEMG and Inertial Measurements Based on Deep Learning Approach
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