Human-in-the-Loop Modeling and Bilateral Skill Transfer Control of Soft Exoskeleton

Soft exoskeletons (exosuits) are expected to provide a comfortable wearing experience and compliant assistance compared with traditional rigid exoskeleton robots. In this paper, an exosuit with twisted string actuators (TSAs) is developed to provide high-strength and variable-stiffness actuation for...

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Published in	Sensors (Basel, Switzerland) Vol. 24; no. 23; p. 7845
Main Authors	Xu, Jiajun, Huang, Kaizhen, Zhao, Mengcheng, Liu, Jinfu
Format	Journal Article
Language	English
Published	Switzerland MDPI AG 08.12.2024 MDPI
Subjects	Actuators adaptive impedance control Algorithms Ankle Biomechanical Phenomena - physiology Cables Comparative analysis Controllers Design Exoskeleton Device Friction Hemiplegia - rehabilitation Humans Knee Movement - physiology Paralysis reinforcement learning Robotics Robotics - methods Robots skill transfer soft exoskeleton skill transfer adaptive impedance control reinforcement learning soft exoskeleton
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ISSN	1424-8220 1424-8220
DOI	10.3390/s24237845

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Abstract	Soft exoskeletons (exosuits) are expected to provide a comfortable wearing experience and compliant assistance compared with traditional rigid exoskeleton robots. In this paper, an exosuit with twisted string actuators (TSAs) is developed to provide high-strength and variable-stiffness actuation for hemiplegic patients. By formulating the analytic model of the TSA and decoding the human impedance characteristic, the human-exosuit coupled dynamic model is constructed. An adaptive impedance controller is designed to transfer the skills of the patient’s healthy limb (HL) to the bilateral impaired limb (IL) with a mirror training strategy, including the movement trajectory and stiffness profiles. A reinforcement learning (RL) algorithm is proposed to optimize the robotic assistance by adapting the impedance model parameters to the subject’s performance. Experiments are conducted to demonstrate the effectiveness and superiority of the proposed method.
AbstractList	Soft exoskeletons (exosuits) are expected to provide a comfortable wearing experience and compliant assistance compared with traditional rigid exoskeleton robots. In this paper, an exosuit with twisted string actuators (TSAs) is developed to provide high-strength and variable-stiffness actuation for hemiplegic patients. By formulating the analytic model of the TSA and decoding the human impedance characteristic, the human-exosuit coupled dynamic model is constructed. An adaptive impedance controller is designed to transfer the skills of the patient’s healthy limb (HL) to the bilateral impaired limb (IL) with a mirror training strategy, including the movement trajectory and stiffness profiles. A reinforcement learning (RL) algorithm is proposed to optimize the robotic assistance by adapting the impedance model parameters to the subject’s performance. Experiments are conducted to demonstrate the effectiveness and superiority of the proposed method. Soft exoskeletons (exosuits) are expected to provide a comfortable wearing experience and compliant assistance compared with traditional rigid exoskeleton robots. In this paper, an exosuit with twisted string actuators (TSAs) is developed to provide high-strength and variable-stiffness actuation for hemiplegic patients. By formulating the analytic model of the TSA and decoding the human impedance characteristic, the human-exosuit coupled dynamic model is constructed. An adaptive impedance controller is designed to transfer the skills of the patient's healthy limb (HL) to the bilateral impaired limb (IL) with a mirror training strategy, including the movement trajectory and stiffness profiles. A reinforcement learning (RL) algorithm is proposed to optimize the robotic assistance by adapting the impedance model parameters to the subject's performance. Experiments are conducted to demonstrate the effectiveness and superiority of the proposed method.Soft exoskeletons (exosuits) are expected to provide a comfortable wearing experience and compliant assistance compared with traditional rigid exoskeleton robots. In this paper, an exosuit with twisted string actuators (TSAs) is developed to provide high-strength and variable-stiffness actuation for hemiplegic patients. By formulating the analytic model of the TSA and decoding the human impedance characteristic, the human-exosuit coupled dynamic model is constructed. An adaptive impedance controller is designed to transfer the skills of the patient's healthy limb (HL) to the bilateral impaired limb (IL) with a mirror training strategy, including the movement trajectory and stiffness profiles. A reinforcement learning (RL) algorithm is proposed to optimize the robotic assistance by adapting the impedance model parameters to the subject's performance. Experiments are conducted to demonstrate the effectiveness and superiority of the proposed method.
Audience	Academic
Author	Liu, Jinfu Xu, Jiajun Zhao, Mengcheng Huang, Kaizhen
AuthorAffiliation	2 Changzhou Vocational Institute of Industry Technology, Changzhou 213164, China 1 College of Mechanical and Electrical Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China; huangkaizhen@nuaa.edu.cn (K.H.); zhaomengcheng@nuaa.edu.cn (M.Z.)
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SubjectTerms	Actuators adaptive impedance control Algorithms Ankle Biomechanical Phenomena - physiology Cables Comparative analysis Controllers Design Exoskeleton Device Friction Hemiplegia - rehabilitation Humans Knee Movement - physiology Paralysis reinforcement learning Robotics Robotics - methods Robots skill transfer soft exoskeleton
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Title	Human-in-the-Loop Modeling and Bilateral Skill Transfer Control of Soft Exoskeleton
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