A human-centered design optimization approach for robotic exoskeletons through biomechanical simulation

Lelai Zhou; Yibin Li; Shaoping Bai

doi:10.1016/j.robot.2016.12.012

A human-centered design optimization approach for robotic exoskeletons through biomechanical simulation

Lelai Zhou, Yibin Li^*, Shaoping Bai

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

71 Citations (Scopus)

Abstract

A design optimization approach for exoskeletons on the basis of simulation of the exoskeleton and a human body model is proposed in this paper. The human-centered approach, addressing the problem of physical human–exoskeleton interactions, models and simulates the mechanics for the exoskeleton and the human body in concern. It allows designers to efficiently analyze and evaluate exoskeleton functions. A simulation platform is developed by integrating a musculoskeletal human body and an exoskeleton. An assistive exoskeleton for the symptom of brachial plexus injury is simulated and analyzed. Two types of passive exoskeletons with gravity-compensating capability are evaluated, and the optimal spring stiffnesses are obtained. The design analysis and optimization results demonstrate the effectiveness of the approach.

Original language	English
Journal	Robotics and Autonomous Systems
Volume	91
Pages (from-to)	337-347
Number of pages	11
ISSN	0921-8890
DOIs	https://doi.org/10.1016/j.robot.2016.12.012
Publication status	Published - 1 May 2017

Keywords

Assistive exoskeleton
Biomechanics
Human-centered design optimization
Human–robot interaction

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title = "A human-centered design optimization approach for robotic exoskeletons through biomechanical simulation",

abstract = "A design optimization approach for exoskeletons on the basis of simulation of the exoskeleton and a human body model is proposed in this paper. The human-centered approach, addressing the problem of physical human–exoskeleton interactions, models and simulates the mechanics for the exoskeleton and the human body in concern. It allows designers to efficiently analyze and evaluate exoskeleton functions. A simulation platform is developed by integrating a musculoskeletal human body and an exoskeleton. An assistive exoskeleton for the symptom of brachial plexus injury is simulated and analyzed. Two types of passive exoskeletons with gravity-compensating capability are evaluated, and the optimal spring stiffnesses are obtained. The design analysis and optimization results demonstrate the effectiveness of the approach.",

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AU - Zhou, Lelai

AU - Li, Yibin

AU - Bai, Shaoping

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N2 - A design optimization approach for exoskeletons on the basis of simulation of the exoskeleton and a human body model is proposed in this paper. The human-centered approach, addressing the problem of physical human–exoskeleton interactions, models and simulates the mechanics for the exoskeleton and the human body in concern. It allows designers to efficiently analyze and evaluate exoskeleton functions. A simulation platform is developed by integrating a musculoskeletal human body and an exoskeleton. An assistive exoskeleton for the symptom of brachial plexus injury is simulated and analyzed. Two types of passive exoskeletons with gravity-compensating capability are evaluated, and the optimal spring stiffnesses are obtained. The design analysis and optimization results demonstrate the effectiveness of the approach.

AB - A design optimization approach for exoskeletons on the basis of simulation of the exoskeleton and a human body model is proposed in this paper. The human-centered approach, addressing the problem of physical human–exoskeleton interactions, models and simulates the mechanics for the exoskeleton and the human body in concern. It allows designers to efficiently analyze and evaluate exoskeleton functions. A simulation platform is developed by integrating a musculoskeletal human body and an exoskeleton. An assistive exoskeleton for the symptom of brachial plexus injury is simulated and analyzed. Two types of passive exoskeletons with gravity-compensating capability are evaluated, and the optimal spring stiffnesses are obtained. The design analysis and optimization results demonstrate the effectiveness of the approach.

KW - Assistive exoskeleton

KW - Biomechanics

KW - Human-centered design optimization

KW - Human–robot interaction

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DO - 10.1016/j.robot.2016.12.012

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SN - 0921-8890

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EP - 347

JO - Robotics and Autonomous Systems

JF - Robotics and Autonomous Systems

ER -

A human-centered design optimization approach for robotic exoskeletons through biomechanical simulation

Abstract

Keywords

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