An innovative equivalent kinematic model of the human upper limb to improve the trajectory planning of exoskeleton rehabilitation robots

Upper limb exoskeleton rehabilitation robots have been attracting significant attention by researchers due to their adaptive training, highly repetitive motion, and ability to enhance the self-care capabilities of patients with disabilities. It is a key problem that the existing upper limb exoskelet...

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Bibliographic Details
Published inMechanical sciences (Göttingen) Vol. 12; no. 1; pp. 661 - 675
Main Authors Xie, Qiaolian, Meng, Qiaoling, Zeng, Qingxin, Yu, Hongliu, Shen, Zhijia
Format Journal Article
LanguageEnglish
Published Gottingen Copernicus GmbH 15.06.2021
Copernicus Publications
Subjects
Activities of daily living
Analysis
Biomechanics
Disabilities
Elbow (anatomy)
Equivalence
Exoskeletons
Human mechanics
Human motion
Kinematics
Range of motion
Rehabilitation
Rehabilitation robots
Robotics industry
Robots
Self-care, Health
Trajectory planning
Wrist
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Summary:Upper limb exoskeleton rehabilitation robots have been attracting significant attention by researchers due to their adaptive training, highly repetitive motion, and ability to enhance the self-care capabilities of patients with disabilities. It is a key problem that the existing upper limb exoskeletons cannot stay in line with the corresponding human arm during exercise. The aim is to evaluate whether the existing upper limb exoskeleton movement is in line with the human movement and to provide a design basis for the future exoskeleton. This paper proposes a new equivalent kinematic model for human upper limb, including the shoulder joint, elbow joint, and wrist joint, according to the human anatomical structure and sports biomechanical characteristics. And this paper analyzes the motion space according to the normal range of motion of joints for building the workspace of the proposed model. Then, the trajectory planning for an upper limb exoskeleton is evaluated and improved based on the proposed model. The evaluation results show that there were obvious differences between the exoskeleton prototype and human arm. The deviation between the human body and the exoskeleton of the improved trajectory is decreased to 41.64 %. In conclusion, the new equivalent kinematics model for the human upper limb proposed in this paper can effectively evaluate the existing upper limb exoskeleton and provide suggestions for structural improvements in line with human motion.
ISSN:2191-916X
2191-9151
2191-916X
DOI:10.5194/ms-12-661-2021