Design and Verification of Parallel Hip Exoskeleton Considering Output Torque Anisotropy

IF 4.9 3区 计算机科学 Q1 ENGINEERING, MULTIDISCIPLINARY
Jilong Xu, Yunzhan Niu, Fucai Liu
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引用次数: 0

Abstract

In rehabilitation training, it is crucial to consider the compatibility between exoskeletons and human legs in motion. However, most exoskeletons today adopt an anthropomorphic serial structure, which results in rotational centers that are not precisely aligned with the center of the hip joint. To address this issue, we introduce a novel exoskeleton called the Parallel Hip Exoskeleton (PH-Exo) in this paper. PH-Exo is meticulously designed based on the anisotropic law of output torque. Considering the friction of the drive components, a dynamic model of the human–machine complex is established. Simulation analysis demonstrates that PH-Exo not only exhibits outstanding torque performance but also achieves high controllability in both flexion/extension and adduction/abduction directions. Additionally, a robust controller is designed to address model uncertainty, friction, and external interference. Wearing experiments indicate that under the control of the robust controller, each motor achieves excellent tracking performance.

Abstract Image

考虑输出扭矩各向异性的平行髋关节外骨骼的设计与验证
在康复训练中,考虑外骨骼与运动中的人腿之间的兼容性至关重要。然而,目前大多数外骨骼都采用拟人化的序列结构,这导致旋转中心与髋关节中心并不精确对齐。为了解决这个问题,我们在本文中介绍了一种名为平行髋关节外骨骼(PH-Exo)的新型外骨骼。PH-Exo 是根据输出扭矩的各向异性规律精心设计的。考虑到驱动部件的摩擦,建立了人机复合体的动态模型。仿真分析表明,PH-Exo 不仅具有出色的扭矩性能,而且在屈/伸和内收/外展两个方向上都具有很高的可控性。此外,还设计了一个鲁棒控制器来解决模型不确定性、摩擦和外部干扰等问题。佩戴实验表明,在鲁棒控制器的控制下,每个电机都能实现出色的跟踪性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Bionic Engineering
Journal of Bionic Engineering 工程技术-材料科学:生物材料
CiteScore
7.10
自引率
10.00%
发文量
162
审稿时长
10.0 months
期刊介绍: The Journal of Bionic Engineering (JBE) is a peer-reviewed journal that publishes original research papers and reviews that apply the knowledge learned from nature and biological systems to solve concrete engineering problems. The topics that JBE covers include but are not limited to: Mechanisms, kinematical mechanics and control of animal locomotion, development of mobile robots with walking (running and crawling), swimming or flying abilities inspired by animal locomotion. Structures, morphologies, composition and physical properties of natural and biomaterials; fabrication of new materials mimicking the properties and functions of natural and biomaterials. Biomedical materials, artificial organs and tissue engineering for medical applications; rehabilitation equipment and devices. Development of bioinspired computation methods and artificial intelligence for engineering applications.
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