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面向康复机器人的新型人体肩部复合体骨骼模型及运动节律分析

A New Skeleton Model and the Motion Rhythm Analysis for Human Shoulder Complex Oriented to Rehabilitation Robotics.

作者信息

Zhibin Song, Tianyu Ma, Chao Nie, Yijun Niu

机构信息

Key Laboratory of Mechanism Theory and Equipment Design of Ministry of Education, Tianjin University, Tianjin 300072, China.

出版信息

Appl Bionics Biomech. 2018 Jun 3;2018:2719631. doi: 10.1155/2018/2719631. eCollection 2018.

DOI:10.1155/2018/2719631
PMID:29967652
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6008631/
Abstract

Rehabilitation robotics has become a widely accepted method to deal with the training of people with motor dysfunction. In robotics medium training, shoulder repeated exercise training has been proven beneficial for improving motion ability of human limbs. An important and difficult paradigm for motor function rehabilitation training is the movement rhythm on the shoulder, which is not a single joint but complex and ingenious combination of bones, muscles, ligaments, and tendons. The most robots for rehabilitation were designed previously considering simplified biomechanical models only, which led to misalignment between robots and human shoulder. Current biomechanical models were merely developed for rehabilitation robotics design. This paper proposes a new hybrid spatial model based on joint geometry constraints to describe the movement of the shoulder skeletal system and establish the position analysis equation of the model by a homogeneous coordinate transformation matrix and vector method, which can be used to calculate the kinematics of human-robot integrated system. The shoulder rhythm, the most remarkable particularity in shoulder complex kinematics and important reference for shoulder training strategy using robotics, is described and analyzed via the proposed skeleton model by three independent variables in this paper. This method greatly simplifies the complexity of the shoulder movement description and provides an important reference for the training strategy making of upper limb rehabilitation via robotics.

摘要

康复机器人技术已成为一种被广泛接受的用于对运动功能障碍患者进行训练的方法。在机器人辅助训练中,肩部重复运动训练已被证明对提高人体肢体的运动能力有益。运动功能康复训练的一个重要且困难的范例是肩部的运动节奏,肩部并非单个关节,而是骨骼、肌肉、韧带和肌腱的复杂精妙组合。此前设计的大多数康复机器人仅考虑简化的生物力学模型,这导致机器人与人体肩部不匹配。当前的生物力学模型仅仅是为康复机器人设计而开发的。本文提出一种基于关节几何约束的新型混合空间模型,用于描述肩部骨骼系统的运动,并通过齐次坐标变换矩阵和矢量法建立该模型的位置分析方程,可用于计算人机集成系统的运动学。本文通过所提出的骨骼模型,利用三个独立变量对肩部运动节奏进行了描述和分析,肩部运动节奏是肩部复杂运动学中最显著的特性,也是使用机器人进行肩部训练策略的重要参考。该方法极大地简化了肩部运动描述的复杂性,为通过机器人进行上肢康复的训练策略制定提供了重要参考。

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