Virtually offloading body mass for rehabilitation: A simulation study

2009 IEEE International Conference on Rehabilitation Robotics Pub Date : 2009-06-23 DOI:10.1109/ICORR.2009.5209493

Qi Lu, O. Ma, B. Qiao

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引用次数: 4

Abstract

This paper describes a computer simulation based investigation of an active body-weight support (BWS) technology which has a high potential of significantly improving treadmill-based locomotion rehabilitation. Using acceleration feedback and force control strategies, the active BWS system can offload not only partial body weight but also partial body mass (thus the dynamic load) of the patient who is supported by the system. As a result of the reduced mass, the patient can perform training with ease and comfort. Due to the safety requirements, the proposed technology has to be thoroughly investigated through simulation and experiment before a human subject experiment can be safely conducted. The work reported in this paper is such a simulation work. In the simulation the physical human is modeled as a multi-body system with 54 degrees of freedom. The model also predicts physical interaction of the feet with the treadmill using contact dynamics simulation. The simulation results verify that the proposed new active BWS system can dynamically and seamlessly reduce dynamic load of the patient in training.

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一项模拟研究:为康复实际上减轻了体重

本文描述了一种基于计算机模拟的主动体重支持(BWS)技术，该技术具有显著改善跑步机运动康复的巨大潜力。利用加速度反馈和力控制策略，主动BWS系统不仅可以减轻患者的部分体重，还可以减轻患者的部分体重(即动态负荷)。由于重量减少，患者可以轻松舒适地进行训练。由于安全要求，所提出的技术必须通过模拟和实验进行彻底的研究，然后才能安全地进行人体受试者实验。本文所报道的工作就是这样一个模拟工作。在仿真中，将人体建模为具有54个自由度的多体系统。该模型还使用接触动力学模拟来预测脚与跑步机的物理相互作用。仿真结果验证了所提出的新型主动BWS系统能够动态无缝地减少训练中患者的动态负荷。

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

2009 IEEE International Conference on Rehabilitation Robotics

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