Modelling Physical Human-Robot Interface with Different Users, Cuffs, and Strapping Pressures: A Case Study.

IEEE ... International Conference on Rehabilitation Robotics : [proceedings] Pub Date : 2023-09-01 DOI:10.1109/ICORR58425.2023.10304754

Mingrui Sun, Tomislav Bacek, Dana Kulic, Jennifer McGinley, Denny Oetomo, Ying Tan

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Abstract

Assisting persons during physical therapy or augmenting their performance often requires precise delivery of an intervention. Robotic devices are perfectly placed to do so, but their intervention highly depends on the physical human-robot connection. The inherent compliance in the connection leads to delays and losses in bi-directional power transmission and can lead to human-robot joint axes misalignment. This is often neglected in the literature by assuming a rigid connection and has a negative impact on the intervention's effectiveness and robustness. This paper presents the preliminary results of a study that aims to close that gap. The study investigates what model forms and parameters best capture human-robot connection dynamics across different persons, connection designs (cuffs), and cuff strapping pressures. The results show that the linear spring-damper model is the best compromise, but its parameters must be adjusted for each individual and different conditions separately.

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具有不同用户、袖带和捆绑压力的物理人机界面建模：一个案例研究。

在物理治疗期间帮助患者或提高他们的表现通常需要精确的干预。机器人设备的位置非常合适，但它们的干预在很大程度上取决于人与机器人的物理连接。连接中固有的顺应性导致双向电力传输的延迟和损失，并可能导致人类-机器人关节轴错位。这在文献中经常被忽视，因为假设存在刚性联系，并对干预的有效性和稳健性产生负面影响。本文介绍了一项旨在缩小这一差距的研究的初步结果。该研究调查了什么样的模型形式和参数最能捕捉不同人之间的人机连接动态、连接设计（袖带）和袖带捆扎压力。结果表明，线性弹簧阻尼器模型是最好的折衷方案，但其参数必须分别针对每个单独和不同的条件进行调整。

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

IEEE ... International Conference on Rehabilitation Robotics : [proceedings]

CiteScore

0.50

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0.00%

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