Characterizing Prosthesis Control Fault During Human-Prosthesis Interactive Walking Using Intrinsic Sensors

IF 4.6 2区计算机科学 Q2 ROBOTICS

IEEE Robotics and Automation Letters Pub Date : 2022-06-27 DOI:10.1109/LRA.2022.3186503

Amirreza Naseri;Ming Liu;I-Chieh Lee;Wentao Liu;He Huang

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引用次数: 2

Abstract

The physical interactions between wearable lower limb robots and humans have been investigated to inform effective robot design for walking augmentation. However, human-robot interactions when internal faults occur within robots have not been systematically reported, but it is essential to improve the robustness of robotic devices and ensure the user’s safety. This letter aims to (1) present a methodology to characterize the behavior of the robotic transfemoral prosthesis as an effective wearable robot platform while interacting with the users in the presence of internal faults, and (2) identify the potential data sources for accurate detection of the prosthesis fault. We first obtained the human perceived response in terms of their walking stability when the prosthesis control fault (inappropriate intrinsic control output/command) was emulated/applied in level-ground walking. Then the measurements and their features, obtained from the transfemoral prosthesis, were examined for the emulated faults that elicited a sense of instability in human users. The optimal features that contributed the most in separating faulty interaction from the normal walking condition were determined using two machine-learning-based approaches: One-Class Support Vector Machine (OCSVM) and Mahalanobis Distance (MD) classifier. The OCSVM anomaly detector could achieve an average sensitivity of 85.7% and an average false alarm rate of 1.7% with a reasonable detecting time of 147.6 ms for detecting emulated control errors among all subjects. The result demonstrates the potential of using machine-learning-based schemes in identifying prosthesis control faults based on intrinsic sensors on the prosthesis. This study presents a procedure to study human-robot fault tolerance and inform the future design of robust prosthesis control.

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利用固有传感器表征人工假肢交互行走过程中的假肢控制故障

已对可穿戴下肢机器人和人类之间的物理交互进行了研究，以为有效的步行增强机器人设计提供信息。然而，机器人内部发生故障时的人机交互尚未系统报道，但提高机器人设备的鲁棒性和确保用户的安全至关重要。这封信的目的是（1）提出一种方法来描述机器人经股假体作为一个有效的可穿戴机器人平台在存在内部故障的情况下与用户交互时的行为，以及（2）确定准确检测假体故障的潜在数据源。当在平地行走中模拟/应用假肢控制故障（不适当的内在控制输出/命令）时，我们首先获得了人类在行走稳定性方面的感知反应。然后，从经股假体获得的测量结果及其特征，被检查是否存在模拟故障，这些故障会引起人类使用者的不稳定感。使用两种基于机器学习的方法：一类支持向量机（OCSVM）和马氏距离（MD）分类器，确定了在将故障交互与正常行走条件分离方面贡献最大的最优特征。OCSVM异常检测器可以实现85.7%的平均灵敏度和1.7%的平均误报率，合理的检测时间为147.6ms，用于检测所有受试者之间的模拟控制错误。该结果证明了使用基于机器学习的方案基于假体上的固有传感器来识别假体控制故障的潜力。本研究提出了一个研究人类机器人容错的程序，并为未来的鲁棒假肢控制设计提供了信息。

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 Robotics and Automation Letters Computer Science-Computer Science Applications

CiteScore

9.60

自引率

15.40%

发文量

1428

期刊介绍： The scope of this journal is to publish peer-reviewed articles that provide a timely and concise account of innovative research ideas and application results, reporting significant theoretical findings and application case studies in areas of robotics and automation.