透明自由运动人机交互导纳控制动力学模型的比较。

Christopher K Bitikofer, Eric T Wolbrecht, Rene M Maura, Joel C Perry
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引用次数: 0

摘要

本文对在五自由度手臂外骨骼上实现的多导纳控制动力学模型进行了实验比较。每个模型的性能都会根据透明度、稳定性和对点对点到达的影响进行评估。尽管理想的导纳控制将为物理人机交互(pHRI)提供一个完全透明的环境,但在实践中,透明度和稳定性之间存在权衡,这两者都会对手臂的自然运动产生不利影响。在这里我们测试了四种导纳模式:1)低质量:零阻尼的低惯性;2) 高质量:高惯性,零阻尼;3) 速度阻尼:具有阻尼的低惯性;和4)一种新型的速度误差阻尼:基于速度误差的低惯性阻尼。一名受试者完成了两个实验:1)20次重复一次到达和返回,2)两次重复到达和返回13个不同的目标。结果表明,所提出的新型速度误差阻尼模型最大限度地提高了透明度,与低质量相比,振动功率平均降低了70%,同时也减少了用户的工作量,对空间/时间精度的影响比其他模式小。结果还表明,不同的模型具有独特的情境优势,因此在它们之间进行选择可能取决于特定任务的目标(即评估、治疗等)。未来的工作应该实时研究合并方法或在它们之间转换。
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Comparison of Admittance Control Dynamic Models for Transparent Free-Motion Human-Robot Interaction.

This paper presents an experimental comparison of multiple admittance control dynamic models implemented on a five-degree-of-freedom arm exoskeleton. The performance of each model is evaluated for transparency, stability, and impact on point-to-point reaching. Although ideally admittance control would render a completely transparent environment for physical human-robot interaction (pHRI), in practice, there are trade-offs between transparency and stability-both of which can detrimentally impact natural arm movements. Here we test four admittance modes: 1) Low-Mass: low inertia with zero damping; 2) High-Mass: high inertia with zero damping; 3) Velocity-Damping: low inertia with damping; and 4) a novel Velocity-Error-Damping: low inertia with damping based on velocity error. A single subject completed two experiments: 1) 20 repetitions of a single reach-and-return, and 2) two repetitions of reach-and-return to 13 different targets. The results suggest that the proposed novel Velocity-Error-Damping model improves transparency the most, achieving a 70% average reduction of vibration power vs. Low-Mass, while also reducing user effort, with less impact on spatial/temporal accuracy than alternate modes. Results also indicate that different models have unique situational advantages so selecting between them may depend on the goals of the specific task (i.e., assessment, therapy, etc.). Future work should investigate merging approaches or transitioning between them in real-time.

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