Human-Variability-Respecting Optimal Control for Physical Human-Machine Interaction

arXiv - CS - Systems and Control Pub Date : 2024-05-06 DOI:arxiv-2405.03502

Sean Kille, Paul Leibold, Philipp Karg, Balint Varga, Sören Hohmann

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Abstract

Physical Human-Machine Interaction plays a pivotal role in facilitating collaboration across various domains. When designing appropriate model-based controllers to assist a human in the interaction, the accuracy of the human model is crucial for the resulting overall behavior of the coupled system. When looking at state-of-the-art control approaches, most methods rely on a deterministic model or no model at all of the human behavior. This poses a gap to the current neuroscientific standard regarding human movement modeling, which uses stochastic optimal control models that include signal-dependent noise processes and therefore describe the human behavior much more accurate than the deterministic counterparts. To close this gap by including these stochastic human models in the control design, we introduce a novel design methodology resulting in a Human-Variability-Respecting Optimal Control that explicitly incorporates the human noise processes and their influence on the mean and variability behavior of a physically coupled human-machine system. Our approach results in an improved overall system performance, i.e. higher accuracy and lower variability in target point reaching, while allowing to shape the joint variability, for example to preserve human natural variability patterns.

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物理人机交互的 "尊重人的可变性 "优化控制

物理人机交互（Physical Human-Machine Interaction）在促进不同领域的协作方面发挥着举足轻重的作用。在设计适当的基于模型的控制器以协助人类进行交互时，人类模型的准确性对于耦合系统的整体行为至关重要。纵观最先进的控制方法，大多数方法都依赖于人类行为的非确定性模型或根本没有模型。这与当前神经科学的人体运动建模标准存在差距，后者使用的随机最优控制模型包含信号相关噪声过程，因此对人体行为的描述比确定性模型更加精确。为了缩小这一差距，我们引入了一种新颖的设计方法，将人类噪声过程及其对物理耦合人机系统的主题和变异性行为的影响纳入到控制设计中，从而产生了尊重人类变异性的最优控制。我们的方法提高了系统的整体性能，即在到达目标点时具有更高的准确性和更低的变异性，同时允许塑造关节变异性，例如保留人类的自然变异模式。

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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arXiv - CS - Systems and Control

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