Cartesian Inertia Optimization via Redundancy Resolution for Physical Human-Robot Interaction

2021 IEEE 17th International Conference on Automation Science and Engineering (CASE) Pub Date : 2021-08-23 DOI:10.1109/CASE49439.2021.9551663

Sheila Sutjipto, Jon Woolfrey, Marc G. Carmichael, G. Paul

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Abstract

The objective of introducing robotic manipulators into human-centric domains is to improve the efficacy of tasks in a safe and practical manner. The shift toward collaborative manipulator platforms has facilitated physical human-robot interaction (pHRI) in such environments. Often, these platforms are kinematically redundant and possess more degrees of freedom (DOF) than needed to complete a desired task. When no additional task is defined, it is possible for the manipulator to converge upon joint configurations that are unfavourable for the collaborative task. Consequently, there is potential for the posture of the manipulator to affect the interaction experienced. This paper investigates an inertia-based optimization control method for redundant manipulators interacting with an active agent. The inertia-based reconfiguration is evaluated through simulations and quantified with real-life experiments conducted with a robot-robot dyad. It was found that resolving redundancy to reconfigure the Cartesian inertia reduced the energy expenditure of the active agent during the interaction.

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基于冗余分辨率的物理人机交互笛卡尔惯性优化

将机械臂引入以人为中心的领域的目的是以安全和实用的方式提高任务的效率。向协作式机械臂平台的转变促进了这种环境中的物理人机交互(pHRI)。通常，这些平台在运动上是冗余的，并且具有比完成期望任务所需的更多自由度(DOF)。当没有定义额外的任务时，操纵器有可能收敛于不利于协同任务的关节构型。因此，机械手的姿势有可能影响所经历的交互。研究了一种基于惯性的冗余机械臂与主动agent交互的优化控制方法。通过仿真评估了基于惯性的重构，并通过机器人-机器人二元体的实际实验进行了量化。研究发现，通过分解冗余来重新配置笛卡尔惯量可以减少交互过程中主动体的能量消耗。

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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2021 IEEE 17th International Conference on Automation Science and Engineering (CASE)

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