Improving Safety in Human-Robot Collaboration via Dynamic Active Constraints Enforcement*

George S. Kanakis, G. Rovithakis
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引用次数: 1

Abstract

The problem of motion planning in obstacle cluttered environments is an important task in robotics. In the literature several methodologies exist to address the problem. In this work we consider using the feedback-based approach, where the solution comes from designing a controller capable of guaranteeing trajectory tracking with obstacle avoidance. Commonly, all respective studies consider simplified robot dynamics, which is usually insufficient in practical applications. In this work we focus on the collision avoidance problem with respect to a moving spherical object. We assume knowledge of a nominal controller that achieves tracking of a desired trajectory in the absence of obstacles, and we design an auxiliary control scheme to guarantee that the robot’s end-effector will always operate in a safe distance from the moving obstacle’s surface. The controller we develop does not take into account the actual robot dynamics, thus constituting a truly model-free approach. Experimental studies conducted on a KUKA LWR4+ robotic manipulator clarify and verify the proposed control scheme.
基于动态主动约束的人机协作安全性改进*
障碍环境下的运动规划问题是机器人技术中的一个重要课题。在文献中存在几种方法来解决这个问题。在这项工作中,我们考虑使用基于反馈的方法,其中的解决方案来自于设计一个能够保证轨迹跟踪和避障的控制器。通常,所有相关的研究都考虑了简化的机器人动力学,这在实际应用中通常是不足的。在这项工作中,我们专注于关于一个运动的球形物体的避碰问题。我们假设已知一个标称控制器,在没有障碍物的情况下实现期望轨迹的跟踪,并且我们设计了一个辅助控制方案,以保证机器人的末端执行器始终在与移动障碍物表面的安全距离内运行。我们开发的控制器没有考虑到实际的机器人动力学,因此构成了一个真正的无模型方法。在KUKA LWR4+机器人上进行的实验研究阐明并验证了所提出的控制方案。
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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