Model Mediated Teleoperation with a Hand-Arm Exoskeleton in Long Time Delays Using Reinforcement Learning

2020 29th IEEE International Conference on Robot and Human Interactive Communication (RO-MAN) Pub Date : 2020-08-01 DOI:10.1109/RO-MAN47096.2020.9223477

H. Mohammadi, Matthias Kerzel, Benedikt Pleintinger, T. Hulin, Philipp Reisich, A. Schmidt, Aaron Pereira, S. Wermter, Neal Y. Lii

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引用次数: 11

Abstract

Telerobotic systems must adapt to new environmental conditions and deal with high uncertainty caused by long-time delays. As one of the best alternatives to human-level intelligence, Reinforcement Learning (RL) may offer a solution to cope with these issues. This paper proposes to integrate RL with the Model Mediated Teleoperation (MMT) concept. The teleoperator interacts with a simulated virtual environment, which provides instant feedback. Whereas feedback from the real environment is delayed, feedback from the model is instantaneous, leading to high transparency. The MMT is realized in combination with an intelligent system with two layers. The first layer utilizes Dynamic Movement Primitives (DMP) which accounts for certain changes in the avatar environment. And, the second layer addresses the problems caused by uncertainty in the model using RL methods. Augmented reality was also provided to fuse the avatar device and virtual environment models for the teleoperator. Implemented on DLR’s Exodex Adam hand-arm haptic exoskeleton, the results show RL methods are able to find different solutions when changes are applied to the object position after the demonstration. The results also show DMPs to be effective at adapting to new conditions where there is no uncertainty involved.

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基于强化学习的长时间延迟手-臂外骨骼模型介导遥操作

远程机器人系统必须适应新的环境条件，并处理由长时间延迟引起的高度不确定性。作为人类智能的最佳替代方案之一，强化学习(RL)可能为应对这些问题提供解决方案。本文提出将强化学习与模型介导遥操作(MMT)概念相结合。远程操作员与模拟的虚拟环境交互，并提供即时反馈。来自真实环境的反馈是延迟的，而来自模型的反馈是即时的，因此具有很高的透明度。MMT与两层智能系统相结合实现。第一层利用动态运动原语(Dynamic Movement Primitives, DMP)来解释角色环境中的某些变化。第二层利用强化学习方法解决了模型中不确定性引起的问题。增强现实技术为远程操作者提供了融合化身设备和虚拟环境模型的方法。在DLR的Exodex Adam手臂触觉外骨骼上实现，结果表明，演示后，当物体位置发生变化时，RL方法能够找到不同的解决方案。研究结果还表明，在没有不确定性的情况下，dmp能够有效地适应新环境。

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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2020 29th IEEE International Conference on Robot and Human Interactive Communication (RO-MAN)

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