Walking-in-Place Foot Interface for Locomotion Control and Telepresence of Humanoid Robots

2020 IEEE-RAS 20th International Conference on Humanoid Robots (Humanoids) Pub Date : 2021-07-19 DOI:10.1109/HUMANOIDS47582.2021.9555768

Ata Otaran, I. Farkhatdinov

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引用次数: 3

Abstract

We present a foot-tapping walking-in-place type locomotion interface and algorithm to generate high-level movement patterns for humanoid remotely controlled robots. Foot tapping motions acting on the platform are used as movement commands to remotely control locomotion of a humanoid robot. We describe two separate motion mapping algorithms suitable for wheeled and bipedal humanoid locomotion. Our interface enables remote locomotion control of humanoid robots with the help of a seated and hands-free interface and enables the use of both handheld or desktop-based interfaces for manipulation tasks. An experimental study with eight participants controlling walking speed of a virtual robot was conducted to explore if the participants could maintain distance (1-3m range) to a reference target (leading robot) moving at different speeds. All participants were able to use the proposed interface to track the leading robot efficiently for walking speeds of less than 1 m/s and an average tracking error was 0.47 m. We discuss the results of the study along with the NASA TLX and system usability surveys.

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人形机器人运动控制与临场感的原地行走足部接口

提出了一种用于类人遥控机器人生成高级运动模式的轻拍原地行走式运动接口和算法。利用作用在平台上的足部轻拍动作作为运动指令，远程控制仿人机器人的运动。我们描述了两种不同的运动映射算法适用于轮式和双足人形运动。我们的界面可以通过坐姿和免提接口实现人形机器人的远程运动控制，并可以使用手持或基于桌面的界面进行操作任务。通过8名被试控制虚拟机器人的行走速度，探讨被试是否能与以不同速度移动的参考目标(领头机器人)保持1 ~ 3m的距离。所有参与者都能够使用所提出的接口有效地跟踪领先机器人，行走速度小于1 m/s，平均跟踪误差为0.47 m。我们与NASA TLX和系统可用性调查一起讨论了研究结果。

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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来源期刊

2020 IEEE-RAS 20th International Conference on Humanoid Robots (Humanoids)

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