Enabling Shared-Control for A Riding Ballbot System

arXiv - CS - Robotics Pub Date : 2024-09-11 DOI:arxiv-2409.07013

Yu Chen, Mahshid Mansouri, Chenzhang Xiao, Ze Wang, Elizabeth T. Hsiao-Wecksler, William R. Norris

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Abstract

This study introduces a shared-control approach for collision avoidance in a self-balancing riding ballbot, called PURE, marked by its dynamic stability, omnidirectional movement, and hands-free interface. Integrated with a sensor array and a novel Passive Artificial Potential Field (PAPF) method, PURE provides intuitive navigation with deceleration assistance and haptic/audio feedback, effectively mitigating collision risks. This approach addresses the limitations of traditional APF methods, such as control oscillations and unnecessary speed reduction in challenging scenarios. A human-robot interaction experiment, with 20 manual wheelchair users and able-bodied individuals, was conducted to evaluate the performance of indoor navigation and obstacle avoidance with the proposed shared-control algorithm. Results indicated that shared-control significantly reduced collisions and cognitive load without affecting travel speed, offering intuitive and safe operation. These findings highlight the shared-control system's suitability for enhancing collision avoidance in self-balancing mobility devices, a relatively unexplored area in assistive mobility research.

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实现骑行球机器人系统的共享控制

本研究介绍了一种用于自平衡骑行球形机器人避免碰撞的共享控制方法，名为 PURE，其特点是动态稳定、全向运动和免提界面。PURE集成了传感器阵列和新颖的被动人工势场（PAPF）方法，通过减速辅助和触觉/声音反馈提供直观导航，有效降低了碰撞风险。这种方法解决了传统 APF 方法的局限性，如控制振荡和在具有挑战性的场景中不必要的减速。为了评估共享控制算法在室内导航和避障方面的性能，我们对20名手动轮椅使用者和健全人进行了人机交互实验。结果表明，共享控制大大减少了碰撞和认知负荷，同时不影响行进速度，提供了直观和安全的操作。这些发现凸显了共享控制系统适用于增强自平衡移动设备的防撞能力，而这是辅助移动研究中一个相对尚未开发的领域。

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 - Robotics

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