Classification of Co-manipulation Modus with Human-Human Teams for Future Application to Human-Robot Systems

IF 4.2 Q2 ROBOTICS

ACM Transactions on Human-Robot Interaction Pub Date : 2024-06-13 DOI:10.1145/3659059

Seth Freeman, Shaden Moss, John L. Salmon, Marc D. Killpack

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引用次数: 0

Abstract

Despite the existence of robots that can lift heavy loads, robots that can help people move heavy objects are not readily available. This paper makes progress towards effective human-robot co-manipulation by studying 30 human-human dyads that collaboratively manipulated an object weighing 27 kg without being co-located (i.e. participants were at either end of the extended object). Participants maneuvered around different obstacles with the object while exhibiting one of four modi–the manner or objective with which a team moves an object together–at any given time. Using force and motion signals to classify modus or behavior was the primary objective of this work. Our results showed that two of the originally proposed modi were very similar, such that one could effectively be removed while still spanning the space of common behaviors during our co-manipulation tasks. The three modi used in classification were quickly, smoothly and avoiding obstacles. Using a deep convolutional neural network (CNN), we classified three modi with up to 89% accuracy from a validation set. The capability to detect or classify modus during co-manipulation has the potential to greatly improve human-robot performance by helping to define appropriate robot behavior or controller parameters depending on the objective or modus of the team.

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未来应用于人机系统的人机团队协同操纵模式分类

尽管存在能够举起重物的机器人，但能够帮助人类移动重物的机器人却并不容易获得。本文通过研究 30 个人类-机器人二人组，在没有共同位置的情况下（即参与者位于延伸物体的两端）协作操纵一个重达 27 公斤的物体，在实现有效的人类-机器人协同操纵方面取得了进展。参与者用该物体绕过不同的障碍物，同时在任何时候都表现出四种模式（团队共同移动物体的方式或目标）中的一种。利用力和运动信号对方式或行为进行分类是这项工作的主要目的。我们的研究结果表明，在最初提出的模式中，有两种非常相似，因此可以有效地去除其中一种，同时仍能涵盖共同操控任务中的常见行为。用于分类的三种模式分别是快速、平稳和避开障碍物。利用深度卷积神经网络（CNN），我们从验证集中对三种模式进行了分类，准确率高达 89%。在协同操纵过程中检测或分类模式的能力可根据团队的目标或模式帮助定义适当的机器人行为或控制器参数，从而大大提高人机协作性能。

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

ACM Transactions on Human-Robot Interaction Computer Science-Artificial Intelligence

CiteScore

7.70

自引率

5.90%

发文量

期刊介绍： ACM Transactions on Human-Robot Interaction (THRI) is a prestigious Gold Open Access journal that aspires to lead the field of human-robot interaction as a top-tier, peer-reviewed, interdisciplinary publication. The journal prioritizes articles that significantly contribute to the current state of the art, enhance overall knowledge, have a broad appeal, and are accessible to a diverse audience. Submissions are expected to meet a high scholarly standard, and authors are encouraged to ensure their research is well-presented, advancing the understanding of human-robot interaction, adding cutting-edge or general insights to the field, or challenging current perspectives in this research domain. THRI warmly invites well-crafted paper submissions from a variety of disciplines, encompassing robotics, computer science, engineering, design, and the behavioral and social sciences. The scholarly articles published in THRI may cover a range of topics such as the nature of human interactions with robots and robotic technologies, methods to enhance or enable novel forms of interaction, and the societal or organizational impacts of these interactions. The editorial team is also keen on receiving proposals for special issues that focus on specific technical challenges or that apply human-robot interaction research to further areas like social computing, consumer behavior, health, and education.