交互式距离场绘图和规划,实现人机协作

IF 4.6 2区 计算机科学 Q2 ROBOTICS IEEE Robotics and Automation Letters Pub Date : 2024-10-16 DOI:10.1109/LRA.2024.3482128
Usama Ali;Lan Wu;Adrian Müller;Fouad Sukkar;Tobias Kaupp;Teresa Vidal-Calleja
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引用次数: 0

摘要

人机协作应用需要不断更新的场景表征,以促进动态场景中的安全运动。在这封信中,我们提出了一种交互式距离场映射和规划(IDMP)框架,它能通过高效的表示来处理动态物体和避免碰撞。我们将交互式映射和规划定义为在线创建和更新场景表示,同时根据该表示规划和调整机器人行动的过程。这项工作的关键在于一个高效的高斯过程场,它可以执行增量更新,并通过基于临时潜在模型查询的简单而优雅的表述来识别移动点,从而可靠地处理动态物体。在映射方面,IDMP 能够融合来自单个和多个传感器的点云数据,以任意空间分辨率查询自由空间,并处理无语义的移动物体。在规划方面,IDMP 可以与基于梯度的反应式规划器无缝集成,从而促进动态避障,实现安全的人机交互。我们在真实和合成数据集上对绘图性能进行了评估。与最先进的类似框架进行比较后发现,该框架在处理动态物体时性能优越,在计算距离和梯度场的准确性方面也有相当或更好的表现。最后,我们展示了该框架如何在模拟和真实世界场景中,在存在移动物体的情况下用于快速运动规划。
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Interactive Distance Field Mapping and Planning to Enable Human-Robot Collaboration
Human-robot collaborative applications require scene representations that are kept up-to-date and facilitate safe motions in dynamic scenes. In this letter, we present an interactive distance field mapping and planning (IDMP) framework that handles dynamic objects and collision avoidance through an efficient representation. We define interactive mapping and planning as the process of creating and updating the representation of the scene online while simultaneously planning and adapting the robot's actions based on that representation. The key aspect of this work is an efficient Gaussian Process field that performs incremental updates and handles dynamic objects reliably by identifying moving points via a simple and elegant formulation based on queries from a temporary latent model. In terms of mapping, IDMP is able to fuse point cloud data from single and multiple sensors, query the free space at any spatial resolution, and deal with moving objects without semantics. In terms of planning, IDMP allows seamless integration with gradient-based reactive planners facilitating dynamic obstacle avoidance for safe human-robot interactions. Our mapping performance is evaluated on both real and synthetic datasets. A comparison with similar state-of-the-art frameworks shows superior performance when handling dynamic objects and comparable or better performance in the accuracy of the computed distance and gradient field. Finally, we show how the framework can be used for fast motion planning in the presence of moving objects both in simulated and real-world scenes.
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来源期刊
IEEE Robotics and Automation Letters
IEEE Robotics and Automation Letters Computer Science-Computer Science Applications
CiteScore
9.60
自引率
15.40%
发文量
1428
期刊介绍: The scope of this journal is to publish peer-reviewed articles that provide a timely and concise account of innovative research ideas and application results, reporting significant theoretical findings and application case studies in areas of robotics and automation.
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