基于Gromov-Hausdorff逼近的多查询机器人任务排序

IF 9.4 1区计算机科学 Q1 ROBOTICS

IEEE Transactions on Robotics Pub Date : 2025-03-24 DOI:10.1109/TRO.2025.3554404

Fouad Sukkar;Jennifer Wakulicz;Ki Myung Brian Lee;Weiming Zhi;Robert Fitch

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引用次数: 0

摘要

机械臂的应用往往需要高效的在线运动规划。当完成多个任务时，序列顺序和目标配置的选择会对规划性能产生巨大影响。这就是众所周知的机器人任务排序问题（RTSP）。当可用的计算时间有限时，现有的通用RTSP算法容易产生低质量的解或完全失败。我们提出了一种新的多查询任务排序方法，旨在在具有静态和非静态障碍的半结构化环境中运行。我们的方法有意地将工作空间的通用性与规划效率相权衡。给定一个带有静态障碍物的用户定义任务空间，我们计算一个子空间分解。关键思想是建立被称为$\epsilon$-Gromov-Hausdorff近似的近似等距，该近似可以识别在任务空间和配置空间中彼此接近的点。重要的是，我们证明了这些子空间中路径长度的有界次优性保证。这些边界关系进一步表明，同一子空间内的路径可以平滑连接，这对于确定有效的任务序列是有用的。我们在一个复杂的模拟环境中用几种运动学配置来评估我们的方法，与基线相比，实现了高达3倍的运动规划和5倍的最大轨迹抖动。

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Multiquery Robotic Manipulator Task Sequencing With Gromov-Hausdorff Approximations

Robotic manipulator applications often require efficient online motion planning. When completing multiple tasks, sequence order and choice of goal configuration can have a drastic impact on planning performance. This is well known as the robot task sequencing problem (RTSP). Existing general-purpose RTSP algorithms are susceptible to producing poor-quality solutions or failing entirely when available computation time is restricted. We propose a new multiquery task sequencing method designed to operate in semistructured environments with a combination of static and nonstatic obstacles. Our method intentionally trades off workspace generality for planning efficiency. Given a user-defined task space with static obstacles, we compute a subspace decomposition. The key idea is to establish approximate isometries known as

$\epsilon$

-Gromov-Hausdorff approximations that identify points that are close to one another in both task and configuration space. Importantly, we prove bounded suboptimality guarantees on the lengths of paths within these subspaces. These bounding relations further imply that paths within the same subspace can be smoothly concatenated, which we show is useful for determining efficient task sequences. We evaluate our method with several kinematic configurations in a complex simulated environment, achieving up to 3× faster motion planning and 5× lower maximum trajectory jerk compared to baselines.

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来源期刊

IEEE Transactions on Robotics 工程技术-机器人学

CiteScore

14.90

自引率

5.10%

发文量

259

审稿时长

6.0 months

期刊介绍： The IEEE Transactions on Robotics (T-RO) is dedicated to publishing fundamental papers covering all facets of robotics, drawing on interdisciplinary approaches from computer science, control systems, electrical engineering, mathematics, mechanical engineering, and beyond. From industrial applications to service and personal assistants, surgical operations to space, underwater, and remote exploration, robots and intelligent machines play pivotal roles across various domains, including entertainment, safety, search and rescue, military applications, agriculture, and intelligent vehicles. Special emphasis is placed on intelligent machines and systems designed for unstructured environments, where a significant portion of the environment remains unknown and beyond direct sensing or control.