论矩形机器人运动规划的参数化复杂性

Iyad Kanj, Salman Parsa
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引用次数: 0

摘要

我们研究的是计算困难的基本运动规划问题,其目标是将 k$ 轴对齐的矩形机器人从初始位置平移到最终位置而不发生碰撞,并且平移动作的次数最少。我们的目标是了解机器人数量与输入实例几何复杂度之间的相互作用,输入实例几何复杂度由输入大小(即编码矩形顶点坐标所需的比特数)衡量。我们重点研究了轴对齐平移,更广义地说,仅限于给定方向集的平移,并研究了机器人在自由平面内移动和被限制在边界框内的两种情况。在所有考虑的情况下,我们都得到了以 $k$ 为参数的固定参数可控 (FPT) 算法。在机器人连续移动(即每个时间步移动一个)和轴对齐的情况下,我们证明了一个结构性结果,即每个问题实例都有一个最优解,在这个最优解中,移动是沿着网格进行的,网格大小是 $k$ 的函数,可以根据输入实例来定义。这一结构性结果意味着问题是固定参数可控的,参数为 $k$。我们还考虑了机器人平行移动的情况(即多个机器人可以在同一时间步长内移动),这种情况属于协调运动规划问题的范畴。最后,我们证明,当机器人在自由平面内运动时,串行运动情况下的 FPT 结果会延续到平移被限制为任意给定方向集的情况。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
On the Parameterized Complexity of Motion Planning for Rectangular Robots
We study computationally-hard fundamental motion planning problems where the goal is to translate $k$ axis-aligned rectangular robots from their initial positions to their final positions without collision, and with the minimum number of translation moves. Our aim is to understand the interplay between the number of robots and the geometric complexity of the input instance measured by the input size, which is the number of bits needed to encode the coordinates of the rectangles' vertices. We focus on axis-aligned translations, and more generally, translations restricted to a given set of directions, and we study the two settings where the robots move in the free plane, and where they are confined to a bounding box. We obtain fixed-parameter tractable (FPT) algorithms parameterized by $k$ for all the settings under consideration. In the case where the robots move serially (i.e., one in each time step) and axis-aligned, we prove a structural result stating that every problem instance admits an optimal solution in which the moves are along a grid, whose size is a function of $k$, that can be defined based on the input instance. This structural result implies that the problem is fixed-parameter tractable parameterized by $k$. We also consider the case in which the robots move in parallel (i.e., multiple robots can move during the same time step), and which falls under the category of Coordinated Motion Planning problems. Finally, we show that, when the robots move in the free plane, the FPT results for the serial motion case carry over to the case where the translations are restricted to any given set of directions.
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