基于改进RRT的月球地下自主挖洞机器人路径规划算法

2020 4th Annual International Conference on Data Science and Business Analytics (ICDSBA) Pub Date : 2020-09-01 DOI:10.1109/ICDSBA51020.2020.00039

Yangyi Liu, Yangping Li, Ke Wang, Z. Qiao, Zihao Yuan, Xihan Li, Lu Zhang, Haifeng Zhao

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引用次数: 0

摘要

自主挖洞机器人的探测可能是未来月球地下探测任务中一种低成本、高效率的解决方案。在月球下表面被月球岩石隔离的情况下，地下机车机器人在三维域的路径规划是一项非常具有挑战性的任务。在这项工作中，提出了一种修剪改进的RRT算法来生成三维地质模型中的机器人路径:一个具有分布障碍物的受限立方体区域。该数字地形模型可基于探月雷达(LPR)成图技术构建。为简便起见，本文采用数值模拟方案。讨论了迭代方案对寻径和地质构造分布的影响。然后利用Bezier参数曲线增强机器人轨迹的平滑度;经过综合研究，证明该算法在有效性和收敛性方面都优于原RRT方法。

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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A Path Planning Algorithm Based on Improved RRT for Lunar Subsurface Autonomous Burrowing Robot

The detection with autonomous burrowing robot might be a low-cost and high-efficient solution for a future lunar subsurface exploration mission. The path planning of underground locomotive robot in a three-dimensional (3-D) domain is a very challenging task under the circumstance of lunar subsurface segregated by lunar rocks. In this work, a pruning-improved RRT algorithm was proposed to generate robotic paths in a 3-D geological model: a confined cubic zone with distributed obstacles. This digital terrain model may be constructed based on the mapping technology of Lunar Penetrating Radar (LPR). Here, a numerical simulation scheme was adapted for a simplicity. The effects of iteration scheme of path finding and distribution of geological structures were discussed. Then, Bezier parametric curve was utilized to enhanced the smoothness of robotic trajectory. After a comprehensive study, the proposed algorithm was proven to outperform the original RRT method in both effectiveness and convergence.

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2020 4th Annual International Conference on Data Science and Business Analytics (ICDSBA)

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