Multi-Robot Path Planning Based on Max–Min Ant Colony Optimization and D* Algorithms in a Dynamic Environment

Ali Hadi Hasan, Akmam Majid Mosa
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引用次数: 5

Abstract

This paper involves a proposition of a new method to find the optimal path for centralized and competitive multirobot in the same dynamic environment. These robots can start from different location(s) and destination to the same goal. The method used to hybrid the pheromone trail updating of MAX– MIN ACO (MMAS) algorithm with D* algorithm strategies to construct a trail of the modified (deposited) pheromone which is updated in each iteration. The robots use tour construction probabilities to choose the best solution to move from the start nodes through the dynamic environment, which contains dynamic obstacles moving in free space, by finding and displaying the optimal path for each robot. A number of experimental results simulated on different dynamic environments for different number of robots indicated that the proposed method performed well. The robots are competitive with each other to reach their targets without colliding with obstacles, and they find the optimal path with minimum iterations and minimum total arc cost. Generally, the increase number of the implemented robots increases the occupy time. However, the amount of that increase varies. It goes from (7%) to (15%) when one to two robots are implemented. It is also noticed that the increase in the time occupy turns to be limited in comparison to the previous ratios, i.e. from (27%) to (30%) when four to five robots are implemented.
动态环境下基于最大最小蚁群优化和D*算法的多机器人路径规划
本文提出了一种在同一动态环境下寻找集中式竞争多机器人最优路径的新方法。这些机器人可以从不同的位置和目的地出发到同一个目标。该方法将MAX - MIN ACO (MMAS)算法的信息素轨迹更新与D*算法策略混合,构建每次迭代更新的修改(沉积)信息素轨迹。机器人通过寻找并显示每个机器人的最优路径,利用行程构建概率选择从起始节点穿过动态环境的最佳解决方案,该动态环境包含在自由空间中移动的动态障碍物。针对不同数量机器人在不同动态环境下的仿真实验结果表明,该方法具有良好的性能。机器人之间相互竞争,在不与障碍物碰撞的情况下到达目标,并以最小的迭代次数和最小的总弧成本找到最优路径。一般来说,机器人数量的增加会增加占用时间。然而,增长的幅度各不相同。当安装一到两个机器人时,这一比例从(7%)上升到(15%)。同样值得注意的是,与之前的比例相比,占用时间的增加变得有限,即当实施4到5个机器人时,从(27%)到(30%)。
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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