Research on path planning of multi-warehouse robots based on ISO-TW algorithm

doi:10.16731/j.cnki.1671-3133.2024.09.008

Abstract

Abstract: To solve the low efficiency and insufficient dynamics of cooperative planning of multi-warehouse robots in current intelligent warehouses,a path planning method combining Improved Snake Optimizer(ISO) and Time Window(TW) model was proposed. Firstly,in the static planning stage,the improved snake optimizer considering the blocking factor was used to plan the global optimal path for multi-warehouse robots,and the time window of each robot was calculated,so as to improve the planning efficiency of warehouse robots. Secondly,in the dynamic planning stage,the time window model of multi-warehouse robots was established and dynamic adjustment strategy was introduced to resolve conflicts and improve the dynamic performance of the algorithm. Finally,simulation and experiments were conducted,the simulation results showed that the ISO-TW algorithm could reduce the number of blocking points by up to 27~43 compared to other algorithms with a reduction of 22.50 %~31.62 % (with a robot size of 80). The proportion of replanned paths could be reduced by 39.82 %~41.05 % (with a robot scale of 40). The average running time could be shortened by up to 38~40 s with a reduction of approximately 18.27 %~19.05 % (with a scale of 60 robots). Experimental results showed that the ISO-TW algorithm reduces the average running time by 8.53 %~9.23 % and the number of conflicts by 11.63 %~15.56 % compared to other algorithms. It could achieve efficient collaborative planning of multi-warehouse robots in real scenarios.

Key words: Snake Optimizer(SO), Time Window(TW), warehouse robot, path planning

CLC Number:

TP242

ZHOU Xiaoqing, TONG Yifei, ZHOU Kaijun. Research on path planning of multi-warehouse robots based on ISO-TW algorithm[J]. Modern Manufacturing Engineering, 2024, 528(9): 54-59.

References

[1] CHEN Y,WU J,HE C,et al.Intelligent Warehouse Robot Path Planning Based on Improved Ant Colony Algorithm[J].IEEE Access,2023,11:12360-12367.
[2] 雷斌,金彦彤,王致诚,等.仓储物流机器人技术现状与发展[J].现代制造工程,2021(12):143-153.
[3] 雷旭,陈静夷,陈潇阳.改进哈里斯鹰算法的仓储机器人路径规划研究[J].系统仿真学报,2024,36(5):1081-1092.
[4] 贺志刚,李大焱,王妮娅,等.一种含链式工作方式的多机器人协作路径规划算法[J].系统仿真学报,2024,3:1-15.
[5] 黄训爱,杨光永,樊康生,等.改进海洋捕食者算法的机器人路径规划研究[J].重庆理工大学学报(自然科学版),2024,38(1):355-3675.
[6] LIANG D,LIU Z Y,BHAMARA R.Collaborative Multi-Robot Formation Control and Global Path Optimization[J].Applied Sciences,2022,12(14):7076-7088.
[7] 李艳生,万勇,张毅,等.基于人工蜂群-自适应遗传算法的仓储机器人路径规划[J].仪器仪表学报,2022,43(4):282-290.
[8] 岳春擂,黄俊,邓乐乐.改进蚁群算法在AGV路径规划上的研究[J].计算机工程与设计,2022,43(9):2533-2541.
[9] HAO G,LV Q,HUANG Z,et al.UAV Path Planning Based on Improved Artificial Potential Field Method[J].Aerospace,2023,10(6):117-135.
[10] HAO K,YANG Y,LI Z,et al.CERRT:A Mobile Robot Path Planning Algorithm Based on RRT in Complex Environments[J].Applied Sciences,2023,13(17):64-74.
[11] 王志辉,陈息坤.融合场景理解与A^*算法的巡检机器人避障设计[J].无线电工程,2022,52(11):2000-2008.
[12] 杨瑞刚,耿明伟,郝成林,等.基于改进速度调节法的AGV群调度决策[J].机械设计与研究,2023,39(4):173-177.
[13] MORTEZA K,ENOL G,JOSE V,et al.A^*-Based Co-Evolutionary Approach for Multi-Robot Path Planning with Collision Avoidance[J].Cybernetics and Systems,2023,54(3):339-354.
[14] HASHIM F A,HUSSIEN A G.Snake Optimizer:a novel meta-heuristic optimization algorithm[J].Knowledge-Based Systems,2022,242(11):108320-108354.
[15] 张涛,王楚楚.考虑软时间窗的同时送取货随机旅行时间车辆路径问题[J].同济大学学报(自然科学版),2023,51(8):1278-1287.