Research on path planning algorithm of mobile robot based on improved RRT* and DWA fusion

doi:10.16731/j.cnki.1671-3133.2025.04.011

Abstract

Abstract: Path planning is a research hotspot of mobile robot,which is directly related to the efficiency and accuracy of mobile robot. Aiming at the problems that the existing research has not effectively solved the redundancy of turning points and the difficulty of obstacle avoidance in dynamic obstacle environment,a path planning algorithm of mobile robots based on B-spline improved RRT^* and Dynamic Window Approach (DWA) fusion was proposed. Firstly,the node pruning strategy was adopted to remove redundant nodes in the path. Then, B-spline curve was used to optimize the pruned path,shorten the path length,reduce the turning angle and make the path smoother. Finally,the improved DWA algorithm was integrated to ensure in real time avoidance of unknown obstacles under the condition of global optimization. Through MATLAB simulation and experiment based on ROS system,the results show that the proposed improved RRT^* and DWA fusion algorithm has the advantages of low cost,short running time,and can keeping a safe distance from obstacles,and planning the optimal path while avoiding dynamic obstacles.

Key words: mobile robot, path planning, improved RRT^*, Dynamic Window Approach (DWA), fusion

CLC Number:

TP242.6

FU Dandan, LI Bo. Research on path planning algorithm of mobile robot based on improved RRT^* and DWA fusion[J]. Modern Manufacturing Engineering, 2025, 535(4): 91-97.

References

[1] 李中华,袁杰,郭振宇.基于信息启发的目标导向Bi-RRT机器人路径规划[J].计算机工程与科学,2023,45(12):2237-2245.
[2] ZHANG X,ZHU T,XU Y,et al.Local path planning of the autonomous vehicle based on adaptive improved RRT algorithm in certain lane environments[J].Actuators,2022,11(4):109.
[3] 靳午煊,马向华,赵金良.改进Informed-RRT^*的移动机器人路径规划算法研究[J].计算机工程与应用,2023,59(19):75-81.
[4] 巩浩,谭向全,李佳欣,等.基于改进RRT算法的移动机器人路径规划研究[J].组合机床与自动化加工技术,2024(1):19-24.
[5] ZHANG Z W,JIA Y W,SU Q Q,et al.ATS-RRT^*:an improved RRT^* algorithm based on alternative paths and triangular area sampling[J].Advanced Robotics,2023,37(10):605-620.
[6] 郭利进,李强.基于改进RRT^*算法的移动机器人路径规划[J].智能系统学报,2024,19(5):1209-1217.
[7] 林桂娟,李子涵,王宇.基于全局关键点提取的改进A^*算法全局路径规划研究[J/OL].系统仿真学报:1-12(2024-03-08)[2024-03-18].https://doi.org/10.16182/j.issn/004731x.joss.23-1375.
[8] 马少博,王立勇,丁炳超,等.方向性JPS的移动机器人全局路径规划方法[J].重庆理工大学学报(自然科学),2022,36(10):192-199.
[9] 杨敏豪,张国良,罗国攀,等.融合间隙与DWA的移动机器人动态避障规划[J].国外电子测量技术,2023,42(11):190-196.
[10] XU C,XU Z B,XIA M Y.Obstacle avoidance in a three-dimensional dynamic environment based on fuzzy dynamic windows[J].Applied Sciences,2021,11(2):504.
[11] 倪建云,杜合磊,谷海青,等.改进人工势场法的移动机器人路径规划研究[J].重庆理工大学学报(自然科学),2023,37(11):247-256.
[12] 时维国,宁宁,宋存利,等.基于蚁群算法与人工势场法的移动机器人路径规划[J].农业机械学报,2023,54(12):407-416.
[13] 刘宙浩,万超一,尹明锋,等.改进A^*算法与DWA融合的移动机器人的路径规划算法研究[J].制造业自动化,2023,45(12):55-60.
[14] 刘紫燕,张杰,袁浩,等.融合改进RRT和DWA算法的移动机器人路径规划[J].机械设计与制造,2023(11):224-229.
[15] 黄雪梅,郝园,张磊安,等.平面轮廓曲线数据的B样条曲线逼近算法[J].现代制造工程,2013(7):129-132.
[16] 柴松,马社祥,李啸.基于均匀B样条曲线的移动小车路径规划方法[J].计算机应用与软件,2023,40(10):76-82.
[17] 王豪杰,马向华,代婉玉,等.改进DWA算法的移动机器人避障研究[J].计算机工程与应用,2023,59(6):326-332.

Research on path planning algorithm of mobile robot based on improved RRT^* and DWA fusion

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	MAO Kun, ZHU Xuejun, YANG Xudong, YU Checao. Robot vision polishing system for complex workpieces: path planning and force control research [J]. Modern Manufacturing Engineering, 2025, 538(7): 31-41.
[2]	WANG Lei, LIU Xinlan, GUO Yuyao, ZHANG Zelin, XIA Xuhui. Fusion semantic information modeling method of waste mechanical product [J]. Modern Manufacturing Engineering, 2025, 538(7): 80-88.
[3]	DENG Zejian, YANG Miaosen, LIU Xiyang, DU Rongzhen, LIU Jianwei. Research on autonomous welding technology for curved workpieces based on structured light [J]. Modern Manufacturing Engineering, 2025, 538(7): 96-104.
[4]	TIAN Ying, XU Rongying. A review of the structural design of the deformation mechanism of spherical mobile robots [J]. Modern Manufacturing Engineering, 2025, 538(7): 139-148.
[5]	DONG Jianlin, GUAN Yuanlin, CHENG Qi, XU Guangsheng, WANG Tichen. Mobile robot path planning based on sparrow search-ant colony algorithm [J]. Modern Manufacturing Engineering, 2025, 537(6): 58-66.
[6]	ZHAO Qian, SHI Yuqiang. Research on real time path planning and obstacle avoidance of AGV by integrating improved A^* algorithm and DWA [J]. Modern Manufacturing Engineering, 2025, 536(5): 91-98.
[7]	LIU Zhen, ZHANG Hong. Warehouse mobile robot path planning integrating improved bidirectional A^{* and dynamic window approach}[J]. Modern Manufacturing Engineering, 2025, 536(5): 99-105.
[8]	HE Haochen, WANG Kun, WANG Gang, LI Sufu, ZHOU Jiyu, CHEN Zexin. Rotating detection algorithm of meter seal screw based on GROOVE-YOLO [J]. Modern Manufacturing Engineering, 2025, 534(3): 99-106.
[9]	ZHU Min, CHEN Siyuan, CHEN Jie. Research on the path planning algorithm of RRT-Connect robotic arm based on improved artificial potential field guidance [J]. Modern Manufacturing Engineering, 2025, 533(2): 1-9.
[10]	ZHOU Guocheng, TAO Yifei, HE Yi, LI Lishan, WU Jiaxing. Research on the online scheduling problem of multi-AGVs in automatic packing system [J]. Modern Manufacturing Engineering, 2025, 533(2): 17-25.
[11]	ZHAO Zhengjun, HU Likun, CAI Chengjie, WEI Wenyang. Mobile robot path planning based on improved egret swarmoptimization algorithm [J]. Modern Manufacturing Engineering, 2025, 533(2): 37-43.
[12]	LI Dandan, ZHU Shilei, LI Zhongkang, JIE Baikun, WANG Hong. Path planning of mobile robot based on improved chameleon swarm algorithm [J]. Modern Manufacturing Engineering, 2024, 528(9): 40-45.
[13]	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.
[14]	GUO Kang, WANG Zhigang, XU Zengbing. Fault diagnosis of small sample bearings based on the AFF-Stablenet model [J]. Modern Manufacturing Engineering, 2024, 528(9): 144-151.
[15]	LIANG Biao, ZHOU Deqiang, SHENG Weifeng, ZUO Wenjuan, HE Changjiang, XI Qing, CHEN Quyan. Research on AGV deviation correction system based on fractional order sliding mode control [J]. Modern Manufacturing Engineering, 2024, 527(8): 51-60.