Joint space trajectory planning of robot based on hybrid genetic  particle swarm optimization

doi:10.16731/j.cnki.1671-3133.2025.06.009

Abstract

Abstract: In order to realise laser cladding repair of mining scrapers,for the problem of maintaining high efficiency and stability of laser cladding robots during operation,the trajectory planning method in the joint space was studied according to the kinematic characteristics of the robots,and a hybrid genetic particle swarm optimization algorithm was proposed. Based on the particle swarm optimization algorithm,the method introduced the crossover and mutation behaviours in the genetic algorithm by constructing adaptive inertia weights and dynamic learning factors,and fitted the trajectory into the joint space of the robot using 3-5-3 polynomial interpolation. The hybrid genetic particle swarm optimization algorithm,chaotic particle swarm optimization algorithm and standard particle swarm optimization algorithm were compared,and after obtaining the optimal interpolation time,simulation was carried out in MATLAB software,and the change process of position,velocity and acceleration of each joint over time was kept in the ideal continuity interval,which realised the time-optimal motion planning in the joint space,and the optimal time was reduced from 5.058 0 s of the standard particle swarm optimization algorithm to 4.633 0 s,and the robotic arm trajectory planning time was shortened by 8.4 %,which verified the feasibility of the proposed algorithm in the trajectory planning of the laser cladding robot for repairing the mining scraper.

Key words: mining scrape, time-optimal, trajectory planning, particle swarm optimization algorithm, genetic algorithm, robotic arm

CLC Number:

TH164

LI Jianru, GONG Yanjue, ZHAO Fu. Joint space trajectory planning of robot based on hybrid genetic particle swarm optimization[J]. Modern Manufacturing Engineering, 2025, 537(6): 84-91.

References

[1] 王幼民.机器人连续轨迹控制中的Bezier曲线轨迹优化与控制 [J].机械传动,2003 (3):42-47,66.
[2] 陈晗,李林升.基于复合形法的时间最优机械臂轨迹规划 [J].机械传动,2019,43(3):72-75,94.
[3] 黄超,茅健,马丽,等.基于改进粒子群算法的时间最优机械臂轨迹规划 [J].上海工程技术大学学报,2020,34(3):238-246.
[4] 王策,孙军锋,徐贞,等.基于PSO算法的工业机器人轨迹优化研究 [J/OL].机械设计,1-9(2024-04-16)[2024-05-16]. https://doi.org/10.13841/j.cnki.jxsj.20240415.001.
[5] 石宪闪,苗鸿宾,张伟.基于改进粒子群算法的六自由度机械臂时间最优轨迹规划 [J].机床与液压,2023,51(1):20-25.
[6] 彭添晨.基于量子粒子群算法的工业机器人时间最优轨迹规划 [J].上海电气技术,2023,16(2):68-72.
[7] 周伟.基于粒子群算法的机械臂轨迹规划研究 [D].南京:南京邮电大学,2022.
[8] 唐建业,张建军,王晓慧,等.一种改进的机器人轨迹规划方法 [J].机械设计,2017,34(3):31-35.
[9] 杜超斐,刘睿,丁军,等.改进粒子群算法在六轴机械臂关节空间轨迹规划中的应用 [J].重庆理工大学学报(自然科学),2024,38(1):368-378.
[10] 付荣,居鹤华.基于粒子群优化的时间最优机械臂轨迹规划算法 [J].信息与控制,2011,40(6):802-808.
[11] 彭思文,梁科,潘雷,等.基于改进粒子群算法的机械臂时间最优轨迹规划 [J].组合机床与自动化加工技术,2023(6):31-34.
[12] DEB K,PRATAP A,AGARWAL S,et al. A fast and elitist multiobjective genetic algorithm:NSGA-II [J]. IEEE Transactions on Evolutionary Computation,2002,6(2):182-197.
[13] 江鸿怀,金晓怡,邢亚飞,等.基于粒子群优化算法的五自由度机械臂轨迹规划 [J].机械设计与研究,2020,36(1):107-110.
[14] YANG Y,XU H Z,LI S H,et al. Time-optimal trajectory optimization of serial robotic manipulator with kinematic and dynamic limits based on improved particle swarm optimization [J]. International Journal of Advanced Manufacturing Technology,2022,120(112):1253-1264.
[15] KUO Y L. Mathematical modeling and analysis of the Delta robot with flexible links [J]. Computers & Mathematics with Applications,2016,71(10):1973-1989.
[16] 金宇杰,龚堰珏,赵罘.基于模拟退火量子遗传算法的焊接机器人轨迹规划 [J].现代制造工程,2024(1):33-38.

Joint space trajectory planning of robot based on hybrid genetic particle swarm optimization

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	HUANG Kaiqi, ZOU Xiumei, LIU Zhengchao. Pose estimation of peg-in-hole assembly based on SHUK-SVSF algorithm [J]. Modern Manufacturing Engineering, 2025, 538(7): 105-112.
[2]	LIAO Xuechao, XIANG Guihong, RUAN Bing, TIAN Ruili, ZHONG Shi. Research on flexible job-shop scheduling problem with AGV quantity constraints [J]. Modern Manufacturing Engineering, 2025, 537(6): 11-21.
[3]	JING Huicheng, ZHANG Bingke, ZHANG Jingxuan, GUO Mingliang, SUN Jinchao. Welding robot arm trajectory planning method based on improved particle swarm algorithm [J]. Modern Manufacturing Engineering, 2025, 537(6): 67-72.
[4]	WANG Jiawei, WANG Yan, JI Zhicheng, LIU Xiang. Dynamic bottleneck prediction method for discrete remanufacturing systems based on LMD-QPSO-LSTM [J]. Modern Manufacturing Engineering, 2025, 537(6): 150-160.
[5]	JIN Qiao, YANG Guangrui, WANG Xiao, XU Linghua, ZHANG Fang. Palletizing robot trajectory planning based on A-TD3 [J]. Modern Manufacturing Engineering, 2025, 536(5): 42-52.
[6]	CHEN Dehai, TIAN Senyan, LI Zhijun, WANG Haifeng. Optimization design of eccentric magnetic pole of permanent magnet synchronous motor based on analytical calculation and GA [J]. Modern Manufacturing Engineering, 2025, 536(5): 153-160.
[7]	LIU Jinfei, LIU Yihan, CHEN Ming, HUANG Hua. Intelligent workshop scheduling with multiple varieties and variable batches based on improved IGA [J]. Modern Manufacturing Engineering, 2025, 535(4): 1-10.
[8]	WANG Chun, ZHANG Chaoyang, JI Weixi, LU Jingyu. Research on optimization of production scheduling in discrete workshops considering equipment degradation [J]. Modern Manufacturing Engineering, 2025, 534(3): 31-40.
[9]	LIU Yu, ZHANG Lei, SHAO Jiangen, LIU Haitao, GU Fengping, ZHANG Yue. Design and control of a staircase cleaning robot with scalable rotating robotic arm [J]. Modern Manufacturing Engineering, 2025, 534(3): 60-68.
[10]	XU Jiawei, LI Lei, WANG Jianhua, ZHANG Yajun, QIN Jiewei, LIU Xuzhen. Time-optimal trajectory planning of manipulator based on TCSPSO algorithm [J]. Modern Manufacturing Engineering, 2025, 534(3): 69-76.
[11]	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.
[12]	LI Juncong, HUANG Xiang, ZENG Jing, WANG Qunsheng. Study on adaptive control strategy of hunting stability for high-speed trains [J]. Modern Manufacturing Engineering, 2025, 533(2): 61-68.
[13]	HUO Junjie, WANG Zhijian. Process planning and workshop scheduling integrated optimization adopting new coding mode genetic algorithm [J]. Modern Manufacturing Engineering, 2024, 528(9): 25-33.
[14]	YANG Xingchen, CHANG Daofang. Research on collaborative mixed flow production scheduling of multiple automobile factories in a limited buffer zone [J]. Modern Manufacturing Engineering, 2024, 527(8): 9-18.
[15]	ZHANG Miaomiao, HOU Rongguo, LÜ Zhe, WANG Longqing, SHI Guangxing, WANG Zhongqing. Experimental study on the surface properties of AWJ surface strengthening 3D printed AlSi10Mg based on GA-GRNN [J]. Modern Manufacturing Engineering, 2024, 526(7): 35-41.