冗余机器人喷涂系统改进人工鱼群逆运动学求解算法

doi:10.3969/j.issn.1004-132X.2022.11.008

摘要/Abstract

摘要： 针对一种带有冗余自由度的船舶分段机器人喷涂系统逆运动学问题，使用改进Denavit-Hartenberg(DH)参数法建立了机器人系统的运动学模型。以位姿误差最小及关节行程最短为目标，构建了冗余机器人逆运动学问题优化模型，提出一种改进人工鱼群算法( IAFSA)对模型进行求解。IAFSA引入基于正态分布的视野范围及移动步长动态调整策略来改善解的精度并缩短计算时间，提高算法综合性能。与人工鱼群算法和混合改进人工鱼群算法进行了对比实验，实验结果表明IAFSA搜索能力强、收敛速度快、计算时间较短，逆解良好的精度和误差稳定性在SolidWorks Motion仿真中得到验证，体现了IAFSA算法在冗余机器人逆运动学求解问题中的有效性。

关键词: 改进人工鱼群算法, 冗余机器人, 逆运动学, 正态分布衰减, 船舶喷涂

Abstract: In order to solve the inverse kinematics problems of a redundant robotic spraying system for ship segments, the modified DH method was used to establish the kinematics model of the robotic systems. An optimization model for inverse kinematics of redundant robots was established to minimize position errors, posture errors and joint travels, and an IAFSA was proposed to solve the model. The dynamic adjustment strategy of visual ranges and step size based on normal distribution was introduced to enhance the precision of the solutions and reduce the computation time, improving the overall performance of the algorithm. Compared with artificial fish swarm algorithm and hybrid IAFSA, the experimental results show that IAFSA possesses stronger search ability, faster convergence speed and relatively less computation time. The high accuracy of the solutions and good stability of the errors were verified in the SolidWorks Motion simulations, which demonstrates the effectiveness of IAFSA in solving the inverse kinematics problems of redundant robots.

Key words: improved artificial fish swarm algorithm(IAFSA), redundant robot, inverse kinematics, normal distribution attenuation, ship spraying

中图分类号:

TP242

刘雪梅, 冯焱, 杨振, 李爱平, 卢军国. 冗余机器人喷涂系统改进人工鱼群逆运动学求解算法[J]. 中国机械工程, 2022, 33(11): 1317-1323.

LIU Xuemei, FENG Yan, YANG Zhen, LI Aiping, LU Junguo. IAFSA for Solving Inverse Kinematics of Redundant Robotic Spraying System[J]. China Mechanical Engineering, 2022, 33(11): 1317-1323.

导出引用管理器 EndNote|Ris|BibTeX

链接本文: http://www.cmemo.org.cn/CN/10.3969/j.issn.1004-132X.2022.11.008

http://www.cmemo.org.cn/CN/Y2022/V33/I11/1317

参考文献

［1］中华人民共和国工业和信息化部. 船舶总装建造智能化标准体系建设指南(2020版)［EB/OL］. (2020-08-10) ［2021-05-20］. https:∥www.miit.gov.cn/
cms_files/filemanager/oldfile/miit/n1146285/n1146352/n3054355/n3057497/n3057498/c8061208/part/8061223.pdf.
Ministry of Industry and Information Technology of the Peoples Republic of China. Guidelines for the Construction of Standard System for Intelligentization of Ship Assembly Construction (2020 Edition) ［EB/OL］. (2020-08-10) ［2021-05-20］. https:∥www.miit.gov.cn/cms_files/filemanager/oldfile/miit/n1146285/n1146352/n3054355/n3057497/n3057498/c8061208/part/8061223.pdf.
［2］衣正尧,林焰,刘英想.造船工业机器人现状分析［J］.机械工程师,2016(7):89-92.
YI Zhengyao, LIN Yan, LIU Yingxiang. Analysis of the State of Art of Industrial Robots in Shipbuilding Industry［J］.Mechanical Engineer, 2016(7):89-92.
［3］JIN Long, LI Shuai, LUO Xin, et al. Neural Dynamics for Cooperative Control of Redundant Robot Manipulators［J］. IEEE Transactions on Industrial Informatics, 2018 (9):3812-3821.
［4］FERREIRA L A, FIGUEIRA Y L, IGLESIAS I F, et al. Offline CAD-based Robot Programming and Welding Parametrization of a Flexible and Adaptive Robotic Cell Using Enriched CAD/CAM System for Shipbuilding［J］. Procedia Manufacturing, 2017(11)：215-223.
［5］缪东晶,吴聊,徐静,等.飞机表面自动喷涂机器人系统与喷涂作业规划［J］.吉林大学学报(工学版), 2015, 45(2)：547-553.
MIU Dongjin, WU Liao, XU Jing, et al. Automatic Spraying Robot Systemfor Aircraft Surfaces and Spraying Operation Planning ［J］. Journal of Jilin University(Engineering and Technology Edition), 2015, 45(2)：547-553.
［6］陆震. 冗余自由度机器人原理及应用［M］. 北京：机械工业出版社, 2006.
LU Zhen. Principle and Application of Robots with Redundant DOFs［M］. Beijing：China Machine Press, 2006.
［7］YANG Lei, ZHANG George. An Analytic Solution Study for a 7-DOF Redundant Robot Manipulator［C］∥2018 IEEE 8th Annual International Conference on CYBER Technology in Automation, Control, and Intelligent Systems(CYBER). Tianjin, 2018：1057-1061.
［8］廖柏林,梁平元,杨喜.基于伪逆的冗余机械臂运动控制的优化方案［J］.信息与控制, 2013, 42(5)：645-651.
LIAO Bolin, LIANG Pingyuan, YANG Xi. Pseudoinverse-based Optimization Scheme for Motion Control of Redundant Robot Manipulators ［J］. Information and Control, 2013, 42(5):645-651.
［9］BENZAOUI M, CHEKIREB H, TADJINE M. Redundant Robot Manipulator Control with Obstacle Avoidance Using Extended Jacobian Method［C］∥18th Mediterranean Conference on Control and Automation. Marrakech, 2010:371-376.
［10］刘世平,曹俊峰,孙涛,等.基于BP神经网络的冗余机械臂逆运动学分析［J］.中国机械工程, 2019, 30(24)：2974-2977.
LIU Shiping, CAO Junfeng, SUN Tao, et al. Inverse Kinematics Analysis of Redundant Manipulators Based on BP Neural Network ［J］. China Mechanical Engineering, 2019, 30(24):2974-2977.
［11］ANTONIO G L C , LOPEZ F C, ARANA D N , et al. Inverse Kinematics for a Manipulator Robot Based on Differential Evolution Algorithm［C］∥2018 IEEE Latin American Conference on Computational Intelligence (LA-CCI). Gudalajara, 2018:1-5.
［12］DERELI S, KKER R. A Meta-heuristic Proposal for Inverse Kinematics Solution of 7-DOF Serial Robotic Manipulator：Quantum Behaved Particle Swarm Algorithm ［J］. Artificial Intelligence Review, 2020, 53(2):949-964.
［13］CHENG Yaozong, LI Chunxu, LI Shuai, et al. Motion Planning of Redundant Manipulator with Variable Joint Velocity Limit Based on Beetle Antennae Search Algorithm［J］. IEEE Access, 2020, 8: 138788-138799.
［14］ZHANG Li, XIAO Nanfeng. A Novel Artificial Bee Colony Algorithm for Inverse Kinematics Calculation of 7-DOF Serial Manipulators［J］. Soft Computing, 2019, 23(10):3269-3277.
［15］罗天洪,陈才,李富盈.基于时变萤火虫群算法的冗余机器人手臂逆解［J］.计算机集成制造系统,2016, 22(2) :576-582.
LUO Tianhong, CHEN Cai, LI Fuying. Inverse Solution of Redundant Robot Arm Based on Glowworm Swarm Optimization Algorithm of Time-Varying ［J］. Computer Integrated Manufacturing Systems,2016,22(2):576-582.
［16］陶帝豪,刘蓉,雷勇杰,等.基于绿色供应链的冷链物流配送路径优化［J］.工业工程,2019,22(2):89-95.
TAO Dihao, LIU Rong, LEI Yongjie, et al. A Research on Routing Optimization of Cold Chain Distribution Based on Green Supply Chain ［J］. Industrial Engineering Journal, 2019,22(2):89-95.
［17］刘大贺,韩晓娟,李建林.基于光伏电站场景下的梯次电池储能经济性分析［J］.电力工程技术,2017,36(6):27-31.
LIU Dahe, HAN Xiaojuan, LI Jianlin. Economic Analysis of Echelon Battery Energy Storage Based on Artificial Fish Swarm Algorithm ［J］. Jiangsu Electrical Engineering, 2017, 36(6):27-31.
［18］杜璞良,杜欣慧.钢铁企业中变压器投切控制节能策略研究［J］.计算机仿真,2017,34(10):78-82.
DU Puliang, DU Xinhui. Research on Energy Saving Strategy of Transformer Switching Control in Iron and Steel Enterprises ［J］. Computer Simulation, 2017, 34(10)：78-82.
［19］于振中,李强,樊启高.智能仿生算法在移动机器人路径规划优化中的应用综述［J］.计算机应用研究,2019,36(11):3210-3219.
YU Zhenzhong, LI Qiang, FAN Qigao. Survey on Application of Bioinspired Intelligent Algorithms in Path Planning Optimization of Mobile Robots ［J］. Application Research of Computers, 2019, 36(11)：3210-3219.
［20］CRAIG J. 机器人学导论［M］. 贠超, 李成群，陈心颐，等, 译. 北京：机械工业出版社, 2006.
CRAIG J. Introduction to Robotics Mechanics and Control ［M］.YUAN Chao, LI Chengqun, CHEN Xinyi, et al, Translated. Beijing：China Machine Press, 2006.
［21］李晓磊, 钱积新. 人工鱼群算法:自下而上的寻优模式［C］∥过程系统工程2001年会论文集. 荆门, 2001:76-82.
LI Xiaolei, QIAN Jixin. Artificial Fish Swarm Algorithm：a Bottom-up Optimization Pattern［C］∥Proceedings of the 2001 Conference of PSE. Jinmen, 2001:76-82.
［22］张毅,杨光辉,花远红.基于改进人工鱼群算法的机器人路径规划［J］.控制工程,2020,27(7):1157-1163.
ZHANG Yi, YANG Guanghui, HUA Yuanhong. Robot Path Planning Based on Improved Artificial Fish Swarm Algorithm［J］. Control Engineering of China, 2020, 27(7):1157-1163.

[1]	陈卓凡, 周坤, 秦菲菲, 王斌锐. 基于改进量子粒子群优化算法的机器人逆运动学求解#br# #br# [J]. 中国机械工程, 2024, 35(02): 293-304.
[2]	刘秀莹, 张建军, 刘承磊, 牛建业, 戚开诚, 郭士杰. 基于工作空间的踝关节康复广义球面并联机器人运动学参数优化[J]. 中国机械工程, 2021, 32(16): 1921-1929.
[3]	张月, 董雷, 宦荣华, 黄志龙. 风电叶片管道内窥履带机器人的设计与运动分析[J]. 中国机械工程, 2021, 32(15): 1884-1889.
[4]	吉阳珍, 侯力, 罗岚, 罗培, 刘旭槟, 梁爽. 基于组合优化算法的6R机器人逆运动学求解[J]. 中国机械工程, 2021, 32(10): 1222-1232.
[5]	肖帆;李光;游雨龙. 空间3R机械手逆向运动学的多模块神经网络求解[J]. 中国机械工程, 2019, 30(10): 1233-1238.
[6]	裴九芳;许德章;王海. 基于旋量理论的三指机器人灵巧手逆运动学分析[J]. 中国机械工程, 2017, 28(24): 2975-2980.
[7]	杨震, 杨文玉, 张晓平. 机器人逆运动学的奇异鲁棒性算法[J]. 中国机械工程, 2014, 25(8): 995-1000.
[8]	刘玮, 常思勤. 一种新型并联机器人的奇异性与工作空间研究[J]. 中国机械工程, 2012, 23(7): 786-790.
[9]	印峰, 王耀南, 夏汉民. 多关节机器人逆运动学问题的实时求解 [J]. 中国机械工程, 2010, 21(10): 1143-1148.
[10]	赵大兴;李九灵;赵智明;周小明;. 集装箱喷漆机器人逆运动学分析[J]. J4, 2008, 19(22): 0-2649.
[11]	王平, 杨沿平, 邓晓. 基于模具表面抛光机器人系统的运动控制研究[J]. 中国机械工程, 2007, 18(20): 2422-2425.
[12]	刘松国, 朱世强, 程永伦, . 一般6R机器人的高精度逆运动学算法研究[J]. 中国机械工程, 2007, 18(20): 2414-2418.