基于扩展任务的双臂机器人位姿优化被引量：2

Pose Optimization of Dual Manipulators System Based on Augmented Task

下载PDF

导出

摘要为了能够在不修改工业机器人控制器的逆解算法的前提下对双机械臂系统进行位姿优化,同时要求以双臂各向同性指标为强化目标,设计出基于扩展任务的双臂姿态优化方法。首先对双臂机器人的协作任务进行了运动学分析与建模,然后基于最近被提出的一种新型的通用冗余机械臂位姿优化方法对双臂位姿优化进行数学描述,并表明了优化指标-双臂各向同性指标的几何和物理意义。再利用蒙特卡洛采样方法和非线性回归拟合出了主机械臂在操作空间的位姿与协作任务的位姿之间的数学关系,即扩展任务的数学模型。最后在ABB Robot Studio机器人仿真软件中对双臂系统进行主从协作运动任务的仿真,结果表明:利用扩展任务的优化方法可以实现以各向同性指标强化为目标的双臂系统的位姿优化,可以使两只机械臂都远离肘关节奇点和肩关节奇点,并且表明本质上还可以减小机械臂的条件数的值。 In order to optimize the pose of the dual manipulators system without modifying the inverse kinematics algorithms in the industrial robot controller. In the meantime the isotropic index of robot is enforced.A dual manipulators pose optimization Method based on augmented task is proposed. In this paper,firstly the kinematical analysis and modelling of the cooperative task of the dual manipulators are carried out,then the mathematic description of pose optimization is established based on a newpose optimization method for redundant manipulator. At last the relationship between the pose of the leader manipulator and the pose of the cooperative task is established based on Monte Carlo sampling and nonlinear regression method so the augmented task mathematical model is established. The leader-follower task simulation was performed in ABB Robot Studio,and the results shows that the pose optimization method can be realized and both manipulators are away from elbowsigularity and shoulder sigularity. In addition it shows that condition number of the manipulators is reduced.

作者郭鹏房灵申赵明扬朱思俊

机构地区中国科学院沈阳自动化研究所机器人学国家重点实验室中国科学院大学中国科学院沈阳自动化研究所扬州工程技术研究中心

出处《组合机床与自动化加工技术》北大核心 2018年第1期8-12,17,共6页 Modular Machine Tool & Automatic Manufacturing Technique

基金江苏省省政策引导类计划:激光拼焊焊缝跟踪与质量检测系统研制(BY201506301)

关键词位姿优化双臂机器人冗余机器人 pose optimization dual manipulators redundant robot

分类号 TH165 [机械工程—机械制造及自动化] TG659 [金属学及工艺—金属切削加工及机床]

引文网络
相关文献

参考文献2

1梁新荣.机器人协调控制及其关节结构优化[J].五邑大学学报（自然科学版）,1999,13(1):42-48. 被引量：8
2谢碧云,赵京.机器人运动灵活性问题研究概述[J].机械科学与技术,2011,30(8):1386-1393. 被引量：13

二级参考文献27

1Salisbury J K, Craig J J. Articulated hands: force control and ki-nematic issues[J].International Journal of Robotics Re-search, 1982,1(1):4- 17. 被引量：1
2Nakamura Y. Advanced Robotics Rendundancy and Optimi-nation[ M].USA; Addidon-Wesley Publishing Company, 1991. 被引量：1
3Merlet J P. Jacobian, manipulability, condition number, and ac-curacy of parallel robots[J].Transactions of the ASME.Journal of Mechanical Design, 2006,128 (1):199- 206. 被引量：1
4Yoshikawa T. Manipulability of robotic mechanisms[ J ].Inter-national Journal of Robotics Research, 1985,4(2):3- 9. 被引量：1
5陆震.冗余自由度机器人原理及应用[ M].北京:机械工业出版社,2006. 被引量：1
6Mayorga R V,Ressa B,Wong A K C. A dexterity measure forrobot manipulators[ A].1990 IEEE International Conferenceon Robotics and Automation[C],Cincinnati, Ohio, 1990,1:656- 661. 被引量：1
7Mayorga R V, Ressa B, Wong A K C. A kinematic criterion forthe design optimization of robot manipulators [ A ]. 1991 IEEEInternational Conference on Robotics and Automation, Sac-ramento[ C],CA, 1991,1:578-583. 被引量：1
8Mayorga R V, et at. Optimal upper bound conditioning for ma-nipulator kinematic design optimization[A].Proceedings of the1997 IEEE/RSJ International Conference on Intelligent Ro-hot and Systems. Innovative Robotics for Real-World Appll-cations [ C ],1997,1:70- 75. 被引量：1
9Jin-oh Kim, Khosia K. Dexterity measures for design and controlof manipulators [ J ] . IEEE International Workshop on IntelH-gent Robots and Systems, 1991, (2) :758- 763. 被引量：1
10Lipkin H, Duffy J. Hybrid twist and wrench control for a roboticmanipulator [ J].Transcations ASME, Journal MechanicalTranscations&Automation In Design, 1988,110:138- 144. 被引量：1