An inertial parameter identification method of eliminating system damping effect for a six-degree-of-freedom parallel manipulator 被引量：5

An inertial parameter identification method of eliminating system damping effect for a six-degree-of-freedom parallel manipulator

原文传递

导出

摘要 A new simple and effective inertial parameter identification method based on sinusoidal vibrations of a six-degree-of-freedom parallel manipulator is proposed. Compared with previously known identification algorithms, the advantages of the new approach are there is no need to design the excitation trajectory to consider the condition number of the observation matrix and the inertial matrix can be accurately defined regardless of the effect of viscous friction. In addition, the use of a sinusoidal exciting trajectory allows calculation of the velocities and accelerations from the measured position response. Simulations show that the new approach has acceptable tolerance of dry friction when using a simple coupling parameter modified formula. The experimental application to the hydraulically driven Stewart platform demonstrates the capability and efficiency of the proposed identification method. A new simple and effective inertial parameter identification method based on sinusoidal vibrations of a six-degree-of-freedom parallel manipulator is proposed. Compared with previously known identification algorithms, the advantages of the new approach are there is no need to design the excitation trajectory to consider the condition number of the observation matrix and the inertial matrix can be accurately defined regardless of the effect of viscous friction. In addition, the use of a sinusoidal exciting trajectory allows calculation of the velocities and accelerations from the measured position response. Simulations show that the new approach has acceptable tolerance of dry friction when using a simple coupling parameter modified formula. The experimental application to the hydraulically driven Stewart platform demonstrates the capability and efficiency of the proposed identification method.

作者 Tian Tixian Jiang Hongzhou Tong Zhizhong He Jingfeng Huang Qitao

机构地区 School of Mechatronics Engineering

出处《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2015年第2期582-592,共11页 中国航空学报（英文版）

基金 financially supported by the National Natural Science Foundation of China (No. 50975055)

关键词 Hydraulically IDENTIFICATION Inertial parameter Parallel manipulator Sinusoidal vibration Hydraulically Identification Inertial parameter Parallel manipulator Sinusoidal vibration

分类号 TP241 [自动化与计算机技术—检测技术与自动化装置]

引文网络
相关文献

参考文献25

1Merlet JP. Parallel robots. 3rd ed. Netherlands: Springer; 2006.
2Chen YX, McInroy JE. Decoupled control of flexure-jointed hexapods using estimated joint-space mass-inertia matrix. IEEE Trans Control Syst Technol 2004;12(3):4131.
3Plnmmer AR, Guinzio PS. Modal control of an electrohydrostatic flight simulator motion system. Proceedings of ASME 2009 dynamic systems and control conference; 2009 October 12-14; Hollywood, California. 2009. p. 345- 52.
4Jiang HZ, He JF, Tong ZZ. Modal space control for a hydrauli- cally driven Stewart platform. J Control Eng Technol 2012;2(3): 106-15.
5Barreto J, Mufioz LE. Inertia parameter identification using a Stewart platform. Proceedings of 2010 41st international sympo- sium on robotics ( ISR) and 2010 6th german conference on robotics (ROBOTIK); 2010 June 7-9; Munich, Germany. Berlin: VDE; 2010. p. 765-72.
6Kraus W, Schmidt V, Rajendra P, Pott A. Load identification and compensation for a cable-driven parallel robot. Proceedings of 2013 IEEE international conference on robotics and automation (ICRA); 2013 May 6-10; Karls-ruhe, Germany. Piscataway: IEEE; 2013. p. 2470-5.
7Honegger M, Brega R, Schweitzer G. Application of a nonlinear adaptive controller to a 6 dof parallel manipulator, Proceedings of IEEE international conference on robotics and automation; 2000 April 24-28; San Francisco, CA, USA. Piscataway: IEEE; 2000. p. 1930-5.
8Vivas A, Poignet P, Marquet F, Pierrot F, Gautier M. Experimental dynamic identification of a fully parallel robot. Proceedings of IEEE international conference on robotics and automation; 2003 September 14-19; Taipei. Piscataway: IEEE; 2003. p. 3278-83.
9Abdellatif H, l-teimann B, Holz C. Time-effective direct dynamics identification of parallel manipulators for rood-el-based feedfor- ward control. Proceedings of the IEEE/ASME international conference on advanced intelligent mechatronics; 2005 July 24-28; Monterey, CA, USA. Piscataway: IEEE; 2005. p. 777-82.
10Chen CT, Renn JC, Yan ZY. Experimental identliacatlon oI inertial and friction parameters for electro-hydraulic motion simulators. Mechatronics 2011;21(1):1-10.

同被引文献55

1刘雄伟,郑亚青,林麒.应用于飞行器风洞试验的绳牵引并联机构技术综述[J].航空学报,2004,25(4):393-400. 被引量：38
2Chen Hua Chen Weishan Liu Junkao.Optimal Design of Stewart Platform Safety Mechanism[J].Chinese Journal of Aeronautics,2007,20(4):370-377. 被引量：7
3吴东苏,顾宏斌.Adaptive Sliding Control of Six-DOF Flight Simulator Motion Platform[J].Chinese Journal of Aeronautics,2007,20(5):425-433. 被引量：21
4于靖军,刘辛军,丁希仑,等.机器人机构学的数学基础[M].北京:机械工业出版社,2007.
5Paredis C J,Khosla P K.Kinematic design of serial link manipulators from task specifications[J].IntJ Robotics Res,1993,12(3):274-87.
6Khosla P K.A multi-population genetic algorithm and its application to design of manipulators[J].In:Proc.IEEE/RSJ int conf on intell robots and syst,1992,3(24):7-10.
7Sarosh P,Tarek S.Task based synthesis of serial manipulators[J].Journal of Advanced Research,2015,39(8):2-7.
8Luv A,Kush A,Ruth J U.Use of artificial neural networks for the development of an inverse kinematic solution and visual identification of singularity zone[J].Variety Management in Manufacturing,2014,8(10):812-817.
9Monika Z F,Ana M D.Complexity analysis for calculating the jacobian matrix of 6-D0F reconfigurable machines[J].Variety Management in Manufacturing,2014,2(19):218-223.
10Yong J K,Shan B C,Sang B K,et al.A stiffness-adjustable hyper redundant manipulator using a variable neutral-line mechanism for minimally invasive surgery[J].IEEE Transactions on Robotics,2014,2(30):382-394.

引证文献5

1胡燕祝,李雷远.基于多层感知人工神经网络的执行机构末端综合定位[J].农业工程学报,2016,32(1):22-29. 被引量：4
2高蕾娜,刘丽,唐辉阳.4自由度示教机械手构型设计与运动分析[J].实验室研究与探索,2016,35(7):44-47. 被引量：3
3Li Kangkang,Jiang Hongzhou,Cui Zuo,Huang Qun.Variable stiffness design of redundantly actuated planar rotational parallel mechanisms[J].Chinese Journal of Aeronautics,2017,30(2):818-826. 被引量：4
4Guohua ZHAO,Dan WANG,Liangbao LIU,Jiangzhen GUO,Wuyi CHEN,He LI.Positioning error compensation for parallel mechanism with two kinematic calibration methods[J].Chinese Journal of Aeronautics,2020,33(9):2472-2489. 被引量：4
5Zhiyu NI,Jinguo LIU,Zhigang WU,Xinhui SHEN.Identification of the state-space model and payload mass parameter of a flexible space manipulator using a recursive subspace tracking method[J].Chinese Journal of Aeronautics,2019,32(2):513-530. 被引量：9

二级引证文献24

1魏晓艳,何正华,彭聚胜,张长云.带旋前方肌蒂尺骨瓣植入术治疗腕舟骨陈旧性骨折[J].中华手外科杂志,2000,16(2):122-122. 被引量：11
2胡燕祝,李雷远.Kalman滤波-BP神经网络在执行机构自主定位中的应用[J].北京邮电大学学报,2016,39(6):110-115. 被引量：3
3许超,卢雪梅,郑艳龙,白永生.六自由度机械手课程设计与实现[J].实验技术与管理,2017,34(4):199-201. 被引量：8
4于海祥.基于MLP神经网络的数控铣床几何误差补偿方法[J].机械设计与制造,2017(8):140-143. 被引量：5
5Kangkang Li,Hongzhou Jiang,Siyu Wang,Jianmin Yu.A Soft Robotic Fish with Variable-stiffness Decoupled Mechanisms[J].Journal of Bionic Engineering,2018,15(4):599-609. 被引量：5
6张震,张亚.基于PSO-RBF神经网络的串联机械臂逆运动学分析[J].科学技术与工程,2019,19(36):195-200. 被引量：10
7肖国红,弓清忠,纪志飞.基于PLC控制的5自由度机械手实验平台开发[J].机械工程师,2020(8):15-17. 被引量：3
8肖国红,纪志飞,弓清忠.5自由度机械手实验平台的运动学分析[J].内燃机与配件,2020(22):223-224. 被引量：1
9李康康,陈巍巍.扑翼的变刚度设计及其对升力和推力的影响[J].航空学报,2020,41(11):413-422. 被引量：3
10陈修龙,陈天祥.机械原理课程设计中机器人机构的动力学建模与仿真[J].实验室研究与探索,2021,40(2):109-114. 被引量：10

1Qiang MENG,Tao ZHANG,Jing-feng HE,Jing-yan SONG,Jun-wei HAN.Dynamic modeling of a 6-degree-of-freedom Stewart platform driven by a permanent magnet synchronous motor[J].Journal of Zhejiang University-Science C(Computers and Electronics),2010,11(10):751-761. 被引量：1
2Hai-Ping Du,Nong Zhang.Robust Active Suspension Design Subject to Vehicle Inertial Parameter Variations[J].International Journal of Automation and computing,2010,7(4):419-427.
3王孙安,万亚民.A Mixed Real-time Algorithm for the Forward Kinematics of Stewart Parallel Manipulator[J].Journal of Electronic Science and Technology of China,2006,4(2):173-180.
4Yuzhe LIU Liping WANG Jun WU Jinsong WANG.A comprehensive analysis of a 3-P （Pa） S spatial parallel manipulator[J].Frontiers of Mechanical Engineering,2015,10(1):7-19. 被引量：1
5Li Jian Tang Xiaoqiang Shao Zhufeng Yao Rui.Hybrid position/force control strategy and experiment of the six-cable driven parallel manipulator for the forty-meter aperture radio telescope[J].High Technology Letters,2012,18(3):230-237.
6Liang YAN,I-Ming CHEN,Song-huat YEO,Yan CHEN,Gui-lin YANG.A high-dexterity low-degree-of-freedom hybrid manipulator structure for robotic lion dance[J].Journal of Zhejiang University-Science A(Applied Physics & Engineering),2010,11(4):240-249.
7吴军,李铁民,刘辛军,王立平.Optimal Kinematic Design of a 2-DOF Planar Parallel Manipulator[J].Tsinghua Science and Technology,2007,12(3):269-275. 被引量：2
8FU Jianxun,GAO Feng.Optimal Design of a 3-Leg 6-DOF Parallel Manipulator for a Specific Workspace[J].Chinese Journal of Mechanical Engineering,2016,29(4):659-668. 被引量：15
9GU XiaoBo,CHANG Qing,XU Yong,WANG Dun.Time synchronization and ranging under unknown positions and velocities[J].Science China(Technological Sciences),2017,60(2):271-281.
10ASHITH SHYAM R B,GHOSAL A.Three-degree-of-freedom Parallel Manipulator to Track the Sun for Concentrated Solar Power Systems[J].Chinese Journal of Mechanical Engineering,2015,28(4):793-800. 被引量：1

Chinese Journal of Aeronautics

2015年第2期

浏览历史

内容加载中请稍等...

An inertial parameter identification method of eliminating system damping effect for a six-degree-of-freedom parallel manipulator 被引量：5

参考文献25

同被引文献55

引证文献5

二级引证文献24

相关作者

相关机构

相关主题

浏览历史