Pose error prediction and real-time compensation of a 5-DOF hybrid robot

被引:46
作者
Liu, Haitao [1 ]
Yan, Zhibiao [1 ]
Xiao, Juliang [1 ]
机构
[1] Tianjin Univ, Key Lab Modern Mech & Equipment Design State, Minist Educ, Tianjin 300072, Peoples R China
来源
MECHANISM AND MACHINE THEORY | 2022年 / 170卷
基金
中国国家自然科学基金; 欧盟地平线“2020”;
关键词
Hybrid robot; Calibration; Neural network; Error prediction; Real-time compensation; INDUSTRIAL ROBOT; CALIBRATION; ACCURACY; IDENTIFICATION;
D O I
10.1016/j.mechmachtheory.2022.104737
中图分类号
TH [机械、仪表工业];
学科分类号
0802 ;
摘要
This paper proposes a new calibration method for a 5-DOF hybrid robot, concentrating particularly on addressing the contradiction between measurement efficiency and calibration accuracy and the real-time compensation with high precision. The approach involves two successive steps: (1) an error prediction model based on a back propagation neural network (BPNN) and the Denavit-Hartenberg (D-H) method is established by the strategy of pose error decomposition; (2) an embedded joint error compensator based on a BPNN is designed to achieve real-time compensation with high precision. Experimental verification shows that the maximum position/orientation errors can be reduced by 87.05%/85.62% over the entire workspace of the robot after calibration.
引用
收藏
页数:19
相关论文
共 36 条
[1]   A systematic technique to estimate positioning errors for robot accuracy improvement using laser interferometry based sensing [J].
Alici, G ;
Shirinzadeh, B .
MECHANISM AND MACHINE THEORY, 2005, 40 (08) :879-906
[2]   Prediction of geometric errors of robot manipulators with Particle Swarm Optimisation method [J].
Alici, Guersel ;
Jagielski, Romuald ;
Sekercioglu, Y. Ahmet ;
Shirinzadeh, Bijan .
ROBOTICS AND AUTONOMOUS SYSTEMS, 2006, 54 (12) :956-966
[3]   Prediction and compensation of relative position error along industrial robot end-effector paths [J].
Angelidis, Antonios ;
Vosniakos, George-Christopher .
INTERNATIONAL JOURNAL OF PRECISION ENGINEERING AND MANUFACTURING, 2014, 15 (01) :63-73
[4]   Calibrate parallel machine tools by using interval type-2 fuzzy interpolation method [J].
Bai, Ying ;
Wang, Dali .
INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2017, 93 (9-12) :3777-3787
[5]   On the Comparison of Trilinear, Cubic Spline, and Fuzzy Interpolation Methods in the High-Accuracy Measurements [J].
Bai, Ying ;
Wang, Dali .
IEEE TRANSACTIONS ON FUZZY SYSTEMS, 2010, 18 (05) :1016-1022
[6]   Off-line compensation of the tool path deviations on robotic machining: Application to incremental sheet forming [J].
Belchior, J. ;
Guillo, M. ;
Courteille, E. ;
Maurine, P. ;
Leotoing, L. ;
Guines, D. .
ROBOTICS AND COMPUTER-INTEGRATED MANUFACTURING, 2013, 29 (04) :58-69
[7]   Application of Universal Kriging for Calibrating Offline-Programming Industrial Robots [J].
Cai, Ying ;
Yuan, Peijiang ;
Shi, Zhenyun ;
Chen, Dongdong ;
Cao, Shuangqian .
JOURNAL OF INTELLIGENT & ROBOTIC SYSTEMS, 2019, 94 (02) :339-348
[8]   A positional error compensation method for industrial robots combining error similarity and radial basis function neural network [J].
Chen, Dongdong ;
Wang, Tianmiao ;
Yuan, Peijiang ;
Sun, Ning ;
Tang, Haiyang .
MEASUREMENT SCIENCE AND TECHNOLOGY, 2019, 30 (12)
[9]   A Compensation Method for Enhancing Aviation Drilling Robot Accuracy Based on Co-Kriging [J].
Chen, Dongdong ;
Yuan, Peijiang ;
Wang, Tianmiao ;
Cai, Ying ;
Xue, Lei .
INTERNATIONAL JOURNAL OF PRECISION ENGINEERING AND MANUFACTURING, 2018, 19 (08) :1133-1142
[10]   A compensation method based on error similarity and error correlation to enhance the position accuracy of an aviation drilling robot [J].
Chen, Dongdong ;
Yuan, Peijiang ;
Wang, Tianmiao ;
Ying, Cai ;
Tang, Haiyang .
MEASUREMENT SCIENCE AND TECHNOLOGY, 2018, 29 (08)
1234