Abstract
Robot kinematic calibration is of capital significance for improving the absolute positioning accuracy in many industrial applications. Aiming at identification and compensation of the kinematic errors in a 6 degree of freedom industrial robot manipulators, a technique for absolute calibration of robot is elaborated and achieved. A calibration model which takes into account all possible geometric error parameters is deduced by combining the geometrical errors in link parameters, base frame and end-effector of the robot. A minimum set of error parameters is established with 27 geometric error parameters which meets three basic requirements: model completeness, parameter minimality and model continuity. An iterative optimization process based on the least squares theory is employed in estimating the values of these kinematic errors with better precision. The effectiveness and anti-noise performance of the proposed algorithm are analyzed by the means of computer simulation. In addition, an effective compensation method based on incremental controlling algorithm is introduced which can be directly applied to Cartesian trajectory controlling of robot without having to calculate the inverse kinematics. An experimental validation with a 6 degree of freedom serial robot shows the effectiveness of the proposed method in improving the absolute positioning accuracy. Experimental results indicate that the proposed method improves the mean/maximum position errors at the measurement points on the end-effector from 2.66 mm/4.42 mm to 0.20 mm/0.36 mm respectively. Furthermore, it is obviously that the proposed technique is valid for the kinematic parameters identification and compensation of most typical 6 degree of freedom serial industrial robot [1,2,3,4,5].
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References
Chen-Gang, Li-Tong, Chu-Ming, Xuan, J.Q., Xu, S.H.: Review on kinematics calibration technology of serial robots. Int. J. Precis. Eng. Manuf. 15(8), 1759–1774 (2014)
Hayati, S., Mirmirani, M.: Improving the absolute positioning accuracy of robot manipulators. J. Robot. Syst. 2(4), 397–413 (1985)
Veitschegger, W.K., Wu, C.H.: Robot calibration and compensation. IEEE J. Robot. Autom. 4(6), 643–656 (1988)
Judd, R.P., Knasinski, A.B.: A technique to calibrate industrial robots with experimental verification. IEEE Trans. Robot. Autom. 6(1), 20–30 (1990)
Gatla, C.S., Lumia, R., Wiid, J., Starr, G.: An automated method to calibrate industrial robots using a virtual closed kinematic chain. IEEE Trans. Robot. 23(6), 1105–1116 (2007)
Ginani, L.S., Motta, J.M.S.T.: Theoretical and practical aspects of robot calibration with experimental verification. J. Braz. Soc. Mech. Sci. Eng. 33(1), 15–21 (2011)
Newman, W.S., Birkhimer, C.E., Horning, R.J., Wilkey, A.T.: Calibration of a Motoman P8 robot based on laser tracking. In: 2000 ICRA. Millennium Conference. IEEE International Conference on Robotics and Automation, San Francisco, pp. 3597–3602. IEEE (2000)
Lightcap, C., Hamner, S., Schmitz, T., Banks, S.: Improved position accuracy of the PA10-6CE robot with geometric and flexibility calibration. IEEE Trans. Robot. 24(2), 452–456 (2008)
Ha, I.C.: Kinematic parameter calibration method for industrial robot manipulator using the relative position. J. Mech. Sci. Technol. 22(6), 1084–1090 (2008)
Nubiola, A., Bonev, I.A.: Absolute calibration of an ABB IRB 1600 robot using a laser tracker. Robot. Comput. Integr. Manuf. 29(1), 236–245 (2013)
Zhou, J., Nguyen, H.N., Kang, H.J.: Simultaneous identification of joint compliance and kinematic parameters of industrial robots. Int. J. Precis. Eng. Manuf. 15(11), 2257–2264 (2014)
Renders, J.M., Rossignol, E., Becquet, M., Hanus, R.: Kinematic calibration and geometrical parameter identification for robots. IEEE Trans. Robot. Autom. 7(6), 721–732 (1991)
Alici, G., Shirinzadeh, B.: Enhanced stiffness modeling, identification and characterization for robot manipulators. IEEE Trans. Robot. 21(4), 554–564 (2005)
Klimchik, A., Wu, Y., Dumas, C., Caro, S., Furet, B., Pashkevich, A.: Identification of geometrical and elastostatic parameters of heavy industrial robots. In: 2013 IEEE International Conference on Robotics and Automation, Karlsruhe, pp. 3707–3714. IEEE (2013)
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Gao, J., Han, H., Geng, J., Li, Z., Li, D. (2020). Kinematic Parameters Identification and Compensation of an Industrial Robot. In: Duan, B., Umeda, K., Hwang, W. (eds) Proceedings of the Seventh Asia International Symposium on Mechatronics. Lecture Notes in Electrical Engineering, vol 588. Springer, Singapore. https://doi.org/10.1007/978-981-32-9437-0_77
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DOI: https://doi.org/10.1007/978-981-32-9437-0_77
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