Complete Stiffness Model for a Serial Robot
Alexandr Klimchik, Stephane Caro, Benoit Furet, Anatol Pashkevich
2014
Abstract
The paper addresses a problem of robotic manipulator calibration. The main contributions are in the area of the elastostatic parameters identification. In contrast to other works, the considered approach takes into account elastic properties of both links and joint. Particular attention is paid to generation of the complete and irreducible stiffness model that is suitable for the identification. To solve the problem, physical and algebraic model reduction methods are proposed. They are based on taking into account the physical properties of the manipulator elements and structure of the corresponding observation matrix. The advantages of the developed approach are illustrated by an application example that deals with elastostatic calibration of an industrial robot.
References
- Abele, E., K. Schützer, J. Bauer and M. Pischan, 2012. Tool path adaption based on optical measurement data for milling with industrial robots. Prod. Eng. Res. Devel. 6: 459-465.
- Alici, G. and B. Shirinzadeh, 2005. Enhanced stiffness modeling, identification and characterization for robot manipulators. Robotics, IEEE Transactions on 21: 554-564.
- Chen, Y., J. Gao, H. Deng, D. Zheng, X. Chen and R. Kelly, 2013. Spatial statistical analysis and compensation of machining errors for complex surfaces. Precision Engineering 37: 203-212.
- Dépincé, P. and J.-Y. Hascoët, 2006. Active integration of tool deflection effects in end milling. Part 1. Prediction of milled surfaces. International Journal of Machine Tools and Manufacture 46: 937-944.
- Dumas, C., S. Caro, S. Garnier and B. Furet, 2011. Joint stiffness identification of six-revolute industrial serial robots. Robotics and Computer-Integrated Manufacturing 27: 881-888.
- Karan, B. and M. Vukobratovic, 1994. Calibration and accuracy of manipulation robot models-an overview. Mechanism and Machine Theory 29: 479-500.
- Khalil, W. and E. Dombre, 2004. Modeling, identification and control of robots. Butterworth-Heinemann.
- Klimchik, A., D. Bondarenko, A. Pashkevich, S. Briot and B. Furet, 2014. Compliance error compensation in robotic-based milling. In: Informatics in control, automation and robotics. (J.-L. Ferrier, A. Bernard, O. Gusikhin and K. Madanis, Eds.). Springer International Publishing, pp. 197-216.
- Klimchik, A., D. Chablat and A. Pashkevich, 2014. Stiffness modeling for perfect and non-perfect parallel manipulators under internal and external loadings. Mechanism and Machine Theory 79: 1-28.
- Klimchik, A., A. Pashkevich and D. Chablat, 2013. Cadbased approach for identification of elasto-static parameters of robotic manipulators. Finite Elements in Analysis and Design 75: 19-30.
- Klimchik, A., A. Pashkevich, D. Chablat and G. Hovland, 2013. Compliance error compensation technique for parallel robots composed of non-perfect serial chains. Robotics and Computer-Integrated Manufacturing 29: 385-393.
- Klimchik, A., Y. Wu, G. Abba, B. Furet and A. Pashkevich. Robust algorithm for calibration of robotic manipulator model. 7th IFAC Conference on Manufacturing Modelling, Management, and Control, 2013, 2013.
- Klimchik, A., Y. Wu, C. Dumas, S. Caro, B. Furet and A. Pashkevich. Identification of geometrical and elastostatic parameters of heavy industrial robots. Robotics and Automation (ICRA), 2013 IEEE International Conference on, 6-10 May 2013, 2013.
- Klimchik, A., Y. Wu, A. Pashkevich, S. Caro and B. Furet, 2012. Optimal selection of measurement configurations for stiffness model calibration of anthropomorphic manipulators. Applied Mechanics and Materials 162: 161-170.
- Kövecses, J. and J. Angeles, 2007. The stiffness matrix in elastically articulated rigid-body systems. Multibody System Dynamics 18: 169-184.
- Lo, C.-C. and C.-Y. Hsiao, 1998. A method of tool path compensation for repeated machining process. International Journal of Machine Tools and Manufacture 38: 205-213.
- Lu, T.-f. and G. C. I. Lin, 1997. An on-line relative position and orientation error calibration methodology for workcell robot operations. Robotics and ComputerIntegrated Manufacturing 13: 89-99.
- Meggiolaro, M. A., S. Dubowsky and C. Mavroidis, 2005. Geometric and elastic error calibration of a high accuracy patient positioning system. Mechanism and Machine Theory 40: 415-427.
- Mooring, B. W., Z. S. Roth and M. R. Driels, 1991. Fundamentals of manipulator calibration. Wiley New York.
- Nubiola, A. and I. A. Bonev, 2013. Absolute calibration of an abb irb 1600 robot using a laser tracker. Robotics and Computer-Integrated Manufacturing 29: 236-245.
- Pashkevich, A. Computer-aided generation of complete irreducible models for robotic manipulators. The 3rd Int. Conference of Modellimg and Simulation. University of Technology of Troyes, France, 2001.
- Roth, Z. S., B. Mooring and B. Ravani, 1987. An overview of robot calibration. Robotics and Automation, IEEE Journal of 3: 377-385.
- Takeda, Y., G. Shen and H. Funabashi, 2004. A dbb-based kinematic calibration method for in-parallel actuated mechanisms using a fourier series. Journal of Mechanical Design 126: 856.
- Timoshenko, S. and J. N. Goodier, 1970. Theory of elasticity. McGraw-Hill, Singapore.
- Wu, Y., A. Klimchik, A. Pashkevich, S. Caro and B. Furet, 2013. Industry-oriented performance measures for design of robot calibration experiment. In: New trends in mechanism and machine science. Springer, pp. 519-527.
Paper Citation
in Harvard Style
Klimchik A., Caro S., Furet B. and Pashkevich A. (2014). Complete Stiffness Model for a Serial Robot . In Proceedings of the 11th International Conference on Informatics in Control, Automation and Robotics - Volume 2: ICINCO, ISBN 978-989-758-040-6, pages 192-202. DOI: 10.5220/0005098701920202
in Bibtex Style
@conference{icinco14,
author={Alexandr Klimchik and Stephane Caro and Benoit Furet and Anatol Pashkevich},
title={Complete Stiffness Model for a Serial Robot},
booktitle={Proceedings of the 11th International Conference on Informatics in Control, Automation and Robotics - Volume 2: ICINCO,},
year={2014},
pages={192-202},
publisher={SciTePress},
organization={INSTICC},
doi={10.5220/0005098701920202},
isbn={978-989-758-040-6},
}
in EndNote Style
TY - CONF
JO - Proceedings of the 11th International Conference on Informatics in Control, Automation and Robotics - Volume 2: ICINCO,
TI - Complete Stiffness Model for a Serial Robot
SN - 978-989-758-040-6
AU - Klimchik A.
AU - Caro S.
AU - Furet B.
AU - Pashkevich A.
PY - 2014
SP - 192
EP - 202
DO - 10.5220/0005098701920202