MODEL-BASED DYNAMIC FRICTION COMPENSATION IN ROBOT ACTUATORS

Juan C. Martínez-Rosas, Luis Alvarez-Icaza, and Daniel Noriega-Pineda

References

  1. [1] B. Armstrong-Héouvry, P. Dupont, and C. Canudas, A survey of models, analysis tools and compensation methods for the control of machines with friction, Automatica, 30(7), 1994, 1083–1138.
  2. [2] F. Al-Bender and J. Swevers, Characterization of friction force dynamics, IEEE Control Systems Magazine, 28 (6), 2008, 64–81.
  3. [3] P.R. Dahl, Solid friction damping of mechanical vibrations, AIAA Journal, 14 (12), 1976, 1675–1682.
  4. [4] C. Canudas de Wit, H. Olsson, K.J. Ǻstrom, and P. Lischinsky, A new model for control of systems with friction, IEEE Transactions on Automatic Control, 40 (3), 1995, 419–425.
  5. [5] Y. Wen, Method for random vibration of hysteretic systems, ASCE Journal of Engineering Mechanics, 102, 1976, 249–263.
  6. [6] S. Choi, S. Lee, S. Rakheja, and C. Sun, A hysteresis model for the field-dependent damping force of a magnetorheological damper, Journal of Sound and Vibration, 2 (245), 2001, 375–383.
  7. [7] M. Sain and B. Spencer, Models for hysteresis and application to structural control, Proc. 1997 American Control Conf., Alburquerque, New Mexico, 1997, 16–20.
  8. [8] J. Swevers, F. Al-Bender, C.G. Ganseman, and T. Prajogo, An integrated friction model structure with improved presliding behavior for accurate friction compensation, IEEE Transactions on Automatic Control, 45 (4), 2000, 675–687.
  9. [9] J. Liang, S. Fillmore, and O. Ma, An extended bristle friction force model with experimental validation, Mechanism and Machine Theory, 56, 2012, 123–137.
  10. [10] C. Canudas and R. Horowitz, Observers for tire/road contact friction using only wheel angular velocity information, Proc. 38th IEEE Conf. on Decision and Control, Phoenix, Arizona,1999, 3932–3937.
  11. [11] C. Canudas de Wit and P. Lischinsky, Adaptive friction compensation with partially known dynamic friction model, International Journal of Adaptive Control and Signal Processing, 11 (1), 1997, 65–80.
  12. [12] J. Yi, L. Alvarez, and R. Horowitz, Adaptive emergency braking control with underestimation of friction coefficient, IEEE Control Systems Technology, 10 (3), 2002, 381–392.
  13. [13] J. Yi, L. Alvarez, R. Horowitz, and X. Claeys, Emergency braking control with and observed-based dynamic tire/road friction model and wheel angular velocity measurement, Journal of Vehicle Systems Dynamics, 39 (2), 2003, 81–97.
  14. [14] T. Piatkowski, Dahl and LuGre dynamic friction models – the analysis of selected properties, Mechanism and Machine Theory, 73, 2014, 91–100.
  15. [15] L. Alvarez-Icaza and R. Jiménez-Fabián, An identifiable control oriented dynamic friction model, Proc. 7th IFAC Symp. Nonlinear Control Systems, Pretoria, RSA, 2007, 419–426.
  16. [16] J.C. Mart´ınez-Rosas and L. Alvarez-Icaza, Adaptive compensation of dynamic friction in an industrial robot, Proc. 2008 IEEE Int. Conf. on Control Applications, San Antonio, USA,2008, 1145–1150.
  17. [17] J.C. Martínez-Rosas, L. Alvarez-Icaza, and D. Noriega-Pineda, Dynamic friction compensation in velocity control of servo-actuators, Proc. 2009 IEEE Int. Conf. on Control Applications, Saint Petersburg, 2009, 54–59.
  18. [18] N. Baravanov and R. Ortega, Necessary and sufficient conditions for passivity of the LuGre friction model, IEEE Transactions on Automatic Control, 45 (4), 2000, 830–832.
  19. [19] R. Kelly and V. Santibáñez, Control de movimiento de robots manipuladores (Prentice-Hall, 2003).
  20. [20] J.J.E. Slotine and W. Li, On the adaptive control of robot manipulators, International Journal of Robotics Research, 6 (3), 1987, 49–59.
  21. [21] H.K. Khalil, Nonlinear systems, 2nd ed. (USA: Prentice-Hall, 1996).

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