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Chattering-free sliding modes in robotic manipulators control

Published online by Cambridge University Press:  09 March 2009

Asif Šabanović ,
Karel Jezernik  and
Kenzo Wada
Asif Šabanović
Affiliation:
TUBITAK-Marmara Research Center, P.K. 21 Gebze, 41470 Kocaeli (Turkey).
Karel Jezernik
Affiliation:
University of Maribor, Faculty of Technical Sciences, Smetanova 17 62000 Maribor (Slovenia).
Kenzo Wada
Affiliation:
Yamaguchi University, Faculty of Engineering, 2557 Tokiwadai Ube 755 (Japan).
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Summary

In this paper sliding mode motion design is considered for nonlinear plants which are linear with respect to control input. The dynamics of the robotic manipulators is treated with and without those of the actuators. When the dynamics of the actuators is included a design of the sliding modes for the systems with discontinuous control is performed. If actuators' dynamics is negelected the control is assumed to be continuous quantity. By combining the variable structure systems and Lyapunov designs a new algorithm is developed which has all the good properties of the sliding mode systems while avoiding unnecessary discontinuity of the control thus eliminating chattering. Neither the explicit calculation of the equivalent control, nor high gain inside the boundary layer are used. The parameters of the control depend on the plant's gain matrix, and the gradients of the sliding mode manifold. This control method is then applied to develop a unified control strategy for the motion control systems including the path tracking control, the impedance control and the force control of a robotic manipulator. It is shown that all these tasks can be formulated in the same mathematical form in which selected so-called sliding mode functions must track their references. In this way the systems state is forced to remain on the selected manifold in the state space after reaching it. The solution is interpreted in both the Joint space and the Work space for n -degrees of freedom robotic manipulators.

Keywords

Sliding mode motionRobot controlActuator dynamicsChattering removal
Type
Articles
Information
Robotica , Volume 14 , Issue 1 , January 1996 , pp. 17 - 29
Copyright
Copyright © Cambridge University Press 1996

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References

1.Paul, R.P., Robot Manipulators (MIT Press, Cambridge, Mass., 1981).Google Scholar
2.Ohnishi, K., “Advanced motion control in robotics” Proc. IEEE IECON'89Philadelphia, USA(1989) pp. 348353.Google Scholar
3.Simura, K., Sugai, M. & Hori, Y., “A novel robot motion control based on decentralized robust servomechanism for each joint” Proc. IECON'91,Kobe, Japan(1991) vol 2, pp. 12831288.Google Scholar
4.Slotine, J.J. & Shastry, S., “Tracking control of nonlinear systems using sliding surfaces, with application to robot manipulatorsInt. J. Contr. 38, No. 2, 465492 (1983).Google Scholar
5.Fengxi, Z. & Fisher, D.G., “Continuous sliding mode controlInt. J. Control 55, No. 2, 313327 (1992).Google Scholar
6.Wang, W.J. & Wu, G.H., “Variable structure control design, on discrete-time systems-another point viewpointControl-Theory and Advanced Technology 8, No. 1, 116 (1992).Google Scholar
7.Šabanović, A. & Ohnishi, K., “Sliding mode control of robotic manipulators” Proc. of the 1992 IEEE/RSJ Intl. Conf. IROS'92,Raleigh, NC(1992) pp. 974979.Google Scholar
8.Izosimov, D.B. & Utkin, V.I., “On equivalence of systems with large coefficients and systems with discontinuous controlAutomatic and Remote Control 11, 189191 (1981).Google Scholar
9.Furuta, K., “Sliding mode control of a discrete systemSystem and Control Letters 14, No. 2, 145152 (1990).CrossRefGoogle Scholar
10.Drakunov, S.V. & Utkin, V.I., “On discrete-time sliding modes” Proc. of Nonlinear Control System Design Conf,Capri, Italy(1989) pp. 273278.Google Scholar
11.Luk'yanov, A.G. & Utkin, V.I., “Method of reducing equations for dynamics systems to a regular formAutomation and Remote Control 43, No. 4, 413420 (1981).Google Scholar
12.Utkin, V.I., Sliding Modes in Control and Optimization (Springer-Verlag, Berlin, 1992).CrossRefGoogle Scholar
13.Draženović, B., “The invariance conditions in variable structure systemsAutomatica 5, 287295 (1969).CrossRefGoogle Scholar
14.Sabanovic, A., “Sliding modes in motion control systems”, Proc. of 2nd IEEE Intl. Workshop on Advanced Motion Control,Nagoya, Japan(1992) pp. 150156.Google Scholar
15.Arai, F., Fukuda, T., Shoi, W. & Wada, H., “Models of mechanical systems for controllers design” Proc. of IF AC Workshop Motion Control for Intelligent AutomationPerugia, Italy(1992) pp. 1319.Google Scholar