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Abstract

Actuators made from so-called smart materials have been proposed in the literature, for use in shape control of various surfaces. At the lowest level, this shape control problem can be thought of as a distributed regulation problem. Because of the hysteresis nonlinearity present in these actuators, there are an infinite number of input values corresponding to a particular output regulation setpoint. One might then ask the question, not relevant to memory-less systems, whether there is some advantage to regulating about one of these states in particular. This work proposes, based on observations from the Preisach model, that for any desired output there is one state in particular at which the system has a better natural (open-loop) rejection of uniformly-distributed noise at its input. This proposition is tested in both simulation and experiment. The reachability of this so-called `neutral state' is discussed, as is the generation of an input to drive the system to the appropriate neutral state. It is demonstrated that closed-loop regulation schemes will also benefit from starting in the appropriate neutral state, requiring less control effort for regulation.

Keywords

hysteresis shape control regulation intelligent materials.

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References

Agrawal, B. and Treanor, K. 1999. ``Shape Control of a Beam Using Piezoelectric Actuators ,'' Smart Materials and Structures, 8(6):729-740.

Cruz-Hernandez, J. and Hayward, V. 2001. ``Phase Control Approach to Hysteresis Reduction,'' IEEE Transactions on Control Systems Technology, 9(1):17-26.

Culshaw, B. 1996. Smart Structures and Materials, Artech House, Boston, London.

da Mota Silva, S. , Ribero, R. , Dias Rodrigues, J. , Vaz, M. and Monteiro, J. 2004. ``The Application of Genetic Algorithms for Shape Control with Piezoelectric Patches - an Experimental Comparison,'' Smart Materials and Structures, 13:220-226.

Galinaitis, W. and Rogers, R. 1998. ``Control of a Hysteretic Actuator Using Inverse Hysteresis Compensation,'' In: Proceedings of the SPIE Conference on Mathematics and Control in Smart Structures, pp. 267-277.

Gorbet, R. , Morris, K. and Wang, D. 1998a. ``Control of Hysteretic Systems: A State Space Approach ,'' In: Learning, Control and Hybrid Systems, Vol. 241, Lecture Notes in Control and Information Sciences, pp. 432-451, Springer, New York.

Gorbet, R. , Morris, K. and Wang, D. 1998b. ``Preisach Model Identication of a Two-wire SMA Actuator.'' In: Proceedings of the 1998 IEEE International Conference on Robotics and Automation, Vol. 3, pp. 2161-2167.

Hughes, D. and Wen, J. 1997. ``Preisach Modeling of Piezoceramic and Shape Memory Alloy Hysteresis,'' Smart Materials and Structures, 6:287-300.

Koconis, D. , Kollar, L. and Springer, G. 1994. ``Shape Control of Composite Plates and Shells with Embedded Actuators II: Desired Shape Specified,'' Journal of Composite Materials, 28(3):262-285.

10.

Madill, D. and Wang, D. 1998. ``Modelling and l2-stability of a Shape Memory Alloy Position Control System,'' IEEE Transactions on Control Systems Technology , 6(4):473-481.

11.

Majima, S. , Kodoma, K. and Hasegawa, T. 2001. ``Modeling of Shape Memory Alloy Actuator and Tracking Control System with the Model,'' IEEE Transactions on Control Systems Technology, 9(1):54-59.

12.

Mayergoyz, I. 1991. Mathematical Models of Hysteresis, Springer-Verlag, New York.

13.

Song, G. , Chaudhry, V. and Batur, C. 2003. ``Precision Tracking Control of Shape Memory Alloy Actuators Using Neural Networks and a Sliding-mode Based Robust Controller, '' Smart Materials and Structures, 12(2):223-231.

14.

Tan, X. , Venkataraman, R. and Krishnaprasad, P. 2001. ``Control of Hysteresis - Theory and Experimental Results,'' In: Proceedings of the Conference on Smart Structures and Materials, pp. 101-112.

15.

Webb, G. , Lagoudas, D. and Kurdila, A. 1998. ``Hysteresis Modelling for SMA Actuators for Control Applications ,'' Journal of Intelligent Material Systems and Structures , 9(6):432-448.

Influence of Initial State on Position Regulation of Hysteretic Actuators

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