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Abstract

This paper considers the robust control of a current-controlled magnetic bearing with a pair of opposing electromagnets and a rigid rotor. A first-order dynamical compensator which uses only position feedback information is applied for control. The dynamical compensator design is based on a linearized one-dimensional second-order linear model, which is treated as an interval system in order to cope with parameter uncertainties. Through robust stability analysis, a parameterization of all the first-order robust stabilizing dynamical compensators for the interval magnetic-bearing system is first obtained. Then, by appropriately selecting the free parameters in the robust stabilizing controller, the H-two norm of the disturbance-output transfer function is made arbitrarily small over the system parameter intervals, and the H-infinity norm of the output-input transfer function is made arbitrarily close to a lower bound. The proposed approach is applied to control a flywheel supported by active magnetic bearings. Simulation and experimental results show that this approach is simple, effective and very robust.

Keywords

disturbance attenuation dynamical compensators interval systems magnetic bearings minimum control effort robust stabilization

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References

Bleuler, H. , Vischer, D. , Schweitzer, G. , Traxler, A. and Zlatnik, D. 1994: New concepts for cost-effective magnetic bearing control. Automatica 30, 871-876.

Duan, G. R. 1993: Robust eigenstructure assignment via dynamical compensators. Automatica 29, 469-474.

Duan, G. R. , Wu Z. Y. and Howe D. 1999: Explicit parametric solution to observer-based control of self-sensing magnetic bearings. The 1999 IFAC World Congress, 5-8 July 1999, Beijing, P.R.C., Vol-O, 379-384.

Duan, G. R. , Wu Z. Y. , Bingham C. and Howe D. 2000a: Magnetic bearing control using robust stabilising dynamical compensators. IEEE Transactions on Industry Application 36, 1654-1660.

Duan, G. R. , Irwin, G. W. and Liu G. P. 2000b: Disturbance attenuation in linear systems via dynamical compensators—a parametric eigenstructure assignment approach. IEE Proceedings, Control Theory and Applications, Vol. 146, No. 2, 129-136.

Dussaux, M. 1990: The industrial applications of active magnetic bearing technology. Proceedings of the Second International Symposium on Magnetic Bearings, 12-14 July 1990, 33-38.

Earnshaw, S. 1842: On the nature of molecular forces. Transactions of the Cambridge Philosophical Society 7, 97-112.

Hispano-Sulza. 1957. Totally active magnetic suspension system. Societe D’Exploitation Des Materiels, French Patent 1186527, November 1957.

Hubbard, M. and McDonald, P. 1980: Feedback control systems for flywhell radial instabilities, 1980 Flywheel Technology Symposium Proceedings, Scottsdale, Arizona, 209-217.

10.

Hung, J. Y. 1995: Magnetic bearing control using fuzzy logic. IEEE Transactions on Industry Applications 31, 1492-1497.

11.

Levine J. , Lotton, J. and Ponsart, J. C. 1996: A nonlinear approach to the control of magnetic bearings. IEEE Transactions on Control Systems Technology 4, 524-544.

12.

Matsumura, F. and Yoshimoto, T. 1988: System modeling and control design of a horizontal-shaft magnetic bearing system. IEEE Transactions on Magnetics MAG-22 196-203.

13.

Mizuno, T. , Araki, K. and Bleuler, H. 1996: Stability analysis of self-sensing magnetic bearing controllers. IEEE Transactions on Control Systems Technology 4, 572-579.

14.

Mizuno, T. and Bleuler, H. 1995: Self-sensing magnetic bearing control system design using the geometric approach. Control Engineering Practice 3, 925-932.

15.

Mohamed, A. M. and Busch-Vishniac, I. 1995: Imbalance compensation and automation balancing in magnetic bearing systems using the Q-parameterization theory. IEEE Transactions on Control Systems Technology 3, 202-211.

16.

Salm, J. and Schweitzer, G. 1984: Modeling and control of a flexible rotor with magnet bearings. Proceedings of the Third International Conference on Vibrations in Totating Machinery, University of York, 11-13 September 1984, C277/84.

17.

Sinha, A. , Meese, K. L. and Wang, K. W. 1991: Sliding mode control of a rigid rotor via magnetic bearings. ASME Biennial Conference on Mechanical Vibration and Noise, Miami, Florida, September 1991.

18.

Stanway, R. and O’Reilly, J. 1984: State variable feedback control of rotor bearing suspension systems. Proceedings of the Third International Conference on Vibrations in Rotating Machinery. University of York, 11-13 September 1984, C277/84.

19.

Vischer, D. and Bleuler, H. 1993: Self-sensing active magnetic levitation. IEEE Transactions on Magnetics 29, 1276-1281.

20.

Youcef-Toumi, K. and Ito, O. 1990: Controller design for systems with unknown dynamics. ASME Journal of Dynamic Systems, Measurement and Control 112, 133-142.

21.

Youcef-Toumi, K. and Reddy, S. 1992: Dynamic analysis and control of high speed and high precision active magnetic bearings. ASME Journal of Dynamic Systems, Measurement and Control 114, 623-633.

Robust control of a magnetic-bearing flywheel using dynamical compensators

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