Intelligent double integral sliding-mode control for five-degree-of-freedom active magnetic bearing system

F.-J. Lin; S.-Y. Chen; M.-S. Huang

Intelligent double integral sliding-mode control for five-degree-of-freedom active magnetic bearing system

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Intelligent double integral sliding-mode control for five-degree-of-freedom active magnetic bearing system

Author(s): F.-J. Lin ; S.-Y. Chen ; M.-S. Huang
DOI: 10.1049/iet-cta.2010.0237

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Author(s): F.-J. Lin ¹ ; S.-Y. Chen ² ; M.-S. Huang ³
- Affiliations: 1: Department of Electrical Engineering, National Central University, Chungli, Taiwan
  2: Information and Communications Research Laboratories, Industrial Technology Research Institute, Hsinchu, Taiwan
  3: Department of Electrical Engineering, National Taipei University of Technology, Taipei, Taiwan
Source: Volume 5, Issue 11, 21 July 2011, p. 1287 – 1303
DOI: 10.1049/iet-cta.2010.0237 , Print ISSN 1751-8644, Online ISSN 1751-8652

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This study presents a decentralised intelligent double integral sliding-mode control (IDISMC) system, which consists of five IDISMCs, to regulate and stabilise a fully suspended five-degree-of-freedom (DOF) active magnetic bearing (AMB) system. The system structure and drive system with differential driving mode (DDM) are introduced first. Then, the decoupled dynamic model of the five-DOF AMB is analysed for the design of the decentralised control. Moreover, a decentralised integral sliding-mode control (ISMC) system is designed based on the decoupled dynamic model to control the five-DOF AMB considering the existences of the uncertainties. Furthermore, since the control characteristics of the five-DOF AMB are highly non-linear and time varying, the decentralised IDISMC system is proposed to further improve the control performance of the five-DOF AMB. In each IDISMC, the adopted double integral sliding surface reinforces the control law with the integral (I) control feature. In addition, the control gains of the IDISMC can be adjusted on-line and the system uncertainty can also be observed simultaneously by using of a modified proportional–integral–derivative neural network (MPIDNN) observer. Thus, the proposed IDISMC combines the merits of the ISMC, adaptive control and neural network (NN). Finally, the experimental results illustrate the validities of the proposed control systems using various operating conditions.

References

1. 1)
  - M. Defoort , T. Floquet , W. Perruquetti , S.V. Drakunov . Integral sliding mode control of an extended Heisenberg system. IET Control Theory Appl. , 10 , 1409 - 1424
2. 2)
  - X. Yu , O. Kaynak . Sliding-mode control with soft computing: a survey. IEEE Trans. Ind. Electron. , 9 , 3275 - 3285
3. 3)
  - N. Miyamoto , T. Enomoto , M. Amada . Suspension characteristics measurement of a bearingless motor. IEEE Trans. Magn. , 6 , 2795 - 2798
4. 4)
  - A. Chiba , T. Fukao , O. Ichikawa , M. Oshima , M. Takemoto , D.G. Dorrell . (2005) Magnetic bearings and bearingless drives.
5. 5)
  - S. Haykin . Neural networks: a comprehensive foundation.
6. 6)
  - B. Lu , H. Choi , G.D. Buckner , K. Tammi . Linear parameter-varying techniques for control of a magnetic bearing system. Control Eng. Pract. , 10 , 1161 - 1172
7. 7)
  - S. Cong , Y. Liang . PID-like neural network nonlinear adaptive control for uncertain multivariable motion control systems. IEEE Trans. Ind. Electron. , 10 , 3872 - 3879
8. 8)
  - M.A. Pichot , J.P. Kajs , B.R. Murphy . Active magnetic bearings for energy storage systems for combat vehicles. IEEE Trans. Magn. , 1 , 318 - 323
9. 9)
  - R.L. Clark , W.R. Saunders , R.P. Gibbs . (1998) Adaptive structures.
10. 10)
  - M. Liu . Decentralized control of robot manipulators: nonlinear and adaptive approaches. IEEE Trans. Autom. Control , 2 , 357 - 363
11. 11)
  - C. Bi , D. Wu , Q. Jiang , Z. Liu . Automatic learning control for unbalance compensation in active magnetic bearings. IEEE Trans. Magn. , 7 , 2270 - 2280
12. 12)
  - S.L. Chen , S.H. Chen , S.T. Yan . Experimental validation of a current-controlled three-pole magnetic rotor-bearing system. IEEE Trans. Magn. , 1 , 99 - 112
13. 13)
  - G. Schweitzer , E.H. Maslen . (2009) Magnetic bearings – theory, design and application to rotating machinery.
14. 14)
  - K.K. Tan , S. Huang , R. Ferdous . Robust self-tuning PID controller for nonlinear systems. J. Process Control , 7 , 753 - 761
15. 15)
  - Y. Sun , Y.S. Ho , L. Yu . Dynamic stiffnesses of active magnetic thrust bearing including eddy-current effects. IEEE Trans. Magn. , 1 , 139 - 149
16. 16)
  - O.S. Kim , S.H. Lee , D.C. Han . Positioning performance and straightness error compensation of the magnetic levitation stage supported by the linear magnetic bearing. IEEE Trans. Ind. Electron. , 2 , 374 - 378
17. 17)
  - M.D. Noh , S.R. Cho , J.H. Kyung , S.K. Ro , J.K. Park . Design and implementation of a fault-tolerant magnetic bearing system for turbo-molecular vacuum pump. IEEE Trans. Mechatronics , 6 , 626 - 631
18. 18)
  - S.C. Tan , Y.M. Lai , C.K. Tse . Indirect sliding mode control of power converters via double integral sliding surface. IEEE Trans. Power Electron. , 2 , 600 - 611
19. 19)
  - J.H. Lee , P.E. Allaire , G. Tao , J.A. Decker , X. Zhang . Experimental study of sliding mode control for a benchmark magnetic bearing system and artificial heart pump suspension. IEEE Trans. Control Syst. Technol. , 1 , 128 - 138
20. 20)
  - E.A. Knoth , J.P. Barber . Magnetic repulsion bearings for turbine engines. IEEE Trans. Magn. , 6 , 3141 - 3143
21. 21)
  - J.J.E. Slotine , W. Li . (1991) Applied nonlinear control.
22. 22)
  - J. Crowe . (2005) PID control: new identification and design methods.
23. 23)
  - C.R. Knospe . Active magnetic bearings for machining applications. Control Eng. Pract. , 307 - 313
24. 24)
  - S. Sivrioglu . Adaptive backstepping for switching control active magnetic bearing system with vibrating base. IET Control Theory Appl. , 4 , 1054 - 1059
25. 25)
  - B. Lennartson , B. Kristiansson . Evaluation and tuning of robust PID controllers. IET Control Theory Appl. , 3 , 294 - 302
26. 26)
  - A.A. Hussien , S. Yamada , M. Iwahara , T. Okada , T. Ohji . Application of the repulsive-type magnetic bearing for manufacturing micromass measurement balance equipment. IEEE Trans. Magn. , 10 , 3802 - 3804
27. 27)
  - Y.S. Huang , C.C. Sung . Implementation of sliding mode controller for linear synchronous motors based on direct thrust control theory. IET Control Theory Appl. , 3 , 326 - 338
28. 28)
  - T.J. Ren , T.C. Chen . Motion control for a two-wheeled vehicle using a self-tuning PID controller. Control Eng. Pract. , 3 , 365 - 375
29. 29)
  - A.T.A. Peijnenburg , J.P.M. Vermeulen , J.V. Eijk . Magnetic levitation systems compared to conventional bearing systems. Micro Electron. Eng. , 1372 - 1375
30. 30)
  - M.N. Sahinkaya , A.E. Hartavi . Variable bias current in magnetic bearings for energy optimization. IEEE Trans. Magn. , 3 , 1052 - 1060

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Intelligent double integral sliding-mode control for five-degree-of-freedom active magnetic bearing system

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