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This paper develops a nonlinear backstepping design scheme for the active control of vehicle suspension systems using a nonlinear full car model with seven degrees of freedom. The non-linear control law is designed to improve ride comfort and reduce the displacement and the acceleration of the sprung mass in the heaving, rolling, and pitching directions. To demonstrate the effectiveness of the proposed control strategy, several simulations are performed on the nonlinear system. They show that active suspension based on backstepping scheme gives superior performances over passive suspension.
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Czasopismo
Rocznik
Tom
Strony
439--457
Opis fizyczny
Bibliogr. 24 poz., rys.
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autor
autor
autor
autor
- Laboratoire de Commande des Processus, Ecole Nationale Polytechnique, Alger, Algerie
Bibliografia
- [1] M. BOUAZARA, M. J. RICHARD and S. RAKHEJA: Safety and comfort analysis of a 3-d vehicle model with optimal non-linear active seat suspension. Journal of Terramechanics, 43 (2006), 97-118.
- [2] A. CHAMSEDDINE, T. RAHARIJAONA and H. NOURA: Sliding mode control applied to active suspension using nonlinear full vehicle and actuator dynamics. Proc. 45th IEEE Conf on Decision and Control, San Diego, CA, USA, (2006).
- [3] S. CHANTRANUWATHANA and H. PENG: Adaptive robust force control for vehicle active suspensions. Int. J. of Adaptive Control and Signal Processing, 18(2), (2004), 83-102.
- [4] M. M. ELMADANY and Z. S. ABDULJABBAR: State-feddback control for passenger ride dynamics. Vehicle System Dynamics, 32 (1999), 479-497.
- [5] M. M. BEN GAID, A. CELA and R. KOCIK: Distributed control of a car suspension system. Proc. 5th EUROSIM Congress on Modeling and Simulation, Paris, France, (2004).
- [6] R. GUCLU: Fuzzy logic control of seat vibrations of a non-linear full vehicle model. Nonlinear Dynamics, 40 (2005), 21-34.
- [7] C. HUANG and J. LIN: Nonlinear active suspension design for half-car models. Proc. of the 2004 IEEE Int. Conf. on Networking, Sensing and Control, 2 (2004), 719-724.
- [8] S. IKENAGA, F. L. LEWIS, J. CAMPOS and L. DAVIS: Active suspension control of ground vehicle based on a full-vehicle model. Proc. of the 2000 American Control Conference, 2, Chicago, USA, (2000), 4019-4024.
- [9] S. IKENAGA, F. L. LEWIS, L. DAVIS, J. CAMPOS, M. EVANS and S. Scul.i,v: Active suspension control using a novel strut and active filtered feedback: design and implementation. Proc. of the 1999 IEEE Int. Conf on Control Applications, Coast-Island of Hawaii, USA, (1999), 1502-1508.
- [10] F. IKHOUANE, V. MANOSA and J. RODELLAR: Adaptive backstepping control of some of uncertain nonlinear systems. application to bout-wen hysteretic oscillators. Proc. of 42nd IEEE Conf on Decision and Control, 4 Maui, Hawaii, USA, (2003), 3784-3789.
- [11] M. KRSTIC, I. KANELLAKOPOULOS and P. KOKOTOVIC: Nonlinear and Adaptive Control Design. John Wiley and Sons, 1995.
- [12] M. KRSTIC: Nonlinear backstepping designs and applications: Adaptive, robust and optimal. Tutorial Workshop in 14th Asian Control Conference, Suntec, Singapore, (2002).
- [13] N. LAGRAA, D. BOUKHETALA, A. GUESSOUM and G. BLOCH: Decentralised neural control of active suspensions. Int. J. of Vehicle Autonomous Systems, 3(2-4), (2005), 292-305.
- [14] N. LAGRAA, D. BOUKHETALA, A. GUESSOUM and G. BLOCH: Decentralized neural control of half-car model. Proc. of the Int. Computer Systems and Information Technology Cory:, Algiers, Algeria, (2005), 405-410.
- [15] J. LIN and I. KANELLAKOPOULOS: Modular adaptive design for active suspensions. Proc. of the 36th IEEE Conf on Decision and Control, 4 (1997), 3626-3631.
- [16] J. LIN and I. KANELLAKOPOULOS: Nonlinear design of active suspensions. IEEE Control Systems Magazine, 17(3), (1997).
- [17] H. A. MAHMOUD, P. T. KABAMBA, A. G. ULSOY and G. A. BRUSHER: Mixed H2 /H. control design for active suspension structures. 28 (2000), 3-16.
- [18] R. K. MEHRA, J. N. AMIN, K. J. HEDRICK, C. OSORIO and S. GOPALASAMY: Active suspension using preview information and model predictive control. Proc. of the 1997 IEEE Int. Conf on Control Applications, San Diego, CA, USA, (1997), 860-865.
- [19] R. R. MENDOZA, M. NAWARECKI, O. SENAME, L. DUGARD and M. M'SAAD: An optimal control approach for the design of an active suspension system. Proc. 1 FAC Workshop on Advanced in Automotive Control, Mars, (1998).
- [20] J. H. PARK and Y. S. KIM: Decentralized variable structure control for active suspensions based on a full-car model. Proc. of the 1998 IEEE Int. Conf on Control Applications, Trieste, Italy, (1998), 383-387.
- [21] L. E. SAKMAN, R. GUCLU and N. YAGIZ: Fuzzy logic control of vehicle suspensions with dry friction nonlinearity. Sadhana, 30 (2005), 649-659.
- [22] D. SAMMIER, a SENAME and L. DUGARD: Hinf control of active vehicle suspensions. Proc. of the 2000 IEEE Int. Conf on Control Applications, Anchorage, Alaska, USA, (2000), 976-981.
- [23] I. SZÁSZI, P. GASAPR and J. BOKOR: Nonlinear active suspension modelling using linear parameter varying approach. Proc. the 10th Mediterranean Conf on Control and Automation, Lisbon, Portugal, (2002).
- [24] T. YOSHIMURA, K. NAKAMINAMI, M. KURIMOTO and J. HINO: Active suspension of passenger cars using linear and fuzzy-logic controls. Control Engineering Practice, 7 (1999), 41-47.
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Bibliografia
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bwmeta1.element.baztech-article-BSW3-0042-0014