Immersion and invariance adaptive control of linear multivariable systems. (English) Zbl 1157.93429
Summary: We show in this paper that it is possible to globally adaptively stabilize linear multivariable systems with reduced prior knowledge of the high-frequency gain. In particular, we relax the restrictive (nongeneric) symmetry condition usually required to solve this problem. Instrumental for the establishment of our result is the use of the new immersion and invariance approach to adaptive control recently proposed in the literature. The controllers obtained with this technique are not certainty equivalent–though smooth and without projections or overparameterizations–and the resulting Lyapunov functions contain cross-terms between the plant states and the parameter errors.
MSC:
| 93C40 | Adaptive control/observation systems |
| 93C10 | Nonlinear systems in control theory |
| 93D15 | Stabilization of systems by feedback |
References:
| [1] | A. Astolfi, L. Hsu, M. Netto and R. Ortega, A solution to the adaptive visual servoing problem, IEEE Conference on Robotics and Automation, Seoul, Korea, May 21-26, 2001 (to appear in IEEE Trans. Robotics and Automation).; A. Astolfi, L. Hsu, M. Netto and R. Ortega, A solution to the adaptive visual servoing problem, IEEE Conference on Robotics and Automation, Seoul, Korea, May 21-26, 2001 (to appear in IEEE Trans. Robotics and Automation). |
| [2] | A. Astolfi, R. Ortega, Immersion and invariance: a new tool for stabilization and adaptive control of nonlinear systems, European Control Conf ECC 2001, Porto, Portugal, September, 4-7, 2001.; A. Astolfi, R. Ortega, Immersion and invariance: a new tool for stabilization and adaptive control of nonlinear systems, European Control Conf ECC 2001, Porto, Portugal, September, 4-7, 2001. · Zbl 1364.93618 |
| [3] | L. Hsu, R. Costa, MIMO direct adaptive control with reduced prior knowledge of the high frequency gain, Proceedings of the 38th IEEE CDC, Phoenix, AZ, December 1999.; L. Hsu, R. Costa, MIMO direct adaptive control with reduced prior knowledge of the high frequency gain, Proceedings of the 38th IEEE CDC, Phoenix, AZ, December 1999. |
| [4] | Hsu, L.; Kaszkurewicz, E.; Bhaya, A., Matrix-theoretic conditions for the realizability of sliding manifolds, Systems Control Lett., 40, 3, 145-152 (2000) · Zbl 0977.93018 |
| [5] | A. Imai, R.R. Costa, L. Hsu, G. Tao, P. Kokotovic, Multivariable MRAC using high frequency gain matrix factorization, Proceedings of the 40th IEEE CDC, Orlando, AZ, December 4-7, 2001, pp. 1193-1198.; A. Imai, R.R. Costa, L. Hsu, G. Tao, P. Kokotovic, Multivariable MRAC using high frequency gain matrix factorization, Proceedings of the 40th IEEE CDC, Orlando, AZ, December 4-7, 2001, pp. 1193-1198. |
| [6] | Ioannou, P.; Sun, J., Robust Adaptive Control (1996), Prentice-Hall: Prentice-Hall Englewood Cliffs, NJ · Zbl 0839.93002 |
| [7] | Landau, I., Adaptive Control: The Model Reference Approach (1979), Marcel Dekker: Marcel Dekker New York · Zbl 0475.93002 |
| [8] | Mareels, I.; Polderman, J. W., Adaptive Systems: An Introduction (1996), Birkhauser: Birkhauser Berlin · Zbl 0923.93028 |
| [9] | Narendra, K.; Annaswamy, A., Stable Adaptive Systems (1989), Prentice-Hall: Prentice-Hall Englewood Cliffs, NJ · Zbl 0758.93039 |
| [10] | Ortega, R.; Herrera, A., A solution to the continuous-time adaptive decoupling problem, IEEE Trans. Automat. Contol, AC-39, 7, 1639-1643 (1994) · Zbl 0925.93584 |
| [11] | Ortega, R.; Yu, T., Robustness of adaptive controllersa survey, Automatica, 25, 5, 651-677 (1989) · Zbl 0692.93024 |
| [12] | Praly, L., Adaptive regulationLyapunov design with a growth condition, Internat. J. Adapt. Control Signal Process., 6, 4, 329-352 (1992) · Zbl 0769.93068 |
| [13] | Sastry, S.; Bodson, M., Adaptive Control: Stability, Convergence and Robustness (1989), Prentice-Hall: Prentice-Hall Englewood Cliff, NJ · Zbl 0721.93046 |
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