TY - GEN
T1 - Direct adaptive control of parabolic systems
T2 - Proceedings of the 32nd IEEE Conference on Decision and Control. Part 3 (of 4)
AU - Hong, Keum S.
AU - Bentsman, Joseph
PY - 1993
Y1 - 1993
N2 - This paper presents a model reference adaptive control of a class of distributed parameter systems described by linear, n-dimensional, parabolic partial differential equations. Unknown parameters appearing in the system equation are either constant or spatially-varying. distributed sensing and actuation are assumed to the available. Adaptation laws are obtained by the Lyapunov redesign method. It is shown that the concept of persistency of excitation, which guarantees the parameter error convergence to zero in finite dimensional adaptive systems, in infinite dimensional adaptive systems should be investigated in relation to time variable, spatial variable, and also boundary conditions. Unlike finite dimensional case, in infinite dimensional adaptive systems even a constant input is shown to be persistently exciting in the sense that it guarantees the convergence of parameters errors to zero. Averaging theorems for two-time scale systems which involve a finite dimensional slow system and an infinite dimensional fast system are developed. The exponential stability of the adaptive system, which is critical in finite dimensional adaptive control in terms of tolerating disturbances and unmodeled dynamics, is shown by applying averaging. A numerical example which demonstrates an averaged system, and computer simulations are provided.
AB - This paper presents a model reference adaptive control of a class of distributed parameter systems described by linear, n-dimensional, parabolic partial differential equations. Unknown parameters appearing in the system equation are either constant or spatially-varying. distributed sensing and actuation are assumed to the available. Adaptation laws are obtained by the Lyapunov redesign method. It is shown that the concept of persistency of excitation, which guarantees the parameter error convergence to zero in finite dimensional adaptive systems, in infinite dimensional adaptive systems should be investigated in relation to time variable, spatial variable, and also boundary conditions. Unlike finite dimensional case, in infinite dimensional adaptive systems even a constant input is shown to be persistently exciting in the sense that it guarantees the convergence of parameters errors to zero. Averaging theorems for two-time scale systems which involve a finite dimensional slow system and an infinite dimensional fast system are developed. The exponential stability of the adaptive system, which is critical in finite dimensional adaptive control in terms of tolerating disturbances and unmodeled dynamics, is shown by applying averaging. A numerical example which demonstrates an averaged system, and computer simulations are provided.
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M3 - Conference contribution
AN - SCOPUS:0027747988
SN - 0780312988
T3 - Proceedings of the IEEE Conference on Decision and Control
SP - 2413
EP - 2418
BT - Proceedings of the IEEE Conference on Decision and Control
A2 - Anon, null
PB - Publ by IEEE
Y2 - 15 December 1993 through 17 December 1993
ER -