Title :
Local-global double algebras for slow H∞ adaptation. II. Optimization of stable plants
Author :
Wang, Le Y. ; Zames, George
Author_Institution :
Dept. of Electr. & Comput. Eng., Wayne State Univ., Detroit, MI, USA
fDate :
2/1/1991 12:00:00 AM
Abstract :
For Pt.I see ibid., vol.36, no.2, p.130-42 (1991). The authors presently establish an explicit formula linking global and local sensitivity for systems with stable plants, in which local sensitivity is a Lipschitz-continuous function of data. Frequency-domain estimates of time-domain sensitivity norms, which become accurate as rates of time variation approach zero, are obtained. Notions of adaptive versus nonadaptive (robust) control are introduced. It is shown that adaptive control can achieve better sensitivity than optimal nonadaptive control. It is demonstrated that, in general, H∞-optimal interpolants do not depend Lipschitz continuously on data. However, δ-suboptimal interpolants of the AAK central (maximal entropy) type are shown to satisfy a tractable Lipschitz condition
Keywords :
adaptive control; algebra; optimal control; optimisation; stability; time-varying systems; δ-suboptimal interpolants; AAK central; H∞ optimal determinants; Lipschitz-continuous function; adaptive control; global sensitivity; local global double algebras; local sensitivity; optimal nonadaptive control; optimisation; slow adaptation; stable plants; time variation; time-domain sensitivity norms; Adaptive control; Algebra; Feedback; Frequency estimation; H infinity control; Interpolation; Joining processes; Programmable control; Stability analysis; Time domain analysis;
Journal_Title :
Automatic Control, IEEE Transactions on
