Adaptive Approximation Based Control: Unifying Neural, Fuzzy and Traditional Adaptive Approximation ApproachesA highly accessible and unified approach to the design and analysis of intelligent control systems Adaptive Approximation Based Control is a tool every control designer should have in his or her control toolbox. Mixing approximation theory, parameter estimation, and feedback control, this book presents a unified approach designed to enable readers to apply adaptive approximation based control to existing systems, and, more importantly, to gain enough intuition and understanding to manipulate and combine it with other control tools for applications that have not been encountered before. The authors provide readers with a thought-provoking framework for rigorously considering such questions as: * What properties should the function approximator have? * Are certain families of approximators superior to others? * Can the stability and the convergence of the approximator parameters be guaranteed? * Can control systems be designed to be robust in the face of noise, disturbances, and unmodeled effects? * Can this approach handle significant changes in the dynamics due to such disruptions as system failure? * What types of nonlinear dynamic systems are amenable to this approach? * What are the limitations of adaptive approximation based control? Combining theoretical formulation and design techniques with extensive use of simulation examples, this book is a stimulating text for researchers and graduate students and a valuable resource for practicing engineers. |
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adaptive approximation based adaptive control adaptive laws algorithm analysis applications approach approximation based control approximation error approximation structure assumed asymptotically B-splines backstepping basis elements basis functions bounding functions chapter closed-loop system coefficients compact set computation consider control design control signal control system converges to zero dead-zone defined denoted derivative discussed ensure equation example Exercise feedback control law feedback linearizing Figure filter finite first fixed function approximation function f fuzzy fuzzy set implementation initial conditions input known learning scheme least squares Lemma linear control linearizable Lyapunov function matrix methods MFAE model error modification nonlinear control nonlinear system online learning operating point optimal parameter adaptation parameter estimation parameter vector parametric model partition of unity perceptron polynomial positive definite radial basis function region D regressor robust satisfies scalar Section selected simulation specification spline stability properties subsection Theorem tracking error dynamics trajectory unknown nonlinearities variables wavelet yd(t
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