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Dynamic Compensator Design of Linear Parabolic MIMO PDEs in $N$-Dimensional Spatial Domain

Jun‐Wei Wang, Jun‐Min Wang

2020IEEE Transactions on Automatic Control27 citationsDOI

Abstract

This article employs the observer-based output feedback control technique to deal with dynamic compensator design for a linear N-D parabolic partial differential equation (PDE) with multiple local piecewise control inputs and multiple noncollocated local piecewise observation outputs. These control inputs and observation outputs are provided by only few actuators and noncollocated sensors active over partial areas (or entire) of the spatial domain. An observer-based dynamic feedback compensator is constructed for exponential stabilization of the linear PDE. Poincaré-Wirtinger inequality and its variant in N-D spatial domain are presented for the closed-loop stability analysis. By the Lyapunov direct method and Poincaré-Wirtinger inequality and its variant, sufficient conditions on the existence of such feedback compensator of the linear PDE are developed, and presented in term of standard linear matrix inequalities. Well-posedness is also analyzed for both open-loop PDE and resulting closed-loop coupled PDEs within the C0-semigroup framework. Finally, numerical simulation results are presented to support the proposed design method.

Topics & Concepts

Control theory (sociology)MathematicsPartial differential equationObserver (physics)Parabolic partial differential equationExponential stabilityLyapunov functionNonlinear systemMathematical analysisComputer scienceControl (management)Artificial intelligencePhysicsQuantum mechanicsStability and Controllability of Differential EquationsAdvanced Mathematical Modeling in EngineeringAdvanced Mathematical Physics Problems
Dynamic Compensator Design of Linear Parabolic MIMO PDEs in $N$-Dimensional Spatial Domain | Litcius