LQR based ω-stabilization of a heat equation with memory

Abstract

We consider a heat equation with memory which is defined on a bounded domain in Rd and is driven by m control inputs acting on the interior of the domain. Our objective is to numerically construct a state feedback controller for this equation such that, for each initial state, the solution of the closed-loop system decays exponentially to zero with a decay rate larger than a given rate ω>0, i.e. we want to solve the ω-stabilization problem for the heat equation with memory. We first show that the spectrum of the state operator A associated with this equation has an accumulation point at -ω0<0. Given a ω∈(0,ω0), we show that the ω-stabilization problem for the heat equation with memory is solvable provided certain verifiable conditions on the control operator B associated with this equation hold. We then consider an appropriate LQR problem for the heat equation with memory. For each n∈N, we construct finite-dimensional approximations An and Bn of A and B, respectively, and then show that by solving a corresponding approximation of the LQR problem a feedback operator Kn can be computed such that all the eigenvalues of An + Bn Kn have real part less than -ω. We prove that Kn for n sufficiently large solves the ω-stabilization problem for the heat equation with memory. A crucial and nontrivial step in our proof is establishing the uniform (in n) stabilizability of the pair (An+ω I, Bn). We have validated our theoretical results numerically using two examples: an 1D example on a unit interval and a 2D example on a square domain.

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