LQR based stabilization of an 1D heat equation with advection and memory effects

Abstract

We derive a one-dimensional model for heat transfer in a moving fluid incorporating Fourier conduction, an exponentially decaying memory term, and advection under thermally insulated boundary conditions. We numerically construct a bounded state feedback law driving the closed-loop solution to zero exponentially with decay rate at least ω>0 for every initial state, i.e., we solve the ω-stabilization problem. We explicitly describe the eigenvalues of the state operator A, a subset of which converges to a finite negative accumulation point that sets the upper bound on the achievable decay rate. Since A lacks compact resolvent, we show that the spectrum is the closure of its eigenvalues, each of finite algebraic multiplicity, and use this to verify stabilizability. For ω below the accumulation bound, the problem is solvable provided the control operator B satisfies a non-orthogonality condition. To compute gains, we formulate an LQR problem and solve finite-dimensional approximations: for each n we construct An, Bn approximating A, B and solve the associated algebraic Riccati equation for a gain Kn. We show that, for all sufficiently large n, Kn can be chosen so every eigenvalue of An+BnKn satisfies Reλ<-ω, and we establish stabilizability of (An+ωI,Bn) uniformly in n. Hence, for large n, these gains solve the ω-stabilization problem for the original system. We validate the results numerically with an example.