Constructive exact control of semilinear 1D wave equations by a least-squares approach

Abstract

It has been proved by Zuazua in the nineties that the internally controlled semilinear 1D wave equation ∂tty-∂xxy + g(y)=f 1ω, with Dirichlet boundary conditions, is exactly controllable in H10(0,1) L2(0,1) with controls f∈ L2((0,1)×(0,T)), for any T>0 and any nonempty open subset ω of (0,1), assuming that g∈ C1() does not grow faster than β x 2 x at infinity for some β>0 small enough. The proof, based on the Leray-Schauder fixed point theorem, is however not constructive. In this article, we design a constructive proof and algorithm for the exact controllability of semilinear 1D wave equations. Assuming that g does not grow faster than β 2 x at infinity for some β>0 small enough and that g is uniformly H\"older continuous on with exponent s∈[0,1], we design a least-squares algorithm yielding an explicit sequence converging to a controlled solution for the semilinear equation, at least with order 1+s after a finite number of iterations.