Approximation of exact controls for semi-linear 1D wave equations using a least-squares approach

Abstract

The exact distributed controllability of the semilinear wave equation ytt-yxx + g(y)=f \,1ω, assuming that g satisfies the growth condition g(s) /( s 2( s))→ 0 as s → ∞ and that g∈ L∞loc(R) has been obtained by Zuazua in the nineties. The proof based on a Leray-Schauder fixed point argument makes use of precise estimates of the observability constant for a linearized wave equation. It does not provide however an explicit construction of a null control. Assuming that g∈ L∞loc(R), that a,b∈ R,a≠ b g(a)-g(b)/ a-br<∞ for some r∈ (0,1] and that g satisfies the growth condition g(s)/2( s)→ 0 as s → ∞, we construct an explicit sequence converging strongly to a null control for the solution of the semilinear equation. The method, based on a least-squares approach guarantees the convergence whatever the initial element of the sequence may be. In particular, after a finite number of iterations, the convergence is super linear with rate 1+r. This general method provides a constructive proof of the exact controllability for the semilinear wave equation.