Approximate controllability of a bilinear wave equation and minimum time

Abstract

We study the global approximate controllability (GAC) of a Klein-Gordon wave equation, posed on the torus Td of arbitrary dimension d∈ N*, with bilinear control potentials supported on the first (2d+1)-Fourier modes. Let Z(W0)⊂ Td be the set of essential zeroes of the initial state W0∈ H1× L2(Td), and r(W0)≥ 0 be the maximum radius of a ball of Td contained in Z(W0). Due to finite speed of propagation, the minimum control time starting from W0 is necessarily larger than or equal to r(W0). We prove the following three facts. In low dimensions d ∈ \1,2\: the minimum time for GAC from W0 ≠ 0 is equal to r(W0). In any dimensions d≥ 3: the minimum time for GAC from W0 is zero if Z(W0) has zero Lebesgue measure; and the GAC in sufficiently large time from all W0≠ 0. The proof strategy consists in combining Lie bracket techniques \`a la Agrachev-Sarychev with the propagation of well-prepared positive states.