Tunneling estimates and approximate controllability for hypoelliptic equations

Abstract

This article is concerned with quantitative unique continuation estimates for equations involving a "sum of squares" operator L on a compact manifold M assuming: (i) the Chow-Rashevski-H\"ormander condition ensuring the hypoellipticity of L, and (ii) the analyticity of M and the coefficients of L. The first result is the tunneling estimate \|\|L2(ω) ≥ Ce- λk2 for normalized eigenfunctions of L from a nonempty open set ω⊂ M, where k is the hypoellipticity index of L and λ the eigenvalue. The main result is a stability estimate for solutions to the hypoelliptic wave equation (∂t2+L)u=0: for T>2 x ∈ M(dist(x,ω)) (here, dist is the sub-Riemannian distance), the observation of the solution on (0,T)× ω determines the data. The constant involved in the estimate is Ceck where is the typical frequency of the data. We then prove the approximate controllability of the hypoelliptic heat equation (∂t+L)v=1ω f in any time, with appropriate (exponential) cost, depending on k. In case k=2 (Grushin, Heisenberg...), we further show approximate controllability to trajectories with polynomial cost in large time. We also explain how the analyticity assumption can be relaxed, and a boundary ∂ M can be added in some situations. Most results turn out to be optimal on a family of Grushin-type operators. The main proof relies on the general strategy developed by the authors in arxiv:1506.04254.