Small-time approximate controllability of bilinear Schr\"odinger equations and diffeomorphisms
Abstract
We consider Schr\"odinger PDEs, posed on a boundaryless Riemannian manifold M, with bilinear control. We propose a new method to prove the global L2-approximate controllability. Contrarily to previous ones, it works in arbitrarily small time and does not require a discrete spectrum. This approach consists in controlling separately the radial part and the angular part of the wavefunction thanks to the control of the group Diffc0(M) of diffeomorphisms of M and the control of phases, which refer to the possibility, for any initial state 0∈ L2(M,C), diffeomorphism P∈ Diffc0(M) and phase ∈ L2(M,R) to reach approximately the states ( DP)1/2(0 P) and ei 0 . The control of the radial part uses the transitivity of the group action of Diffc0(M) on positive densities proved by Moser. We develop this approach on two examples of Schr\"odinger equations, posed on Td or Rd, for which the small-time control of phases was recently proved. We prove that it implies the small-time control of flows of vector fields thanks to Lie bracket techniques. Combining this property with the simplicity of the group Diffc0(M) proved by Thurston, we obtain the control of the group Diffc0(M).
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