Local exact controllability to the trajectories of the convective Brinkman-Forchheimer equations

Abstract

In this article, we discuss the local exact controllability to trajectories of the following convective Brinkman-Forchheimer (CBF) equations (or damped Navier-Stokes equations) defined in a bounded domain ⊂Rd (d=2,3) with smooth boundary: align* ∂u∂ t-μ u+(u·∇)u+αu+β|u|2u+∇ p=f+, \ \ \ ∇·u=0, align* where the control is distributed in a subdomain ω ⊂ , and the parameters α,β,μ>0 are constants. We first present global Carleman estimates and observability inequality for the adjoint problem of a linearized version of CBF equations by using a global Carleman estimate for the Stokes system. This allows us to obtain its null controllability at any time T>0. We then use the inverse mapping theorem to deduce local results concerning the exact controllability to the trajectories of CBF equations.