Traveling profiles and control cost for a PDE describing the evolution of invasive species

Abstract

We develop a detailed analysis of optimal traveling waves U(t,x) = U(x - βt) for a model of invasive-species control proposed in [Bressan, Chiri, and Salehi, Math. Models Methods Appl. Sci., 2022] : the relative density U ∈ [0,1] of the invasive species satisfies the following reaction-diffusion equation with a positive control equation Equa:PDEabstract Ut = Uxx + f(U) - α(t,x) U, U ∈ [0,1], \ α≥ 0. equation The control α(t,x) represents the fraction of the population removed at (t,x): the minimal control effort E(β,f) required to sustain a traveling invasion front with prescribed speed β is defined as the minimal L1-norm of α for a traveling wave solution U(x-βt) to the PDE. In order to study large scale dynamics (t,x) (εt,εx), a fundamental role is played by the structure of traveling waves and the convexity and regularity properties of E. The main results of this paper are the following: 1)In the phase plane (U,P=Ux), there exists a unique optimal profile Pβ(U) minimizing the effort; 2) It satisfies explicit first-order conditions, which are both necessary and sufficient; 3) The associated control is acting on an open subset of the set \U : Pβ(U) = U f(U)\, in particular it is uniformly integrable, and it depends smoothly on (β,f) on a dense open set; 4)The effort function E(β,f) is only C1 w.r.t. β and Lipschitz w.r.t. f in the C2-topology, and is asymptocally linear for β ∞; 5)β E(β,f) is in general neither convex nor subadditive.