Time-averaging for weakly nonlinear CGL equations with arbitrary potentials

Abstract

Consider weakly nonlinear complex Ginzburg--Landau (CGL) equation of the form: ut+i(- u+V(x)u)=εμ u+ε P( u), x∈ Rd\,, (*) under the periodic boundary conditions, where μ≥slant0 and P is a smooth function. Let \ζ1(x),ζ2(x),…\ be the L2-basis formed by eigenfunctions of the operator - +V(x). For a complex function u(x), write it as u(x)=Σk≥slant1vkζk(x) and set Ik(u)=12|vk|2. Then for any solution u(t,x) of the linear equation (*)ε=0 we have I(u(t,·))=const. In this work it is proved that if equation (*) with a sufficiently smooth real potential V(x) is well posed on time-intervals t ε-1, then for any its solution uε(t,x), the limiting behavior of the curve I(uε(t,·)) on time intervals of order ε-1, as ε0, can be uniquely characterized by a solution of a certain well-posed effective equation: ut=εμ u+ε F(u), where F(u) is a resonant averaging of the nonlinearity P(u). We also prove a similar results for the stochastically perturbed equation, when a white in time and smooth in x random force of order ε is added to the right-hand side of the equation. The approach of this work is rather general. In particular, it applies to equations in bounded domains in Rd under Dirichlet boundary conditions.