A first-order Fourier integrator for the nonlinear Schr\"odinger equation on T without loss of regularity

Abstract

In this paper, we propose a first-order Fourier integrator for solving the cubic nonlinear Schr\"odinger equation in one dimension. The scheme is explicit and can be implemented using the fast Fourier transform. By a rigorous analysis, we prove that the new scheme provides the first order accuracy in Hγ for any initial data belonging to Hγ, for any γ >32. That is, up to some fixed time T, there exists some constant C=C(\|u\|L∞([0,T]; Hγ))>0, such that \|un-u(tn)\|Hγ( T) C τ, where un denotes the numerical solution at tn=nτ. Moreover, the mass of the numerical solution M(un) verifies |M(un)-M(u0)| Cτ5. In particular, our scheme dose not cost any additional derivative for the first-order convergence and the numerical solution obeys the almost mass conservation law. Furthermore, if u0∈ H1( T), we rigorously prove that \|un-u(tn)\|H1( T) Cτ12-, where C= C(\|u0\|H1( T))>0.