6533b835fe1ef96bd129f558

RESEARCH PRODUCT

High precision numerical approach for Davey–Stewartson II type equations for Schwartz class initial data

Kenneth D.t-r MclaughlinChristian KleinNikola Stoilov

subject

semiclassical limitClass (set theory)General MathematicsGeneral Physics and AstronomywaveType (model theory)01 natural sciences010305 fluids & plasmasDavey-Stewartson equationsevolution0103 physical sciencesApplied mathematics[MATH]Mathematics [math]0101 mathematicsMathematicsInverse scattering transform010102 general mathematicsGeneral EngineeringD-bar problemsFourier spectral methodsimulationkadomtsev-petviashviliinverse scattering transformpacketssystemsSolitonsolitonblow-up

description

We present an efficient high-precision numerical approach for Davey–Stewartson (DS) II type equa- tions, treating initial data from the Schwartz class of smooth, rapidly decreasing functions. As with previous approaches, the presented code uses discrete Fourier transforms for the spatial dependence and Driscoll’s composite Runge–Kutta method for the time dependence. Since DS equations are non-local, nonlinear Schrödinger equations with a singular symbol for the non-locality, standard Fourier methods in practice only reach accuracy of the order of 10−6or less for typical examples. This was previously demonstrated for the defocusing integrable case by comparison with a numerical approach for DS II via inverse scattering. By applying a regularization to the singular symbol, originally developed for D-bar problems, the presented code is shown to reach machine precision. The code can treat integrable and non-integrable DS II equations. Moreover, it has the same numerical complexity as existing codes for DS II. Several examples for the integrable defocusing DS II equation are discussed as test cases. In an appendix by C. Kalla, a doubly periodic solution to the defocusing DS II equation is presented, providing a test for direct DS codes based on Fourier methods.

yearjournalcountryeditionlanguage
2020-07-01Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences
https://doi.org/10.1098/rspa.2019.0864