A computational framework of high order conservative finite difference methods to approximate the solution of a general system of N coupled nonlinear Schrödinger equations (N-CNLS) is proposed. Exact conservation of the discrete analogues of the mass and the system's Hamiltonian is achieved by decomposing the original system into a sequence of smaller nonlinear problems, associated to each component of the complex field, and a modified Crank–Nicolson time marching scheme appropriately designed for systems. For a particular model problem, we formally prove that a method, based on the standard second order difference formula, converges with order τ+h2; and, using the theory of composition method, schemes of order τ2+h2 and τ4+h2 are derived. The methodology can be easily extended to other high order finite difference formulas and composition methods. Conservation and accuracy are numerically validated.

Aguilera, A., Castillo, P., Gomez, S. (2021). Structure preserving-Field directional splitting difference methods for nonlinear Schrodinger systems. APPLIED MATHEMATICS LETTERS, 119 [10.1016/j.aml.2021.107211].

Structure preserving-Field directional splitting difference methods for nonlinear Schrodinger systems

Sergio Gomez
2021

Abstract

A computational framework of high order conservative finite difference methods to approximate the solution of a general system of N coupled nonlinear Schrödinger equations (N-CNLS) is proposed. Exact conservation of the discrete analogues of the mass and the system's Hamiltonian is achieved by decomposing the original system into a sequence of smaller nonlinear problems, associated to each component of the complex field, and a modified Crank–Nicolson time marching scheme appropriately designed for systems. For a particular model problem, we formally prove that a method, based on the standard second order difference formula, converges with order τ+h2; and, using the theory of composition method, schemes of order τ2+h2 and τ4+h2 are derived. The methodology can be easily extended to other high order finite difference formulas and composition methods. Conservation and accuracy are numerically validated.
Articolo in rivista - Articolo scientifico
Coupled nonlinear Schrödinger systems; Finite difference; Mass (charge) and Hamiltonian conservation; Splitting and composition methods;
English
2021
119
107211
none
Aguilera, A., Castillo, P., Gomez, S. (2021). Structure preserving-Field directional splitting difference methods for nonlinear Schrodinger systems. APPLIED MATHEMATICS LETTERS, 119 [10.1016/j.aml.2021.107211].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/442743
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