An Efficient Finite Difference Scheme for the 2D Sine-Gordon Equation

TL;DR

This paper introduces a second-order finite difference scheme for the 2D sine-Gordon equation that conserves energy, is computationally efficient, and is validated through numerical simulations demonstrating accuracy and robustness.

Contribution

A novel semi-implicit finite difference scheme for the 2D sine-Gordon equation that preserves energy and employs an efficient linear iteration method.

Findings

Scheme achieves second-order accuracy.

Energy conservation verified numerically.

Successfully simulates circular ring solitons.

Abstract

We present an efficient second-order finite difference scheme for solving the 2D sine-Gordon equation, which can inherit the discrete energy conservation for the undamped model theoretically. Due to the semi-implicit treatment for the nonlinear term, it leads to a sequence of nonlinear coupled equations. We use a linear iteration algorithm, which can solve them efficiently, and the contraction mapping property is also proven. Based on truncation errors of the numerical scheme, the convergence analysis in the discrete $l^2$-norm is investigated in detail. Moreover, we carry out various numerical simulations, such as verifications of the second order accuracy, tests of energy conservation and circular ring solitons, to demonstrate the efficiency and the robustness of the proposed scheme.