A Generalized Sine-Gordon Equation: Reductions and Integrable Discretizations

IF 2.6 2区数学 Q1 MATHEMATICS, APPLIED

Journal of Nonlinear Science Pub Date : 2024-04-17 DOI:10.1007/s00332-024-10030-w

Han-Han Sheng, Bao-Feng Feng, Guo-Fu Yu

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Abstract

In this paper, we propose fully discrete analogues of a generalized sine-Gordon (gsG) equation \(u_{t x}=\left( 1+\nu \partial _x^2\right) \sin u\). The key points of the construction are based on the bilinear discrete KP hierarchy and appropriate definition of discrete reciprocal transformations. We derive semi-discrete analogues of the gsG equation from the fully discrete gsG equation by taking the temporal parameter limit \(b\rightarrow 0\). In particular, one fully discrete gsG equation is reduced to a semi-discrete gsG equation in the case of \(\nu =-1\) (Feng et al. in Numer Algorithms 94:351–370, 2023). Furthermore, N-soliton solutions to the semi- and fully discrete analogues of the gsG equation in the determinant form are presented. Dynamics of one- and two-soliton solutions for the discrete gsG equations are analyzed. By introducing a parameter c, we demonstrate that the gsG equation can reduce to the sine-Gordon equation and the short pulse at the levels of continuous, semi-discrete and fully discrete cases. The limiting forms of the N-soliton solutions to the gsG equation in each level also correspond to those of the sine-Gordon equation and the short pulse equation.

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广义正弦-戈登方程：还原与积分离散化

在本文中，我们提出了广义正弦-戈登（gsG）方程（u_{t x}=left( 1+\nu \partial _x^2\right) \sin u\ ）的完全离散类比。构造的要点基于双线性离散 KP 层次和离散倒易变换的适当定义。我们通过时间参数极限 \(b\arrow 0\) 从完全离散的 gsG 方程推导出 gsG 方程的半离散类似物。特别是，在 \(\nu =-1\) 的情况下，一个完全离散的gsG方程被简化为一个半离散的gsG方程（Feng等人，发表于《数值算法》94:351-370，2023年）。此外，还提出了行列式的半离散和全离散类似 gsG 方程的 N-孑子解。我们还分析了离散 gsG 方程的单oliton 和双oliton 解的动力学。通过引入参数 c，我们证明了 gsG 方程可以在连续、半离散和完全离散的情况下还原为正弦-戈登方程和短脉冲。gsG 方程在各层次上的 N 索利子解的极限形式也对应于正弦-戈登方程和短脉冲方程的极限形式。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Nonlinear Science 数学-力学

CiteScore

5.00

自引率

3.30%

发文量

审稿时长

4.5 months

期刊介绍： The mission of the Journal of Nonlinear Science is to publish papers that augment the fundamental ways we describe, model, and predict nonlinear phenomena. Papers should make an original contribution to at least one technical area and should in addition illuminate issues beyond that area''s boundaries. Even excellent papers in a narrow field of interest are not appropriate for the journal. Papers can be oriented toward theory, experimentation, algorithms, numerical simulations, or applications as long as the work is creative and sound. Excessively theoretical work in which the application to natural phenomena is not apparent (at least through similar techniques) or in which the development of fundamental methodologies is not present is probably not appropriate. In turn, papers oriented toward experimentation, numerical simulations, or applications must not simply report results without an indication of what a theoretical explanation might be. All papers should be submitted in English and must meet common standards of usage and grammar. In addition, because ours is a multidisciplinary subject, at minimum the introduction to the paper should be readable to a broad range of scientists and not only to specialists in the subject area. The scientific importance of the paper and its conclusions should be made clear in the introduction-this means that not only should the problem you study be presented, but its historical background, its relevance to science and technology, the specific phenomena it can be used to describe or investigate, and the outstanding open issues related to it should be explained. Failure to achieve this could disqualify the paper.