广义(3+1)维浅水波模型的波浪剖面、paul - painlev方法和相平面分析

IF 1.9 3区 数学 Q1 MATHEMATICS
Minghan Liu, Jalil Manafian, Gurpreet Singh, Abdullah Saad Alsubaie, Khaled Hussein Mahmoud, Parvin Mustafayeva
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引用次数: 0

摘要

本文得到了孤波解、周期解和单孤子解。本文利用Hirota双线性算子研究了单孤子、周期波解和周期波解的渐近情况。利用符号计算和应用方法,研究了广义(3+1)维浅水波浪方程。研究了case周期形式的变分原理格式。(3+1)-GSWW模型表现为行波,本文的研究表明。通过Maple的三维设计、轮廓设计、密度设计和二维设计,较好地解释了单孤子解和周期波解的物理特征。研究结果证明了所研究模型的各种显式解决方案。结果发现了所研究问题的精确孤波解,包括孤波解、单孤子解和周期波解。在建立哈密顿函数后,对相平面进行了快速检查。研究了波速和其他自由因素对波浪剖面的影响。结果表明,该方法在数学物理中具有实用性和灵活性。这项工作的所有结果对于理解所探索结果的物理意义和行为以及阐明研究几种非线性波现象在科学和工程中的意义是必要的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Wave Profile, Paul-Painlevé Approaches and Phase Plane Analysis to the Generalized (3+1)-Dimensional Shallow Water Wave Model

Wave Profile, Paul-Painlevé Approaches and Phase Plane Analysis to the Generalized (3+1)-Dimensional Shallow Water Wave Model

In this paper, the solitary wave solutions, the periodic type, and single soliton solutions are acquired. Here, the Hirota bilinear operator is employed to investigate single soliton, periodic wave solutions and the asymptotic case of periodic wave solutions. By utilizing symbolic computation and the applied method, generalized (3+1)-dimensional shallow water wave (GSWW) equation is investigated. The variational principle scheme to case periodic forms is studied. The (3+1)-GSWW model exhibits travelling waves, as shown by the research in the current paper. Through three-dimensional design, contour design, density design, and two-dimensional design using Maple, the physical features of single soliton and periodic wave solutions are explained all right. The findings demonstrate the investigated model’s broad variety of explicit solutions. As a result, exact solitary wave solutions to the studied issues, including solitary, single soliton, and periodic wave solution, are found. The phase plane is quickly examined after establishing the Hamiltonian function. The effects of wave velocity and other free factors on the wave profile are also investigated. It is shown that the approach is practical and flexible in mathematical physics. All outcomes in this work are necessary to understand the physical meaning and behavior of the explored results and shed light on the significance of the investigation of several nonlinear wave phenomena in sciences and engineering.

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来源期刊
Qualitative Theory of Dynamical Systems
Qualitative Theory of Dynamical Systems MATHEMATICS, APPLIED-MATHEMATICS
CiteScore
2.50
自引率
14.30%
发文量
130
期刊介绍: Qualitative Theory of Dynamical Systems (QTDS) publishes high-quality peer-reviewed research articles on the theory and applications of discrete and continuous dynamical systems. The journal addresses mathematicians as well as engineers, physicists, and other scientists who use dynamical systems as valuable research tools. The journal is not interested in numerical results, except if these illustrate theoretical results previously proved.
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