On the Solution of Zabolotskaya–Khokhlov Equation Using Differential Quadrature Method by Fourier and Lagrange Bases

IF 1.8 3区数学 Q1 MATHEMATICS, APPLIED

Mathematical Methods in the Applied Sciences Pub Date : 2025-07-26 DOI:10.1002/mma.70005

A. Elmekawy, M. S. El-Azab, Atallah El-Shenawy

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引用次数: 0

Abstract

This manuscript provides a comprehensive investigation of the Zabolotskaya–Khokhlov (Z-K) equation, a nonlinear partial differential equation essential for modeling wave propagation in acoustics. The main goal is to formulate and assess a hybrid numerical approach that combines finite difference and differential quadrature techniques, utilizing both Fourier and Lagrange basis functions to improve accuracy and efficiency. The problem formulation commences with defining the parameters and physical meaning of the Z-K equation, succeeded by its discretization in both temporal and spatial domains utilizing the proposed hybrid methodology. We systematically investigate the application of the differential quadrature method for approximating spatial derivatives while utilizing the finite difference method for temporal discretization. The paper introduces a quasi-linearization technique based on Taylor expansion of the nonlinear temporal terms. This dual methodology facilitates a versatile and resilient handling of the nonlinear features of the Z-K equation. A comprehensive error analysis is performed, establishing limits on both temporal and spatial errors related to the numerical solutions. The results indicate that the hybrid approach markedly enhances accuracy relative to conventional methods, with error barriers determined through meticulous mathematical derivation and corroborated by numerical simulations. The proposed scheme provides an error estimate of orders $𝒪 (Δ t^{2}, \frac{ς h^{(N - σ)}}{(N - σ)!}), 𝒪 (Δ t^{2}, \frac{ς 2^{(N - σ)}}{(N - σ)!})$ for both Lagrange and Fourier bases, respectively. The results indicate the method's effectiveness in capturing the complex behavior of wave propagation, rendering it a viable instrument for applications in acoustics and related domains. This study enhances the numerical solutions of the Z-K equation and offers insights into the wider use of hybrid approaches for solving nonlinear wave equations.

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用傅里叶和拉格朗日基微分积分法求解Zabolotskaya-Khokhlov方程

这份手稿提供了一个全面的调查Zabolotskaya-Khokhlov （Z-K）方程，非线性偏微分方程必不可少的模拟波传播在声学。主要目标是制定和评估结合有限差分和微分正交技术的混合数值方法，利用傅里叶和拉格朗日基函数来提高精度和效率。问题的表述从定义Z-K方程的参数和物理意义开始，然后利用所提出的混合方法在时间和空间域中进行离散化。我们系统地研究了微分正交法近似空间导数的应用，同时利用有限差分法进行时间离散化。本文介绍了一种基于非线性时间项泰勒展开的拟线性化技术。这种对偶方法有助于对Z-K方程的非线性特征进行通用和弹性处理。进行了全面的误差分析，建立了与数值解相关的时间和空间误差的限制。结果表明，与传统方法相比，混合方法的精度明显提高，其误差障碍是通过细致的数学推导确定的，并得到数值模拟的证实。所提出的方案提供了阶数的误差估计：ς h （N−σ）（n−σ）！，态Δ t1，ς 2 （n−σ）（n−σ）！分别适用于拉格朗日基和傅里叶基。结果表明，该方法在捕捉波传播的复杂行为方面是有效的，使其成为声学和相关领域应用的可行仪器。该研究增强了Z-K方程的数值解，并为更广泛地使用混合方法求解非线性波动方程提供了见解。

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

Mathematical Methods in the Applied Sciences 数学-应用数学

CiteScore

4.90

自引率

6.90%

发文量

798

审稿时长

6 months

期刊介绍： Mathematical Methods in the Applied Sciences publishes papers dealing with new mathematical methods for the consideration of linear and non-linear, direct and inverse problems for physical relevant processes over time- and space- varying media under certain initial, boundary, transition conditions etc. Papers dealing with biomathematical content, population dynamics and network problems are most welcome. Mathematical Methods in the Applied Sciences is an interdisciplinary journal: therefore, all manuscripts must be written to be accessible to a broad scientific but mathematically advanced audience. All papers must contain carefully written introduction and conclusion sections, which should include a clear exposition of the underlying scientific problem, a summary of the mathematical results and the tools used in deriving the results. Furthermore, the scientific importance of the manuscript and its conclusions should be made clear. Papers dealing with numerical processes or which contain only the application of well established methods will not be accepted. Because of the broad scope of the journal, authors should minimize the use of technical jargon from their subfield in order to increase the accessibility of their paper and appeal to a wider readership. If technical terms are necessary, authors should define them clearly so that the main ideas are understandable also to readers not working in the same subfield.