Analysis of the Burgers–Huxley Equation Using the Nondimensionalisation Technique: Universal Solution for Dirichlet and Symmetry Boundary Conditions

IF 1.9 3区数学 Q1 MATHEMATICS, APPLIED

Axioms Pub Date : 2023-12-11 DOI:10.3390/axioms12121113

J. Sánchez-Pérez, Joaquín Solano-Ramírez, Enrique Castro, M. Conesa, Fulgencio Marín-García, G. García-Ros

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Abstract

The Burgers–Huxley equation is important because it involves the phenomena of accumulation, drag, diffusion, and the generation or decay of species, which are common in various problems in science and engineering, such as heat transmission, the diffusion of atmospheric contaminants, etc. On the other hand, the mathematical technique of nondimensionalisation has proven to be very useful in the appropriate grouping of the variables involved in a physical–chemical phenomenon and in obtaining universal solutions to different complex engineering problems. Therefore, a deep analysis using this technique of the Burgers–Huxley equation and its possible boundary conditions can facilitate a common understanding of these problems through the appropriate grouping of variables and propose common universal solutions. Thus, in this case, the technique is applied to obtain a universal solution for Dirichlet and symmetric boundary conditions. The validation of the methodology is carried out by comparing different cases, where the coefficients or the value of the boundary condition are varied, with the results obtained through a numerical simulation. Furthermore, one of the cases presented presents a boundary condition that changes at a certain time. Finally, after applying the technique, it is studied which phenomenon is predominant, concluding that from a certain value diffusion predominates, with the rest being practically negligible.

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利用非尺寸化技术分析伯格斯-赫胥黎方程：迪里夏特和对称边界条件的通用解法

伯格斯-赫胥黎方程之所以重要，是因为它涉及物种的积聚、阻力、扩散和生成或衰变现象，这些现象在科学和工程领域的各种问题中很常见，如热传导、大气污染物的扩散等。另一方面，事实证明，无量纲化数学技术非常有助于对物理化学现象中涉及的变量进行适当分组，并获得不同复杂工程问题的通用解决方案。因此，利用这种技术对伯格斯-赫胥黎方程及其可能的边界条件进行深入分析，可以通过对变量进行适当分组，促进对这些问题的共同理解，并提出通用的通用解决方案。因此，在本案例中，应用该技术获得了 Dirichlet 和对称边界条件的通用解。通过比较不同情况下的系数或边界条件值与数值模拟获得的结果，对该方法进行了验证。此外，其中一个案例中的边界条件在一定时间内会发生变化。最后，在应用该技术后，对哪种现象占主导地位进行了研究，得出的结论是，从某个值开始，扩散现象占主导地位，其他现象实际上可以忽略不计。

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

Axioms Mathematics-Algebra and Number Theory

自引率

10.00%

发文量

604

审稿时长

11 weeks

期刊介绍： Axiomatic theories in physics and in mathematics (for example, axiomatic theory of thermodynamics, and also either the axiomatic classical set theory or the axiomatic fuzzy set theory) Axiomatization, axiomatic methods, theorems, mathematical proofs Algebraic structures, field theory, group theory, topology, vector spaces Mathematical analysis Mathematical physics Mathematical logic, and non-classical logics, such as fuzzy logic, modal logic, non-monotonic logic. etc. Classical and fuzzy set theories Number theory Systems theory Classical measures, fuzzy measures, representation theory, and probability theory Graph theory Information theory Entropy Symmetry Differential equations and dynamical systems Relativity and quantum theories Mathematical chemistry Automata theory Mathematical problems of artificial intelligence Complex networks from a mathematical viewpoint Reasoning under uncertainty Interdisciplinary applications of mathematical theory.