论变换方法：通过较简单线性或非线性微分方程的解获得非线性微分方程的解

IF 1.9 3区数学 Q1 MATHEMATICS, APPLIED

Axioms Pub Date : 2023-12-08 DOI:10.3390/axioms12121106

N. Vitanov

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引用次数: 0

摘要

变换常用于将复杂的非线性微分方程与具有已知精确解的简单方程联系起来。两个例子是Hopf-Cole变换和简单方程法。在本文中，我们遵循一个与Hopf和Cole的思想相反的思想:我们使用变换来将更简单的线性或非线性微分方程(具有已知解)转换为更复杂的非线性微分方程。用这种方法，我们可以得到许多非线性微分方程的精确解。我们将这种方法应用于经典抛物型微分方程(波动方程)、经典双曲型微分方程(热方程)和经典椭圆型微分方程(拉普拉斯方程)。此外，我们还利用线性微分方程的解和Bernoulli和Riccati的非线性微分方程的解来求非线性常微分方程的精确解。最后，我们证明了该方法在其他非线性偏微分方程已知解的基础上得到非线性偏微分方程精确解的能力。作为一个例子，我们使用Korteweg-de Vries方程及其解。本文特别关注非线性微分方程的行波解。我们证明了一些得到的解所描述的以下现象的存在性:(i)孤波-孤反波从解中出现，它在初始时刻为零(类似于从真空中出现粒子和反粒子);(ii)将一个非线性孤立波分裂成两个孤立波(类似于将一个粒子分裂成两个粒子);(iii)某些所得波的孤子行为;(iv)存在以相同速度运动的孤子，尽管孤子的形状和振幅不同。

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On the Method of Transformations: Obtaining Solutions of Nonlinear Differential Equations by Means of the Solutions of Simpler Linear or Nonlinear Differential Equations

Transformations are much used to connect complicated nonlinear differential equations to simple equations with known exact solutions. Two examples of this are the Hopf–Cole transformation and the simple equations method. In this article, we follow an idea that is opposite to the idea of Hopf and Cole: we use transformations in order to transform simpler linear or nonlinear differential equations (with known solutions) to more complicated nonlinear differential equations. In such a way, we can obtain numerous exact solutions of nonlinear differential equations. We apply this methodology to the classical parabolic differential equation (the wave equation), to the classical hyperbolic differential equation (the heat equation), and to the classical elliptic differential equation (Laplace equation). In addition, we use the methodology to obtain exact solutions of nonlinear ordinary differential equations by means of the solutions of linear differential equations and by means of the solutions of the nonlinear differential equations of Bernoulli and Riccati. Finally, we demonstrate the capacity of the methodology to lead to exact solutions of nonlinear partial differential equations on the basis of known solutions of other nonlinear partial differential equations. As an example of this, we use the Korteweg–de Vries equation and its solutions. Traveling wave solutions of nonlinear differential equations are of special interest in this article. We demonstrate the existence of the following phenomena described by some of the obtained solutions: (i) occurrence of the solitary wave–solitary antiwave from the solution, which is zero at the initial moment (analogy of an occurrence of particle and antiparticle from the vacuum); (ii) splitting of a nonlinear solitary wave into two solitary waves (analogy of splitting of a particle into two particles); (iii) soliton behavior of some of the obtained waves; (iv) existence of solitons which move with the same velocity despite the different shape and amplitude of the solitons.

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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.