Dynamics of solutions of nonlinear functional differential equation of parabolic type

IF 0.5 Q4 PHYSICS, MULTIDISCIPLINARY

Izvestiya Vysshikh Uchebnykh Zavedeniy-Prikladnaya Nelineynaya Dinamika Pub Date : 2022-03-31 DOI:10.18500/0869-6632-2022-30-2-132-151

A. Kornuta, V. Lukianenko

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引用次数: 0

Abstract

Purpose of this work is to study the initial-boundary value problem for a parabolic functional-differential equation in an annular region, which describes the dynamics of phase modulation of a light wave passing through a thin layer of a nonlinear Kerr-type medium in an optical system with a feedback loop, with a rotation transformation (corresponds the involution operator) and the Neumann conditions on the boundary in the class of periodic functions. A more detailed study is made of spatially inhomogeneous stationary solutions bifurcating from a spatially homogeneous stationary solution as a result of a bifurcation of the “fork” type and time-periodic solutions of the “traveling wave” type. Methods. To represent the original equation in the form of nonlinear integral equations, the Green’s function is used. The method of central manifolds is used to prove the theorem on the existence of solutions of the indicated equation in a neighborhood of the bifurcation parameter and to study their asymptotic form. Numerical modeling of spatially inhomogeneous solutions and traveling waves was carried out using the Galerkin method. Results. Integral representations of the considered problem are obtained depending on the form of the linearized operator. Using the method of central manifolds, a theorem on the existence and asymptotic form of solutions of the initial-boundary value problem for a functional-differential equation of parabolic type with an involution operator on an annulus is proved. As a result of numerical modeling based on Galerkin approximations, in the problem under consideration, approximate spatially inhomogeneous stationary solutions and time-periodic solutions of the traveling wave type are constructed. Conclusion. The proposed scheme is applicable not only to involutive rotation operators and Neumann conditions on the boundary of the ring, but also to other boundary conditions and circular domains. The representation of the initial-boundary value problem in the form of nonlinear integral equations of the second kind allows one to more simply find the coefficients of asymptotic expansions, prove existence and uniqueness theorems, and also use a different number of expansion coefficients of the nonlinear component in the right-hand side of the original equation in the neighborhood of the selected solution (for example, stationary). Visualization of the numerical solution confirms the theoretical calculations and shows the possibility of forming complex phase structures.

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抛物型非线性泛函微分方程解的动力学

本文的目的是研究环形区域中抛物型泛函微分方程的初边值问题，该问题描述了具有反馈环的光学系统中光波通过非线性kerr型介质薄层时的相位调制动力学，该方程具有周期函数类的旋转变换(对应对合算子)和边界上的Neumann条件。更详细地研究了空间非齐次平稳解由于“叉”型分岔和“行波”型时周期解的分岔而从空间均匀平稳解分岔的问题。方法。为了将原方程表示为非线性积分方程，采用格林函数。利用中心流形的方法，证明了所指示方程在分岔参数的邻域内解的存在性定理，并研究了其渐近形式。采用伽辽金方法对空间非齐次解和行波进行了数值模拟。结果。所考虑的问题的积分表示取决于线性化算子的形式。利用中心流形的方法，证明了环上带对合算子的抛物型泛函微分方程初边值问题解的存在性和渐近形式定理。基于伽辽金近似的数值模拟，构造了该问题的空间非齐次平稳近似解和行波型时间周期近似解。结论。该格式不仅适用于环边界上的对合旋转算子和Neumann条件，而且适用于其他边界条件和圆域。用第二类非线性积分方程的形式表示初边值问题，可以更简单地求出渐近展开的系数，证明存在唯一性定理，也可以在所选解的邻域内(例如，平稳)使用原方程右侧非线性分量的不同数量的展开系数。数值解的可视化结果证实了理论计算结果，显示了形成复杂相结构的可能性。

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

Izvestiya Vysshikh Uchebnykh Zavedeniy-Prikladnaya Nelineynaya Dinamika PHYSICS, MULTIDISCIPLINARY-

CiteScore

1.20

自引率

25.00%

发文量

期刊介绍： Scientific and technical journal Izvestiya VUZ. Applied Nonlinear Dynamics is an original interdisciplinary publication of wide focus. The journal is included in the List of periodic scientific and technical publications of the Russian Federation, recommended for doctoral thesis publications of State Commission for Academic Degrees and Titles at the Ministry of Education and Science of the Russian Federation, indexed by Scopus, RSCI. The journal is published in Russian (English articles are also acceptable, with the possibility of publishing selected articles in other languages by agreement with the editors), the articles data as well as abstracts, keywords and references are consistently translated into English. First and foremost the journal publishes original research in the following areas: -Nonlinear Waves. Solitons. Autowaves. Self-Organization. -Bifurcation in Dynamical Systems. Deterministic Chaos. Quantum Chaos. -Applied Problems of Nonlinear Oscillation and Wave Theory. -Modeling of Global Processes. Nonlinear Dynamics and Humanities. -Innovations in Applied Physics. -Nonlinear Dynamics and Neuroscience. All articles are consistently sent for independent, anonymous peer review by leading experts in the relevant fields, the decision to publish is made by the Editorial Board and is based on the review. In complicated and disputable cases it is possible to review the manuscript twice or three times. The journal publishes review papers, educational papers, related to the history of science and technology articles in the following sections: -Reviews of Actual Problems of Nonlinear Dynamics. -Science for Education. Methodical Papers. -History of Nonlinear Dynamics. Personalia.