离散分数阶捕食者-猎物系统耦合网络中的多重分岔与混沌控制

IF 1.4 4区 综合性期刊 Q2 MULTIDISCIPLINARY SCIENCES
Neriman Kartal
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引用次数: 0

摘要

与连续时间动力学系统相比,离散时间动力学系统表现出更丰富的动力学行为,如混沌。为了描述二维分数阶 Lesli-Gower 捕食系统中的混沌,我们需要从分数连续时间动力学系统过渡到离散时间版本。实现这一过渡的实用方法之一是在模型中使用片断常数参数。基于在区间 \(t\in [nh, (n+1)h)\) 中使用片断常数参数的离散化程序之后,我们得到了一个新的二维差分方程系统。利用 Schur-Cohn 判据给出了平衡点稳定的必要条件和充分条件。同时还研究了离散系统正平衡点附近可能存在的分岔类型。理论分析表明,系统在参数 q 的作用下会发生 Neimark-Sacker 分岔和翻转分岔。此外,还研究了离散捕食者-猎物系统耦合网络中的分岔。数值模拟表明,当耦合强度参数达到临界值时,复杂动力学网络中会形成混沌行为。所有涉及耦合网络稳定性、分岔和过渡混沌的理论结果都是由数值模拟激发的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Multiple Bifurcations and Chaos Control in a Coupled Network of Discrete Fractional Order Predator–Prey System

Multiple Bifurcations and Chaos Control in a Coupled Network of Discrete Fractional Order Predator–Prey System

Discrete-time dynamical system exhibits richer dynamical behaviors such as chaos rather than continuous-time dynamical systems. In order to describe chaos in two dimensional fractional order Lesli–Gower predator–prey systems, we need to transition from fractional continuous-time dynamical systems to the discrete-time version. One of the practical ways to achieve this transition is to use piecewise constant arguments in the model. After the discretization procedure based on the use of piecewise constant arguments in the interval \(t\in [nh, (n+1)h)\), we obtain a new two dimensional system of difference equations. Necessary and sufficient conditions for the stability of the equilibrium points are given by using Schur–Cohn criterions. It is also investigated the existence of possible bifurcation types about the positive equilibrium point of the discrete system. Theoretical analysis shows that the system undergoes Neimark–Sacker and flip bifurcations with respect to parameter q. In addition, OGY feedback control method is implemented in order to control chaos in discrete model. Bifurcations in a coupled network of the discrete predator–prey system are also examined. Numerical simulations show that when the coupling strength parameter arrives the critical value, chaotic behavior is formed in the complex dynamical networks. All of the theoretical results dealing with the stability, bifurcation and transition chaos in the coupled network are stimulated by numerical simulations.

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来源期刊
CiteScore
4.00
自引率
5.90%
发文量
122
审稿时长
>12 weeks
期刊介绍: The aim of this journal is to foster the growth of scientific research among Iranian scientists and to provide a medium which brings the fruits of their research to the attention of the world’s scientific community. The journal publishes original research findings – which may be theoretical, experimental or both - reviews, techniques, and comments spanning all subjects in the field of basic sciences, including Physics, Chemistry, Mathematics, Statistics, Biology and Earth Sciences
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