具有多个绝对连续不变测度的自洽动力系统

IF 1 Q3 Engineering

Journal of Computational Dynamics Pub Date : 2019-09-10 DOI:10.3934/jcd.2021002

Fanni M. S'elley

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引用次数: 5

摘要

本文研究了一类\emph{自洽动力系统，自洽}是指离散时间动力学在每一步中随当前统计量的不同而不同。一般框架允许流行的例子，如耦合地图系统。受M. Blank的一个例子的启发，我们专注于一个特殊情况，其中每个步骤中的动态是一个$\beta$ -map和一些$\beta \geq 2$。在$\beta$的定义中包含了一个控制自洽强度的参数$\varepsilon > 0$。我们证明了这样一个自洽系统，它对$\varepsilon=0$有唯一的绝对连续不变测度(acim)，但对任意$\varepsilon > 0$至少有两个。稍微修改一下，我们将这个系统转换成一个产生类似相变行为的系统:它对$0< \varepsilon < \varepsilon^*$有一个唯一的acim，对$\varepsilon$有足够大的值有多个。利用自洽转移算子的数值表示，通过计算机模拟讨论了不变量测度的稳定性。

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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A self-consistent dynamical system with multiple absolutely continuous invariant measures

In this paper we study a class of \emph{self-consistent dynamical systems}, self-consistent in the sense that the discrete time dynamics is different in each step depending on current statistics. The general framework admits popular examples such as coupled map systems. Motivated by an example of M. Blank, we concentrate on a special case where the dynamics in each step is a $\beta$-map with some $\beta \geq 2$. Included in the definition of $\beta$ is a parameter $\varepsilon > 0$ controlling the strength of self-consistency. We show such a self-consistent system which has a unique absolutely continuous invariant measure (acim) for $\varepsilon=0$, but at least two for any $\varepsilon > 0$. With a slight modification, we transform this system into one which produces a phase transition-like behavior: it has a unique acim for $0< \varepsilon < \varepsilon^*$, and multiple for sufficiently large values of $\varepsilon$. We discuss the stability of the invariant measures by the help of computer simulations employing the numerical representation of the self-consistent transfer operator.

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来源期刊

Journal of Computational Dynamics Engineering-Computational Mechanics

CiteScore

2.30

自引率

10.00%

发文量

期刊介绍： JCD is focused on the intersection of computation with deterministic and stochastic dynamics. The mission of the journal is to publish papers that explore new computational methods for analyzing dynamic problems or use novel dynamical methods to improve computation. The subject matter of JCD includes both fundamental mathematical contributions and applications to problems from science and engineering. A non-exhaustive list of topics includes * Computation of phase-space structures and bifurcations * Multi-time-scale methods * Structure-preserving integration * Nonlinear and stochastic model reduction * Set-valued numerical techniques * Network and distributed dynamics JCD includes both original research and survey papers that give a detailed and illuminating treatment of an important area of current interest. The editorial board of JCD consists of world-leading researchers from mathematics, engineering, and science, all of whom are experts in both computational methods and the theory of dynamical systems.