Orbit Growth of Sofic Shifts and Periodic-Finite-Type Shifts

IF 1.9 3区数学 Q1 MATHEMATICS

Qualitative Theory of Dynamical Systems Pub Date : 2024-05-09 DOI:10.1007/s12346-024-01055-3

Azmeer Nordin, Mohd Salmi Md Noorani, Mohd Hafiz Mohd

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Abstract

A sofic shift is a shift space consisting of bi-infinite labels of paths from a labelled graph. Being a dynamical system, the distribution of its closed orbits may indicate the complexity of the shift. For this purpose, prime orbit and Mertens’ orbit counting functions are introduced as a way to describe the growth of the closed orbits. The asymptotic behaviours of these counting functions can be implied from the analyticity of the Artin–Mazur zeta function of the shift. Its zeta function is expressed implicitly in terms of several signed subset matrices. In this paper, we will prove the asymptotic behaviours of the counting functions for sofic shifts via their zeta function. This involves investigating the properties of the said matrices. Suprisingly, the proof simply uses some well-known facts about sofic shifts, especially on the minimal right-resolving presentations. Furthermore, we will demonstrate this result by revisiting the case for periodic-finite-type shifts, which are a particular type of sofic shifts. At the end, we will briefly discuss the application of our finding towards the finite group and homogeneous extensions of a sofic shift.

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索菲克位移和周期-菲尼克斯型位移的轨道增长

sofic位移是一个位移空间，由来自带标签图的路径的双无限标签组成。作为一个动力学系统，其闭合轨道的分布可以显示移位的复杂性。为此，我们引入了质轨道和梅尔滕斯轨道计数函数来描述闭合轨道的增长。这些计数函数的渐近行为可以从平移的阿尔丁-马祖尔zeta函数的解析性中得到暗示。它的zeta函数用几个带符号的子集矩阵隐式表示。在本文中，我们将通过其 zeta 函数来证明索菲克偏移的计数函数的渐近行为。这需要研究上述矩阵的性质。令人惊奇的是，证明只需使用一些众所周知的关于索菲克变换的事实，尤其是关于最小右解析呈现的事实。此外，我们还将通过重温周期-有限型变换来证明这一结果，周期-有限型变换是索非克变换的一种特殊类型。最后，我们将简要讨论我们的发现在有限群和索菲克平移的同质扩展中的应用。

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

Qualitative Theory of Dynamical Systems MATHEMATICS, APPLIED-MATHEMATICS

CiteScore

2.50

自引率

14.30%

发文量

130

期刊介绍： Qualitative Theory of Dynamical Systems (QTDS) publishes high-quality peer-reviewed research articles on the theory and applications of discrete and continuous dynamical systems. The journal addresses mathematicians as well as engineers, physicists, and other scientists who use dynamical systems as valuable research tools. The journal is not interested in numerical results, except if these illustrate theoretical results previously proved.