Hereditarily frequently hypercyclic operators and disjoint frequent hypercyclicity

arXiv - MATH - Functional Analysis Pub Date : 2024-09-11 DOI:arxiv-2409.07103

F. Bayart, S. Grivaux, E. Matheron, Q. Menet

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Abstract

We introduce and study the notion of hereditary frequent hypercyclicity, which is a reinforcement of the well known concept of frequent hypercyclicity. This notion is useful for the study of the dynamical properties of direct sums of operators; in particular, a basic observation is that the direct sum of a hereditarily frequently hypercyclic operator with any frequently hypercyclic operator is frequently hypercyclic. Among other results, we show that operators satisfying the Frequent Hypercyclicity Criterion are hereditarily frequently hypercyclic, as well as a large class of operators whose unimodular eigenvectors are spanning with respect to the Lebesgue measure. On the other hand, we exhibit two frequently hypercyclic weighted shifts $B_w,B_{w'}$ on $c_0(\mathbb{Z}_+)$ whose direct sum $B_w\oplus B_{w'}$ is not $\mathcal{U}$-frequently hypercyclic (so that neither of them is hereditarily frequently hypercyclic), and we construct a $C$-type operator on $\ell_p(\mathbb{Z}_+)$, $1\le p<\infty$ which is frequently hypercyclic but not hereditarily frequently hypercyclic. We also solve several problems concerning disjoint frequent hypercyclicity: we show that for every $N\in\mathbb{N}$, any disjoint frequently hypercyclic $N$-tuple of operators $(T_1,\dots ,T_N)$ can be extended to a disjoint frequently hypercyclic $(N+1)$-tuple $(T_1,\dots ,T_N, T_{N+1})$ as soon as the underlying space supports a hereditarily frequently hypercyclic operator; we construct a disjoint frequently hypercyclic pair which is not densely disjoint hypercyclic; and we show that the pair $(D,\tau_a)$ is disjoint frequently hypercyclic, where $D$ is the derivation operator acting on the space of entire functions and $\tau_a$ is the operator of translation by $a\in\mathbb{C}\setminus\{ 0\}$. Part of our results are in fact obtained in the general setting of Furstenberg families.

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遗传频繁超循环算子和不相连频繁超循环性

我们引入并研究了遗传频繁超周期性的概念，它是对众所周知的频繁超周期性概念的强化。这个概念对于研究算子直接和的动力学性质非常有用；特别是，一个基本观察结果是，遗传频繁超周期算子与任何频繁超周期算子的直接和是频繁超周期的。除其他结果外，我们还证明了满足频繁超循环准则的算子是遗传频繁超循环的，以及一大类算子，它们的单模态特征向量相对于 Lebesgue 度量是遍及的。另一方面，我们展示了$c_0(\mathbb{Z}_+)$上两个频繁超循环的加权移$B_w,B_{w'}$，它们的直接和$B_w\oplus B_{w'}$不是$\mathcal{U}$-频繁超循环的（因此它们都不是遗传频繁超循环的）、我们在$\ell_p(\mathbb{Z}_+)$上构造了一个$C$型算子，$1\le p<\infty$，它是频繁超循环的，但不是遗传频繁超循环的。我们还解决了几个与频繁超循环性相关的问题：我们证明，对于每一个 $N/in/mathbb{N}$，只要底层空间支持一个遗传频繁超循环算子，任何不相邻的频繁超循环 $N$ 元组算子 $(T_1,\dots ,T_N)$ 都可以扩展为不相邻的频繁超循环 $(N+1)$ 元组算子 $(T_1,\dots,T_N, T_{N+1})$ ；我们构造了一个不密集相交超循环的不相交频繁超循环对；我们证明了一对$(D,\tau_a)$是不相交频繁超循环的，其中$D$是作用于全函数空间的求导算子，$\tau_a$是通过$a\in\mathbb{C}\setminus\{ 0\}$平移的算子。我们的部分结果实际上是在弗斯滕伯格族的一般环境中得到的。

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arXiv - MATH - Functional Analysis

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