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Main Authors: Pfrang, David, Petrat, Sören, Reinke, Bernhard, Schleicher, Dierk
Format: Preprint
Published: 2021
Subjects:
Online Access:https://arxiv.org/abs/2109.06863
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author Pfrang, David
Petrat, Sören
Reinke, Bernhard
Schleicher, Dierk
author_facet Pfrang, David
Petrat, Sören
Reinke, Bernhard
Schleicher, Dierk
contents Filaments are a natural generalization of the well-known concept of dynamic rays in complex dynamics. In this article we investigate which periodic or preperiodic filaments land together for arbitrary post-singularly finite transcendental entire functions. Our first main result is a combinatorial description of the landing relation of filaments in terms of the dynamic partitions of the space of external addresses. One of the main difficulties deals with taming the more complicated topology of filaments. In the end, filaments possess all the topological properties of dynamic rays that are essential for the construction of dynamic partitions. The results of this paper are the foundation for the development of combinatorial models, in particular homotopy Hubbard trees, for arbitrary post-singularly finite transcendental entire functions. Our second mail result is that every postsingularly finite entire function has an iterated that possesses and invariant spider: spiders are, like homotopy Hubbard trees, an important tool for the combinatorial classification of postsingularly finite polynomials and presumably also for entire functions.
format Preprint
id arxiv_https___arxiv_org_abs_2109_06863
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Filament Pairs, Dynamic Partitions, and Spiders for Post-Singularly Finite Entire Functions
Pfrang, David
Petrat, Sören
Reinke, Bernhard
Schleicher, Dierk
Dynamical Systems
37F10, 37F20
Filaments are a natural generalization of the well-known concept of dynamic rays in complex dynamics. In this article we investigate which periodic or preperiodic filaments land together for arbitrary post-singularly finite transcendental entire functions. Our first main result is a combinatorial description of the landing relation of filaments in terms of the dynamic partitions of the space of external addresses. One of the main difficulties deals with taming the more complicated topology of filaments. In the end, filaments possess all the topological properties of dynamic rays that are essential for the construction of dynamic partitions. The results of this paper are the foundation for the development of combinatorial models, in particular homotopy Hubbard trees, for arbitrary post-singularly finite transcendental entire functions. Our second mail result is that every postsingularly finite entire function has an iterated that possesses and invariant spider: spiders are, like homotopy Hubbard trees, an important tool for the combinatorial classification of postsingularly finite polynomials and presumably also for entire functions.
title Filament Pairs, Dynamic Partitions, and Spiders for Post-Singularly Finite Entire Functions
topic Dynamical Systems
37F10, 37F20
url https://arxiv.org/abs/2109.06863