Ratio geometry, rigidity and the scenery process for hyperbolic Cantor sets
Abstract
Given a hyperbolic Cantor set , we study the sequence of Cantor subsets which nest down toward a point in . We show that is asymptotically equal to an ergodic Cantor set valued process. The values of this process, called limit sets, are indexed by a H\"older continuous set-valued function defined on D. Sullivan's dual Cantor set. We show the limit sets are themselves or hyperbolic Cantor sets, with the highest degree of smoothness which occurs in the conjugacy class of . The proof of this leads to the following rigidity theorem: if two or hyperbolic Cantor sets are -conjugate, then the conjugacy (with a different extension) is in fact already or . Within one conjugacy class, each smoothness class is a Banach manifold, which is acted on by the semigroup given by rescaling subintervals. Conjugacy classes nest down, and contained in the intersection of them all is a compact set which is the attractor for the semigroup: the collection of limit sets. Convergence is exponentially fast, in the norm.
Keywords
Cite
@article{arxiv.math/9405217,
title = {Ratio geometry, rigidity and the scenery process for hyperbolic Cantor sets},
author = {Tim Bedford and Albert M. Fisher},
journal= {arXiv preprint arXiv:math/9405217},
year = {2016}
}