English

Ratio geometry, rigidity and the scenery process for hyperbolic Cantor sets

Dynamical Systems 2016-09-06 v1

Abstract

Given a C1+γC^{1+\gamma} hyperbolic Cantor set CC, we study the sequence Cn,xC_{n,x} of Cantor subsets which nest down toward a point xx in CC. We show that Cn,xC_{n,x} 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 Ck+γ,CC^{k+\gamma}, C^\infty or CωC^\omega hyperbolic Cantor sets, with the highest degree of smoothness which occurs in the C1+γC^{1+\gamma} conjugacy class of CC. The proof of this leads to the following rigidity theorem: if two Ck+γ,CC^{k+\gamma}, C^\infty or CωC^\omega hyperbolic Cantor sets are C1C^1-conjugate, then the conjugacy (with a different extension) is in fact already Ck+γ,CC^{k+\gamma}, C^\infty or CωC^\omega. Within one C1+γC^{1+\gamma} 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 C1C^1 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}
}