Local time of self-affine sets of Brownian motion type and the jigsaw puzzle problem

Let Ω⊂[0,1]×[0,1] be the solution of the set equation:Ω=⋃i=1k(φIi,1×φJi,τi)(Ω), where for an interval I=[a,b]⊂[0,1] and τ∈{−1,1}, φI,τ:[0,1]→I is the linear map such that φI,1(0)=a, φI,1(1)=b, φI,−1(0)=b, φI,−1(1)=a, and {Ii;i=1,⋯,k} is a partition of [0,1] with |Ji|=|Ii|1/2. Thus, Ω is a graph of a...

Full description

Saved in:
Bibliographic Details
Published inJournal of mathematical analysis and applications Vol. 419; no. 1; pp. 79 - 93
Main Authors Xue, Yu-Mei, Kamae, Teturo
Format Journal Article
LanguageEnglish
Published Elsevier Inc 01.11.2014
Subjects
Hausdorff dimension
Jigsaw puzzle
Local time
Self-affine set of Brownian motion type
Self-affine set of Brownian motion type
Hausdorff dimension
Jigsaw puzzle
Local time
Online AccessGet full text

Cover

More Information
Summary:Let Ω⊂[0,1]×[0,1] be the solution of the set equation:Ω=⋃i=1k(φIi,1×φJi,τi)(Ω), where for an interval I=[a,b]⊂[0,1] and τ∈{−1,1}, φI,τ:[0,1]→I is the linear map such that φI,1(0)=a, φI,1(1)=b, φI,−1(0)=b, φI,−1(1)=a, and {Ii;i=1,⋯,k} is a partition of [0,1] with |Ji|=|Ii|1/2. Thus, Ω is a graph of a Borel function fΩ almost surely and it is called a self-affine set of Brownian motion type. Let λ be the Lebesgue measure on [0,1] and let μΩ=λ∘fΩ−1. The density ρΩ=dμΩdλ, if it exists, is called the local time of Ω and it has been studied. It is known that dimHΩ=3/2 if ρΩ exists. In the present study, ρΩ is obtained by solving the so-called jigsaw puzzle on {Ji,τi;i=1,⋯,k}, i.e., the problem of decomposing ρΩ into a sum of its self-similar images with the support Ji and the orientation τi for i=1,⋯,k.
ISSN:0022-247X
1096-0813
DOI:10.1016/j.jmaa.2014.04.018