Random sparse sampling in a Gibbs weighted tree
Abstract
Let be the geometric realization on of a Gibbs measure on associated with a H\"older potential. The thermodynamic and multifractal properties of are well known to be linked via the multifractal formalism. In this article, the impact of a random sampling procedure on this structure is studied. More precisely, let stand for the collection of dyadic subintervals of naturally indexed by the set of finite dyadic words . Fix , and a sequence of independent Bernoulli variables of parameters ( is the length of ). We consider the (very sparse) remaining values . We prove that when , it is possible to entirely reconstruct from the sole knowledge of , while it is not possible when , hence a first phase transition phenomenon. We show that, for all , it is possible to reconstruct a large part of the initial multifractal structure of , via the fine study of . After reorganization, these coefficients give rise to a random capacity with new remarkable scaling and multifractal properties: its -spectrum exhibits two phase transitions, and has a rich thermodynamic and geometric structure.
Cite
@article{arxiv.1512.04368,
title = {Random sparse sampling in a Gibbs weighted tree},
author = {Julien Barral and Stéphane Seuret},
journal= {arXiv preprint arXiv:1512.04368},
year = {2015}
}
Comments
59 pages, 15 figures