English

Random sparse sampling in a Gibbs weighted tree

Mathematical Physics 2015-12-15 v1 Dynamical Systems Metric Geometry math.MP Probability

Abstract

Let μ\mu be the geometric realization on [0,1][0,1] of a Gibbs measure on Σ={0,1}N\Sigma=\{0,1\}^{\mathbb{N}} associated with a H\"older potential. The thermodynamic and multifractal properties of μ\mu 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 {Iw}wΣ\{I_w\}_{w\in \Sigma^*} stand for the collection of dyadic subintervals of [0,1][0,1] naturally indexed by the set of finite dyadic words Σ\Sigma^*. Fix η(0,1)\eta\in(0,1), and a sequence (pw)wΣ(p_w)_{w\in \Sigma^*} of independent Bernoulli variables of parameters 2w(1η)2^{-|w|(1-\eta)} (w|w| is the length of ww). We consider the (very sparse) remaining values μ~={μ(Iw):wΣ,pw=1}\widetilde\mu=\{\mu(I_w): w\in \Sigma^*, p_w=1\}. We prove that when η<1/2\eta<1/2, it is possible to entirely reconstruct μ\mu from the sole knowledge of μ~\widetilde\mu, while it is not possible when η>1/2\eta>1/2, hence a first phase transition phenomenon. We show that, for all η(0,1)\eta \in (0,1), it is possible to reconstruct a large part of the initial multifractal structure of μ\mu, via the fine study of μ~\widetilde\mu. After reorganization, these coefficients give rise to a random capacity with new remarkable scaling and multifractal properties: its LqL^q-spectrum exhibits two phase transitions, and has a rich thermodynamic and geometric structure.

Keywords

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

R2 v1 2026-06-22T12:09:11.346Z