English

Finite resolution effects in p-leader multifractal analysis

Numerical Analysis 2017-05-05 v2

Abstract

Multifractal analysis has become a standard signal processing tool,for which a promising new formulation, the p-leader multifractal formalism, has recently been proposed. It relies on novel multiscale quantities, the p-leaders, defined as local l^p norms of sets of wavelet coefficients located at infinitely many fine scales. Computing such infinite sums from actual finite-resolution data requires truncations to the finest available scale, which results in biased p-leaders and thus in inaccurate estimates of multifractal properties. A systematic study of such finite-resolution effects leads to conjecture an explicit and universal closed-form correction that permits an accurate estimation of scaling exponents. This conjecture is formulated from the theoretical study of a particular class of models for multifractal processes, the wavelet-based cascades. The relevance and generality of the proposed conjecture is assessed by numerical simulations conducted over a large variety of multifractal processes. Finally, the relevance of the proposed corrected estimators is demonstrated on the analysis of heart rate variability data.

Keywords

Cite

@article{arxiv.1612.01430,
  title  = {Finite resolution effects in p-leader multifractal analysis},
  author = {Roberto Leonarduzzi and Herwig Wendt and Patrice Abry and Stéphane Jaffard and Clothilde Melot},
  journal= {arXiv preprint arXiv:1612.01430},
  year   = {2017}
}

Comments

10 pages, accepted in IEEE Transactions in Signal Processing

R2 v1 2026-06-22T17:13:44.136Z