English

Using Machine Learning to predict extreme events in the H\'enon map

Machine Learning 2020-02-25 v1 Chaotic Dynamics Machine Learning

Abstract

Machine Learning (ML) inspired algorithms provide a flexible set of tools for analyzing and forecasting chaotic dynamical systems. We here analyze the performance of one algorithm for the prediction of extreme events in the two-dimensional H\'enon map at the classical parameters. The task is to determine whether a trajectory will exceed a threshold after a set number of time steps into the future. This task has a geometric interpretation within the dynamics of the H\'enon map, which we use to gauge the performance of the neural networks that are used in this work. We analyze the dependence of the success rate of the ML models on the prediction time TT , the number of training samples NTN_T and the size of the network NpN_p. We observe that in order to maintain a certain accuracy, NTexp(2hT)N_T \propto exp(2 h T) and Npexp(hT)N_p \propto exp(hT), where hh is the topological entropy. Similar relations between the intrinsic chaotic properties of the dynamics and ML parameters might be observable in other systems as well.

Keywords

Cite

@article{arxiv.2002.10268,
  title  = {Using Machine Learning to predict extreme events in the H\'enon map},
  author = {Martin Lellep and Jonathan Prexl and Moritz Linkmann and Bruno Eckhardt},
  journal= {arXiv preprint arXiv:2002.10268},
  year   = {2020}
}

Comments

9 pages, 12 figures

R2 v1 2026-06-23T13:51:41.373Z