English

Modeling Extremes with d-max-decreasing Neural Networks

Machine Learning 2022-03-03 v2 Machine Learning Computation

Abstract

We propose a novel neural network architecture that enables non-parametric calibration and generation of multivariate extreme value distributions (MEVs). MEVs arise from Extreme Value Theory (EVT) as the necessary class of models when extrapolating a distributional fit over large spatial and temporal scales based on data observed in intermediate scales. In turn, EVT dictates that dd-max-decreasing, a stronger form of convexity, is an essential shape constraint in the characterization of MEVs. As far as we know, our proposed architecture provides the first class of non-parametric estimators for MEVs that preserve these essential shape constraints. We show that our architecture approximates the dependence structure encoded by MEVs at parametric rate. Moreover, we present a new method for sampling high-dimensional MEVs using a generative model. We demonstrate our methodology on a wide range of experimental settings, ranging from environmental sciences to financial mathematics and verify that the structural properties of MEVs are retained compared to existing methods.

Keywords

Cite

@article{arxiv.2102.09042,
  title  = {Modeling Extremes with d-max-decreasing Neural Networks},
  author = {Ali Hasan and Khalil Elkhalil and Yuting Ng and Joao M. Pereira and Sina Farsiu and Jose H. Blanchet and Vahid Tarokh},
  journal= {arXiv preprint arXiv:2102.09042},
  year   = {2022}
}
R2 v1 2026-06-23T23:16:05.393Z