English

Entropy-based closure for probabilistic learning on manifolds

Probability 2018-03-30 v2 Machine Learning

Abstract

In a recent paper, the authors proposed a general methodology for probabilistic learning on manifolds. The method was used to generate numerical samples that are statistically consistent with an existing dataset construed as a realization from a non-Gaussian random vector. The manifold structure is learned using diffusion manifolds and the statistical sample generation is accomplished using a projected Ito stochastic differential equation. This probabilistic learning approach has been extended to polynomial chaos representation of databases on manifolds and to probabilistic nonconvex constrained optimization with a fixed budget of function evaluations. The methodology introduces an isotropic-diffusion kernel with hyperparameter {\epsilon}. Currently, {\epsilon} is more or less arbitrarily chosen. In this paper, we propose a selection criterion for identifying an optimal value of {\epsilon}, based on a maximum entropy argument. The result is a comprehensive, closed, probabilistic model for characterizing data sets with hidden constraints. This entropy argument ensures that out of all possible models, this is the one that is the most uncertain beyond any specified constraints, which is selected. Applications are presented for several databases.

Keywords

Cite

@article{arxiv.1803.08161,
  title  = {Entropy-based closure for probabilistic learning on manifolds},
  author = {C. Soizea and R. Ghanem and C. Safta and X. Huan and Z. P. Vane and J. Oefelein and G. Lacaz and H. N. Najm and Q. Tang and X. Chen},
  journal= {arXiv preprint arXiv:1803.08161},
  year   = {2018}
}

Comments

Co author is not happy with the paper would like to withdraw submission and improve the paper

R2 v1 2026-06-23T01:01:12.148Z