Dimensionality reduction can be used as a surrogate model for high-dimensional forward uncertainty quantification
Abstract
We introduce a method to construct a stochastic surrogate model from the results of dimensionality reduction in forward uncertainty quantification. The hypothesis is that the high-dimensional input augmented by the output of a computational model admits a low-dimensional representation. This assumption can be met by numerous uncertainty quantification applications with physics-based computational models. The proposed approach differs from a sequential application of dimensionality reduction followed by surrogate modeling, as we "extract" a surrogate model from the results of dimensionality reduction in the input-output space. This feature becomes desirable when the input space is genuinely high-dimensional. The proposed method also diverges from the Probabilistic Learning on Manifold, as a reconstruction mapping from the feature space to the input-output space is circumvented. The final product of the proposed method is a stochastic simulator that propagates a deterministic input into a stochastic output, preserving the convenience of a sequential "dimensionality reduction + Gaussian process regression" approach while overcoming some of its limitations. The proposed method is demonstrated through two uncertainty quantification problems characterized by high-dimensional input uncertainties.
Cite
@article{arxiv.2402.04582,
title = {Dimensionality reduction can be used as a surrogate model for high-dimensional forward uncertainty quantification},
author = {Jungho Kim and Sang-ri Yi and Ziqi Wang},
journal= {arXiv preprint arXiv:2402.04582},
year = {2026}
}