English

A physics and data co-driven surrogate modeling method for high-dimensional rare event simulation

Computation 2024-05-10 v2 Applications

Abstract

This paper presents a physics and data co-driven surrogate modeling method for efficient rare event simulation of civil and mechanical systems with high-dimensional input uncertainties. The method fuses interpretable low-fidelity physical models with data-driven error corrections. The hypothesis is that a well-designed and well-trained simplified physical model can preserve salient features of the original model, while data-fitting techniques can fill the remaining gaps between the surrogate and original model predictions. The coupled physics-data-driven surrogate model is adaptively trained using active learning, aiming to achieve a high correlation and small bias between the surrogate and original model responses in the critical parametric region of a rare event. A final importance sampling step is introduced to correct the surrogate model-based probability estimations. Static and dynamic problems with input uncertainties modeled by random field and stochastic process are studied to demonstrate the proposed method.

Keywords

Cite

@article{arxiv.2310.00261,
  title  = {A physics and data co-driven surrogate modeling method for high-dimensional rare event simulation},
  author = {Jianhua Xian and Ziqi Wang},
  journal= {arXiv preprint arXiv:2310.00261},
  year   = {2024}
}
R2 v1 2026-06-28T12:36:56.099Z