English

The ROMES method for statistical modeling of reduced-order-model error

Numerical Analysis 2015-04-16 v3 Numerical Analysis Machine Learning

Abstract

This work presents a technique for statistically modeling errors introduced by reduced-order models. The method employs Gaussian-process regression to construct a mapping from a small number of computationally inexpensive `error indicators' to a distribution over the true error. The variance of this distribution can be interpreted as the (epistemic) uncertainty introduced by the reduced-order model. To model normed errors, the method employs existing rigorous error bounds and residual norms as indicators; numerical experiments show that the method leads to a near-optimal expected effectivity in contrast to typical error bounds. To model errors in general outputs, the method uses dual-weighted residuals---which are amenable to uncertainty control---as indicators. Experiments illustrate that correcting the reduced-order-model output with this surrogate can improve prediction accuracy by an order of magnitude; this contrasts with existing `multifidelity correction' approaches, which often fail for reduced-order models and suffer from the curse of dimensionality. The proposed error surrogates also lead to a notion of `probabilistic rigor', i.e., the surrogate bounds the error with specified probability.

Keywords

Cite

@article{arxiv.1405.5170,
  title  = {The ROMES method for statistical modeling of reduced-order-model error},
  author = {Martin Drohmann and Kevin Carlberg},
  journal= {arXiv preprint arXiv:1405.5170},
  year   = {2015}
}
R2 v1 2026-06-22T04:19:12.183Z