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Main Authors: Stanley, Michael, Coons, Thomas, Bomarito, Geoffrey, Leser, Patrick, Pribe, Joshua, Warner, James
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.23016
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_version_ 1866914590461263872
author Stanley, Michael
Coons, Thomas
Bomarito, Geoffrey
Leser, Patrick
Pribe, Joshua
Warner, James
author_facet Stanley, Michael
Coons, Thomas
Bomarito, Geoffrey
Leser, Patrick
Pribe, Joshua
Warner, James
contents Multi-fidelity Monte Carlo (MFMC) is a variance reduction method that leverages a multi-fidelity ensemble of models of varying cost and accuracy levels. Constructing an MFMC estimator with optimal variance requires knowledge of the correlation coefficients between the different fidelity models which are not usually known in practice. The correlations are typically estimated using offline pilot samples and the sample correlation formula, after which the MFMC method proceeds as if the estimated correlations are the true correlations. Computational cost often restricts the number of pilot samples used leading to poor correlation estimates and suboptimal estimators. Leveraging the MFMC problem setting and probabilistic information about the sample covariance matrix, we present a method to improve standard sample-based correlation estimates in the presence of limited pilot samples. We define a novel discrepancy function quantifying the estimator suboptimality which in turn facilitates selecting a correlation estimator minimizing the worst-case expected discrepancy, where the expectation is taken with respect to the pilot sampling variability. Through a simple bivariate Gaussian example and a multi-fidelity modeling application from a NASA Entry, Descent, and Landing (EDL) problem, we show that this method produces better MFMC estimators than the standard sample covariance under small pilot sample sizes and limited total budgets.
format Preprint
id arxiv_https___arxiv_org_abs_2605_23016
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Sample correlation adjustments for robust Multi-fidelity Monte Carlo under limited pilot sampling
Stanley, Michael
Coons, Thomas
Bomarito, Geoffrey
Leser, Patrick
Pribe, Joshua
Warner, James
Methodology
Computation
Multi-fidelity Monte Carlo (MFMC) is a variance reduction method that leverages a multi-fidelity ensemble of models of varying cost and accuracy levels. Constructing an MFMC estimator with optimal variance requires knowledge of the correlation coefficients between the different fidelity models which are not usually known in practice. The correlations are typically estimated using offline pilot samples and the sample correlation formula, after which the MFMC method proceeds as if the estimated correlations are the true correlations. Computational cost often restricts the number of pilot samples used leading to poor correlation estimates and suboptimal estimators. Leveraging the MFMC problem setting and probabilistic information about the sample covariance matrix, we present a method to improve standard sample-based correlation estimates in the presence of limited pilot samples. We define a novel discrepancy function quantifying the estimator suboptimality which in turn facilitates selecting a correlation estimator minimizing the worst-case expected discrepancy, where the expectation is taken with respect to the pilot sampling variability. Through a simple bivariate Gaussian example and a multi-fidelity modeling application from a NASA Entry, Descent, and Landing (EDL) problem, we show that this method produces better MFMC estimators than the standard sample covariance under small pilot sample sizes and limited total budgets.
title Sample correlation adjustments for robust Multi-fidelity Monte Carlo under limited pilot sampling
topic Methodology
Computation
url https://arxiv.org/abs/2605.23016