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Main Authors: Haario, Heikki, Liu, Zhi-Song, Simon, Martin, Weichel, Hendrik
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.10987
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author Haario, Heikki
Liu, Zhi-Song
Simon, Martin
Weichel, Hendrik
author_facet Haario, Heikki
Liu, Zhi-Song
Simon, Martin
Weichel, Hendrik
contents Neural networks are a commonly used approach to replace physical models with computationally cheap surrogates. Parametric uncertainty quantification can be included in training, assuming that an accurate prior distribution of the model parameters is available. Here we study the common opposite situation, where direct screening or random sampling of model parameters leads to exhaustive training times and evaluations at unphysical parameter values. Our solution is to decouple uncertainty quantification from network architecture. Instead of sampling network weights, we introduce the model-parameter distribution as an input to network training via Markov chain Monte Carlo (MCMC). In this way, the surrogate achieves the same uncertainty quantification as the underlying physical model, but with substantially reduced computation time. The approach is fully agnostic with respect to the neural network choice. In our examples, we present a quantile emulator for prediction and a novel autoencoder-based ODE network emulator that can flexibly estimate different trajectory paths corresponding to different ODE model parameters. Moreover, we present a mathematical analysis that provides a transparent way to relate potential performance loss to measurable distribution mismatch.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10987
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle MCMC Informed Neural Emulators for Uncertainty Quantification in Dynamical Systems
Haario, Heikki
Liu, Zhi-Song
Simon, Martin
Weichel, Hendrik
Machine Learning
Neural networks are a commonly used approach to replace physical models with computationally cheap surrogates. Parametric uncertainty quantification can be included in training, assuming that an accurate prior distribution of the model parameters is available. Here we study the common opposite situation, where direct screening or random sampling of model parameters leads to exhaustive training times and evaluations at unphysical parameter values. Our solution is to decouple uncertainty quantification from network architecture. Instead of sampling network weights, we introduce the model-parameter distribution as an input to network training via Markov chain Monte Carlo (MCMC). In this way, the surrogate achieves the same uncertainty quantification as the underlying physical model, but with substantially reduced computation time. The approach is fully agnostic with respect to the neural network choice. In our examples, we present a quantile emulator for prediction and a novel autoencoder-based ODE network emulator that can flexibly estimate different trajectory paths corresponding to different ODE model parameters. Moreover, we present a mathematical analysis that provides a transparent way to relate potential performance loss to measurable distribution mismatch.
title MCMC Informed Neural Emulators for Uncertainty Quantification in Dynamical Systems
topic Machine Learning
url https://arxiv.org/abs/2603.10987