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Autori principali: Boelts, Jan, Schröder, Cornelius, Beck, Jonas, Macke, Jakob H., Deistler, Michael, Gedon, Daniel
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2605.13551
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author Boelts, Jan
Schröder, Cornelius
Beck, Jonas
Macke, Jakob H.
Deistler, Michael
Gedon, Daniel
author_facet Boelts, Jan
Schröder, Cornelius
Beck, Jonas
Macke, Jakob H.
Deistler, Michael
Gedon, Daniel
contents Neural Posterior Estimation (NPE) enables rapid parameter inference for complex simulators with intractable likelihoods. NPE trains an inference network to estimate a probability density over parameters given data, typically assumed to be \emph{continuous}. However, many scientific models involve parameter spaces that are \emph{mixed}, that is, they contain both discrete and continuous dimensions. We address this limitation by extending NPE to mixed parameter spaces through an inference network that jointly handles discrete and continuous parameters. The inference network factorizes the joint posterior into discrete and continuous components, combining an autoregressive classifier for the discrete parameters with a generative model for the continuous parameters, trained jointly under a single simulation-based objective. In addition, we propose a diagnostic tool to assess the calibration of the mixed posterior approximation. Across tractable toy examples and real-world scientific simulators, our joint inference approach yields accurate and calibrated posteriors. The inference framework is available in the \texttt{sbi} Python package.
format Preprint
id arxiv_https___arxiv_org_abs_2605_13551
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Mixed neural posterior estimation for simulators with discrete and continuous parameters
Boelts, Jan
Schröder, Cornelius
Beck, Jonas
Macke, Jakob H.
Deistler, Michael
Gedon, Daniel
Machine Learning
Neural Posterior Estimation (NPE) enables rapid parameter inference for complex simulators with intractable likelihoods. NPE trains an inference network to estimate a probability density over parameters given data, typically assumed to be \emph{continuous}. However, many scientific models involve parameter spaces that are \emph{mixed}, that is, they contain both discrete and continuous dimensions. We address this limitation by extending NPE to mixed parameter spaces through an inference network that jointly handles discrete and continuous parameters. The inference network factorizes the joint posterior into discrete and continuous components, combining an autoregressive classifier for the discrete parameters with a generative model for the continuous parameters, trained jointly under a single simulation-based objective. In addition, we propose a diagnostic tool to assess the calibration of the mixed posterior approximation. Across tractable toy examples and real-world scientific simulators, our joint inference approach yields accurate and calibrated posteriors. The inference framework is available in the \texttt{sbi} Python package.
title Mixed neural posterior estimation for simulators with discrete and continuous parameters
topic Machine Learning
url https://arxiv.org/abs/2605.13551