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Main Authors: Touron, Camille, Cardoso, Gabriel V., Arbel, Julyan, Rodrigues, Pedro L. C.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.15817
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author Touron, Camille
Cardoso, Gabriel V.
Arbel, Julyan
Rodrigues, Pedro L. C.
author_facet Touron, Camille
Cardoso, Gabriel V.
Arbel, Julyan
Rodrigues, Pedro L. C.
contents Simulation-based inference (SBI) has become a widely used framework in applied sciences for estimating the parameters of stochastic models that best explain experimental observations. A central question in this setting is how to effectively combine multiple observations in order to improve parameter inference and obtain sharper posterior distributions. Recent advances in score-based diffusion methods address this problem by constructing a compositional score, obtained by aggregating individual posterior scores within the diffusion process. While it is natural to suspect that the accumulation of individual errors may significantly degrade sampling quality as the number of observations grows, this important theoretical issue has so far remained unexplored. In this paper, we study the compositional score produced by the GAUSS algorithm of Linhart et al. (2024) and establish an upper bound on its mean squared error in terms of both the individual score errors and the number of observations. We illustrate our theoretical findings on a Gaussian example, where all analytical expressions can be derived in a closed form.
format Preprint
id arxiv_https___arxiv_org_abs_2510_15817
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Error analysis of a compositional score-based algorithm for simulation-based inference
Touron, Camille
Cardoso, Gabriel V.
Arbel, Julyan
Rodrigues, Pedro L. C.
Machine Learning
Simulation-based inference (SBI) has become a widely used framework in applied sciences for estimating the parameters of stochastic models that best explain experimental observations. A central question in this setting is how to effectively combine multiple observations in order to improve parameter inference and obtain sharper posterior distributions. Recent advances in score-based diffusion methods address this problem by constructing a compositional score, obtained by aggregating individual posterior scores within the diffusion process. While it is natural to suspect that the accumulation of individual errors may significantly degrade sampling quality as the number of observations grows, this important theoretical issue has so far remained unexplored. In this paper, we study the compositional score produced by the GAUSS algorithm of Linhart et al. (2024) and establish an upper bound on its mean squared error in terms of both the individual score errors and the number of observations. We illustrate our theoretical findings on a Gaussian example, where all analytical expressions can be derived in a closed form.
title Error analysis of a compositional score-based algorithm for simulation-based inference
topic Machine Learning
url https://arxiv.org/abs/2510.15817