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Hauptverfasser: Valsecchi, Davide, Donegà, Mauro, Wallny, Rainer
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2602.13184
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author Valsecchi, Davide
Donegà, Mauro
Wallny, Rainer
author_facet Valsecchi, Davide
Donegà, Mauro
Wallny, Rainer
contents Unbinned likelihood fits aim at maximizing the information one can extract from experimental data, yet their application in realistic statistical analyses is often hindered by the computational cost of profiling systematic uncertainties. Additionally, current machine learning-based inference methods are typically limited to estimating scalar parameters in a multidimensional space rather than full differential distributions. We propose a general framework for Simulation-Based Inference (SBI) that efficiently profiles nuisance parameters while measuring multivariate Distributions of Interest (DoI), defined as learnable invertible transformations of the feature space. We introduce Factorizable Normalizing Flows to model systematic variations as parametric deformations of a nominal density, preserving tractability without combinatorial explosion. Crucially, we develop an amortized training strategy that learns the conditional dependence of the DoI on nuisance parameters in a single optimization process, bypassing the need for repetitive training during the likelihood scan. This allows for the simultaneous extraction of the underlying distribution and the robust profiling of nuisances. The method is validated on a synthetic dataset emulating a high-energy physics measurement with multiple systematic sources, demonstrating its potential for unbinned, functional measurements in complex analyses.
format Preprint
id arxiv_https___arxiv_org_abs_2602_13184
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Profiling systematic uncertainties in Simulation-Based Inference with Factorizable Normalizing Flows
Valsecchi, Davide
Donegà, Mauro
Wallny, Rainer
High Energy Physics - Phenomenology
Data Analysis, Statistics and Probability
Machine Learning
Unbinned likelihood fits aim at maximizing the information one can extract from experimental data, yet their application in realistic statistical analyses is often hindered by the computational cost of profiling systematic uncertainties. Additionally, current machine learning-based inference methods are typically limited to estimating scalar parameters in a multidimensional space rather than full differential distributions. We propose a general framework for Simulation-Based Inference (SBI) that efficiently profiles nuisance parameters while measuring multivariate Distributions of Interest (DoI), defined as learnable invertible transformations of the feature space. We introduce Factorizable Normalizing Flows to model systematic variations as parametric deformations of a nominal density, preserving tractability without combinatorial explosion. Crucially, we develop an amortized training strategy that learns the conditional dependence of the DoI on nuisance parameters in a single optimization process, bypassing the need for repetitive training during the likelihood scan. This allows for the simultaneous extraction of the underlying distribution and the robust profiling of nuisances. The method is validated on a synthetic dataset emulating a high-energy physics measurement with multiple systematic sources, demonstrating its potential for unbinned, functional measurements in complex analyses.
title Profiling systematic uncertainties in Simulation-Based Inference with Factorizable Normalizing Flows
topic High Energy Physics - Phenomenology
Data Analysis, Statistics and Probability
Machine Learning
url https://arxiv.org/abs/2602.13184