An implementation of neural simulation-based inference for parameter estimation in ATLAS

The ATLAS collaboration

doi:10.1088/1361-6633/add370

An implementation of neural simulation-based inference for parameter estimation in ATLAS

The ATLAS collaboration

Aix-Marseille Université
University of Bergen
University of Oklahoma
New York University Abu Dhabi
University of Göttingen
TU Dortmund University
United States Department of Energy
Southern Methodist University
Mohammed V University in Rabat
Tel Aviv University
New York University
National Institute for Nuclear Physics
Abdus Salam International Centre for Theoretical Physics
Heidelberg University
Université Savoie Mont Blanc
AGH University of Science and Technology
SLAC National Accelerator Laboratory
University of Manchester
Northern Illinois University
Istanbul University
Rutherford Appleton Laboratory
University of California at Santa Cruz
The University of Chicago
Institute for High Energy Physics
Johannes Gutenberg University Mainz
Alexandru Ioan Cuza University of Iaşi
CERN
Royal Holloway University of London
Zhengzhou University
University of Rome Tor Vergata
University of Valencia
University of Hassan II Casablanca
Lund University
Stony Brook University
Waseda University
University of Bonn
Bogazici University
University of Victoria BC
Université Grenoble Alpes
University of Edinburgh
Oklahoma State University
Horia Hulubei National Institute of Physics and Nuclear Engineering
National Technical University of Athens
University of Geneva
University of Warwick
Czech Technical University in Prague
Lancaster University
The California State University
University of Liverpool
University of Johannesburg
Université Paris-Saclay
University of Sussex
University of Birmingham
University of Naples Federico II
Universidad Nacional de La Plata
University of Washington
Universidade Federal do Rio de Janeiro
McGill University
Ludwig Maximilian University of Munich
University of Michigan, Ann Arbor
University of Freiburg
University of Toronto
Laboratório de Instrumentação e Física Experimental de Partículas
Aristotle University of Thessaloniki
High Energy Accelerator Research Organization, Tsukuba
University of Oslo
University of Sheffield
University of Texas at Austin
University of Glasgow
University of Milan
National and Kapodistrian University of Athens
Columbia University
The University of Tokyo
German Electron Synchrotron
Brandeis University
Cracow
Duke University
University of Montreal
University of Rome La Sapienza
Nagoya University
Ochanomizu University
Comenius University
University of California at Irvine
University of Cape Town
Mohammed VI Polytechnic University
University of Pennsylvania School of Arts and Sciences
Université Clermont Auvergne
Slovak Academy of Sciences
Carleton University
Technische Universität Dresden
Humboldt University of Berlin
University of Oregon
Queen Mary University of London
Yale University
University of Belgrade
University of Texas at Arlington
University of Bologna
University of Cambridge
United Arab Emirates University
University of Pittsburgh
University of Melbourne
University of Genoa
University of Amsterdam
Max Planck Institute for Physics (Werner Heisenberg Institute)
Palacký University Olomouc
University of Science and Technology of China
University of Oxford
University College London
Universidad Autónoma de Madrid
CAS - Institute of High Energy Physics
TRIUMF
University of British Columbia
University of Innsbruck
Universidad de Buenos Aires
Sorbonne Université
Tufts University
University of Bern
Istinye University
Universidade do Estado do Rio de Janeiro
Harvard University
Uppsala University
Lawrence Berkeley National Laboratory
CNRS
Charles University
University of Würzburg
University of Wuppertal
Gaziantep University
Weizmann Institute of Science
University of Calabria
University of Siegen
Ohio State University
University of Massachusetts
INFN-TIFPA
University of Trento
Michigan State University
Indiana University Bloomington
York University Toronto
Stockholm University
Oskar Klein Centre
University of Illinois
Simon Fraser University
Boston University
Justus Liebig University Giessen
University of Chinese Academy of Sciences
Nanjing University
Ankara University
University of Copenhagen
Radboud University Nijmegen
Universidad Técnica Federico Santa Maria
University of Minho
Universidad Nacional de Colombia
Universidade Federal de Juiz de Fora
University of Pisa
Tbilisi State University
Argonne National Laboratory
Shanghai Jiao Tong University
Kyoto University
Tsinghua University
University of Wisconsin
Chinese University of Hong Kong
University of Arizona
National Tsing Hua University
Czech Academy of Sciences
University of Ljubljana
University of Udine
University of Lisbon
Academia Sinica - Institute of Physics
University of Salento
Roma Tre University
Pontificia Universidad Católica de Chile
Millennium Institute for Subatomic physics at high energy frontier (SAPHIR)
KTH Royal Institute of Technology
University of Bucharest
Universidade Federal da Bahia
Ibn Tofail University
The University of Hong Kong
Louisiana Tech University
Shandong University
IMB-CNM. CSIC
University of Adelaide
University of Coimbra
National Institute of Physics, College of Science, University of the Philippines, Diliman
University of Sharjah
University of New Mexico
Demokritos National Centre for Scientific Research
Jagiellonian University in Kraków
University of Alberta
The University of Georgia, Tbilisi
West University of Timisoara
Sun Yat-Sen University
A. Alikhanian Yerevan Institute of Physics
Shinshu University
Osaka University
University of Tsukuba
University Politehnica of Bucharest
Azerbaijan National Academy of Sciences
Universidade de São Paulo
Universidad de La Serena
University of Pavia
Yeditepe University
Georgian National Academy of Sciences
Ilia State University
Tokyo Institute of Technology
Universidad de Tarapacá
Technion-Israel Institute of Technology
University of the Witwatersrand
Iowa State University
Universidad Andrés Bello
Kobe University
Hong Kong University of Science and Technology
University of Liege
University of Iowa
Kyushu University
Mohamed I University
Universidad Antonio Nariño
University of Sydney
Transilvania University of Brasov
National Institute for Research and Development of Isotopic and Molecular Technologies
University of West Attica
TOBB University of Economics and Technology
Tokyo Metropolitan University
University of California at Berkeley

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

Neural simulation-based inference (NSBI) is a powerful class of machine-learning-based methods for statistical inference that naturally handles high-dimensional parameter estimation without the need to bin data into low-dimensional summary histograms. Such methods are promising for a range of measurements, including at the Large Hadron Collider, where no single observable may be optimal to scan over the entire theoretical phase space under consideration, or where binning data into histograms could result in a loss of sensitivity. This work develops a NSBI framework for statistical inference, using neural networks to estimate probability density ratios, which enables the application to a full-scale analysis. It incorporates a large number of systematic uncertainties, quantifies the uncertainty due to the finite number of events in training samples, develops a method to construct confidence intervals, and demonstrates a series of intermediate diagnostic checks that can be performed to validate the robustness of the method. As an example, the power and feasibility of the method are assessed on simulated data for a simplified version of an off-shell Higgs boson couplings measurement in the four-lepton final states. This approach represents an extension to the standard statistical methodology used by the experiments at the Large Hadron Collider, and can benefit many physics analyses.

Original language	English
Article number	067801
Journal	Reports on Progress in Physics
Volume	88
Issue number	6
DOIs	https://doi.org/10.1088/1361-6633/add370
Publication status	Published - 1 Jun 2025

Keywords

frequentist statistics
likelihood-free inference
machine learning
neural simulation-based inference
parameter inference

ASJC Scopus subject areas

General Physics and Astronomy

Access to Document

10.1088/1361-6633/add370

Cite this

@article{9dd73cc9247d469895516547faf86234,

title = "An implementation of neural simulation-based inference for parameter estimation in ATLAS",

abstract = "Neural simulation-based inference (NSBI) is a powerful class of machine-learning-based methods for statistical inference that naturally handles high-dimensional parameter estimation without the need to bin data into low-dimensional summary histograms. Such methods are promising for a range of measurements, including at the Large Hadron Collider, where no single observable may be optimal to scan over the entire theoretical phase space under consideration, or where binning data into histograms could result in a loss of sensitivity. This work develops a NSBI framework for statistical inference, using neural networks to estimate probability density ratios, which enables the application to a full-scale analysis. It incorporates a large number of systematic uncertainties, quantifies the uncertainty due to the finite number of events in training samples, develops a method to construct confidence intervals, and demonstrates a series of intermediate diagnostic checks that can be performed to validate the robustness of the method. As an example, the power and feasibility of the method are assessed on simulated data for a simplified version of an off-shell Higgs boson couplings measurement in the four-lepton final states. This approach represents an extension to the standard statistical methodology used by the experiments at the Large Hadron Collider, and can benefit many physics analyses.",

keywords = "frequentist statistics, likelihood-free inference, machine learning, neural simulation-based inference, parameter inference",

author = "\{The ATLAS collaboration\} and G. Aad and E. Aakvaag and B. Abbott and S. Abdelhameed and K. Abeling and Abicht, \{N. J.\} and Abidi, \{S. H.\} and M. Aboelela and A. Aboulhorma and H. Abramowicz and Y. Abulaiti and Acharya, \{B. S.\} and A. Ackermann and \{Adam Bourdarios\}, C. and L. Adamczyk and Addepalli, \{S. V.\} and Addison, \{M. J.\} and J. Adelman and A. Adiguzel and T. Adye and Affolder, \{A. A.\} and Y. Afik and Agaras, \{M. N.\} and A. Aggarwal and C. Agheorghiesei and F. Ahmadov and S. Ahuja and X. Ai and G. Aielli and A. Aikot and \{Ait Tamlihat\}, M. and B. Aitbenchikh and M. Akbiyik and {\AA}kesson, \{T. P.A.\} and Akimov, \{A. V.\} and D. Akiyama and Akolkar, \{N. N.\} and S. Aktas and Alberghi, \{G. L.\} and J. Albert and P. Albicocco and Albouy, \{G. L.\} and S. Alderweireldt and Alegria, \{Z. L.\} and M. Aleksa and Aleksandrov, \{I. N.\} and Connell, \{S. H.\} and Gololo, \{M. G.D.\} and N. Govender and L. Truong",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Published by IOP Publishing Ltd.",

year = "2025",

month = jun,

day = "1",

doi = "10.1088/1361-6633/add370",

language = "English",

volume = "88",

journal = "Reports on Progress in Physics",

issn = "0034-4885",

publisher = "IOP Publishing Ltd.",

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T1 - An implementation of neural simulation-based inference for parameter estimation in ATLAS

AU - The ATLAS collaboration

AU - Aad, G.

AU - Aakvaag, E.

AU - Abbott, B.

AU - Abdelhameed, S.

AU - Abeling, K.

AU - Abicht, N. J.

AU - Abidi, S. H.

AU - Aboelela, M.

AU - Aboulhorma, A.

AU - Abramowicz, H.

AU - Abulaiti, Y.

AU - Acharya, B. S.

AU - Ackermann, A.

AU - Adam Bourdarios, C.

AU - Adamczyk, L.

AU - Addepalli, S. V.

AU - Addison, M. J.

AU - Adelman, J.

AU - Adiguzel, A.

AU - Adye, T.

AU - Affolder, A. A.

AU - Afik, Y.

AU - Agaras, M. N.

AU - Aggarwal, A.

AU - Agheorghiesei, C.

AU - Ahmadov, F.

AU - Ahuja, S.

AU - Ai, X.

AU - Aielli, G.

AU - Aikot, A.

AU - Ait Tamlihat, M.

AU - Aitbenchikh, B.

AU - Akbiyik, M.

AU - Åkesson, T. P.A.

AU - Akimov, A. V.

AU - Akiyama, D.

AU - Akolkar, N. N.

AU - Aktas, S.

AU - Alberghi, G. L.

AU - Albert, J.

AU - Albicocco, P.

AU - Albouy, G. L.

AU - Alderweireldt, S.

AU - Alegria, Z. L.

AU - Aleksa, M.

AU - Aleksandrov, I. N.

AU - Connell, S. H.

AU - Gololo, M. G.D.

AU - Govender, N.

AU - Truong, L.

PY - 2025/6/1

Y1 - 2025/6/1

N2 - Neural simulation-based inference (NSBI) is a powerful class of machine-learning-based methods for statistical inference that naturally handles high-dimensional parameter estimation without the need to bin data into low-dimensional summary histograms. Such methods are promising for a range of measurements, including at the Large Hadron Collider, where no single observable may be optimal to scan over the entire theoretical phase space under consideration, or where binning data into histograms could result in a loss of sensitivity. This work develops a NSBI framework for statistical inference, using neural networks to estimate probability density ratios, which enables the application to a full-scale analysis. It incorporates a large number of systematic uncertainties, quantifies the uncertainty due to the finite number of events in training samples, develops a method to construct confidence intervals, and demonstrates a series of intermediate diagnostic checks that can be performed to validate the robustness of the method. As an example, the power and feasibility of the method are assessed on simulated data for a simplified version of an off-shell Higgs boson couplings measurement in the four-lepton final states. This approach represents an extension to the standard statistical methodology used by the experiments at the Large Hadron Collider, and can benefit many physics analyses.

AB - Neural simulation-based inference (NSBI) is a powerful class of machine-learning-based methods for statistical inference that naturally handles high-dimensional parameter estimation without the need to bin data into low-dimensional summary histograms. Such methods are promising for a range of measurements, including at the Large Hadron Collider, where no single observable may be optimal to scan over the entire theoretical phase space under consideration, or where binning data into histograms could result in a loss of sensitivity. This work develops a NSBI framework for statistical inference, using neural networks to estimate probability density ratios, which enables the application to a full-scale analysis. It incorporates a large number of systematic uncertainties, quantifies the uncertainty due to the finite number of events in training samples, develops a method to construct confidence intervals, and demonstrates a series of intermediate diagnostic checks that can be performed to validate the robustness of the method. As an example, the power and feasibility of the method are assessed on simulated data for a simplified version of an off-shell Higgs boson couplings measurement in the four-lepton final states. This approach represents an extension to the standard statistical methodology used by the experiments at the Large Hadron Collider, and can benefit many physics analyses.

KW - frequentist statistics

KW - likelihood-free inference

KW - machine learning

KW - neural simulation-based inference

KW - parameter inference

UR - https://www.scopus.com/pages/publications/105007089483

U2 - 10.1088/1361-6633/add370

DO - 10.1088/1361-6633/add370

M3 - Article

AN - SCOPUS:105007089483

SN - 0034-4885

VL - 88

JO - Reports on Progress in Physics

JF - Reports on Progress in Physics

IS - 6

M1 - 067801

ER -

An implementation of neural simulation-based inference for parameter estimation in ATLAS

Abstract

Keywords

ASJC Scopus subject areas

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