Progress in end-to-end optimization of fundamental physics experimental apparata with differentiable programming

Max Aehle; Lorenzo Arsini; R. Belén Barreiro; Anastasios Belias; Alexey Boldyrev; Florian Bury; Susana Cebrian; Alexander Demin; Jennet Dickinson; Julien Donini; Tommaso Dorigo; Michele Doro; Nicolas R. Gauger; Andrea Giammanco; Lindsey Gray; Borja S. González; Verena Kain; Jan Kieseler; Lisa Kusch; Marcus Liwicki; Gernot Maier; Federico Nardi; Fedor Ratnikov; Ryan Roussel; Roberto Ruiz de Austri; Fredrik Sandin; Michael Schenk; Bruno Scarpa; Pedro Silva; Giles C. Strong; Pietro Vischia

doi:10.1016/j.revip.2025.100120

Progress in end-to-end optimization of fundamental physics experimental apparata with differentiable programming

Max Aehle
, Lorenzo Arsini
, R. Belén Barreiro
, Anastasios Belias
, Alexey Boldyrev
, Florian Bury
, Susana Cebrian
, Alexander Demin
, Jennet Dickinson
, Julien Donini
, Tommaso Dorigo
, Michele Doro
, Nicolas R. Gauger
, Andrea Giammanco
, Lindsey Gray
, Borja S. González
, Verena Kain
, Jan Kieseler
, Lisa Kusch
, Marcus Liwicki

Gernot Maier, Federico Nardi, Fedor Ratnikov, Ryan Roussel, Roberto Ruiz de Austri, Fredrik Sandin, Michael Schenk, Bruno Scarpa, Pedro Silva, Giles C. Strong, Pietro Vischia

Computational Illumination Optics

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In this article we examine recent developments in the research area concerning the creation of end-to-end models for the complete optimization of measuring instruments. The models we consider rely on differentiable programming methods and on the specification of a software pipeline including all factors impacting performance — from the data-generating processes to their reconstruction and the inference on the parameters of interest — along with the careful specification of a utility function well aligned with the end goals of the experiment. Building on previous studies originated within the MODE Collaboration, we focus specifically on applications involving instruments for particle physics experimentation, as well as industrial and medical applications that share the detection of radiation as their data-generating mechanism. This report illustrates the most recent advancements in the area, and outlines, for each of the discussed applications as well as for automatic differentiation itself, ongoing and future work.

Originele taal-2	Engels
Artikelnummer	100120
Aantal pagina's	38
Tijdschrift	Reviews in Physics
Volume	13
DOI's	https://doi.org/10.1016/j.revip.2025.100120
Status	Gepubliceerd - dec. 2025

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Publisher Copyright:
© 2025 The Authors

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Aehle, M., Arsini, L., Barreiro, R. B., Belias, A., Boldyrev, A., Bury, F., Cebrian, S., Demin, A., Dickinson, J., Donini, J., Dorigo, T., Doro, M., Gauger, N. R., Giammanco, A., Gray, L., González, B. S., Kain, V., Kieseler, J., Kusch, L., ... Vischia, P. (2025). Progress in end-to-end optimization of fundamental physics experimental apparata with differentiable programming. Reviews in Physics, 13, Artikel 100120. https://doi.org/10.1016/j.revip.2025.100120

@article{a81166e7b77c4c9eb09e8da0aa469502,

title = "Progress in end-to-end optimization of fundamental physics experimental apparata with differentiable programming",

abstract = "In this article we examine recent developments in the research area concerning the creation of end-to-end models for the complete optimization of measuring instruments. The models we consider rely on differentiable programming methods and on the specification of a software pipeline including all factors impacting performance — from the data-generating processes to their reconstruction and the inference on the parameters of interest — along with the careful specification of a utility function well aligned with the end goals of the experiment. Building on previous studies originated within the MODE Collaboration, we focus specifically on applications involving instruments for particle physics experimentation, as well as industrial and medical applications that share the detection of radiation as their data-generating mechanism. This report illustrates the most recent advancements in the area, and outlines, for each of the discussed applications as well as for automatic differentiation itself, ongoing and future work.",

keywords = "Astrophysics, Differentiable programming, Machine learning, Nuclear physics, Optimization, Particle detectors, Particle physics",

author = "Max Aehle and Lorenzo Arsini and Barreiro, \{R. Bel{\'e}n\} and Anastasios Belias and Alexey Boldyrev and Florian Bury and Susana Cebrian and Alexander Demin and Jennet Dickinson and Julien Donini and Tommaso Dorigo and Michele Doro and Gauger, \{Nicolas R.\} and Andrea Giammanco and Lindsey Gray and Gonz{\'a}lez, \{Borja S.\} and Verena Kain and Jan Kieseler and Lisa Kusch and Marcus Liwicki and Gernot Maier and Federico Nardi and Fedor Ratnikov and Ryan Roussel and \{Ruiz de Austri\}, Roberto and Fredrik Sandin and Michael Schenk and Bruno Scarpa and Pedro Silva and Strong, \{Giles C.\} and Pietro Vischia",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors",

year = "2025",

month = dec,

doi = "10.1016/j.revip.2025.100120",

language = "English",

volume = "13",

journal = "Reviews in Physics",

publisher = "Elsevier",

}

Aehle, M, Arsini, L, Barreiro, RB, Belias, A, Boldyrev, A, Bury, F, Cebrian, S, Demin, A, Dickinson, J, Donini, J, Dorigo, T, Doro, M, Gauger, NR, Giammanco, A, Gray, L, González, BS, Kain, V, Kieseler, J, Kusch, L, Liwicki, M, Maier, G, Nardi, F, Ratnikov, F, Roussel, R, Ruiz de Austri, R, Sandin, F, Schenk, M, Scarpa, B, Silva, P, Strong, GC & Vischia, P 2025, 'Progress in end-to-end optimization of fundamental physics experimental apparata with differentiable programming', Reviews in Physics, vol. 13, 100120. https://doi.org/10.1016/j.revip.2025.100120

TY - JOUR

T1 - Progress in end-to-end optimization of fundamental physics experimental apparata with differentiable programming

AU - Aehle, Max

AU - Arsini, Lorenzo

AU - Barreiro, R. Belén

AU - Belias, Anastasios

AU - Boldyrev, Alexey

AU - Bury, Florian

AU - Cebrian, Susana

AU - Demin, Alexander

AU - Dickinson, Jennet

AU - Donini, Julien

AU - Dorigo, Tommaso

AU - Doro, Michele

AU - Gauger, Nicolas R.

AU - Giammanco, Andrea

AU - Gray, Lindsey

AU - González, Borja S.

AU - Kain, Verena

AU - Kieseler, Jan

AU - Kusch, Lisa

AU - Liwicki, Marcus

AU - Maier, Gernot

AU - Nardi, Federico

AU - Ratnikov, Fedor

AU - Roussel, Ryan

AU - Ruiz de Austri, Roberto

AU - Sandin, Fredrik

AU - Schenk, Michael

AU - Scarpa, Bruno

AU - Silva, Pedro

AU - Strong, Giles C.

AU - Vischia, Pietro

PY - 2025/12

Y1 - 2025/12

N2 - In this article we examine recent developments in the research area concerning the creation of end-to-end models for the complete optimization of measuring instruments. The models we consider rely on differentiable programming methods and on the specification of a software pipeline including all factors impacting performance — from the data-generating processes to their reconstruction and the inference on the parameters of interest — along with the careful specification of a utility function well aligned with the end goals of the experiment. Building on previous studies originated within the MODE Collaboration, we focus specifically on applications involving instruments for particle physics experimentation, as well as industrial and medical applications that share the detection of radiation as their data-generating mechanism. This report illustrates the most recent advancements in the area, and outlines, for each of the discussed applications as well as for automatic differentiation itself, ongoing and future work.

AB - In this article we examine recent developments in the research area concerning the creation of end-to-end models for the complete optimization of measuring instruments. The models we consider rely on differentiable programming methods and on the specification of a software pipeline including all factors impacting performance — from the data-generating processes to their reconstruction and the inference on the parameters of interest — along with the careful specification of a utility function well aligned with the end goals of the experiment. Building on previous studies originated within the MODE Collaboration, we focus specifically on applications involving instruments for particle physics experimentation, as well as industrial and medical applications that share the detection of radiation as their data-generating mechanism. This report illustrates the most recent advancements in the area, and outlines, for each of the discussed applications as well as for automatic differentiation itself, ongoing and future work.

KW - Astrophysics

KW - Differentiable programming

KW - Machine learning

KW - Nuclear physics

KW - Optimization

KW - Particle detectors

KW - Particle physics

UR - https://www.scopus.com/pages/publications/105004409699

U2 - 10.1016/j.revip.2025.100120

DO - 10.1016/j.revip.2025.100120

M3 - Review article

AN - SCOPUS:105004409699

VL - 13

JO - Reviews in Physics

JF - Reviews in Physics

M1 - 100120

ER -

Progress in end-to-end optimization of fundamental physics experimental apparata with differentiable programming

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