Simple and statistically sound recommendations for analysing physical theories

Shehu S. Abdussalam; Fruzsina J. Agocs; Benjamin C. Allanach; Peter Athron; Csaba Balázs; Emanuele Bagnaschi; Philip Bechtle; Oliver Buchmueller; Ankit Beniwal; Jihyun Bhom; Sanjay Bloor; Torsten Bringmann; Andy Buckley; Anja Butter; José Eliel Camargo-Molina; Marcin Chrzaszcz; Jan Conrad; Jonathan M. Cornell; Matthias Danninger; Jorge De Blas; Albert De Roeck; Klaus Desch; Matthew Dolan; Herbert Dreiner; Otto Eberhardt; John Ellis; Ben Farmer; Marco Fedele; Henning Flächer; Andrew Fowlie; Tomás E. Gonzalo; Philip Grace; Matthias Hamer; Will Handley; Julia Harz; Sven Heinemeyer; Sebastian Hoof; Selim Hotinli; Paul Jackson; Felix Kahlhoefer; Kamila Kowalska; Michael Krämer; Anders Kvellestad; Miriam Lucio Martinez; Farvah Mahmoudi; Diego Martinez Santos; Gregory D. Martinez; Satoshi Mishima; Keith Olive; Ayan Paul; Markus Tobias Prim; Werner Porod; Are Raklev; Janina J. Renk; Christopher Rogan; Leszek Roszkowski; Roberto Ruiz De Austri; Kazuki Sakurai; Andre Scaffidi; Pat Scott; Enrico Maria Sessolo; Tim Stefaniak; Patrick Stöcker; Wei Su; Sebastian Trojanowski; Roberto Trotta; Yue Lin Sming Tsai; Jeriek Van Den Abeele; Mauro Valli; Aaron C. Vincent; Georg Weiglein; Martin White; Peter Wienemann; Lei Wu; Yang Zhang

doi:10.1088/1361-6633/ac60ac

Simple and statistically sound recommendations for analysing physical theories

Shehu S. Abdussalam, Fruzsina J. Agocs, Benjamin C. Allanach, Peter Athron, Csaba Balázs, Emanuele Bagnaschi, Philip Bechtle, Oliver Buchmueller, Ankit Beniwal, Jihyun Bhom, Sanjay Bloor, Torsten Bringmann, Andy Buckley, Anja Butter, José Eliel Camargo-Molina, Marcin Chrzaszcz, Jan Conrad, Jonathan M. Cornell, Matthias Danninger, Jorge De BlasAlbert De Roeck, Klaus Desch, Matthew Dolan, Herbert Dreiner, Otto Eberhardt, John Ellis, Ben Farmer, Marco Fedele, Henning Flächer, Andrew Fowlie, Tomás E. Gonzalo, Philip Grace, Matthias Hamer, Will Handley, Julia Harz, Sven Heinemeyer, Sebastian Hoof, Selim Hotinli, Paul Jackson, Felix Kahlhoefer, Kamila Kowalska, Michael Krämer, Anders Kvellestad, Miriam Lucio Martinez, Farvah Mahmoudi, Diego Martinez Santos, Gregory D. Martinez, Satoshi Mishima, Keith Olive, Ayan Paul, Markus Tobias Prim, Werner Porod, Are Raklev, Janina J. Renk, Christopher Rogan, Leszek Roszkowski, Roberto Ruiz De Austri, Kazuki Sakurai, Andre Scaffidi, Pat Scott, Enrico Maria Sessolo, Tim Stefaniak, Patrick Stöcker, Wei Su, Sebastian Trojanowski, Roberto Trotta, Yue Lin Sming Tsai, Jeriek Van Den Abeele, Mauro Valli, Aaron C. Vincent, Georg Weiglein, Martin White, Peter Wienemann, Lei Wu, Yang Zhang

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

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Abstract

Physical theories that depend on many parameters or are tested against data from many different experiments pose unique challenges to statistical inference. Many models in particle physics, astrophysics and cosmology fall into one or both of these categories. These issues are often sidestepped with statistically unsound ad hoc methods, involving intersection of parameter intervals estimated by multiple experiments, and random or grid sampling of model parameters. Whilst these methods are easy to apply, they exhibit pathologies even in low-dimensional parameter spaces, and quickly become problematic to use and interpret in higher dimensions. In this article we give clear guidance for going beyond these procedures, suggesting where possible simple methods for performing statistically sound inference, and recommendations of readily-available software tools and standards that can assist in doing so. Our aim is to provide any physicists lacking comprehensive statistical training with recommendations for reaching correct scientific conclusions, with only a modest increase in analysis burden. Our examples can be reproduced with the code publicly available at Zenodo.

Original language	English (US)
Article number	052201
Journal	Reports on Progress in Physics
Volume	85
Issue number	5
DOIs	https://doi.org/10.1088/1361-6633/ac60ac
State	Published - May 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2022 IOP Publishing Ltd.

Keywords

methodology
particle physics
statistics

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10.1088/1361-6633/ac60ac

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Abdussalam, S. S., Agocs, F. J., Allanach, B. C., Athron, P., Balázs, C., Bagnaschi, E., Bechtle, P., Buchmueller, O., Beniwal, A., Bhom, J., Bloor, S., Bringmann, T., Buckley, A., Butter, A., Camargo-Molina, J. E., Chrzaszcz, M., Conrad, J., Cornell, J. M., Danninger, M., ... Zhang, Y. (2022). Simple and statistically sound recommendations for analysing physical theories. Reports on Progress in Physics, 85(5), Article 052201. https://doi.org/10.1088/1361-6633/ac60ac

Abdussalam, SS, Agocs, FJ, Allanach, BC, Athron, P, Balázs, C, Bagnaschi, E, Bechtle, P, Buchmueller, O, Beniwal, A, Bhom, J, Bloor, S, Bringmann, T, Buckley, A, Butter, A, Camargo-Molina, JE, Chrzaszcz, M, Conrad, J, Cornell, JM, Danninger, M, De Blas, J, De Roeck, A, Desch, K, Dolan, M, Dreiner, H, Eberhardt, O, Ellis, J, Farmer, B, Fedele, M, Flächer, H, Fowlie, A, Gonzalo, TE, Grace, P, Hamer, M, Handley, W, Harz, J, Heinemeyer, S, Hoof, S, Hotinli, S, Jackson, P, Kahlhoefer, F, Kowalska, K, Krämer, M, Kvellestad, A, Martinez, ML, Mahmoudi, F, Santos, DM, Martinez, GD, Mishima, S, Olive, K, Paul, A, Prim, MT, Porod, W, Raklev, A, Renk, JJ, Rogan, C, Roszkowski, L, Ruiz De Austri, R, Sakurai, K, Scaffidi, A, Scott, P, Sessolo, EM, Stefaniak, T, Stöcker, P, Su, W, Trojanowski, S, Trotta, R, Sming Tsai, YL, Van Den Abeele, J, Valli, M, Vincent, AC, Weiglein, G, White, M, Wienemann, P, Wu, L & Zhang, Y 2022, 'Simple and statistically sound recommendations for analysing physical theories', Reports on Progress in Physics, vol. 85, no. 5, 052201. https://doi.org/10.1088/1361-6633/ac60ac

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AU - Abdussalam, Shehu S.

AU - Agocs, Fruzsina J.

AU - Allanach, Benjamin C.

AU - Athron, Peter

AU - Balázs, Csaba

AU - Bagnaschi, Emanuele

AU - Bechtle, Philip

AU - Buchmueller, Oliver

AU - Beniwal, Ankit

AU - Bhom, Jihyun

AU - Bloor, Sanjay

AU - Bringmann, Torsten

AU - Buckley, Andy

AU - Butter, Anja

AU - Camargo-Molina, José Eliel

AU - Chrzaszcz, Marcin

AU - Conrad, Jan

AU - Cornell, Jonathan M.

AU - Danninger, Matthias

AU - De Blas, Jorge

AU - De Roeck, Albert

AU - Desch, Klaus

AU - Dolan, Matthew

AU - Dreiner, Herbert

AU - Eberhardt, Otto

AU - Ellis, John

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AU - Fedele, Marco

AU - Flächer, Henning

AU - Fowlie, Andrew

AU - Gonzalo, Tomás E.

AU - Grace, Philip

AU - Hamer, Matthias

AU - Handley, Will

AU - Harz, Julia

AU - Heinemeyer, Sven

AU - Hoof, Sebastian

AU - Hotinli, Selim

AU - Jackson, Paul

AU - Kahlhoefer, Felix

AU - Kowalska, Kamila

AU - Krämer, Michael

AU - Kvellestad, Anders

AU - Martinez, Miriam Lucio

AU - Mahmoudi, Farvah

AU - Santos, Diego Martinez

AU - Martinez, Gregory D.

AU - Mishima, Satoshi

AU - Olive, Keith

AU - Paul, Ayan

AU - Prim, Markus Tobias

AU - Porod, Werner

AU - Raklev, Are

AU - Renk, Janina J.

AU - Rogan, Christopher

AU - Roszkowski, Leszek

AU - Ruiz De Austri, Roberto

AU - Sakurai, Kazuki

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AU - Scott, Pat

AU - Sessolo, Enrico Maria

AU - Stefaniak, Tim

AU - Stöcker, Patrick

AU - Su, Wei

AU - Trojanowski, Sebastian

AU - Trotta, Roberto

AU - Sming Tsai, Yue Lin

AU - Van Den Abeele, Jeriek

AU - Valli, Mauro

AU - Vincent, Aaron C.

AU - Weiglein, Georg

AU - White, Martin

AU - Wienemann, Peter

AU - Wu, Lei

AU - Zhang, Yang

PY - 2022/5

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N2 - Physical theories that depend on many parameters or are tested against data from many different experiments pose unique challenges to statistical inference. Many models in particle physics, astrophysics and cosmology fall into one or both of these categories. These issues are often sidestepped with statistically unsound ad hoc methods, involving intersection of parameter intervals estimated by multiple experiments, and random or grid sampling of model parameters. Whilst these methods are easy to apply, they exhibit pathologies even in low-dimensional parameter spaces, and quickly become problematic to use and interpret in higher dimensions. In this article we give clear guidance for going beyond these procedures, suggesting where possible simple methods for performing statistically sound inference, and recommendations of readily-available software tools and standards that can assist in doing so. Our aim is to provide any physicists lacking comprehensive statistical training with recommendations for reaching correct scientific conclusions, with only a modest increase in analysis burden. Our examples can be reproduced with the code publicly available at Zenodo.

AB - Physical theories that depend on many parameters or are tested against data from many different experiments pose unique challenges to statistical inference. Many models in particle physics, astrophysics and cosmology fall into one or both of these categories. These issues are often sidestepped with statistically unsound ad hoc methods, involving intersection of parameter intervals estimated by multiple experiments, and random or grid sampling of model parameters. Whilst these methods are easy to apply, they exhibit pathologies even in low-dimensional parameter spaces, and quickly become problematic to use and interpret in higher dimensions. In this article we give clear guidance for going beyond these procedures, suggesting where possible simple methods for performing statistically sound inference, and recommendations of readily-available software tools and standards that can assist in doing so. Our aim is to provide any physicists lacking comprehensive statistical training with recommendations for reaching correct scientific conclusions, with only a modest increase in analysis burden. Our examples can be reproduced with the code publicly available at Zenodo.

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KW - particle physics

KW - statistics

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JO - Reports on Progress in Physics

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ER -

Simple and statistically sound recommendations for analysing physical theories

Abstract

Bibliographical note

Keywords

Access

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