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Main Authors: Calvi, Marta, Fulghesu, Tommaso, Hallett, George, Hartman, Luca, Khanji, Basem, Kirsebom, Veronica S., Latham, Thomas, Lehuraux, Marion, Li, Ching-Hua, Mathad, Abhijit, Monk, Matthew, Morris, Andy, Rudolph, Matthew Scott, Swystun, Francesca, Bruch, Dorothea vom
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.11487
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author Calvi, Marta
Fulghesu, Tommaso
Hallett, George
Hartman, Luca
Khanji, Basem
Kirsebom, Veronica S.
Latham, Thomas
Lehuraux, Marion
Li, Ching-Hua
Mathad, Abhijit
Monk, Matthew
Morris, Andy
Rudolph, Matthew Scott
Swystun, Francesca
Bruch, Dorothea vom
author_facet Calvi, Marta
Fulghesu, Tommaso
Hallett, George
Hartman, Luca
Khanji, Basem
Kirsebom, Veronica S.
Latham, Thomas
Lehuraux, Marion
Li, Ching-Hua
Mathad, Abhijit
Monk, Matthew
Morris, Andy
Rudolph, Matthew Scott
Swystun, Francesca
Bruch, Dorothea vom
contents The Run 3 of the LHC brings unprecedented luminosity and a surge in data volume to the LHCb detector, necessitating a critical reduction in the size of each reconstructed event without compromising the physics reach of the heavy-flavour programme. While signal decays typically involve just a few charged particles, a single proton-proton collision produces hundreds of tracks, with charged particle information dominating the event size. To address this imbalance, a suite of inclusive isolation tools have been developed, including both classical methods and a novel Inclusive Multivariate Isolation (IMI) algorithm. The IMI unifies the key strengths of classical isolation techniques and is designed to robustly handle diverse decay topologies and kinematics, enabling efficient reconstruction of decay chains with varying final-state multiplicities. It consistently outperforms traditional methods, with superior background rejection and high signal efficiency across diverse channels and event multiplicities. By retaining only the most relevant particles in each event, the method achieves a 45 % reduction in data size while preserving full physics performance, selecting signal particles with 99% efficiency. We also validate IMI on Run 3 data, confirming its robustness under real data-taking conditions. In the long term, IMI could provide a fast, lightweight front-end to support more compute-intensive selection strategies in the high-multiplicity environment of the High-Luminosity LHC.
format Preprint
id arxiv_https___arxiv_org_abs_2511_11487
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Minimising Event Size, Maximising Physics: Inclusive Particle Isolation for LHCb's Run 3
Calvi, Marta
Fulghesu, Tommaso
Hallett, George
Hartman, Luca
Khanji, Basem
Kirsebom, Veronica S.
Latham, Thomas
Lehuraux, Marion
Li, Ching-Hua
Mathad, Abhijit
Monk, Matthew
Morris, Andy
Rudolph, Matthew Scott
Swystun, Francesca
Bruch, Dorothea vom
High Energy Physics - Experiment
The Run 3 of the LHC brings unprecedented luminosity and a surge in data volume to the LHCb detector, necessitating a critical reduction in the size of each reconstructed event without compromising the physics reach of the heavy-flavour programme. While signal decays typically involve just a few charged particles, a single proton-proton collision produces hundreds of tracks, with charged particle information dominating the event size. To address this imbalance, a suite of inclusive isolation tools have been developed, including both classical methods and a novel Inclusive Multivariate Isolation (IMI) algorithm. The IMI unifies the key strengths of classical isolation techniques and is designed to robustly handle diverse decay topologies and kinematics, enabling efficient reconstruction of decay chains with varying final-state multiplicities. It consistently outperforms traditional methods, with superior background rejection and high signal efficiency across diverse channels and event multiplicities. By retaining only the most relevant particles in each event, the method achieves a 45 % reduction in data size while preserving full physics performance, selecting signal particles with 99% efficiency. We also validate IMI on Run 3 data, confirming its robustness under real data-taking conditions. In the long term, IMI could provide a fast, lightweight front-end to support more compute-intensive selection strategies in the high-multiplicity environment of the High-Luminosity LHC.
title Minimising Event Size, Maximising Physics: Inclusive Particle Isolation for LHCb's Run 3
topic High Energy Physics - Experiment
url https://arxiv.org/abs/2511.11487