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Autoencoders for Real-Time SUEP Detection

Confining dark sectors with pseudo-conformal dynamics can produce Soft Unclustered Energy Patterns, or SUEPs, at the Large Hadron Collider: the production of dark quarks in proton-proton collisions leading to a dark shower and the high-multiplicity production of dark hadrons. The final experimental...

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Autores principales: Chhibra, Simranjit Singh, Chernyavskaya, Nadezda, Maier, Benedikt, Pierini, Maurzio, Hasan, Syed
Lenguaje:eng
Publicado: 2023
Materias:
Acceso en línea:http://cds.cern.ch/record/2866763
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author Chhibra, Simranjit Singh
Chernyavskaya, Nadezda
Maier, Benedikt
Pierini, Maurzio
Hasan, Syed
author_facet Chhibra, Simranjit Singh
Chernyavskaya, Nadezda
Maier, Benedikt
Pierini, Maurzio
Hasan, Syed
author_sort Chhibra, Simranjit Singh
collection CERN
description Confining dark sectors with pseudo-conformal dynamics can produce Soft Unclustered Energy Patterns, or SUEPs, at the Large Hadron Collider: the production of dark quarks in proton-proton collisions leading to a dark shower and the high-multiplicity production of dark hadrons. The final experimental signature is spherically-symmetric energy deposits by an anomalously large number of soft Standard Model particles with a transverse energy of a few hundred MeV. The dominant background for the SUEP search, if it gets produced via gluon-gluon fusion, is multi-jet QCD events. We have developed a deep learning-based Anomaly Detection technique to reject QCD jets and identify any anomalous signature, including SUEP, in real-time in the High-Level Trigger system of the Compact Muon Solenoid experiment at the Large Hadron Collider. A deep convolutional neural autoencoder network has been trained using QCD events by taking transverse energy deposits in the inner tracker, electromagnetic calorimeter, and hadron calorimeter sub-detectors as 3-channel image data. To tackle the biggest challenge of the task, due to the sparse nature of the data: only ~0.5% of the total ~300 k image pixels have non-zero values, a non-standard loss function, the inverse of the so-called Dice Loss, has been exploited. The trained autoencoder with learned spatial features of QCD jets can detect 40% of the SUEP events, with a QCD event mistagging rate as low as 2%. The model inference time has been measured using the Intel CoreTM i5-9600KF processor and found to be ~20 ms, which perfectly satisfies the High-Level Trigger system's latency of O(100) ms. Given the virtue of the unsupervised learning of the autoencoders, the trained model can be applied to any new physics model that predicts an experimental signature anomalous to QCD jets.
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institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2023
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spelling cern-28667632023-10-03T15:53:09Zhttp://cds.cern.ch/record/2866763engChhibra, Simranjit SinghChernyavskaya, NadezdaMaier, BenediktPierini, MaurzioHasan, SyedAutoencoders for Real-Time SUEP Detectioncs.LGComputing and Computershep-exParticle Physics - ExperimentConfining dark sectors with pseudo-conformal dynamics can produce Soft Unclustered Energy Patterns, or SUEPs, at the Large Hadron Collider: the production of dark quarks in proton-proton collisions leading to a dark shower and the high-multiplicity production of dark hadrons. The final experimental signature is spherically-symmetric energy deposits by an anomalously large number of soft Standard Model particles with a transverse energy of a few hundred MeV. The dominant background for the SUEP search, if it gets produced via gluon-gluon fusion, is multi-jet QCD events. We have developed a deep learning-based Anomaly Detection technique to reject QCD jets and identify any anomalous signature, including SUEP, in real-time in the High-Level Trigger system of the Compact Muon Solenoid experiment at the Large Hadron Collider. A deep convolutional neural autoencoder network has been trained using QCD events by taking transverse energy deposits in the inner tracker, electromagnetic calorimeter, and hadron calorimeter sub-detectors as 3-channel image data. To tackle the biggest challenge of the task, due to the sparse nature of the data: only ~0.5% of the total ~300 k image pixels have non-zero values, a non-standard loss function, the inverse of the so-called Dice Loss, has been exploited. The trained autoencoder with learned spatial features of QCD jets can detect 40% of the SUEP events, with a QCD event mistagging rate as low as 2%. The model inference time has been measured using the Intel CoreTM i5-9600KF processor and found to be ~20 ms, which perfectly satisfies the High-Level Trigger system's latency of O(100) ms. Given the virtue of the unsupervised learning of the autoencoders, the trained model can be applied to any new physics model that predicts an experimental signature anomalous to QCD jets.arXiv:2306.13595oai:cds.cern.ch:28667632023-06-23
spellingShingle cs.LG
Computing and Computers
hep-ex
Particle Physics - Experiment
Chhibra, Simranjit Singh
Chernyavskaya, Nadezda
Maier, Benedikt
Pierini, Maurzio
Hasan, Syed
Autoencoders for Real-Time SUEP Detection
title Autoencoders for Real-Time SUEP Detection
title_full Autoencoders for Real-Time SUEP Detection
title_fullStr Autoencoders for Real-Time SUEP Detection
title_full_unstemmed Autoencoders for Real-Time SUEP Detection
title_short Autoencoders for Real-Time SUEP Detection
title_sort autoencoders for real-time suep detection
topic cs.LG
Computing and Computers
hep-ex
Particle Physics - Experiment
url http://cds.cern.ch/record/2866763
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AT chernyavskayanadezda autoencodersforrealtimesuepdetection
AT maierbenedikt autoencodersforrealtimesuepdetection
AT pierinimaurzio autoencodersforrealtimesuepdetection
AT hasansyed autoencodersforrealtimesuepdetection