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Energy Reconstruction Techniques in TileCal under High Pile-up Conditions

Particle colliders are machines built to probe fundamental questions in physics. The properties of the produced particles are measured by complex experiments which use a wide variety of devices, such as the calorimeter system. In the ATLAS experiment at LHC, the Tile Calorimeter (TileCal) comprises...

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Detalles Bibliográficos
Autores principales: Inacio Goncalves, Guilherme, ATLAS Tile Collaboration
Lenguaje:eng
Publicado: 2021
Materias:
Acceso en línea:http://cds.cern.ch/record/2767754
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author Inacio Goncalves, Guilherme
ATLAS Tile Collaboration
author_facet Inacio Goncalves, Guilherme
ATLAS Tile Collaboration
author_sort Inacio Goncalves, Guilherme
collection CERN
description Particle colliders are machines built to probe fundamental questions in physics. The properties of the produced particles are measured by complex experiments which use a wide variety of devices, such as the calorimeter system. In the ATLAS experiment at LHC, the Tile Calorimeter (TileCal) comprises about 10,000 readout channels that amplify, shape, and sample each signal every 25 ns. Since LHC collisions occur every 25 ns, and due to the increase of the luminosity level, signals from adjacent collisions may be read out within the same TileCal readout window, deforming the expected signal, and degrading the energy estimation efficiency. Therefore, this work compares the performance of the currently available methods for TileCal energy estimation using LHC collision data. Different pile-up conditions are considered. The results show that the performance in terms of the uncertainty of the energy estimation can be improved up to 35% in high occupancy readout channels.
id cern-2767754
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2021
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spelling cern-27677542021-05-27T21:50:54Zhttp://cds.cern.ch/record/2767754engInacio Goncalves, GuilhermeATLAS Tile CollaborationEnergy Reconstruction Techniques in TileCal under High Pile-up ConditionsParticle Physics - ExperimentParticle colliders are machines built to probe fundamental questions in physics. The properties of the produced particles are measured by complex experiments which use a wide variety of devices, such as the calorimeter system. In the ATLAS experiment at LHC, the Tile Calorimeter (TileCal) comprises about 10,000 readout channels that amplify, shape, and sample each signal every 25 ns. Since LHC collisions occur every 25 ns, and due to the increase of the luminosity level, signals from adjacent collisions may be read out within the same TileCal readout window, deforming the expected signal, and degrading the energy estimation efficiency. Therefore, this work compares the performance of the currently available methods for TileCal energy estimation using LHC collision data. Different pile-up conditions are considered. The results show that the performance in terms of the uncertainty of the energy estimation can be improved up to 35% in high occupancy readout channels.ATL-TILECAL-PROC-2021-002oai:cds.cern.ch:27677542021-05-27
spellingShingle Particle Physics - Experiment
Inacio Goncalves, Guilherme
ATLAS Tile Collaboration
Energy Reconstruction Techniques in TileCal under High Pile-up Conditions
title Energy Reconstruction Techniques in TileCal under High Pile-up Conditions
title_full Energy Reconstruction Techniques in TileCal under High Pile-up Conditions
title_fullStr Energy Reconstruction Techniques in TileCal under High Pile-up Conditions
title_full_unstemmed Energy Reconstruction Techniques in TileCal under High Pile-up Conditions
title_short Energy Reconstruction Techniques in TileCal under High Pile-up Conditions
title_sort energy reconstruction techniques in tilecal under high pile-up conditions
topic Particle Physics - Experiment
url http://cds.cern.ch/record/2767754
work_keys_str_mv AT inaciogoncalvesguilherme energyreconstructiontechniquesintilecalunderhighpileupconditions
AT atlastilecollaboration energyreconstructiontechniquesintilecalunderhighpileupconditions