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Sensor shapes and weak modes of the ATLAS Inner Detector track-based alignment

The alignment of the ATLAS Inner Detector is performed with a track-based algorithm. The aim of the detector alignment is to provide an accurate description of the detector geometry such that track parameters are accurately determined and bias free. The detector alignment is validated and improved b...

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Autor principal: Wollrath, Julian
Lenguaje:eng
Publicado: 2019
Materias:
Acceso en línea:http://cds.cern.ch/record/2676520
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author Wollrath, Julian
author_facet Wollrath, Julian
author_sort Wollrath, Julian
collection CERN
description The alignment of the ATLAS Inner Detector is performed with a track-based algorithm. The aim of the detector alignment is to provide an accurate description of the detector geometry such that track parameters are accurately determined and bias free. The detector alignment is validated and improved by studying resonance decays ($J/\psi$ and $Z$ to $\mu^+\mu^-$). The detailed study of these resonances (together with the properties of the tracks of their decay products) allows to detect and correct for alignment weak modes such as detector curls and radial deformations that may bias the momentum and/or the impact parameter. Here, radial distortions were investigated. Furthermore, a new analysis with a detailed scrutiny of the track-to-hit residuals allows to study the deformation shape of the Pixel and IBL modules. The sensor distortion can result in track-to-hit residual biases of up to 10µm within a given module. The shape of the IBL modules is parametrised with Bernstein-Bézier functions and used to correct the hit positioning in the track fitting procedure.
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institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2019
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spelling cern-26765202021-05-03T08:10:53Zhttp://cds.cern.ch/record/2676520engWollrath, JulianSensor shapes and weak modes of the ATLAS Inner Detector track-based alignmentParticle Physics - ExperimentThe alignment of the ATLAS Inner Detector is performed with a track-based algorithm. The aim of the detector alignment is to provide an accurate description of the detector geometry such that track parameters are accurately determined and bias free. The detector alignment is validated and improved by studying resonance decays ($J/\psi$ and $Z$ to $\mu^+\mu^-$). The detailed study of these resonances (together with the properties of the tracks of their decay products) allows to detect and correct for alignment weak modes such as detector curls and radial deformations that may bias the momentum and/or the impact parameter. Here, radial distortions were investigated. Furthermore, a new analysis with a detailed scrutiny of the track-to-hit residuals allows to study the deformation shape of the Pixel and IBL modules. The sensor distortion can result in track-to-hit residual biases of up to 10µm within a given module. The shape of the IBL modules is parametrised with Bernstein-Bézier functions and used to correct the hit positioning in the track fitting procedure.The alignment of the ATLAS Inner Detector is performed with a track-based algorithm. The aim of the detector alignment is to provide an accurate description of the detector geometry such that track parameters are accurately determined and bias free. The detector alignment is validated and improved by studying resonant decays ($J/\psi$ and $Z$ to $\mu^+\mu^-$). The detailed study of these resonances (together with the properties of the tracks of their decay products) allows to detect and correct for alignment weak modes such as detector curls and radial deformations that may bias the momentum and/or the impact parameter measurements. Here, radial distortions were investigated. Furthermore, a new analysis with a detailed scrutiny of the track-to-hit residuals allowed to study the deformation shape of the Pixel and IBL modules. The sensor distortion can result in track-to-hit residual biases of up to $10\mu m$ within a given module. The shape of the IBL modules was parametrised with Bernstein-B\'ezier functions and used to correct the hit position in the track fitting procedure.arXiv:1910.06060ATL-PHYS-PROC-2019-039PROC-CTD19-134oai:cds.cern.ch:26765202019-05-27
spellingShingle Particle Physics - Experiment
Wollrath, Julian
Sensor shapes and weak modes of the ATLAS Inner Detector track-based alignment
title Sensor shapes and weak modes of the ATLAS Inner Detector track-based alignment
title_full Sensor shapes and weak modes of the ATLAS Inner Detector track-based alignment
title_fullStr Sensor shapes and weak modes of the ATLAS Inner Detector track-based alignment
title_full_unstemmed Sensor shapes and weak modes of the ATLAS Inner Detector track-based alignment
title_short Sensor shapes and weak modes of the ATLAS Inner Detector track-based alignment
title_sort sensor shapes and weak modes of the atlas inner detector track-based alignment
topic Particle Physics - Experiment
url http://cds.cern.ch/record/2676520
work_keys_str_mv AT wollrathjulian sensorshapesandweakmodesoftheatlasinnerdetectortrackbasedalignment