TY - JOUR
T1 - Reconstruction of muon number of air showers with the surface detector of the Pierre Auger Observatory using neural networks
AU - Pierre Auger Collaboration
AU - Hahn, Steffen Traugott
AU - Abdul Halim, A.
AU - Abreu, P.
AU - Aglietta, M.
AU - Allekotte, I.
AU - Almeida Cheminant, K.
AU - Almela, A.
AU - Aloisio, R.
AU - Alvarez-Muñiz, J.
AU - Ammerman Yebra, J.
AU - Anastasi, G. A.
AU - Anchordoqui, L.
AU - Andrada, B.
AU - Andringa, S.
AU - Aramo, C.
AU - Araújo Ferreira, P. R.
AU - Arnone, E.
AU - Arteaga Velázquez, J. C.
AU - Asorey, H.
AU - Assis, P.
AU - Avila, G.
AU - Avocone, E.
AU - Badescu, A. M.
AU - Bakalova, A.
AU - Balaceanu, A.
AU - Barbato, F.
AU - Bartz Mocellin, A.
AU - Bellido, J. A.
AU - Berat, C.
AU - Bertaina, M. E.
AU - Bhatta, G.
AU - Bianciotto, M.
AU - Biermann, P. L.
AU - Binet, V.
AU - Bismark, K.
AU - Bister, T.
AU - Biteau, J.
AU - Blazek, J.
AU - Bleve, C.
AU - Blümer, J.
AU - Boháčová, M.
AU - Boncioli, D.
AU - Bonifazi, C.
AU - Bonneau Arbeletche, L.
AU - Borodai, N.
AU - Brack, J.
AU - Brichetto Orchera, P. G.
AU - Briechle, F. L.
AU - Bueno, A.
AU - Ventura, C.
N1 - Publisher Copyright:
© Copyright owned by the author(s) under the terms of the Creative Commons.
PY - 2024/9/27
Y1 - 2024/9/27
N2 - To understand the physics of cosmic rays at the highest energies, it is mandatory to have an accurate knowledge of their mass composition. Since the mass of the primary particles cannot be measured directly, we have to rely on the analysis of mass-sensitive observables to gain insights into this composition. A promising observable for this purpose is the number of muons at the ground relative to that of an air shower induced by a proton primary of the same energy and inclination angle, commonly referred to as the relative muon number Rµ. Due to the complexity of shower footprints, the extraction of Rµ from measurements is a challenging task and intractable to solve using analytic approaches. We, therefore, reconstruct Rµ by exploiting the spatial and temporal information of the signals induced by shower particles using neural networks. Using this data-driven approach permits us to tackle this task without the need of modeling the underlying physics and, simultaneously, gives us insights into the feasibility of such an approach. In this contribution, we summarize the progress of the deep-learning-based approach to estimate Rµ using simulated surface detector data of the Pierre Auger Observatory. Instead of using single architecture, we present different network designs verifying that they reach similar results. Moreover, we demonstrate the potential for estimating Rµ using the scintillator surface detector of the AugerPrime upgrade.
AB - To understand the physics of cosmic rays at the highest energies, it is mandatory to have an accurate knowledge of their mass composition. Since the mass of the primary particles cannot be measured directly, we have to rely on the analysis of mass-sensitive observables to gain insights into this composition. A promising observable for this purpose is the number of muons at the ground relative to that of an air shower induced by a proton primary of the same energy and inclination angle, commonly referred to as the relative muon number Rµ. Due to the complexity of shower footprints, the extraction of Rµ from measurements is a challenging task and intractable to solve using analytic approaches. We, therefore, reconstruct Rµ by exploiting the spatial and temporal information of the signals induced by shower particles using neural networks. Using this data-driven approach permits us to tackle this task without the need of modeling the underlying physics and, simultaneously, gives us insights into the feasibility of such an approach. In this contribution, we summarize the progress of the deep-learning-based approach to estimate Rµ using simulated surface detector data of the Pierre Auger Observatory. Instead of using single architecture, we present different network designs verifying that they reach similar results. Moreover, we demonstrate the potential for estimating Rµ using the scintillator surface detector of the AugerPrime upgrade.
UR - http://www.scopus.com/inward/record.url?scp=85212278678&partnerID=8YFLogxK
M3 - Conference article
AN - SCOPUS:85212278678
SN - 1824-8039
VL - 444
JO - Proceedings of Science
JF - Proceedings of Science
M1 - 318
T2 - 38th International Cosmic Ray Conference, ICRC 2023
Y2 - 26 July 2023 through 3 August 2023
ER -