TY - JOUR
T1 - Combining Maximum-Likelihood with Deep Learning for Event Reconstruction in IceCube
AU - The IceCube Collaboration
AU - Hünnefeld, Mirco
AU - Abbasi, R.
AU - Ackermann, M.
AU - Adams, J.
AU - Aguilar, J. A.
AU - Ahlers, M.
AU - Ahrens, M.
AU - Alispach, C.
AU - Alves, A. A.
AU - Amin, N. M.
AU - An, R.
AU - Andeen, K.
AU - Anderson, T.
AU - Anton, G.
AU - Argüelles, C.
AU - Ashida, Y.
AU - Axani, S.
AU - Bai, X.
AU - Balagopal, A. V.
AU - Barbano, A.
AU - Barwick, S. W.
AU - Bastian, B.
AU - Basu, V.
AU - Baur, S.
AU - Bay, R.
AU - Beatty, J. J.
AU - Becker, K. H.
AU - Becker Tjus, J.
AU - Bellenghi, C.
AU - BenZvi, S.
AU - Berley, D.
AU - Bernardini, E.
AU - Besson, D. Z.
AU - Binder, G.
AU - Bindig, D.
AU - Blaufuss, E.
AU - Blot, S.
AU - Boddenberg, M.
AU - Bontempo, F.
AU - Borowka, J.
AU - Böser, S.
AU - Botner, O.
AU - Böttcher, J.
AU - Bourbeau, E.
AU - Bradascio, F.
AU - Braun, J.
AU - Bron, S.
AU - Brostean-Kaiser, J.
AU - Browne, S.
AU - Resconi, E.
N1 - Publisher Copyright:
© Copyright owned by the author(s).
PY - 2022/3/18
Y1 - 2022/3/18
N2 - The field of deep learning has become increasingly important for particle physics experiments, yielding a multitude of advances, predominantly in event classification and reconstruction tasks. Many of these applications have been adopted from other domains. However, data in the field of physics are unique in the context of machine learning, insofar as their generation process and the laws and symmetries they abide by are usually well understood. Most commonly used deep learning architectures fail at utilizing this available information. In contrast, more traditional likelihood-based methods are capable of exploiting domain knowledge, but they are often limited by computational complexity. In this contribution, a hybrid approach is presented that utilizes generative neural networks to approximate the likelihood, which may then be used in a traditional maximum-likelihood setting. Domain knowledge, such as invariances and detector characteristics, can easily be incorporated in this approach. The hybrid approach is illustrated by the example of event reconstruction in IceCube.
AB - The field of deep learning has become increasingly important for particle physics experiments, yielding a multitude of advances, predominantly in event classification and reconstruction tasks. Many of these applications have been adopted from other domains. However, data in the field of physics are unique in the context of machine learning, insofar as their generation process and the laws and symmetries they abide by are usually well understood. Most commonly used deep learning architectures fail at utilizing this available information. In contrast, more traditional likelihood-based methods are capable of exploiting domain knowledge, but they are often limited by computational complexity. In this contribution, a hybrid approach is presented that utilizes generative neural networks to approximate the likelihood, which may then be used in a traditional maximum-likelihood setting. Domain knowledge, such as invariances and detector characteristics, can easily be incorporated in this approach. The hybrid approach is illustrated by the example of event reconstruction in IceCube.
UR - http://www.scopus.com/inward/record.url?scp=85145019872&partnerID=8YFLogxK
M3 - Conference article
AN - SCOPUS:85145019872
SN - 1824-8039
VL - 395
JO - Proceedings of Science
JF - Proceedings of Science
M1 - 1065
T2 - 37th International Cosmic Ray Conference, ICRC 2021
Y2 - 12 July 2021 through 23 July 2021
ER -