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AKPIK: Arbeitskreis Physik, moderne Informationstechnologie und Künstliche Intelligenz
AKPIK 2: AKPIK II: Deep Learning
AKPIK 2.4: Vortrag
Mittwoch, 17. März 2021, 16:45–17:00, AKPIKa
Boosting the performance of the neural network using symmetry properties for the prediction of the shower maximum using the water Cherenkov Detectors of the Pierre Auger Observatory as an example — Darko Veberic1, David Schmidt1, Markus Roth1, •Steffen Hahn1, Ralph Engel1, and Brian Wundheiler2 for the Pierre Auger collaboration — 1Karlsruhe Institute of Technology (KIT), IAP, Germany — 2Universidad Nacional de San Martin (UNSAM), ITEDA, Argentina
To probe physics beyond the scales of human-made accelerators with cosmic rays demands an accurate knowl- edge of their primary mass composition. Using fluorescence detectors, one is able to estimate this by measur- ing the depth of the shower maximum Xmax. These, however, exhibit a very low duty cycle of typically below 15 %.
Inferring Xmax from a surface detector array (SD) such as the water-Cherenkov array of the Pierre Auger Observatory is highly non-trivial due to the inherent complexity and fluctuations of the shower footprint. Moreover, the sheer amount of data makes it non-trivial to find hidden patterns in the spatial and temporal distributions of detector signals. Neural networks provide a straightforward way of tackling such a problem doing a data-driven analysis.
Relying solely on geometrical quantities, timing, and the signal-time information of the SD stations, we show that by exploiting the symmetries due to their triangular arrangement, we are able to boost a standard anal- ysis network significantly without modifying its architecture or training process. Furthermore, these consid- erations yield a standardization procedure which also enables us to encode the footprint’s information in a memory-efficient way. The presented procedure can also be generalized and extended to systems whose setup has an underlying hexagonal geometry.