Search for Cosmic-Ray Events Using Radio Signals and CNNs in Data from the IceTop Enhancement Prototype Station

A. Rehman,Alan Coleman, F. Schröder, Dana Kullgren,R. Abbasi,M. Ackermann,J. Adams,S. Agarwalla,J. Aguilar,M. Ahlers, J. Alameddine,N. M. Amin,K. Andeen,G. Anton,C. Argüelles,Y. Ashida,S. Athanasiadou,S. Axani,X. Bai,A. Balagopal V,M. Baricevic,S. Barwick,V. Basu,R. Bay,James Beatty,J. Becker Tjus,J. Beise,C. Bellenghi,C. Benning,S. BenZvi,D. Berley,E. Bernardini,D. Besson,E. Blaufuss,S. Blot,F. Bontempo, J. Book,Caterina Boscolo Meneguolo,S. Boser,O. Botner,J. Bottcher,E. Bourbeau,J. Braun,B. Brinson,J. Brostean-Kaiser, R. Burley, R. Busse,D. Butterfield,M. Campana,K. Carloni, E. Carnie-Bronca,S. Chattopadhyay,Thien Nhan Chau,Chujie Chen,Zheyang Chen,D. Chirkin,Seowon Choi,B. Clark,L. Classen,G. Collin,A. Connolly,Janet M. Conrad,P. Coppin,P. Correa,D. Cowen,Pranav Dave,C. De Clercq, J. DeLaunay,D. Delgado Lopez,S. Deng,K. Deoskar,A. Desai,P. Desiati,Krijn de Vries,G. de Wasseige,T. DeYoung,Alejandro Diaz,J. C. Díaz-Vélez,M. Dittmer,A. Domi,H. Dujmovic, M. DuVernois,T. Ehrhardt,P. Eller,E. Ellinger, Sharif El Mentawi,D. Elsässer,R. Engel,H. Erpenbeck,J. Evans,P. Evenson,K. L. Fan,K. Fang,K. Farrag,A. Fazely,A. Fedynitch,N. Feigl,S. Fiedlschuster,C. Finley,L. Fischer,D. Fox,A. Franckowiak,Alexander Fritz,P. Furst,J. Gallagher,E. Ganster,Alfonso Garcia,L. Gerhardt,A. Ghadimi,C. Glaser,T. Glauch,T. Glusenkamp,N. Goehlke,Javier Gonzalez,S. Goswami,Darren Grant, S. Gray,O. Gries,S. Griffin,S. Griswold,K. M. Groth,C. Günther,P. Gutjahr,C. Haack,A. Hallgren,R. Halliday,L. Halve,F. Halzen,H. Hamdaoui,M. Ha Minh,K. Hanson,J. Hardin, A. Harnisch,P. Hatch,A. Haungs,K. Helbing,J. Hellrung,F. Henningsen,L. Heuermann,N. Heyer,S. Hickford,A. Hidvégi,C. Hill,G. Hill, K. Hoffman,S. Hori,K. Hoshina,Wenjie Hou,T. Huber,K. Hultqvist,Mirco Hünnefeld,R. Hussain,K. Hymon,S. In,A. Ishihara,M. Jacquart,O. Janik,M. Jansson,G. Japaridze,M. Jeong,M. Jin, B. Jones,D. Kang,W. Kang,Xinyue Kang,A. Kappes,D. Kappesser,L. Kardum,T. Karg,M. Karl,A. Karle,U. Katz,M. Kauer,J. Kelley, Arifa Khatee Zathul,A. Kheirandish,J. Kiryluk,S. Klein,A. Kochocki,R. Koirala,H. Kolanoski,T. Kontrimas,L. Kopke,C. Kopper, J. Koskinen,P. Koundal,M. Kovacevich,M. Kowalski,T. Kozynets,K. Jayakumar,K. Kruiswijk,E. Krupczak,Anil Kumar,E. Kun, N. K. Neilson,N. Lad,C. Lagunas Gualda,M. Lamoureux,M. Larson,S. Latseva,F. Lauber, J. Lazar,Jiwoong Lee,K. Leonard DeHolton,A. Leszczyńska,M. Lincetto,Qinrui Liu,M. Liubarska,E. Lohfink,C. Love,C. J. Lozano Mariscal,Lu Lu,F. Lucarelli,W. Luszczak,Y. Lyu,J. Madsen,K. Mahn,Y. Makino,E. Manao,S. Mancina,W. Marie Sainte,I. Mariş, S. Márka, Z. Márka,M. Marsee,I. Martinez-Soler,R. Maruyama,F. Mayhew,T. McElroy,F. McNally,J. V. Mead,K. Meagher,S. Mechbal,A. Medina,M. Meier,Y. Merckx,L. Merten,J. Micallef,J. Mitchell,T. Montaruli,R. Moore,Y. Morii,Bob Morse,M. Moulai,T. Mukherjee,R. Naab,R. Nagai,M. Nakos,U. Naumann,J. Necker,A. Negi,M. Neumann,H. Niederhausen, M. Nisa,A. Noell,A. Novikov, S. Nowicki, A. Pollmann,V. O'Dell,M. Oehler,B. Oeyen,A. Olivas,R. Orsoe,J. Osborn,E. O’Sullivan,H. Pandya,N. Park, G. Parker, E. Paudel,L. Paul,C. Pérez de los Heros,Josh Peterson,S. Philippen,A. Pizzuto,M. Plum, A. N. N. Pontén,Yuriy Popovych,M. Prado Rodriguez,B. Pries,R. Procter-Murphy,G. Przybylski,C. Raab,J. Rack-Helleis,K. Rawlins,Z. Rechav,P. Reichherzer,G. Renzi,E. Resconi,S. Reusch,W. Rhode,B. Riedel,A. Rifaie, E. Roberts,S. Robertson,S. Rodan,G. Roellinghoff,M. Rongen,C. Rott,T. Ruhe, Ruohan Li,D. Ryckbosch,I. Safa,J. Saffer,D. Salazar-Gallegos,P. Sampathkumar, S. Sanchez Herrera,A. Sandrock,M. Santander, S. Sarkar,S. Sarkar,J. Savelberg,P. Savina,M. Schaufel,H. Schieler,Sebastian Schindler,L. Schlickmann,B. Schlüter,F. Schlüter,N. Schmeisser,T. Schmidt,Judith Schneider,L. Schumacher,G. Schwefer,S. Sclafani,D. Seckel,M. Seikh,S. Seunarine,R. Shah,Ankur Sharma,S. Shefali,N. Shimizu,Manuel Silva,B. Skrzypek,B. Smithers,R. Snihur,J. Soedingrekso,A. Søgaard,D. Soldin,P. Soldin,G. Sommani,C. Spannfellner,G. Spiczak,C. Spiering,M. Stamatikos,T. Stanev,T. Stezelberger,T. Sturwald,T. Stuttard,G. Sullivan,I. Taboada,S. Ter-Antonyan,M. Thiesmeyer, W. Thompson,J. Thwaites,S. Tilav,K. Tollefson,C. Tönnis,S. Toscano,D. Tosi,A. Trettin, C. Tung,R. Turcotte,J. P. Twagirayezu,B. Ty, M. U. Unland Elorrieta, A. Upadhyay,K. Upshaw,N. Valtonen-Mattila,J. Vandenbroucke,N. van Eijndhoven,D. Vannerom,J. van Santen,J. Vara,J. Veitch-Michaelis,M. Venugopal,M. Vereecken,S. Verpoest,D. Veske,A. Vijai,C. Walck,C. Weaver,P. Weigel,A. Weindl,J. Weldert,C. Wendt,J. Werthebach,M. Weyrauch,N. Whitehorn,C. Wiebusch,N. Willey,Dawn R. Williams,L. Witthaus, Annika Wolf,M. Wolf,G. Wrede,Xianwu Xu, J. Yáñez,E. Yildizci,S. Yoshida,R. Young,Felix J. Yu,Shiqi Yu,T. Yuan,Zelong Zhang,P. Zhelnin,M. Zimmerman

International Conference on Rebooting Computing（2023）

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摘要

Cosmic-ray air showers emit radio waves that can be used to measure the properties of cosmic-ray primary particles. The radio detection technique presents several advantages, such as low cost and year-round duty cycle as well as the ability to provide high sensitivity to X max and energy estimation with minimal theoretical uncertainties, making it a promising tool for studying cosmic rays at the highest energies. However, the primary limitation of radio detection is the irreducible background from various sources that obscure the impulsive signals generated by air showers. To address this issue, we investigated the use of Convolutional Neural Networks (CNNs), trained on CoREAS simulations and radio backgrounds measured by a prototype station at the South Pole. We developed two different CNNs: a Classifier that distinguishes between cosmic ray event radio signals and pure background waveforms, and a Denoiser that mitigates background noise to recover the underlying cosmic-ray signal. After training the networks we apply them to the air-shower data to search for radio events. With two months data, we were able to identify 51 candidate events. The event’s arrival direction reconstructed using CNN denoised radio waveforms is found to be in good agreement with the IceTop reconstruction. Finally, our approach demonstrated improved directional reconstruction compared to traditional methods.

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