Particle identification algorithms for the HARP forward spectrometer

di Capua, E.; Mg, Catanesi; Radicioni, E.; Edgecock, R.; Ellis, M.; Robbins, S.; Soler, Fjp J. P.; Gößling, C.; Fjp, Soler; Chelkov, G.; Chukanov, A.; Dedovitch, D.; Gostkin, M.; Guskov, A.; Khartchenko, D.; Klimov, O.; Krasnoperov, A.; Kroumchtein, Z.; Gossling, C.; Kustov, D.; Nefedov, Y.; Goessling, C.; Popov, B.; Serdiouk, V.; Tereshchenko, V.; Zhemchugov, A.; Vidal-Sitjes, G.; Giani, S.; Gilardoni, S.; Gorbunov, P.; Grant, A.; Grossheim, A.; Gruber, P.; Ivanchenko, V.; Kayis-Topaksu, A.; Panman, J.; Papadopoulos, I.; Pasternak, J.; Tcherniaev, E.; Tsukerman, I.; Veenhof, R.; Veenhotf, R.; Wiebusch, C.; Zucchelli, P.; Cervera-Villanueva, A.; Morone, Mc C.; Mc, Morone; Prior, G.; Schroeter, R.; Kato, I.; Nakaya, T.; Nishikawa, K.; Ueda, S.; Gastaldi, U.; Mills, Gb B.; Graulich, Js S.; Gb, Mills; Js, Graulich; Grégoire, G.; De Min, A.; Gregoire, G.; Ferri, F.; Paganoni, M.; Paleari, F.; Kirsanov, M.; Grichine, V.; Polukhina, N.; Palladino, V.; Coney, L.; Schmitz, D.; De Santo, A.; Pattison, C.; Zuber, K.; Gibin, D.; Guglielmi, A.; Laveder, M.; Menegolli, A.; Mezzetto, M.; Dumarchez, J.; Vannucci, F.; Koreshev, V.; Semak, A.; Zaets, V.; Orestanov, D.; Dore, U.; Orestano, D.; Pastore, F.; Pastorev, F.; Tonazzo, A.; Tortora, L.; Tortorav, L.; Hodgson, P.; Howlett, L.; Chizhov, M.; Kolev, D.; Tsenov, R.; Piperov, S.; Temnikov, P.; Chimenti, P.; Giannini, G.; Santin, G.; Hayato, Y.; Ichikawa, A.; Kobayashi, T.; Gomez-Cadenas, Jj; Gómez-Cadenas, J. J.; Novella, P.; Sorel, M.; Tornero, A.; Bunyatov, S.; Artamonov, A.; Arce, P.; Blondel, A.; Borghi, S.; Campanelli, M.; Catanesi, Mg G. And Cervera Villanueva Anselmo Novella Pau Burguet Castell Jordi Gómez Cadenas Juan José Sorel Michel Tornero Ana Marı́a Arce Pedro; Bonesini, M.; Bagulya, A.; Barr, G.; Bobisut, F.; Ammosov, V.; Booth, C.; Buttar, C.; Bogomilov, M.; Apollonio, M.; Burguet-Castell, J.

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Particle identification algorithms for the HARP forward spectrometer

Journal article published in 2007 by E. di Capua, Catanesi Mg, E. Radicioni, R. Edgecock, M. Ellis, S. Robbins, Fjp J. P. Soler, C. Gößling, Soler Fjp, G. Chelkov, A. Chukanov, D. Dedovitch, M. Gostkin, A. Guskov, D. Khartchenko and other authors.

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Abstract

The particle identification (PID) methods used for the calculation of secondary pion yields with the HARP forward spectrometer are presented. Information from time of flight and Cherenkov detectors is combined using likelihood techniques. The efficiencies and purities associated with the different PID selection criteria are obtained from the data. For the proton-aluminium interactions at 12.9 GeV/c incident momentum, the PID efficiencies for positive pions are 86 % in the momentum range below 2 GeV/c, 92 % between 2 and 3 GeV/c and 98 % in the momentum range above 3 GeV/c. The purity of the selection is better than 92 % for all momenta. Special emphasis has been put on understanding the main error sources. The final PID uncertainty on the pion yield is 3.3 %. © 2007 Elsevier B.V. All rights reserved.

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Particle identification algorithms for the HARP forward spectrometer

Abstract