par Artamonov, Andrei;Gorbunov, P.A. P.A.;Wong, Henry;Bonekämper, D.;Rondeshagen, D.;Wolff, Th;Brunner, Jürgen;Carnevale, G.;Cussans, David;Ferreira, Rui;Friend, B.;Guerriero, Antonio;Gurin, Ruten;Litmaath, Maarten;Macina, Daniela;Meijer Drees, Reena;Meinhard, Helge;Veras, H.;Panman, Jaap;Riccardi, F.;Rozanov, Alexandre N.;Saltzberg, David;Bülte, A.;Catanesi, Gabriela;Cocco, Alfredo;Jong, M.;Oldeman, Rudolf G C;Poel, C.A.F. C.A.F.;Uiterwijk, J.W.E. J.W.E.;Maslennikov, Alexei;Mazzoni, Maria Alessandra;Mommaert, Chantal;Vander Donckt, Muriel 
;Zucchelli, Piero
Référence Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment, 479, 2-3, page (412-438)
Publication Publié, 2002-03
;Zucchelli, PieroRéférence Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment, 479, 2-3, page (412-438)
Publication Publié, 2002-03
Article révisé par les pairs
| Résumé : | An analysis of the data acquisition (DAQ) system used in the CHORUS experiment was presented. The DAQ used is versatile due to its novel implementation of important concepts, including a remote operating system (REMOS), a finite state machine language, a buffer manager, a dispatcher, a control panel and a supervisor. It was observed that the performance of the DAQ was satisfactory with an efficiency of more than 99%. |
