M. J. Costa
Spanish National Research Council
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Publication
Featured researches published by M. J. Costa.
Journal of Instrumentation | 2008
A. Abdesselam; T. Barber; Alan Barr; P.J. Bell; J. Bernabeu; J. M. Butterworth; J. R. Carter; A. A. Carter; E. Charles; A. Clark; A. P. Colijn; M. J. Costa; J Dalmau; B. Demirkoz; Paul Dervan; M. Donega; M D'Onifrio; C. Escobar; D. Fasching; D. Ferguson; P. Ferrari; D. Ferrere; J. Fuster; Bj Gallop; C. Garcia; S. Gonzalez; S. Gonzalez-Sevilla; M. J. Goodrick; A. Gorišek; A. Greenall
The SemiConductor Tracker (SCT) data acquisition (DAQ) system will calibrate, configure, and control the approximately six million front-end channels of the ATLAS silicon strip detector. It will provide a synchronized bunch-crossing clock to the front-end modules, communicate first-level triggers to the front-end chips, and transfer information about hit strips to the ATLAS high-level trigger system. The system has been used extensively for calibration and quality assurance during SCT barrel and endcap assembly and for performance confirmation tests after transport of the barrels and endcaps to CERN. Operating in data-taking mode, the DAQ has recorded nearly twenty million synchronously-triggered events during commissioning tests including almost a million cosmic ray triggered events. In this paper we describe the components of the data acquisition system, discuss its operation in calibration and data-taking modes and present some detector performance results from these tests
IEEE Transactions on Nuclear Science | 2007
W. Vandelli; P. Adragna; D. Burckhart; M. Bosman; M. Caprini; A. Corso-Radu; M. J. Costa; M. Della Pietra; J. Von Der Schmitt; A. Dotti; I. Eschrich; M. L. Ferrer; R Ferrari; Gabriella Gaudio; Haleh Khani Hadavand; S. J. Hillier; M. Hauschild; B. Kehoe; S. Kolos; K. Kordas; R. A. McPherson; M. Mineev; C. Padilla; T. Pauly; I. Riu; C. Roda; D. Salvatore; Ingo Scholtes; S. Sushkov; H. G. Wilkens
ATLAS is one of the four experiments under construction along the Large Hadron Collider (LHC) ring at CERN. The LHC will produce interactions at a center-of-mass energy equal to radics = 14 TeV with a frequency of 40 MHz. The detector consists of more than 140 million electronic channels. The challenging experimental environment and the extreme detector complexity impose the necessity of a common, scalable, distributed monitoring framework, which can be tuned for optimal use by different ATLAS sub-detectors at the various levels of the ATLAS data flow. This paper presents the architecture of this monitoring software framework and describes its current implementation, which has already been used at the ATLAS beam test activity in 2004. Preliminary performance results, obtained on a computer cluster consisting of 700 nodes, will also be presented, showing that the performance of the current implementation is within the range of the final ATLAS requirements.
Journal of Instrumentation | 2007
J. Bernabeu; J.V. Civera; M. J. Costa; C. Escobar; J. Fuster; C. Garcia; J.E. Garcia-Navarro; F Gonzalez; S. Gonzalez-Sevilla; C. Lacasta; G. Llosa; S. Marti-Garcia; M. Miñano; V. A. Mitsou; P. Modesto; J. Nacher; R. Rodriguez-Oliete; F. Sánchez; L. Sospedra; V. Strachko
ATLAS experiment, designed to probe the interactions of particles emerging out of proton proton collisions at energies of up to 14 TeV, will assume operation at the Large Hadron Collider (LHC) at CERN in 2007. This paper discusses the assembly and the quality control tests of forward detector modules for the ATLAS silicon microstrip detector assembled at the Instituto de F?sica Corpuscular (IFIC) in Valencia. The construction and testing procedures are outlined and the laboratory equipment is briefly described. Emphasis is given on the module quality achieved in terms of mechanical and electrical stability.
