M. Krivda
Slovak Academy of Sciences
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Featured researches published by M. Krivda.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2003
P. Riedler; G. Anelli; F. Antinori; M. Burns; K Banicz; R Caliandro; M. Campbell; M Caselle; P. Chochula; R. Dinapoli; S. Easo; D. Elia; F. Formenti; M Girone; T. Gys; J.J. van Hunen; A Jusko; Alexander Kluge; M. Krivda; V. Lenti; M. Lupták; V. Manzari; F. Meddi; M. Morel; F. Riggi; W. Snoeys; G. Stefanini; Ken Wyllie
Abstract System prototyping of the ALICE silicon pixel detector (SPD) is well underway. The ALICE SPD consists of two barrel layers with 9.83 million channels in total. These are read out by the ALICE1LHCb pixel chip, which has been developed in a commercial 0.25 μm process with radiation hardening by design layout. The readout chip contains 8192 pixel cells each with a fast analog preamplifier and shaper followed by a discriminator and digital delay lines. Test results show a pixel cell noise of about 110 electrons rms and a mean minimum threshold of about 1000 electrons rms before threshold fine tuning. Several readout chips have been flip-chip bonded to detectors using two different bump-bonding techniques (solder, indium). Results of radioactive source measurements of these assemblies are presented for 90 Sr and 55 Fe sources. Several chip-detector assemblies have been tested in a 150 GeV / c pion beam at CERN where an online efficiency of about 99% across a wide range of detector bias and threshold settings was observed. All preliminary investigations confirm the functionality of the chip and the chip-detector assemblies for the ALICE experiment.
Nuclear Physics | 2003
P. Chochula; F. Antinori; G. Anelli; M. Burns; M. Campbell; M. Caselle; R. Dinapoli; D. Elia; R.A. Fini; F. Formenti; J.J. van Hunen; S. Kapusta; Alexander Kluge; M. Krivda; V. Lenti; V. Manzari; F. Meddi; M. Morel; P. Nilsson; A. Pepato; P. Riedler; R. Santoro; G. Stefanini; K. Wyllie
CERN European Organization for Nuclear Research, CH-1211 Geneva 23, Switzerland Universita degli Studi di Padova, I-35131, Padova, Italy Dipartimento IA di Fisica e Sez. INFN di Bari, I-70126,Bari,Italy Comenius University, SK-84215 Bratislava, Slovakia NIKHEF, National Institute for Nuclear Physics and High Energy Physics, 1098 SJ Amsterdam, The Netherlands Slovak Academy of Sciences, SK-04353, Kosice, Slovakia Universita di Roma I, La Sapienza, I-00185, Roma, Italy
Prepared for | 2001
Alexander Kluge; J.J. van Hunen; Marilyn Luptak; J. Ban; M. Burns; P. Riedler; F. Meddi; M. Krivda; W. Snoeys; F. Formenti; R. Dinapoli; M. Campbell; F. Antinori; G. Stefanini; P. Chochula; M. Morel; G. Anelli; K. Wyllie
The on-detector electronics of the ALICE silicon pixel detector (nearly 10 million pixels) consists of 1,200 readout chips, bump-bonded to silicon sensors and mounted on the front-end bus, and of 120 control (PILOT) chips, mounted on a multi chip module (MCM) together with opto-electronic transceivers. The environment of the pixel detector is such that radiation tolerant components are required. The front-end chips are all ASICs designed in a commercial 0.25-micron CMOS technology using radiation hardening layout techniques. An 800 Mbit/s Glink-compatible serializer and laser diode driver, also designed in the same 0.25 micron process, is used to transmit data over an optical fibre to the control room where the actual data processing and event building are performed. We describe the system and report on the status of the PILOT system.
Archive | 2001
J.J. van Hunen; Manzari; F. Meddi; R. Dinapoli; F. Formenti; G. Stefanini; S. Easo; M. Morel; Marilyn Luptak; F. Antinori; D. Elia; T. Gys; A Jusko; M. Girone; M. Campbell; M. Caselle; P. Riedler; P. Chochula; W. Snoeys; K Banicz; G. Anelli; Ken Wyllie; Lenti; M. Burns; F. Riggi; M. Krivda; Alexander Kluge; R Caliandro
The Alice1LHCb front-end chip [1,2] has been designed for the ALICE pixel and the LHCb RICH detectors. It is fabricated in a commercial 0.25 μm CMOS technology, with special design techniques to obtain radiation tolerance. The chip has been irradiated with low energy protons and heavy ions, to determine the cross-section for Single Event Upsets (SEU), and with X-rays to evaluate the sensitivity to total ionising dose. We report the results of those measurements. We also report preliminary results of measurements done with 150 GeV pions at the CERN SPS.
Journal of Physics G | 2004
V Manzari; G. Anelli; F. Antinori; A. Boccardi; G E Bruno; M. Burns; I.A. Cali; M. Campbell; M. Caselle; P. Chochula; M. Cinausero; A. Dalessandro; R. Dima; R. Dinapoli; D. Elia; D. Fabris; R.A. Fini; E. Fioretto; F. Formenti; B Ghidini; S. Kapusta; A. Kluge; M. Krivda; V. Lenti; F. Librizzi; M. Lunardon; M. Morel; S. Moretto; F Navach; P. Nilsson
The ALICE silicon pixel detector (SPD) constitutes the two innermost layers of the inner tracking system (ITS). The basic building block of the SPD is the half-stave carrying two detector ladders. The half-stave is equipped with a multi-chip module (MCM) and an optical fibre link for control and readout. A 5-layer aluminium/polyimide bus ensures the distribution of power and signals on each half-stave. The half-staves are mounted on a light-weight carbon-fibre structure with an integrated evaporative cooling system. An overview of the SPD development and the current status of the construction are presented.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2006
D. Elia; G. Anelli; F. Antinori; A. Badalà; G. E. Bruno; M. Burns; I.A. Cali; M. Campbell; M. Caselle; S. Ceresa; P. Chochula; M. Cinausero; J. Conrad; R. Dima; D. Fabris; R.A. Fini; E. Fioretto; S. Kapusta; Alexander Kluge; M. Krivda; V. Lenti; F. Librizzi; M. Lunardon; V. Manzari; M. Morel; S. Moretto; P. Nilsson; F. Osmic; G. S. Pappalardo; V. Paticchio
The two innermost layers of the ALICE inner tracking system are instrumented with silicon pixel detectors. Single chip assembly prototypes of the ALICE pixels have been tested in high energy particle beams at the CERN SPS. Detection efficiency and spatial precision have been studied as a function of the threshold and the track incidence angle. The experimental method, data analysis and main results are presented.
Journal of Physics: Conference Series | 2006
S. Moretto; G. Anelli; F. Antinori; A. Badalà; A. Boccardi; G. E. Bruno; M. Burns; Ivan Amos Cali; M. Campbell; M. Caselle; S. Ceresa; P. Chochula; M. Cinausero; J. Conrad; R. Dima; D. Elia; D. Fabris; R. A. Fini; E. Fioretto; S. Kapusta; A. Kluge; M. Krivda; V. Lenti; F. Librizzi; M. Lunardon; V. Manzari; M. Morel; P. Nilsson; F. Osmic; G. S. Pappalardo
The Silicon Pixel Detector (SPD) is the innermost part of the Inner Tracking System (ITS) of the ALICE experiment at LHC. 240 detector ladders containing in total about 10 million pixel cells with dimension 50 × 425 µm2, have to be assembled on a carbon fibre support. The mounting procedure of the basic SPD modules (Half-Staves) and the assembly of the barrel sectors are presented. Results on the assembly of the first sector are reported.
ieee nuclear science symposium | 2005
Alexander Kluge; G. Anelli; F. Antinori; A. Badalà; A. Boccardi; G.E. Bruno; M. Burns; Ivan Amos Cali; M. Campbell; M. Caselle; S. Ceresa; P. Chochula; M. Cinausero; J. Conrad; R. Dima; D. Eliad; D. Fabris; R.A. Fini; E. Fioretto; F. Formenti; S. Kapusta; M. Krivda; V. Lenti; F. Librizzi; M. Lunardon; V. Manzari; M. Morel; S. Moretto; F. Osmic; G.S. Pappalardo
The ALICE silicon pixel detector (SPD) comprises the two innermost layers of the ALICE inner tracker system. The SPD includes 120 half staves each consisting of 10 ALICE pixel chips bump bonded to two silicon sensors and one multi-chip read-out module. Each pixel chip contains 8192 active cells, so that the total number of pixel cells in the SPD is ap107. The on-detector read-out is based on a multi-chip-module containing 4 ASICs and an optical transceiver module. The constraints on material budget detector module dimensions are very demanding
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2007
J. Conrad; G. Anelli; F. Antinori; A. Badalà; R. Barbera; A. Boccardi; M. Burns; G. E. Bruno; Ivan Amos Cali; M. Campbell; M. Caselle; P. Chochula; S. Ceresa; M. Cinausero; R. Dima; D. Elia; D. Fabris; E. Fioretto; R. A. Fini; S. Kapusta; A. Kluge; M. Krivda; V. Lenti; F. Librizzi; M. Lunardon; V. Manzari; M. Morel; S. Moretto; A. Morsch; P. Nilsson
The silicon pixel detector (SPD) of the ALICE experiment in preparation at the Large Hadron Collider (LHC) at CERN is designed to provide the precise vertex reconstruction needed for measuring heavy flavor production in heavy ion collisions at very high energies and high multiplicity. The SPD forms the innermost part of the Inner Tracking System (ITS) which also includes silicon drift and silicon strip detectors. Single assembly prototypes of the ALICE SPD have been tested at the CERN SPS using high energy proton/pion beams in 2002 and 2003. We report on the experimental determination of the spatial precision. We also report on the first combined beam test with prototypes of the other ITS silicon detector technologies at the CERN SPS in November 2004. The issue of SPD simulation is briefly discussed.
Proceedings of the 8th Conference | 2004
Alexander Kluge; G. Anelli; F. Antinori; A. Boccardi; M. Burns; Ivan Amos Cali; M. Campbell; P. Chochula; R. Dinapoli; Domenico Elia; F. Formenti; A. O. Giner; M. Krivda; V. Lenti; V. Manzari; M. Morel; P. Nilsson; A. Pepato; P. Riedler; R. Santoro; G. Stefanini
G. ANELLI, F. ANTINORI, A. BOCCARDI, M. BURNS, I. A. CALI, M. CAMPBELL, P. CHOCHULA, R. DINAPOLI, D. ELIA, F. FORMENTI, A. O. GINER, M. KRIVDA, V. LENTI, V. MANZARI, M. MOREL, P. NILSSON, A. PEPATO, P. RIEDLER, R. SANTORO, G. STEFANINI CERN European Organization for Nuclear Research, CH-1211 Geneva 23, Switzerland Universita degli Studi di Padova, I-35131, Padova, Italy Dipartimento IA di Fisica e Sez. INFN di Bari, I-70126, Bari ,Italy Slovak Academy of Sciences, SK-04353, Kosice, Slovakia ASP-Associazione per lo Sviluppo Scientifico e Technologico del Piemonte, I-10133 Torino, Italy
