MICROROC: MICRO-mesh gaseous structure Read-Out Chip

被引:13
作者
Adloff, C. [1 ]
Blaha, J. [1 ]
Chefdeville, M. [1 ]
Dalmaz, A. [1 ]
Drancourt, C. [1 ]
Dulucq, F. [2 ]
Espargiliere, A. [1 ]
Gaglione, R. [1 ]
Geffroy, N. [1 ]
Jacquemier, J. [1 ]
Karyotakis, Y. [1 ]
Martin-Chassard, G. [2 ]
Prast, J. [1 ]
Seguin-Moreau, N. [2 ]
de La Taille, Ch [2 ]
Vouters, G. [1 ]
机构
[1] Univ Savoie, Lab Annecy Le Vieux Phys Particules, CNRS IN2P3, Annecy Le Vieux, France
[2] Univ Paris 11, Lab Accelerateur Lineaire Omega, CNRS IN2P3, Orsay, France
关键词
Electronic detector readout concepts (gas; liquid); Analogue electronic circuits; CMOS readout of gaseous detectors; Front-end electronics for detector readout;
D O I
10.1088/1748-0221/7/01/C01029
中图分类号
TH7 [仪器、仪表];
学科分类号
0804 ; 080401 ; 081102 ;
摘要
MICRO MEsh GAseous Structure (MICROMEGAS) and Gas Electron Multipliers (GEM) detectors are two candidates for the active medium of a Digital Hadronic CALorimeter (DHCAL) as part of a high energy physics experiment at a future linear collider (ILC/CLIC). Physics requirements lead to a highly granular hadronic calorimeter with up to thirty million channels with probably only hit information (digital readout calorimeter). To validate the concept of digital hadronic calorimetry with such small cell size, the construction and test of a cubic meter technological prototype, made of 40 planes of one square meter each, is necessary. This technological prototype would contain about 400 000 electronic channels, thus requiring the development of front-end ASIC. Based on the experience gained with previous ASIC that were mounted on detectors and tested in particle beams, a new ASIC called MICROROC has been developped. This paper summarizes the caracterisation campaign that was conducted on this new chip as well as its integration into a large area Micromegas chamber of one square meter.
引用
收藏
页数:11
相关论文
共 7 条
[1]   Micromegas for imaging hadronic calorimetry [J].
Adloff, C. ;
Blaha, J. ;
Cap, S. ;
Chefdeville, M. ;
Dalmaz, A. ;
Drancourt, C. ;
Espargiliere, A. ;
Gaglione, R. ;
Gallet, R. ;
Geffroy, N. ;
Jacquemier, J. ;
Karyotakis, Y. ;
Peltier, F. ;
Prast, J. ;
Vouters, G. .
XIV INTERNATIONAL CONFERENCE ON CALORIMETRY IN HIGH ENERGY PHYSICS (CALOR 2010), 2011, 293
[2]   MICROMEGAS chambers for hadronic calorimetry at a future linear collider [J].
Adloff, C. ;
Attie, D. ;
Blaha, J. ;
Cap, S. ;
Chefdeville, M. ;
Colas, P. ;
Dalmaz, A. ;
Drancourt, C. ;
Espargiliere, A. ;
Gaglione, R. ;
Gallet, R. ;
Geffroy, N. ;
Giomataris, I. ;
Jacquemier, J. ;
Karyotakis, Y. ;
Peltier, F. ;
Prasta, J. ;
Vouters, G. .
JOURNAL OF INSTRUMENTATION, 2009, 4
[3]   HARDROC1,Readout chip of the Digital Hadronic Calorimeter of ILC [J].
Callier, S. ;
Dulucq, F. ;
de La Taille, C. ;
Martin-Chassard, G. ;
Seguin-Moreau, N. ;
Gaglione, R. ;
Laktineh, I. ;
Mathez, H. ;
Boudry, V. ;
Brient, J. C. ;
Jauffret, C. .
2007 IEEE NUCLEAR SCIENCE SYMPOSIUM CONFERENCE RECORD, VOLS 1-11, 2007, :1851-+
[4]  
Callier S., 2007, P TOP WORKSH EL PART
[5]  
Gaglione R., 2009, P TOP WORKSH EL PART
[6]  
Gaglione R., 2008, IEEE NUCL SCI S, P1815
[7]   Micromegas in a bulk [J].
Giomataris, I. ;
De Oliveira, R. ;
Andriamonje, S. ;
Aune, S. ;
Charpak, G. ;
Colas, P. ;
Fanourakis, G. ;
Ferrer, E. ;
Giganon, A. ;
Rebourgeard, Ph. ;
Salin, P. .
NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2006, 560 (02) :405-408