ICALEPCS2011 - List of Authors (Tarem, S.)

Paper

Title

Page

Detector Control System for the ATLAS Muon Spectrometer And Operational Experience After The First Year of LHC Data Taking

267

S. Zimmermann
Albert-Ludwig Universität Freiburg, Freiburg, Germany
G. Aielli
Università di Roma II Tor Vergata, Roma, Italy
M. Bindi, A. Polini
INFN-Bologna, Bologna, Italy
S. Bressler, E. Kajomovitz, S. Tarem
Technion, Haifa, Israel
R.G.K. Hart
NIKHEF, Amsterdam, The Netherlands
G. Iakovidis, E. Ikarios, K. Karakostas, S. Leontsinis, E. Mountricha
National Technical University of Athens, Athens, Greece

Muon Reconstruction is a key ingredient in any of the experiments at the Large Hadron Collider LHC. The muon spectrometer of ATLAS comprises Monitored Drift Tube (MDTs) and Cathode Strip Chambers (CSCs) for precision tracking as well as Resistive Plate (RPC) and Thin Gap (TGC) Chambers as muon trigger and for second coordinate measurement. Together with a strong magnetic field provided by a super conducting toroid magnet and an optical alignment system a high precision determination of muon momentum up to the highest particle energies accessible by the LHC collisions is provided. The Detector Control System (DCS) of each muon sub-detector technology must efficiently and safely manage several thousands of LV and HV channels, the front-end electronics initialization as well as monitoring of beam, background, magnetic field and environmental conditions. This contribution will describe the chosen hardware architecture, which as much as possible tries to use common technologies, and the implemented controls hierarchy. In addition the muon DCS human machine interface (HMI) layer and operator tools will be covered. Emphasis will be given to reviewing the experience from the first year of LHC and detector operations, and to lessons learned for future large scale detector control systems. We will also present the automatic procedures put in place during last year and review the improvements gained by them for data taking efficiency. Finally, we will describe the role DCS plays in assessing the quality of data for physics analysis and in online optimization of detector conditions.
On Behalf of the ATLAS Muon Collaboration

Poster MOPMN014 [0.249 MB]

Paper	Title	Page
MOPMN014	Detector Control System for the ATLAS Muon Spectrometer And Operational Experience After The First Year of LHC Data Taking	267
	S. Zimmermann Albert-Ludwig Universität Freiburg, Freiburg, Germany G. Aielli Università di Roma II Tor Vergata, Roma, Italy M. Bindi, A. Polini INFN-Bologna, Bologna, Italy S. Bressler, E. Kajomovitz, S. Tarem Technion, Haifa, Israel R.G.K. Hart NIKHEF, Amsterdam, The Netherlands G. Iakovidis, E. Ikarios, K. Karakostas, S. Leontsinis, E. Mountricha National Technical University of Athens, Athens, Greece
	Muon Reconstruction is a key ingredient in any of the experiments at the Large Hadron Collider LHC. The muon spectrometer of ATLAS comprises Monitored Drift Tube (MDTs) and Cathode Strip Chambers (CSCs) for precision tracking as well as Resistive Plate (RPC) and Thin Gap (TGC) Chambers as muon trigger and for second coordinate measurement. Together with a strong magnetic field provided by a super conducting toroid magnet and an optical alignment system a high precision determination of muon momentum up to the highest particle energies accessible by the LHC collisions is provided. The Detector Control System (DCS) of each muon sub-detector technology must efficiently and safely manage several thousands of LV and HV channels, the front-end electronics initialization as well as monitoring of beam, background, magnetic field and environmental conditions. This contribution will describe the chosen hardware architecture, which as much as possible tries to use common technologies, and the implemented controls hierarchy. In addition the muon DCS human machine interface (HMI) layer and operator tools will be covered. Emphasis will be given to reviewing the experience from the first year of LHC and detector operations, and to lessons learned for future large scale detector control systems. We will also present the automatic procedures put in place during last year and review the improvements gained by them for data taking efficiency. Finally, we will describe the role DCS plays in assessing the quality of data for physics analysis and in online optimization of detector conditions. On Behalf of the ATLAS Muon Collaboration
	Poster MOPMN014 [0.249 MB]