Commenced in January 2007
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Paper Count: 33093
A Large Ion Collider Experiment (ALICE) Diffractive Detector Control System for RUN-II at the Large Hadron Collider
Authors: J. C. Cabanillas-Noris, M. I. Martínez-Hernández, I. León-Monzón
Abstract:
The selection of diffractive events in the ALICE experiment during the first data taking period (RUN-I) of the Large Hadron Collider (LHC) was limited by the range over which rapidity gaps occur. It would be possible to achieve better measurements by expanding the range in which the production of particles can be detected. For this purpose, the ALICE Diffractive (AD0) detector has been installed and commissioned for the second phase (RUN-II). Any new detector should be able to take the data synchronously with all other detectors and be operated through the ALICE central systems. One of the key elements that must be developed for the AD0 detector is the Detector Control System (DCS). The DCS must be designed to operate safely and correctly this detector. Furthermore, the DCS must also provide optimum operating conditions for the acquisition and storage of physics data and ensure these are of the highest quality. The operation of AD0 implies the configuration of about 200 parameters, from electronics settings and power supply levels to the archiving of operating conditions data and the generation of safety alerts. It also includes the automation of procedures to get the AD0 detector ready for taking data in the appropriate conditions for the different run types in ALICE. The performance of AD0 detector depends on a certain number of parameters such as the nominal voltages for each photomultiplier tube (PMT), their threshold levels to accept or reject the incoming pulses, the definition of triggers, etc. All these parameters define the efficiency of AD0 and they have to be monitored and controlled through AD0 DCS. Finally, AD0 DCS provides the operator with multiple interfaces to execute these tasks. They are realized as operating panels and scripts running in the background. These features are implemented on a SCADA software platform as a distributed control system which integrates to the global control system of the ALICE experiment.Keywords: AD0, ALICE, DCS, LHC.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1123574
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[1] About CERN (2015). European Organization for Nuclear Research. Geneva, Switzerland. Recovered from: http://home.web.cern.ch/
[2] ALICE Collaboration (2015). A Large Ion Collider Experiment. Recovered from: aliweb.cern.ch.
[3] Villalobos, O. (2012). A Study of Diffractive Production in ALICE. Journal of Physics: Conference Series. 381 012039 doi:10.1088/1742-6596/381/1/012039.
[4] Herrera, G. (2011). Diffractive physics in ALICE at the LHC. 5th International Workshop On High-pT Physics at LHC. AIP Conference Proceedings, Volume 1348, pp. 45-52 (2011). Recovered from: http://indico.nucleares.unam.mx/getFile.py/access?contribId=26&resId=0&materialId=0&confId=205
[5] Chochula, P. et al. (2012). Operational Experiences with the ALICE Detector Control System. Proceedings of ICALEPCS2013. San Francisco, CA, USA. FRCOAAB07.
[6] Aamodt, K. et al. (2008). The ALICE experiment at the CERN LHC. Journal of Instrumentation (JINST), vol. 3, article no. S08002, doi:10.1088/1748-0221/3/08/S08002.
[7] Company ETM (2015). (Online Website). Recovered from: www.etm.at (Consultation: June 2015).
[8] JCOP Framework (2015) (Online Website). Recovered from: https://wikis.web.cern.ch/wikis/display/EN/JCOP+Framework (Consultation: July 2015).
[9] Holme, O. et al (2005). The JCOP FRAMEWORK. 10th ICALEPCS Int. Conf. on Accelerator & Large Expt. Physics Control Systems. Geneva, 10 - 14 Oct 2005. WE2.1-6O.
[10] The Standard DCS User Interface in ALICE. Ver. 3.0.7 (2008). ALICE DCS. Recovered from: http://alicedcs.web.cern.ch/alicedcs/Software/Downloads/AliceDcsUi_v3.0.pdf (Consultation: December 2015).
[11] CAEN Company (2015). (Online Website). Recovered from: www.caen.it (Consultation: July 2015).
[12] Zoccarato, Y., et al. (2011). Front end electronics and first results of the ALICE V0 detector. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment. Elsevier. Volumes 626–627, 11–21 January 2011, Pages 90–96.
[13] Pinazza, O. READY for RUN2? Last steps and instructions for WinCC projects. DCS Workshop during the ALICE Week. CERN. March 2015.
[14] Mercado-Pérez, Jorge (2008). Development of the control system of the ALICE Transition Radiation Detector and of a test environment for quality-assurance of its front-end electronics. PhD Thesis. CERN-THESIS-2008-141. Universitat Heidelberg.