Data quality from the Detector Control System at the ATLAS experiment

Abstract In conjunction with the High Luminosity upgrade of the Large Hadron Collider accelerator at CERN, the ATLAS detector is also undergoing an upgrade to handle the significantly higher data rates. The muon end-cap system upgrade in ATLAS, lies with the replacement of the Small Wheel. The New Small Wheel (NSW) is expected to combine high tracking precision with upgraded information for the Level-1 trigger. To accomplish this, small Thin Gap Chamber (sTGC) and MicroMegas detector technologies are being deployed. Due to their installation location in ATLAS, the effects of Barrel Toroid and End-Cap Toroid magnets on NSW must be measured. For the final experiment at ATLAS, each sTGC large double wedge will be equipped with magnetic field Hall effect sensors to monitor the magnetic field near the NSW. The readout is done with an Embedded Local Monitor Board (ELMB) called MDT DCS Module (MDM). For the integration of this hardware in the experiment, first, a detector control system was developed to test the functionality of all sensors before their installation on the detectors. Subsequently, another detector control system was developed for the commissioning of the sensors. Finally, a detector control system based on the above two is under development for the expert panels of ATLAS experiment. In this paper, the sensor readout, the connectivity mapping and the detector control systems will be presented.

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The detector control system of the ATLAS experiment

Journal of Instrumentation ◽

10.1088/1748-0221/3/05/p05006 ◽

2008 ◽

Vol 3 (05) ◽

pp. P05006-P05006 ◽

Cited By ~ 12

Author(s):

A Barriuso Poy ◽

H Boterenbrood ◽

H J Burckhart ◽

J Cook ◽

V Filimonov ◽

...

Keyword(s):

Control System ◽

Atlas Experiment ◽

Detector Control System

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Detector Control System for the AFP detector in ATLAS experiment at CERN

Journal of Physics Conference Series ◽

10.1088/1742-6596/898/3/032022 ◽

2017 ◽

Vol 898 ◽

pp. 032022

Author(s):

E Banaś ◽

D Caforio ◽

S Czekierda ◽

Z Hajduk ◽

J Olszowska ◽

...

Keyword(s):

Control System ◽

Atlas Experiment ◽

Detector Control System

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The Detector Control System of the New Small Wheel for the ATLAS experiment

10.22323/1.397.0169 ◽

2021 ◽

Author(s):

Christos Paraskevopoulos

Keyword(s):

Control System ◽

Atlas Experiment ◽

Detector Control System

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The Detector Control System of the New Small Wheel for the ATLAS experiment

Journal of Physics Conference Series ◽

10.1088/1742-6596/2105/1/012025 ◽

2021 ◽

Vol 2105 (1) ◽

pp. 012025

Author(s):

Polyneikis Tzanis

Keyword(s):

Control System ◽

Continuous Monitoring ◽

Automatic Processes ◽

High Luminosity ◽

Central System ◽

Term Operation ◽

Atlas Experiment ◽

Data Rates ◽

Detector Control System

Abstract The ATLAS Muon Spectrometer is going through an extensive Phase I upgrade to cope up with the future LHC runs of high luminosity of up to instantaneous luminosity of 7.5 × 1034cm−2s−1. The luminosity increase drastically impacts the ATLAS trigger and readout data rates. The present ATLAS Small Wheel Muon detector will be replaced with a New Small Wheel (NSW) detector which is expected to be installed in the ATLAS underground cavern by the end of the Long Shutdown 2 of the LHC. Due to its complexity and long-term operation, the NSW requires the development of a sophisticated Detector Control System (DCS). The use of such a system is necessary to allow the detector to function consistently and safely as well as to function as a seamless interface to all sub-detectors and the technical infrastructure of the experiment. The central system handles the transition between the probe’s possible operating states while ensuring continuous monitoring and archiving of the system’s operating parameters. Any abnormality in any subsystem of the detector triggers a signal or alert (alarm), which alerts the user and either adapts to automatic processes or allows manual actions to reset the system to function properly.

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Implementation of Marine Environment Monitoring Data Quality Control System

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.926-930.4254 ◽

2014 ◽

Vol 926-930 ◽

pp. 4254-4257 ◽

Cited By ~ 2

Author(s):

Jin Xu ◽

Da Tao Yu ◽

Zhong Jie Yuan ◽

Bo Li ◽

Zi Zhou Xu

Keyword(s):

Quality Control ◽

Control System ◽

Data Quality ◽

Marine Environment ◽

Quality Control System ◽

Monitoring Data ◽

Environment Monitoring ◽

Data Quality Control ◽

Labor Costs ◽

Marine Environment Monitoring

Traditional artificial perception quality control methods of marine environment monitoring data have many disadvantages, including high labor costs and mistakes of data review. Based on GIS spatial analysis technology, Marine Environment Monitoring Data Quality Control System is established according to the Bohai Sea monitoring regulation. In the practical application process, it plays the role of improving efficiency of quality control, saving the manpower and financial resources. It also provides an important guarantee for the comprehensive analysis and management of marine environment data.

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Drilling Data Quality Management: Case Study With a Laboratory Scale Drilling Rig

Volume 8: Polar and Arctic Sciences and Technology; Petroleum Technology ◽

10.1115/omae2018-77510 ◽

2018 ◽

Cited By ~ 1

Author(s):

Suranga C. H. Geekiyanage ◽

Dan Sui ◽

Bernt S. Aadnoy

Keyword(s):

Decision Making ◽

Quality Improvement ◽

Control System ◽

Data Analysis ◽

Quality Management ◽

Data Quality ◽

Incomplete Data ◽

Laboratory Scale ◽

Data Quality Management ◽

Drilling Rig

Drilling industry operations heavily depend on digital information. Data analysis is a process of acquiring, transforming, interpreting, modelling, displaying and storing data with an aim of extracting useful information, so that the decision-making, actions executing, events detecting and incident managing of a system can be handled in an efficient and certain manner. This paper aims to provide an approach to understand, cleanse, improve and interpret the post-well or realtime data to preserve or enhance data features, like accuracy, consistency, reliability and validity. Data quality management is a process with three major phases. Phase I is an evaluation of pre-data quality to identify data issues such as missing or incomplete data, non-standard or invalid data and redundant data etc. Phase II is an implementation of different data quality managing practices such as filtering, data assimilation, and data reconciliation to improve data accuracy and discover useful information. The third and final phase is a post-data quality evaluation, which is conducted to assure data quality and enhance the system performance. In this study, a laboratory-scale drilling rig with a control system capable of drilling is utilized for data acquisition and quality improvement. Safe and efficient performance of such control system heavily relies on quality of the data obtained while drilling and its sufficient availability. Pump pressure, top-drive rotational speed, weight on bit, drill string torque and bit depth are available measurements. The data analysis is challenged by issues such as corruption of data due to noises, time delays, missing or incomplete data and external disturbances. In order to solve such issues, different data quality improvement practices are applied for the testing. These techniques help the intelligent system to achieve better decision-making and quicker fault detection. The study from the laboratory-scale drilling rig clearly demonstrates the need for a proper data quality management process and clear understanding of signal processing methods to carry out an intelligent digitalization in oil and gas industry.

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