Presentation is loading. Please wait.

Presentation is loading. Please wait.

CHEP 2010 – TAIPEI Robert Gomez-Reino on behalf of CMS DAQ group.

Published byMartina Casey Modified over 8 years ago

Similar presentations

Presentation on theme: "CHEP 2010 – TAIPEI Robert Gomez-Reino on behalf of CMS DAQ group."— Presentation transcript:

1 CHEP 2010 – TAIPEI Robert Gomez-Reino on behalf of CMS DAQ group

2 the Compact Muon Solenoid A multi-purpose Large Hadron Collider experiment The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

3  Ensure safe detector operation  anticipating the Detector Safety System (DSS) actions, triggering protection mechanisms on adverse conditions (high temperatures, high humidity, overcurrents, water leaks, electrical trips…)  preventing potentially dangerous actions  issuing alert notifications (alert screen, SMS, control room voice alerts)  Provide efficient detector operation  making sure that voltages are present whenever the accelerator conditions allow for physics data taking  guaranteeing that the controlled parameters are stable within their calibrated operating ranges Responsibilities & Requirements A non sleeping 24hr/day 365d/year running system The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

4 Control system size ~ 10 6 control system parameters The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

5 Design & Implementation Control system blocks The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

6 Design & Implementation The control tree structure (based on SMI++) The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

7 Infrastructure overview Computing resources, functionality and software life cycle The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

8 Infrastructure overview Development environment The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

9 Infrastructure overview Computing resources management The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

10 Infrastructure overview Production environment The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

11  Using CMS design and implementation guidelines CMS achieved a complete sub-detector control system integration  The control system homogeneity achieved allows for common functional components (warning notification system, performance monitoring, protection mechanism...)  A central supervisor governs the sub-detector operation allowing for automated actions Control system integration The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

12 Control system automation Driven by LHC status The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei LHC THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK CMS Detector readiness BEAM MODE: NO BEAM MACHINE MODE: ACCESS

13 Automation matrix Automatic commands and protection interlocks The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK Detector readiness LHC CMS BEAM MODE: SETUP MACHINE MODE: PROTON PHYSICS

14 LHC-CMS handshake CMS prepares for injection The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK Detector readiness LHC CMS BEAM MODE: SETUP MACHINE MODE: PROTON PHYSICS INJECTION REQUEST!

15 LHC-CMS handshake CMS is ready for injection The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK Detector readiness LHC CMS BEAM MODE: INJECTION PROBE BEAM MACHINE MODE: PROTON PHYSICS INJECTION REQUEST REPLY

16 THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei Detector readiness LHC CMS BEAM MODE: FLAT TOP MACHINE MODE: PROTON PHYSICS Automation matrix

17 THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei Detector readiness LHC CMS BEAM MODE: STABLE BEAMS MACHINE MODE: PROTON PHYSICS Automation matrix CMS ready for data taking

18 Main supervisor panel The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

19 Main supervisor panel The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

20 Main supervisor panel The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

21 Main supervisor panel The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

22 Main supervisor panel The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

23 The alert screen Where all the detector problems are reflected The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

24  Avoid alarm flooding  Summary alerts  Hierarchical alarm reduction  Provide useful instructions for alerts  Alert help expert database  Web interface for entering alert help by detector experts  Web interface connected to the control room to offer help to the operator for each alert  Incremental alert help definition The alert screen Making its use efficient The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

25  Today  Distributed control system with no redundant peers  Infrastructure for fast recovery (<1h)  Future  Redundant distributed control system with peers running in virtual machines on different servers and different racks  No interruptions Redundant control system Maximizing reliability The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei THE EXPERIMENTDCS OVERVIEWAUTOMATION OPERATIONONGOING WORK

26  A robust system architecture proving to ensure the detector protection anticipating the safety system in most of the cases  Efficient detector operation achieved automating the detector operation. Efficiency > 99%  A reliable system requiring practically no expert interventions  A high system homogeneity easing the maintenance  An intuitive control room interface allowing a single non expert operator to supervise the whole experiment control system  A computing resources management infrastructure allowing for system recovery (but ongoing work to eliminate down time!) Summary The Compact Muon Solenoid detector control system - Robert Gomez-Reino - CHEP 2010, Taipei

Download ppt "CHEP 2010 – TAIPEI Robert Gomez-Reino on behalf of CMS DAQ group."

Similar presentations

André Augustinus 15 March 2003 DCS Workshop Safety Interlocks.

André Augustinus 15 March 2003 DCS Workshop Safety Interlocks.
The Control System for the ATLAS Pixel Detector

The Control System for the ATLAS Pixel Detector
CWG10 Control, Configuration and Monitoring Status and plans for Control, Configuration and Monitoring 16 December 2014 ALICE O 2 Asian Workshop

CWG10 Control, Configuration and Monitoring Status and plans for Control, Configuration and Monitoring 16 December 2014 ALICE O 2 Asian Workshop
André Augustinus 16 June 2003 DCS Workshop Safety.

André Augustinus 16 June 2003 DCS Workshop Safety.
Slow Control LHCf Catania Meeting - July 04-06, 2009 Lorenzo Bonechi.

Slow Control LHCf Catania Meeting - July 04-06, 2009 Lorenzo Bonechi.
June 2010 At A Glance The Room Alert Adapter software in conjunction with AVTECH Room Alert™ devices assists in monitoring computer room environments as.

June 2010 At A Glance The Room Alert Adapter software in conjunction with AVTECH Room Alert™ devices assists in monitoring computer room environments as.
André Augustinus ALICE Detector Control System  ALICE DCS is responsible for safe, stable and efficient operation of the experiment  Central monitoring.

André Augustinus ALICE Detector Control System  ALICE DCS is responsible for safe, stable and efficient operation of the experiment  Central monitoring.
Safe Machine Parameters General Machine Timing Cross-Check Safe Machine Parameters General Machine Timing Cross-Check 9 th May 2012 - 0v3.

Safe Machine Parameters General Machine Timing Cross-Check Safe Machine Parameters General Machine Timing Cross-Check 9 th May v3.
Clara Gaspar, May 2010 The LHCb Run Control System An Integrated and Homogeneous Control System.

Clara Gaspar, May 2010 The LHCb Run Control System An Integrated and Homogeneous Control System.
Brookhaven Science Associates U.S. Department of Energy 1 The New Alarm Display Software for the RHIC Control Room Peter F. Ingrassia Main Control Room.

Brookhaven Science Associates U.S. Department of Energy 1 The New Alarm Display Software for the RHIC Control Room Peter F. Ingrassia Main Control Room.
DCS LEB Workshop ‘98, Rome, Detector Control System, H.J.Burckhart,1 Detector Control System H.J Burckhart, CERN u Motivation and Scope u Detector and.

DCS LEB Workshop ‘98, Rome, Detector Control System, H.J.Burckhart,1 Detector Control System H.J Burckhart, CERN u Motivation and Scope u Detector and.
1 CALO DCS power supply status CALO meeting 28.04.2009 Anatoli Konoplyannikov [ITEP / LAPP] Outline  Introduction  Power supply description with hardware.

1 CALO DCS power supply status CALO meeting Anatoli Konoplyannikov [ITEP / LAPP] Outline  Introduction  Power supply description with hardware.
CERN Machine Protection – A Future Safety System? Introduction 1 SMP = Safe Machine Parameters System which receives accelerator.

CERN Machine Protection – A Future Safety System? Introduction 1 SMP = Safe Machine Parameters System which receives accelerator.
The Detector Safety System for LHC Experiments Stefan Lüders ― CERN EP/SFT & IT/CO CHEP03 ― UC San Diego ― March 27 th, 2003.

The Detector Safety System for LHC Experiments Stefan Lüders ― CERN EP/SFT & IT/CO CHEP03 ― UC San Diego ― March 27 th, 2003.
All content in this presentation is protected – © 2008 American Power Conversion Corporation Symmetra ® LX – redundant UPS High performance, redundant.

All content in this presentation is protected – © 2008 American Power Conversion Corporation Symmetra ® LX – redundant UPS High performance, redundant.
GV-Control Center Overview

GV-Control Center Overview
An Introduction to AlarmInsight

An Introduction to AlarmInsight
Robert Gomez-Reino on behalf of PH-CMD CERN group.

Robert Gomez-Reino on behalf of PH-CMD CERN group.
20120314Calo Piquet Training Session - Xvc1 ECS Overview Piquet Training Session Cuvée 2012 Xavier Vilasis.

Calo Piquet Training Session - Xvc1 ECS Overview Piquet Training Session Cuvée 2012 Xavier Vilasis.
Designing a HEP Experiment Control System, Lessons to be Learned From 10 Years Evolution and Operation of the DELPHI Experiment. André Augustinus 8 February.

Designing a HEP Experiment Control System, Lessons to be Learned From 10 Years Evolution and Operation of the DELPHI Experiment. André Augustinus 8 February.

Similar presentations

Ads by Google