ICALEPCS2013 - List of Authors (Franz, S.)

Paper

Title

Page

A Movement Control System for Roman Pots at the LHC

115

B. Farnham, O.O. Andreassen, I. Atanassov, J. Baechler, B. Copy, M. Deile, M. Dutour, P. Fassnacht, S. Franz, S. Jakobsen, F. Lucas Rodríguez, X. Pons, E. Radermacher, S. Ravat, F. Ravotti, S. Redaelli
CERN, Geneva, Switzerland
K.H. Hiller
DESY Zeuthen, Zeuthen, Germany

This paper describes the movement control system for detector positioning based on the Roman Pot design used by the ATLAS-ALFA and TOTEM experiments at the LHC. A key system requirement is that LHC machine protection rules are obeyed: the position is surveyed every 20ms with an accuracy of 15?m. If the detectors move too close to the beam (outside limits set by LHC Operators) the LHC interlock system is triggered to dump the beam. LHC Operators in the CERN Control Centre (CCC) drive the system via an HMI provided by a custom built Java application which uses Common Middleware (CMW) to interact with lower level components. Low-level motorization control is executed using National Instruments PXI devices. The DIM protocol provides the software interface to the PXI layer. A FESA gateway server provides a communication bridge between CMW and DIM. A cut down laboratory version of the system was built to provide a platform for verifying the integrity of the full chain, with respect to user and machine protection requirements, and validating new functionality before deploying to the LHC. The paper contains a detailed system description, test bench results and foreseen system improvements.

MOPPC032

OPC Unified Architecture within the Control System of the ATLAS Experiment

143

P.P. Nikiel, B. Farnham, S. Franz, S. Schlenker
CERN, Geneva, Switzerland
H. Boterenbrood
NIKHEF, Amsterdam, The Netherlands
V. Filimonov
PNPI, Gatchina, Leningrad District, Russia

The Detector Control System (DCS) of the ATLAS experiment at the LHC has been using the OPC DA standard as interface for controlling various standard and custom hardware components and their integration into the SCADA layer. Due to its platform restrictions and expiring long-term support, OPC DA will be replaced by the succeeding OPC Unified Architecture (UA) standard. OPC UA offers powerful object-oriented information modeling capabilities, platform independence, secure communication and allows server embedding into custom electronics. We present an OPC UA server implementation for CANopen devices which is used in the ATLAS DCS to control dedicated IO boards distributed within and outside the detector. Architecture and server configuration aspects are detailed and the server performance is evaluated and compared with the previous OPC DA server. Furthermore, based on the experience with the first server implementation, OPC UA is evaluated as standard middleware solution for future use in the ATLAS DCS and beyond.

Poster MOPPC032 [2.923 MB]

Paper	Title	Page
MOPPC025	A Movement Control System for Roman Pots at the LHC	115
	B. Farnham, O.O. Andreassen, I. Atanassov, J. Baechler, B. Copy, M. Deile, M. Dutour, P. Fassnacht, S. Franz, S. Jakobsen, F. Lucas Rodríguez, X. Pons, E. Radermacher, S. Ravat, F. Ravotti, S. Redaelli CERN, Geneva, Switzerland K.H. Hiller DESY Zeuthen, Zeuthen, Germany
	This paper describes the movement control system for detector positioning based on the Roman Pot design used by the ATLAS-ALFA and TOTEM experiments at the LHC. A key system requirement is that LHC machine protection rules are obeyed: the position is surveyed every 20ms with an accuracy of 15?m. If the detectors move too close to the beam (outside limits set by LHC Operators) the LHC interlock system is triggered to dump the beam. LHC Operators in the CERN Control Centre (CCC) drive the system via an HMI provided by a custom built Java application which uses Common Middleware (CMW) to interact with lower level components. Low-level motorization control is executed using National Instruments PXI devices. The DIM protocol provides the software interface to the PXI layer. A FESA gateway server provides a communication bridge between CMW and DIM. A cut down laboratory version of the system was built to provide a platform for verifying the integrity of the full chain, with respect to user and machine protection requirements, and validating new functionality before deploying to the LHC. The paper contains a detailed system description, test bench results and foreseen system improvements.

MOPPC032	OPC Unified Architecture within the Control System of the ATLAS Experiment	143
	P.P. Nikiel, B. Farnham, S. Franz, S. Schlenker CERN, Geneva, Switzerland H. Boterenbrood NIKHEF, Amsterdam, The Netherlands V. Filimonov PNPI, Gatchina, Leningrad District, Russia
	The Detector Control System (DCS) of the ATLAS experiment at the LHC has been using the OPC DA standard as interface for controlling various standard and custom hardware components and their integration into the SCADA layer. Due to its platform restrictions and expiring long-term support, OPC DA will be replaced by the succeeding OPC Unified Architecture (UA) standard. OPC UA offers powerful object-oriented information modeling capabilities, platform independence, secure communication and allows server embedding into custom electronics. We present an OPC UA server implementation for CANopen devices which is used in the ATLAS DCS to control dedicated IO boards distributed within and outside the detector. Architecture and server configuration aspects are detailed and the server performance is evaluated and compared with the previous OPC DA server. Furthermore, based on the experience with the first server implementation, OPC UA is evaluated as standard middleware solution for future use in the ATLAS DCS and beyond.
	Poster MOPPC032 [2.923 MB]