ICALEPCS2013 - List of Keywords (synchrotron-radiation)

Paper	Title	Other Keywords	Page
MOPPC020	New Automated Control System at Kurchatov Synchrotron Radiation Source Based on SCADA System Citect	controls, synchrotron, electron, radiation	97
	Y.A. Fomin, V. Dombrovsky, Y.V. Efimov, E.V. Kaportsev, V. Korchuganov, Y.V. Krylov, K. Moseev, N.I. Moseiko, A.G. Valentinov NRC, Moscow, Russia A. Dorovatovsky, L.A. Moseiko RRC, Moscow, Russia
	The description of new automated control system of Kurchatov synchrotron radiation source which is realized at present time is presented in the paper. The necessity of automated control system modernization is explained by the equipment replacement in which we take state of art hardware decisions for facility control and increase the performances of facility control system. In particular, the number of control channels are increase, the processing and transmitting data speed are considerably increase and the requirements to measurement accuracy are become more strict. The paper presents the detailed description of all control levels (lower, server and upper) of new automated control system and integration of SCADA-system Citect into facility control system which provides the facility control, alarms notify, detailed reports preparation, acquisition and storage of historical data et al.

MOPPC107	RF-Generators Control Tools for Kurchatov Synchrotron Radiation Source	controls, synchrotron, electron, radiation	359
	Y.V. Krylov RRC, Moscow, Russia Y.V. Efimov, Y.A. Fomin, E.V. Kaportsev, D. V. Konyakhin, K. Moseev, N.I. Moseiko, A. Vernov NRC, Moscow, Russia
	Now the technology equipment of the Kurchatov Synchrotron Radiation Source (KSRS) is upgraded. At the same time, new equipment and software solutions for the control system are implemented. The KSRS main ring is the electron synchrotron with two 181 MHz RF-generators, their control system provides measurement of parameters of generation, regulation of tuning elements in wave guides and resonators, output of alarm messages. At the execution level the VME standard equipment is used. Server level is supported by Citect SCADA and the SQL historian server. The operator level of control system is implemented, as a PC local network. It allowed to expand number of measuring channels, to increase speed of processing and data transfers, to have on demand historical data with the big frequency of inquiry, and also to improve the accuracy of measurements. In article the control system structure by KSRS RF-generators, including the description of all levels of control is provided. Examples of implementation of the operator interface are given.
	Poster MOPPC107 [1.671 MB]

TUMIB02	A Control System for the ESRF Synchrotron Radiation Therapy Clinical Trials	controls, synchrotron, software, radiation	521
	C. Nemoz, P. Berkvens, G. Berruyer, T. Brochard, H. Gonzalez, R. Hino, M. Renier ESRF, Grenoble, France J.F. Adam Université Joseph Fourier, Saint Martin d'Hères, France H. Elleaume INSERM, Grenoble Institut des Neurosciences, La Tronche, France
	The bio-medical beamline of the European Synchrotron Radiation Facility (ESRF) located in Grenoble, France, has recently started the Phase I-II Stereotactic Synchrotron Radiation Therapy (SSRT) clinical trials targeting brain tumours. This very first SSRT protocol consists in a combined therapy where monochromatic X-rays are delivered to the tumour pre-loaded with high Z element. The challenges of this technique are the accurate positioning of the target tumour with respect to the beam and the precision of the dose delivery whilst fully assuring the patient safety. The positioning system used for previous angiography clinical trials has been adapted to this new modality. 3-D imaging is performed for positioning purpose to fit to the treatment planning. The control system of this experiment will be described from the hardware and software point of view with emphasis on the constraints imposed by the Patient Safety System.
	Slides TUMIB02 [0.839 MB]

TUPPC112	GeoSynoptic Panel	database, synchrotron, radiation, storage-ring	840
	Ł. Żytniak, C.J. Bocchetta, P.P. Goryl, P. Pamula, A.I. Wawrzyniak, M. Zając Solaris, Kraków, Poland V.H. Hardion, D.P. Spruce MAX-lab, Lund, Sweden
	Funding: Synchrotron Radiation Centre SOLARIS at Jagiellonian University ul. Gronostajowa 7/P-1.6 30-387 Kraków Poland Solaris is a third generation Polish Synchrotron under construction at the Jagiellonian University in Kraków. Furthermore, National Synchrotron Radiation Center is member of the Tango Collaboration. The project is based on the 1.5 GeV storage ring being at the simultaneously built for the MAX IV project in Lund, Sweden. The Solaris project is a prime example of the benefits of use EU regional development funds and sharing of knowledge and resources for the rapid establishment of a national research infrastructure. The Solaris develops highly customizable and adaptable application called the GeoSynoptic Panel. Main goal of the GeoSynoptic Panel is to provide a graphical map of devices based on information stored in the Tango database. It is achieved by providing additional device/class properties which describe location and graphical components (such as icons and particular GUI window) related to a particular device or class . The application is expected to reduce time needed for preparation of synoptic applications for each individual (part of) machines or subsystems and to reduce effort related to debugging and change management.
	Poster TUPPC112 [19.249 MB]

THCOAAB04	Synchrobots: Experiments with Telepresence and Teleoperated Mobile Robots in a Synchrotron Radiation Facility	controls, radiation, synchrotron, experiment	1052
	M. Pugliese, F. Billè, R. Borghes, A. Curri, D. Favretto, G. Kourousias, M. Prica, M. Turcinovich Elettra-Sincrotrone Trieste S.C.p.A., Basovizza, Italy
	Synchrobot is an autonomous mobile robot that supports the machine operators of Elettra (), a synchrotron radiation facility, in tasks such as diagnostic and measurement campaigns being capable of moving in the restricted area when the machine is running. In general, telepresence robots are mobile robot platforms capable of providing two way audio and video communication. Recently many companies are entering the business of telepresence robots. This paper describes our experience with tools like synchrobot and also commercially available telepresence robots. Based on our experience, we present a set of guidelines for using and integrating telepresence robots in the daily life of a research infrastructure and explore potential future development scenarios. http://www.elettra.eu*
	Slides THCOAAB04 [9.348 MB]

THPPC049	The Power Supply System for Electron Beam Orbit Correctors and Focusing Lenses of Kurchatov Synchrotron Radiation Source	controls, power-supply, operation, synchrotron	1180
	N.I. Moseiko, Y.V. Efimov, V. Korchuganov, V.V. Kordhikov, S.G. Pesterev, A.G. Valentinov NRC, Moscow, Russia I.V. Akimenkov, A.F. Shamarin Marathon Ltd., Moscow, Russia A.S. Chepurnov, A.S. Nikolaev MSU SINP, Moscow, Russia I.V. Gribov MSU, Moscow, Russia Y.V. Krylov, L.A. Moseiko RRC, Moscow, Russia
	The modernization project of the low-current power supply system of Kurchatov Synchrotron Radiation Source has been designed and is under implementation now. It includes transition to the new power suppliers to feed electron beam orbit correctors and focusing lenses. Multi-level control system, based on CAN/CANopen fieldbus, has been developed for specific accelerator applications, which allows startup and continuous run of hundreds of power supplies together with the other subsystems of the accelerator. The power sources data and status are collected into the archive with the Citect SCADA 7.2 Server SCADA Historian Server. The following operational parameters of the system are expected: current control resolution - 0.05% of IMAX; current stability - 5*10^-4 ; 10 hours current variance - 100 ppm of IMAX ; temperature drift - 40ppm/K of IMAX.

Paper

Title

Other Keywords

Page

MOPPC020

New Automated Control System at Kurchatov Synchrotron Radiation Source Based on SCADA System Citect

controls, synchrotron, electron, radiation

97

Y.A. Fomin, V. Dombrovsky, Y.V. Efimov, E.V. Kaportsev, V. Korchuganov, Y.V. Krylov, K. Moseev, N.I. Moseiko, A.G. Valentinov
NRC, Moscow, Russia
A. Dorovatovsky, L.A. Moseiko
RRC, Moscow, Russia

The description of new automated control system of Kurchatov synchrotron radiation source which is realized at present time is presented in the paper. The necessity of automated control system modernization is explained by the equipment replacement in which we take state of art hardware decisions for facility control and increase the performances of facility control system. In particular, the number of control channels are increase, the processing and transmitting data speed are considerably increase and the requirements to measurement accuracy are become more strict. The paper presents the detailed description of all control levels (lower, server and upper) of new automated control system and integration of SCADA-system Citect into facility control system which provides the facility control, alarms notify, detailed reports preparation, acquisition and storage of historical data et al.

MOPPC107

RF-Generators Control Tools for Kurchatov Synchrotron Radiation Source

controls, synchrotron, electron, radiation

359

Y.V. Krylov
RRC, Moscow, Russia
Y.V. Efimov, Y.A. Fomin, E.V. Kaportsev, D. V. Konyakhin, K. Moseev, N.I. Moseiko, A. Vernov
NRC, Moscow, Russia

Now the technology equipment of the Kurchatov Synchrotron Radiation Source (KSRS) is upgraded. At the same time, new equipment and software solutions for the control system are implemented. The KSRS main ring is the electron synchrotron with two 181 MHz RF-generators, their control system provides measurement of parameters of generation, regulation of tuning elements in wave guides and resonators, output of alarm messages. At the execution level the VME standard equipment is used. Server level is supported by Citect SCADA and the SQL historian server. The operator level of control system is implemented, as a PC local network. It allowed to expand number of measuring channels, to increase speed of processing and data transfers, to have on demand historical data with the big frequency of inquiry, and also to improve the accuracy of measurements. In article the control system structure by KSRS RF-generators, including the description of all levels of control is provided. Examples of implementation of the operator interface are given.

Poster MOPPC107 [1.671 MB]

TUMIB02

A Control System for the ESRF Synchrotron Radiation Therapy Clinical Trials

controls, synchrotron, software, radiation

521

C. Nemoz, P. Berkvens, G. Berruyer, T. Brochard, H. Gonzalez, R. Hino, M. Renier
ESRF, Grenoble, France
J.F. Adam
Université Joseph Fourier, Saint Martin d'Hères, France
H. Elleaume
INSERM, Grenoble Institut des Neurosciences, La Tronche, France

The bio-medical beamline of the European Synchrotron Radiation Facility (ESRF) located in Grenoble, France, has recently started the Phase I-II Stereotactic Synchrotron Radiation Therapy (SSRT) clinical trials targeting brain tumours. This very first SSRT protocol consists in a combined therapy where monochromatic X-rays are delivered to the tumour pre-loaded with high Z element. The challenges of this technique are the accurate positioning of the target tumour with respect to the beam and the precision of the dose delivery whilst fully assuring the patient safety. The positioning system used for previous angiography clinical trials has been adapted to this new modality. 3-D imaging is performed for positioning purpose to fit to the treatment planning. The control system of this experiment will be described from the hardware and software point of view with emphasis on the constraints imposed by the Patient Safety System.

Slides TUMIB02 [0.839 MB]

TUPPC112

GeoSynoptic Panel

database, synchrotron, radiation, storage-ring

840

Ł. Żytniak, C.J. Bocchetta, P.P. Goryl, P. Pamula, A.I. Wawrzyniak, M. Zając
Solaris, Kraków, Poland
V.H. Hardion, D.P. Spruce
MAX-lab, Lund, Sweden

Funding: Synchrotron Radiation Centre SOLARIS at Jagiellonian University ul. Gronostajowa 7/P-1.6 30-387 Kraków Poland
Solaris is a third generation Polish Synchrotron under construction at the Jagiellonian University in Kraków. Furthermore, National Synchrotron Radiation Center is member of the Tango Collaboration. The project is based on the 1.5 GeV storage ring being at the simultaneously built for the MAX IV project in Lund, Sweden. The Solaris project is a prime example of the benefits of use EU regional development funds and sharing of knowledge and resources for the rapid establishment of a national research infrastructure. The Solaris develops highly customizable and adaptable application called the GeoSynoptic Panel. Main goal of the GeoSynoptic Panel is to provide a graphical map of devices based on information stored in the Tango database. It is achieved by providing additional device/class properties which describe location and graphical components (such as icons and particular GUI window) related to a particular device or class . The application is expected to reduce time needed for preparation of synoptic applications for each individual (part of) machines or subsystems and to reduce effort related to debugging and change management.

Poster TUPPC112 [19.249 MB]

THCOAAB04

Synchrobots: Experiments with Telepresence and Teleoperated Mobile Robots in a Synchrotron Radiation Facility

controls, radiation, synchrotron, experiment

1052

M. Pugliese, F. Billè, R. Borghes, A. Curri, D. Favretto, G. Kourousias, M. Prica, M. Turcinovich
Elettra-Sincrotrone Trieste S.C.p.A., Basovizza, Italy

Synchrobot is an autonomous mobile robot that supports the machine operators of Elettra (*), a synchrotron radiation facility, in tasks such as diagnostic and measurement campaigns being capable of moving in the restricted area when the machine is running. In general, telepresence robots are mobile robot platforms capable of providing two way audio and video communication. Recently many companies are entering the business of telepresence robots. This paper describes our experience with tools like synchrobot and also commercially available telepresence robots. Based on our experience, we present a set of guidelines for using and integrating telepresence robots in the daily life of a research infrastructure and explore potential future development scenarios.
http://www.elettra.eu

Slides THCOAAB04 [9.348 MB]

THPPC049

The Power Supply System for Electron Beam Orbit Correctors and Focusing Lenses of Kurchatov Synchrotron Radiation Source

controls, power-supply, operation, synchrotron

1180

N.I. Moseiko, Y.V. Efimov, V. Korchuganov, V.V. Kordhikov, S.G. Pesterev, A.G. Valentinov
NRC, Moscow, Russia
I.V. Akimenkov, A.F. Shamarin
Marathon Ltd., Moscow, Russia
A.S. Chepurnov, A.S. Nikolaev
MSU SINP, Moscow, Russia
I.V. Gribov
MSU, Moscow, Russia
Y.V. Krylov, L.A. Moseiko
RRC, Moscow, Russia

The modernization project of the low-current power supply system of Kurchatov Synchrotron Radiation Source has been designed and is under implementation now. It includes transition to the new power suppliers to feed electron beam orbit correctors and focusing lenses. Multi-level control system, based on CAN/CANopen fieldbus, has been developed for specific accelerator applications, which allows startup and continuous run of hundreds of power supplies together with the other subsystems of the accelerator. The power sources data and status are collected into the archive with the Citect SCADA 7.2 Server SCADA Historian Server. The following operational parameters of the system are expected: current control resolution - 0.05% of IMAX; current stability - 5*10^-4 ; 10 hours current variance - 100 ppm of IMAX ; temperature drift - 40ppm/K of IMAX.