RuPAC2014 - List of Authors (Rogovsky, Yu. A.)

Paper

Title

Page

Status and Perspectives of the VEPP-2000 Complex

6

Yu. A. Rogovsky, D.E. Berkaev, A.S. Kasaev, I. Koop, A.N. Kyrpotin, A.P. Lysenko, E. Perevedentsev, V.P. Prosvetov, A.L. Romanov, A.I. Senchenko, P.Yu. Shatunov, Y.M. Shatunov, D.B. Shwartz, A.N. Skrinsky, I.M. Zemlyansky, Yu.M. Zharinov
BINP SB RAS, Novosibirsk, Russia
Yu. A. Rogovsky
NSU, Novosibirsk, Russia

The VEPP-2000 is a modern electron-positron collider at BINP. Last season in 2012–2013 was dedicated to the energy range of 160520 MeV per beam. The application of round colliding beams concept along with the accurate orbit and lattice correction yielded the high peak luminosity of 1.21031 cm^-2s⁻¹ at 500 MeV with average luminosity of 0.91031 cm^-2s⁻¹ per run. The peak luminosity limited only by beam-beam effects, while average luminosity – by present lack of positrons in whole energy range of 1601000 MeV. To perform high luminosity at high energies with small dead time the top-up injection is needed. At present new electron and positron injection complex at BINP is commissioned and ready to feed VEPP-2000 collider with intensive beams with energy of 450 MeV. Last calendar 2014 year was dedicated to the full/partial upgrade of complex's main parts.

Slides TUY01 [4.152 MB]

THPSC27

Modernization of VEPP-2000 Control System

377

Yu. A. Rogovsky
NSU, Novosibirsk, Russia
D.E. Berkaev, O.V. Gorbatenko, A.P. Lysenko, Yu. A. Rogovsky, A.L. Romanov, A.I. Senchenko, P.Yu. Shatunov, Y.M. Shatunov
BINP SB RAS, Novosibirsk, Russia

Electron-positron collider VEPP-2000 delivered data for the high energy physics since the end of 2009. In the summer of 2013 the long shutdown was started dedicated to the deep upgrade of the wide range of subsystems. The main goal of the improvements is to reach or exceed design luminosity in the whole energy range from 200 MeV to 1000 MeV per bunch. The hardware of the accelerator complex consists of high current main field power supplies, low current power supplies for steering and multipole magnets, pulsed power supplies for channel's elements, RF subsystems, BPM and some other special subsystems (such as vacuum, temperature, etc.). The control system is based on CANbas, CAMAC and VME devices. The wide range of software corresponding to specific hardware subsystems forms complicated interacting system that manages all parts of the VEPP-2000 accelerator facility. Automation software is running on several TCP/IP connected PC platforms under operating system Linux and uses client-server techniques. The paper presents general overview and changes made in architecture, implementation and functionality of hardware and software of the VEPP-2000 collider control system.

Poster THPSC27 [7.957 MB]

FRCA01

Cooling Storage Ring CR of the FAIR Facility - Status and Perspectives

456

Yu. A. Rogovsky, D.E. Berkaev, A.S. Kasaev, E.S. Kazantseva, I. Koop, A.A. Krasnov, A.V. Semenov, P.Yu. Shatunov, D.B. Shwartz, A.A. Starostenko
BINP SB RAS, Novosibirsk, Russia
U. Blell, C. Dimopoulou, A. Dolinskyy, O.E. Gorda, U. Laier, H. Leibrock, S.A. Litvinov, I. Schurig, U. Weinrich
GSI, Darmstadt, Germany
Yu. A. Rogovsky
NSU, Novosibirsk, Russia

The Collector Ring (CR) is a wide aperture storage ring of the FAIR international facility (Darmstadt, Germany) dedicated to perform the stochastic precooling of secondary particles, rare isotopes or antiprotons. BINP (Novosibirsk) takes responsibility on the design and construction of almost all systems of the CR. The project status, preliminary design of main systems and results of the modelling of beam dynamics are presented.

Slides FRCA01 [2.060 MB]

THPSC27

Modernization of VEPP-2000 Control System

377

Yu. A. Rogovsky
NSU, Novosibirsk, Russia
D.E. Berkaev, O.V. Gorbatenko, A.P. Lysenko, Yu. A. Rogovsky, A.L. Romanov, A.I. Senchenko, P.Yu. Shatunov, Y.M. Shatunov
BINP SB RAS, Novosibirsk, Russia

Electron-positron collider VEPP-2000 delivered data for the high energy physics since the end of 2009. In the summer of 2013 the long shutdown was started dedicated to the deep upgrade of the wide range of subsystems. The main goal of the improvements is to reach or exceed design luminosity in the whole energy range from 200 MeV to 1000 MeV per bunch. The hardware of the accelerator complex consists of high current main field power supplies, low current power supplies for steering and multipole magnets, pulsed power supplies for channel's elements, RF subsystems, BPM and some other special subsystems (such as vacuum, temperature, etc.). The control system is based on CANbas, CAMAC and VME devices. The wide range of software corresponding to specific hardware subsystems forms complicated interacting system that manages all parts of the VEPP-2000 accelerator facility. Automation software is running on several TCP/IP connected PC platforms under operating system Linux and uses client-server techniques. The paper presents general overview and changes made in architecture, implementation and functionality of hardware and software of the VEPP-2000 collider control system.

Poster THPSC27 [7.957 MB]

FRCA01

Cooling Storage Ring CR of the FAIR Facility - Status and Perspectives

456

Yu. A. Rogovsky, D.E. Berkaev, A.S. Kasaev, E.S. Kazantseva, I. Koop, A.A. Krasnov, A.V. Semenov, P.Yu. Shatunov, D.B. Shwartz, A.A. Starostenko
BINP SB RAS, Novosibirsk, Russia
U. Blell, C. Dimopoulou, A. Dolinskyy, O.E. Gorda, U. Laier, H. Leibrock, S.A. Litvinov, I. Schurig, U. Weinrich
GSI, Darmstadt, Germany
Yu. A. Rogovsky
NSU, Novosibirsk, Russia

The Collector Ring (CR) is a wide aperture storage ring of the FAIR international facility (Darmstadt, Germany) dedicated to perform the stochastic precooling of secondary particles, rare isotopes or antiprotons. BINP (Novosibirsk) takes responsibility on the design and construction of almost all systems of the CR. The project status, preliminary design of main systems and results of the modelling of beam dynamics are presented.

Slides FRCA01 [2.060 MB]

Paper	Title	Page
TUY01	Status and Perspectives of the VEPP-2000 Complex	6
	Yu. A. Rogovsky, D.E. Berkaev, A.S. Kasaev, I. Koop, A.N. Kyrpotin, A.P. Lysenko, E. Perevedentsev, V.P. Prosvetov, A.L. Romanov, A.I. Senchenko, P.Yu. Shatunov, Y.M. Shatunov, D.B. Shwartz, A.N. Skrinsky, I.M. Zemlyansky, Yu.M. Zharinov BINP SB RAS, Novosibirsk, Russia Yu. A. Rogovsky NSU, Novosibirsk, Russia
	The VEPP-2000 is a modern electron-positron collider at BINP. Last season in 2012–2013 was dedicated to the energy range of 160520 MeV per beam. The application of round colliding beams concept along with the accurate orbit and lattice correction yielded the high peak luminosity of 1.21031 cm^-2s⁻¹ at 500 MeV with average luminosity of 0.91031 cm^-2s⁻¹ per run. The peak luminosity limited only by beam-beam effects, while average luminosity – by present lack of positrons in whole energy range of 1601000 MeV. To perform high luminosity at high energies with small dead time the top-up injection is needed. At present new electron and positron injection complex at BINP is commissioned and ready to feed VEPP-2000 collider with intensive beams with energy of 450 MeV. Last calendar 2014 year was dedicated to the full/partial upgrade of complex's main parts.
	Slides TUY01 [4.152 MB]

THPSC27	Modernization of VEPP-2000 Control System	377
	Yu. A. Rogovsky NSU, Novosibirsk, Russia D.E. Berkaev, O.V. Gorbatenko, A.P. Lysenko, Yu. A. Rogovsky, A.L. Romanov, A.I. Senchenko, P.Yu. Shatunov, Y.M. Shatunov BINP SB RAS, Novosibirsk, Russia
	Electron-positron collider VEPP-2000 delivered data for the high energy physics since the end of 2009. In the summer of 2013 the long shutdown was started dedicated to the deep upgrade of the wide range of subsystems. The main goal of the improvements is to reach or exceed design luminosity in the whole energy range from 200 MeV to 1000 MeV per bunch. The hardware of the accelerator complex consists of high current main field power supplies, low current power supplies for steering and multipole magnets, pulsed power supplies for channel's elements, RF subsystems, BPM and some other special subsystems (such as vacuum, temperature, etc.). The control system is based on CANbas, CAMAC and VME devices. The wide range of software corresponding to specific hardware subsystems forms complicated interacting system that manages all parts of the VEPP-2000 accelerator facility. Automation software is running on several TCP/IP connected PC platforms under operating system Linux and uses client-server techniques. The paper presents general overview and changes made in architecture, implementation and functionality of hardware and software of the VEPP-2000 collider control system.
	Poster THPSC27 [7.957 MB]

FRCA01	Cooling Storage Ring CR of the FAIR Facility - Status and Perspectives	456
	Yu. A. Rogovsky, D.E. Berkaev, A.S. Kasaev, E.S. Kazantseva, I. Koop, A.A. Krasnov, A.V. Semenov, P.Yu. Shatunov, D.B. Shwartz, A.A. Starostenko BINP SB RAS, Novosibirsk, Russia U. Blell, C. Dimopoulou, A. Dolinskyy, O.E. Gorda, U. Laier, H. Leibrock, S.A. Litvinov, I. Schurig, U. Weinrich GSI, Darmstadt, Germany Yu. A. Rogovsky NSU, Novosibirsk, Russia
	The Collector Ring (CR) is a wide aperture storage ring of the FAIR international facility (Darmstadt, Germany) dedicated to perform the stochastic precooling of secondary particles, rare isotopes or antiprotons. BINP (Novosibirsk) takes responsibility on the design and construction of almost all systems of the CR. The project status, preliminary design of main systems and results of the modelling of beam dynamics are presented.
	Slides FRCA01 [2.060 MB]

THPSC27	Modernization of VEPP-2000 Control System	377
	Yu. A. Rogovsky NSU, Novosibirsk, Russia D.E. Berkaev, O.V. Gorbatenko, A.P. Lysenko, Yu. A. Rogovsky, A.L. Romanov, A.I. Senchenko, P.Yu. Shatunov, Y.M. Shatunov BINP SB RAS, Novosibirsk, Russia
	Electron-positron collider VEPP-2000 delivered data for the high energy physics since the end of 2009. In the summer of 2013 the long shutdown was started dedicated to the deep upgrade of the wide range of subsystems. The main goal of the improvements is to reach or exceed design luminosity in the whole energy range from 200 MeV to 1000 MeV per bunch. The hardware of the accelerator complex consists of high current main field power supplies, low current power supplies for steering and multipole magnets, pulsed power supplies for channel's elements, RF subsystems, BPM and some other special subsystems (such as vacuum, temperature, etc.). The control system is based on CANbas, CAMAC and VME devices. The wide range of software corresponding to specific hardware subsystems forms complicated interacting system that manages all parts of the VEPP-2000 accelerator facility. Automation software is running on several TCP/IP connected PC platforms under operating system Linux and uses client-server techniques. The paper presents general overview and changes made in architecture, implementation and functionality of hardware and software of the VEPP-2000 collider control system.
	Poster THPSC27 [7.957 MB]

FRCA01	Cooling Storage Ring CR of the FAIR Facility - Status and Perspectives	456
	Yu. A. Rogovsky, D.E. Berkaev, A.S. Kasaev, E.S. Kazantseva, I. Koop, A.A. Krasnov, A.V. Semenov, P.Yu. Shatunov, D.B. Shwartz, A.A. Starostenko BINP SB RAS, Novosibirsk, Russia U. Blell, C. Dimopoulou, A. Dolinskyy, O.E. Gorda, U. Laier, H. Leibrock, S.A. Litvinov, I. Schurig, U. Weinrich GSI, Darmstadt, Germany Yu. A. Rogovsky NSU, Novosibirsk, Russia
	The Collector Ring (CR) is a wide aperture storage ring of the FAIR international facility (Darmstadt, Germany) dedicated to perform the stochastic precooling of secondary particles, rare isotopes or antiprotons. BINP (Novosibirsk) takes responsibility on the design and construction of almost all systems of the CR. The project status, preliminary design of main systems and results of the modelling of beam dynamics are presented.
	Slides FRCA01 [2.060 MB]