ICALEPCS2013 - List of Keywords (storage-ring)

Paper	Title	Other Keywords	Page
MOPPC036	The BPM Integration in the Taiwan Photon Source	booster, feedback, FPGA, electronics	158
	C.H. Kuo, Y.-T. Chang, J. Chen, Y.-S. Cheng, P.C. Chiu, K.T. Hsu, K.H. Hu, D. Lee, C.Y. Wu NSRRC, Hsinchu, Taiwan
	TPS (Taiwan Photon Source) is a 3 GeV synchrotron light source which is being in construction at NSRRC. The TPS BPM is based on xTCA platform, is used for various request and function reasons. These functions will be discussed. Another purpose is for orbit feedback system. The tradition BPM electronic is separated from orbit feedback system, is just monitor. In the TPS, the orbit feedback system is embedded in the BPM crate with FPGA modules. High throughput backplane, data transfer and processing support rich function for waveform recorder, diagnostic, beam study and transient analysis. The implementation result of the BPM system will be reported in this conference.

MOPPC109	Status of the MAX IV Laboratory Control System	controls, linac, interface, TANGO	366
	J. Lidón-Simon, V.H. Hardion, J.J. Jamroz, M. Lindberg, A.G. Persson, D.P. Spruce MAX-lab, Lund, Sweden
	The MAX IV Laboratory is a new synchrotron light source being built in Lund, south Sweden. The whole accelerator complex consists of a 3GeV 300m long full energy linac, two Storage Rings of 1.5GeV and 3GeV and a Short Pulse Facility for pump and probe experiments with bunches around 100fs long. First x-rays for the users are expected to be delivered in 2015 for the SPF and 2016 for the Storage Rings. This paper describes the progress in the design of the control system for the accelerator and the different solutions adopted for data acquisition, synchronisation, networking, safety and other aspects related to the control system
	Poster MOPPC109 [0.522 MB]

TUPPC112	GeoSynoptic Panel	database, synchrotron, radiation, synchrotron-radiation	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]

THPPC103	Timing System at MAX IV	timing, linac, gun, injection	1300
	J.J. Jamroz, V.H. Hardion, J. Lidón-Simon, L. Malmgren, A.M. Milán, A.M. Mitrovic, R. Nilsson, M. Sjöström, D.P. Spruce MAX-lab, Lund, Sweden
	The MAX IV Laboratory is the successor of the MAX-lab national laboratory in Sweden. The facility is being constructed at Brunnshög in the North Eastern part of Lund and will contain one long linac 3GeV (full energy injector), two storage rings (SR 1.5GeV and SR 3GeV) and a short pulse facility (SPF). This paper describes the design status of the timing system in 2013.
	Poster THPPC103 [7.134 MB]

THPPC110	Timing of the ALS Booster Injection and Extraction	booster, timing, injection, extraction	1318
	C. Serrano, J.M. Weber LBNL, Berkeley, California, USA
	The Advanced Light Source (ALS) timing system upgrade introduces a complete replacement of both the hardware and the technology used to drive the timing of the accelerator. The implementation of a new strategy for the booster injection and extraction mechanisms is conceptually similar to the one in place today, but fundamentally different due to the replacement of the technology. Here we describe some of the building blocks of this new implementation as well as an example of how the system can be configured to provide timing for injection and extraction of the ALS booster.
	Poster THPPC110 [0.207 MB]

THPPC137	Time Domain Simulation Software of the APS Storage Ring Orbit Real-time Feedback System	feedback, simulation, software, FPGA	1373
	H. Shang, J. Carwardine, G. Decker, L. Emery, F. Lenkszus, N. Sereno, S. Xu ANL, Argonne, USA
	The APS storage ring real-time feedback (RTFB) system will be upgraded as part of the APS Upgrade project. The time domain simulation software is implemented to find the best parameters of correctors and evaluate the performance of different system configurations. The software includes two parts: the corrector noise model generator and the RTFB simulation. The corrector noise model generates the corrector noise data that are the input for the RTFB simulation. The corrector noise data are generated from the measured APS BPM turn-by-turn noise data, so that simulation actually reproduces the real machine. This paper introduces the algorithm and high-level software development of the corrector noise model generator and the RTFB simulation. Work supported by U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences, under Contract No. DE-AC02-06CH11357.
	Poster THPPC137 [0.445 MB]

Paper

Title

Other Keywords

Page

MOPPC036

The BPM Integration in the Taiwan Photon Source

booster, feedback, FPGA, electronics

158

C.H. Kuo, Y.-T. Chang, J. Chen, Y.-S. Cheng, P.C. Chiu, K.T. Hsu, K.H. Hu, D. Lee, C.Y. Wu
NSRRC, Hsinchu, Taiwan

TPS (Taiwan Photon Source) is a 3 GeV synchrotron light source which is being in construction at NSRRC. The TPS BPM is based on xTCA platform, is used for various request and function reasons. These functions will be discussed. Another purpose is for orbit feedback system. The tradition BPM electronic is separated from orbit feedback system, is just monitor. In the TPS, the orbit feedback system is embedded in the BPM crate with FPGA modules. High throughput backplane, data transfer and processing support rich function for waveform recorder, diagnostic, beam study and transient analysis. The implementation result of the BPM system will be reported in this conference.

MOPPC109

Status of the MAX IV Laboratory Control System

controls, linac, interface, TANGO

366

J. Lidón-Simon, V.H. Hardion, J.J. Jamroz, M. Lindberg, A.G. Persson, D.P. Spruce
MAX-lab, Lund, Sweden

The MAX IV Laboratory is a new synchrotron light source being built in Lund, south Sweden. The whole accelerator complex consists of a 3GeV 300m long full energy linac, two Storage Rings of 1.5GeV and 3GeV and a Short Pulse Facility for pump and probe experiments with bunches around 100fs long. First x-rays for the users are expected to be delivered in 2015 for the SPF and 2016 for the Storage Rings. This paper describes the progress in the design of the control system for the accelerator and the different solutions adopted for data acquisition, synchronisation, networking, safety and other aspects related to the control system

Poster MOPPC109 [0.522 MB]

TUPPC112

GeoSynoptic Panel

database, synchrotron, radiation, synchrotron-radiation

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]

THPPC103

Timing System at MAX IV

timing, linac, gun, injection

1300

J.J. Jamroz, V.H. Hardion, J. Lidón-Simon, L. Malmgren, A.M. Milán, A.M. Mitrovic, R. Nilsson, M. Sjöström, D.P. Spruce
MAX-lab, Lund, Sweden

The MAX IV Laboratory is the successor of the MAX-lab national laboratory in Sweden. The facility is being constructed at Brunnshög in the North Eastern part of Lund and will contain one long linac 3GeV (full energy injector), two storage rings (SR 1.5GeV and SR 3GeV) and a short pulse facility (SPF). This paper describes the design status of the timing system in 2013.

Poster THPPC103 [7.134 MB]

THPPC110

Timing of the ALS Booster Injection and Extraction

booster, timing, injection, extraction

1318

C. Serrano, J.M. Weber
LBNL, Berkeley, California, USA

The Advanced Light Source (ALS) timing system upgrade introduces a complete replacement of both the hardware and the technology used to drive the timing of the accelerator. The implementation of a new strategy for the booster injection and extraction mechanisms is conceptually similar to the one in place today, but fundamentally different due to the replacement of the technology. Here we describe some of the building blocks of this new implementation as well as an example of how the system can be configured to provide timing for injection and extraction of the ALS booster.

Poster THPPC110 [0.207 MB]

THPPC137

Time Domain Simulation Software of the APS Storage Ring Orbit Real-time Feedback System

feedback, simulation, software, FPGA

1373

H. Shang, J. Carwardine, G. Decker, L. Emery, F. Lenkszus, N. Sereno, S. Xu
ANL, Argonne, USA

The APS storage ring real-time feedback (RTFB) system will be upgraded as part of the APS Upgrade project. The time domain simulation software is implemented to find the best parameters of correctors and evaluate the performance of different system configurations. The software includes two parts: the corrector noise model generator and the RTFB simulation. The corrector noise model generates the corrector noise data that are the input for the RTFB simulation. The corrector noise data are generated from the measured APS BPM turn-by-turn noise data, so that simulation actually reproduces the real machine. This paper introduces the algorithm and high-level software development of the corrector noise model generator and the RTFB simulation.
Work supported by U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences, under Contract No. DE-AC02-06CH11357.

Poster THPPC137 [0.445 MB]