Author: Sugimoto, T.
Paper Title Page
MOPMN025 New SPring-8 Control Room: Towards Unified Operation with SACLA and SPring-8 II Era. 296
 
  • A. Yamashita, R. Fujihara, N. Hosoda, Y. Ishizawa, H. Kimura, T. Masuda, C. Saji, T. Sugimoto, S. Suzuki, M. Takao, R. Tanaka
    JASRI/SPring-8, Hyogo-ken, Japan
  • T. Fukui, Y. Otake
    RIKEN/SPring-8, Hyogo, Japan
 
  We have renovated the SPring-8 control room. This is the first major renovation since its inauguration in 1997. In 2011, the construction of SACLA (SPring-8 Angstrom Compact Laser Accelerator) was completed and it is planned to be controlled from the new control room for close cooperative operation with the SPring-8 storage ring. It is expected that another SPring-8 II project will require more workstations than the current control room. We have extended the control room area for these foreseen projects. In this renovation we have employed new technology which did not exist 14 years ago, such as a large LCD and silent liquid cooling workstations for comfortable operation environment. We have incorporated many ideas which were obtained during the 14 years experience of the design. The operation in the new control room began in April 2011 after a short period of the construction.  
 
TUCAUST06 Event-Synchronized Data Acquisition System of 5 Giga-bps Data Rate for User Experiment at the XFEL Facility, SACLA 581
 
  • M. Yamaga, A. Amselem, T. Hirono, Y. Joti, A. Kiyomichi, T. Ohata, T. Sugimoto, R. Tanaka
    JASRI/SPring-8, Hyogo-ken, Japan
  • T. Hatsui
    RIKEN/SPring-8, Hyogo, Japan
 
  A data acquisition (DAQ), control, and storage system has been developed for user experiments at the XFEL facility, SACLA, in the SPring-8 site. The anticipated experiments demand shot-by-shot DAQ in synchronization with the beam operation cycle in order to correlate the beam characteristics, and recorded data such as X-ray diffraction pattern. The experiments produce waveform or image data, of which the data size ranges from 8 up to 48 M byte for each x-ray pulse at 60 Hz. To meet these requirements, we have constructed a DAQ system that is operated in synchronization with the 60Hz of beam operation cycle. The system is designed to handle up to 5 Gbps data rate after compression, and consists of the trigger distributor/counters, the data-filling computers, the parallel-writing high-speed data storage, and the relational database. The data rate is reduced by on-the-fly data compression through front-end embedded systems. The self-described data structure enables to handle any type of data. The pipeline data-buffer at each computer node ensures integrity of the data transfer with the non-real-time operating systems, and reduces the development cost. All the data are transmitted via TCP/IP protocol over GbE and 10GbE Ethernet. To monitor the experimental status, the system incorporates with on-line visualization of waveform/images as well as prompt data mining by 10 PFlops scale supercomputer to check the data health. Partial system for the light source commissioning was released in March 2011. Full system will be released to public users in March 2012.  
slides icon Slides TUCAUST06 [3.248 MB]  
 
WEBHAUST03 Large-bandwidth Data Acquisition Network for XFEL Facility, SACLA 626
 
  • T. Sugimoto, Y. Joti, T. Ohata, R. Tanaka, M. Yamaga
    JASRI/SPring-8, Hyogo-ken, Japan
  • T. Hatsui
    RIKEN/SPring-8, Hyogo, Japan
 
  We have developed a large-bandwidth data acquisition (DAQ) network for user experiments at the SPring-8 Angstrom Compact Free Electron Laser (SACLA) facility. The network connects detectors, on-line visualization terminals and a high-speed storage of the control and DAQ system to transfer beam diagnostic data of each X-ray pulse as well as the experimental data. The development of DAQ network system (DAQ-LAN) was one of the critical elements in the system development because the data with transfer rate reaching 5 Gbps should be stored and visualized with high availability. DAQ-LAN is also used for instrument control. In order to guarantee the operation of both the high-speed data transfer and instrument control, we have implemented physical and logical network system. The DAQ-LAN currently consists of six 10-GbE capable network switches exclusively used for the data transfer, and ten 1-GbE capable network switches for instrument control and on-line visualization. High-availability was achieved by link aggregation (LAG) with typical convergence time of 500 ms, which is faster than RSTP (2 sec.). To prevent network trouble caused by broadcast, DAQ-LAN is logically separated into twelve network segments. Logical network segmentation are based on DAQ applications such as data transfer, on-line visualization, and instrument control. The DAQ-LAN will connect the control and DAQ system to the on-site high performance computing system, and to the next-generation super computers in Japan including K-computer for instant data mining during the beamtime, and post analysis.  
slides icon Slides WEBHAUST03 [5.795 MB]  
 
TUDAUST01 Inauguration of the XFEL Facility, SACLA, in SPring-8 585
 
  • R. Tanaka, Y. Furukawa, T. Hirono, M. Ishii, M. Kago, A. Kiyomichi, T. Masuda, T. Matsumoto, T. Matsushita, T. Ohata, C. Saji, T. Sugimoto, M. Yamaga, A. Yamashita
    JASRI/SPring-8, Hyogo-ken, Japan
  • T. Fukui, T. Hatsui, N. Hosoda, H. Maesaka, T. Ohshima, T. Otake, Y. Otake, H. Takebe
    RIKEN/SPring-8, Hyogo, Japan
 
  The construction of the X-ray free electron laser facility (SACLA) in SPring-8 started in 2006. After 5 years of construction, the facility completed to accelerate electron beams in February 2011. The main component of the accelerator consists of 64 C-band RF units to accelerate beams up to 8GeV. The beam shape is compressed to a length of 30fs, and the beams are introduced into the 18 insertion devices to generate 0.1nm X-ray laser. The first SASE X-ray was observed after the beam commissioning. The beam tuning will continue to achieve X-ray laser saturation for frontier scientific experiments. The control system adopts the 3-tier standard model by using MADOCA framework developed in SPring-8. The upper control layer consists of Linux PCs for operator consoles, Sybase RDBMS for data logging and FC-based NAS for NFS. The lower consists of 100 Solaris-operated VME systems with newly developed boards for RF waveform processing, and the PLC is used for slow control. The Device-net is adopted for the frontend devices to reduce signal cables. The VME systems have a beam-synchronized data-taking link to meet 60Hz beam operation for the beam tuning diagnostics. The accelerator control has gateways to the facility utility system not only to monitor devices but also to control the tuning points of the cooling water. The data acquisition system for the experiments is challenging. The data rate coming from 2D multiport CCD is 3.4Gbps that produces 30TB image data in a day. A sampled data will be transferred to the 10PFlops supercomputer via 10Gbps Ethernet for data evaluation.  
slides icon Slides TUDAUST01 [5.427 MB]