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Lister, J. B.

Paper Title Page
TOPA01 Data Management at JET with a Look Forward to ITER 74
 
  • A. J. Capel, N. J. Cook, A. M. Edwards, E. M. Jones, R. A. Layne, D. C. McDonald, M. W. Wheatley, J. W. Farthing
    UKAEA Culham, Culham, Abingdon, Oxon
  • M. Greenwald
    MIT/PSFC, Cambridge, Massachusetts
  • J. B. Lister
    ITER, St Paul lez Durance
 
  Since the first JET pulse in 1983, the raw data collected per ~40s of plasma discharge (pulse) has roughly followed a Moore's Law-like doubling every 2 years. Today we collect up to ~10GB per pulse, and the total data collected over ~70,000 pulses amounts to ~35TB. Enhancements to JET should result in ~60GB per pulse being collected by 2010. An ongoing challenge is to maintain the pulse repetition rate, data access times, and data security. The mass data store provides storage, archiving, and also the data access methods. JET, like most fusion experiments, provides an MDSplus (http://www.mdsplus.org) access layer on top of its own client-server access. Although ITER will also be a pulsed experiment, the discharge will be ~300-5000s in duration. Data storage and analysis must hence be performed exclusively in real time. The ITER conceptual design proposes a continuous timeline for access to all project data. The JET mass data store will be described together with the planned upgrades required to cater for the increases in data at the end of 2009. The functional requirements for the ITER mass storage system will be described based on the current status of the ITER conceptual design.  
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ROAA01 Status of the ITER CODAC Conceptual Design 481
 
  • J. W. Farthing
    UKAEA Culham, Culham, Abingdon, Oxon
  • M. Greenwald
    MIT/PSFC, Cambridge, Massachusetts
  • I. Yonekawa
    JAEA/NAKA, Ibaraki-ken
  • J. B. Lister
    ITER, St Paul lez Durance
 
  Since the last ICALEPCS conference, a number of issues have been studied in the conceptual design of the ITER Control, Data Access, and Communication Systems. Almost all of the technical challenges have seen workable approaches selected. The conceptual design will be reviewed in 2007, before starting the preliminary engineering design. One software component that does not have a clear solution is the execution of data-driven schedules to operate the installation at multiple levels, from daily program management to plasma feedback control. Recent developments in workflow products might be useful. The present conceptual weakness is not having found a satisfactory "universal" description of the I&C design process for the "self-description" of the 100 procured Plant Systems. A vital CODAC design feature is to operate the full plant on the basis of imported “self-description” data, which necessarily includes the process description in each Plant System. The targeted formal link between 3-D design, process design, and process control has not yet been created. Some of the strawman designs meeting the technical requirements will be mentioned in detail.  
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