Author: Goryl, P.P.
Paper Title Page
MOPGF179 Status of the Solaris Control System - Collaborations and Technology 510
 
  • P.P. Goryl, C.J. Bocchetta, P. Bulira, A.I. Wawrzyniak, K. Wawrzyniak, Ł. Żytniak
    Solaris, Kraków, Poland
  • V.H. Hardion, J.J. Jamróz, J. Lidón-Simon, M. Lindberg, A.G. Persson, D.P. Spruce
    MAX-lab, Lund, Sweden
  • M.J. Stankiewicz
    Solaris National Synchrotron Radiation Centre, Jagiellonian University, Kraków, Poland
  • T. Szymocha
    Cyfronet, Kraków, Poland
 
  Funding: Work supported by the European Regional Development Fund within the frame of the Innovative Economy Operational Program: POIG.02.01.00-12-213/09.
The Solaris is a synchrotron light source starting just now in Kraków, Poland. It is built with strong collaboration with other European accelerator facilities. The MAX-IV project in Lund, Sweden and Tango Community are the most important partners in the project. Solaris has built a twin copy of MAX-IV 1.5GeV ring and linear accelerator based on the same components as the ones of MAX-IV. Thus, both facilities share know-how and apply similar technologies for the control system, among them the Tango CS is used for software layer. Status of the control system in Kraków as well as collaborations and technological choices impact on its success will be presented.
 
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WEPGF145 A Structured Approach to Control System GUI Design for the Solaris Light Source 1044
 
  • V. Juvan, I. Dolin'ek, T. Humar, M. Pavleski
    Cosylab, Ljubljana, Slovenia
  • P.P. Goryl
    Solaris, Kraków, Poland
 
  In the framework of delivering control system services to the Solaris synchrotron light source, Kraków, Poland, Cosylab realized a comprehensive set of controls GUIs, using a structured approach. The goals of using this architecture are threefold. The first is to achieve reliable, predictable and consistent behaviour of the controls software. The second is that it is easy to deploy and maintain through scripting. The third is that it is future-proof by providing extensibility, using dedicated templates. The system is based on a configuration database, populated with devices, device specifics and device groups (clusters of devices performing specific operations). The GUIs are dynamically generated from this configuration. For the synoptic views, TANGO-standard JDraw and its configuration are integrated into the framework. Existing GUIs, written in PyTango can be easily adapted to function as part of this system. The compelling user benefits are high usability and life-time management through controlled upgrade and extension. For new big physics projects this GUI control program offers a customizable solution for any TANGO based control system.  
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