Author: Bell, P.J.
Paper Title Page
MOAPL02 The First Operation of the MAX IV Laboratory Synchrotron Facilities 6
 
  • V.H. Hardion, A. Barsek, P.J. Bell, F. Bolmsten, Y. Cerenius, F. H. Hennies, J.J. Jamróz, K. Larsson, J. Lidón-Simon, M. Lindberg, Z. Matej, P. Sjöblom, M. Sjöström, D.P. Spruce
    MAX IV Laboratory, Lund University, Lund, Sweden
  
  On 21st of June 2016 the MAX IV Laboratory was inaugurated in the presence of the officials and has welcome the first external researchers to the new experimental stations. The MAX IV facility is the largest and most ambitious Swedish investment in research infrastructure and designed to be one of the brightest source of X-rays worldwide. The current achievements, progress, collaborations and vision of the facility will be described from the perspective of the control and IT systems.  
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slides icon Slides MOAPL02 [91.373 MB]  
DOI • reference for this paper ※ https://doi.org/10.18429/JACoW-ICALEPCS2017-MOAPL02  
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TUPHA197 Control and Data Acquisition Using TANGO and SARDANA at the Nanomax Beamline at MAX IV 900
 
  • P.J. Bell, V.H. Hardion, J.J. Jamróz, J. Lidón-Simon
    MAX IV Laboratory, Lund University, Lund, Sweden
  
  The MAX IV synchrotron radiation facility in Lund, Sweden, received its first external commissioning users in November 2016 at the Nanomax hard X-ray beamline. All components of the beamline, including the motorisation, vacuum and diagnostic elements, were integrated into the TANGO-based control system, which through the SARDANA layer also managed the collection of diffraction and fluorescence data from one- and two-dimensional detector channels. Hardware-synchronised continuous scanning (‘‘fly-scanning'') of the sample, mounted on a piezo stage, was achieved using a system built around a standard pulse generator and acquisition board controlled by a dedicated TANGO device. SARDANA macros were used to configure and execute the continuous scanning, and position data from the piezo controller were buffered in synchronization with triggers sent to the detectors, with all data subsequently written to HDF5 files. After successful initial operation, the system is currently being revised and expanded for the users expected in 2018.  
poster icon Poster TUPHA197 [0.668 MB]  
DOI • reference for this paper ※ https://doi.org/10.18429/JACoW-ICALEPCS2017-TUPHA197  
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THPHA132 Preliminary Scanning Integration at MAX IV Beamlines 1688
 
  • J.J. Jamróz, P.J. Bell, J. Lidón-Simon, P. Sjöblom, D.P. Spruce
    MAX IV Laboratory, Lund University, Lund, Sweden
  
  Funding: MAX IV Laboratory
The MAX IV Laboratory is in a stage where beamlines are starting to welcome users that will collect data utilizing various scanning methods. This paper focuses on the different motion and synchronization techniques, hardware integration, software solutions, data acquisition and experiment supervision at MAX IV beamlines. 		 
poster icon Poster THPHA132 [0.532 MB]  
DOI • reference for this paper ※ https://doi.org/10.18429/JACoW-ICALEPCS2017-THPHA132  
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