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Czuba, K.

Paper Title Page
WE5PFP073 Demonstration of an ATCA Based LLRF System at FLASH 2177
 
  • S. Simrock, M.K. Grecki, T. Jezynski, W. Koprek
    DESY, Hamburg
  • L. Butkowski, K. Czuba
    Warsaw University of Technology, Institute of Electronic Systems, Warsaw
  • G.W. Jablonski, W. Jalmuzna, D.R. Makowski, A. Piotrowski
    TUL-DMCS, Łódź
  
 

Future RF Control systems will require simultaneuous data acquisition of up to 100 fast ADC channels at sampling rates of around 100 MHz and real time signal processing within a few hundred nanoseconds. At the same time the standardization of low-level systems are common objectives for all laboratories for cost reduction, performance optimization and machine reliability. Also desirable are modularity and scalability of the design as well as compatibility with accelerator instrumentation needs including the control system. All these requirements can be fulfilled with the new telecommunication standard ATCA when adopted to the domain of instrumentation. We describe the architecture and design of an ATCA based LLRF system for the European XFEL. Initial results of the demonstration of such a system at the FLASH user facility will be presented.

  
WE5PFP102 The RF Phase Reference Distribution System Concept for the European XFEL 2255
 
  • K. Czuba, K. Antoszkiewicz
    Warsaw University of Technology, Institute of Electronic Systems, Warsaw
  • S. Simrock, H.C. Weddig
    DESY, Hamburg
  
 

One of the most important requirements for the XFEL RF system is to assure a very precise RF field stability within the accelerating cavities. The required amplitude and phase stability equals respectively dA/A <3·10-5, dphi<0.01 deg @ 1.3GHz in the injector and dA/A<10-3, dphi <0.1 deg @1.3GHz in the main linac section of the XFEL facility. Fulfilling such requirements is a very challenging task for the 1.5 km long main linac system and about 3.4 km length of the entire facility. Thousands of electronic and RF devices must be precisely phase synchronized for effective controlling of the RF field parameters. We describe the the proposed architecture of the RF Master Oscillator and the Phase Reference Distribution System for the XFEL. Design choices were based on the experience gained during the commissioning of the FLASH phase reference distribution system and on many laboratory experiments with distribution system components. Proposed system parameter analysis shows that the given requirements for the distributed signal phase stability can be fulfilled easily for the main linac section. Fulfilling the injector requirements may require using optical distribution techniques.