• DocumentCode
    2889470
  • Title

    Simulation of ILC feedback bpm signals in an intense background environment

  • Author

    Hartin, A. ; Burrows, P. ; Christian, G. ; Clarke, C. ; Constance, B. ; Khan, Haidar ; Perry, C. ; Swinson, C. ; Arnold, R. ; Molloy, S. ; Smith, S. ; White, G. ; Woods, M. ; Kalinin, A.

  • Author_Institution
    Oxford Univ. Phys., Oxford
  • fYear
    2007
  • fDate
    25-29 June 2007
  • Firstpage
    2889
  • Lastpage
    2891
  • Abstract
    Experiment T-488 at SLAC, End station A recorded distorted BPM voltage signals and an accurate simulation of these signals was performed. Geant simulations provided the energy and momentum spectrum of the incident spray and secondary emissions, and a method via image charges was used to convert particle momenta and number density into BPM stripline currents. Good agreement was achieved between simulated and measured signals. Further simulation of experiment T-488 with incident beam on axis and impinging on a thin radiator predicted minimal impact due to secondary emission. By extension to worst case conditions expected at the ILC, simulations showed that background hits on BPM striplines would have a negligible impact on the accuracy of beam position measurements and hence the operation of the FONT feedback system.
  • Keywords
    beam handling techniques; linear colliders; particle beam diagnostics; BPM stripline currents; BPM voltage signals; FONT feedback system; Geant simulations; ILC feedback system; SLAC; T-488 experiment; beam position measurements; energy spectrum; image charges; number density; particle momenta; Distortion; Feedback; Image converters; Linear accelerators; Physics; Predictive models; Shape; Spraying; Stripline components; Voltage;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Particle Accelerator Conference, 2007. PAC. IEEE
  • Conference_Location
    Albuquerque, NM
  • Print_ISBN
    978-1-4244-0916-7
  • Type

    conf

  • DOI
    10.1109/PAC.2007.4440610
  • Filename
    4440610