Implementation of dynamic misalignments and luminosity stabilization

被引:0
|
作者
Hendrickson, L [1 ]
Himel, T [1 ]
Raubenheimer, TO [1 ]
Seryi, A [1 ]
Tenenbaum, P [1 ]
Woodley, M [1 ]
机构
[1] Stanford Linear Accelerator Ctr, Stanford, CA 94309 USA
来源
PROCEEDINGS OF THE 2003 PARTICLE ACCELERATOR CONFERENCE, VOLS 1-5 | 2003年
关键词
D O I
暂无
中图分类号
O412 [相对论、场论]; O572.2 [粒子物理学];
学科分类号
摘要
To fully characterize the luminosity performance of a linear collider, it is important to simulate the effects of ground motion as well as the beam-beam feedback and other stabilization systems planned to compensate for that motion. The linear collider simulation codes have recently been extended to include both ground motion models and stabilization systems to support the work of the International Linear Collider Technical Review Committee (TRC) [1]. This paper discusses the implementation details and the optimization strategies for interpulse beam-beam feedback.
引用
收藏
页码:2757 / 2759
页数:3
相关论文
共 50 条
  • [1] Effects of dynamic misalignments and feedback performance on luminosity stability in linear colliders
    Seryi, A
    Hendrickson, L
    Raubenheimer, TO
    Tenenbaum, P
    Woodley, M
    Schulte, D
    [J]. PROCEEDINGS OF THE 2003 PARTICLE ACCELERATOR CONFERENCE, VOLS 1-5, 2003, : 662 - 664
  • [2] Misalignments in ERP implementation: A dialectic perspective
    Soh, C
    Sia, SK
    Boh, WF
    Tang, M
    [J]. INTERNATIONAL JOURNAL OF HUMAN-COMPUTER INTERACTION, 2003, 16 (01) : 81 - 100
  • [3] Rigid spacecraft robust optimal attitude stabilization under actuator misalignments
    Wang, Zhong
    Li, Yan
    [J]. AEROSPACE SCIENCE AND TECHNOLOGY, 2020, 105
  • [4] Implementation of chamber misalignments and deformations in the ATLAS Muon Spectrometer description
    Benekos, N.
    Chevalier, L.
    Goldfarb, S.
    Harrington, R.
    Laporte, J. F.
    Logashenko, I.
    Miller, J.
    Nicolaidou, R.
    Ouraou, A.
    Rebuzzi, D.
    Schott, M.
    Spagnolo, S.
    van Eldik, N.
    Verducci, M.
    Willocq, S.
    [J]. NUCLEAR PHYSICS B-PROCEEDINGS SUPPLEMENTS, 2008, 177 : 339 - 340
  • [5] Implementation of sine condition test to measure optical system misalignments
    Lampen, Sara
    Dubin, Matthew
    Burge, James H.
    [J]. APPLIED OPTICS, 2011, 50 (34) : 6391 - 6398
  • [6] EARLY DIAGNOSIS OF DYNAMIC UNBALANCES AND OF MISALIGNMENTS IN LARGE TURBOGENERATORS
    CLAPIS, A
    GARIBOLDI, R
    LAPINI, G
    POSSA, G
    ROSSINI, T
    [J]. ENERGIA NUCLEARE, 1976, 23 (05): : 271 - 277
  • [7] The implementation of stabilization policy
    Loisel, Olivier
    [J]. THEORETICAL ECONOMICS, 2021, 16 (02) : 677 - 716
  • [8] Dynamic stabilization
    Shaffrey, Christopher I.
    Smith, Justin S.
    [J]. JOURNAL OF NEUROSURGERY-SPINE, 2014, 21 (04) : 582 - 583
  • [9] Dynamic stabilization?
    N. Peter Armitage
    [J]. Nature Materials, 2014, 13 (7) : 665 - 666
  • [10] DESIGN OF TOOTH FLANK MODIFICATIONS IN TRANSMISSION SYSTEMS CONSIDERING DYNAMIC MISALIGNMENTS
    Westphal, Christian
    Brimmers, Jens
    Brecher, Christian
    [J]. PROCEEDINGS OF ASME 2023 INTERNATIONAL DESIGN ENGINEERING TECHNICAL CONFERENCES AND COMPUTERS AND INFORMATION IN ENGINEERING CONFERENCE, IDETC-CIE2023, VOL 11, 2023,
12345