High Power Laser and Particle Beams, Volume. 36, Issue 8, 084005(2024)

Digital low-level radio frequency system and cavity simulator for 1.3 GHz continuous-wave superconducting radio-frequency cavity

Kui Liu1...2, Cheng Wang3, Yuxuan Huang1,2, Kuntuo Zhu1,2, and Tao Wang12 |Show fewer author(s)
Author Affiliations
  • 1Key Laboratory of Intelligent Computing Technology, SAST, Shanghai 201109, China
  • 2Shanghai Aerospace Electronic Technology Institute, Shanghai 201109, China
  • 3Shanghai Advanced Research Institute, Chinese Academy of Sciences, Shanghai 201210, China
  • show less
    References(24)

    [1] Rolles D. Time-resolved experiments on gas-phase atoms and molecules with XUV and X-ray free-electron lasers[J]. Advances in Physics: X, 8, 2132182(2023).

    [5] [5] Neumann A. Compensating microphonics in SRF cavities to ensure beam stability f future free electron lasers[D]. Hamburg: University of Hamburg, 2008.

    [9] [9] Reece C. Overview of SRFrelated activities at Jefferson Lab[C]Proceedings of the 10th Wkshop on RF Superconductivity. 2001.

    [10] [10] Schulze D. Ponderomotive stability of R. F. resonats resonat control systems[R]. ANLTRANS944, 1972.

    [11] [11] Delayen J R. Phase amplitude stabilization of superconducting resonats[D]. Califnia: Califnia Institute of Technology, 1978.

    [12] [12] Pławski T. Digital RF control system f superconducting cavity with large Lentz fce detuning coefficient[D]. Warsaw: Warsaw University of Technology, 2014.

    [13] [13] Konrad M. Development commissioning of a digital rf control system f the SDALINAC migration of the accelerat control system to an EPICSbased system[D]. Darmstadt: Technische Universität Darmstadt, 2013.

    [14] [14] Powers T. Practical aspects of SRF cavity testing operations[C]SRF Wkshop. 2011: 6063.

    [15] [15] Geßler P. Synchronization sequencing of data acquisition control electronics at the European Xray free electron laser[D]. Hamburg: Technische Universität Hamburg, 2015.

    [16] [16] Doolittle L, Ma Hengjie, Champion M S. Digital lowlevel RF control using nonIQ sampling[C]Proceedings of LINAC2006. 2006: 568570.

    [19] [19] Du Botao, Lin Hongxiang, Liu Wei, et al. DSP Frame Algithm of LLRF of IRFEL[C]Proceedings of IPAC2017. 2017: 40174019.

    [20] [20] raka R. A survey of CDIC algithms f FPGA based computers[C]Proceedings of the 1998 ACMSIGDA Sixth International Symposium on Field Programmable Gate Arrays. 1998: 191200.

    [21] [21] Mittal S, Gupta S, Dasgupta S. System generat: the stateofart FPGA design tool f DSP applications[C]Third International Innovative Conference on Embedded Systems, Mobile Communication Computing (ICEMC2 2008). 2008: 187190.

    [22] [22] Schilcher T. Vect sum control of pulsed accelerating fields in Lentz fces detuned superconducting cavities[D]. Hamburg: University of Hamburg, 1998.

    [24] [24] Butkowski L, Kozak T, Yang Bin, et al. FPGA firmware framewk f MTCA. 4 AMC modules[C]Proceedings of the 15th International Conference on Accelerat Large Experimental Physics Control Systems. 2015.

    Tools

    Get Citation

    Copy Citation Text

    Kui Liu, Cheng Wang, Yuxuan Huang, Kuntuo Zhu, Tao Wang. Digital low-level radio frequency system and cavity simulator for 1.3 GHz continuous-wave superconducting radio-frequency cavity[J]. High Power Laser and Particle Beams, 2024, 36(8): 084005

    Download Citation

    EndNote(RIS)BibTexPlain Text
    Save article for my favorites
    Paper Information

    Category:

    Received: Sep. 19, 2023

    Accepted: Apr. 15, 2024

    Published Online: Aug. 8, 2024

    The Author Email:

    DOI:10.11884/HPLPB202436.230325

    Topics