基于相位前馈的超导腔脉冲射频场控制方法

Phase feedforward control method for pulsed RF fields in superconducting cavities

  • 摘要: 超导腔内射频场稳定性对束流的能量增益和束流品质至关重要。脉冲射频场的建立阶段常出现强动态洛伦兹力失谐,致使控制系统在闭环的初始阶段出现非预期的瞬态响应,射频场的幅度出现“下凹”,影响束流加速的一致性,同时也会造成不必要的功率耗费。为解决上述问题,通过低电平控制系统对脉冲射频场施加相位前馈补偿,有效提升了脉冲模式下射频场稳定性和加速效率。具体过程包括对前向电压和超导腔加速电压(以下简称腔压)信号提取、计算得到超导腔的失谐频率随时间的变化曲线;计算出前向电压和腔压之间的失谐角,最后向低电平机箱内部FPGA写入需要补偿的相位数据。在强流重离子加速器(HIAF)中实验证明,应用该方法后腔压稳定性提升,在保证腔压不变的情况下前向电压幅度减小23%,峰值功率降低约40%。

     

    Abstract:
    Background The stability of the radio-frequency (RF) electromagnetic field in superconducting cavities is a critical factor determining energy gain and beam quality in modern particle accelerators. In pulsed operation, the interaction between RF electromagnetic pressure and cavity wall deformation causes strong dynamic Lorentz force detuning (LFD). This effect leads to rapid shifts in the cavity resonant frequency, resulting in pronounced transient “field droop” in RF amplitude during low-level RF (LLRF) control, which degrades field stability and acceleration consistency.
    Purpose This study aims to mitigate the adverse effects of LFD-induced perturbations by implementing a phase feedforward compensation strategy. The goal is to counteract anticipated frequency deviations through the LLRF control system, thereby suppressing transient field perturbations and enhancing RF field stability during the cavity fill and beam acceleration phases.
    Methods A quantitative characterization method for cavity detuning was developed by extracting and processing forward voltage and cavity accelerating voltage signals. Based on these signals, the time-dependent detuning frequency and the instantaneous detuning phase angle between the forward and cavity voltages were calculated. These calculated phase offsets were converted into compensation data and programmed into a field-programmable gate array (FPGA) within the LLRF controller. This setup enabled real-time, synchronized phase correction during pulsed operation.
    Results The proposed method was experimentally verified at the High Intensity Heavy-Ion Accelerator Facility (HIAF). The experimental results demonstrated that the application of phase feedforward compensation significantly reduced the RF amplitude droop. The system exhibited improved field stability under high-current pulsed operation, aligning with theoretical expectations and confirming the feasibility of the FPGA-based real-time correction.
    Conclusions The phase feedforward strategy provides an effective framework for managing dynamic LFD in pulsed superconducting accelerators. By integrating precise detuning calculations with real-time FPGA compensation, the approach enhances both RF stability and acceleration efficiency. This method offers a practical and robust solution for high-performance LLRF control in high-current accelerator environments.

     

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