麦克风测量系统在SHINE水平测试的应用

application of microphonics measurement system in SHINE horizontal testing

  • 摘要: 上海硬X射线自由电子激光装置(SHINE)中主要使用1.3 GHz和3.9 GHz两种频率的超导腔,运行时综合考虑了功率源的功率耦合以及高功率耦合器的性能,调节超导腔有载品质因子(QL)大于4.12×107,导致超导腔系统运行带宽极窄,容易受到外界的干扰源影响,因此加速腔压会产生抖动现象,对束流能量稳定产生冲击,这种现象称为麦克风效应。麦克风效应成功测量是稳定运行的前提,因此我们研发了一套麦克风测量系统,对该系统进行频偏测量和振荡频率测量,RF信号动态响应进行了标定,结果表明该系统可应用于超导腔模组测试。使用该系统对1.3 GHz模组和3.9 GHz模组测试了相关麦克风背景以及测量压电陶瓷(Piezo)与腔之间的压电频率变化精度,对低电平的稳定控制起到了推动的作用。

     

    Abstract:
    Background In the Shanghai HIgh repetitioN rate XFEL and Extreme light facility (SHINE), superconducting cavities at frequencies of 1.3 GHz and 3.9 GHz are primarily used to accelerate the electron beam. Considering both the power coupling of the RF source and the performance of the high-power coupler during the overall operation of SHINE, the loaded quality factor (QL) of the superconducting cavities is set to be greater than 4.12×107. This results in an extremely narrow operating bandwidth for the superconducting cavity system, making it susceptible to external disturbances. Consequently, the accelerating cavity voltage exhibits fluctuations, which severely impact the beam energy stability and degrade the quality of the beam.
    Purpose The main task of this study is to develop a measurement system capable of, during superconducting cavity operation, determining both the vibration frequency of external disturbance sources and the magnitude of the resulting frequency variation of the superconducting cavity.
    Methods The measurement system is built around NI PXIe instruments and programmed using LabVIEW for discrete data acquisition. The SEL (Symmetric Extension of Local) morphological discrete frequency variation principle is employed for data processing, followed by a Fourier transform to display the oscillation frequency and frequency deviation of the vibration sources.
    Results The system was verified by measuring the 1.3 GHz and 3.9 GHz cavities. The measurement error of frequency deviation was evaluated as a function of different oscillation frequencies and frequency deviations. The results show that the frequency deviation error increases with larger frequency deviation values and is proportional to the oscillation frequency. The precision of frequency deviation under different signal powers was also measured, yielding a frequency deviation error of 0.002 Hz. Using the system, the frequency deviations of eight 1.3 GHz cavities in the CM02 module and eight 3.9 GHz cavities in the HCM01 module were measured on a horizontal test platform. Additionally, the system was used to evaluate the precision of piezo actuators.
    Conclusions This system can detect the oscillation frequency and frequency deviation caused by external disturbance sources on the superconducting cavity modules, meeting the design goals of the system. It serves as a prerequisite exploration for designing subsequent microphonics suppression schemes.

     

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