We present a design study for an X-band frequency-doubling magnicon amplifier driven by a 500 keV, 172 A beam from a field-emission diode. This study makes use of steady-state particle simulations employing the realistic fields of magnicon cavities connected by beam tunnels, and includes the effects of finite electron beam diameter. The simulations propagate an electron beam through a sequence of deflection cavities at 5.7 GHz, followed by an output cavity that operates at 11.4 GHz. The deflection cavities and the output cavity contain synchronously rotating TM modes. The deflection cavities progressively spin up the beam transverse momentum, until /spl alpha//spl equiv/v/sub /spl perp///v/sub z/<1, where v/sub /spl perp// and v/sub z/ are the velocity components perpendicular and parallel to the axial magnetic field. The output cavity uses this synchronously gyrating beam to generate microwave radiation at twice the drive frequency. Self-consistency of the simulation is achieved by iteration until power balance exists in each cavity, and until the optimum RF phase in each cavity is determined. The final magnicon circuit should produce 20 to 50 MW at 11.4 GHz, depending on initial beam diameter, with a drive power of 1 kW at 5.7 GHz.
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机译:我们提出了一个X波段倍频磁控放大器的设计研究,该放大器由来自场发射二极管的500 keV,172 A光束驱动。这项研究利用稳态粒子模拟,利用了通过束隧道连接的磁子腔的真实场,并包括了有限电子束直径的影响。模拟将电子束传播通过一系列5.7 GHz的偏转腔,然后传播工作在11.4 GHz的输出腔。偏转腔和输出腔包含同步旋转的TM模式。偏转腔逐渐使光束横向动量旋转,直到/ spl alpha // spl equiv / v / sub / spl perp /// v / sub z / <1,其中v / sub / spl perp //和v / sub z /是垂直和平行于轴向磁场的速度分量。输出腔使用此同步旋转光束以两倍于驱动频率的频率产生微波辐射。通过迭代实现仿真的自洽性,直到每个腔中都存在功率平衡为止,直到确定每个腔中的最佳RF相位为止。最终的磁控电路在11.4 GHz时应产生20至50 MW,具体取决于初始光束直径,在5.7 GHz时的驱动功率为1 kW。
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