首页> 外文会议>German Microwave Conference >Particle-in-Cell simulation of gyro-TWT using a metal PBG circuit

【24h】

Particle-in-Cell simulation of gyro-TWT using a metal PBG circuit

机译：使用金属PBG电路进行陀螺仪TWT的粒子模拟

获取原文

页面导航

摘要
著录项
相似文献
相关主题

摘要

The Particle-in-Cell (PIC) simulation of a Ka-band Gyrotron Traveling Wave Tube (gyro-TWT) amplifier using a Metal Photonic Band Gap (MPBG) waveguide as its RF interaction circuit is presented to study the electron beam-RF wave interaction behavior. The MPBG guide is chosen as an RF interaction circuit to accomplish the single mode operation in the amplifier by its mode selective property at short wavelengths. The technique for generating hollow annular gyrating electron beam is demonstrated using “CST particle studio” code. The energy transfer phenomenon from the gyrating hot electron beam to the propagating electromagnetic (EM) wave has been studied. The PIC code predicts that the peak output power in the MPBG loaded gyro-TWT as ~ 90 kW at 35 GHz with an electronic efficiency of ~ 13 % for a velocity ratio of 1.05. The saturated gain has been calculated as ~ 40 dB and the 3 dB instantaneous bandwidth is obtained ~ 14%.

机译：提出了使用金属光子带隙（MPBG）波导作为其RF相互作用电路的Ka波段回旋行波管（gyro-TWT）放大器的粒子模拟（PIC），以研究电子束-RF波互动行为。选择MPBG波导作为RF交互电路，以其在短波长下的模式选择特性来完成放大器中的单模式操作。使用“ CST Particle Studio”代码演示了产生空心环形旋转电子束的技术。已经研究了从旋转的热电子束到传播的电磁波（EM）的能量转移现象。 PIC代码预测，在35 GHz时，加载MPBG的陀螺仪TWT的峰值输出功率为〜90 kW，电子效率为〜13％，速度比为1.05。计算出的饱和增益约为40 dB，而3 dB的瞬时带宽约为14％。

著录项

来源
《German Microwave Conference 》|2015年|268-271|共4页
会议地点
作者
Thottappan M.; Jain P.K.;
展开▼
作者单位

展开▼
会议组织
原文格式 PDF
正文语种
中图分类
关键词
PIC simulation; beam-wave interaction; gyro-TWT; metal PBG; mode competition;

机译：PIC仿真;束波相互作用;陀螺TWT;金属PBG;模式竞争;

相似文献

外文文献
中文文献
专利

1. Gyro-TWT Using a Metal PBG Waveguide as Its RF Circuit—Part II: PIC Simulation and Parametric Analysis [J] . Muthiah Thottappan, Pardeep Singh, Pradip Kumar Jain IEEE Transactions on Electron Devices . 2016 ,第5期

机译：使用金属PBG波导作为射频电路的陀螺仪TWT，第二部分：PIC仿真和参数分析
2. Gyro-TWT Using a Metal PBG Waveguide as Its RF Circuit—Part I: Analysis and Design [J] . Muthiah Thottappan, Sukwinder Singh, Pradip Kumar Jain IEEE Transactions on Electron Devices . 2016 ,第5期

机译：使用金属PBG波导作为其射频电路的陀螺仪TWT-第一部分：分析和设计
3. Self-consistent Nonlinear Analysis and 3D Particle-In-Cell Simulation of a W-band Gyro-TWT [J] . Yong Tang, Yong Luo, Yong Xu, Journal of Infrared, Millimeter and Terahertz Waves . 2014 ,第10期

机译：W波段陀螺-TWT的自洽非线性分析和3D粒子模拟
4. Particle-in-Cell simulation of gyro-TWT using a metal PBG circuit [C] . Thottappan M., Jain P.K. German Microwave Conference . 2015

机译：使用金属PBG电路的Gyro-TWT的粒子细胞仿真
5. Modeling and profile simulation of silicon and metal etching in integrated circuit manufacturing. [D] . Zheng, Jie. 1998

机译：集成电路制造中硅和金属蚀刻的建模和轮廓仿真。
6. Whistler anisotropy instabilities as the source of banded chorus: Van Allen Probes observations and particle-in-cell simulations [O] . Xiangrong Fu, Misa M Cowee, Reinhard H Friedel, -1

机译：惠斯勒各向异性的不稳定性是带状合唱的根源：Van Allen Probes的观察结果和细胞内颗粒模拟
7. Simulation and Manipulation of Tunable Weyl-Semimetal Bands Using Superconducting Quantum Circuits [O] . Xinsheng Tan, Y. X. Zhao, Qiang Liu, 2019

机译：使用超导量子电路进行可调谐Weyl-Semimetal频带的仿真和操纵
8. Switch-Level Timing Simulation of MOS VLSI (Metal-Oxide-Semiconductor Very Large-Scale Integrated) Circuits. [R] . Rao, V. B. 1985

机译：mOs VLsI（金属氧化物半导体超大规模集成电路）的开关级时序仿真。

Particle-in-Cell simulation of gyro-TWT using a metal PBG circuit

摘要

著录项

相似文献

相关主题

期刊订阅