Investigation of Microstrip Meander-Line Traveling-Wave Tube Using EBG Ground Plane

Bai Ningfeng; Shen Meng; Sun Xiaohan

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Investigation of Microstrip Meander-Line Traveling-Wave Tube Using EBG Ground Plane

机译：EBG地平面研究微带弯折行波管

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摘要

A novel electromagnetic bandgap meander-line (EBG-ML) slow-wave structure (SWS) is proposed for improvement of the interaction impedance and reduction of circuit attenuation by in-phase reflection of EBG for traveling-wave tube applications. With high on-axis interaction impedance, the EBG-ML SWS can interact with a low-current-density electron beam. The backward-wave mode of EBG-ML SWS can be suppressed by the transmission stopband of EBG. Particle-in-cell simulations are carried out for the proposed structure with a sheet beam source. The simulation results show that a 50% improved interaction impedance and a 20% reduced circuit attenuation of EBG-ML SWS can be achieved, in comparison with those of traditional ML SWS. With a small input signal, the RF efficiency of EBG-ML is improved by 137.5% over that of the ML SWS.

机译：提出了一种新颖的电磁带隙曲折线（EBG-ML）慢波结构（SWS），以通过行波管应用中的EBG的同相反射来改善相互作用阻抗并减小电路衰减。 EBG-ML SWS具有高的同轴相互作用阻抗，可以与低电流密度电子束相互作用。 EBG-ML SWS的反向波模式可以通过EBG的传输阻带来抑制。对带有片状束源的拟议结构进行了单元内粒子模拟。仿真结果表明，与传统ML SWS相比，EBG-ML SWS的交互阻抗提高了50％，电路衰减降低了20％。在较小的输入信号下，EBG-ML的RF效率比ML SWS的RF效率提高了137.5％。

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来源
《Electron Devices, IEEE Transactions on》 |2015年第5期|1622-1627|共6页
作者
Bai Ningfeng; Shen Meng; Sun Xiaohan;
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作者单位

Department of Electronics Engineering, Southeast University, Nanjing, China;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词
Electromagnetic bandgap (EBG); meander line (ML); slow-wave structure (SWS); traveling-wave tube (TWT);

机译：电磁带隙（EBG）;曲折线（ML）;慢波结构（SWS）;行波管（TWT）;

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1. Study of the Symmetrical Microstrip Angular Log-Periodic Meander-Line Traveling-Wave Tube [J] . Shaomeng Wang, Yubin Gong, Zhanliang Wang, IEEE Transactions on Plasma Science . 2016,第9期

机译：对称微带角对数周期曲折线行波管的研究
2. Symmetric Double V-Shaped Microstrip Meander-Line Slow-Wave Structure for W-Band Traveling-Wave Tube [J] . Fei Shen Electron Devices, IEEE Transactions on . 2012,第5期

机译：W波段行波管的对称双V形微带曲折线慢波结构
3. Study on a W-band modified V-shaped microstrip meander-line traveling-wave tube [J] . Shen Fei, Wei Yan-Yu, Xu Xiong, 中国物理：英文版 . 2012,第006期

机译：W波段改进的V形微带曲折线行波管的研究
4. Development of a millimeter-band traveling-wave tube with a meander-line microstrip slow wave structure [C] . N.M.Ryskin, A.V.Starodubov, R.A.Torgashov, International Conference on Terahertz and Microwave Radiation: Generation, Detection, and Applications . 2020

机译：具有曲折线微带慢波结构的毫米带行波管的研制
5. Ground plane slot structures for isolation of cosited microstrip antennas. [D] . Kerby, Kiersten C. 2009

机译：用于隔离同位微带天线的接地平面缝隙结构。
6. Meander-Line Slot-Loaded High-Sensitivity Microstrip Patch Sensor Antenna for Relative Permittivity Measurement [O] . Junho Yeo, Jong-Ig Lee 2019

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7. Uniplanar EBG structure based on a modified Spidron fractal and meander-line configuration [O] . Son Trinh-Van, Gina Kwon, Keum Cheol Hwang, 2013

机译：基于改进的蜘蛛网分形和曲折线配置的Uniplanar EBG结构
8. Ring-Plane Traveling-Wave Tube Slow-Wave Circuit Design Simulations at V-BandFrequencies [R] . Kory, C. L., Wilson, J. D. 1995

机译：V形带频率下的环面行波管慢波电路设计仿真

Investigation of Microstrip Meander-Line Traveling-Wave Tube Using EBG Ground Plane

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