Harmonic suppression in a helix TWT using SUNRAY-3D code

Fifth IEEE International Vacuum Electronics Conference (IEEE Cat. No.04EX786) Pub Date : 2004-04-27 DOI:10.1109/IVELEC.2004.1316194

A. Srivastava, T. Ghosh, V. Srivastava, S. Joshi

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引用次数: 1

Abstract

Summary form only given. Because of the inherently wide bandwidth of the helical slow-wave structure (SWS) and nonlinearity in the electron beam at large signal levels, second and higher order harmonics of the input RF signal(s) are also generated significantly near the output, at the cost of the growth of the input (fundamental) RF signal. This reduces the TWT efficiency. Therefore, the helix SWS is to be designed in such a fashion that the harmonic levels can be suppressed near the tube output to enhance the growth of the fundamental RF signal. This requires an accurate multi-signal large-signal model for analysis of the beam-wave interaction along the helix SWS. The SUNRAY-3D program (V Srivastava, IETE Journal of Research, vol.49, no.4, p.239-246, 2003) was used for determination of the generation of second harmonic power along with output power of the fundamental (input) RF signal, after checking convergence of simulated results for different numbers of discs per wavelength and for different number of rings per disc, for a broadband TWT. Harmonic power is given along with the output power of the fundamental (input) RF signal.

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利用SUNRAY-3D代码抑制螺旋行波管中的谐波

只提供摘要形式。由于螺旋慢波结构(SWS)固有的宽带宽和大信号电平下电子束的非线性，输入射频信号(s)的二次和更高次谐波也在输出附近显著产生，代价是输入(基频)射频信号的增长。这降低了行波管的效率。因此，螺旋SWS应设计成这样一种方式，即谐波水平可以在管输出附近被抑制，以增强基本射频信号的增长。这需要一个精确的多信号大信号模型来分析沿螺旋SWS的波束波相互作用。SUNRAY-3D程序(V Srivastava, IETE学报，vol.49, no. 11)。4, p.239-246, 2003)用于确定二次谐波功率的产生以及基频(输入)射频信号的输出功率，在检查了宽带行波管中每个波长的不同圆盘数和每个圆盘的不同环数的模拟结果的收敛性之后。谐波功率随基频(输入)射频信号的输出功率一起给出。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Fifth IEEE International Vacuum Electronics Conference (IEEE Cat. No.04EX786)

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