A System Stability Analysis for a Time-delayed Four Meander Line Antenna Legs Birdcage for Helicon Excitation with Titanium Alloy and Copper Legs

2019 IEEE International Conference on Microwaves, Antennas, Communications and Electronic Systems (COMCAS) Pub Date : 2019-11-01 DOI:10.1109/COMCAS44984.2019.8958056

O. Aluf, Netanya, Israel

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Abstract

A four meander line antenna legs birdcage for helicon excitation with titanium alloy and copper legs is used in many applications. Helicon waves are electromagnetic waves which propagate in magnetized plasma. An approach for helicon plasma source improvement consists in optimizing helicon wave excitation by means of specific antenna designs. The antenna is composed of N1 identical meander line antenna legs equally distributed on a cylinder of radius Rc. We consider an $\mathrm{N}_{1}=4$ design. Due to the RF antenna leg parasitic effect we get each leg’s current with delay $\tau_{k}$ (k is a leg number index, $\mathrm{k}=1,\ldots,4$). For simplicity, we assume all time delays are equal, $\tau_{k}=\tau$ for $k = 1$, 2, 3, 4. We present a practical guide which combines graphical information with theoretical analysis to effectively study the local stability of models involving delay dependent parameters. The stability of a given steady state is determined by the graphs of some function of $\tau$.

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钛合金-铜支腿螺旋激励延时四曲线天线支腿鸟笼系统稳定性分析

一种采用钛合金和铜支腿的四曲线天线支腿鸟笼，用于螺旋激励。螺旋波是在磁化等离子体中传播的电磁波。改进螺旋等离子体源的途径是通过特定的天线设计来优化螺旋波激发。天线由N1个相同的曲线形天线支腿组成，均匀分布在半径为Rc的圆柱体上。我们考虑$\ mathm {N}_{1}=4$设计。由于射频天线腿的寄生效应，我们以延迟$\tau_{k}$ (k是腿号索引，$\ mathm {k}=1，\ldots,4$)获得每条腿的电流。为了简单起见，我们假设所有的时间延迟都是相等的，$\tau_{k}=\tau$对于$k = 1$， 2,3,4。我们提出了一种实用指南，将图形信息与理论分析相结合，有效地研究了包含时滞相关参数的模型的局部稳定性。给定稳态的稳定性是由$\tau$函数的图决定的。

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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2019 IEEE International Conference on Microwaves, Antennas, Communications and Electronic Systems (COMCAS)

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