A Hybrid Method of Analysis for Shaped Dielectric Lenses Compared with Measurement Results

2017 IEEE MTT-S International Microwave and RF Conference (IMaRC) Pub Date : 2017-12-01 DOI:10.1109/IMARC.2017.8449675

S. Ravishankar, A. Mahesh, K. S. Shushrutha, Cdr Vijay Singh

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Abstract

A novel hybrid method to compute EM fields for a hemi-shaped lens based array antennas using modal analysis and geometrical optics over a near field spherical surface is presented in this paper. The near field of the array radiator is obtained from its far field pattern as a spherical modal expansion (SME). The requisite number of spherical modes characterizing the array are treated as co-located plane wave sources radiating into the shaped dielectric lens and analyzed using geometrical optics (GO). The total field at any point on a spherical surface surrounding the lens is the sum of individual plane wave contributions. These are easily transformed to far field using a SME. Presented in this effort are computations using the hybrid technique for hemi-spheroidal and hemi-spherical lenses irradiated by 1×2 and 2×2 array in C and X-bands that are compared with results using an EM Flow solver (HFSS). Significantly the hybrid procedure is validated with measured results obtained in an anechoic chamber that shows a far better agreement, as compared to EM flow solver. Notably the computation time required by hybrid method is nearly 18 times less compared to the simulation time of EM Flow solver.

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异型介质透镜的混合分析方法与测量结果比较

本文提出了一种利用模态分析和几何光学在近场球面上计算半透镜阵列天线电磁场的新方法。阵列辐射器的近场是由其远场方向图作为球面模态展开(SME)得到的。将表征阵列特征的一定数量的球面模作为共定位的平面波源辐射到形状介质透镜中，并使用几何光学(GO)对其进行分析。围绕透镜的球面上任何一点的总场是各个平面波贡献的总和。使用SME很容易将这些转换为远场。本文介绍了利用混合技术对1×2和2×2阵列辐照的半球面和半球面透镜在C和x波段的计算，并与EM Flow求解器(HFSS)的结果进行了比较。值得注意的是，混合程序与在消声室中获得的测量结果进行了验证，与电磁流求解器相比，显示出更好的一致性。值得注意的是，混合方法所需的计算时间比EM流求解器的模拟时间缩短了近18倍。

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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2017 IEEE MTT-S International Microwave and RF Conference (IMaRC)

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