PSO-aided ILA Methodology for Hemispherical Beam Coverage and Scan Loss Mitigation

2020 International Symposium on Antennas and Propagation (ISAP) Pub Date : 2021-01-25 DOI:10.23919/ISAP47053.2021.9391376

Youngno Youn, Jaehong Choi, Daehyeon Kim, A. Omar, Jaehyun Choi, I. Yoon, S. Ko, Jungyub Lee, Youngju Lee, W. Hong

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引用次数: 1

Abstract

This paper proposes an accurate and efficient integrated lens antenna (ILA) concept and design methodology for extraordinary beam coverage and scan loss mitigation at millimeter-wave spectrum. The geometry of the proposed ILA consists of inhomogeneous curvatures and internal center offset, where multiple parameters have high order and non-linear relations. Relying entirely on conventional full-wave simulation becomes realistically unviable. Based on geometrical optics, twodimensional ray tracing model calculates refractions on the arbitrarily-curved boundaries. The preliminary geometry of the proposed ILA is determined by a novel particle swarm optimization (PSO) algorithm, significantly enhancing the entire efficiency of the design procedure. With the integration of 8×16 phased array antenna, the devised ILA exceeds the conventional beam scanning limitations by 93%, achieving a main beam scanning range of 174 and scan loss of 2.2 dB for both vertical and horizontal polarizations and broad operational bandwidth. This method is estimated to alleviate the mmWave 5G antenna CAPEX (capital expenditure) by more than 50%.

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半球面波束覆盖和扫描损耗减缓的pso辅助ILA方法

本文提出了一种精确、高效的集成透镜天线(ILA)概念和设计方法，用于毫米波频谱的超常规波束覆盖和扫描损耗降低。该模型的几何结构由非齐次曲率和内部中心偏移组成，其中多个参数具有高阶非线性关系。完全依靠传统的全波模拟实际上是不可行的。基于几何光学的二维光线追踪模型计算了任意弯曲边界上的折射。采用粒子群优化算法确定了ILA的初步几何形状，大大提高了整个设计过程的效率。在集成8×16相控阵天线的情况下，所设计的ILA超过了常规波束扫描限制93%，在垂直极化和水平极化情况下，主波束扫描范围为174，扫描损耗为2.2 dB，工作带宽很宽。据估计，这种方法可以将毫米波5G天线的CAPEX(资本支出)降低50%以上。

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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2020 International Symposium on Antennas and Propagation (ISAP)

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