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Fast MoM Solver (GIFFT) for Large Arrays of Microstrip and Cavity-Backed Antennas

机译：用于大型微带和腔背天线阵列的快速mom求解器（GIFFT）

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A straightforward numerical analysis of large arrays of arbitrary contour (and possibly missing elements) requires large memory storage and long computation times. Several techniques are currently under development to reduce this cost. One such technique is the GIFFT (Green's function interpolation and FFT) method discussed here that belongs to the class of fast solvers for large structures. This method uses a modification of the standard AIM approach (1) that takes into account the reusability properties of matrices that arise from identical array elements. If the array consists of planar conducting bodies, the array elements are meshed using standard subdomain basis functions, such as the RWG basis. The Green's function is then projected onto a sparse regular grid of separable interpolating polynomials. This grid can then be used in a 2D or 3D FFT to accelerate the matrix-vector product used in an iterative solver (2). The method has been proven to greatly reduce solve time by speeding up the matrix-vector product computation. The GIFFT approach also reduces fill time and memory requirements, since only the near element interactions need to be calculated exactly. The present work extends GIFFT to layered material Green's functions and multiregion interactions via slots in ground planes. In addition, a preconditioner is implemented to greatly reduce the number of iterations required for a solution. The general scheme of the GIFFT method is reported in (2); this contribution is limited to presenting new results for array antennas made of slot-excited patches and cavity-backed patch antennas.

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作者
Fasenfest, B. J.; Capolino, F.; Wilton, D.;
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年度 2005
页码 p.1-10
总页数 10
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Arrays; Antennas; Storage; Greens functions; Numerical analysis; Interpolation; Polynomials; Matrices; Modifications;

机译：阵列;天线;存储;格林函数;数值分析;插值;多项式;矩阵;修改;

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专利

1. Preconditioned GIFFT: A Fast MoM Solver for Large Arrays of Printed Antennas [J] . B. J.Fasenfest, F. Capolino, D.R. Wilton Applied Computational Electromagnetics Society journal . 2006,第3期

机译：预处理的GIFFT：一种用于大型印刷天线阵列的快速MoM解决方案
2. Wide-scan Phased Antenna Array Based on Cavity-Backed ELC-Slot Microstrip Patch Antenna Element [J] . Dadashzadeh Gholamreza, Torabi Yalda, Kargar Mohammad, IETE Journal of Research . 2016,第5期

机译：基于腔体支持的ELC插槽微带贴片天线元件的宽扫描相控天线阵列
3. Fast Iterative Algorithm for Solving Matrix Equation in MoM Analysis of Large-Scale Array Antennas [J] . Qiang CHEN, Qiaowei YUAN, Kunio SAWAYA 電子情報通信学会技術研究報告. アンテナ·伝播. Antennas and Propagation . 2003,第297期

机译：大型阵列天线MoM分析中求解矩阵方程的快速迭代算法
4. A fast MoM solver (GIFFT) for large arrays of microstrip and cavity-backed antennas [C] . Fasenfest, B.J., Capolino, . 2005

机译：快速MoM求解器（GIFFT），适用于大型微带和背腔天线
5. Efficient hybrid MoM/Green's function technique to analyze conformal microstrip antennas and arrays. [D] . Erturk, Vakur Behcet. 2000

机译：高效的MoM / Green混合功能技术，可以分析共形微带天线和阵列。
6. Array Design of 300 GHz Dual-Band Microstrip Antenna Based on Dual-Surfaced Multiple Split-Ring Resonators [O] . Shuhang Bie, Shi Pu 2021

机译：基于双浮出的多分裂环谐振器的300 GHz双频微带天线阵列设计
7. Design and Fabrication of a High Gain 60-GHz Cavity-backed Slot Antenna Array fed by Inverted Microstrip Gap Waveguide [O] . Liu, Jinlin, Vosoogh, Abbas, Zaman, Ashraf Uz, 2017

机译：反向微带隙波导馈电的高增益60 GHz腔后向缝隙天线阵列的设计与制作

Fast MoM Solver (GIFFT) for Large Arrays of Microstrip and Cavity-Backed Antennas

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