Efficient iterative method for analysis of large finite phased arrays

## Abstract A discrete Fourier transform (DFT)‐based iterative method of moments (IMoM) algorithm is developed to provide an __O__(__N__~__tot__~) computational complexity and memory storages for the efficient analysis of electromagnetic radiation/scattering from large phased arrays. Here, __N__~__

## Abstract In this paper, a method is presented for analyzing very large finite arrays of tapered‐slot antenna elements. The Toeplitz matrix property of regularly spaced arrays, combined with a parametrically truncated coupling radius, generates fixed matrix storage based on the coupling radius ra

## Abstract A rigorous integral equation formulation is made in this paper for the analysis of phased arrays of radiating slots fed by rectangular waveguides. The number of elements is assumed to be finite, and the integral equation used is that of the method of moments. According to the equivalenc

## Abstract A discrete‐Fourier‐transform (DFT) based forward‐backward (FB) algorithm has been developed for the fast and accurate analysis of electrically large freestanding dipole arrays [1]. In this paper, an extension of the FB method (FBM) with a DFT‐based acceleration approach is presented to

## Abstract The segmented analysis method of a finite planar ridged tapered slot antenna (RTSA) array is presented to develop a wideband phased array with a triangular lattice. The RTSA array is segmented into two‐parts with a feeder and the arrays of tapered slot antenna (TSA) and these scattering

## Abstract The article presents an efficient method for characterization of substrate integrated waveguide structures. Substrate integrated circuits are considered as an ensemble of conducting vias placed in a parallel‐plate waveguide. The analysis is based on the wave concept formulation and the