Andre S. Conradie scite author profile

Rigorously accounting for mutual coupling effects in antenna array synthesis, generally requires that embedded element patterns (EEPs) be determined. The method of moments (MoM) is typically used. Multiple linear system solutions are required, corresponding to every excitation vector associated with an EEP. This paper presents the direct coupling technique (DCT) to obtain the MoM solution for arrays with disjoint elements, by iteratively solving a series of localized subproblems, one associated with each array element. It utilizes a physics‐based, direct‐coupling approximation to incorporate global coupling into the local problems. Local matrices do not change between iterations or with excitation vectors, hence they can be inverted as a preprocessing step, allowing for efficient solution of multiple excitation configurations. Numerical results demonstrate rapid convergence. The convergence rate can be controlled via local problem domain sizing. Since the DCT is ideally suited to parallelization, it is applicable to very large arrays.

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Andre S. Conradie

Iterative DGFM Solver Extensions for Fast Sparse Array Analysis

Improved Iterative DGFM Convergence, Towards Large-Scale Antenna Array Analysis

Antenna Array Analysis by Iterative DGFM-Based Local Solutions

Modelling of MFAA Candidate Arrays Using a New Solver Based on Localised Solutions

Physics‐based iterative scheme for computing antenna array embedded element patterns

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