Fast computation of spatial Green's functions of multilayered microstrip antennas

Dyadic Green's functions for a dielectric half-space, based on ''Formulation C,'' are computed by a fast algorithm using the discrete complex image method with a two-le¨el approximation. The results show ¨ery good agreement with those calculated by direct numerical integration. It is expected to be

In this paper, we introduce a novel acceleration method for the calculation of dyadic Green's functions for the mixed potential integral equation formulation of electromagnetic scattering of scatterers embedded in a multilayered medium. Numerical results are provided to demonstrate the efficiency an

In this paper, neural networks are used to efficiently calculate the multilayered media boxed Green's functions needed in integral equation (IE) formulations. The analysis of complex multilayered shielded circuits is computationally time consuming, due to the need to calculate the multilayered-media

## Abstract The discrete complex image method is one of the most efficient techniques used to evaluate the Green's functions of multilayered media. The usual extraction of surface waves may limit the validity of this method in the near‐field region. The aim of this work is to handle this problem su

A set of closed-form Green's functions is used in a mixed-potential integral-equation technique for the efficient modeling of planar microstrip structures of arbitrary shape on an electrically thin substrate. Various MMIC and microstrip antenna structures are simulated. It is shown that excellent ac