Fast convergent dyadic Green's function in a rectangular waveguide

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

## Abstract A relatively simple method of derivation of the Green's function for vertical current sources embedded in uniform waveguides has been described. The question of singularity of the electric dyadic Green's function in the source region has been discussed, and an appropriate form of the si

## Abstract A new formalism combining modal expansions based on perfectly matched layers (PMLs) and on Floquet modes is proposed to derive a fast‐converging series expansion for the 2D Green's function of layered media. The PML‐based modal expansion is obtained by terminating the waveguide, formed

## Abstract The dyadic Green's function in spherically layered media is considered by assuming that source and field points can be located anywhere. After manipulations from the expression of the dyadic Green's function based on the reflections and transmissions of the scalar waves, the dyadic Gree

In this paper, the Green's function method is used to obtain an analytical solution of the free vibration problem of a system of two rectangular, orthotropic Levy plates. The plates of the system are elastically connected along straight lines perpendicular to the simply supported plate edges. The Gr

## Abstract Reflection and transmission behaviors of an E‐plane T‐junction in a parallel‐plate waveguide are theoretically investigated. Green's function and the iterative procedure are used to obtain the iterative equations for the __H__~__z__~ field modal coefficients. Numerical computations illu