Numerical solution of electromagnetic scattering problems. Case of perfectly conducting cylinders

## Abstract We consider the scattering of a plane time‐harmonic electromagnetic wave by a perfectly conducting infinite cylinder with axis in the direction k, where k is the unit vector along the z axis. Suppose the incident wave propagates in a direction perpendicular to the cylinder. For a given

A new numerical method is applied to the solution of electromagnetic wave diffraction problems on perfectly conducting screens. The method is based on a special class of Gaussian approximating functions that are used for discretization of the original integral equation of the problem. These function

## Abstract The aim of this paper is to analyze the scattering by a rectangular‐section perfectly conducting cylinder. The solution method is based on the use of the Neumann series; the problem is regularized by factorizing the right edge behavior of the current. © 2004 Wiley Periodicals, Inc. Micr

An iterative Neumann series method, employing a real auxiliary scattering integral equation, is used to calculate scattering lengths and phase shifts for the atomic Yukawa and exponential potentials. For these potentials the original Neumann series diverges. The present iterative method yields resul

A time-dependent method is presented for the numerical solution of the wave equation and its associated Helmholtz equation in electromagnetic scattering problems. l'his method provides an efficient iterative scheme for the solution of the matrix equation resulting from the application of finite-diff