Multicenter perfectly matched layer implementation for finite element mesh truncation

## Abstract In this article, we introduce the locally conformal perfectly matched layer (PML) technique, which is an easily implementable conformal PML implementation, obtained via complex coordinate transformation, for the purpose of mesh truncation in the finite element method. After deriving the

Perfectly matched layer PML absorbers deteriorate the condition of the resulting finite-element sparse systems. Therefore, poor con¨ergence scenarios are obser¨ed when an iterati¨e sol¨er is employed. In this work, we show that, by choosing the PML parameters in an optimal manner, substantial speedu

Figure shows the percentage discrepancies between the measured resonant frequencies and those obtained from, respectively, (91, (15), and ( ) as functions of substrate electrical thicknesses of all antenna elements given in Table . The average discrepancies of expressions (9), (13, and (16) are, re

means of three numerical examples, the functional showed better agreement with the reference results than the traditional scheme, in which the feeding point impedance is computed directly from the ratio of the feeding point voltage and current. Variational-based methods offer a new and more accurate

The perfectly matched layer boundary condition is incorporated into the beam propagation method based on a "nite element scheme for 3-D optical waveguides. Not only an approximate scalar formulation but a full-wave formulation is presented. Its e!ectiveness is veri"ed by way of numerical examples.