Simpler and more intuitive interpretation of stability condition for finite-difference time-domain method

Figure 8 Reconstruction of a 2-D configuration of small cylinders. Ž . Ž . a True objects. b Best chromosome of the first generation. Fit-Ž . ness s 0.9963340. c Best chromosome of the 500th generation. Ž . Fitness s 0.9999881. d Best chromosome of the 1000th generation. Ž . Fitness s 0.9999915. e B

Two different types of source excitation for finite-difference ( ) time-domain FDTD simulations, i.e., electric and magnetic field types, are in¨estigated in this work for configurations that ha¨e no ground planes. This paper shows that the electric field excitation introduces errors in the computed

## Abstract In this paper we discuss the use of perfectly matched layers (PMLs) for the termination of conducting media in the body of revolution finite difference time domain (BOR–FDTD) algorithm. This type of termination enables us, to accurately and efficiently model long conductors possessing r

## Abstract A new method to reduce the numerical dispersion of the conventional alternating‐direction‐implicit finite‐difference time‐domain (ADI‐FDTD) method is proposed. First, the numerical formulations are modified with the artificial anisotropy, and the numerical dispersion relation is derived

## Abstract A modified finite‐difference time‐domain (FDTD) code is presented for the line response characterization of a transmission line illuminated by a Gaussian pulse‐modulated electromagnetic signal. The final expressions are transformed according to the complex‐envelope representation in ord

Numerical modeling of the eddy currents induced in the human body by the pulsed field gradients in MRI presents a difficult computational problem. It requires an efficient and accurate computational method for high spatial resolution analyses with a relatively low input frequency. In this article, a