Numerical analysis of Bragg fibers using a compact 1D finite-difference frequency-domain method

The propagation characteristics of ridged circular waveguides are analyzed by using 2D finite-difference frequency-domain (2D FDFD). Based on the 2D FDFD method in a cylindrical coordinate system, general difference formulas for the ridged circular waveguide are deduced, and modified difference form

In this article, a general full-wave two dimensional finite difference frequency domain (2D-FDFD) method is presented that could be used to analyze general circular multi-layered multi-conductor guiding structures. The FDFD method is mainly used to get the dispersion curves for these structures. The

## Abstract To simulate periodic structures efficiently, Floquet's theorem is applied to a compact finite‐difference method for the analysis of dispersion characteristics of general periodic guided wave structures. By solving the full‐field‐component Eigen equations, dispersion characteristics and

## Abstract An efficient finite‐difference time‐domain method is proposed for the full‐wave analysis of guided modes in photonic crystal fibers. The three‐dimensional hybrid guided modes can be calculated by a two‐dimensional mesh, if one assumes that the propagation constant along the __z__‐direct

## Abstract The finite‐difference time domain (FDTD) method is successfully used to analyze characteristics of a U‐slot patch antenna without using commercial software packages such as HFSS, IE3D, and CST. The method is proved to be an efficient tool for deep insight studies on complicated patch an