A semivectorial method for the modeling of photonic crystal fibers

## Abstract A simple formula for calculating the mode‐field diameter of large‐mode‐area endlessly single‐mode photonic‐crystal fiber (PCF) is obtained and used to estimate the splice loss of PCF/single‐mode fiber. The accuracy of splice‐loss estimation is less than 0.2 dB. © 2004 Wiley Periodicals,

## Abstract Simple, fast, and efficient 1D models for evaluating the transmission properties of photonic crystal fibers are proposed. Using these models, axial propagation constant, chromatic dispersion, effective area, and leakage loss can be predicted with a reasonable accuracy but much faster th

## 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

We demonstrate single-mode guiding in a 4-μminner-diameter hollow photonic-crystal fiber filled with a highly nonlinear liquid. The nonlinear response of such a fiber is shown to drastically differ from a typical nonlinear response of a silica waveguide. Strong inertia of optical nonlinearity of the

## Abstract This research applies an efficient two‐dimensional cylindrical finite‐difference–time‐domain (2D‐CFDTD) algorithm implemented on the transverse plane of a guided‐wave structure to analyze a photonic crystal fiber (PCF) structure. An unsplit anisotropic perfectly matched layer (APML) is