Title :
Generalized Finite-Difference Time-Domain Method Utilizing Auxiliary Differential Equations for the Full-Vectorial Analysis of Photonic Crystal Fibers
Author :
Hu, Juan Juan ; Shum, Ping ; Lu, Chao ; Ren, Guobin
Author_Institution :
Nanyang Technol. Univ., Singapore
Abstract :
We present the generalized finite-difference time-domain full-vectorial method by reformulating the time-dependent Maxwell´s curl equations with electric flux density and magnetic field intensity, with auxiliary differential equations using complex-conjugate pole-residue pairs. The model is generic and robust to treat general frequency-dependent material and nonlinear material. The Sellmeier equation is implicitly incorporated as a special case of the general formulation to account for material dispersion of fused silica. The results are in good agreement with the results from the multipole method. Kerr nonlinearity is also incorporated in the model and demonstrated. Nonlinear solutions are provided for a one ring photonic crystal fiber as an example.
Keywords :
Maxwell equations; finite difference time-domain analysis; optical Kerr effect; optical fibre dispersion; photonic crystals; Kerr nonlinearity; Sellmeier equation; auxiliary differential equations; complex-conjugate pole-residue pairs; electric flux density; frequency-dependent material; fused silica; generalized finite-difference time-domain full-vectorial method; magnetic field intensity; material dispersion; multipole method; nonlinear material; ring photonic crystal fiber; time-dependent Maxwell curl equations; Crystalline materials; Differential equations; Finite difference methods; Magnetic analysis; Magnetic fields; Magnetic materials; Maxwell equations; Nonlinear equations; Photonic crystal fibers; Time domain analysis; Auxiliary differential equation (ADE); Kerr nonlinearity; finite-difference time-domain (FDTD); material dispersion; photonic crystal fibers (PCF);
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2007.909696
