Title :
FDTD Maxwell´s equations models for nonlinear electrodynamics and optics
Author :
Joseph, Rose M. ; Taflove, Allen
Author_Institution :
Lincoln Lab., MIT, Lexington, MA, USA
fDate :
3/1/1997 12:00:00 AM
Abstract :
This paper summarizes algorithms which extend the finite-difference time-domain (FDTD) solution of Maxwell´s equations to nonlinear optics. The use of the FDTD in this field is novel. Previous modeling approaches were aimed at modeling optical-wave propagation in electrically long structures such as fibers and directional couplers, wherein the primary flow of energy is along a single principal direction. However, the FDTD is aimed at modeling compact structures having energy flow in arbitrary directions. Relative to previous methods, the FDTD achieves robustness by directly solving, for fundamental quantities, the optical E and H fields in space and time rather than performing asymptotic analyses or assuming paraxial propagation and nonphysical envelope functions. As a result, it is almost completely general. It permits accurate modeling of a broad variety of dispersive and nonlinear media used in emerging technologies such as micron-sized lasers and optical switches
Keywords :
Maxwell equations; electric fields; electrodynamics; finite difference time-domain analysis; magnetic fields; nonlinear optics; optical dispersion; FDTD Maxwell´s equations models; FDTD solution; compact structures; directional couplers; dispersive media; electrically long structures; energy flow; finite-difference time-domain; micron sized lasers; nonlinear electrodynamics; nonlinear media; nonlinear optics; optical E fields; optical H fields; optical fibers; optical switches; optical wave propagation; Directional couplers; Electrodynamics; Fiber nonlinear optics; Finite difference methods; Maxwell equations; Nonlinear optics; Optical fiber couplers; Optical propagation; Space technology; Time domain analysis;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
