Title :
A unified approach to coupled-mode phenomena
Author_Institution :
Dept. of Electr. Eng., Tel Aviv Univ., Israel
fDate :
7/1/1998 12:00:00 AM
Abstract :
A unified approach is presented for the treatment of various coupled-mode phenomena in two parallel waveguides. This approach is summarized in a set of four coupled equations, which is derived directly from Maxwell´s equations. The equations are further simplified when applied to special cases such as evanescent coupling and grating-assisted coupling between parallel waveguides [e.g., reduced to a set of two equations]. In particular, for evanescently coupled waveguides, the equations reduce to the familiar vectorial coupled-mode equations. For grating-assisted waveguides the equations agree with earlier treatments, although, in some cases, may include extra terms which were omitted previously. Considering the special case of perturbations in a single waveguide, the equations in the examples coincide with those given elsewhere in earlier works. The reduction to scalar equations or extension to multiwaveguide systems is straightforward
Keywords :
coupled mode analysis; diffraction gratings; optical directional couplers; optical waveguide theory; optical waveguides; vectors; Maxwell´s equations; coupled equations; coupled-mode phenomena; evanescent coupling; grating-assisted coupling; multiwaveguide systems; parallel waveguides; perturbations; scalar equations; vectorial coupled-mode equations; Dielectric constant; Directional couplers; Electromagnetic waveguides; Gratings; Maxwell equations; Optical arrays; Optical devices; Optical waveguide theory; Optical waveguides; Waveguide components;
Journal_Title :
Quantum Electronics, IEEE Journal of
