We describe a method for calculating the solution of the electromagnetic field in a non-rectilinear open waveguide by using a series expansion, starting from the field of a rectilinear waveguide. Our approach is based on a method of variation of boundaries. We prove that the obtained series expansion converges and we provide a radiation condition at infinity in such a way that the problem has a unique solution. Our approach can model several kinds of optical devices which are used in optical integrated circuits. Numerical examples will be shown for the case of finite aperiodic waveguide grating couplers
Fourier series expansion of simultaneous integral equations for collinear coupled waveguides radiati...
In the theory of integrated optics, a central role is played by the rib waveguide geometry. The elec...
Galerkin's method is employed to analyze the quasi-vector wave equation for optical waveguides with ...
We describe a method for calculating the solution of the electromagnetic field in a non-rectilinear...
A boundary Variation method for the analysis of both infinite periodic and finite aperiodic waveguid...
A boundary variation method for the fast and accurate modeling of three-dimensional waveguide gratin...
A rigorous approach for precise and efficient calculation of light propagation along nonuniform wave...
Abstract: "We have recently introduced a method of variation of boundaries for the solution of diffr...
Abstract. The higher degree of freedom available for non-periodic gratings (as compared with their p...
Optical fibers or integrated optical waveguides have arbitrary cross-sectional index or refraction d...
Grating structures have found applications in microwave, millimeter wave, and optical devices and sy...
Full-wave simulations of optical waveguides are often intractable due to their large electrical size...
Based on the Galerkin's method, a numerical method is developed to analysis the cutoff frequencies o...
The propagation of electromagnetic waves in dielec-tric slab waveguides with periodic corrugations i...
International audienceClassically, waveguides are structures with uniform sections or are periodic a...
Fourier series expansion of simultaneous integral equations for collinear coupled waveguides radiati...
In the theory of integrated optics, a central role is played by the rib waveguide geometry. The elec...
Galerkin's method is employed to analyze the quasi-vector wave equation for optical waveguides with ...
We describe a method for calculating the solution of the electromagnetic field in a non-rectilinear...
A boundary Variation method for the analysis of both infinite periodic and finite aperiodic waveguid...
A boundary variation method for the fast and accurate modeling of three-dimensional waveguide gratin...
A rigorous approach for precise and efficient calculation of light propagation along nonuniform wave...
Abstract: "We have recently introduced a method of variation of boundaries for the solution of diffr...
Abstract. The higher degree of freedom available for non-periodic gratings (as compared with their p...
Optical fibers or integrated optical waveguides have arbitrary cross-sectional index or refraction d...
Grating structures have found applications in microwave, millimeter wave, and optical devices and sy...
Full-wave simulations of optical waveguides are often intractable due to their large electrical size...
Based on the Galerkin's method, a numerical method is developed to analysis the cutoff frequencies o...
The propagation of electromagnetic waves in dielec-tric slab waveguides with periodic corrugations i...
International audienceClassically, waveguides are structures with uniform sections or are periodic a...
Fourier series expansion of simultaneous integral equations for collinear coupled waveguides radiati...
In the theory of integrated optics, a central role is played by the rib waveguide geometry. The elec...
Galerkin's method is employed to analyze the quasi-vector wave equation for optical waveguides with ...