3-D refractive index adaptive gridding for finite-difference time-domain methods

A new method for refractive index adaptive meshing based on grid interfacing at material boundaries in "nite-di!erence time-domain (FDTD) methods is presented. It allows highly e$cient simulation of structures consisting of homogeneous regions with large di!erences in refractive index, which are fre

Computing time in finite-difference time-domain can be saved by expressing a portion of the grid (macromodel) as an linear time invariant (LTI) system. The output then becomes a convolution of the input with the LTI impulse response. To achieve a constant time for the convolution, the macromodel's r

This paper presents a 3D body-conforming "nite element solution of the time-dependent vector wave equation. The method uses edge elements on tetrahedra for the electric "eld interpolation. This kind of element is suited to model Maxwell's equations since it only enforces tangential continuity of vec

## Abstract The increase of the time step size significantly deteriorates the property of the coefficient matrix generated from the Crank‐Nicolson finite‐difference time‐domain (CN‐FDTD) method. As a result, the convergence of classical iterative methods, such as generalized minimal residual method