A compact one‐dimensional modal FDTD method

Abstract: SUMMARYThe finite-difference time-domain (FDTD) method is an effective technique for computing wideband electrical parameters such as scattering parameters of waveguide structures. in the computations, a known incident is normally required and is usually obtained with a simulation of a long uniform structure. For a three-dimensional problem, simulation of a long structure can be very memory-and CPU time-intensive. In addition, effective absorbing boundary conditions are needed to effectively terminate the stru… Show more

“…This is a multi‐grid procedure that generates a local mesh for each object and interconnects the result using Green's function instead of interpolation techniques. The paper by Luo and Chen 2 describes an innovative modelling algorithm for wave propagation along transmission structures with a uniform cross section; the algorithm has the same accuracy as a complete three‐dimensional routine but requires only a fraction of the CPU time compared with the latter method. The paper by Firsov and LoVetri 3 combines FVTD with integral equations; the implementation allows physical objects to be placed arbitrarily close to the absorbing boundaries situated on the mesh surface without compromising accuracy.…”

Guest Editorial

“…This is a multi‐grid procedure that generates a local mesh for each object and interconnects the result using Green's function instead of interpolation techniques. The paper by Luo and Chen 2 describes an innovative modelling algorithm for wave propagation along transmission structures with a uniform cross section; the algorithm has the same accuracy as a complete three‐dimensional routine but requires only a fraction of the CPU time compared with the latter method. The paper by Firsov and LoVetri 3 combines FVTD with integral equations; the implementation allows physical objects to be placed arbitrarily close to the absorbing boundaries situated on the mesh surface without compromising accuracy.…”

Guest Editorial

Application of the Modal CFS-PML-FDTD to the Analysis of Magnetic Photonic Crystal Waveguides