Title :
A hybrid FDTD-transfer matrix method applicable to adiabatic photonic simulation
Author :
Samolis, Christos D. ; Daniel, Luca
Author_Institution :
Res. Lab. of Electron., Massachusetts Inst. of Technol., Cambridge, MA, USA
Abstract :
This paper reports on an algorithm that permits the efficient optical simulation of adiabatic photonic structures with the accuracy of FDTD1. Using a transfer matrix method we divide the simulation window into modular blocks, which can then be cascaded yielding the final result. Sequential time-domain simulation of each block provides a linear speed-up as well as a memory advantage when compared to performing an FDTD simulation for the entire device. Furthermore, the method also allows for temporal parallelization in addition to the spatial parallelizability inherent to FDTD.
Keywords :
finite difference time-domain analysis; optical elements; optical engineering computing; sequential estimation; time-domain analysis; transfer function matrices; adiabatic photonic structures; hybrid FDTD-transfer matrix method; optical simulation; sequential time-domain simulation; spatial parallelizability; temporal parallelization; Accuracy; Computational modeling; Finite difference methods; Mathematical model; Optical pulses; Photonics; Time-domain analysis; Adiabatic mode evolution; Finite difference time domain; Photonics; Transfer matrices;
Conference_Titel :
Applied Computational Electromagnetics (ACES), 2015 31st International Review of Progress in
Conference_Location :
Williamsburg, VA
