Beam propagation method based on fast fourier transform and finite difference schemes and its application to optical diffraction grating

Abstract EN

Accurate modeling of photonic devices is essential for the development of new higher performance optical components required by current and future large or wide bandwidth communication systems.

This paper introduces several key techniques for such modeling, many of which are used in commercial design tools.

These include several techniques of the beam propagation methods (BPM), such as fast Fourier transform ( FFTBPM), wide angle fast Fourier transform ( WAFFT-BPM), scalar finite difference (FD-BPM), scalar wide angle finite difference beam propagation method (WAFD-BPM), Generalized Douglas finite difference (GDFD-BPM), and full vectorial finite difference beam propagation method (FVFD-BPM).

The numerical simulations are applied to a real optical diffraction grating fabricated by a double–ion exchange technique.