Litcius/Paper detail

Inverse design of a binary waveguide crossing by the particle swarm optimization algorithm

Kiyanoush Goudarzi, Moonjoo Lee

2022Results in Physics26 citationsDOIOpen Access PDF

Abstract

This paper describes the inverse design of the particle swarm optimization algorithm combined with the three-dimensional finite-difference time-domain simulation to design a waveguide crossing that resembles a binary code. The device consists of 15 × 15 air holes in a 220-nm silicon slab on a 3-μm-thick SiO2 substrate with one input port and three output waveguide ports. The designed device has a small footprint of 4μm2 and a short simulation time of 1.7 h. In the wavelength range of 1.5–1.6μm, the device has insertion loss IL<0.85 dB and crosstalk XT<−14.5 dB. This device tolerates air hole-position disordering of ηp=23%, and hole-radius disordering of ηr=35%, so it is appropriate to use in the complementary metal–oxide–semiconductor fabrication process. The paper also proposes integrated interconnections that contain 2 × 2 waveguide crossings and have IL<2.9 dB and XT<−13 dB, and 3 × 3 waveguide crossings that have IL<5 and XT<−12.5 dB.

Topics & Concepts

Particle swarm optimizationWaveguideInsertion lossInverseOpticsMaterials sciencePhysicsAlgorithmOptoelectronicsComputer scienceMathematicsGeometryPhotonic and Optical DevicesPhotonic Crystals and ApplicationsOptical Coatings and Gratings