Title :
Low-Power All-Optical Switch Based on Time-Reversed Microring Laser
Author_Institution :
Sch. of Eng. & Technol., Central Michigan Univ., Mount Pleasant, MI, USA
Abstract :
An all-optical switch based on an absorbing microring resonator laterally coupled to two waveguides is described theoretically using the coupling of modes in time formalism and numerically using the finite-difference time-domain method. The operating principle of the device is based on the recently published time-reversed laser concept. The proposed switch relies on a combination of coherent interference and absorption in the microring and does not require nonlinear refractive index changes. It has a smaller footprint than other approaches, and it is capable of converting frequency- or phase-shift-keyed digital signals to amplitude-shift-keyed signals for direct detection.
Keywords :
amplitude shift keying; finite difference time-domain analysis; infrared spectra; laser modes; light interference; micro-optomechanical devices; microcavity lasers; micromechanical resonators; optical frequency conversion; optical switches; phase shift keying; ring lasers; waveguide lasers; absorption; amplitude-shift-keyed signals; coherent interference; direct detection; finite-difference time-domain method; frequency-shift-keyed digital signal; laterally coupled absorbing microring resonator; low-power all-optical switch; mode coupling; phase-shift-keyed digital signal; time formalism; time-reversed microring laser; waveguides; Absorption; Couplings; Nonlinear optics; Optical resonators; Optical switches; Optical waveguides; Waveguide lasers; Theory and design; coherent effects; integrated nanophotonic systems; modeling; optics; waveguide devices;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2012.2229265
