Numerical scheme for simulation of self-pulsing and chaos in coupled microring resonators

Numerical scheme for simulation of self-pulsing and chaos in coupled microring resonators

Peer-reviewed article not indexed in WoS or Scopus

Nonlinear coupled equations that describe propagation of optical pulses in waveguide structures under the slowly varying envelope approximation are solved by a simple explicit finite-difference scheme. The technique, which is based on upwind differencing, is used for modeling of Kerr-nonlinear structures with microring resonators in all-pass filter configuration. We show numerical examples that demonstrate existence of self-pulsing and chaotic solutions.

Nonlinear coupled equations that describe propagation of optical pulses in waveguide structures under the slowly varying envelope approximation are solved by a simple explicit finite-difference scheme. The technique, which is based on upwind differencing, is used for modeling of Kerr-nonlinear structures with microring resonators in all-pass filter configuration. We show numerical examples that demonstrate existence of self-pulsing and chaotic solutions.

coupled mode theory, nonlinear optics, ring resonator, self-pulsing, chaos

coupled mode theory, nonlinear optics, ring resonator, self-pulsing, chaos

PETRÁČEK, J.; STERKHOVA, A.; LUKSCH, J.

2013

01.10.2011

Wiley Periodicals, Inc.

0895-2477

MICROWAVE AND OPTICAL TECHNOLOGY LETTERS

53

10

United States of America

2238

2242

5