---
res:
  bibo_abstract:
  - Typical optical integrated circuits combine elements, like straight and curved
    waveguides, or cavities, the simulation and design of which is well established
    through numerical eigenproblem-solvers. It remains to predict the interaction
    of these modes. We address this task by a ”Hybrid” variant (HCMT) of Coupled Mode
    Theory. Using methods from finite-element numerics, the optical properties of
    a circuit are approximated by superpositions of eigen-solutions for its constituents,
    leading to quantitative, low-dimensional, and interpretable models in the frequency
    domain. Spectral scans are complemented by the direct computation of supermode
    properties (spectral positions and linewidths, coupling-induced phase shifts).
    This contribution outlines the theoretical background, and discusses briefly limitations
    and implementational details, with the help of an example of a 2-D coupled-resonator-optical-waveguide
    configuration.@eng
  bibo_authorlist:
  - foaf_Person:
      foaf_givenName: Manfred
      foaf_name: Hammer, Manfred
      foaf_surname: Hammer
      foaf_workInfoHomepage: http://www.librecat.org/personId=48077
    orcid: 0000-0002-6331-9348
  bibo_doi: 10.1117/12.2214331
  bibo_issue: '9750'
  dct_date: 2016^xs_gYear
  dct_language: eng
  dct_publisher: SPIE@
  dct_subject:
  - tet_topic_waveguide
  - tet_topic_numerics
  dct_title: 'Wave interaction in photonic integrated circuits: Hybrid analytical
    / numerical coupled mode modeling@'
...