The fourth and sixth sections discuss how to set up the propagator simulation. Section 2 and section 3 use the eigenmode solver and the analytical results from the discussion and results section to design the ring resonator.
lms file and proceed to the following steps if you want to know the results first. You can skip this step, open the associated. The first section describes how to setup the model. Compare results with the theoretical design and 3D FDTD results.Use the Eigenmode Solver to choose the waveguide spacing, coupling length and ring length for the desired FSR and Q factor.Insert a ring resonator object from the components library.In this example, we show how MODE can be used to design a ring resonator. Part 3: Final parameter extraction using FDTD Learning objectives Part 2: Parameter extraction and Monte Carlo using MODE Part 1: Design and initial simulation using MODE Part 3 does the final simulation and parameter extraction using a 3D FDTD simulation.
In Part 2, we will consider how to carry out the parameter extraction and Monte Carlo analysis process for this design. Free spectral range (FSR) and quality factor (Q factor) are key performance metrics for this silicon on insulator (SOI) based waveguide design targeting on-chip communication applications. Part 1 of the ring resonator tutorial uses MODE to design and simulate a ring resonator.
