![]() ![]() Instructions for running the model and discussion of key results If you are new to this example, we strongly recommend going through the preceding sections and learning about the individual steps before moving to the Advanced users already familiar with this example can proceed to this section directly. Section uses a script to automatically go through these steps and extract the data for CML Compiler in the required format. ![]() To generate the compact model of the waveguide with CML Compiler, simply skip Step 3 and provide the data extracted in Steps 1 and 2 to CML Compiler. Import the waveguide data into INTERCONNECT to create a new waveguide element that can be used in a circuit simulation.Ĭompact Model Generation With CML Compiler Step 3: Import Waveguide Data in INTERCONNECT Run a frequency sweep to obtain their properties as a function of the frequency/wavelength. The solver provides a comprehensive list of mode properties including spatial mode profile, effective index, loss, etc. ![]() The characterization of the waveguide is done using the FDE solver in MODE.Ĭalculate the supported modes from a 2D cross section of the waveguide. Understand the simulation workflow and key results How to extract these parameters for compact model generation using the CML Compiler is also demonstrated. The calculated mode parameters are then used to create a waveguide element in INTERCONNECT. In this example, the Finite Difference Eigenmode (FDE) solver in MODE is used to characterize a straight waveguide. ![]()
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