This modeling tool computes the effective complex permittivity and permeability of composite materials at GHz frequencies. It captures how microscopic material composition influences macroscopic electromagnetic behavior by incorporating inclusion properties, volume fraction, geometry, and frequency dependence. The result is an accurate prediction of how real composite materials interact with electromagnetic fields in RF and microwave regimes.

The computational platform supports a broad class of composite materials, including mixtures with dielectric or magnetic inclusions embedded in polymer, ceramic, or magnetic host media. It is suitable for multi-phase, lossy, and frequency-dispersive materials commonly encountered in RF and microwave engineering, and is designed to model realistic composite structures rather than idealized homogeneous media.

This solver has demonstrated close agreement with experimental measurements of effective permittivity and permeability across the GHz frequency range. The underlying models are grounded in electromagnetic theory and calibrated to capture the dominant physical mechanisms governing composite material response. As a result, the predictions provide reliable correspondence with measured data while enabling rapid evaluation of material configurations without the cost and time associated with repeated fabrication and testing.