Mician Uwave Wizard

Users build designs by connecting elements in a schematic-like environment, rather than drawing a single large 3D object.

: Faster CPU time compared to full 3D meshes makes it ideal for repetitive optimization tasks.

Because the Mode-Matching technique uses analytical solutions for these building blocks, it is often orders of magnitude faster than full-wave solvers like CST Microwave Studio or Ansys HFSS . Mician Uwave Wizard

In a practical application of a C-band OMT, researchers achieved an input return loss of roughly 25 dB and an isolation of over 70 dB between polarization channels. The tool's speed allowed engineers to quickly optimize the device for high-performance requirements. Mician μWave Wizard vs. 3D EM Simulators

Developing corrugated horns and complex feeding networks for radio telescopes and satellite ground stations. Users build designs by connecting elements in a

Essential for separating orthogonal polarization states in satellite dishes and radar feeds.

A key application of μWave Wizard is in the design of high-performance Orthomode Transducers. Studies have shown that configuration and optimization of OMTs can be entirely managed within μWave Wizard, offering superior efficiency over purely numerical solvers. In a practical application of a C-band OMT,

At its core, μWave Wizard uses the technique. Unlike time-domain solvers that subdivide a volume into millions of tiny voxels (mesh cells), Mode-Matching uses analytical solutions to Maxwell's equations in different waveguide sections (rectangular, circular, coaxial, ridged). It matches the field modes at the boundaries between these sections.