Difference between revisions of "EM.Cube Application Gallery"
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[[image:prop-ico.png | link=EM.Terrano]] </td> | [[image:prop-ico.png | link=EM.Terrano]] </td> | ||
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| − | [[image:Terrano | + | [[image:Terrano L5N Fig title.png|60px | link=EM.Terrano Tutorial Lesson 5: Simulating A Dense Urban Canyon Propagation Scene]] [[image:Terrano L7N Fig title.png|60px | link=EM.Terrano Tutorial Lesson 7: Parametric Study Of A Realistic Urban Scene]] [[image:Terrano L8N Fig title.png|60px | link=EM.Terrano Tutorial Lesson 8: Simulating A Communications Link With Directional Antennas]] [[image:Terrano L9N Fig title.png|60px | link=EM.Terrano Tutorial Lesson 9: Modeling A Mobile Communications Link Using Python]] [[image:ART MANH Fig title.png|60px | link=Application Note 2: Modeling Polarimetric Wave Propagation In The Lower Manhattan Scene Using EM.Terrano]] </td> |
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Revision as of 20:09, 24 June 2017
EM.Cube provides the ultimate solution to all of your electromagnetic modeling needs. Using EM.Cube's computational modules, you can solve a wide range of EM analysis and RF design problems. These modules together cover the entire frequency spectrum from DC to light. The following table lists a few examples of electromagnetic modeling problems you can solve with one or more EM.Cube modules:
| Problem Type / Application | Suitable EM.Cube Module | Example Projects, Notes or Articles |
| Analyze directional communication links in high multipath urban environments |
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| Model large, finite-sized, antenna arrays on the transmitter and receiver ends |
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| Evaluate platform and feed mechanism effects on the radiation characteristics of antenna systems |
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| Design multilayer planar RF, microwave and millimeter wave circuits |
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| Analyze metallic and dielectric waveguide and resonator structures for microwave and millimeter wave applications |
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| Embed passive and active devices and circuits into your electromagnetic analysis |
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| Model frequency response of multiport structures and generate S-parameter data for equivalent circuit models (for export to RF.Spice A/D) |
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| Model transient propagation of arbitrary waveforms and signals in your circuits |
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| Investigate the interaction of incident plane waves and focused Gaussian beams with complex geometries, biological environments or dispersive materials |
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| Study reflection and transmission properties of periodic surfaces and metamaterial structures |
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| Compute low frequency electric and magnetic fields, capacitance and inductance of lumped circuit devices |
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| Compute quasi-static characteristic impedance and effective permittivity of physical transmission lines |
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| Build complex structures using native standard geometric objects or custom expression-based curves & surface and import/export external CAD models |
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| Compute radar cross section (RCS) of complex targets |
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| Run parametric and random sweeps of design variables with complex interdependencies defined through mathematical functions and/or Python scripts |
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| Optimize your design variables using classical and statistical methods including multi-objective Pareto genetic algorithms |
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| Run lightning fast EM simulations on multicore CPU/GPU platforms using a variety of hardware and software accelerators |
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