Contact Information (202) 64-EMLAB [email protected]500 West University Avenue El Paso, TX 79912 hp://emlab.utep.edu/ Research Accomplishments Spatially Variant Lattices Capable of spaally varying unit cell orientaon, lace spacing, fill fracon, material composion, and more, in arbitrary paerns without deforming the unit cells or introducing defects. Spatially Variant Anisotropic Metamaterials (SVAMs) Improves electromagnec compability by reshaping the near-field around components. Excellent for placing antennas and other components in close proximity. Spatially Variant Photonic Crystals Controls light in three dimensions with unprecedented abruptness even using low refracve index. World record for ghtest bend of unguided opcal beam. Able to mulplex different funcons and physics within the same volume of space. High Power Microwave Frequency Selective Surfaces Demonstrated world’s highest power FSS operang in excess of 2.0 GW. Also broke records for bandwidth and field-of-view. Computational EM Developed an extensive suite of custom algorithms for simulang and opmizing advanced electromagnec devices. Imagine what is next! Pioneering 21st Century Electromagnetics and Photonics Stereo image of EM Lab logo
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Capable of spatially varying unit cell orientation, lattice spacing, fill fraction, material composition, and more, in arbitrary patterns without deforming the unit cells or introducing defects.
Improves electromagnetic compatibility by reshaping the near-field around components. Excellent for placing antennas and other components in close proximity.
Spatially Variant Photonic Crystals
Controls light in three dimensions with unprecedented abruptness even using low refractive index. World record for tightest bend of unguided optical beam. Able to multiplex different functions and physics within the same volume of space.
High Power Microwave Frequency Selective Surfaces
Demonstrated world’s highest power FSS operating in excess of 2.0 GW. Also broke records for bandwidth and field-of-view.
Computational EM
Developed an extensive suite of custom algorithms for simulating and optimizing advanced electromagnetic devices.
Imagine what is next!
Pioneering 21st Century Electromagnetics and Photonics
Custom Software Our custom tools execute much faster and incorporate more physics than commercial packages.
Finite-Difference Time-Domain Finite-Difference Frequency-Domain Method of Moments Transfer Matrix Method Method of Lines Rigorous Coupled-Wave Analysis Plane Wave Expansion Method Particle Swarm Optimization
Genetic Algorithms Transformation Optics
Fast Marching Method Spatially-Variant Lattices
Research Areas
3D Printed Circuits and Systems
Metamaterials and Photonic Crystals
Antennas and Frequency Selective Surfaces
Computational Electromagnetics
3D Printing Hybrid 3D Printing: simultaneous
dielectrics, conductors, and laser cutting/sintering with extreme resolution.
Multi-filament FDM 3D high-frequency circuits. Embedded and structural
electronics. Immediate access to: stereo-
lithography, electron beam melting, selective laser sintering, Objet, ZCorp, nScrypt, and many others.
Traditional Manufacturing Immediate access to: CNC
machining, welding, plating, injection molding, etc.
Manufacturing Capabilities
Device Testing Anechoic chamber and open desert. Vector network analyzer. Vector signal analyzer/generator. Spectrum analyzers. EMI shielded room. Microscopes and probe station for
testing micro-circuits. Oscilloscopes, power supplies,
function generators, and more.
Materials Characterization , , tan, anisotropy, and
dielectric breakdown. Waveguide and split-cavity
Test and Measurement Capabilities
Pioneering 21st Century Electromagnetics and Photonics