Sofia Rahiminejad - Technologist - NASA Jet Propulsion Laboratory | LinkedIn
Realizing a 140 GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining | SpringerLink
Micromachines | Free Full-Text | Dry Film Photoresist-Based Microfabrication: A New Method to Fabricate Millimeter-Wave Waveguide Components
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Realizing a 140 GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining | SpringerLink
PDF) Carbon Nanotubes as Base Material for Fabrication of Gap Waveguide Components
PDF) The SWE Gapwave antenna - A new wideband thin planar antenna for 60GHz communications
Realizing a 140 GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining | SpringerLink
Design of Micromachined Ridge Gap Waveguides for Millimeter-Wave Applications
PDF) Realizing a 140-GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining
Micromachined gap waveguides for 100 GHz applications
PDF) Micromachined contactless pin-flange adapter for robust high-frequency measurements
Realizing a 140 GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining | SpringerLink
Årsberättelse 2016 | Chalmers
Sofia Rahiminejad - Technologist - NASA Jet Propulsion Laboratory | LinkedIn
Design of Micromachined Ridge Gap Waveguides for Millimeter-Wave Applications
Realizing a 140 GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining | SpringerLink
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Micromachines | Free Full-Text | Dry Film Photoresist-Based Microfabrication: A New Method to Fabricate Millimeter-Wave Waveguide Components
Realizing a 140 GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining | SpringerLink
Evaluation of losses of the Ridge Gap Waveguide at 100 GHz
Chalmers Research: Sadia Farjana
Realizing a 140 GHz Gap Waveguide–Based Array Antenna by Low-Cost Injection Molding and Micromachining | SpringerLink
