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High-Efficiency Refracting Millimeter-Wave Metasurfaces

Andreas E. Olk, Pierre E. M. Macchi, David A. Powell

2020IEEE Transactions on Antennas and Propagation31 citationsDOIOpen Access PDF

Abstract

Printed circuit metasurfaces have attracted significant attention in the microwave community for their versatile wavefront manipulation capability. Despite their promising potential in telecommunications and radar applications, few transmissive metasurfaces have been reported operating at millimeter-wave frequencies. Several secondary effects including fabrication tolerances, interlayer near-field coupling, and the roughness of conductors are more severe at such high frequencies and can cause significant performance degradation. Additionally, very accurate experimental techniques are required in order to characterize these effects. In this article, we present highly efficient refracting metasurfaces operating at 83GHz. We use a synthesis technique that minimizes performance degradation due to effects such as interlayer near-field coupling and conductor roughness. Our experimental characterization includes an accurate determination of the intensity of all forward propagating Floquet harmonics in a broad frequency range. The experimental data show very good agreement with full-wave simulation and verify our synthesis method.

Topics & Concepts

OpticsWavefrontElectrical conductorFloquet theoryMaterials scienceMicrowaveConductorHarmonicsFabricationMetamaterialPerfect conductorPrinted circuit boardRadarOptoelectronicsSurface roughnessCharacterization (materials science)Surface finishEquivalent circuitTerahertz radiationFinite-difference time-domain methodCoupling (piping)PhysicsRadar imagingFrequency responseRadar cross-sectionMicrowave imagingHarmonic analysisRadomeSynthetic aperture radarSurface waveImpedance matchingBroadbandRangingComputer sciencePolarizerMetamaterials and Metasurfaces ApplicationsAdvanced Antenna and Metasurface TechnologiesAdvanced Wireless Communication Technologies
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