A Wire-Metamaterial-Loaded Resonant Cavity Antenna Using 3-D Printing Technology

Homogeneous dielectric slabs (HDSs) are widely used as the superstrate of resonant cavity antennas (RCAs). For HDS-loaded RCAs, the achievable directivity increases with the relative permittivity (ε,.) of the HDS. Commercial printed circuit boards with removed copper cover are usually used as the HD...

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Veröffentlicht in:	IEEE antennas and wireless propagation letters 2018-11, Vol.17 (11), p.2119-2122
Hauptverfasser:	Yu, Yin-Hua, Wu, Wen, Zong, Zhi-Yuan, Fang, Da-Gang
Format:	Artikel
Sprache:	eng
Schlagworte:	Antenna measurements Antennas Cavity resonators Circuit boards Cross polarization Dielectrics Directivity Equivalence Homogeneous dielectric Loaded antennas Metamaterials Permittivity Prototyping Reflection coefficient Reflector antennas resonant cavity antennas (RCAs) Sidelobes Slabs Three dimensional printing three-dimensionally (3-D) printed host dielectric Wire wire metamaterial (WMM)
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creator	Yu, Yin-Hua Wu, Wen Zong, Zhi-Yuan Fang, Da-Gang
description	Homogeneous dielectric slabs (HDSs) are widely used as the superstrate of resonant cavity antennas (RCAs). For HDS-loaded RCAs, the achievable directivity increases with the relative permittivity (ε,.) of the HDS. Commercial printed circuit boards with removed copper cover are usually used as the HDS superstrate, but their ε,. and thickness are limited in the market. Three-dimensional (3-D) printed HDS has the advantage of fast prototyping, process simplicity, and rigidity and can alleviate the limitation of thickness. However, the low ε,. makes it unattractive in the application of RCA serving the superstrate. In this letter, the wire metamaterial (WMM) with 3-D-printed host dielectric is used as the superstrate of RCA. The effective relative permittivity and effective thickness of the WMM are investigated. It is found that the WMM slab can be equivalent to an HDS with higher ε,. and thinner thickness. To validate the equivalence, the WMM-loaded RCA operating at 14 GHz is simulated, fabricated, and measured. The gain of 12.9 dBi, sidelobe level of -18 dB, and cross polarization of -24 dB have been achieved.
doi_str_mv	10.1109/LAWP.2018.2851204
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For HDS-loaded RCAs, the achievable directivity increases with the relative permittivity (ε,.) of the HDS. Commercial printed circuit boards with removed copper cover are usually used as the HDS superstrate, but their ε,. and thickness are limited in the market. Three-dimensional (3-D) printed HDS has the advantage of fast prototyping, process simplicity, and rigidity and can alleviate the limitation of thickness. However, the low ε,. makes it unattractive in the application of RCA serving the superstrate. In this letter, the wire metamaterial (WMM) with 3-D-printed host dielectric is used as the superstrate of RCA. The effective relative permittivity and effective thickness of the WMM are investigated. It is found that the WMM slab can be equivalent to an HDS with higher ε,. and thinner thickness. To validate the equivalence, the WMM-loaded RCA operating at 14 GHz is simulated, fabricated, and measured. The gain of 12.9 dBi, sidelobe level of -18 dB, and cross polarization of -24 dB have been achieved.</description><identifier>ISSN: 1536-1225</identifier><identifier>EISSN: 1548-5757</identifier><identifier>DOI: 10.1109/LAWP.2018.2851204</identifier><identifier>CODEN: IAWPA7</identifier><language>eng</language><publisher>New York: IEEE</publisher><subject>Antenna measurements ; Antennas ; Cavity resonators ; Circuit boards ; Cross polarization ; Dielectrics ; Directivity ; Equivalence ; Homogeneous dielectric ; Loaded antennas ; Metamaterials ; Permittivity ; Prototyping ; Reflection coefficient ; Reflector antennas ; resonant cavity antennas (RCAs) ; Sidelobes ; Slabs ; Three dimensional printing ; three-dimensionally (3-D) printed host dielectric ; Wire ; wire metamaterial (WMM)</subject><ispartof>IEEE antennas and wireless propagation letters, 2018-11, Vol.17 (11), p.2119-2122</ispartof><rights>Copyright The Institute of Electrical and Electronics Engineers, Inc. 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For HDS-loaded RCAs, the achievable directivity increases with the relative permittivity (ε,.) of the HDS. Commercial printed circuit boards with removed copper cover are usually used as the HDS superstrate, but their ε,. and thickness are limited in the market. Three-dimensional (3-D) printed HDS has the advantage of fast prototyping, process simplicity, and rigidity and can alleviate the limitation of thickness. However, the low ε,. makes it unattractive in the application of RCA serving the superstrate. In this letter, the wire metamaterial (WMM) with 3-D-printed host dielectric is used as the superstrate of RCA. The effective relative permittivity and effective thickness of the WMM are investigated. It is found that the WMM slab can be equivalent to an HDS with higher ε,. and thinner thickness. To validate the equivalence, the WMM-loaded RCA operating at 14 GHz is simulated, fabricated, and measured. The gain of 12.9 dBi, sidelobe level of -18 dB, and cross polarization of -24 dB have been achieved.</description><subject>Antenna measurements</subject><subject>Antennas</subject><subject>Cavity resonators</subject><subject>Circuit boards</subject><subject>Cross polarization</subject><subject>Dielectrics</subject><subject>Directivity</subject><subject>Equivalence</subject><subject>Homogeneous dielectric</subject><subject>Loaded antennas</subject><subject>Metamaterials</subject><subject>Permittivity</subject><subject>Prototyping</subject><subject>Reflection coefficient</subject><subject>Reflector antennas</subject><subject>resonant cavity antennas (RCAs)</subject><subject>Sidelobes</subject><subject>Slabs</subject><subject>Three dimensional printing</subject><subject>three-dimensionally (3-D) printed host dielectric</subject><subject>Wire</subject><subject>wire metamaterial (WMM)</subject><issn>1536-1225</issn><issn>1548-5757</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNo9kFtLwzAUx4MoOKcfQHwp-JyZS9Okj2VeYeKQjT2GNDmdHVs6k0zYt7dl4tM5h_O_wA-hW0omlJLyYVat5hNGqJowJSgj-RkaUZErLKSQ58POC0wZE5foKsYNIVQWgo_QvMpWbQD8DsnsTILQmi2edcaByz4hdt74lE3NT5uOWeUTeG-yZWz9OuP4MZuH1qfhWID98t22Wx-v0UVjthFu_uYYLZ-fFtNXPPt4eZtWM2xZyRPmxLGaMWZtQYTLCwWNLWqoc3ASGlqT4U8dkdY01DDqqKtVWUrVcMeElXyM7k-5-9B9HyAmvekOwfeVmlEmyzIvyrxX0ZPKhi7GAI3eh3ZnwlFTogdwegCnB3D6D1zvuTt5WgD41yveR6qC_wKgd2ll</recordid><startdate>20181101</startdate><enddate>20181101</enddate><creator>Yu, Yin-Hua</creator><creator>Wu, Wen</creator><creator>Zong, Zhi-Yuan</creator><creator>Fang, Da-Gang</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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For HDS-loaded RCAs, the achievable directivity increases with the relative permittivity (ε,.) of the HDS. Commercial printed circuit boards with removed copper cover are usually used as the HDS superstrate, but their ε,. and thickness are limited in the market. Three-dimensional (3-D) printed HDS has the advantage of fast prototyping, process simplicity, and rigidity and can alleviate the limitation of thickness. However, the low ε,. makes it unattractive in the application of RCA serving the superstrate. In this letter, the wire metamaterial (WMM) with 3-D-printed host dielectric is used as the superstrate of RCA. The effective relative permittivity and effective thickness of the WMM are investigated. It is found that the WMM slab can be equivalent to an HDS with higher ε,. and thinner thickness. To validate the equivalence, the WMM-loaded RCA operating at 14 GHz is simulated, fabricated, and measured. 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subjects	Antenna measurements Antennas Cavity resonators Circuit boards Cross polarization Dielectrics Directivity Equivalence Homogeneous dielectric Loaded antennas Metamaterials Permittivity Prototyping Reflection coefficient Reflector antennas resonant cavity antennas (RCAs) Sidelobes Slabs Three dimensional printing three-dimensionally (3-D) printed host dielectric Wire wire metamaterial (WMM)
title	A Wire-Metamaterial-Loaded Resonant Cavity Antenna Using 3-D Printing Technology
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