Effects of extreme surface roughness on 3D printed horn antenna

3D printing is an emerging technology in manufacturing. It is the long-term goal of the industry to print complex and fully functional products from cell phones to vehicles. A drawback of many 3D printing technologies is rough surface finish. It is known that metals with high surface roughness sever...

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Veröffentlicht in:	Electronics letters 2013-06, Vol.49 (12), p.734-736
Hauptverfasser:	Garcia, C.R, Rumpf, R.C, Tsang, H.H, Barton, J.H
Format:	Artikel
Sprache:	eng
Schlagworte:	3D printed horn antenna 3D printing technologies Antennas Antennas and propagation Applied sciences cell phones electromagnetic impact electromagnetic wave propagation Exact sciences and technology extreme surface roughness frequency 12 GHz to 15 GHz microstrip antennas microwave antennas Radiocommunications surface roughness Telecommunications Telecommunications and information theory three‐dimensional printing vehicles
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creator	Garcia, C.R Rumpf, R.C Tsang, H.H Barton, J.H
description	3D printing is an emerging technology in manufacturing. It is the long-term goal of the industry to print complex and fully functional products from cell phones to vehicles. A drawback of many 3D printing technologies is rough surface finish. It is known that metals with high surface roughness severely degrade the propagation of electromagnetic waves. Presented is the first known evaluation of the electromagnetic impact of the typical surface roughness in metal parts produced by electron beam melting. Two Ku-band (12–15 GHz) horn antennas were 3D printed, with different surface roughness, and compared to a standard horn antenna purchased from Pasternack.
doi_str_mv	10.1049/el.2013.1528
format	Article
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subjects	3D printed horn antenna 3D printing technologies Antennas Antennas and propagation Applied sciences cell phones electromagnetic impact electromagnetic wave propagation Exact sciences and technology extreme surface roughness frequency 12 GHz to 15 GHz microstrip antennas microwave antennas Radiocommunications surface roughness Telecommunications Telecommunications and information theory three‐dimensional printing vehicles
title	Effects of extreme surface roughness on 3D printed horn antenna
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