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Demonstration of a micromachined planar distribution network in gap waveguide technology for a linear slot array antenna at 100 GHz

Sofia Rahiminejad (Institutionen för mikroteknologi och nanovetenskap, Elektronikmaterial och system ) ; Ashraf Uz Zaman (Institutionen för signaler och system, Antennsystem) ; Haasl Sjoerd (Institutionen för mikroteknologi och nanovetenskap, Elektronikmaterial och system ) ; Per-Simon Kildal (Institutionen för signaler och system, Antennsystem) ; Peter Enoksson (Institutionen för mikroteknologi och nanovetenskap, Elektronikmaterial och system )
Journal of Micromechanics and Microengineering (0960-1317). Vol. 26 (2016), 7, p. Art. no. 074001.
[Artikel, refereegranskad vetenskaplig]

The need for high frequency antennas is rapidly increasing with the development of new wireless rate communication technology. Planar antennas have an attractive form factor, but they require a distribution network. Microstrip technology is most commonly used at low frequency but suffers from large dielectric and ohmic losses at higher frequencies and particularly above 100 GHz. Substrate-integrated waveguides also suffer from dielectric losses. In addition, standard rectangular waveguide interfaces are inconvenient due to the four flange screws that must be tightly fastened to the antenna to avoid leakage. The current paper presents a planar slot array antenna that does not suffer from any of these problems. The distribution network is realized by micromachining using low-loss gap waveguide technology, and it can be connected to a standard rectangular waveguide flange without using any screws or additional packaging. To realize the antenna at these frequencies, it was fabricated with micromachining, which offers the required high precision, and a low-cost fabrication method. The antenna was micromachined with DRIE in two parts, one silicon-on-insulator plate and one Si plate, which were both covered with Au to achieve conductivity. The input reflection coefficient was measured to be below 10 dB over a 15.5% bandwidth, and the antenna gain was measured to be 10.4 dBi, both of which are in agreement with simulations.

Nyckelord: antenna; gap waveguide; GHz; high-frequency; metamaterial; RF-MEMS; Si

Denna post skapades 2016-09-16. Senast ändrad 2017-07-13.
CPL Pubid: 241914


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