Cherif, A.; Himdi, M.; Castel, X.; Simon, Q.; Dakhli, S.; Choubani, F. Radiation Beam Width and Beam Direction Electronic Control of Transparent and Compact Vivaldi Antennas. Appl. Sci.2023, 13, 7878.
Cherif, A.; Himdi, M.; Castel, X.; Simon, Q.; Dakhli, S.; Choubani, F. Radiation Beam Width and Beam Direction Electronic Control of Transparent and Compact Vivaldi Antennas. Appl. Sci. 2023, 13, 7878.
Cherif, A.; Himdi, M.; Castel, X.; Simon, Q.; Dakhli, S.; Choubani, F. Radiation Beam Width and Beam Direction Electronic Control of Transparent and Compact Vivaldi Antennas. Appl. Sci.2023, 13, 7878.
Cherif, A.; Himdi, M.; Castel, X.; Simon, Q.; Dakhli, S.; Choubani, F. Radiation Beam Width and Beam Direction Electronic Control of Transparent and Compact Vivaldi Antennas. Appl. Sci. 2023, 13, 7878.
Abstract
A printed Vivaldi antenna that is optically transparent, ultra-wideband (UWB), and reconfigurable has been developed, fabricated, and tested at millimeter wave frequencies. It covers a broad frequency range of 20-30 GHz by using three PIN diodes. The diodes control the current flow to direct the beam of the antenna. The results of numerical simulations and measurements match at millimeter wave frequencies. The design of this antenna is unique as it allows for a reduction in size and ease of integration while also providing the ability to change the radiation pattern by up to 300 degrees, making it suitable for 5G and 6G communications. Additionally, this antenna can also be useful for RF applications that require dynamic switching of radiation patterns and cognitive radio.
Keywords
Optical transparency; Vivaldi antenna; Active antenna; Reconfigurability; Wide band frequency
Subject
Physical Sciences, Optics and Photonics
Copyright:
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