A novel geometry of unit cells relying on printed technology and featuring full dispersion diagram (DD) exhibiting an unusual large number of electromagnetic band-gaps (EBGs) is proposed. The printed patch consists of a filter-like geometry, meandered around the symmetry center of the unit cell and connected to the ground plane by three aligned vias, locally increasing the loading inductances; the multiple resonances shown by the structure determine the limits of the band-gaps. In particular, the DD of the unit cell presents an EBG between every two consecutive modes of propagation within the first eight modes in the case of one-directional propagation. The same phenomenon has been demonstrated for 2-D propagation, where four EBGs are proven to exist between the first five modes, in the case of arbitrarily directed propagation in the main plane of the structure. The 2-D scanning needed for building up the full DDs is realized by computer simulation with dedicated software. The small differences in band limits between the 1-D and 2-D cases reflect a small amount of anisotropy. The wide range of mono-modal behavior allows the structure to be used in applications requiring selective filtering, e.g., direct incorporation into antenna feeding systems, self-collimation, super lens, etc.

Unit-cell geometry in stripline technology featuring sequential band-gaps between every two consecutive modes / A., De Sabata; Matekovits, Ladislau. - In: IEEE ANTENNAS AND WIRELESS PROPAGATION LETTERS. - ISSN 1536-1225. - STAMPA. - 11:(2012), pp. 97-100. [10.1109/LAWP.2012.2183848]

Unit-cell geometry in stripline technology featuring sequential band-gaps between every two consecutive modes

MATEKOVITS, Ladislau
2012

Abstract

A novel geometry of unit cells relying on printed technology and featuring full dispersion diagram (DD) exhibiting an unusual large number of electromagnetic band-gaps (EBGs) is proposed. The printed patch consists of a filter-like geometry, meandered around the symmetry center of the unit cell and connected to the ground plane by three aligned vias, locally increasing the loading inductances; the multiple resonances shown by the structure determine the limits of the band-gaps. In particular, the DD of the unit cell presents an EBG between every two consecutive modes of propagation within the first eight modes in the case of one-directional propagation. The same phenomenon has been demonstrated for 2-D propagation, where four EBGs are proven to exist between the first five modes, in the case of arbitrarily directed propagation in the main plane of the structure. The 2-D scanning needed for building up the full DDs is realized by computer simulation with dedicated software. The small differences in band limits between the 1-D and 2-D cases reflect a small amount of anisotropy. The wide range of mono-modal behavior allows the structure to be used in applications requiring selective filtering, e.g., direct incorporation into antenna feeding systems, self-collimation, super lens, etc.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2498242
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