A Compact Metamaterial-Based Antenna for Multiband Phased Array Applications

In this communication, we present a miniaturized multiband metamaterial (MTM)-based antenna for array applications, operating with good radiation performance over the long term evolution (LTE) and Universal Mobile Telecommunications System (UMTS) uplinks within the 800-3000 MHz range. Each antenna e...

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Bibliographic Details
Published in:IEEE transactions on antennas and propagation 2021-12, Vol.69 (12), p.8872-8877
Main Authors: Gallardo, Diego, Monasterio, David, Finger, Ricardo, Mena, F. Patricio, Bronfman, Leonardo
Format: Article
Language:English
Subjects:
Antenna arrays
Antennas
Bandwidth
Broadband antennas
Conductors
Electric communication systems
Electric conductors
Extraterrestrial radiation
Half spaces
Metamaterials
metasurface
multifrequency antennas
Phased arrays
Radiation
Radiators
Response functions
Spiral antennas
Spirals
Telecommunications systems
Universal Mobile Telecommunications System (UMTS)
Uplink
Uplinking
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Summary:In this communication, we present a miniaturized multiband metamaterial (MTM)-based antenna for array applications, operating with good radiation performance over the long term evolution (LTE) and Universal Mobile Telecommunications System (UMTS) uplinks within the 800-3000 MHz range. Each antenna element consists of a radiator and an MTM reflector. The former is a miniaturized Archimedean spiral antenna with an integrated matching line. The latter is placed 39 mm below the radiator and is shared among the multiple elements in the array application. The radiator is very compact, a square of 75 mm per side, equivalent to only 0.2 (0.75) times the free-space wavelength at 800 MHz (3000 MHz). The reflector is incorporated to achieve half-space radiation and is implemented with a novel multilayered MTM structure to improve the radiation efficiency. The MTM, moreover, is used in a nonconventional way. In fact, we take advantage of its complete phase-response function, behaving, thus, as a magnetic or electric conductor in different parts of the band. In this way, the in-phase reflection is not limited by the typical narrow bandwidth of artificial magnetic conductors. The measured S_{11} parameter is less than −8 dB and the simulated gain is greater than 4.2 dBi in a range exceeding the one covered by the UMTS and LTE uplinks. Furthermore, a 2\times 2 antenna array was also built. The reflections of each element are similar to those obtained in the single-element antenna.
ISSN:0018-926X
1558-2221
DOI:10.1109/TAP.2021.3090861