Overview of Metamaterials-Integrated Antennas for Beam Manipulation Applications: The Two Decades of Progress

Esmail, Bashar A. F.; Koziel, Slawomir; Golunski, Lukasz; Majid, H. A.; Barik, Rusan Kumar

doi:10.1109/access.2022.3185260

Cited by 11 publications

(3 citation statements)

References 159 publications

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“…In this section, the dual-C-notch NZIM structure is designed to achieve two targets: one is to improve the out-of-band suppression by introducing the radiation nulls of the lower and upper gain stopbands by energy absorption and other is to enhance the bandwidth by impedance matching. This design idea of dual-C-notch NZIM is derived from absorptive-branch-loaded structure and dual-notch NZIM structure [30,31]. For convenience of expression, the dual-C-notch NZIM structure is defined as a C-type antenna (this C-type antenna is cut into dual-C-notch on the surface of the ME structure of the B-type antenna.).…”

Section: Design Of the Dual-c-notch Nzimmentioning

confidence: 99%

Stereoscopic UWB Yagi–Uda Antenna with Stable Gain by Metamaterial for Vehicular 5G Communication

Shen

Dou

et al. 2023

Sensors

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In this paper, a stereoscopic ultra-wideband (UWB) Yagi–Uda (SUY) antenna with stable gain by near-zero-index metamaterial (NZIM) has been proposed for vehicular 5G communication. The proposed antenna consists of magneto-electric (ME) dipole structure and coaxial feed patch antenna. The combination of patch antenna and ME structure allows the proposed antenna can work as a Yagi–Uda antenna, which enhances its gain and bandwidth. NZIM removes a pair of C-notches on the surface of the ME structure to make it absorb energy, which results in two radiation nulls on both sides of the gain passband. At the same time, the bandwidth can be enhanced effectively. In order to further improve the stable gain, impedance matching is achieved by removing the patch diagonally; thus, it is able to tune the antenna gain of the suppression boundary and open the possibility to reach the most important characteristic: a very stable gain in a wide frequency range. The SUY antenna is fabricated and measured, which has a measured −10 dBi impedance bandwidth of approximately 40% (3.5–5.5 GHz). Within it, the peak gain of the antenna reaches 8.5 dBi, and the flat in-band gain has a ripple lower than 0.5 dBi.

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Section: Design Of the Dual-c-notch Nzimmentioning

confidence: 99%

Stereoscopic UWB Yagi–Uda Antenna with Stable Gain by Metamaterial for Vehicular 5G Communication

Shen

Dou

et al. 2023

Sensors

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“…In essence, the integration of split ring resonator metamaterials into antenna systems [9,10] represents a ground-breaking advancement in wireless communication technology. Their unique electromagnetic properties [11,12] enable unparalleled control and optimization of antenna performance, ushering in an era characterized by enhanced efficiency, reliability, and overall performance. The objectives of this paper are 1.…”

Section: Introductionmentioning

confidence: 99%

Exploring the Impact of Split Ring Resonator Metamaterial Structure Integration on 4X4 MIMO Antenna Performance in Sub-6GHz Bands for 5G Applications

Padmasree,

Rohith,

Poojitha

et al. 2024

IJCSMC

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This research delves into the realm of antenna engineering, with a specific focus on examining the performance of 4x4 MIMO antennas with and without integration of split ring resonator metamaterial structure. The objective is to comprehend the influence of split ring resonator metamaterials on antenna characteristics within the 6 GHz frequency range. Employing CST Studio Suite software, comprehensive simulations are conducted to evaluate various parameters including gain, directivity, radiation efficiency, S-parameters, power distribution, VSWR, and total efficiency. In the frequency band up to 6GHz, observed gain values were 24.62dB without split ring resonator metamaterial integration and ranging from 6dB to 27dB with integration. Through a systematic comparison, the study aims to delineate the precise effects of split ring resonator metamaterials on antenna performance, thereby offering valuable insights into their potential for enhancing MIMO antenna systems.

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“…On the other hand, due to their peculiar electromagnetic properties, such as negative permittivity and permeability, metamaterial structures have attracted the curiosity of researchers throughout the last two decades [18]- [21], [30]- [33]. In fact, the radiation pattern or the gain of antennas can be manipulated by incorporating metamaterial cells in the vicinity of the radiating part or etched into the substrate [22]- [24]. For example, Dadgarpour et al inserted an array of H-shape unit cells into the bow-tie antenna substrate for tilting the radiation angle [25].…”

Section: Introductionmentioning

confidence: 99%

Design and Implementation of a 2.4-GHz Fully Integrated Butler Matrix for Smart Antenna System

Montoya-Villada

Morales-Guerra

Catano-Ochoa

et al. 2023

IRECAP

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This work proposes and analyzes a low-cost fixed microstrip beamforming system based on a uniform linear array with four rectangular patch antennas controlled by a Butler matrix that operates in the 2.4 GHz ISM band. A 4×4 Butler matrix consisting of four hybrid quadrature directional couplers, two crossovers, and two 45° phase shifters was designed and implemented to control the beam direction of the entire system. Similarly, a comparative study is performed between two different antenna arrays, the first consisting of a conventional linear antenna array and the second antenna array consisting of four patch antennas loaded with metamaterial structures on the ground plane. Finally, the electrical performance of both smart beamforming systems was evaluated, and their potential application as a wireless power transmitter was evaluated. Four beams with distinct orientations were created in each situation. The smart antenna based on a conventional array has a higher gain, while the smart antenna based on metamaterial structures has a higher HPBW.

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Overview of Metamaterials-Integrated Antennas for Beam Manipulation Applications: The Two Decades of Progress

Cited by 11 publications

References 159 publications

Stereoscopic UWB Yagi–Uda Antenna with Stable Gain by Metamaterial for Vehicular 5G Communication

Stereoscopic UWB Yagi–Uda Antenna with Stable Gain by Metamaterial for Vehicular 5G Communication

Exploring the Impact of Split Ring Resonator Metamaterial Structure Integration on 4X4 MIMO Antenna Performance in Sub-6GHz Bands for 5G Applications

Design and Implementation of a 2.4-GHz Fully Integrated Butler Matrix for Smart Antenna System

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