Mutual Coupling Suppression Between Two Closely Placed Microstrip Patches Using EM-Bandgap Metamaterial Fractal Loading

Alibakhshikenari, Mohammad; Khalily, Mohsen; Virdee, Bal S.; See, Chan Hwang; Abd‐Alhameed, Raed A.; Limiti, Ernesto

doi:10.1109/access.2019.2899326

Cited by 162 publications

(108 citation statements)

References 21 publications

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“…The coming into existence of metamaterials has encouraged researchers and scientists in the area of electromagnetic theory in relation to radiation and propagation phenomena towards the design and fabrication of devices for various applications such as couplers, [41][42][43] phaseshifters, 44,45 imaging systems, 46 radar, 47 satellite, 48,49 seismic protection, 50 absorbers, 51 lens, 52,53 filters, 54 sensors, 55 electromagnetic cloaks, 31,51 and antennas. [56][57][58][59][60][61][62][63][64][65][66][67][68][69][70] The metamaterial field also has research dimensions in materials science, acoustics, and thermodynamics 71 in addition to the electromagnetics prospect. In this work, emphasis has been given only for the application of metamaterial and its derivatives such as metasurface, artificial magnetic conductor (AMC), and frequency selective surface for performance enhancement of patch antenna.…”

Section: Application Areas Of Metamaterials and Metasurfacementioning

confidence: 99%

Application of metamaterials for performance enhancement of planar antennas: A review

Tadesse

Acharya

Sahu

2020

Int J RF Microw Comput Aided Eng

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Metamaterials are assemblies of metallic and/or dielectric materials with properties that are not readily found in naturally existing materials. Hence, metamaterial structures are commonly loaded on/near the patch, embedded in the substrate, loaded/etched from the ground plane or placed as a superstrate layer for enhancing bandwidth and gain, and size miniaturization of conventional patch antennas. The demand for wide bandwidth, high gain, and compact antennas is highly contemplated in recent wireless communication research studies. Despite their lightweight, ease of fabrication, low profile, and simplicity for integration, patch antennas have performance limitations as result of their narrow bandwidth, lower gain, larger size, and lower power handling capacity. To address these problems, metamaterial‐based antennas have gained massive interest. There exist inadequate literatures about review of current state of extensive study reports on metamaterial application for patch antenna performance enhancement. Thus, this paper has reviewed and discussed latest research works on metamaterial applications for performance enhancement of planar patch antennas.

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Section: Application Areas Of Metamaterials and Metasurfacementioning

confidence: 99%

Application of metamaterials for performance enhancement of planar antennas: A review

Tadesse

Acharya

Sahu

2020

Int J RF Microw Comput Aided Eng

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“…All these techniques have been employed to reduce coupling in the range 3.1 GHz-10.6 GHz. Further, mutual coupling reduced by metamaterial in [30][31][32][33][34][35][36][37][38][39] and [40][41][42][43]. Most of these antennas possess large dimensions, have low isolation enhancement and low %BW and gain.…”

Section: Introductionmentioning

confidence: 99%

Design of SWB MIMO Antenna with Extremely Wideband Isolation

et al. 2020

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This paper presents a compact planar multiple input multiple output (MIMO) antenna for super wide band (SWB) applications. The presented MIMO antenna comprises two identical patches on the same substrate. Dimensions of the MIMO antenna are 0.17λ × 0.20λ × 0.006λ mm3, with respect to the lowest resonance of 1.30 GHz. The SWB antenna was manufactured using F4B substrate having a dielectric constant of 2.65 that provides a percent impedance bandwidth and bandwidth ratio of 187% and 30.76:1, respectively. The mutual coupling between the antenna elements is suppressed by placing a T-shaped corrugated strip in the mid of two antenna elements. The proposed MIMO antenna exhibits maximum diversity gain of 10 dB, low mutual coupling (<−20 dB), low envelope correlation coefficient (ECC < 0.02), efficiency >80%, and low reflection coefficient (<−10 dB) in the SWB frequency range (1.30 GH–40 GHz). The presented antenna is a good candidate for SWB applications. The designed antenna has been experimentally validated, and the simulated results were also verified.

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“…Metamaterial has some unusual and interesting properties, 7 which can be used for the improvement of different antenna parameters. For example, impedance bandwidth, [8][9][10][11] side-lobe levels, isolation in MIMO antennas, [12][13][14] crosspolarization, 15 antenna gain [15][16][17][18][19][20] can be improved by exploiting various properties of MTMs. In, ref.…”

Section: Introductionmentioning

confidence: 99%

Metamaterial‐inspired low‐profile high‐gain slot antenna

Pandit

Mohan

Ray

2019

Micro & Optical Tech Letters

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This article presents a novel polarization‐independent metamaterial (MTM) which is used for the design of a low‐profile high‐gain magnetic dipole antenna operating at 9.8 GHz. The MTM is alike star‐shape and shows low impedance property around the frequency 9.8 GHz. The reference antenna, which is the SIW‐based slot antenna acts as a magnetic dipole antenna and it has peak gain of 3 dBi. The metamaterial‐inspired slot antenna has low‐profile, that is, 0.133 λ0 at the frequency 9.8 GHz, and peak gain of 8.24 dBi. At the resonance frequency, more than 5 dB gain improvement is achieved in the proposed design. These results are verified with the fabrication of a prototype antenna and measurements. The cross‐polarized radiation is negligibly altered by this gain enhancement method. The proposed antenna can be used in wireless power transfer and LoS communications.

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Mutual Coupling Suppression Between Two Closely Placed Microstrip Patches Using EM-Bandgap Metamaterial Fractal Loading

Cited by 162 publications

References 21 publications

Application of metamaterials for performance enhancement of planar antennas: A review

Application of metamaterials for performance enhancement of planar antennas: A review

Design of SWB MIMO Antenna with Extremely Wideband Isolation

Metamaterial‐inspired low‐profile high‐gain slot antenna

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