Design of Compact and High Directive Slot Antennas Using Grounded Metamaterial Slab

Mitra, Debasis; Sarkhel, Abhishek; Kundu, Olyvia; Chaudhuri, Sheli Sinha

doi:10.1109/lawp.2014.2380772

Cited by 22 publications

(12 citation statements)

References 7 publications

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“…It indicates that the CSRR unit cell presents the negative permittivity metamaterial at desired resonance frequency band. The similar results were also observed by other groups [17,18]. To evaluate the effect of using CSRR MTM structure on microstrip antenna design, the technical parameters of both normal and MTM antennas were carried out.…”

Section: Simulation Results and Discussionsupporting

confidence: 81%

A Miniaturization of Microstrip Antenna Using Negative Permitivity Metamaterial Based on CSRR-Loaded Groundfor Wlan Applications

Tung

Lam

Hòa

2016

JST

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A microstrip antenna using negative permittivity metamaterial based on complementary split ring resonator (CSRR)-loaded ground has been investigated in order to miniaturize the size and improve the antenna characteristics. The antennas are designed on FR4 material and simulated results are provided by HFSS software. The metamaterial antenna is reduced 77 % the antenna size compared to the normal microstrip antenna. Furthermore, compared with the normal microstrip antenna, the antenna characteristics of the metamaterial antenna are improved significantly. The proposed metamaterial antenna achieves the antenna resonate at 2.45 GHz, the gain of higher than 6.5 dB and the bandwidth of 110 MHz through the whole WLAN band. The obtained results indicate that the proposed antenna is a good candidate for WLAN applications.

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Section: Simulation Results and Discussionsupporting

confidence: 81%

A Miniaturization of Microstrip Antenna Using Negative Permitivity Metamaterial Based on CSRR-Loaded Groundfor Wlan Applications

Tung

Lam

Hòa

2016

JST

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“…For enhancing the gain/directivity, Lovat et al proposed a novel idea using epsilon‐near‐zero (ENZ) and/or a mu‐very‐large (MVL) material excited by an electric dipole source as described in References , whereas, a mu‐near‐zero (MNZ) material and/or an epsilon‐very‐large (EVL) material is excited by a magnetic dipole. The EVL based metamaterial recently has been successfully applied for increasing directivity of a magnetic dipole, that is, slot antenna with compact configuration …”

Section: Introductionmentioning

confidence: 99%

“…The EVL based metamaterial recently has been successfully applied for increasing directivity of a magnetic dipole, that is, slot antenna with compact configuration. [10][11][12] In this article, an MVL based metamaterial slab has been applied for directivity enhancement of a wire monopole antenna owing to its electric dipole nature. In this regard, a magnetic metamaterial, operating under normal incidence, is used as unit cell of the metamaterial slab.…”

Section: Introductionmentioning

confidence: 99%

Directivity enhancement of wire monopole antenna using magnetic metamaterials

Das

Shaw

Mitra

et al. 2019

Int J RF Microw Comput Aided Eng

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This article proposes the use of a magnetic metamaterial (MTM) slab over the ground plane of a wire monopole antenna to improve its directivity. In this regard, mu very large (MVL) behavior of the metamaterial is utilized for enhancing the directivity of the monopole. Despite the directivity enhancement of about 5 dB, an improved bandwidth of 35% is obtained for the proposed configuration. Initially, a 2 × 3 array of a single MTM slab has been placed over the ground plane of the monopole. It is shown that, over the whole working band, a significant directivity improvement is maintained compared to the unloaded monopole. Further, the directivity performance has been investigated with different combination of MTM slab.

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“…This concept was first theoretically developed by Lovat et al for electric as well as magnetic dipole source in [15,16] where the gain/directivity enhancement was achieved through mu-near-zero (MNZ) material and/or an epsilonvery-large (EVL) material for a magnetic dipole source and epsilon-near-zero (ENZ) and/or a mu-verylarge (MVL) material for an electric dipole source, respectively. Recently, according to the concept, the directivity of a magnetic dipole, i.e., slot antenna has been successfully enhanced using an EVL based metamaterial structure in [17,18]. It is known that EVL characteristic could be achieved from the electric resonance of an electric inductive capacitive (ELC) resonator type metamaterial structure [19].…”

Section: Introductionmentioning

confidence: 99%

Gain Enhancement of Planar Dipole Antenna Using Grounded Metamaterial

Das¹,

Dutta²,

Mitra³

et al. 2019

PIER Letters

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In this paper, a simple approach for enhancing the gain of a planar dipole antenna using the concept of grounded metamaterial (MTM) has been proposed. In this regard, a magnetic metamaterial with Mu-very large (MVL) property has been placed over the ground plane of the antenna to increase the gain of the electric dipole source. A fully planar structure has been configured due to the placement of the metamaterial just over the ground plane. A significant amount of gain improvement of about 3.7 dB for the dipole has been attained using the metamaterial. In addition, increase of fractional bandwidth by 2.2% has been obtained due to the loading of the metamaterial. A comparative study with respect to recently reported literature for the gain enhancement of planar dipole has also been discussed. The proposed antenna is a worthy candidate for wireless communication owing to the high gain, low profile, and wide bandwidth characteristics.

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Design of Compact and High Directive Slot Antennas Using Grounded Metamaterial Slab

Cited by 22 publications

References 7 publications

A Miniaturization of Microstrip Antenna Using Negative Permitivity Metamaterial Based on CSRR-Loaded Groundfor Wlan Applications

A Miniaturization of Microstrip Antenna Using Negative Permitivity Metamaterial Based on CSRR-Loaded Groundfor Wlan Applications

Directivity enhancement of wire monopole antenna using magnetic metamaterials

Gain Enhancement of Planar Dipole Antenna Using Grounded Metamaterial

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