Design of MIMO antenna to interference inherent for ultra wide band systems using defected ground structure

Babu, K. Vasu; Anuradha, B.

doi:10.1002/mop.31958

Cited by 37 publications

(20 citation statements)

References 25 publications

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“…With the goal of solving the trade-off among the high operational bandwidth, antenna compactness and good inter-port isolation characteristics, [12][13][14][15][16][17][18][19][20][21][22] a 2 × 2 miniaturized Koch curve fractal MPA array with a higher operational range and significant diversity performance is presented in this research. The proposed fractal array is modeled on a 1.57 mm thick FR-4 lossy substrate with relative permittivity ( r ) and loss tangent (tan ) of 4.4 and 0.024 respectively.…”

Section: Introductionmentioning

confidence: 99%

Computational analysis of a dual‐port semi‐circular patch antenna combined with Koch curve fractals for ultra‐wideband systems

Sohi

Kaur

2021

Engineering Reports

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This paper presents a two-port microstrip-fed semi-circular patch antenna integrated with Koch curve fractals and common ground with defected ground structure for the effective implementation in handheld ultra-wideband (UWB) systems. The proposed array is engraved on a 1.57 mm thick FR-4 substrate with an overall array size of 30.5 × 47 × 1.64 mm 3 . The parametric analysis of the proposed array indicates that the two optimized Koch curve fractal (second iteration order) radiators (upper substrate layer) provides an optimum matching performance in a wide operational band (4.395-10.184 GHz, 79.4%) and minimizes the patch area by 41.2% as compared to the conventional circular patch. To realize good port-to-port isolation (S 21 /S 12 ≤ −16.8 dB), the reduced ground is slotted and incorporated with a funnel-shaped decoupling structure at the center. The prototype of the proposed array is fabricated and experimentally tested to justify the simulated S-parameter results. All diversity metrics like envelope correlation coefficient, diversity gain (DG), mean effective gain, channel capacity loss, and total active reflection coefficient lie within their acceptable limits which affirm a high signal-to-noise ratio and the proficiency of the proposed array in the development of high data-rate UWB communication devices. K E Y W O R D Sdefected ground structure (DGS), Koch curve fractal, multiple-input multiple-output (MIMO), ultra-wideband (UWB)This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Section: Introductionmentioning

confidence: 99%

Computational analysis of a dual‐port semi‐circular patch antenna combined with Koch curve fractals for ultra‐wideband systems

Sohi

Kaur

2021

Engineering Reports

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“…A fractal compactness octagonal structure with frequency 3.1–10.6 GHz with band rejection for wireless LAN systems, 7 two closely spaced dual‐band MIMO design using decoupling structure, 8 using the superstrate of EMNZ patch‐type antenna for gain as well as isolation enhancement, 9 a novel technique of Sierpinski Knopp structure using four elements with notch band characteristics 10 designed for dual‐band MIMO systems. The technique of defect in ground structure (DGS) used for interference inherent MIMO has been designed 11 for UWB systems, MIMO antenna was designed for portable devices and wireless LAN rejection, 12,13 using the structure of ohm‐type symbol and structure of L‐shape designed for reduction of mutual coupling, 14 a mushroom structure using metamaterial designed four elements for isolation enhancement MIMO system, 15 a compact novel structure of kotch fractal radiator for band rejection of wireless LAN systems, 16 using the structure of F‐shaped stubs involved, 17 for WLAN rejection characteristics of 4 × 4 MIMO radiator was designed, 18 the technique of neutralization line method for mutual coupling reduction of Wang‐shaped structure, 19 for improvement of the parameter isolation using the technique of molecule fractal structure utilization is designed in 20 . To obtain the low mutual coupling, the technique used periodic‐type multilayered EBG structure, 21 for the applications of wireless services designed UWB MIMO packaging system, 22 and finally, a tree‐like structure of diversity/MIMO radiator for wideband isolation improvement 23 was designed.…”

Section: Introductionmentioning

confidence: 99%

Opportunistic control of fractal‐based MIMO antenna for sub‐6‐GHz 5G applications

Sree

Nelaturi

2021

Int J Communication

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Summary The proposed research work is on fractal MIMO antenna with microstrip feeding for lower sub‐6 GHz. The design construct's goal is to improve the isolation among the patches and is constructed with a combination of circular strip and rectangular strip slots, and rectangular slots are introduced on the ground plane. The fractal‐shaped MIMO structure composes of FR‐4 material and compact size of 25 × 35 mm2. The current 2 × 1 fractal MIMO radiator resonates at a frequency 3.5 GHz for lower sub‐6‐GHz applications with directional radiation patterns. In this structure, the performance characteristics of design antenna parameters like S‐parameters, surface current distributions, and radiation pattern of the fractal MIMO radiator are investigated. In addition to antenna parameters, MIMO parameters like diversity gain (DG), mean effective gain (MEG), channel capacity loss (CCL), total active reflection coefficient (TARC), and time‐domain analysis parameters are also evaluated. It has been observed that the MIMO parameters of the antenna are in the acceptable range. Fractal‐based prototype MIMO structures are fabricated as well as tested for effective radiation and impedance. The improvised MIMO design that's been installed on a printed circuit board with connector, device housing, compact size, and various types of housing shows better performance compared to the conventionally designed antennas.

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“…The lower mutual coupling between the elements ensures high radiation efficiency and, therefore, the diversity performance of the antenna is improved [20]. There are various techniques implemented to improve the high level of isolation between the antennas, such as a slit in the ground plane [21,22], adjusting the spacing between the antenna elements [23], a stub in the ground plane [24,25], using a decoupling structure in the ground plane [26], inserting a stub between the radiators [27], the orthogonal placement of radiators [28][29][30][31][32][33] and the neutralization line technique [34,35]. Most of the existing wideband antennas are not suitable for compact diversity systems due their large sizes [36,37] and improper mutual coupling characteristics over the entire operational validated frequencies.…”

Section: Introductionmentioning

confidence: 99%

“…(1) The designed MIMO antenna operates from 2.9 to more than 30 GHz, which corresponds to a bandwidth greater than 27 GHz; (2) The bandwidth (GHz and %) of this proposed antenna is greater than all the other antennas referenced in Table 1; (3) From the standpoint of dimensions, the proposed antenna has compact geometry when compared with [20,23,27,28,30,32]; (4) Without any decoupling structure, the isolation characteristics of the proposed MIMO antenna are better than those in [17][18][19][20][21][22]25,27,32,33]; (5) This work also focused on the DG and ECC of the MIMO configuration. DG was not reported in [17,[20][21][22][23][27][28][29][30][31], and a higher DG value is shown when compared with [24,34]. The ECC values were not reported in [21,23,27,28,30,31].…”

Section: Introductionmentioning

confidence: 99%

“…The ECC values were not reported in [21,23,27,28,30,31]. Due to the better isolation characteristics, the proposed antenna provides lower ECC compared with [17][18][19][20]22,24,25,29,[32][33][34]; (6) Due to the compact geometry and wider bandwidth, the proposed antenna offers higher a BDR value, compared with the other work referred to in the table.…”

Section: Introductionmentioning

confidence: 99%

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On the Design and Analysis of Compact Super-Wideband Quad Element Chiral MIMO Array for High Data Rate Applications

et al. 2020

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This paper presents a compact, bouquet-inspired, four-element MIMO array for super wideband (SWB) applications. The proposed unit element monopole antenna has compact geometry, and it is deployed by the fusion of an elliptical and circular-shaped radiator. The convoluted geometry and semi-elliptical ground plane, along with the narrow rectangular slit defected ground structure, provides a wide impedance bandwidth. The designed unit cell has the dimensions of 32 mm × 20 mm × 0.8 mm, operates from 2.9 to 30 GHz (S11 ≤ −10 dB) and provides a bandwidth dimension ratio (BDR) of 2894. The proposed low-profile diversity array without any decoupling structures consists of four orthogonally placed, uncorrelated antennas with an inter element spacing of 0.05 λ0, occupies an area of 57 mm × 57 mm and provides dual polarization. The performance metrics of the diversity array were validated for frequencies over ultra-wideband, using mutual coupling characteristics, envelope correlation coefficient (ECC) by far-field radiation, diversity gain (DG), total active reflection coefficient (TARC), channel capacity loss (CCL) and cumulative distribution function (CDF) analysis. The measured mutual coupling over the operating band was less than −18 dB, the ECC was less than 0.004 and the TARC was less than −15 dB, and a better CCL of ˂0.28 bits/s/Hz was achieved by the fabricated antenna.

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Design of MIMO antenna to interference inherent for ultra wide band systems using defected ground structure

Abstract: A compact monopole ultra wide band (UWB) antenna is analyzed and described with defect in ground plane.

Cited by 37 publications

References 25 publications

Computational analysis of a dual‐port semi‐circular patch antenna combined with Koch curve fractals for ultra‐wideband systems

Computational analysis of a dual‐port semi‐circular patch antenna combined with Koch curve fractals for ultra‐wideband systems

Opportunistic control of fractal‐based MIMO antenna for sub‐6‐GHz 5G applications

On the Design and Analysis of Compact Super-Wideband Quad Element Chiral MIMO Array for High Data Rate Applications

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