Design Methodology of Multiband Printed Antennas for Future Generations of Mobile Handsets

Farahat, Asmaa E.; Hussein, Khalid F. A.; El-Hassan, M. Abo

doi:10.1109/access.2022.3192548

Cited by 12 publications

(3 citation statements)

References 24 publications

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“…The most commonly used method to increase the bandwidth of such resonant microstrip patch antennas is to use a defected ground structure (DGS) that effectively increases the aperture size of the resonant cavity and, hence, increases the bandwidth. Also, a recently published work [7] has shown that loading the main radiator (patch) with capacitively coupled elements has the effect of enhancing the bandwidth and/or adding extra resonances to the radiating modes of the microstrip patch structures. It has been shown that using both techniques (partial removal of the ground plane and capacitive loading of the main patch with parasitic elements) [8] may result in adding more resonant frequency bands, and at the same time, improving the bandwidth of some of these radiating modes.…”

Section: Design Methodology and Geometry Of The Proposed Antennamentioning

confidence: 99%

Ultra-wide Band Antenna on Flexible Substrate for Future Wireless Communications

Elshakawy¹,

Hussein²,

Farahat³

2022

PIER Letters

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In this paper, a novel ultra-wideband (UWB) antenna with a planar single-layer structure is proposed. The antenna consists of a main circular patch that is capacitively coupled to six circular patches of very small size relative to the main patch. The coupling is achieved through narrow gaps of semicircular shape which are uniformly distributed on the circumference of the main patch. A coplanar waveguide (CPW) is used for feeding the antenna to get the complete antenna structure with the feeding line printed on one face of a flexible dielectric substrate. The antenna is fabricated and subjected to experimental assessment of its performance regarding the bandwidth, gain, and radiation efficiency. The measurements show good agreement with the simulation results. It is shown that the proposed antenna operates efficiently over the frequency band of 3.1-10.6 GHz. The antenna has a radiation efficiency that ranges from 99% to 100% over the entire band. This high efficiency is attributed to the planar single-layer structure of the antenna and the use of a thin low-loss substrate. The antenna maximum gain ranges from 2 dBi to 5 dBi over the entire frequency band. The substrate material is Rogers RO3003 TM which is flexible and can be conformal to planar and curved surfaces. The total substrate dimensions are 35 × 39.4 × 0.5 mm.

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Section: Design Methodology and Geometry Of The Proposed Antennamentioning

confidence: 99%

Ultra-wide Band Antenna on Flexible Substrate for Future Wireless Communications

Elshakawy¹,

Hussein²,

Farahat³

2022

PIER Letters

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“…A resonator loaded patch antenna is designed in [10], a high performance air filled multi-mode resonant u slot antenna in [11], and a shared aperture antenna for base station application in [12] is proposed to obtain multiple bands. A design methodology is discussed to obtain multibands in printed antennas [13] and multiband monopole antenna with enhancement in bandwidth [14] for mobile handset application. In the above techniques, to obtain multiple bands much effort is needed in terms of design, feeding method, and optimization due to the sensitivity of parameters, and it is incapable to tune frequency bands independently.…”

Section: Introductionmentioning

confidence: 99%

A Triband Slot Antenna Loaded with Asymmetric Split Ring Resonator for Wireless Applications

Sugganapalya Rajanna,

Venkatesh,

Tharehalli Rajanna

et al. 2024

PIER Letters

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For applications involving triple bands, a small slot structure loaded with an asymmetric split ring resonator (ASRR) is suggested in this article. The slot mode, which is agitated with the help of a microstrip line feed, produces the first band. 2.24 GHz resonance frequency is the intended operating band. The second and third frequency bands are achieved by loading ASRR on the slot. The slot produces axial magnetic field required to excite the ASRR. The asymmetry introduced in the conventional SRR produces dual resonances. The ASRR gives the resonant frequencies at 2.97 GHz and 3.66 GHz. The frequency bands of the slot and ASRR can be independently tuned. The proposed geometry is verified experimentally, and it is in good agreement with the simulated one. The impedance bandwidth of all three resonant bands measured from experiment are 14.25%, 1.78%, 8.37%. The peak gains of 3.1 dBi, 2.18 dBi, and 3.29 dBi are obtained at resonant points, respectively. The designed antenna is compact and well suits for wireless application like WLAN, GPS, and LTE48/TD3600.

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“…In order to promote isolation, a decoupling structure is built that isolates the input of the radiating patches from the corresponding network arrangement in [8][9][10][11][12]. To increase the isolation between the patches, parasitic components are utilized in [13][14][15][16][17][18]. Using the literature mentioned above, it is necessary to create a MIMO antenna that operates on a multiband application with an ultra-wide bandwidth, improved TARC, and better cross correlation.…”

Section: Introduction Modern Antenna Technology Relies Heavily On Mul...mentioning

confidence: 99%

Development of Two UWB Multiband MIMO Antennas with Enhanced Isolation and Cross-Correlation

Sarade¹,

Ruikar²

2023

Eng. Technol. Appl. Sci. Res.

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An Ultra-Wide Band (UWB) MIMO antenna working at millimeter-wave is proposed in this research. It is composed of eight radiating elements with various shapes. It is designed with a rectangular structure and various carved slots. The carved slots are used to increase the antenna's bandwidth. The antenna's radiating elements are placed near one another, and thus, isolation is widespread. In order to improve the isolation of the MIMO antenna, parasitic elements and a defective ground structure are used. Antenna parameters such as Correlation Coefficient (CC), Envelope Correlation Coefficient (ECC), Diversity Gain (DG), and Total Active Reflection Coefficient (TARC) depend on the isolation. Parasitic elements with a rectangular form are positioned between the radiating patches. Rectangular-shaped ground structures with defects comprise the ground plane. An FR-4 substrate is used to fabricate the antenna. The analysis of the antenna shows that there is less than -14dB return loss, less than -40dB isolation, less than 0.0010 cross-correlation, less than 0.10 TARC, and higher than 500MHz bandwidth. The antenna uses a fractional bandwidth higher than 35% (UWB) for the 6GHz frequency and operates on a variety of bands. This antenna is suitable for many different wireless system applications.

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Design Methodology of Multiband Printed Antennas for Future Generations of Mobile Handsets

Cited by 12 publications

References 24 publications

Ultra-wide Band Antenna on Flexible Substrate for Future Wireless Communications

Ultra-wide Band Antenna on Flexible Substrate for Future Wireless Communications

A Triband Slot Antenna Loaded with Asymmetric Split Ring Resonator for Wireless Applications

Development of Two UWB Multiband MIMO Antennas with Enhanced Isolation and Cross-Correlation

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