A Patch Antenna with Enhanced Gain and Bandwidth for Sub-6 GHz and Sub-7 GHz 5G Wireless Applications

Noor, Shehab Khan; Jusoh, M.; Sabapathy, Thennarasan; Rambe, Ali Hanafiah; Vettikalladi, Hamsakutty; Albishi, Ali M.; Himdi, Mohamed

doi:10.3390/electronics12122555

Cited by 11 publications

(5 citation statements)

References 17 publications

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“…As a result of this comparison, a considerable improvement in the antenna gain is discovered, along with an acceptable size reduction. 3.5 GHz 1.88 [11] 3.5 GHz 5.3 [16] 3.6 GHz 2.52 [18] 3.5 GHz 4.2 [28] 3.5 GHz 4.57 4.90 5 [31] 3.5 GHz 6.05 [34] 3.5 GHz 5.43 [35] 3.29 GHz 3.38 [36] 3.36 GHz 1.07 [37] 3.5 GHz 5.8 [38] 3.45 GHz 3.83 [40] 3.5 GHz 4.28 [41] 3.45 GHz 4.64 [42] 3.5 GHz 3.338 4.66 5.08 This work 3.5 GHz 6.02 6. CONCLUSION A 3.5 GHz microstrip patch antenna has been designed in the said paper.…”

Section: Results Analysismentioning

confidence: 99%

For wireless LAN application, microstrip patch antenna design in S-band

Rana,

Islam Sourav,

Al Mamun

et al. 2024

IJEECS

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This article presents a 3.5 GHz rectangular microstrip patch antenna (RMPA) designed, studied, and analyzed for wireless LAN applications. Using Fr-4 as substrate material, whose dielectric permittivity is 4.3, patch thickness is 1.65 mm, and loss tangent is 0.025. A feeding line with an impedance of 50 Ω is utilized to supply the antenna with power. Computer simulation technology (CST) software has been used to design the antenna and origin pro software has been used to display the resulting figures from the simulation. The antenna simulation showed that the return loss is -56.82 dB; the directivity gain is 6.02 dBi, the bandwidth is 0.148 GHz, and the voltage standing wave ratio (VSWR) is 1.0028. The paper aims to increase the return loss, develop a standard VSWR, increase the directivity gain of the antenna, and improve the antenna bandwidth. The results of the proposed antenna were much better than previously published papers, which were suitable for wireless applications. This proposed antenna can be used for future wireless LAN applications.

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Section: Results Analysismentioning

confidence: 99%

For wireless LAN application, microstrip patch antenna design in S-band

Rana,

Islam Sourav,

Al Mamun

et al. 2024

IJEECS

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“…Different applications have been shown by patch antennas. Because of their being light weight, having a low profile and efficient radiation, they are being tried for 5G systems and even 6G communication [8] [63]. In medical diagnosis among other fields, patch antennas of dual bands are designed to work at specified frequencies like 2.4 GHz and 3.33 GHz through slot configuration [17].…”

Section: Future Directionsmentioning

confidence: 99%

“…For instance, a study by Nassr and Khamiss proposed a patch antenna at 38 GHz with enhanced gain and reduced side lobes to meet the demands of 5G communication [7]. Additionally, Jusoh's research demonstrated the design of a novel patch antenna operating at sub-6 GHz and sub-7 GHz bands, showcasing wider bandwidth and improved gains compared to conventional designs [8]. Yoo and Son introduced a millimeter-wave patch antenna that Disclaimer/Publisher's Note: The statements, opinions, and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s).…”

Section: Introductionmentioning

confidence: 99%

Recent Advances of 5G Technology Based on Patch Antenna: A Literature Review

Sacala,

Arboleda

2024

Preprint

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For their speed in data processing, low heights and cheapness, patch antennas are important to 5G networks. While there have been improvements in the area of bandwidth and size reduction; however, there are still problems that need to be fixed with regards achieving high data rates as well as wideband operation and compact sizes for 5G applications. In the coming years researchers should concentrate on materials optimization and feeding methods so that they can work efficiently at shorter wavelengths for next-generation systems while still covering all necessary bands.

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“…The designed antenna has a frequency range that ranges from 3.8-4.4 GHz and the gain of 12.1 dB at 4.148 GHz [3]. With gain of 3.83 and 0.576 dB, antenna described in [4] has a broader BW of 160 MHz at 3.45 GHz and 220 MHz at 5.9 GHz. A sixteen element Ku/Ka-band multi-polarized antenna patch is built, and experimental results shows that impedance bandwidth of 19.4% (14.4-17.5 GHz) for dual linearly polarized (LP) and 7.4% (32.5-35 GHz) for dual circularly polarized (CP) may be achieved.…”

Section: Introductionmentioning

confidence: 99%

Design of higher gain linearly polarized 2×2 microstrip patch array antenna for wireless communication

Gani,

Hegde

2024

IJECE

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The fifth-generation technology is popular and best as far as data rates are concerned for wireless applications. To meet the increased demand of the modern world for faithful communication, this research work is carried out. In this approach, a single patch, 1×2 array, and 2×2 array are designed using a low-cost FR4 dielectric substrate ( =4.4) covering the 3.3–3.8 GHz frequency band. Due to the lack of gain from arrays in the present research, an attempt is made to achieve excellent gain from arrays with a minimum number of patches. First, the gain of a single inset-fed antenna is compared with another normal single patch of the same thickness but with an additional air dielectric medium. Next, the second single patch is extended to obtain a rectangular 1×2 array and a 2×2 array antenna. A second single patch measuring 50×32.5×0.8 mm is designed assuming an infinite ground plane. It has 3mm air gap between the patch strip and the ground. Air acts as a second dielectric layer that reduces power loss. This allows a maximum gain of 15.2 dB with a return loss of -22 dB. Also, antenna efficiency and bandwidth are 91% and 267.69 MHz, respectively.

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A Patch Antenna with Enhanced Gain and Bandwidth for Sub-6 GHz and Sub-7 GHz 5G Wireless Applications

Cited by 11 publications

References 17 publications

For wireless LAN application, microstrip patch antenna design in S-band

For wireless LAN application, microstrip patch antenna design in S-band

Recent Advances of 5G Technology Based on Patch Antenna: A Literature Review

Design of higher gain linearly polarized 2×2 microstrip patch array antenna for wireless communication

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