Design of Millimeter-Wave Microstrip Antenna Array for 5G Communications – A Comparative Study

Ghosh, Saswati

doi:10.1007/978-3-319-76348-4_91

Cited by 5 publications

(4 citation statements)

References 18 publications

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“…The simulated results show that the impedance bandwidth over 57 -64 GHz is achieved for micro-strip patch antenna with U-slot. Also the 1 × 10 array using this antenna shows sufficient gain (15.3 dBi) and good scanning performance over +/−60 • [128]. The performance of micro-strip linearly-fed tapered patch antenna array and probe-fed microstrip comb line array structure are studied in [128] (Figure 11(a) -11(b)).…”

Section: Ghz Band (57 -64 Ghz)mentioning

confidence: 99%

“…Also the 1 × 10 array using this antenna shows sufficient gain (15.3 dBi) and good scanning performance over +/−60 • [128]. The performance of micro-strip linearly-fed tapered patch antenna array and probe-fed microstrip comb line array structure are studied in [128] (Figure 11(a) -11(b)). The arrays show gain of 12 dBi and 9.9 dBi respectively over the 60 GHz band.…”

Section: Ghz Band (57 -64 Ghz)mentioning

confidence: 99%

“…The performance of several interesting planar antenna structures e.g. micro-strip patch, elliptical dipole and broadband probe-fed micro-strip patch antenna with U-shaped slot [140] is compared for 60 GHz applications in [128] (Figure 10). The antenna structures are simulated and optimized using commercial electromagnetic simulator e.g.…”

Section: Ghz Band (57 -64 Ghz)mentioning

confidence: 99%

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An Inclusive Survey on Array Antenna Design for Millimeter-Wave Communications

2019

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The enormous growth of wireless data traffic in recent years has made the millimeter-wave (mm-wave) technology as a good fit for high-speed communication systems. Extensive works are continuing from the device to system, to the radio architecture, to the network to support the communication in mm-wave frequency ranges. To support this extensive high data rate, beam forming is found to be the key-enabling technology. Hence, an array antenna design is an extremely important issue. The beam-forming arrays are chosen to achieve the desired link capacity considering the high path loss and atmospheric loss at mm-wave frequencies and also to increase the coverage of the mm-wave communication system. There are diverse design challenges of the array due to the small size, use of large numbers of antennas in close vicinity, integration with radio-frequency (RF) front ends, hardware constraints, and so on. This paper focuses on the evolution and development of mm-wave array antenna and its implementation for wireless communication and numerous other related areas. The scope of the discussion is extended on the reported works in every sphere of mm-wave antenna array design, including the selection of antenna elements, array configurations, feed mechanism, integration with front-end circuitry to understand the effects on system performance, and the underlying reason of it. The new design aspects and research directions are unfolded as a result of this discussion.INDEX TERMS Mm-wave communication, antenna array design, array configuration, feed mechanism, RF circuit. SASWATI GHOSH received the Ph.D. degree from IIT Kharagpur, India, where she is currently a Postdoctoral Research Fellow with G. S. Sanyal School of Telecommunications. She is involved in active research in the area of antenna design for 60-GHz communication, RF energy harvesting, EMI/EMC measurements and EMI sensors, estimation of EMC of high-frequency electronic systems, and EMI/EMC/ESD on spacecraft bodies. She has 15 international journal publications, three book chapters, and more than 60 publications, including national journals and national/international conference proceedings. She serves as a Reviewer for several international journals. She had received the Young Scientist Fellowship twice and the Women Scientist Fellowship from the Department of Science and Technology, Government of India. DEBARATI SEN received the Ph.D. degree in telecommunication engineering from IIT Kharagpur, Kharagpur, India, where she is currently an Assistant Professor. Her research interests include wireless and optical communication systems, mostly on MB-OFDM, synchronization, equalization, UWB, BAN, green communications, 60-GHz communications, and baseband algorithm design for coherent optical communications.

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Section: Ghz Band (57 -64 Ghz)mentioning

confidence: 99%

Section: Ghz Band (57 -64 Ghz)mentioning

confidence: 99%

Section: Ghz Band (57 -64 Ghz)mentioning

confidence: 99%

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An Inclusive Survey on Array Antenna Design for Millimeter-Wave Communications

2019

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“…3,[8][9][10][11][12][13][14][15][16][17][18][19] The performance of few interesting microstrip antenna structures is compared for 60 GHz applications. 20 It is noticed from the existing literature that though several micro-strip antennas/arrays are designed for 60 GHz communications, the design of appropriate broad-band antenna of compact size, light weight, minimum power consumption, easy to fabricate and integrable with other devices considering the constraints, for example, high feed-line loss, substrate loss, and so on, is a challenging issue.…”

Section: Introductionmentioning

confidence: 99%

Design of broadband electromagnetically coupled planar antenna and array for 60 GHz millimeter wave applications

Ghosh

2022

Int J RF Mic Comp-Aid Eng

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The millimeter wave frequency range is found suitable for 5G communications. The design of suitable antenna/array is required for this purpose. This article presents a broadband electromagnetically coupled modified microstrip patch antenna for millimeter wave communications at 60 GHz. The antenna structure is designed and optimized with the help of commercial electromagnetic simulation software. For accurate estimation of performance of the antenna before fabrication, the optimization is performed of the overall antenna module including the antenna, feed, microstrip to waveguide transition and metal fixture. The antenna module shows wide impedance bandwidth from 58.5 to 64 GHz and 6.8 dBi gain at 60 GHz. The prototype of the antenna module is fabricated and the measured results are compared with the simulated results. Next, studies are extended for designing a four element linear array using the proposed antenna as element and other modifications to improve the array directivity and side lobe performance. The array shows gain of around 11.8 dBi.

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Review of Antenna Array for 5G Technology Using mmWave Massive MIMO

Karad

Hendre

2021

Lecture Notes in Electrical Engineering

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Design of Millimeter-Wave Microstrip Antenna Array for 5G Communications – A Comparative Study

Cited by 5 publications

References 18 publications

An Inclusive Survey on Array Antenna Design for Millimeter-Wave Communications

An Inclusive Survey on Array Antenna Design for Millimeter-Wave Communications

Design of broadband electromagnetically coupled planar antenna and array for 60 GHz millimeter wave applications

Review of Antenna Array for 5G Technology Using mmWave Massive MIMO

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