Directional Radio Propagation Path Loss Models for Millimeter-Wave Wireless Networks in the 28-, 60-, and 73-GHz Bands

Sulyman, Ahmed Iyanda; Alwarafy, Abdulmalik; MacCartney, George R.; Rappaport, Theodore S.; Alsanie, Abdulhameed

doi:10.1109/twc.2016.2594067

Cited by 153 publications

(72 citation statements)

References 35 publications

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“…For mm-Wave communications, the propagation path-loss will be related to both distance and frequency [35], [36]. For simplicity, here we focus on the distance-dependent path-loss model (i.e., neglecting the effect from frequency), which is expressed as:…”

Section: B Propagation Modelmentioning

confidence: 99%

Learning-Based Spectrum Sharing and Spatial Reuse in mm-Wave Ultradense Networks

Fan

Zhao

et al. 2018

IEEE Trans. Veh. Technol.

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Section: B Propagation Modelmentioning

confidence: 99%

Learning-Based Spectrum Sharing and Spatial Reuse in mm-Wave Ultradense Networks

Fan

Zhao

et al. 2018

IEEE Trans. Veh. Technol.

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“…Furthermore, the shift to mm-wave also involves a change to directive communications, rather than broadcasting, which introduces new challenges [8,9]. Within future wireless networks, mm-wave frequencies around 28 GHz and 37 GHz have been proposed for use in cellular 2 International Journal of Antennas and Propagation networks in urban environments (e.g., [10][11][12][13]), with the 25-40 GHz band being considered by the Federal Communications Commission in the US [14], whilst mm-wave frequencies between 55 and 100 GHz have been proposed for indoor environments and short-range outdoor environments, including vehicle-to-vehicle links, as well as other applications that may also rely on 5G networks (e.g., [13,[15][16][17]). …”

Section: Background and Motivationsmentioning

confidence: 99%

Beam-Steering Performance of Flat Luneburg Lens at 60 GHz for Future Wireless Communications

Foster

Nagarkoti

Gao

et al. 2017

International Journal of Antennas and Propagation

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The beam-steering capabilities of a simplified flat Luneburg lens are reported at 60 GHz. The design of the lens is first described, using transformation electromagnetics, before discussion of the fabrication of the lens using casting of ceramic composites. The simulated beam-steering performance is shown, demonstrating that the lens, with only six layers and a highest permittivity of 12, achieves scan angles of ±30 ∘ with gains of at least 18 dBi over a bandwidth from 57 to 66 GHz. To verify the simulations and further demonstrate the broadband nature of the lens, raw high definition video was transmitted over a wireless link at scan angles up to 36 ∘ . Background and MotivationsThe quest for ubiquitous wireless connectivity with everincreasing data rates has been a feature of the last half century. With the advent of the Internet of Things (IoT) adding huge numbers of devices requiring bandwidth to an alreadychallenging push for even greater data rates to be supported on personal wireless terminals, considerable research effort is being invested into future wireless networks. High-data rate applications include the streaming of ultrahigh definition video and virtual and augmented reality (e.g., [1,2]); the use of 60 GHz for these applications is now relatively wellestablished, with IEEE standards (e.g., 802.15.3c, 802.11ad[3]) well-suited for this aspect of 5G services and networks.Other aspects of 5G development are concerned with serving greater numbers of end-terminals and reducing latency, with some applications in the IoT relevant to this (even when data rate requirements are not severe).A large number of technologies are being brought together to achieve the various aims for the next generation of wireless networks [4]. This includes the use of small cells (where the density of base stations is increased), cooperative communications (where interference is reduced via communication between nodes, to improve achievable data rates and reliability), carrier aggregation (where bandwidth from disparate channels is combined to meet requirements), and heterogeneous networks (where multiple networks operating at different frequencies and with different modulations, etc., are used). One key technology is massive multi-input-multioutput (M-MIMO) systems, where the number of antennas is increased by at least an order of magnitude (e.g., [5][6][7]).One key approach to realise the objectives of future wireless networks is to utilise previously unused parts of the electromagnetic spectrum at higher frequency bands, particularly the millimetre-wave (mm-wave) and terahertz (THz) bands. Currently, wireless networks predominantly use the spectrum between 0.1 and 10 GHz, as these have offered key benefits of long propagation ranges, ease of fabrication, and ease of power generation and signal modulation, amongst others. Conversely, the higher bands must overcome increased propagation losses, smaller feature sizes that increase fabrication challenges, and other problems; the demand for bandwidth is such that these challenges...

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“…The fifth-generation (5G) cellular systems have been vastly investigated in the last years [1][2][3][4][5], as well as its applicability for the new internet services, such as high-definition video stream, bitpipe communications at Gbps [1], tactile internet, Internet of Things (IoT), rural access networks [4], and autonomous cars. New challenges, including spectrum, propagation channel, reliability, cost, and energy efficient aspects, become extremely important for the success of 5G networks.…”

Section: Introductionmentioning

confidence: 99%

“…The 5G networks are likely to operate in the centimetrewave (3-30 GHz) and millimetre-wave (30-300 GHz) frequency bands [2,3], in which there is a lot of unexploited spectrum worldwide. The E-band and W-band have also been analyzed for fulfilling the tough requirements of this new generation [6].…”

Section: Introductionmentioning

confidence: 99%

Waveguide-Based Antenna Arrays for 5G Networks

Sodré

Costa

Santos

et al. 2018

International Journal of Antennas and Propagation

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This work reports the development of two high-performance waveguide-based antenna arrays for 5G cellular networks, operating in the underutilized millimetre wave (mm-wave) frequency spectrum. Two different scenarios of mm-wave communications are proposed for illustrating the applicability of the proposed arrays, which provide specific radiation patterns, namely, 12 dBi gain omnidirectional coverage in the 28 GHz band and dual-band sectorial coverage using the 28 and 38 GHz bands with gain up to 15.6 dBi. Numerical and experimental results of the array reflection coefficient, radiation pattern, and gain have been shown in an excellent agreement.

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Directional Radio Propagation Path Loss Models for Millimeter-Wave Wireless Networks in the 28-, 60-, and 73-GHz Bands

Cited by 153 publications

References 35 publications

Learning-Based Spectrum Sharing and Spatial Reuse in mm-Wave Ultradense Networks

Learning-Based Spectrum Sharing and Spatial Reuse in mm-Wave Ultradense Networks

Beam-Steering Performance of Flat Luneburg Lens at 60 GHz for Future Wireless Communications

Waveguide-Based Antenna Arrays for 5G Networks

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