TUTCRIS - Tampereen teknillinen yliopisto

TUTCRIS

Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios

Tutkimustuotosvertaisarvioitu

Standard

Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios. / Zeman, K.; Stusek, M.; Pokorny, J.; Masek, P.; Hosek, J.; Andreev, S.; Dvorak, P.; Josth, R.

2017 40th International Conference on Telecommunications and Signal Processing (TSP). IEEE, 2017. s. 86-90.

Tutkimustuotosvertaisarvioitu

Harvard

Zeman, K, Stusek, M, Pokorny, J, Masek, P, Hosek, J, Andreev, S, Dvorak, P & Josth, R 2017, Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios. julkaisussa 2017 40th International Conference on Telecommunications and Signal Processing (TSP). IEEE, Sivut 86-90, 1/01/00. https://doi.org/10.1109/TSP.2017.8075942

APA

Zeman, K., Stusek, M., Pokorny, J., Masek, P., Hosek, J., Andreev, S., ... Josth, R. (2017). Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios. teoksessa 2017 40th International Conference on Telecommunications and Signal Processing (TSP) (Sivut 86-90). IEEE. https://doi.org/10.1109/TSP.2017.8075942

Vancouver

Zeman K, Stusek M, Pokorny J, Masek P, Hosek J, Andreev S et al. Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios. julkaisussa 2017 40th International Conference on Telecommunications and Signal Processing (TSP). IEEE. 2017. s. 86-90 https://doi.org/10.1109/TSP.2017.8075942

Author

Zeman, K. ; Stusek, M. ; Pokorny, J. ; Masek, P. ; Hosek, J. ; Andreev, S. ; Dvorak, P. ; Josth, R. / Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios. 2017 40th International Conference on Telecommunications and Signal Processing (TSP). IEEE, 2017. Sivut 86-90

Bibtex - Lataa

@inproceedings{796864462b7a4a11abf6a0bd2b871d2d,
title = "Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios",
abstract = "Nowadays, many emerging technologies, such as Augmented and Virtual reality, require extremely high-rate data transmissions. This imposes an increasing demand on the network throughput, which currently surpasses the capabilities of commercially available wireless communication systems. To address this constraint, some companies are considering the implementation of high-throughput wired technologies, such as optical fibers, as part of their products. This approach is effective in terms of communication link capacity, but on the other hand may bring disadvantages and constraints in terms of user mobility (i.e., the limited length of cables). Therefore, we are currently witnessing much faster development of novel high-rate wireless technologies, which are considered to be enablers for future 5G applications. This paper offers an evaluation of the emerging IEEE 802.11ad (WiGig) wireless technology capable of delivering multi-gigabit data transfer rates. This hands-on assessment aims at real-world experimentation as well as simulation-based study of selected scenarios to assess the usability of the millimeter-wave technology in prospective 5G applications. All of our practical measurements were conducted on the commercially available WiGig-ready Dell D5000 hardware platforms. The obtained data was comprehensively compared with the corresponding simulation scenario in Network Simulator 3.",
keywords = "5G mobile communication, radio transceivers, wireless LAN, 5G applications, IEEE 802.11ad, WiGig radios, communication link capacity, millimeter-wave technology, multigigabit data transfer rates, user mobility, Antenna measurements, Bandwidth, Base stations, Hardware, Throughput, Wireless communication, 5G, Augmented and Virtual Reality, Millimeter Wave, WiGig",
author = "K. Zeman and M. Stusek and J. Pokorny and P. Masek and J. Hosek and S. Andreev and P. Dvorak and R. Josth",
year = "2017",
month = "7",
day = "1",
doi = "10.1109/TSP.2017.8075942",
language = "English",
pages = "86--90",
booktitle = "2017 40th International Conference on Telecommunications and Signal Processing (TSP)",
publisher = "IEEE",

}

RIS (suitable for import to EndNote) - Lataa

TY - GEN

T1 - Emerging 5G applications over mmWave: Hands-on assessment of WiGig radios

AU - Zeman, K.

AU - Stusek, M.

AU - Pokorny, J.

AU - Masek, P.

AU - Hosek, J.

AU - Andreev, S.

AU - Dvorak, P.

AU - Josth, R.

PY - 2017/7/1

Y1 - 2017/7/1

N2 - Nowadays, many emerging technologies, such as Augmented and Virtual reality, require extremely high-rate data transmissions. This imposes an increasing demand on the network throughput, which currently surpasses the capabilities of commercially available wireless communication systems. To address this constraint, some companies are considering the implementation of high-throughput wired technologies, such as optical fibers, as part of their products. This approach is effective in terms of communication link capacity, but on the other hand may bring disadvantages and constraints in terms of user mobility (i.e., the limited length of cables). Therefore, we are currently witnessing much faster development of novel high-rate wireless technologies, which are considered to be enablers for future 5G applications. This paper offers an evaluation of the emerging IEEE 802.11ad (WiGig) wireless technology capable of delivering multi-gigabit data transfer rates. This hands-on assessment aims at real-world experimentation as well as simulation-based study of selected scenarios to assess the usability of the millimeter-wave technology in prospective 5G applications. All of our practical measurements were conducted on the commercially available WiGig-ready Dell D5000 hardware platforms. The obtained data was comprehensively compared with the corresponding simulation scenario in Network Simulator 3.

AB - Nowadays, many emerging technologies, such as Augmented and Virtual reality, require extremely high-rate data transmissions. This imposes an increasing demand on the network throughput, which currently surpasses the capabilities of commercially available wireless communication systems. To address this constraint, some companies are considering the implementation of high-throughput wired technologies, such as optical fibers, as part of their products. This approach is effective in terms of communication link capacity, but on the other hand may bring disadvantages and constraints in terms of user mobility (i.e., the limited length of cables). Therefore, we are currently witnessing much faster development of novel high-rate wireless technologies, which are considered to be enablers for future 5G applications. This paper offers an evaluation of the emerging IEEE 802.11ad (WiGig) wireless technology capable of delivering multi-gigabit data transfer rates. This hands-on assessment aims at real-world experimentation as well as simulation-based study of selected scenarios to assess the usability of the millimeter-wave technology in prospective 5G applications. All of our practical measurements were conducted on the commercially available WiGig-ready Dell D5000 hardware platforms. The obtained data was comprehensively compared with the corresponding simulation scenario in Network Simulator 3.

KW - 5G mobile communication

KW - radio transceivers

KW - wireless LAN

KW - 5G applications

KW - IEEE 802.11ad

KW - WiGig radios

KW - communication link capacity

KW - millimeter-wave technology

KW - multigigabit data transfer rates

KW - user mobility

KW - Antenna measurements

KW - Bandwidth

KW - Base stations

KW - Hardware

KW - Throughput

KW - Wireless communication

KW - 5G

KW - Augmented and Virtual Reality

KW - Millimeter Wave

KW - WiGig

U2 - 10.1109/TSP.2017.8075942

DO - 10.1109/TSP.2017.8075942

M3 - Conference contribution

SP - 86

EP - 90

BT - 2017 40th International Conference on Telecommunications and Signal Processing (TSP)

PB - IEEE

ER -