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Journals & Magazines >IEEE Transactions on Microwav... >Volume: 60 Issue: 3

120-GHz-Band Wireless Link Technologies for Outdoor 10-Gbit/s Data Transmission

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Akihiko Hirata; Toshihiko Kosugi; Hiroyuki Takahashi; Jun Takeuchi; Hiroyoshi Togo; Makoto Yaita
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Abstract:

Our progress in 120-GHz-band wireless link technologies enables us to transmit 10-Gbit/s data transmission over a distance of more than 1 km. The 120-GHz-band wireless li...Show More

Metadata

Abstract:

Our progress in 120-GHz-band wireless link technologies enables us to transmit 10-Gbit/s data transmission over a distance of more than 1 km. The 120-GHz-band wireless link uses high-speed uni-traveling carrier photodiodes (UTC-PD) and InP high-electron mobility transistor (HEMT) millimeter-wave (MMW) monolithic integrated circuits (MMICs) for the generation of MMW signals. We investigate the maximum output power of these devices and compare the phase noise of MMW signals generated by UTC-PDs and InP HEMT MMICs. We describe the antennas we used and their operation technologies. Finally, we investigate the dependence of transmission distance on availability using the statistical rain attenuation data. The calculation results show that the 120-GHz-band wireless link can transmit 10-Gbit/s data over a distance of 1 km with availability of 99.999%.
Published in: IEEE Transactions on Microwave Theory and Techniques ( Volume: 60, Issue: 3, March 2012)
Page(s): 881 - 895
Date of Publication: 12 January 2012

ISSN Information:

DOI: 10.1109/TMTT.2011.2178256
References is not available for this document.
Contents

I. Introduction

Broadband wireless link using the upper millimeter-wave (MMW) band has recently been attracting significant interest among a diverse group comprising telecommunications carriers, mobile telephone and data network operators, broadcasters, consumer electronics manufacturers, enterprise users, and others, because of its gigabit-class data transmission capability. For indoor applications, gigabit-class 60-GHz-band wireless standards, such as WirelessHD and IEEE802.15.3c, have been established, and a WirelessHD system has achieved 4.0Gbit/s and already been integrated into television systems [1]. For outdoor applications, TV program relay broadcast and high-speed backhaul services for mobile communications appear to be the most promising applications, because the data rate necessary for these applications is increasing in proportion to the broadband trend in high-definition video or new mobile services. The 60-GHz-band and -band wireless link can achieve a data rate from 1.0 to 2.5 Gbit/s, and they have been actually used in the mobile backhaul services. It is expected that the over-10-Gbit/s data rate will be required for mobile backhaul in the near future.

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