Title :
Investigation and simulation of meteorological effects on millimeter wave ad-hoc mesh networks in 5G systems
Author :
Farago, Akos ; Kantor, Peter ; Bito, Janos Z.
Author_Institution :
Dept. of Broadband Infocommunications & Electromagn. Theor., Budapest Univ. of Technol. & Econ., Budapest, Hungary
Abstract :
Substantial growth of mobile data and rapidly increasing spread of smartphones nowadays present major challenge for mobile service providers. The allotted spectrum for the currently operating mobile communicating systems have been saturated in the last years by such considerable rate that the future´s fifth generation network would not be able to fulfil its requirements without applying new frequencies. In accordance with the concept of 5G, millimeter wave spectrum will also be used along with the current frequency bands. This spectrum however, introduces meteorological effects as a new and significant attenuation factor. In this paper mm-wave propagation affected by precipitation will be investigated and a simulation environment (written in Matlab) used for the 5G mm-wave mesh networks statistical investigation will be presented.
Keywords :
5G mobile communication; atmospheric precipitation; meteorology; millimetre wave propagation; radio spectrum management; smart phones; tropospheric electromagnetic wave propagation; wireless mesh networks; 5G millimeter wave ad hoc mesh network statistics; attenuation factor; fifth generation network; meteorological effects; millimeter wave spectrum; mm-wave propagation; mobile communication system; mobile data substantial growth; smart phone; 5G mobile communication; Attenuation; Mesh networks; Millimeter wave technology; Nonhomogeneous media; Rain; 5G; cellular; mesh network; millimeter wave propagation; mobile communication; rain attenuation;
Conference_Titel :
Transparent Optical Networks (ICTON), 2015 17th International Conference on
Conference_Location :
Budapest
DOI :
10.1109/ICTON.2015.7193470
