%0 Conference Proceedings
%T Analog IFoF/mmWave 5G Optical Fronthaul Architecture for Hot-Spots Using Multi-channel OFDM-Based WDM Signals
%+ Aristotle University of Thessaloniki
%+ Department of Computer Engineering and Informatics [Patras]
%+ LIONIX International B.V.
%A Mitsolidou, Charoula
%A Vagionas, Christos
%A Mesodiakaki, Agapi
%A Maniotis, Pavlos
%A Kalfas, George
%A Roeloffzen, Chris
%A Dijk, Paulus
%A Oldenbeuving, Ruud, M.
%A Miliou, Amalia
%A Pleros, Nikos
%Z Part 2: Poster Papers
%< avec comité de lecture
%( Lecture Notes in Computer Science
%B 23th International IFIP Conference on Optical Network Design and Modeling (ONDM)
%C Athens, Greece
%Y Anna Tzanakaki
%Y Manos Varvarigos
%Y Raul Muñoz
%Y Reza Nejabati
%Y Noboru Yoshikane
%Y Markos Anastasopoulos
%Y Johann Marquez-Barja
%I Springer International Publishing
%3 Optical Network Design and Modeling
%V LNCS-11616
%P 504-515
%8 2019-05-13
%D 2019
%R 10.1007/978-3-030-38085-4_43
%K 5G networks
%K Analog fronthaul
%K Intermediate Frequency over Fiber
%K OFDM
%K Photonic Integrated Circuit
%K ROADM
%Z Computer Science [cs]
%Z Computer Science [cs]/Networking and Internet Architecture [cs.NI]Conference papers
%X An analog Intermediate-Frequency-over-Fiber (IFoF) – based fronthaul 5G architecture for high traffic hot-spot environments is presented. The proposed optical fronthaul link utilizes Photonic Integrated Circuit (PIC) Wavelength Division Multiplexing (WDM) Externally Modulated Laser (EML) - based optical transmitters at a centralized Base Band Unit (BBU) and Reconfigurable Optical Add-Drop Multiplexers (ROADMs) at the Remote Radio Head (RRH) side located in the hot-spot area. By employing two WDM links, where each wavelength carries six 0.5 Gbaud IF bands of Orthogonal Frequency Division Multiplexing (OFDM) with 16 – QAM Sub-Carrier (SC) modulation, a total data rate of 96 Gb/s was achieved. Error Vector Magnitude (EVM) measurements were carried out, exhibiting acceptable performance below the EVM FEC limit of 12.5%. A power budget study was also performed, suggesting up to 9.5 km fiber lengths between the BBU and the hot-spot network. The proposed architecture complies with the high capacity and low latency requirements of the 5G vision, thus may be an efficient solution for 5G fronthauling of heavy traffic hot-spot areas.
%G English
%Z TC 6
%Z WG 6.10
%2 https://inria.hal.science/hal-03200670/document
%2 https://inria.hal.science/hal-03200670/file/484327_1_En_43_Chapter.pdf
%L hal-03200670
%U https://inria.hal.science/hal-03200670
%~ IFIP-LNCS
%~ IFIP
%~ IFIP-TC
%~ IFIP-WG
%~ IFIP-TC6
%~ IFIP-LNCS-11616
%~ IFIP-ONDM
%~ IFIP-WG6-10