W-band Millimeter Wave Generation and Transmission for 5G
Dr. Kamissoko Drissa
Associate Prof. Jing He
Prof. Xiquan Fu
Computer Science and Technology
College of Computer Science and Electronic Engineering
The millimeter wave communication at W-band (75–110 GHz) is one of the promising approaches to provide abundant spectrum source for the wired and wireless applications with the aid of the enormous bandwidth of the fiber. Optical fiber is the ideal medium for the mm-wave transmission due to its low loss, low cost and wide bandwidth. The resultant technology is called mm-wave RoF. In this technology, the generation of optical mm-wave carrier is one of the most relevant tasks, especially for the W-band frequencies. Various techniques have been developed for generating the mm-wave carriers and transport wideband data though RoF.
The mm-wave radio-over-fiber (mm-wave RoF) can provide efficient transmission of very high data rate from the CS to the BS enabling centralized control and monitoring. Unfortunately, due to some constraints such as crossing highways or accidental regions, fiber deployment becomes expensive and impracticable. In that case, free space optical (FSO) can be an ideal alternative to supply the equivalent capacity and quality of the fiber. FSO is a wireless line-of-sight (LOS) technology that uses invisible beams of light to provide optical bandwidth connections. Severe atmospheric attenuation such as rain can de-grade the performance of the FSO link. OFDM is a high spectrally efficient modulation technique that can resist to strong turbulence and achieve very high-speed transmission as the data is distributed over a large number of orthogonal sub-carriers. OFDM-FSO system is currently being positioned as a possible 5G backhaul and fronthaul solution because it can deliver huge volumes of data at super-fast speeds, without wires.
Kamissoko, Drissa, He, Jing, Jing He, Hassana Ganame, and Macki Tall: ‘Performance investigation of W-band millimeter-wave radio-over-fiber system employing optical heterodyne generation and self-homodyne detection’. Optics Communications 474 (2020) 126174, Doi: 10.1016/j.optcom.2020.126174.
Drissa Kamissoko, Jing He, Macki Tall and, Hassana Ganame : Characterization of OFDM Based Free Space Optical (FSO) Transmission System Under Heavy Rain Weather’. Conference paper Accepted in EAI ICECI 2020.
Drissa Kamissoko, Jing He, Macki Tall and, Hassana Ganame: “OFDM performance Under Marshal-Palmer model for Free Space Optical Transmission System”; Optics Communications
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