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Proceedings Paper

Performance evaluation of non-line-of-sight optical communication system operating in the solar-blind ultraviolet spectrum
Author(s): Nikos Raptis; Evangelos Pikasis; Dimitris Syvridis
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Paper Abstract

For several years, it has been examined if the attributes of the wavelengths in C band of the Ultraviolet (UV) spectrum that lie between 200 and 280 nm can be exploited in order to set up short range covert links of low rate in a Non-Line-of-Sight (NLOS) regime. In the present work, it is experimentally investigated and verified that using this band, short range and low rate NLOS links using the same transmitter/receiver pair under different atmospheric conditions without applying extreme power levels can be implemented rather effectively. The transmitter was composed of four Light Emitting Diodes. At the receiving side, an optical filter was followed by a Photo-Multiplier Tube. Initially, we measured the power losses of the channels with and without fog (artificially generated) for ranges up to 20 meters and several transmitters/receiver configurations. Secondly, the performance of Fourth-order Pulse Position Modulation (4-PPM) and Flip Orthogonal Frequency Division Multiplexing (Flip-OFDM) was evaluated for such channels and 10 Kbit/s rate. Applying emissions at 265 nm, NLOS links can operate efficiently especially in harsh environments, as the power losses were lowered when fog appeared. In terms of the modulation formats, 4-PPM performed better in most cases. Better results were obtained for both schemes when the medium became thicker due to the presence of fog. Finally, some initial measurements were realized with a Silicon Carbide PiN photodiode for the same rate but low elevation angles. The performance was exactly the opposite compared to a receiver with inherent gain when the atmosphere thickened.

Paper Details

Date Published: 21 October 2016
PDF: 13 pages
Proc. SPIE 9991, Advanced Free-Space Optical Communication Techniques and Applications II, 999107 (21 October 2016); doi: 10.1117/12.2241424
Show Author Affiliations
Nikos Raptis, National and Kapodistrian Univ. of Athens (Greece)
Evangelos Pikasis, National and Kapodistrian Univ. of Athens (Greece)
Dimitris Syvridis, National and Kapodistrian Univ. of Athens (Greece)


Published in SPIE Proceedings Vol. 9991:
Advanced Free-Space Optical Communication Techniques and Applications II
Leslie Laycock; Henry J. White, Editor(s)

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