Title :
Fade Mitigation Based on Semiconductor Optical Amplifiers
Author :
Yiannopoulos, K. ; Sagias, Nikos C. ; Boucouvalas, A.C.
Author_Institution :
Dept. of Inf. & Telecommun., Univ. of Peloponnese, Tripoli, Greece
Abstract :
We present and analyze a novel fade mitigation technique that is applicable on outdoor optical wireless systems. Our key idea is to utilize the nonlinear power-dependent gain properties of a semiconductor optical amplifier (SOA) to provide unbalanced amplification between faded and non-faded instances of the optical wireless signal. We analytically demonstrate that this power equalization process smoothes out fade-induced power fluctuations and drastically reduces the probability of the system being in a fade state. In medium to strong turbulence governed by gamma-gamma statistics, our results predict that the fade probability can be reduced by over 80% when the SOA is introduced at the optical wireless receiver. We also show that the duration of remaining fades is reduced by a sizeable percentage, and a percentile reduction of the average fade duration of over 85% can be achieved at the SOA output.
Keywords :
fading channels; gamma distribution; optical receivers; semiconductor optical amplifiers; SOA; average fade duration; fade mitigation; fade probability; fade state; fade-induced power fluctuations; gamma-gamma statistics; nonlinear power-dependent gain properties; optical wireless receiver; optical wireless signal; outdoor optical wireless systems; power equalization; semiconductor optical amplifiers; turbulence; unbalanced amplification; Gain; Optical pulses; Optical receivers; Optical saturation; Optical transmitters; Power generation; Semiconductor optical amplifiers; Average fade duration; gamma-gamma fading; level crossing rates (LCR); outdoor optical wireless; scintillation index (SI); semiconductor optical amplifier (SOA);
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2013.2285260
