Title :
Power Adaptation Based on Truncated Channel Inversion for Hybrid FSO/RF Transmission With Adaptive Combining
Author :
Rakia, Tamer ; Hong-Chuan Yang ; Gebali, Fayez ; Alouini, Mohamed-Slim
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Victoria, Victoria, BC, Canada
Abstract :
Hybrid free-space optical (FSO)/radio-frequency (RF) systems have emerged as a promising solution for high-data-rate wireless communications. In this paper, we consider power adaptation strategies based on truncated channel inversion for the hybrid FSO/RF system employing adaptive combining. Specifically, we adaptively set the RF link transmission power when FSO link quality is unacceptable to ensure constant combined signal-to-noise ratio (SNR) at the receiver. Two adaptation strategies are proposed. One strategy depends on the received RF SNR, whereas the other one depends on the combined SNR of both links. Analytical expressions for the outage probability of the hybrid system with and without power adaptation are obtained. Numerical examples show that the hybrid FSO/RF system with power adaptation achieves a considerable outage performance improvement over the conventional system.
Keywords :
optical links; optical receivers; probability; radiocommunication; RF link transmission power; adaptive combining; hybrid FSO/RF transmission; outage probability; power adaptation; receiver; signal-to-noise ratio; truncated channel inversion; Adaptive optics; Atmospheric modeling; Hybrid power systems; Optical receivers; Radio frequency; Signal to noise ratio; Gamma-Gamma atmospheric turbulence model; Gamma???Gamma atmospheric turbulence model; Hybrid FSO/RF; Hybrid free-space optical (FSO)/radio-frequency (RF); MRC combining; Nakagami- $m$ fading model; Nakagami-m fading model; Outage probability; Pointing errors; Power adaptation; maximal ratio combining (MRC); outage probability; pointing errors; power adaptation;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2015.2460118
