Abstract
This paper investigates the impact of cooperative spectrum sharing policy on the performance of hybrid radio frequency and free space optical wireless communication networks, where primary users and secondary users develop a band of the same spectrum resource. The radio frequency links obey Nakagami-m distribution with arbitrary fading parameter m, while the free space optical link follows gamma-gamma distributed atmospheric turbulence with nonzero pointing error. Because the secondary users access the spectrum band without payment, their behavior needs to be restricted. Specifically, the power of the secondary users is dominated by the tolerable threshold of the primary users. Considering both heterodyne and intensity modulation/direct detection strategies in optical receiver, the performance of optical relaying networks is completely different from that of traditional networks. With the help of bivariable Fox’s H function, new expressions for cumulative distribution function of equivalent signal to noise ratio at destination, probability density function, outage probability, ergodic capacity and symbol error probability are built in closed forms.
Highlights
Cooperative Spectrum Sharing.The introduction of optical communication technology into a relaying system to form an optical relaying network is one of the current research hotspots
The obtained results above are used to verify the influence on the performance of the hybrid radio frequency (RF)/free space optical (FSO) in distinct atmosphere turbulence conditions and fading parameters
The design of the simulation experiments refers to the high quality references [8,9,10,11,12,13], which provide a general method for FSO communication simulation
Summary
The introduction of optical communication technology into a relaying system to form an optical relaying network is one of the current research hotspots. By combining the advantages of both radio frequency (RF) and optical communication technologies, higher rate and lower delay can be achieved by seamless connections. The construction of asymmetrical hybrid RF and optical communication links fills the connection gap between the RF circuit and the optical fiber backbone network. Based free space optical (FSO) network was investigated in [1] employing differentially. M-ary phase shift keying constellation over an exponential Weibull distributed atmospheric turbulence channel. According to the transition probability matrix in multihop scenario, the authors of [1] derived an average transition probability in an arbitrary differentially
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