Abstract
In this paper, we propose a unified framework for hybrid satellite/unmanned aerial vehicle (HSUAV) terrestrial non-orthogonal multiple access (NOMA) networks, where satellite aims to communicate with ground users with the aid of a decode-forward (DF) UAV relay by using NOMA protocol. All users are randomly deployed to follow a homogeneous Poisson point process (PPP), which is modeled by the stochastic geometry approach. To reap the benefits of satellite and UAV, the links of both satellite-to-UAV and UAV-to-ground user are assumed to experience Rician fading. More practically, we assume that perfect channel state information (CSI) is infeasible at the receiver, as well as the distance-determined path-loss. To characterize the performance of the proposed framework, we derive analytical approximate closed-form expressions of the outage probability (OP) for the far user and the near user under the condition of imperfect CSI. Also, the system throughput under delay-limited transmission mode is evaluated and discussed. In order to obtain more insights, the asymptotic behavior is explored in the high signal-to-noise ratio (SNR) region and the diversity orders are obtained and discussed. To further improve the system performance, based on the derived approximations, we optimize the location of the UAV to maximize the sum rate by minimizing the average distance between the UAV and users. The simulated numerical results show that: i) there are error floors for the far and the near users due to the channel estimation error; ii) the outage probability decreases as the Rician factor K increasing, and iii) the outage performance and system throughput performance can be further improved considerably by carefully selecting the location of the UAV.
Highlights
In this paper, we propose a unified framework for hybrid satellite/unmanned aerial vehicle (HS-unmanned aerial vehicles (UAVs)) terrestrial non-orthogonal multiple access (NOMA) networks, where satellite aims to communicate with ground users with the aid of a decode-forward (DF) UAV relay by using nonorthogonal multiple access (NOMA) protocol
Motivated by the aforementioned discussion, in this study, we elaborate on the performance of the hybrid satellite/UAV (HS-UAV) networks, where the satellite aims to communicate with NOMA users with the aid of a UAV
We propose a unified framework of HS-UAV NOMA network by using a stochastic geometry approach to model the randomly deployment of ground users
Summary
W ITH the developments of mobile internet networks (MIN) and internet-of-things (IoT), there are great challenges for the fifth generation (5G) wireless communication to support massive connectivity and seamless connection under limited spectrum. Apart from the above benefits, NOMA can ensure fairness by allocating more power to the far user and few power to the near user. Regarding cellular downlink NOMA systems, authors of [16] derived analytical expressions for the outage probability (OP) and ergodic sum rate over Rayleigh fading channels. Considering the effects of residual hardware impairments on transceivers, Li et al proposed a novel cooperative simultaneous wireless information and power transfer NOMA (SWIPT-NOMA) protocol and derived the analytical expressions for the outage probability and system throughput [21]. Regarding a fullduplex (FD) scenario, Liu et al in [23] derived the analytical closed-form expressions for the outage probability and the ergodic sum rate of cooperative NOMA network, where both perfect and imperfect SIC are taken into account. Do et al in [24] considered the underlay cognitive radio inspired hybrid OMA/NOMA networks, and the outage probability and system throughput of the downlink in the secondary network were investigated and evaluated
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