Abstract
Unmanned aerial vehicle (UAV) communication is regarded as a promising technology for lightweight Internet of Things (IoT) communications in narrowband-IoT (NB-IoT) systems deployed in rugged terrain. In such UAV-assisted NB-IoT systems, the optimal UAV placement and resource allocation play a critical role. Consequently, the joint optimization of the UAV placement and resource allocation is considered in this study to improve the system capacity. Because the considered optimization problem is an NP-hard problem and owing to its non-convex property, it is difficult to optimize both the UAV placement and resource allocation simultaneously. Therefore, a competitive clustering algorithm has been developed by exchanging strategies between the UAV and the adjacent IoT devices to optimize the UAV placement. With multiple iterations, the UAV and the IoT devices within the coverage area of the UAV, converge their clustering strategies, which are suboptimal, to satisfy both sides. The bordering IoT devices of the adjacent clusters are then migrated heuristically toward each other to obtain the optimal system capacity maximization. Finally, the transmission throughput is optimized using the Nash equilibrium. The simulation results demonstrate that the algorithms proposed in this study exhibit rapid convergence, within 10 iterations, even in a large environment. The performance evaluation demonstrates that the proposed scheme improves the system capacity of the existing schemes by approximately 28%.
Highlights
Unmanned aerial vehicle (UAV)-assisted communications have gained widespread attention for their contribution toward human convenience and efficient line-of-sight (LoS)links [1] from the air to the ground
Extensive research on UAV communications in wireless systems has been carried out recently to serve mobile users in complex urban areas as well as remote locations, where terrestrial communication is extremely difficult. This issue is more critical in Internet of Things (IoT) systems because IoT devices are typically limited to small battery capacities and,are used in short-distance communication [4,5]
The fixed beamwidth of the receiving antenna was set to π/3 for each UAV, and the altitude constraint of each UAV was in the range of hmin = 50 m and hmax = 500 m
Summary
Unmanned aerial vehicle (UAV)-assisted communications have gained widespread attention for their contribution toward human convenience and efficient line-of-sight (LoS)links [1] from the air to the ground. In various fields, such as agriculture and logistics, the use of UAVs is popular and common, and virtually essential [2,3]. Extensive research on UAV communications in wireless systems has been carried out recently to serve mobile users in complex urban areas as well as remote locations, where terrestrial communication is extremely difficult. This issue is more critical in Internet of Things (IoT) systems because IoT devices are typically limited to small battery capacities and ,are used in short-distance communication [4,5]. The utilization of UAVs to assist such IoT systems with the narrowband-IoT (NB-IoT) technology is a novel solution [11,12]
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