Abstract
Unmanned Aerial Vehicles (UAVs), used in civilian applications such as emergency medical deliveries, precision agriculture, wireless communication provisioning, etc., face the challenge of limited flight time due to their reliance on the on-board battery. Therefore, developing efficient mechanisms for in situ power transfer to recharge UAV batteries holds potential to extend their mission time. In this paper, we study the use of the far-field wireless power transfer (WPT) technique from specialized, transmitter UAVs (tUAVs) carrying Multiple Input Multiple Output (MIMO) antennas for transferring wireless power to receiver UAVs (rUAVs) in a mission. The tUAVs can fly and adjust their distance to the rUAVs to maximize energy transfer gain. The use of MIMO antennas further boosts the energy reception by narrowing the energy beam toward the rUAVs. The complexity of their dynamic operating environment increases with the growing number of tUAVs and rUAVs with varying levels of energy consumption and residual power. We propose an intelligent trajectory selection algorithm for the tUAVs based on a deep reinforcement learning model called Proximal Policy Optimization (PPO) to optimize the energy transfer gain. The simulation results demonstrate that the PPO-based system achieves about a tenfold increase in flight time for a set of realistic transmit power, distance, sub-band number and antenna numbers. Further, PPO outperforms the benchmark movement strategies of “Traveling Salesman Problem” and “Low Battery First” when used by the tUAVs.
Highlights
The recent years have seen increasing advancements and decreasing costs of lowaltitude Unmanned Aerial Vehicles (UAVs), commonly known as drones
We evaluated the performance of the proposed algorithm against benchmark schemes with wireless power transfer (WPT) enabled transmitter UAVs (tUAVs)
We demonstrated that the Multiple Input Multiple Output (MIMO)-WPT provided a tenfold increase in the flight time for the deployed system compared to no wireless recharging of the UAVs
Summary
The recent years have seen increasing advancements and decreasing costs of lowaltitude UAVs, commonly known as drones. Drones carrying a range of technologies for sensing and communication are becoming popular with service providers as innovative service delivery platforms, such as for emergency medical deliveries, precision agriculture, aerial imagery, etc. Drones are employed in 5G networks either as aerial base stations providing a wireless Hotspot or mobile relaying services to the ground nodes [2,3], or as aerial nodes of cellular UAV networks [4,5]. With such a staggering market value, reliability through service continuity becomes a critical success factor [6]. In situ recharging of the drone battery using ambient energy harvesting techniques is considered as a core technology for operational UAVs in
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