Abstract
Unmanned Aerial Vehicle (UAV)-assisted cellular networks over the millimeter-wave (mmWave) frequency band can meet the requirements of a high data rate and flexible coverage in next-generation communication networks. However, higher propagation loss and the use of a large number of antennas in mmWave networks give rise to high energy consumption and UAVs are constrained by their low-capacity onboard battery. Energy harvesting (EH) is a viable solution to reduce the energy cost of UAV-enabled mmWave networks. However, the random nature of renewable energy makes it challenging to maintain robust connectivity in UAV-assisted terrestrial cellular networks. Energy cooperation allows UAVs to send their excessive energy to other UAVs with reduced energy. In this paper, we propose a power allocation algorithm based on energy harvesting and energy cooperation to maximize the throughput of a UAV-assisted mmWave cellular network. Since there is channel-state uncertainty and the amount of harvested energy can be treated as a stochastic process, we propose an optimal multi-agent deep reinforcement learning algorithm (DRL) named Multi-Agent Deep Deterministic Policy Gradient (MADDPG) to solve the renewable energy resource allocation problem for throughput maximization. The simulation results show that the proposed algorithm outperforms the Random Power (RP), Maximal Power (MP) and value-based Deep Q-Learning (DQL) algorithms in terms of network throughput.
Highlights
Unmanned Aerial Vehicles (UAVs) are aircrafts without a human pilot on board
We study optimal power allocation strategies for UAV-assisted mmWave cellular networks when there is channel-state uncertainty and the amount of harvested energy can be treated as a stochastic process
A power allocation algorithm based on energy harvesting and energy cooperation is proposed to maximize the throughput of a UAV-assisted mmWave cellular network
Summary
Unmanned Aerial Vehicles (UAVs) are aircrafts without a human pilot on board. UAVs are able to establish on-demand wireless connectivity faster than terrestrial communications and they can adjust their height and position to provide robust channels with shortrange line-of-sight links [1]. The large available spectrum resources of mmWave communication and flexible beamforming can meet the requirements of high data rate and flexible coverage for UAVs serving as base stations (UAV-BSs) in UAV-assisted cellular networks [3]. [24], a downlink wireless power transfer and an uplink information transfer is proposed for mmWave UAVto-ground networks These contributions do not analyze energy cooperation between UAV-BSs. In this paper, we propose a power allocation algorithm based on energy harvesting and energy cooperation to maximize the throughput of a UAV-assisted mmWave cellular network. We propose a power allocation algorithm based on energy harvesting and energy cooperation to maximize the throughput of a UAV-assisted mmWave cellular network This optimal power allocation and energy transfer problem can be regarded as a discrete-time Markov Decision Process (MDP) [25] with continuous state and action space.
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