Abstract
A communication system based on unmanned aerial vehicles (UAVs) is a viable alternative for meeting the coverage and capacity needs of future wireless networks. However, because of the limitations of UAV-enabled communications in terms of coverage, energy consumption, and flying laws, the number of studies focused on the sustainability element of UAV-assisted networking in the literature was limited thus far. We present a solution to this problem in this study; specifically, we design a Q-learning-based UAV placement strategy for long-term wireless connectivity while taking into account major constraints such as altitude regulations, nonflight zones, and transmit power. The goal is to determine the best location for the UAV base station (BS) while reducing energy consumption and increasing the number of users covered. Furthermore, a weighting method is devised, allowing energy usage and the number of users served to be prioritized based on network/battery circumstances. The suggested Q-learning-based solution is contrasted to the standard k-means clustering method, in which the UAV BS is positioned at the centroid location with the shortest cumulative distance between it and the users. The results demonstrate that the proposed solution outperforms the baseline k-means clustering-based method in terms of the number of users covered while achieving the desired minimization of the energy consumption.
Highlights
It was a truism that the number of subscriptions to mobile communication networks and the amount of data consumed per user were increasing over the years, and that the newer generations were becoming more dominant than the legacy after a few years of their first deployment [1]
From (11) it is understood that the value in the second case, i.e., with maximum allowed height of 120 m, can be assumed as the upper-bound in terms of coverage, since in this case the unmanned aerial vehicles (UAVs) is placed in the best 2D position with the maximum allowed height, that means the maximum achievable coverage area with respect to the size of the considered urban area, obtaining the maximum number of covered users
A smart UAV base station (BS) positioning mechanism was proposed by taking altitude regulations as well as NFZs into account along with some hard constraints, including maximum transmit power and directivity of the UAV BS antenna, to provide sustainable wireless coverage and services to the ground users under more realistic conditions
Summary
It was a truism that the number of subscriptions to mobile communication networks and the amount of data consumed per user were increasing over the years, and that the newer generations were becoming more dominant than the legacy after a few years of their first deployment [1]. In the fifth generation of mobile communications (5G), on the other hand, such increase is more highlighted due to the fact that there are more demanding emerging applications, including tactile internet, 4K video streaming, online gaming, etc., and the concept of Internet of Things (IoT) was seriously proliferating and pervading our daily lives with a large inclusion in various domains, such as healthcare, manufacturing, etc. The use of millimeter-wave (mmWave) frequencies, massive multi-input multioutput (mMIMO), and network densification are some of the most popular and practical ones among others [3,4,5,6]. Each of these technologies has a different set of advantages and disadvantages, they mainly target capacity enhancement in mobile communication networks. With mmWave communications, for example, an additional spectrum added to 5G networks—it was already included in 5G
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