To solve the problems of unreasonable deployment and high construction costs caused by the rapid increase of the fifth generation (5 G) base stations, this article proposes a 5 G base station deployment optimization method that considers coverage and cost weights for certain areas in Kowloon, Hong Kong.
Introduction With the rapid advancement of global communication technologies, fifth generation (5 G) networks have increasingly become the cornerstone of the information age (e.g., [1, 2]). Driven by 5 G technology, there has been an explosive growth in user numbers, which has raised higher demands for base station deployment.
However, most researchers focusing on intelligent algorithm-based base station deployment consider only two-dimensional map environments, neglecting the impact of real three-dimensional geographic environments on signal propagation and the actual random distribution of users based on real-world streets and other settings.
Base station deployment optimization method based on dynamic adjustment quantum genetic algorithm
Abstract—The performance and functionalities of a com-mercial fifth generation base station are evaluated inside the reverberation chamber at the mmWave frequency range.
This article conducts an in-depth exploration of key factors influencing 5 G base station deployment optimization, including base station types, locations, heights, and other critical
Beijing''s first 5G-A (5G-Advanced) experimental base station, built by China Mobile International Information Port in Changping District, was unveiled recently after the field construction for integrated
This shows that the method proposed in this paper can effectively solve the problem of siting 5G communication base stations and achieve the rational utilization of urban spatial site resources and
This paper discusses the site optimization technology of mobile communication network, especially in the aspects of enhancing coverage and optimizing base station layout.
We showed through outdoor experimental trials that high communication speeds could be achieved over a wide area.
With 5G, communication on the ground is to merge with space for the first time to form non-terrestrial networks, in which satellites can completely take over the role of base stations.
Experimental results demonstrate that the communication base station site selection method based on an improved genetic algorithm exhibits excellent feasibility, effectiveness, and
A 38-GHz band 5G NTN (non-terrestrial network) communication base station and core network equipment, newly developed for installation in HAPS, were installed in a Cessna aircraft
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