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01.12.2023

Optimizing radio access in 5G vehicle networks using novel machine learning-driven resource management

verfasst von: Rajesh Natarajan, Natesh Mahadev, Badria Sulaiman Alfurhood, Christodoss Prasanna Ranjith, John Zaki, M. N. Manu

Erschienen in: Optical and Quantum Electronics | Ausgabe 14/2023

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Abstract

Modern wireless technologies and vehicular networks are unable to handle the enormous crossover of vehicle network requirements. In order to achieve objectives in a vehicle environment, managing resource has become a challenging endeavor. The 5G wireless protocol claims it provides exceptionally fast, dependable, and delay-free connectivity. A crucial technology that will make 5G possible includes software-defined networking (SDN). It ensures improved performance everywhere. The major difficulties are limiting the expanding range of vehicles and ensuring uninterrupted changes inside the bases. Furthermore, very low latency and high reliability necessary for offering applications that require safety like autonomous driving. Effective resource allocation solutions are needed because of the small quantity of spectrum that's accessible and the fluid nature of vehicular communication. In order to keep the network functional effectively, interference and congestion in channels must be avoided, and priority approaches are needed to accommodate different users' demands. In the current piece, we suggested an energy allocation method for using a radio frequency in 5G networks for vehicles Boosting Ant Colony Optimization and Magnified Recurrent Neural Network (BACO–MRNN) based traffic classification. The BACO–MRNN algorithm imposed superior outcomes as measured by several parameters, combining precision of 97.23%, accuracy of 98.10%, F1-Score of 98.45%, recall of 98.15%, and RMSE of 30.10%. A highly complex aptitude for discrimination was also revealed by the BACO–MRNN classification. For connected vehicles to fulfill all of their potential and for smart modes of transportation to be noticed radio accessibility pertaining to 5G vehicle networks has to be effectively addressed. 5G vehicle networks are necessary for the widespread adoption of autonomous vehicles. In order to facilitate safe and efficient autonomous driving, 5G’s ultra-low latency and fast connectivity enable motor vehicles, amenities the cloud, and real-time communication.

Vorheriger Artikel Next generation WDM-radio over fiber passive optical network: deep neural network based performance analysis

Nächster Artikel Bifurcation and chaotic behaviors to the Sasa–Satsuma and higher-order Sasa–Satsuma equations in fluid dynamics and nonlinear optics

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Titel: Optimizing radio access in 5G vehicle networks using novel machine learning-driven resource management
verfasst von: Rajesh Natarajan
Natesh Mahadev
Badria Sulaiman Alfurhood
Christodoss Prasanna Ranjith
John Zaki
M. N. Manu
Publikationsdatum: 01.12.2023
Verlag: Springer US
Erschienen in: Optical and Quantum Electronics / Ausgabe 14/2023
Print ISSN: 0306-8919
Elektronische ISSN: 1572-817X
DOI: https://doi.org/10.1007/s11082-023-05388-2

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