Traffic scheduling, network slicing and virtualization based on deep reinforcement learning

The revolutionary paradigm of the 5 G network slicing introduces promising market possibilities through multi-tenancy support. Customized slices might be provided to other tenants at a different price as an emerging company to operators. Network slicing is difficult to deliver higher performance and...

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Bibliographic Details
Published in:Computers & electrical engineering 2022-05, Vol.100, p.107987, Article 107987
Main Authors: Kumar, Priyan Malarvizhi, Basheer, Shakila, Rawal, Bharat S., Afghah, Fatemeh, Babu, Gokulnath Chandra, Arunmozhi, Manimuthu
Format: Article
Language:English
Subjects:
Decision analysis
Deep learning
Deep reinforcement learning
Network slicing
Power control
Scheduling
Traffic models
Traffic scheduling
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Summary:The revolutionary paradigm of the 5 G network slicing introduces promising market possibilities through multi-tenancy support. Customized slices might be provided to other tenants at a different price as an emerging company to operators. Network slicing is difficult to deliver higher performance and cost-effective facilities through render resources utilisation in alignment with customer activity. Therefore, this paper, Deep Reinforcement Learning-based Traffic Scheduling Model (DRLTSM), has been proposed to interact with the environment by searching for new alternative actions and reinforcement patterns believed to encourage outcomes. The DRL for network slicing situations addresses power control and core network slicing and priority-based sizing involves radio resource. This paper aims to develop three main network slicing blocks i) traffic analysis and network slice forecasting, (ii) network slice admission management decisions, and (iii) adaptive load prediction corrections based on calculated deviations; Our findings suggest very significant possible improvements show that DRLTSM is dramatically improving its efficiency rate to 97.32%, scalability and compatibility in comparison with its baseline.
ISSN:0045-7906
1879-0755
DOI:10.1016/j.compeleceng.2022.107987