AI-Driven Data Analytics and Intent-Based Networking for Orchestration and Control of B5G Consumer Electronics Services

Abbas, Khizar and Nauman, Ali and Bilal, Muhammad and Yoo, Jae-Hyung and Hong, James Won-Ki and Song, Wang-Cheol (2024) AI-Driven Data Analytics and Intent-Based Networking for Orchestration and Control of B5G Consumer Electronics Services. IEEE Transactions on Consumer Electronics, 70 (1). 2155 - 2169. ISSN 0098-3063

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Abstract

Network slicing is a critical feature of the beyond fifth-generation (B5G) network that supports a wide range of innovative services from 5.0 industries, next-generation consumer electronics, smart healthcare, etc. Network slicing guarantees the provisioning of quality of service (QoS) aware dedicated resources to each service. However, the orchestration and management of network slicing is very challenging because of the complex configuration process for underlying network resources. Furthermore, the third generation partnership project (3GPP) presented artificial intelligence (AI) based network data analytics function (NWDAF) in 5G for proactive management and intelligence. Therefore, we have developed an intent-based networking (IBN) system for automating network slices and an AI-driven NWDAF for proactive and intelligent resource assurance. The network data analytics function uses a hybrid stacking ensemble learning (STEL) algorithm to predict network resource utilization and a novel automated machine learning (AutoML) and voting ensemble learning-based mechanism to detect and mitigate network anomalies. To validate the performance of the implemented work, real-time datasets were employed, and a comparative analysis was conducted. The experimental result shows that our STEL model enhances the accuracy by 20% and reduces the error rate by 45%. The AutoML and ensemble learning-based optimized model achieved 99.22% accuracy for anomaly detection.

Item Type:
Journal Article
Journal or Publication Title:
IEEE Transactions on Consumer Electronics
Uncontrolled Keywords:
Research Output Funding/yes_externally_funded
Subjects:
?? electrical and electronic engineering5g communicationsintent-based networkingyes - externally fundednomedia technologyelectrical and electronic engineeringgeneral computer science ??
ID Code:
210045
Deposited By:
Deposited On:
21 Nov 2023 15:30
Refereed?:
Yes
Published?:
Published
Last Modified:
11 Dec 2024 00:32