基于联合优化的网络切片资源分配策略

doi:10.11959/j.issn.1000-436x.2023089

Abstract

Abstract:

To improve network resource utilization that was decreased by different applications with different requirements in 5G networks, a network slicing resource allocation strategy based on joint optimization was proposed, which was utilized to maximize both network resource utilization and network revenue by comprehensively considering in tra-slice and inter-slice resource schedule.Firstly, the user’s average satisfaction function was defined in the inter-slicing resource allocation problem.Furthermore, in terms of the number of users, slicing schedule delay and priority, a proportional fair resource allocation algorithm based on quality of service (QoS) was proposed, which was employed to achieve the best tradeoff between fairness and the users’ requirements among slices.Secondly, after two functions (service degradation and resource migration) were introduced in the inter-slice resource schedule problem, two price models were established for internal access users and external access users respectively, where congestion and non-congestion conditions were analyzed.According to the proposed price models, a Stackelberg game between the base station and users was constructed, and a global search algorithm with low complexity was leveraged to obtain the best response of the game, where the best tradeoff between the base station revenue and user utility was obtained.Simulation results show that the proposed strategy can effectively improve resource utilization and network revenue while reducing network congestion.Therefore, it can better realize fairness in resource allocation.

Key words: resource allocation, network slicing, proportional fair, Stackelberg game

CLC Number:

TN929.5

Zaijian WANG, Huimin GU. Network slicing resource allocation strategy based on joint optimization[J]. Journal on Communications, 2023, 44(5): 234-245.

Figures/Tables 9

References 25

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仿真参数	参数值
基站数量/个	2
切片数/个	3
用户数/个	100
用户分布	随机撒点
带宽/MHz	5

Network slicing resource allocation strategy based on joint optimization

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