SDN和MEC架构下V2X卸载与资源分配

doi:10.11959/j.issn.1000-436x.2020023

Abstract

Abstract:

To address the serious problem of delay and energy consumption increase and service quality degradation caused by complex network status and huge amounts of computing data in the scenario of vehicle-to-everything (V2X),a vehicular network architecture combining mobile edge computing (MEC) and software defined network (SDN) was constructed.MEC sinks cloud serviced to the edge of the wireless network to compensate for the delay fluctuation caused by remote cloud computing.The SDN controller could sense network information from a global perspective,flexibly schedule resources,and control offload traffic.To further reduce the system overhead,a joint task offloading and resource allocation scheme was proposed.By modeling the MEC-based V2X offloading and resource allocation,the optimal offloading decision,communication and computing resource allocation scheme were derived.Considering the NP-hard attribute of the problem,Agglomerative Clustering was used to select the initial offloading node,and Q-learning was used for resource allocation.The offloading decision was modeled as an exact potential game,and the existence of Nash equilibrium was proved by the potential function structure.The simulation results show that,as compared to other mechanisms,the proposed mechanism can effectively reduce the system overhead.

Key words: vehicular network, mobile edge computing, software defined network, resource allocation

CLC Number:

TN929.5

Haibo ZHANG,Zixin WANG,Xiaofan HE. V2X offloading and resource allocation under SDN and MEC architecture[J]. Journal on Communications, 2020, 41(1): 114-124.

Figures/Tables 7

References 37

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参数	数值
任务计算大小d_i /KB	400～500
计算任务所需CPU周期s_i /Megacycle	1 200～2 000
上行传输信道数量K	10
单小区车辆数目	18
信道总带宽/MHz	20
高斯白噪声功率N₀ /dBm	-60
权重因子设置α=β	0.5
车辆计算能力F_i/GHz	0.7 ～1
MEC服务器计算能力 f_j /GHz	4
车辆最大发射功率 p_max/dBm	20
RSU的覆盖半径/m	250

V2X offloading and resource allocation under SDN and MEC architecture

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