空天地协同的边缘云服务功能链动态编排方法

doi:10.19665/j.issn1001-2400.2022.02.010

Abstract

Abstract:

As a new network architecture,the space air terrestrial integrated network has the advantages of wide network coverage and ubiquitous seamless access ability,but it also faces the contradiction between increasing users’ demands and limited network service resources.Introducing edge computing into space air terrestrial integrated networks can greatly improve the system’s business processing capability.Meanwhile,first,in order to improve the resources utilization of Space Air Terrestrial aided Mobile-access Edge Cloud (SAT-MEC) networks,and provide users with diversified and high-quality network services,we connect a group of virtual network functions according to a certain business logic,which forms a dynamic and reconfigurable service function chain.Considering the high dynamic and heterogeneous characteristics of the SAT-MEC network,the efficient scheduling method for its dynamic service function chain is studied,and the system model of the SAT-MEC network is designed.On this basis,the objective function of end-to-end delay optimization constrained by network resources and service requests is constructed.Second,combining the advantages of efficient parallel computing of Quantum Machine Learning,the path selection problem of the service function chain is modeled as a Hidden Markov Model based on Open Quantum Random Walk,with the model solved by the Quantum Backtrack Decoding method.Compared with the traditional precise solution and heuristic methods,simulation results show that the proposed method can improve the success rate of service request and reduce the end-to-end average delay under the condition of a high network traffic load.

Key words: space air terrestrial network, edge cloud network, SDN/NFV, quantum machine learning

CLC Number:

TP393

QIAO Wenxin,LU Yu,LIU Yicen,LI Zhiwei,LI Xi. Dynamic scheduling method for service function chains in space air terrestrial aided edge cloud networks[J].Journal of Xidian University, 2022, 49(2): 79-88.

Figures/Tables 8

符号	描述
G=(N,L)	底层网络拓扑G包含节点集合N和链路集合L
N=N_S∪N_A∪N_T	节点集合N包含卫星节点集合N_S、无人平台节点集合N_A和地面节点集合N_T
P,R	SFC路径集合和服务请求集合
$T n i, v x p r o c e s s$	第x个VNF v_x在节点n_i上的处理时延
$T n i, n j t r a n s f e r$ , $T n i, n j d u r a t i o n$	节点n_i和n_j之间的链路传输时延和链路可持续时间
η(v_x),δ(l)	VNF v_x所需的处理能力和链路l所需的带宽容量
π(n_i),ρ(p)	节点n_i的容量和路径p的容量
R=(E,F,D,T_d)	服务请求R包含请求所属边缘云E、所需VNFs集合F、时延D和生命周期T_d
$X n i r, v x$	服务请求r所需的VNF v_x是否映射到节点n_i的布尔变量,1代表映射,0代表否
$Y n i, n j, p r, v x, v y$	服务请求r所需的VNFs v_x和v_y是否映射到节点n_i和n_j的布尔变量,1代表映射,0代表否
$H l, p n i, n j$	虚拟链路l被节点n_i和n_j之间的路径p遍历的布尔数组,1代表遍历,0代表否

References 20

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参数	数量	计算资源/Unit	带宽资源/(Mb·s^-1)	处理时延/ms
核心云节点	1	2 000	[800,1 000]	[0.1,0.3]
MEC节点	15	[200,400]	[400,500]	[1,3]
LEO-MEC节点	1	200	[200,300]	[2,5]
SFC请求		[1,5]	[1,5]

Dynamic scheduling method for service function chains in space air terrestrial aided edge cloud networks

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