智慧交通场景下云边端协同的多目标优化卸载决策

doi:10.19665/j.issn1001-2400.20230802

Abstract

Abstract:

With the rapid development of intelligent transportation,the cloud computing network and the edge computing network,the information interaction among vehicle terminal,road base unit and central cloud server becomes more and more frequent.In view of how to efficiently realize vehicle-road-cloud integration fusion sensing,group decision making and reasonable allocation of re-sources between each server and the servers under the cloud-edge-terminal collaborative computing scenario of intelligent transportation,a network architecture based on the comprehensive convergence of the cloud-edge-terminal and intelligent transportation is designed.A network architecture based on the comprehensive integration of cloud-side-end and intelligent transportation is designed.Under this architecture,by reasonably dividing the task types,each server selectively caches and offloads them;under the collaborative computing scenario of the cloud-side-end of intelligent transportation,an adaptive caching model for tasks,a task offloading delay model,a system energy loss model,a model for evaluating the dissatisfaction of in-vehicle users with the quality of service,and a model for the multi-objective optimization problem are designed in turn,and a multi-objective optimization task offloading decision-making scheme is given based on the improved non-dominated genetic algorithms.Experimental results show that the proposed scheme can effectively reduce the delay and energy consumption brought by the task offloading process,improve the utilization rate of system resources,and bring better service experience to the vehicle user.

Key words: smart transportation, cloud edge collaborative computing, offloading decision, multi-objective optimization algorithm, non-dominated select genetic algorithms Ⅱ(NSGA-Ⅱ) algorithm

CLC Number:

TP393.1

ZHU Sifeng, SONG Zhaowei, CHEN Hao, ZHU Hai, QIAO Rui. Multi-objective optimization offloading decision with cloud-side-end collaboration in smart transportation scenarios[J].Journal of Xidian University, 2024, 51(3): 63-75.

Figures/Tables 12

References 22

[1]	SUN Y, HU Y, ZHANG H, et al. A Parallel Emission Regulatory Framework for Intelligent Transportation Systems and Smart Cities[J]. IEEE Transactions on Intelligent Vehicles, 2023, 2(8):1017-1020.
[2]	ZHU F, LV Y, CHEN Y, et al. Parallel Transportation Systems:Toward IoT-Enabled Smart Urban Traffic Control and Management[J]. IEEE Transactions on Intelligent Transportation Systems, 2020, 10(21):4063-4071.
[3]	MAO S, WU J S, LIU L, et al. Energy-Efficient Cooperative Communication and Computation for Wireless Powered Mobile-Edge Computing[J]. IEEE Systems Journal, 2022, 16(1):28-41.
[4]	CHEN C, LIU B, WANG S, et al. An Edge Traffic Flow Detection Scheme Based on Deep Learning in an Intelligent Transportation System[J]. IEEE Transactions on Intelligent Transportation Systems, 2021, 3(22):1840-1852.
[5]	XU X, ZHANG X, LIU X, et al. Adaptive Computation Offloading with Edge for 5G-Envisioned Internet of Connected Vehicles[J]. IEEE Transactions on Intelligent Transportation Systems, 2020, 22(8):5213-5222.
[6]	LIANG S. Edge YOLO:Real-Time Intelligent Object Detection System Based on Edge-Cloud Cooperation in Autonomous Vehicles[J]. IEEE Transactions on Intelligent Transportation Systems, 2022, 12(23):25345-25360.
[7]	QIAO G, LENG S, MAHARJAN S, et al. Deep Reinforcement Learning for Cooperative Content Caching in Vehicular Edge Computing and Networks[J]. IEEE Internet of Things Journal, 2020, 1(7):247-257.
[8]	朱思峰, 蔡江昊, 柴争义, 等. 车联网云边协同计算场景下的多目标优化卸载决策[J]. 通信学报, 2022, 43(6):223-234. doi: 10.11959/j.issn.1000-436x.2022114
	ZHU Sifeng, CAI Jianghao, CHAI Zhengyi, et al. Multi-Objective Optimal Offloading Decision under Cloud-Side Cooperative Computing Scenario for Vehicular Networking[J]. Journal on Communications, 2022, 43(6):223-234. doi: 10.11959/j.issn.1000-436x.2022114
[9]	ZHAO J, LI Q, GONG Y, et al. Computation Offloading and Resource Allocation for Cloud Assisted Mobile Edge Computing in Vehicular Networks[J]. IEEE Transactions on Vehicular Technology, 2019, 68(8):7944-7956.
[10]	POL P S, PACHGHARE V K. Quality of Service Estimation Enabled with Trust-Based Resource Allocation in Collaborative Cloud Using Improved Grey Wolf Optimization[J]. The Computer Journal, 2022, 65(12):3209-3222.
[11]	马璐, 刘铭, 李超, 等. 面向6G边缘网络的云边协同计算任务调度算法[J]. 北京邮电大学学报, 2020, 43(6):66-73. doi: 10.13190/j.jbupt.2020-161
	MA Lu, LIU Ming, LI Chao, et al. Task Scheduling Algorithm of Cloud Edge Collaborative Computing for 6G Edge Networks[J]. Journal of Beijing University of Posts and Telecommunications, 2020, 43(6):66-73. doi: 10.13190/j.jbupt.2020-161
[12]	WU H, ZHANG Z, GUAN C, et al. Collaborate Edge and Cloud Computing with Distributed Deep Learning for Smart City Internet of Things[J]. IEEE Internet of Things Journal, 2020, 7(9):8099-8110.
[13]	赵辉, 冯南之, 王泉, 等. 面向边缘计算平台的半线上任务动态调度方法[J]. 西安电子科技大学学报, 2021, 48(6):8-15.
	ZHAO Hui, FENG Nanzhi, WANG Quan, et al. A Dynamic Scheduling Method for Semi-Online Tasks for Edge Computing Platform[J]. Journal of Xidian University, 2021, 48(6):8-15.
[14]	朱思峰, 孙恩林, 柴争义. 移动边缘计算场景下基于免疫优化的任务卸载[J]. 西安电子科技大学学报, 2022, 49(1):152-160.
	ZHU Sifeng, SUN Enlin, CHAI Zhengyi. Immuno Optimization Based Task Offloading in Mobile Edge Computing Scenarios[J]. Journal of Xidian University, 2022, 49(1):152-160.
[15]	LUO Q, LI C, LUAN T, et al. Minimizing the Delay and Cost of Computation Offloading for Vehicular Edge Computing[J]. IEEE Transactions on Services Computing, 2022, 15(5):2897-2909.
[16]	XIAO Z, SHU J, JIANG H, et al. Perception Task Offloading with Collaborative Computation for Autonomous Driving[J]. IEEE Journal on Selected Areas in Communications, 2023, 41(2):457-473.
[17]	QU G, WU H, LI R, et al. DMRO:A Deep Meta Reinforcement Learning-Based Task Offloading Framework for Edge-Cloud Computing[J]. IEEE Transactions on Network and Service Management, 2021, 18(3):3448-3459.
[18]	DEB K, PRATAP A, AGARWAl S, et al. A Fast and Elitist Multi-Objective Genetic Algorithm:NSGA-Ⅱ[J]. IEEE Transactions on Evolutionary Computation, 2002, 6(2):182-197.
[19]	ALIOUI Y, RESAT A. An Evaluation of a Constrained Multi-Objective Genetic Algorithm[J]. Journal of Scientific Perspectives, 2020, 4(2):137-146.
[20]	LIANG X, CHEN J, GU X, et al. Improved Adaptive Non-Dominated Sorting Genetic Algorithm with Elite Strategy for Solving Multi-Objective Flexible Job-Shop Scheduling Problem[J]. IEEE Access, 2021, 38(9):106352-106362.
[21]	MA X, LI X, ZHANG Q, et al. A Survey on Cooperative Co-Evolutionary Algorithms[J]. IEEE Transactions on Evolutionary Computation, 2019, 23(3):421-441.
[22]	SONG F, XING H, LUO S, et al. A Multi-Objective Computation Offloading Algorithm for Mobile-Edge Computing[J]. IEEE Internet of Things Journal, 2020, 9(7):8780-8799.

参数	数值
任务的数据量D_i_,_k/MIPS	1~5随机
存储任务所需的存储资源Z_i_,_k/MIPS	1~5随机
服务单元计算资源C_i/MIPS	10,100,600,1 000
缓存资源Z_r/MIPS	10~100随机
带宽B_M/(M·bit^-1)	200,300,2 000
信道个数N	10,6,5
边缘服务器传输功率P/W	600
同一信道下车辆之间的干扰参数L/Hz	60~120随机
边缘服务器与路测单元间的信道增益η/W	10~15随机
ɑ₁	0.8
ɑ₂	0.1
ɑ₃	0.8
θ_V2V/(M·bit^-1)	600
θ_V2E/(M·bit^-1)	1 000
智能网联车计算功率∂/W	50
智能网联车传输功率γ/W	100

Multi-objective optimization offloading decision with cloud-side-end collaboration in smart transportation scenarios

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 12

References 22

Related Articles 1

Metrics

Comments

Recommended 0