Mobile Edge Computing and Field Trial Results for 5G Low Latency Scenario 被引量：7

Mobile Edge Computing and Field Trial Results for 5G Low Latency Scenario

下载PDF

导出

摘要 Through enabling the IT and cloud computation capacities at Radio Access Network(RAN),Mobile Edge Computing(MEC) makes it possible to deploy and provide services locally.Therefore,MEC becomes the potential technology to satisfy the requirements of 5G network to a certain extent,due to its functions of services localization,local breakout,caching,computation offloading,network context information exposure,etc.Especially,MEC can decrease the end-to-end latency dramatically through service localization and caching,which is key requirement of 5G low latency scenario.However,the performance of MEC still needs to be evaluated and verified for future deployment.Thus,the concept of MEC is introduced into5 G architecture and analyzed for different 5G scenarios in this paper.Secondly,the evaluation of MEC performance is conducted and analyzed in detail,especially for network end-to-end latency.In addition,some challenges of the MEC are also discussed for future deployment. Through enabling the IT and cloud computation capacities at Radio Access Network(RAN),Mobile Edge Computing(MEC) makes it possible to deploy and provide services locally.Therefore,MEC becomes the potential technology to satisfy the requirements of 5G network to a certain extent,due to its functions of services localization,local breakout,caching,computation offloading,network context information exposure,etc.Especially,MEC can decrease the end-to-end latency dramatically through service localization and caching,which is key requirement of 5G low latency scenario.However,the performance of MEC still needs to be evaluated and verified for future deployment.Thus,the concept of MEC is introduced into5 G architecture and analyzed for different 5G scenarios in this paper.Secondly,the evaluation of MEC performance is conducted and analyzed in detail,especially for network end-to-end latency.In addition,some challenges of the MEC are also discussed for future deployment.

作者 Jianmin Zhang Weiliang Xie Fengyi Yang Qi Bi

机构地区 China Telecom Co.

出处《China Communications》 SCIE CSCD 2016年第S2期174-182,共9页 中国通信（英文版）

基金 supported by the National High Technology Research and Development Program(863) of China(No.2015AA01A701)

关键词 mobile edge computing(MEC) 5G network architecture low latency mobile edge computing(MEC) 5G network architecture low latency

分类号 TN929.5 [电子电信—通信与信息系统]

引文网络
相关文献

参考文献2

1YANG Fengyi,WANG Haining,MEI Chengli,ZHANG Jianmin,WANG Min.A Flexible Three Clouds 5G Mobile Network Architecture Based on NFV & SDN[J].China Communications,2015,12(S1):121-131. 被引量：3
2WU Zhouyun,XIE Weiliang,YANG Fengyi,BI Qi.User Association in Heterogeneous Network with Dual Connectivity and Constrained Backhaul[J].China Communications,2016,13(2):11-20. 被引量：5

二级参考文献32

1A. Ghosh, et al.: "Heterogeneous cellular networks: From theory to practice", IEEE Communications Magazine, Vol. 50, Issue 6, pp. 54-64, June 2012. 被引量：1
2A. Damnjanovic, J. Montojo, Y. Wei, T. Ji, T. Luo, M. Vajapeyam, T. Yoo, O. Song, and D. Malladi, "A survey on 3GPP heterogeneous networks," IEEE Wireless Communications Magazine, yoU8, pp. 10-21, June 2011. 被引量：1
33GPP TR 36.842 V0.2.0, "Study on small cell enhancements for E-UTRA and E-UTRAN - Higher layer aspects," 2013. 被引量：1
43GPP TR 36.872, "Small cell enhancements for E-UTRA and E-UTRAN physical layer aspects Release 12)," Dec. 2013. 被引量：1
5A. Zakrzewska, D. L'opez-P'erezy, S. Kuceray, and H. Claussen, "Dua connectivity in LTE HetNets with split control- and user-plane," Proc. GLOBECOM 2013 Workshop on Broadband Wireless Access, pp. 391-396, Atlanta, GA, 2013. 被引量：1
6Koizumi, T., Higuchi, K.: 'A simple decentralized cell association method for heterogeneous networks'. Proc. IEEE ISWCS, Paris, France, pp. 256-260, August 2012. 被引量：1
7Siomina, I., Yuan, D.: 'Load balancing in heterogeneous LTE: Range optimization via cell offset and load-coupling characterization'. Proc. [EEE [CC, Ottawa, Canada, pp. 1357-1361, June 2012. 被引量：1
8S. Corroy, L. Falconetti, and R. Mathar, "Dynamic cell association for downLink sum rate maximization in multi-cell heterogeneous networksj' in Proc. IEEE ICC, pp. 2457-2461, Jun. 2012. 被引量：1
9H.-S. Jo, Y. J. Sang, R Xia, and J. Andrews, "Hetero- geneous cellular networks with flexible cell association: A comprehensive downlink sinr analysis," IEEE Trans. Wireless Commun., vol. 11, no. 10, pp. 3484-3495, Oct. 2012. 被引量：1
10Q. Ye, B. Rong, Y. Chen, M. AlShalash, C. Caramanis, and J. Andrews, "User association for load balancing in heterogeneous cellular networks," IEEE Trans. Wireless Commun., vol. 12, no. 6, pp. 2706-2716, Jun. 2013. 被引量：1

共引文献6

1张建敏,谢伟良,杨峰义.5G超密集组网网络架构及实现[J].电信科学,2016,32(6):36-43. 被引量：56
2Laiwei Jiang,Xuejun Sha,Xuanli Wu,Naitong Zhang.A Novel Resource Allocation Algorithm based on Downlink and Uplink Decouple Access Scheme in Heterogeneous Networks[J].China Communications,2016,13(6):22-31. 被引量：4
3孙杰,史迎春,宋焕生.异构网络双连接中联合资源分配快速算法[J].中国科技论文,2016,11(14):1565-1569. 被引量：1
4刘鑫一,姜建.基于用户满意度的异构物联网资源分配策略[J].中国科技论文,2017,12(8):879-882. 被引量：2
5Wenchao Xia,Jun Zhang,Shi Jin,Hongbo Zhu.Delay-Based User Association in Heterogeneous Networks with Backhaul[J].China Communications,2017,14(10):130-141. 被引量：5
6周述淇,郑辉,李小文.面向5G通信网D2D通信的架构综述[J].广东通信技术,2017,37(11):37-45. 被引量：5

同被引文献11

1张建敏,谢伟良,杨峰义,武洲云,谢亮.移动边缘计算技术及其本地分流方案[J].电信科学,2016,32(7):132-139. 被引量：74
2俞一帆,任春明,阮磊峰,陈思仁.移动边缘计算技术发展浅析[J].通信世界,2017,0(11):46-48. 被引量：5
3许明元.5G低时延技术的应用浅析[J].移动通信,2017,41(9):90-96. 被引量：19
4张建敏,谢伟良,杨峰义,武洲云.基于MEC的LTE本地分流技术[J].电信科学,2017,33(6):154-163. 被引量：21
5李佐昭,刘金旭.移动边缘计算在车联网中的应用[J].现代电信科技,2017,47(3):37-41. 被引量：29
6Mengmeng Wang,Jianwei Liu,Jian Mao,Haosu Cheng,Jie Chen,Chan Qi.Route Guardian: Constructing Secure Routing Paths in Software-Defined Networking[J].Tsinghua Science and Technology,2017,22(4):400-412. 被引量：2
7姚姝姣.5G网络关键技术及应用场景研究[J].信息通信,2017,30(3):274-275. 被引量：14
8shangguang wang,ao zhou,michael m.komarov,stephen s.yau.SERVICES AND COMMUNICATIONS IN FOG COMPUTING[J].China Communications,2017,14(11). 被引量：1
9Lihua Zhao,Minghui Du,Lin Chen.A New Multi-Resource Allocation Mechanism： A Tradeoff between Fairness and Efficiency in Cloud Computing[J].China Communications,2018,15(3):57-77. 被引量：2
10Feng Wei,Sixuan Chen,Weixia Zou.A Greedy Algorithm for Task Offloading in Mobile Edge Computing System[J].China Communications,2018,15(11):149-157. 被引量：33

引证文献7

1张建敏,谢伟良,杨峰义,武洲云.基于MEC的LTE本地分流技术[J].电信科学,2017,33(6):154-163. 被引量：21
2张建敏,谢伟良,杨峰义,武洲云.5GMEC融合架构及部署策略[J].电信科学,2018,34(4):109-117. 被引量：41
3Feng Wei,Sixuan Chen,Weixia Zou.A Greedy Algorithm for Task Offloading in Mobile Edge Computing System[J].China Communications,2018,15(11):149-157. 被引量：33
4陈志伟,郭宝,张阳.5G网络边缘计算MEC技术方案及应用分析[J].移动通信,2018,42(7):34-38. 被引量：18
5杨鑫,赵慧玲.多接入边缘计算MEC技术及业务发展策略[J].移动通信,2019,43(1):29-33. 被引量：9
6Yan Huo,Chun Meng,Ruinian Li,Tao Jing.An Overview of Privacy Preserving Schemes for Industrial Internet of Things[J].China Communications,2020,17(10):1-18.
7WANG Zhonglin,CAO Hankai,ZHAO Ping,RAO Wei.Energy-Delay Tradeoff for Online Offloading Based on Deep Reinforcement Learning in Wireless Powered Mobile-Edge Computing Networks[J].Journal of Donghua University(English Edition),2020,37(6):498-503.

二级引证文献111

1王丽丽.MEC系统关键技术在5G通信中的应用[J].新闻研究导刊,2020,0(2):240-240. 被引量：5
2沈华,王丽琼.基于移动边缘计算的任务卸载及隐私保护问题综述[J].武汉大学学报（理学版）,2023,69(2):258-269. 被引量：3
3贺海涛.5G承载网在煤矿的组网研究[J].工矿自动化,2024,50(S01):1-6.
4何二朝,耿朋进,张慧丽.基于边缘计算的电力无线专网组网方案[J].电信科学,2019,35(S02):248-255. 被引量：7
5刘云毅,张建敏,杨峰义.基于MEC的移动网络CDN增强及部署场景建议[J].电信科学,2019,35(S02):36-43. 被引量：6
6毕波.基于LTE的车联网通信系统时延优化方案[J].移动通信,2017,41(24):1-6. 被引量：7
7张建敏,谢伟良,杨峰义,武洲云.5GMEC融合架构及部署策略[J].电信科学,2018,34(4):109-117. 被引量：41
8周进,张陆洋,杨鹏.基于合同理论的D2D数据协作转发机制[J].电信科学,2018,34(10):18-26. 被引量：3
9陈志伟,郭宝,张阳.5G网络边缘计算MEC技术方案及应用分析[J].移动通信,2018,42(7):34-38. 被引量：18
10崔波,滕琳雅,吴坚鹏,孙兵,范才坤.5G自动驾驶业务网络解决方案探讨[J].广东通信技术,2019,39(2):36-40. 被引量：3

1HU Ting,QIU Chen,YU Ping,YANG LongZhi,WANG WanJun,JIANG XiaoQing,YANG Mei,ZHANG Lei,YANG JianYi.Silicon photonic network-on-chip and enabling components[J].Chinese Science Bulletin,2013,58(7):543-553. 被引量：2
2英特尔将与台湾联手布建全球首个WiMAX普及基地[J].军民两用技术与产品,2005(12):20-20.
3Zuoliang Yin,Xingpeng Mao,Jun Cai,Naitong Zhang.IDMA based MAI mitigation scheme with low complexity and low latency[J].Journal of Systems Engineering and Electronics,2012,23(6):791-801.
4周贵喜.LTE-Wi-Fi Offloading测试解决方案[J].电信网技术,2014(11):61-64.
5Bao Xuyan,Zhou Xiaojin,Zhang Yong,Song Mei.Cellular traffic offloading utilizing set-cover based caching in mobile social networks[J].The Journal of China Universities of Posts and Telecommunications,2016,23(2):46-55.
6Sang Soo Lee,Hyun Woo Cho,Sang Kyu Lim,Ki Ho Han,Jin Soo Han,Moo Jung Chu,Je Soo Ko,Kyeong-Mo Yoon,Yong-Gi Lee.Field Trial of 40 Gbit/s ETDM Prototype System over 219 km of Installed Single Mode Fiber[J].光学学报,2003,23(S1):659-660.
7Adrian Schumacher.智能数据分流Smartdata offloading——Wi-Fi数据分流可帮助运营商应对迅速增加的数据流量[J].电信网技术,2012(8):86-89.
8肖勇,周润德.Low Latency High Throughout Circular Asynchronous FIFO[J].Tsinghua Science and Technology,2008,13(6):812-816.
9Xiaofeng Tao,Dezhuang Wu,Waheed Ur Rehman,Yue Yin,Zhiling Tang.Analysis and design of handover in multicell cooperation networks: a field trial[J].Chinese Science Bulletin,2014,59(17):2065-2070.
10Kai Liang,Liqiang Zhao,Xiaohui Zhao,Yong Wang,Shumao Ou.Joint Resource Allocation and Coordinated Computation Offloading for Fog Radio Access Networks[J].China Communications,2016,13(S2):131-139. 被引量：4

China Communications

2016年第S2期

浏览历史

内容加载中请稍等...