5G先进技术研究进展

林泓池; 孙文彬; 郭继冲; 麻津铭; 周永康; 于启月; 孟维晓

doi:10.11959/j.issn.1000−0801.2018238

您当前的位置：

首页 >

文章列表页 >

5G先进技术研究进展

专题：5G | 更新时间：2024-06-05

- 5G先进技术研究进展
- Research progress of 5G advanced technologies
- 电信科学 2018年34卷第8期页码：34-45
- 作者机构：
- 作者简介：
  
  [ "林泓池（1993−），男，哈尔滨工业大学硕士生，主要研究方向为超密集组网和非正交多址。" ]
  [ "孙文彬（1990−），男，哈尔滨工业大学博士生，主要研究方向为无线通信、多天线技术以及预编码技术。" ]
  [ "郭继冲（1992−），男，哈尔滨工业大学博士生，主要研究方向为无线信道建模、毫米波系统、预编码技术。" ]
  [ "麻津铭（1994−），男，哈尔滨工业大学硕士生，主要研究方向为超密集组网。" ]
  [ "周永康（1994−），男，哈尔滨工业大学硕士生，主要研究方向为稀疏码多址接入的码本设计和技术应用。" ]
  [ "于启月（1982−），女，博士，哈尔滨工业大学电子与信息工程学院教授、博士生导师，主要研究方向为宽带无线通信、信息论与编码等。" ]
  [ "孟维晓（1968−），男，博士，哈尔滨工业大学电子与信息工程学院教授、博士生导师，主要研究方向为无线移动通信、空天通信网络和卫星定位导航。" ]
- 基金信息：
  
  国家自然科学基金资助项目;The National Natural Science Foundation of China(61728104);黑龙江省自然科学基金重点项目;The Natural Science FoundationMajor Project of Heilongjiang Province(ZD2017013)
- DOI：10.11959/j.issn.1000−0801.2018238
  中图分类号： TP393
- 网络出版日期：2018-08，
  
  纸质出版日期：2018-08-20
- 稿件说明：
移动端阅览
林泓池, 孙文彬, 郭继冲, 等. 5G先进技术研究进展[J]. 电信科学, 2018,34(8):34-45.

Hongchi LIN, Wenbin SUN, Jichong GUO, et al. Research progress of 5G advanced technologies[J]. Telecommunications science, 2018, 34(8): 34-45.
林泓池, 孙文彬, 郭继冲, 等. 5G先进技术研究进展[J]. 电信科学, 2018,34(8):34-45. DOI： 10.11959/j.issn.1000−0801.2018238.

Hongchi LIN, Wenbin SUN, Jichong GUO, et al. Research progress of 5G advanced technologies[J]. Telecommunications science, 2018, 34(8): 34-45. DOI： 10.11959/j.issn.1000−0801.2018238.

摘要

5G 移动通信技术的标准制定正在如火如荼地进行中，相比前几代移动通信技术，5G面临着更复杂的业务需求、更极致的用户体验和更密集的网络架构。而且5G需要在大数据和人工智能的时代到来之前，做好万物互联的通信基础。对目前5G的一些热点技术进行了简单的介绍，首先给出了5G的技术愿景和需求目标，然后对大规模天线技术、超密集组网技术和非正交多址技术3个热点技术的研究进展情况进行了简单的阐述。

Abstract

The standards of the 5th generation communication technology were picking up.Compared with previous generations’communication technologies

5G will facemore complex business requirements

more extreme user experience andmore dense network architecture.Moreover

5G needs to lay a good communication foundation for IoT before the arrival of the era of big data and artificial intelligence.Some hot technologies of 5G were briefly introduced.Firstly

the techni cal vision and demand target of 5G was given

and then the research progress of three hot technologies ofmassive MIMO

ultra dense network and non-orthogonalmulti-access technology was expounded.

关键词

Keywords

references

IMT-2020(5G)推进组.5G 概念白皮书 [R ] . 2015 .

IMT-2020(5G)Propulsion Group.5G concept white paper [R ] . 2015 .

ITU-R.IMT vision,framework and overall objectives of the future development of IMT for 2020 and beyond:ITU-R Document 5/199-E.M 2083-0 [S ] . 2015 .

张平 , 陶运铮 , 张治 . 5G 若干关键技术评述 [J ] . 通信学报 , 2016 , 37 ( 7 ): 15 - 29 .

ZHANG P , TAO Y Z , ZHANG Z . Survey of several key technologies for 5G [J ] . Journal on Communications , 2016 , 37 ( 7 ): 15 - 29 .

AGYAPONG P , IWAMURA M , STAEHLE D , et al . Design considerations for a 5G network architecture [J ] . IEEE CommunicationsMagazine , 2014 , 52 ( 11 ): 65 - 75

王祖阳 , 杨传祥 , 张进 , 等 . 5G 无线网技术特征及部署应对策略分析 [J ] . 电信科学 , 2018 , 34 ( Z1 ): 9 - 16 .

WANG Z Y , YANG C X , ZHANG J , et al . Analysis of 5G wireless network technology characteristics and deployment strategy [J ] . Telecommunications Science , 2018 , 34 ( Z1 ): 9 - 16 .

尤肖虎 , 潘志文 , 高西奇 , 等 . 5G 移动通信发展趋势与若干关键技术 [J ] . 中国科学:信息科学 , 2014 , 44 ( 5 ): 551 - 563 .

YOU X H , PAN Z W , GAO X Q , et al . The 5Gmobile communication:the development trends and its emerging key techniques [J ] . Scientia Sinica Informationis , 2014 , 44 ( 5 ): 551 - 563 .

ANDREWS J G . What will 5G be? [J ] . IEEE Journal on Selected Areas in Communications , 2014 , 32 ( 6 ): 1065 - 1082 .

MARZETTA T . Noncooperative cellular wireless with unlimited numbers of base station antennas [J ] . IEEE Transactions on Wireless Communications , 2010 , 11 ( 9 ): 3590 - 3600 .

SOHRABI F , YU W . Hybrid digital and analog beamforming design for large-s cale antenna arrays [J ] . IEEE Journal of Selected Topics in Signal Processing , 2016 , 10 ( 3 ): 501 - 513 .

GAO X , DAI L , CHEN Z , et al . Near-optimal beam selection for beamspacemmWavemassive MIMO systems [J ] . IEEE Communications Letters , 2016 , 20 ( 5 ): 1054 - 1057 .

SONG N , YANG T , SUN H . Overlapped subarray based hybrid beamforming formillimeter wavemultiusermassive MIMO [J ] . IEEE Signal Processing Letters , 2017 , 24 ( 5 ): 550 - 554 .

BRADY J , BEHDAD N , SAYEED A M . Beamspace MIMO formillimeter-wave communications:system architecture,modeling,analysis,andmeasurements [J ] . IEEE Transactions on Antennas and Propagation , 2013 , 61 ( 7 ): 3814 - 3827 .

SAYEED A , BRADY J . Beamspace MIMO for high-dimensionalmultiuser communication atmillimeter-wave frequencies [C ] // 2013 IEEE Global Communications Conference(GLOBECOM),Dec 9-13,2013,Atlanta,GA,USA . Piscataway:IEEE Press , 2013 : 3679 - 3684 .

ZHU X , WANG Z , DAI L , et al . Adaptive hybrid precoding formultiusermassive MIMO [J ] . IEEE Communications Letters , 2016 , 20 ( 4 ): 776 - 779 .

SOHRABI F , YU W . Hybrid analog and digital beamforming formmWave OFDM large-s cale antenna arrays [J ] . IEEE Journal on Selected Areas in Communications , 2017 , 35 ( 7 ): 1432 - 1443 .

BUZZI S , D’ANDREA C . Energy efficiency and asymptotic performance evaluation of beamforming structures in doublymassive MIMOmmWave systems [J ] . IEEE Transactions on Green Communications and Networking , 2018 , 2 ( 2 ): 385 - 396 .

NGUYEN D H N , LE L B , LE-NGOC T , et al . Hybrid MMSE precoding and combining designs for mmWavemultiuser systems [J ] . IEEE Access , 2017 ( 5 ): 19167 - 19181 .

AYACH O E , RAJAGOPAL S , ABU-SURRA S , et al . Spatially sparse precoding inmillimeter wave MIMO systems [J ] . IEEE Transactions on Wireless Communications , 2014 , 13 ( 3 ): 1499 - 1513 .

LIANG L , XU W , DONG X . Low-complexity hybrid precoding inmassivemultiuser MIMO systems [J ] . IEEE Wireless Communications Letters , 2014 , 3 ( 6 ): 653 - 656 .

SUN W , YUE Q , MENG W , et al . Transmissionmechanism and performance analysis ofmultiuser opportunistic beamforming in Rayleigh and Rician fading channels [J ] . IEEE Transactions on VehiculaRtechnology,(has been accepted) .

SADR S , ADVE R S . Partially-distributed resource allocation in small-cell networks [J ] . IEEE Transactions on Wireless Communications , 2014 , 13 ( 12 ): 6851 - 6862 .

ANDREWS J G , BACCELLI F , GANTI R K . A tractable approach to coverage and rate in cellular networks [J ] . IEEE Transactions on Communications , 2011 , 59 ( 11 ): 3122 - 3134 .

SOKUN H U , BEDEER E , GOHARY R H , et al . Optimization of discrete power and resource block allocation for achievingmaximum energy efficiency in OFDMA networks [J ] . IEEE Access , 2017 ( 5 ): 8648 - 8658 .

HU B , WANG Y , WANG C . Amaximum data transmission rate oriented dynamic APs grouping scheme in user-centric UDN [C ] // 2017 International Symposium on Intelligent Signal Processing and Communication Systems(ISPACS),Sept 25-26,2017,Jeju Island,South Korea . Piscataway:IEEE Press , 2017 : 56 - 61 .

BOLJEVIC S , . Cost of optimal placement of a CHP plant within existing UDN [C ] // 201714th International Conference on the European EnergyMarket(EEM),June 6-9,2017,Dresden,Germany.[S.l.:s.n . ] , 2017 : 1 - 6 .

TAO Y , LIU L , LIU S , et al . A survey:several technologies of non-orthogonal transmission for 5G [J ] . China Communications , 2015 , 121 ( 10 ): 1 - 15 .

胡显安 . 5G新型非正交多址技术研究 [D ] . 北京:北京交通大学 , 2017 .

HU X A . Research on 5G new non orthogonalmultiple access technology [D ] . Beijing:Beijing Jiaotong University , 2017 .

HONG S , BRAND J , CHOI J I , et al . Applications of self-interference cancellation in 5G and beyond [J ] . IEEE CommunicationsMagazine , 2014 , 52 ( 2 ): 114 - 121 .

张德坤 . 非正交多址系统功率分配及干扰消除算法研究 [D ] . 哈尔滨:哈尔滨工业大学 , 2015 .

ZHANG D K . Algorithm of power allocation and interference cancellation for non-orthogonalmultiple access systems [D ] . Harbin:Harbin Institute of Technology , 2015 .

NIKOPOUR H , BALIGH H . Sparse codemultiple access [C ] // 2013 IEEE 24th International Symposium on Personal Indoor and Mobile Radio Communications(PIMRC),Sept 8-11,2013,London,UK . Piscataway:IEEE Press , 2013 : 332 - 336 .

FORNEY G D , WEI L F . Multidimensional constellations.Part.I:introduction,figures ofmerit,and generalized cross constellations [J ] . IEEE Journal on Selected Areas in Communications , 1989 , 7 ( 6 ): 877 - 892 .

FORNEY G D . Multidimensional constellations.Part.II:voronio constellations [J ] . IEEE Journal on Selected Areas in Communications , 1989 , 7 ( 6 ): 941 - 958 .

BAYESTEH A , NIKOPOUR H , TAHERZADEH M , et al . Low complexity techniques for SCMA detection [C ] // 2015 IEEE GLOBECOM Workshops(GC Wkshps),Dec 6-10,2015,San Diego,CA,USA . Piscataway:IEEE Press , 2015 : 1 - 6 .

TAHERZADEH M , NIKOPOUR H , BAYESTEH A , et al . SCMA for downlinkmultiple access of 5G wireless networks [C ] // 2014 IEEE Global Communications Conference(GlobeCom),Dec 8-12,2014,Austin,TX,USA . Piscataway:IEEE Press , 2014 : 3940 - 3945 .

AU K , ZHANG L , NIKOPOUR H , et al . Uplink contention based SCMA for 5G radio access [C ] // 2014 GlobeCom Workshops(GC Wkshps),Dec 8-12,2014,Austin,TX,USA . Piscataway:IEEE Press , 2014 : 900 - 905 .

浏览量

下载量

CSCD

文章被引用时，请邮件提醒。

提交

工具集

关联资源

5G超密集组网网络架构及实现

HSM：支持6G密集部署和高速移动性场景的新型网络架构

面向垂直行业专网的确定性SLA指标分级研究

5G多路冗余传输技术综述

星地融合下的手机直连关键技术研究