何睿斯

博士、教授、国家优青,副所长

基本信息

办公电话: 电子邮件: ruisi.he@bjtu.edu.cn
通讯地址:北京交通大学思源楼813室 邮编:100044

教育背景

何睿斯,北京交通大学教授、博导,电子信息工程学院现代通信研究所副所长,国家优秀青年科学基金获得者。曾赴美国佐治亚理工学院、美国南加州大学、比利时鲁汶大学、西班牙马德里理工大学开展访问研究。主要研究方向包括无线信道测量与建模、5G/6G通信、智能环境感知与数字孪生技术等。曾获国际无线电科学联盟古贺逸策金牌奖章(URSI Issac Koga Gold Medal)、IEEE通信学会亚太杰出青年学者奖、北京市高校优秀共产党员、电子学会优秀博士学位论文、北京交通大学五四奖章等,研究成果获北京市自然科学二等奖、电子学会自然科学一等奖、教育部自然科学二等奖等。入选全球顶尖科学家榜单、爱思唯尔中国高被引学者榜单、中国科协青年人才托举工程等。担任IEEE Transactions on Wireless Communications、IEEE Transactions on Communications、IEEE Transactions on Antennas and Propagation等期刊编委,担任IEEE JSAC期刊首席客座编委。担任国际无线电科学联盟首届青年职业代表(ECR)、国际无线电科学联盟中国青年科学家委员会主席、中国科协联合国咨商信息与通讯技术专业委员会委员等。

工作经历

My website in English: https://sites.google.com/view/ruisihe/home
个人部分研究介绍可参看英文网站

本人隶属于北京交通大学全国重点实验室&电子信息工程学院现代通信研究所大团队,重点从事无线通信物理层关键技术研究,主要研究方向包括:
1. 无线电波传播、无线信道测量与建模
2. 人工智能与通信融合应用
3. 智能环境感知与数字孪生
4. 5G/6G通信,物联网,轨道交通专用通信


依托全国重点实验室、国家“2011协同创新中心”、国家铁路局铁路行业重点实验室等平台,科研经费充足,国际交流机会多;与华为、中兴、诺基亚、国铁集团等企业保持密切合作,强调科研理论的深度和高度,注重对研究生实践及动手能力的培养。欢迎报考。


本人有较长的国外访问研究经历,与美国佐治亚理工学院著名无线通信专家Gordon L. Stüber教授、美国南加州大学著名无线通信专家Andreas Molisch教授、比利时鲁汶大学著名MIMO技术专家Claude Oestges教授、以及英国、丹麦、瑞典、芬兰等大学知名教授保持密切合作关系,有机会推荐研究生至国外高校访问,非常适合希望出国深造、访问的同学。也欢迎有意出国深造的本科生邮件联系我(请提供简历及本科成绩单),愿助你一臂之力。


招生原则:踏实、有责任心、肯钻研。
现招收5G/6G移动通信、人工智能及无线大数据、物联网、RIS及毫米波等领域的博士生、硕士生若干名,可提供国际联合培养机会!


2024年招生已开启,博士1-2人,硕士3-4人。当前还有若干考研名额,欢迎联系!

致詹天佑22级直博生:本人3月份日程较满,预计4月份组织面谈,欢迎联系!

课题组2019版情况介绍PPT:课题组介绍



研究方向

  • 宽带移动通信系统与专用移动通信
  • 通信工程
  • 人工智能
  • 新一代电子信息技术

团队成员

博士研究生
孙桂琪,面向6G的RIS通信
米   航,6G毫米波通信
刘昌柱,6G深度覆盖扩展技术
张正宇,6G感知通信一体化
汪琛龙,6G AI智能信道建模  
元   媛,6G超大规模MIMO与RIS
邱志成,基于深度学习的信道预测
戚子羿,复杂电磁环境重构
张雪剑,基于视觉的环境感知与电波预测
王世睿,智能信道建模与仿真


硕士研究生
袁冰冰,6G高精度定位技术
刘春雨,环境感知与智慧物联技术
张语昕,AI无线信道数字孪生 
何泽乾,毫米波通信
金云伟,通感一体化
苏   心,THz与RIS融合通信
李卓音,智能信道仿真
郭珂莹,电磁环境数字孪生
宋浚哲,通感一体化
张   众,智能环境重构


Alumni:
成   晶 (2023年毕业),博士,高可靠低时延通信;毕业去向:大唐移动
尚辉超 (2023年毕业),硕士,铁路物联网OTFS;毕业去向:中国星网研究院
杨齐萍 (2023年毕业),硕士,RIS辅助通信的信道及系统性能;毕业去向:华科读博
马张枫 (2022年毕业),博士,6G无人机通信;毕业去向:邵阳学院高聘副教授
赵威程 (2022年毕业),硕士,新型车联网高精度定位技术;毕业去向:HONOR荣耀
杨   汨 (2021年毕业),博士,LTE-Vehicle通信技术;毕业去向:北京交通大学留校任教
黄   晨 (2021年毕业),博士,基于人工智能的通信信号处理及预测;毕业去向:南京紫金山实验室
温子睿 (2021年毕业),硕士,5G-R信道测量及AI驱动的建模技术;毕业去向:中国移动研究院
李天时 (2021年毕业),硕士,5G空天地一体化通信技术;毕业去向:中电科五十四研究所
郑青碧 (2020年毕业),硕士,基于AI的通信场景识别与信号聚类分析;毕业去向:中国移动研究院
李健之 (2019年毕业),博士,5G三维Massive MIMO技术;毕业去向:大唐创新研究中心
李   岩 (2018年毕业),博士,D2D/V2V信道建模与仿真;毕业去向:中国移动研究院
王   琦 (2018年毕业),博士,非平稳信道建模及系统性能分析;毕业去向:中国信息通信研究院
张   北 (2018年毕业),博士,面向LTE-R的下一代铁路通信技术;毕业去向:英特尔研究院(北京)

招生专业

  • 信息与通信工程硕士
  • 通信工程(含宽带网络、移动通信等)硕士
  • 信息与通信工程博士
  • 通信工程(含宽带网络、移动通信等)博士
  • 人工智能硕士
  • 新一代电子信息技术(含量子技术等)硕士
  • 新一代电子信息技术(含量子技术等)博士

科研项目

  • 北京交通大学: 超分辨确定性信道建模和电磁环境反演, 2023-2024
  • 北京交通大学: 基于5G无源物联网技术的智能车站定位应用技术服务, 2023-2023
  • 红果园国家级“科技委”: 面向无人机城市作战场景的电磁环境及信道一体化模拟技术, 2022-2024
  • 北京交通大学: 智能仓场景外场信道测量, 2023-2025
  • 铁路总公司(原铁道部): 铁路 5G-R 系统安全管控关键技术研究, 2022-2024
  • 国家重点研发计划-任务: 农田传感器低功耗轻便型的专用通信组网设备研发, 2023-2025
  • 国家自然科学基金“创新群体”: 轨道交通信息高效可靠传输, 2023-2027
  • 国家自然科学基金“面上”: 面向高速铁路下一代通信的智能电波覆盖与感知理论研究, 2023-2026
  • 红果园国家级"四总部": 无线通信场景模拟与验证平台信道建模分系统研制, 2022-2025
  • 铁路总公司(原铁道部): 东郊环行铁道5G专用移动通信系统技术试验, 2021-2024
  • 铁路总公司(原铁道部): 铁路5G专网标准体系架构与关键应用技术研究-课题1铁路5G专网标准体系架构及技术标准研究, 2021-2023
  • 铁路总公司(原铁道部): 铁路5G专网标准体系架构与关键应用技术研究-课题2适应5G专网条件的列控系统关键技术和试验方案研究-5G-R承载列控总体方案及标准研究, 2021-2023
  • 高可靠车路云通信技术
  • 国家重点实验室: 5G/5G-R NR基站试验系统, 2022-2022
  • 国家重点实验室: 矢量信号发生器, 2022-2022
  • 国家重点实验室: 高速铁路智能电波覆盖与感知理论研究, 2022-2024
  • 北京交通大学: 面向通信感知一体化的无线信道统计建模方法与实测模型, 2021-2023
  • 北京交通大学: 铁路客运车站安检智联网技术与平台系统测试, 2021-2022
  • 国家铁路局课题计划: 铁路新一代移动通信5G标准体系研究, 2021-2023
  • 铁路总公司(原铁道部): 基于2100MHz频率的铁路5G专网技术体系及关键技术研究-课题1, 2021-2022
  • 北京交通大学: 中国神华重载铁路宽带移动通信体系研究, 2021-2022
  • 国家重点实验室: LTE-R/5G云化接入和移动管理功能单元, 2021-2022
  • 国家重点实验室: LTE-R MC应用单元, 2021-2022
  • 国家重点实验室: LTE-R/5G SIP Core单元, 2021-2022
  • 国家重点实验室: LTE-R/5G云化分组数据网关, 2021-2022
  • 国家重点实验室: LTE-R/5G云化服务网关, 2021-2022
  • 国家重点实验室: LTE-R/5G云化归属用户服务器, 2021-2022
  • 国家重点实验室: LTE-R/5G/5G-R基站测试仪, 2021-2022
  • 国家重点研发计划-课题: 异构多网融合覆盖扩展技术, 2020-2023
  • 国家自然科学基金“专项基金项目”: 面向未来高速铁路主要技术领域发展趋势及关键问题研究, 2020-2020
  • 国家重点实验室: LTE-R云化策略与计费规则功能单元(PCRF), 2020-2021
  • 国家重点实验室: LTE-R云化多播网关(MBMS-GW), 2020-2021
  • 国家重点实验室: LTE-R云化多小区多播协调实体(MCE), 2020-2021
  • 国家重点实验室: LTE-R云化广播业务中心(eBM-SC), 2020-2021
  • 面向智慧高铁场景与业务的全链接高可信专用无线通信理论与方法
  • 国家重点实验室: 面向智慧铁路的高频多维非平稳信道参数估计与建模方法, 2020-2021
  • 国家重点实验室: 面向智能轨道交通场景与业务的6G技术, 2020-2021
  • 国家自然科学基金"优秀青年基金: 高速移动场景信道测量与建模理论, 2020-2022
  • 国家重点实验室: 面向智慧高速铁路的移动通信理论与关键技术, 2019-2021
  • 铁路总公司(原铁道部): 铁路下一代移动通信技术发展规划研究, 2018-2020
  • 铁路总公司(原铁道部): 铁路5G移动通信应用技术研究, 2018-2020
  • 面向车联网通信特殊场景的信道建模研究
  • 其他部市(2020.10起仅限省部级科技计划\基金\专项): 中国科协青年人才托举工程, 2018-2021
  • 北京交通大学: LTE-R高速场景下承载技术及GL混合组网研究, 2018-2020
  • 国家重点研发计划: MIMO空间角度谱测量理论方法研究, 2018-2020
  • 北京市科委: 高速移动场景下高可靠传输与移动性资源管理技术研究, 2018-2019
  • 国家重点实验室: 基于机器学习的高速铁路时变非平稳信道多径跟踪与分簇算法研究, 2018-2020
  • 北京市自然基金“面上”: 城市轨道交通车站热点场景毫米波大规模多天信道建模研究, 2018-2020
  • 基于机器学习理论的无线信道参数分析方法研究
  • 国家自然科学基金“面上”: 面向车-车通信智能感知的毫米波极化多天线信道建模理论研究, 2018-2021
  • 北京交通大学: 无线信道多径自动归簇算法设计, 2016-2018
  • 国家重点研发计划: 天临空地车专用网络安全保障技术, 2016-2020
  • 北京交通大学: LTE-V车载天线及信道特征研究, 2016-2019
  • 北京交通大学: 面向轨道交通专网的5G需求及网络架构研究, 2016-2018
  • 铁路总公司(原铁道部): 铁路通信网运维综合管理数据平台关键技术研究, 2016-2019
  • 国家重点实验室: 多径分簇算法研究, 2016-2017
  • 轨道交通智慧感知与信息处理基础理论研究
  • 国家重点实验室: 第五代移动通信系统原型设计平台-数字信号处理卡, 2016-2016
  • 国家重点实验室: 多通道无线信道探测仪器, 2016-2016
  • 国家重点实验室: 第五代移动通信系统原型设计平台-宽带信号接收器, 2016-2016
  • 北京交通大学: 5G关键技术(续), 2016-2019
  • 基于非平稳相关散射特性的车对车信道建模
  • 国家重点实验室: 面向高速铁路车-地无线通信的传播信道建模研究, 2016-2018
  • 北京交通大学: 高速铁路LTE-R系统信道特性分析与建模技术研究, 2015-2022
  • 北京市科委: 高速铁路移动通信无线信道测试仪研发, 2015-2016
  • 国家重点实验室: 城轨路网运营安全保障实验模拟平台, 2015-2017
  • 国家重点实验室: 下一代列控系统的车地通信系统仿真、分析与测试(2), 2015-2017
  • 国家重点实验室: 虚拟天线转台, 2015-2017
  • 国家重点实验室: 下一代列控系统的车地通信系统仿真、分析与测试, 2015-2017
  • 铁路总公司(原铁道部): LTE-R频率适应性研究和测试 , 2015-2016
  • 北京市科委: 5G大规模虚拟天线阵列无线信道建模研究, 2015-2016
  • 国家自然科学基金"青年基金": 车-车通信时变信道多径动态簇建模研究, 2016-2018
  • 轨道交通列车控制系统信息安全测试平台研究
  • 北京交通大学: 3GPP RAN4 LTE高速性能评估, 2015-2019
  • 其他部市(2020.10起仅限省部级科技计划\基金\专项): 无线传播信道多径分簇研究, 2015-2016
  • 车对车信道非平稳特性研究与建模
  • 国家重点实验室: 轨道交通通信网络多天线信道建模理论与方法研究, 2015-2018
  • 国家重点实验室: 高速铁路复杂场景宽带信道建模, 2015-2016
  • 高速铁路无线信道传播理论研究

教学工作

本科生课程:
1. 第五代通信技术概论
2. 移动通信技术及应用 
3. 工程经济与项目管理

研究生课程:
1. 数字通信理论
2. 无线信道理论与建模方法
3. 通信新技术与选题
4. 英文学术论文写作方法与技巧
5. 论文写作与学术规范

论文/期刊

发表学术论文>200篇(含SCI论文>100篇),详见个人Google Scholar主页。部分代表性英文论文如下:  

Selected Publications (Updated: 2019-05)

Journal Publications:

  • J. Li, B. Ai, R. He, M. Yang, Z. Zhong, and Y. Hao, “A cluster-based channel model for massive MIMO communications in indoor hotspot scenarios”, IEEE Transactions on Wireless Communications, to appear
  • J. Li, B. Ai, R. He, M. Yang, Z. Zhong, Y. Hao, and G. Shi, “On 3D cluster-based channel modeling for large-scale array communications,” IEEE Transactions on Wireless Communications, to appear
  • W. Zhao, G. Wang, S. U. B. Atapattu, R. He, and Y.-C. Liang, “Channel Estimation for Ambient Backscatter Communication Systems with Massive-Antenna Reader,” IEEE Transactions on Vehicular Technology, to appear
  • M. Yang, B. Ai, R. He, L. Chen, X. Li, J. Li, B. Zhang, C. Huang, and Z. Zhong, “A cluster-based three-dimensional channel model for vehicle-to-vehicle communications,” IEEE Transactions on Vehicular Technology, vol. 68, no. 6, pp. 5208-5220, 2019.
  • Y. Miao, W. Fan, J. Takada, R. He, X. Yin, M. Yang, J. R.-Pineiro, A. A. Glazunov, W. Wang, and Y. Gong, “Comparing channel emulation algorithms by using plane waves and spherical vector waves in multiprobe anechoic chamber setups,” IEEE Transactions on Antennas and Propagation, vol. 67, no. 6, pp. 4091-4103, 2019.
  • B. Zhang, Z. Zhong, R. He, G. Dahman, J. Ding, S. Lin, B. Ai, and M. Yang, “A measurement based wideband multi-link model for railway channels,” IEEE Transactions on Intelligent Transportation Systems, vol. 20, no. 3, pp. 985-999, 2019.
  • C. Huang, R. He, Z. Zhong, B. Ai, Y. Geng, Z. Zhong, Q. Li, K. Haneda, and C. Oestges, “A power-angle-spectrum based clustering and tracking algorithm for time-varying radio channels,” IEEE Transactions on Vehicular Technology, vol. 68, no. 1, pp. 291-305, 2019.
  • Y. Chen, B. Ai, Y. Niu, R. He, Z. Zhong, and Z. Han, “Resource allocation for device-to-device communications in multi-cell multi-band heterogeneous cellular networks,” IEEE Transactions on Vehicular Technology, vol. 68, no. 5, pp. 4760-4773, 2019.
  • J. Li, B. Ai, R. He, M. Yang, and Z. Zhong, “On modeling of dense multipath component for indoor massive MIMO channels”, IEEE Antennas and Wireless Propagation Letters, vol. 18, no. 3, pp. 526-530, 2019.
  • C. Zhang, G. Wang, M. Jia, R. He, L. Zhou, and B. Ai, “Doppler shift estimation for millimeter-wave communication systems on high-speed railways,” IEEE ACCESS, vol. 7, pp. 40454-40462, 2019.
  • R. He, B. Ai, A. F. Molisch, G. L. Stüber, Q. Li, Z. Zhong, and J. Yu, “Clustering enabled wireless channel modeling using big data algorithms,” IEEE Communications Magazine, vol. 56, no. 5, pp. 177-183, 2018.
  • R. He, B. Ai, G. L. Stüber, and Z. Zhong, “Mobility model-based non-stationary mobile-to-mobile channel modeling,” IEEE Transactions on Wireless Communications, vol. 17, no. 7, pp. 4388-4400, 2018.
  • R. He, B. Ai, G. L. Stuber, G. Wang, and Z. Zhong, “Geometrical based modeling for millimeter wave MIMO mobile-to-mobile channels,” IEEE Transactions on Vehicular Technology, vol. 67, no. 4, pp. 2848-2863, 2018.
  • R. He, B. Ai, G. L. Stüber, and Z. Zhong, “Geometrical-based statistical modeling for polarized MIMO mobile-to-mobile channels,” IEEE Transactions on Antennas and Propagation, vol. 66, no. 8, pp. 4213-4227, 2018.
  • J. Li, B. Ai, R. He, M. Yang, Q. Wang, B. Zhang, and Z. Zhong, “Cluster-based 3-D channel modeling for massive MIMO in subway station environment,” IEEE ACCESS, vol.6, pp. 6257-6272, 2018.
  • Y. Geng, Q. Li, R. Zheng, F. Zhuang, R. He, and N. Xiong, “RECOME: a new density-based clustering algorithm using relative KNN kernel density,” Information Sciences, vol. 436-437, pp. 13-30, 2018.
  • R. He, Q. Li, B. Ai, Y. Geng, A. F. Molisch, V. Kristem, Z. Zhong, and J. Yu, “A Kernel-power-density based algorithm for channel multipath components clustering,” IEEE Transactions on Wireless Communications, vol. 16, no. 11, pp. 7138-7151, 2017.
  • B. Ai, K. Guan, R. He, J. Li, G. Li, D. He, Z. Zhong, and K. M. S. Huq, “On indoor millimeter wave massive MIMO channels: measurement and simulation,” IEEE Journal on Selected Areas in Communications, vol. 35, no. 7, pp. 1678-1690, 2017.
  • C. Huang, R. He, Z. Zhong, Y. Geng, Q. Li, and Z. Zhong, “A novel tracking based multipath component clustering algorithm”, IEEE Antennas and Wireless Propagation Letters, vol. 16, no. 1, pp. 2679-2683, 2017.
  • Y. Li, R. He, S. Lin, K. Guan, D. He, Q. Wang, and Z. Zhong, “Cluster-based non-stationary channel modeling for vehicle-to-vehicle communications,” IEEE Antennas and Wireless Propagation Letters, vol. 16, pp. 408-411, 2017.
  • B. Zhang, Z. Zhong, R. He, F. Tufvesson, and B. Ai, “Measurement-based multiple-scattering model of small-scale fading in high-speed railway cutting scenarios,” IEEE Antennas and Wireless Propagation Letters, vol. 16, pp. 1427-1430, 2017.
  • Q. Wang, B. Ai, R. He, K. Guan, Y. Li, Z. Zhong, and G. Shi, “A framework of automatic clustering and tracking for time-variant multipath components,” IEEE Communications Letters, vol. 21, no. 4, pp. 953-956, 2017.
  • B. Zhang, Z. Zhong, R. He, B. Ai, G. Dahman, M. Yang, and J. Li, “Multi-user channels with large-scale antenna arrays in a subway environment: characterization and modeling,” IEEE Access, vol. 5, no. 1, pp. 23613-23625, 2017.
  • Q. Wang, B. Ai, D. W. Matolak, R. He, K. Guan, Z. Zhong, and D. Li, “Spatial variation analysis for measured indoor massive MIMO channels,” IEEE Access, vol. 5, no. 1, pp. 20828-20840, 2017.
  • X. Zhou, Z. Zhong, X. Bian, R. He, R. Sun, K. Guan, and K. Liu, “Indoor wideband channel measurements and analysis at 11 and 14 GHz,” IET Microwaves, Antennas & Propagation, vol. 11, no. 10, pp. 1393-1400, 2017.
  • R. He, W. Chen, B. Ai, A. F. Molisch, W. Wang, Z. Zhong, J. Yu, and S. Sangodoyin, “On the clustering of radio channel impulse responses using sparsity-based methods,” IEEE Transactions on Antennas and Propagation, vol. 64, no. 6, pp. 2465-2474, 2016.
  • R. He, O. Renaudin, V.-M. Kolmonen, K. Haneda, Z. Zhong, B. Ai, and C. Oestges, “Characterization of quasi-stationarity regions for vehicle-to-vehicle radio channels,” IEEE Transactions on Antennas and Propagation, vol. 63, no. 5, pp. 2237-2251, 2015. 
  • R. He, Z. Zhong, B. Ai, and K. Guan, “Reducing cost of the high-speed railway communications: from propagation channel view,” IEEE Transactions on Intelligent Transportation Systems, vol.16, no. 4, pp. 2050-2060, 2015. 
  • R. He, Z. Zhong, B. Ai, and C. Oestges, “Shadow fading correlation in high-speed railway environments,” IEEE Transactions on Vehicular Technology, vol. 64, no. 7, pp. 2762-2772, 2015.
  • M. Hu, Z. Zhong, M. Ni, and R. He, "Analysis of link lifetime with auto-correlated shadowing in high-speed railway networks," IEEE Communication Letters, vol. 19, no. 12, pp. 2106-2109, 2015.
  • T. Wang, B. Ai, R. He, and Z. Zhong, "Two-dimension direction-of-arrival estimation for massive MIMO systems," IEEE Access, vol. 3, pp. 2122-2128, 2015.
  • X. Zhou, Z. Zhong, B. Zhang, R. He, K. Guan, Q. Wang, and D. Matolak, "Experimental characterization and correlation analysis of indoor channels at 15 GHz," International Journal of Antennas and Propagation, vol. 2015, pp. 1-11, 2015.   
  • R. He, A. F. Molisch, F. Tufvesson, Z. Zhong, B. Ai, and T. Zhang, “Vehicle-to-vehicle propagation models with large vehicle obstructions,” IEEE Transactions on Intelligent Transportation Systems, vol. 15, no. 5, pp. 2237-2248, 2014. 
  • B. Ai, X. Cheng, T. Kürner, Z. Zhong, K. Guan, R. He, L. Xiong, D. Matolak, D. G. Michelson, and C. Briso, “Challenges toward wireless communications for high-speed railway,” IEEE Transactions on Intelligent Transportation Systems, vol. 15, no. 5, pp. 2143-2158, 2014.
  • R. He, Z. Zhong, B. Ai, K. Guan, B. Chen, J. I. Aionso, and C. Briso, “Propagation channel measurements and analysis at 2.4 GHz in subway tunnels,” IET Microwaves, Antennas & Propagation, vol. 7, no. 11, pp. 934-941, 2013.
  • R. He, Z. Zhong, B. Ai, K. Guan, and R. Chen, “Simplified analytical propagation model for railway environments based on uniform theory of diffraction,” Electronics Lettersvol. 49, no. 6, pp. 397-399, 2013.
  • R. He, Z. Zhong, B. Ai, J. Ding, Y. Yang, and A. F. Molisch, “Short-term fading behavior in high-speed railway cutting scenario: measurements, analysis, and statistical models,” IEEE Transactions on Antennas and Propagation, vol. 61, no. 4, pp. 2209-2222, 2013.
  • R. He, Z. Zhong, B. Ai, G. Wang, J. Ding, and A. F. Molisch, “Measurements and analysis of propagation channels in high-speed railway viaducts,” IEEE Transactions on Wireless Communications, vol. 12, no. 2, pp. 794-805, 2013.
  • R. He, Z. Zhong, B. Ai, and J. Ding, “An empirical path loss model and fading analysis for high-speed railway viaduct scenarios, IEEE Antennas and Wireless Propagation Lettersvol. 10, pp. 808-812, 2011.
  • R. He, Z. Zhong, B. Ai, and J. Ding, “Propagation measurements and analysis for high-speed railway cutting scenario,” Electronics Lettersvol. 47, no. 21, pp. 1167-1168, Oct. 2011.

Conference Publications:

  • Z. Ma, B. Ai, R. He, and Z. Zhong, “A 3D air-to-air wideband non-stationary channel model of UAV communications,” in Proc. IEEE VTC-Fall, 2019, accepted.
  • M. Yang, B. Ai, R. He, L. Chen, X. Li, J. Li, Z. Ma, and Z. Zhong, “Directional analysis of vehicle-to-vehicle channels with large vehicle obstructions,” in Proc. IEEE VTC-Fall, 2019, accepted.
  • C. Huang, A. F. Molisch, R. Wang, P. Tang, R. He, and Z. Zhong, “Angular information-based NLOS/LOS identification for vehicle to vehicle MIMO system,” in Proc. IEEE ICC workshop, 2019, accepted.
  • C. Huang, A. F. Molisch, R. Wang, P. Tang, R. He, and Z. Zhong, “Research on Kernel functions of SVM for NLOS/LOS identification in vehicle to vehicle MIMO system,” in Proc. IEEE APS, 2019, accepted.
  • W. Lyu, Y. Li, Z. Liu, C. Huang, and R. He, “A target recognition based NLOS identification algorithm,” in Proc. IEEE APS, 2019, accepted.
  • S. Ma, Y. Zhu, G. Wang, and R. He, “Machine learning aided channel estimation for ambient backscatter communication systems,” in Proc. IEEE ICCS, 2018, accepted.
  • Q. Wang, B. Ai, R. He, M. Yang, B. Zhang, J. Li, L. Chen, and X. Li, “Time-variant cluster-based channel modeling for V2V communications,” in Proc. IEEE ICC, 2018.
  • J. Li, B. Ai, R. He, M. Yang, Y. Zhang, X. Liu, Z. Zhong, and Y. Hao, “Directional analysis of massive MIMO channels at 11 GHz in theater environment,” in Proc. IEEE VTC-Fall, 2018.
  • J. Li, B. Ai, R. He, M. Yang, Q. Wang, B. Zhang, Z. Zhong, and Y. Hao, “Channel characterization for massive MIMO in subway station environment at 6 GHz and 11 GHz,” in Proc. IEEE VTC-Fall, 2018.
  • C. Huang, R. He, Z. Zhong, B. Ai, G. Wang, Z. Zhong, C. Oestges, and K. Haneda, “A Novel Target Recognition Based Radio Channel Clustering Algorithm,” in Proc. WCSP, 2018.
  • J. Li, B. Ai, R. He, M. Yang, Z. Zhong, Y. Hao, and G. Shi, “The 3D spatial non-stationarity and spherical wavefront in massive MIMO channel measurement,” in Proc. WCSP, 2018.
  • M. Yang, B. Ai, R. He, L. Chen, X. Li, Z. Huang, J. Li, and C. Huang, “Path loss analysis and modeling for vehicle-to-vehicle communications with vehicle obstructions,” in Proc. WCSP, 2018.
  • J. Li, B. Ai, R. He, M. Yang, Z. Zhong, and Y. Hao, “Measurement-Based Massive MIMO Channel Characterization in Lobby Environment at 11 GHz,” in Proc. IEEE/CIC ICCC, 2018.
  • M. Yang, B. Ai, R. He, L. Chen, X. Li, J. Li, Q. Wang, B. Zhang, and C. Huang, “A Cluster-Based 3D Channel Model for Vehicle-to-Vehicle Communications,” in Proc. IEEE/CIC ICCC, 2018.
  • C. Zhang, G. Wang, R. He, and Y. Zou, “A Doppler Shift Estimator for Millimeter-Wave Communication Systems on High-Speed Railways,” in Proc. IEEE/CIC ICCC, 2018.
  • Q. Zheng, R. He, and C. Huang, “A tracking-based multipath components clustering algorithm,” in Proc. URSI AT-RASC, 2018.
  • M. Yang, B. Ai, R. He, C. Huang, J. Li, L. Chen, X. Li, “Influence of different antenna locations on channel characterization for V2V communications,” in Proc. IEEE APS, 2018.
  • C. Huang, R. He, Z. Zhong, and Z. Zhong, “Analysis of edge detection for the clusters in radio propagation channel,” in Proc. IEEE APS, 2018.
  • Q. Wang, B. Ai, R. He, J. Li, B. Zhang, M. Yang, and Z. Zhong, “Measurement-based massive MIMO channel characterization in subway station,” in Proc. EuCAP, 2018.
  • R. He, Q. Li, B. Ai, Y. Geng, A. F. Molisch, V. Kristem, Z. Zhong, and J. Yu, “An automatic clustering algorithm for multipath components based on Kernel-power-density,” in Proc. IEEE WCNC, 2017.
  • R. He, B. Ai, G. L. Stüber, G. Wang, and Z. Zhong, “A cluster based geometrical model for millimeter wave mobile-to-mobile channels,” in Proc. IEEE/CIC ICCC, 2017.
  • R. He, B. Ai, G. L. Stüber, and Z. Zhong, “Non-stationary mobile-to-mobile channel modeling using the Gauss-Markov mobility model,” in Proc. WCSP, 2017.
  • R. He, G. L. Stüber, B. Ai, and Z. Zhong, “A two-cylinder based polarized MIMO channel model,” in Proc. URSI GASS, Canada, 2017.
  • J. Li, B. Ai, R. He, Q. Wang, B. Zhang, M. Yang, K. Guan, and Z. Zhong, “Directional analysis of indoor massive MIMO channels at 6 GHz using SAGE,” in Proc. IEEE VTC-Spring, 2017.
  • B. Zhang, Z. Zhong, B. Ai, R. He, F. Tufvesson, J. Flordelis, Q. Wang, and J. Li, “Empirical evaluation of indoor multi-user MIMO channels with linear and planar large antenna arrays,” in Proc. IEEE PIMRC, 2017.
  • L. Wang, B. Ai, D. He, G. Li, K. Guan, R. He, Z. Zhong, “Channel characteristics analysis in smart warehouse scenario”, in Proc. IEEE APS, 2017.
  • X. Wang, G. Wang, R. He, and Y. Zou, “Uplink channel estimation with basis expansion model and expectation maximization for wireless communication systems on high speed railways,” in Proc. IEEE/CIC ICCC, 2017.
  • C. Huang, R. He, and Z. Zhong, “A novel power weighted multipath component tracking algorithm,” in Proc. URSI GASS, 2017.
  • J. Li, B. Ai, R. He, M. Yang, Y. Zhang, X. Liu, and Z. Zhong, “Characterization of indoor massive MIMO channel at 11 GHz,” in Proc. URSI GASS, 2017.
  • M. Yang, B. Ai, R. He, D. Yao, J. Li, B. Zhang, Q. Wang, D. Fei, and M. Ni, “Path loss characteristics for vehicle-to-infrastructure channel in urban and suburban scenarios at 5.9 GHz,” in Proc. URSI GASS, 2017.
  • Q. Wang, B. Ai, R. He, J. Li, Z. Zhong, N. Li, and H. Qin, “A research on SAGE algorithm based on massive MIMO channel measurements,” in Proc. URSI GASS, 2017.
  • R. He, A. F. Molisch, F. Tufvesson, R. Wang, T. Zhang, Z. Li, Z. Zhong, and B. Ai, “Measurement-based analysis of relaying performance for vehicle-to-vehicle communications with large vehicle obstructions,” in Proc. IEEE VTC-Fall, Canada, 2016, pp. 1-6.
  • R. He, W. Chen, B. Ai, A. F. Molisch, W. Wang, Z. Zhong, J. Yu, and S. Sangodoyin, “A sparsity-based clustering framework for radio channel impulse responses,” in Proc. IEEE VTC-Spring, Nanjing, China, May 15-18, 2016, pp. 1-5.
  • R. He, M. Yang, L. Xiong, H. Dong, K. Guan, D. He, B. Zhang, D. Fei, B. Ai, Z. Zhong, Z. Zhao, D. Miao, and H. Guan, “Channel measurements and modeling for 5G communication systems at 3.5 GHz band,” in Proc. URSI Asia-Pacific Radio Science Conference, Korea, 2016, pp. 1855-1858.
  • Q. Wang, B. Ai, R. He, K. Guan, J. Li, and D. Fei, “Parameter estimation using SAGE algorithm based on Massive MIMO channel measurements,” in Proc. IEEE APS, Puerto Rico, 2016, pp. 1457-1458.
  • J. Yang, B. Ai, K. Guan, R. He, Q. Wang, D. He, Z. Zhao, D. Miao, H. Guan, “Quasi-stationarity regions analysis for channel in composite high-speed railway scenario,” in Proc. IEEE APS, Puerto Rico, 2016, pp. 1699-1700.
  • G. Li, B. Ai, K. Guan, R. He, Z. Zhong, B. Hui, and J. Kim, “Channel characterization for mobile hotspot network in subway tunnels at 30 GHz band,” in Proc. IEEE VTC-Spring, China, 2016, pp. 1-5.
  • T. Wang, B. Ai, R. He, and Z. Zhong, “Local mean power estimation for long term evolution in railways,” in Proc. IEEE VTC-Spring, Nanjing, China, May 15-18, 2016, pp. 1-5.
  • J. Yang, B. Ai, K. Guan, D. He, R. He, B. Zhang, Z. Zhong, Z. Zhao, D. Miao, and H. Guan, “Deterministic modeling and stochastic analysis for channel in composite high-speed railway scenario,” in Proc. IEEE VTC-Spring, Nanjing, China, May 15-18, 2016, pp. 1-5.
  • J. Li, B. Ai, R. He, Q. Wang, K. Guan, D. Fei, Z. Zhong, Z. Zhao, D. Miao, and H. Guan, “Measurement-based characterizations of indoor massive MIMO channels at 2 GHz, 4 GHz, and 6 GHz frequency bands,” in Proc. IEEE VTC-Spring, Nanjing, China, May 15-18, 2016, pp. 1-5.
  • G. Li, B. Ai, K. Guan, R. He, Z. Zhong, L. Tian, and J. Dou, “Path loss modeling and fading analysis for channels with various antenna setups in tunnels at 30 GHz band,” in Proc. EuCAP, Davos, Switzerland, 10-15 April, 2016, pp. 1-5.
  • B. Zhang, Z. Zhong, X. Zhou, K. Guan, and R. He, “Path loss characteristics of indoor radio channels at 15 GHz,” in Proc. EuCAP, Davos, Switzerland, 10-15 April, 2016, pp. 1-5.
  • J. Yang, B. Ai, K. Guan, R. He, Z. Zhong, Z. Zhao, D. Miao, and H. Guan, “On the influence of mobility: Doppler spread and fading analysis in rapidly time-varying channels,” in Proc. EuCAP, Davos, Switzerland, 10-15 April, 2016, pp. 1-5.
  • R. He, J. Ding, Z. Zhong, B. Ai, and R. Chen, “Determination of percentage of linear coverage area in railways,” in Proc. URSI Atlantic Radio Science Conference, Gran Canaria, Spain, May 18-22, 2015, pp.1-1.
  • R. He, O. Renaudin, V.-M. Kolmonen, K. Haneda, Z. Zhong, B. Ai, and C. Oestges, “Statistical characterization of dynamic multi-path components for vehicle-to-vehicle radio channels,” in Proc. IEEE VTC-SpringGlasgow, United Kingdom, May 11-14, 2015, pp. 1-6.
  • R. He, O. Renaudin, V.-M. Kolmonen, K. Haneda, Z. Zhong, S. Hubert, and C. Oestges, “Angular dispersion characterization of vehicle-to-vehicle channel in cross-road scenarios,” in Proc. EuCAPLisbon, Portugal, April 13-17, 2015, pp. 1-4.
  • B. Zhang, Z. Zhong, R. He, K. Guan, J. Ding, and C. Briso, “Empirical correlation property of multi-path for high-speed railways in composite propagation scenario,” in Proc. IEEE APS, Vancouver, Canada, July 19-24, 2015, pp. 91-92.
  • R. He, A. F. Molisch, F. Tufvesson, Z. Zhong, B. Ai, and T. Zhang, “Vehicle-to-vehicle channel models with large vehicle obstructions,” in Proc. IEEE ICC, Australia, June 10-14, 2014, pp. 5647-5652.
  • R. He, Z. Zhong, B. Ai, J. Ding, W. Jiang, H. Zhang, and X. Li, “A standardized path loss model for the GSM-railway based high-speed railway communication systems,” in Proc. IEEE VTC-Spring, Seoul, South Korea, May 18-21, 2014, pp. 1-5.
  • R. He, Z. Zhong, B. Ai, and B. Zhang, “Measurement-based auto-correlation model of shadow fading for the high-speed railways in urban, suburban, and rural environments,” in Proc. IEEE APS, 2014, pp. 949-950.
  • R. He, Z. Zhong, B. Ai, and C. Oestges, “A heuristic cross-correlation model of shadow fading in high-speed railway environments,” in Proc. IEEE URSI GASS, 2014, pp. 1-4.
  • B. Zhang, Z. Zhong, B. Ai, D. Yao, and R. He, “Measurements and modeling of cross-correlation property of shadow fading in high-speed railway”, in Proc. IEEE VTC, Vancouver, Canada, Sept. 14-17, 2014, pp. 1-5.
  • B. Zhang, Z. Zhong, K. Guan, R. He, and C. Briso-Rodriguez, “Shadow fading cross-correlation of multi-frequencies in curved subway tunnels”, in Proc. IEEE ITSC, 2014, pp. 1111-1116.
  • R. He, A. F. Molisch, Z. Zhong, B. Ai, J. Ding, R. Chen, and Z. Li, “Measurement based channel modeling with directional antennas for high-speed railways,” in Proc. IEEE WCNC, China, 2013, pp. 2932-2936.
  • R. He, Z. Zhong, B. Ai, J. Ding, and Y. Yang, “Propagation measurements and analysis of fading behavior for high speed rail cutting scenarios,” in Proc. IEEE Globecom, USA, 2012, pp. 5237-5242.
  • R. He, Z. Zhong, B. Ai, and J. Ding, “Measurements and analysis of short-term fading behavior for high-speed rail viaduct scenario,” in Proc. IEEE ICC, Canada, 2012, pp. 4563-4567.
  • R. He, Z. Zhong, B. Ai, and J. Ding, “Distance-dependent model of Ricean K-factors in high-speed rail viaduct channel,” in Proc. IEEE VTC, Canada, 2012, pp. 1-5.
  • R. He, Z. Zhong, B. Ai, and J. Ding, “Measurements and analysis of the directional antenna bottom area in high speed rail,” in Proc. IEEE APS, USA, 2012, pp. 1-2.
  • R. He, Z. Zhong, and C. Briso, “Broadband channel long delay cluster measurements and analysis at 2.4 GHz in subway tunnels,” in Proc. IEEE VTC, Hungary, 2011, pp. 1-5.
  • R. He, Z. Zhong, and B. Ai, “Path loss measurements and analysis for high-speed railway viaduct scene,” in Proc. IWCMC, France, 2010, pp. 266-270.

专著/译著

部分英文著作(含章节):
1. Applications of Machine Learning in Wireless Communications, IET, 2019
2. Dedicated Mobile Communications for High-Speed Railway, Springer, 2018
3. Radio Propagation Measurements and Channel Modeling: Best Practices for Millimeter-Wave and Sub-Terahertz Frequencies, 2022 
4. IRACON Channel Measurements and Models, Inclusive Radio Communications for 5G and Beyond, Elsevier, 2021
5. Device-to-Device Channels, Wiley 5G Ref: The Essential 5G Reference Online, Wiley, 2019
6. Radio Channel Measurements and Modeling for V2V Communications, Vehicle-to-Vehicle and Vehicle-to-Infrastructure Communications - A Technical Approach,” CRC Press, 2018
7. Vehicular Communication Environments, Cooperative Radio Communications for Green Smart Environments, River Publishers Series in Communications, 2016

部分中文著作:
1. 移动场景下无线信道测量与建模:理论与应用,人民邮电出版社,2018
2. 轨道交通电波传播与无线信道建模,北京交通大学出版社,2018
3. 轨道交通5G关键技术,科学出版社,2020
4. 铁路宽带移动通信系统(LTE-R)关键技术,中国铁道出版社有限公司,2020

专利

授权中国发明专利10余项、美国发明专利1项。部分已授权专利:
1. 何睿斯,等,“一种面向高速铁路线状小区的无线通信链路估计方法”,发明专利,中国,ZL201310580797.2
2. 何睿斯,等,“面向信道冲激响应的分簇方法和装置”,发明专利,中国,ZL201510968873.6
3. 何睿斯,等,“实现毫米波信道空间一致性的仿真方法”,发明专利,中国,ZL202010818703.0
4. 何睿斯,等,“Method for clustering wireless channel MPCs based on a KPD doctrine”,发明专利,美国,US10374902B2

获奖与荣誉

Elsevier中国高被引学者
中国电子学会自然科学一等奖
中国电子学会优秀科技工作者
北京高校优秀共产党员
国际无线电科学联盟古贺逸策金牌奖章(URSI Issac Koga Gold Medal)
IEEE通信学会亚太地区杰出青年学者奖(IEEE Asia-Pacific Outstanding Young Researcher Award)
北京交通大学“卓越百人计划”入选者
2019年国家优秀青年科学基金获得者
北京交通大学五四奖章
入选第三届中国科协青年人才托举工程
中国教育部自然科学奖二等奖
中国电子学会优秀博士学位论文奖 
国际无线电科学联盟(URSI)青年科学家奖

社会兼职

Lead Guest Editor, IEEE Journal on Selected Areas in Communications, 2020
Lead Guest Editor, IEEE Transactions on Antennas and Propagation, 2021
Editor, IEEE Transactions on Communications, 2023-Present
Editor, IEEE Transactions on Wireless Communications, 2016-2022
Editor, IEEE Transactions on Antennas and Propagation, 2022-Present
Editor, IEEE Antennas and Propagation Magazine, 2019-Present
Editor, IEEE Communications Letters, 2019-Present
国际无线电科学联盟 (URSI) “无线电通信系统与信号处理委员会 (Commission C)”首届青年职业代表
IEEE Senior Member、中国电子学会高级会员、中国通信学会高级会员