通信工程系

付澍


姓名:付    

职称/职务:教授、博/硕士生导师

邮箱:shufu@cqu.edu.cn

工作单位:bat365在线平台官方网站

个人简介:

 付澍,博士,教授,博/硕导。Elsevier /斯坦福2023年全球前2%顶尖科学家年度影响力榜单学者。2016年博士毕业于电子科技大学通信抗干扰国家级重点实验室,同年进入bat365在线平台官方网站任讲师、2018年晋升副教授、2023年晋升教授。曾在2013年至2014年于天津大学计算机学院访学;2014年至2015年于加拿大滑铁卢大学博士联合培养;2019年于加拿大多伦多都市大学任短期助理研究员。

 现已发表论文60余篇、授权发明专利9件。学术论文谷歌引用2000余次,单篇最高引用900余次。近五年以一作或通讯作者在IEEE TWCTCOMTVTWCM等通信领域旗舰SCI期刊发表论文20余篇。已主持并结题国家自然科学基金青年项目一项,主持并在研国家自然科学基金面上项目一项,主持项目经费累积400余万元。长期与504所、中电54所、重庆星网等科研院所与公司保持长期合作。

 所指导的研究生曾获得校优秀硕士学位论文、国家奖学金等荣誉,且多次在通信领域SCI顶刊发表论文。团队优秀的研究生可推荐至海外知名高校和团队继续攻博,或推荐至国内知名科研院所与企业工作。2024年还有少量硕士研究生、博士研究生名额,欢迎联系报考!

社会兼职:

[1]   中国电子学会物联网青年专技组委员;

[2]   信息物理社会可信服务计算教育部重点实验室工业互联网研究所副所长;

[3]   工业互联网产业联盟泛在确定性网络实验室骨干成员;

[4]   中国通信学会会员;

[5]   重庆市产学研合作促进会成员;

[6]   国家自然科学基金通信评议专家;

[7]   重庆市科委自然科学基金评议专家;

[8]   bat365在线平台官方网站竞标评审专家。

在研项目:

[1]   国家自然科学基金委员会,面上项目,62271093,高时效无人机应急数据收集理论与机制研究,20231月至202612月,在研,主持;

[2]   重庆市科技局,重庆市自然科学基金创新发展联合基金重点项目,CSTB2023NSCQ-LZX0108,基于 5G 波束管理的多星多波束协同理论与机制研究,202311月至202410月,在研,主持;

[3]   重点实验室开放研究基金,FZ2022KF16,星基增强系统可用范围预测及定位精度、完好性提升研究,20231月至202412月,在研,主持;

[4]   国家级纵向项目,HHX23641X002,融合5G的捷变波束低轨卫星随机接入控制和资源调度方案研究,20235月至20245月,在研,主持;

[5]   国家自然科学基金委员会,区域重点项目,U21A20448,山地大城市环境的电磁传输特性与网络优化理论与方法研究,20221月至202512月,在研,参与。

结题项目:

[1]   研究所/企业横向项目,卫星互联网网络侧能力供给模块开发,20235月至202311月,结题,主持; 

[2]   重点实验室开放研究基金,2021RZJ03,无人机集群智能任务分配与自适应路由机制,20219月至20239月,结题,主持;

[3]   研究所/企业横向项目,物联网终端自组织网络组网和路由算法,202212月至20233月,结题,主持; 

[4]   研究所/企业横向项目,星间链路测控数传一体化组网系统,20221月至202212月,结题,主持;  

[5]   中华人民共和国教育部,中央高校基本科研业务费学科交叉与团队建设专项项目2021CDJQY-013,智能光无线融合多址接入技术理论与实验研究,20211月至202212月,结题,参与;

[6]   重庆市科学技术局,重庆市自然科学基金面上项目,cstc2019jcyj-msxmX0375,基于时间敏感网络的超高可靠低时延移动前传网络关键技术研究,20197月至20226月,结题,参与。 

[7]   重点实验室开放研究基金,ISN21-07,空天地一体化中的存储与计算融合技术研究,20204月至20223月,结题,主持;

[8]   中华人民共和国教育部,中央高校基本科研业务费学科交叉与团队建设专项项目2020CDJQY-A001,物联网的通信、安全、及传输一体化机制研究,20201月至202112月,结题,主持;

[9]   研究所/企业横向项目,融合低轨卫星、北斗和 5G 的电力应急通信系统关键技术研究,20211月至202112月,结题,外协;

[10]           重庆市科学技术局,重庆市技术创新与应用发展专项5G重大主题专项,cstc2019jscx-zdztzxX00235G应用驱动的边缘计算网络技术研发及应用,20199月至20218月,结题,参与;

[11]           国家自然科学基金委员会,青年科学基金项目,61701054,超密集网络中基于服务器虚拟机的多点协作技术研究,20181月至202012月,结题,主持;

[12]           国家级纵向项目,61405180409,人工智能技术行业应用研究(主题),20191月至202012月,结题,参与。  

SCI客座主编(Special Issue

[1]   “Advanced technologies and applications of 6G NTN,” Mobile Networks& Applications (Monet), 2023.CCF-C, 5-year IF = 3.3

[2]    “Advances in detection, security, and communication for UAV,” Drones, 2023.5-year IF = 5.5

[3]    “Advanced research on smart cities based on data processing and intelligent computing,” Applied Sciences, 2023.5-year IF = 2.9

[4]    “Edge computing in 6G networks,” Applied Sciences, 2023.5-year IF = 2.9

[5]    “Intelligent UAV based data collection networks,” Electronics, 2023.5-year IF = 2.9

[6]    “New technologies in space-ground integrated network,” Electronics, 2022.5-year IF = 2.9

特邀报告(Invited Speech

[1]   “Resource scheduling for NOMA-based mobile phones and IoT fusion satellite network”IEEE ICCSN202311月,中国沈阳;

[2]   “Guarantee for wireless communication security: Covert communication”IEEE ICCT202211月,中国南京;

[3]   “A substantial guarantee for wireless communication security: UAV-aided covert communication”IEEE ICCCAS20225月,新加坡;

[4]   “Collaborative multi-resource allocation in terrestrial-satellite network”IEEE ICCT202110月,中国天津;

[5]    “存储计算及通信融合,第四届先进智能与自组织网络国际研讨会,202112月,中国西安;

[6]   无人机应急数据收集的智能架构,重庆邮电大学电子信息与网络工程研究院前沿论坛,20216月,中国重庆;

[7]   面向6G的星地网络传输 第十一届中国卫星导航年会特邀报告,202011月,中国成都;

[8]   “Collaborative multi-resource allocation in terrestrial-satellite network (TSN) towards 6G”IEEE Vehicular Technology Chapter of IEEE Toronto Section20209月,加拿大多伦多;

[9]    “Dynamic power strategy space for non-cooperative power game with pricing (Invited Paper)” IEEE Vehicular Technology Conference (IEEE VTC-Fall)2017年,加拿大多伦多。

举办/协办学术会议

[1]   “11th EAI International Conference on Game Theory for Networks”, General Co-Chair, July 7-8, 2022, Chongqing, China.

[2]    “Intelligent Edge Service Towards 6G Workshops,” in Proceedings of 12th International Symposium on Parallel Architectures, Algorithms and Programming (IEEE PAAP), Workshop Chair, Dec. 10-12, 2021, Xian, China.

[3]    “Next Generation Networking Symposium,” IEEE ICCC, Co-Session Chair, Aug. 10-12, 2023, Dalian, China.

[4]   “Modern Electronic Technology and communication Systems Symposium,” IEEE ICSCC, Session Chair, Oct. 20-22, 2023, Chongqing, China.

[5]   “Vehicular Communication Symposium,” IEEE IWCMC, Session Chair, June 28-July 2, 2021, Harbin, China.

[6]   IEEE International Conference on Communications, TPC Member, 2017—2024;

[7]   IEEE Global Communications Conference, TPC Member, 2017—2024.

教学竞赛

[1]   bat365在线平台官方网站第九届青年教师教学基本功比赛,校级三等奖,2023年;

[2]   bat365在线平台官方网站第八届青年教师教学基本功比赛,校级三等奖,2021年。

研究方向及代表作:

1B5G/6G超密集蜂窝网络的协同与多址传输理论

B5G/6G超密集蜂窝网络存储、计算、传输资源智能协同机制;基于凸优化、博弈论、深度强化学习的多址干扰管理;智能反射表面(RIS)协同的非正交多址(NOMA)技术。

学术论文

[1]

“Reconfigurable   intelligent surface assisted non-orthogonal multiple access network based on   machine learning approaches,” IEEE Network, early access, pp. 1-7, 2024.(一作)  

[2]

“Energy-efficient design of STAR-RIS aided MIMO-NOMA   networks,” IEEE Transactions on Communications, vol. 71, no. 1, pp. 498-511,   2023.(通讯)

[3]

“Optimizing   age of information in RIS-assisted NOMA networks: A deep reinforcement   learning approach,” IEEE Wireless Communications Letters, vol. 11, no. 10,   pp. 2100-2104, 2022.(学生一作,导师通讯)

[4]

“Virtualization   enabled multi-point cooperation with convergence of communication, caching,   and computing”, IEEE Network, vol. 34, no. 1, pp. 94-100, 2020.(一作)

[5]

“Cooperative   computing in integrated blockchain based internet of things,” IEEE   Internet of Things Journal, vol. 7, no. 3, pp. 1603-1612, 2020.(一作)

[6]

“Joint   transmission scheduling and power allocation in non-orthogonal multiple   access,” IEEE Transactions on Communications, vol. 67, no. 11, pp.   8137-8150, 2019.(一作)

[7]

“Interference   cooperation via distributed game in 5G networks,” IEEE Internet of   Things Journal, vol. 6, no. 1, pp. 311-320, 2019.(一作)

[8]

“Power-fractionizing   mechanism: Achieving joint user scheduling and power allocation via geometric   programming,” IEEE Transactions on Vehicular Technology, vol. 67, no. 3,   pp. 2025-2034, 2018.(一作)

[9]

“Distributed   transmission scheduling and power allocation in CoMP,” IEEE Systems   Journal, vol. 12, no. 4, pp. 3096-3107, 2018.(一作)  

[10]

“Green   wireless cooperative networks,” A chapter of Green IT Engineering:   Social, Business and Industrial Applications, Springer, ISBN:   978-3-030-00252-7, 41-71, 2016.(一作)

[11]

“Energy-efficient   pre-coded coordinated multi-point transmission with pricing power game   mechanism,” IEEE Systems Journal, vol. 11, no. 2, pp. 578-587,   2017.(一作)

[12]

“Transmission   scheduling and game theoretical power allocation for interference   coordination in CoMP,” IEEE Transactions on Wireless Communications,   vol. 13, no. 1, pp. 112 -123, 2014.(一作)

2)无人机辅助的网络智能应急服务理论

基于多维时效性的无人机智能应急服务机制;基于深度强化学习的无人机协同干扰管理;多无人机协同隐蔽通信;面向无人机协同的多智能体架构设计。

代表作

[1]

“Joint Power Allocation and 3D Deployment for UAV-BSs: A game theory based deep reinforcement learning approach,” IEEE Transactions on Wireless Communications, vol. 23, no. 1, pp. 736-748, 2024.(一作)

[2]

“Minimizing the average AoI of UAV aided covert communication with a DRL framework,” submitted to Chinese Journal of Aeronautics, pp. 1-12, 2024.(一作)

[3]

“Caching placement optimization in UAV-assisted cellular networks: A deep reinforcement learning based framework,” IEEE Wireless Communications Letters, vol. 12, no. 8, pp. 1359-1363, 2023.(学生一作,导师通讯)

[4]

“Towards energy-efficient data collection by unmanned aerial vehicle base station with NOMA for emergency communications in IoT,” IEEE Transactions on Vehicular Technology, vol. 72, no. 1, pp. 1211-1223, 2023.(一作)

[5]

“Optimal hovering height and power allocation for UAV-aided NOMA covert communication system,” IEEE Wireless Communications Letters, vol. 12, no. 6, pp. 937-941, 2023.(学生一作,导师二作)

[6]

“Towards energy-efficient UAV-assisted wireless networks using an artificial intelligence approach,” IEEE Wireless Communications, vol. 29, no. 5, pp. 77-83, 2022.(一作)

[7]

“An energy efficient intelligent framework of UAV enhanced vehicular networks,” IEEE Vehicular Technology Magazine, vol. 17, no. 2, pp. 94-102, 2022.(一作)

[8]

“Energy-efficient UAV enabled data collection via wireless charging: a reinforcement learning approach,” IEEE Internet of Things Journal, vol. 8, no. 12, pp. 10209-10219, 2021.(一作)

[9]

“Joint 3D deployment and power allocation for UAV-BS: A deep reinforcement learning approach,” IEEE Wireless Communications Letters, vol. 10, no. 10, pp. 2309-2312, 2021.  (学生一作,导师通讯)

[10]

物联网数据收集中无人机路径智能规划,” 通信学报, 42(2): 124-133, 2021.(一作)

[11]

“Joint unmanned aerial vehicle (UAV) deployment and power control for internet of things networks” IEEE Transactions on Vehicular Technology, vol. 69, no. 4, pp. 4367-4378, 2020.(一作)

3)基于低轨卫星互联网的星地协同理论

面向海量终端设备的星地多维资源协同分配机制;星地协同中的数据安全传输与用户公平性保障机制;星地传输中的飞艇中继与时间窗扩展机制;星地中继的用户分簇与多跳路由机制。

代表作

[1]

“Collaborative multi-resource allocation in terrestrial-satellite network towards 6G,” IEEE Transactions on Wireless Communications, vol. 20, no. 11, pp. 7057-7071, 2021.(一作)

[2]

“Improving the system performance in terrestrial-satellite relay networks by configuring aerial relay,” IEEE Transactions on Vehicular Technology, vol. 70, no. 20, pp. 13139-13148, 2021.(学生一作,导师通讯)

[3]

“Multi-resources management in 6G-oriented terrestrial-satellite network,” China Communications, vol. 18, no. 9, pp. 24-36, 2021.(一作)

[4]

“Dynamic scheduling for emergency tasks in space data relay network” IEEE Transactions on Vehicular Technology, vol. 70, no. 1, pp. 795-807, 2021.(三作)

[5]

“Integrated resource management for terrestrial-satellite systems,” IEEE Transactions on Vehicular Technology, vol. 69, no. 3, pp. 3256-3266, 2020.(一作)

[6]

“Dynamic user association for resilient backhauling in satellite–terrestrial integrated networks,” IEEE Systems Journal, vol. 14, no. 4, pp. 5025-5036, 2020.(三作)

[7]

“Contact plan design with directional space-time graph in two-layer space communication networks,” IEEE Internet of Things Journal, vol. 6, no. 6, pp. 10862-10874, 2019.(三作)

4)全光交换与传输理论

全光交换器组网的多域性能联合分析;低时延保障的WDM网络联合数据调度与路由机制;可见光通信的多址传输机制;低时延与高能效的光与无线跨网络协同传输机制。

代表作

[1]

 “NOMA for energy-efficient LiFi-enabled bidirectional IoT communication,” IEEE Transactions on Communications, vol. 69, no. 3, pp. 1693-1706, 2021.(二作)

[2]

“OFDM-based generalized optical MIMO,” Journal of Lightwave Technology, vol. 39, no. 19, pp. 6063-6075, 2021.(三作)

[3]

“Software defined wireline-wireless cross-networks: framework, challenges and prospects,” IEEE Communications Magazine, vol. 56, no. 8, pp. 145-151, 2018.(一作)

[4]

“A Survey of underwater optical wireless communication,” IEEE Communications Surveys & Tutorials, vol. 19, no. 1, pp. 204-238, 2017.(二作,高被引)

[5]

“Cross-networks energy efficiency tradeoff: From wired networks to wireless networks,” IEEE Access, vol. 5, pp. 15-26, 2017.(一作)

[6]

“Switch cost and packet delay tradeoff in data center networks with switch reconfiguration overhead,” Elsevier Computer Networks, vol. 87, pp. 33-43, 2015.(一作)

[7]

“Joint scheduling and routing for QoS guaranteed packet transmission in energy efficient reconfigurable WDM mesh networks,” IEEE Journal on Selected Areas in Communications, vol. 32, no. 8, pp. 1533-1541, 2014.(二作) 

5)面向下一代网络的通信维度突破

对无线通信时域、频域、空域之外,新的信息承载方式的探索;基于数论的信源编码与信息压缩。

代表作

[1] “Data attachment: A novel type of wireless transmission,” IEEE Wireless Communications, vol. 26, no. 6, pp. 126-131, 2019.(一作)

专利

已授权(近五年)

[1]

 一种无人机在数据收集过程中的路径规划方法,专利号:ZL202110148205.4,授权日期:2023081日。(排序第一)

[2]

一种基于二元逻辑关系的无线数据发送方法,专利号:ZL201811197664.6,授权日期:20220211日。(排序第一)

[3]

一种空天地卫星通信系统的总吞吐量及能耗优化方法,专利号:ZL202110025379.1,授权日期:202118日。(排序第一)

[4]

一种SDN化的5G网络系统及其协作控制方法,专利号:ZL201711041233.6,授权日期:20201013日。(排序第一)
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