研究生课程开设申请表
开课院(系、所):779cn太阳集团
课程申请开设类型: 新开☑ 重开□ 更名□(请在□内打勾,下同)
课程 名称 | 中文 | 毫米波与太赫兹大规模阵列技术 | ||||||||||
英文 | Millimeter-wave and Terahertz Large-Scale Array Technologies | |||||||||||
待分配课程编号 | DB004314 | 课程适用学位级别 | 博士 | | 硕士 | | ||||||
总学时 | 48 | 课内学时 | 36 | 学分 | 3 | 实践环节 | 12 | 用机小时 | ||||
课程类别 | □公共基础 □专业基础 □专业必修 ☑专业选修 | |||||||||||
开课院(系) | 779cn太阳集团 | 开课学期 | □秋季 ☑春季 | |||||||||
考核方式 | A.□笔试(□开卷 □闭卷) B.□口试 C.□笔试与口试结合 D.☑其他 课程大作业 | |||||||||||
课程负责人 | 教师 姓名 | 郝张成、洪伟、徐俊、蒋之浩、周健义、陈鹏11255、周培根 | 职称 | 教授 | ||||||||
zchao@seu.edu.cn | 网页地址 | /2018/0930/c19949a241896/page.htm | ||||||||||
授课语言 | 中文 | 课件地址 | ||||||||||
适用学科范围 | 电磁场与微波技术 | 所属一级学科名称 | 电子科学与技术 | |||||||||
实验(案例)个数 | 先修课程 | 高等电磁场、微波网络等 | ||||||||||
教学用书 | 教材名称 | 教材编者 | 出版社 | 出版年月 | 版次 | |||||||
主要教材 | 《毫米波与太赫兹大规模阵列技术 上册:无源波束成形阵列》;《毫米波与太赫兹大规模阵列技术 下册:有源波束成形阵列》 | 上册: 下册: | 科学出版社 | 上册:2025.11 下册:2026.01 | 1 | |||||||
主要参考书 | ||||||||||||
一、课程介绍(含教学目标、教学要求等)(300字以内)
毫米波与太赫兹大规模阵列技术将成为未来无线通信系统的核心使能技术,本课程立足毫米波技术领域人才培养需求,讲授无源和有源波束成形技术在内的毫米波与太赫兹大规模阵列技术。整个课程的课堂授课环节分为十二部分,包括毫米波与太赫兹大规模阵列技术研究概论、电路型无源波束成形技术及多波束阵列天线、准光型无源波束成形技术及多波束阵列天线、其他类型无源波束成形技术及多波束阵列天线、毫米波与太赫兹集成电路、毫米波多通道波束成形芯片、毫米波大规模MIMO混合多波束阵列、毫米波全数字多波束大规模MIMO阵列、基于半导体器件的n-bit反射阵和透射阵、基于向列相液晶材料的相控阵天线、毫米波与太赫兹片上阵列、硅基太赫兹高速无线传输技术等。本课程课堂讲授36课时,技术研讨12课时,总计48课时,本课程将布置同毫米波与太赫兹大规模阵列技术相关的课程大作业,并以完成情况作为员工课程成绩的主要依据。
教学大纲(含章节目录):(可附页)
第一章:毫米波与太赫兹大规模阵列技术研究概论
1.1各类无线电应用技术的演进历史
1.2大规模波束成形阵列的分类
1.3无源波束成形阵列技术
1.4有源波束成形阵列技术与系统架构
第二章:电路型无源波束成形技术及多波束阵列天线
2.1 Butler矩阵及多波束天线
2.2 Blass矩阵及多波束天线
2.3 Nolan矩阵及多波束天线
2.4多模腔波束成形网络及多波束天线
第三章:准光型无源波束成形技术及多波束阵列天线
3.1 Rotman透镜及多波束天线
3.2 R-kR透镜及多波束天线
3.3基片集成抛物反射面及多波束天线
3.4多馈源透镜多波束天线
第四章:其他类型无源波束成形技术及多波束阵列天线
4.1单脉冲天线
4.2八端口结基片集成多波束天线
4.3多极化多波束阵列天线
第五章:毫米波与太赫兹集成电路
5.1毫米波太赫兹器件
5.2接收机芯片
5.3发射机芯片
第六章:毫米波多通道波束成形芯片
6.1模拟波束成形芯片
6.2支持全数字多波束阵列系统的多通道收发芯片
6.3多通道射频全连接波束成形芯片
第七章:毫米波大规模MIMO混合多波束阵列
7.1技术指标与架构
7.2天线单元设计
7.3变频子系统设计
7.4本振子系统设计
7.5有源阵列天线系统的远场测试和测试结果
7.6阵面自校准技术
第八章:毫米波全数字多波束大规模MIMO阵列
8.1对称全数字多波束大规模MIMO阵列
8.2非对称全数字多波束大规模MIMO阵列
第九章 基于半导体器件的n-bit反射阵和透射阵
9.1n-Bit空馈波束成形阵列基础原理和阵列构架
9.2n-bit反射式波束成形阵列
9.3n-bit透射式波束成形阵列
9.4n-bit辐射式波束成形阵列
第十章:基于向列相液晶材料的相控阵天线
10.1液晶材料及其电特性
10.2液晶移相器技术
10.3液晶相控阵
10.4液晶相控阵校准技术
第十一章:毫米波与太赫兹片上阵列
11.1片上天线
11.2片上多通道相控阵列
11.3太赫兹相干辐射源阵列
第十二章:硅基太赫兹高速无线传输技术
12.1 D-波段硅基收发机和传输实验
12.2 220GHz硅基收发机和和高速无线传输实验
12.3 300GHz硅基收发机和和无线传输实验
三、教学周历
周次 | 教学内容 | 教学方式 |
1 | 毫米波与太赫兹大规模阵列技术研究概论 | 讲课 |
2 | 电路型无源波束成形技术及多波束阵列天线 | 讲课 |
3 | 准光型无源波束成形技术及多波束阵列天线 | 讲课 |
4 | 其他类型无源波束成形技术及多波束阵列天线 | 讲课 |
5 | 毫米波与太赫兹集成电路 | 讲课 |
6 | 毫米波多通道波束成形芯片 | 讲课 |
7 | 毫米波大规模MIMO混合多波束阵列 | 讲课 |
8 | 毫米波全数字多波束大规模MIMO阵列 | 讲课 |
9 | 基于半导体器件的n-bit反射阵和透射阵 | 讲课 |
10 | 基于向列相液晶材料的相控阵天线 | 讲课 |
11 | 毫米波与太赫兹片上阵列 | 讲课 |
12 | 硅基太赫兹高速无线传输技术 | 讲课 |
13 | 技术研讨 | 课后研究 |
14 | 技术研讨 | 课后研究 |
15 | 技术研讨 | 课后研究 |
16 | 技术研讨 | 课后研究 |
17 | ||
18 |
注:1.以上一、二、三项内容将作为中文教学大纲,在研究生院中文网页上公布,四、五内容将保存在研究生院。2.开课学期为:春季、秋季或春秋季。3.授课语言为:汉语、英语或双语教学。4.适用学科范围为:公共,一级,二级,三级。5.实践环节为:实验、调研、研究报告等。6.教学方式为:讲课、讨论、实验等。7.学位课程考试必须是笔试。8.课件地址指在网络上已经有的课程课件地址。9.主讲教师简介主要为基本信息(出生年月、性别、学历学位、专业职称等)、研究方向、教学与科研成果,以100至500字为宜。
四、主讲教师简介:
郝张成,779cn太阳集团首席教授,教育部长江学者特聘教授,1997年毕业于西安电子科技大学微波电信工程系获学士学位;2002年3月和2006年1月毕业于779cn太阳集团无线电工程系电磁场与微波技术专业分别获硕士与博士学位。2006年至2011年,分别在法国ENSTB和英国Heriot-Watt University担任博士后从事微波毫米波电路与天线的研究,2011年底回国工作。主要研究领域为微波毫米波器件与电路,亚毫米波太赫兹器件与系统。近年来,先后主持了中组部、教育部、科技部、军科委、自然基金委等支持的项目十余项;在国际核心学术期刊和重要会议上发表论文200余篇;获授权国家发明专利20余项;曾担任ICMMT2019、ISAP2019、ACES2019、iWat2018和IWS2018等十多个国际学术会议的技术委员会主席/共主席;担任IEEE T-AP、IEEE T-MTT等十多个国际核心期刊的审稿人,担任国际核心期刊IET Electronics Letters和IET Microwaves Antennas and Propagation副主编;曾获2016年国家自然科学奖二等奖(排名2)等学术奖励。
洪伟,中国科公司院士、中国电子学会会士、中国电子学会微波分会副主任委员、中国电子学会天线分会副主任委员、IEEE Fellow。曾任毫米波国家重点实验室主任(2003-2021)、大陆首位IEEE MTT-S AdCom委员等。在毫米波基础理论、芯片与系统、测量技术与仪器方面做出了系统性、创造性贡献。作为主要贡献者之一发展了“基片集成类导波结构及器件”新领域,突破毫米波多通道大带宽测量系列关键技术,率先在国内发展了覆盖至800GHz的系列硅基芯片,实现了关键毫米波芯片的国产化替代和规模应用。在中国科学、Engineering、IEEE期刊和Advanced Materials等权威学术期刊上发表论文480余篇,出版专著2部;谷歌引用37000余次,H因子95,在英、意、波、日、新、韩、中等国召开的重要国际会议上作大会/主旨报告28次。承担完成国家973、重点研发计划,创新群体、国家重大科研仪器研制项目等多项。研究成果应用于某型号装备、5G毫米波基站AAU、毫米波卫通设备、北斗卫星导航测试等。获国家自然科学奖二等奖1项(排1,2016)、国家科技进步奖二等奖1项(排1,2023)、国家自然科学奖四等奖1项(排3,1991)、省部一等奖3项(均排1)、首届全国创新争先奖状、IEEE国际标准杰出贡献奖等。
徐俊,博士,副教授。2019年底获779cn太阳集团博士学位,2022年加入779cn太阳集团毫米波全国重点实验室。主要研究方向包括通信、感知及成像系统中的微波/毫米波/太赫兹天线、电路与系统集成技术等。
蒋之浩,779cn太阳集团青年首席教授,美国宾夕法尼亚州立大学博士。主要研究方向为天线理论与技术、电磁超表面、电磁半解析方法等,提出共口径多波束产生新方法,发展了超表面天线模式理论和多极化阵列设计方法,研制了我国首套卫星通信大规模液晶相控阵。入选国家级高层次青年人才计划。
周健义,779cn太阳集团教授, 2001年获779cn太阳集团无线电工程系博士学位。自1996年4月任职于779cn太阳集团,从事电磁场理论、微波电路、移动通信射频系统等方面的科研和教学工作。
陈鹏,博士,副教授。2009年获779cn太阳集团博士学位,主要研究方向包括无源及有源多波束阵列系统等。
周培根,博士,副研究员。2020年获779cn太阳集团博士学位,主要研究方向包括毫米波太赫兹射频集成电路等。
五、任课教师信息(包括主讲教师):
任课 教师 | 学科 (专业) | 办公 电话 | 住宅 电话 | 手机 | 电子邮件 | 通讯地址 | 邮政 编码 |
郝张成 | 电磁场与微波技术 | zchao@seu.edu.cn | 南京江宁区779cn太阳集团路2号 | 211189 | |||
洪伟 | 电磁场与微波技术 | weihong@seu.edu.cn | 南京江宁区779cn太阳集团路2号 | 211189 | |||
徐俊 | 电磁场与微波技术 | junxu@seu.edu.cn | 南京江宁区779cn太阳集团路2号 | 211189 | |||
蒋之浩 | 电磁场与微波技术 | Zhihao.jiang@seu.edu.cn | 南京江宁区779cn太阳集团路2号 | 211189 | |||
周健义 | 电磁场与微波技术 | jyzhou@seu.edu.cn | 南京江宁区779cn太阳集团路2号 | 211189 | |||
陈鹏 | 电磁场与微波技术 | 南京江宁区779cn太阳集团路2号 | 211189 | ||||
周培根 | 电磁场与微波技术 | 南京江宁区779cn太阳集团路2号 | 211189 |
六、课程必要性说明
面向新一代移动通信100Gbps+的超高速率需求,技术演进呈现双轨突破:在频谱维度向毫米波(mmWave)甚至太赫兹(THz)频段延伸,突破传统sub-6GHz频谱的资源瓶颈;在空域维度采用大规模有源一体化阵列,通过同时生成数百个波束实现超大规模空间复用。因此,毫米波与太赫兹大规模阵列技术将成为未来无线通信系统的核心使能技术。当前开设的博士和硕士研究生专业课程中未有系统讲授毫米波与太赫兹大规模阵列技术相关内容,而这一部分内容又是未来一段时间内专业领域的重要研究方向,因而申请开设这门课程。
七、课程开设审批意见
所在院(系)
审 批 意 见
负责人:
日 期:
所在学位评定分
委员会审批意见
分委员会主席:
日 期:
研究生院审批意见
负责人:
日 期:
注
说明:1.研究生课程重开、更名申请也采用此表。表格下载:http: /seugs.seu.edu.cn/down/1.asp
2.此表一式三份,交研究生院、院(系)和自留各一份,同时提交电子文档交研究生院。
Application Form For Opening Graduate Courses
School (Department/Institute):School of Information Science and Engineering
Course Type: New Open☑ Reopen □ Rename □(Please tick in □, the same below)
Course Name | Chinese | 毫米波与太赫兹大规模阵列技术 | |||||||||||
English | Millimeter-wave and Terahertz Large-Scale Array Technologies | ||||||||||||
Course Number | Type of Degree | Ph. D | | Master | | ||||||||
Total Credit Hours | 48 | In Class Credit Hours | 36 | Credit | 3 | Practice | 12 | Computer-using Hours | 0 | ||||
Course Type | □Public Fundamental □Major Fundamental □Major Compulsory ☑Major Elective | ||||||||||||
School (Department) | School of Information Science and Engineering | Term | Spring | ||||||||||
Examination | A. □Paper(□Open-book □ Closed-book) B. □Oral C. □Paper-oral Combination D.☑ Others course design report | ||||||||||||
Chief Lecturer | Name | Zhang-Cheng Hao | Professional Title | Professor | |||||||||
zchao@seu.edu.cn | Website | /2018/0930/c19949a241896/page.htm | |||||||||||
Teaching Language used in Course | Chinese | Teaching Material Website | |||||||||||
Applicable Range of Discipline | Electromagnetic Field and Microwave Engineering, Electronic Information | Name of First-Class Discipline | Electronics Science and Technology,Electronic and Information Engineering | ||||||||||
Number of Experiment | Preliminary Courses | Advanced electromagnetic fields, microwave engineering, antenna theory and technology, radio frequency integrated circuits, etc | |||||||||||
Teaching Books | Textbook Title | Author | Publisher | Year of Publication | Edition Number | ||||||||
Main Textbook | 《Millimeter-Wave and Terahertz Large-Scale Array Technologies | Volume I::Wei Hong、Peng Chen、Jun Xu、Yu Jian Cheng;Volume II::Wei Hong、Jixin Chen、Zhang-Cheng Hao、Zhi Hao Jiang、Jianyi Zhou | Science Press | Volume I: November, 2025; Volume II: January, 2026 | 1 | ||||||||
Main Reference Books | |||||||||||||
Course Introduction (including teaching goals and requirements) within 300 words:
Millimeter-wave and terahertz large-scale array technology will emerge as the core enabling technology for future wireless communication systems. Based on the talent cultivation needs in the field of millimeter-wave technology, this course provides instruction on millimeter-wave and terahertz large-scale array technology, encompassing both passive and active beamforming techniques. The classroom teaching component of the entire course is divided into twelve sections, including an overview of research on millimeter-wave and terahertz large-scale array technology, circuit-based passive beamforming technology and multi-beam array antennas, quasi-optical passive beamforming technology and multi-beam array antennas, other types of passive beamforming technology and multi-beam array antennas, millimeter-wave and terahertz integrated circuits, millimeter-wave multi-channel beamforming chips, millimeter-wave large-scale MIMO hybrid multi-beam arrays, millimeter-wave fully digital multi-beam large-scale MIMO arrays, n-bit reflectarrays and transmitarrays based on semiconductor devices, phased array antennas based on nematic liquid crystal materials, millimeter-wave and terahertz on-chip arrays, and silicon-based terahertz high-speed wireless transmission technology, among others. This course comprises 36 classroom teaching hours and 12 classroom discussion hours, totaling 48 hours. It will assign course design topics related to millimeter-wave and terahertz large-scale array technology, with the completion of these topics serving as the primary basis for evaluating students' course performance.
Teaching Syllabus (including the content of chapters and sections. A sheet can be attached):
Chapter 1: Overview of Research on Millimeter-Wave and Terahertz Large-Scale Array Technologies
1.1 Evolutionary History of Various Radio Application Technologies
1.2 Classification of Large-Scale Beamforming Arrays
1.3 Passive Beamforming Array Technology
1.4 Active Beamforming Array Technology and System Architecture
Chapter 2: Circuit-Based Passive Beamforming Technology and Multi-Beam Array Antennas
2.1 Butler Matrix and Multi-Beam Antennas
2.2 Blass Matrix and Multi-Beam Antennas
2.3 Nolan Matrix and Multi-Beam Antennas
2.4 Multi-Mode Cavity Beamforming Networks and Multi-Beam Antennas
Chapter 3: Quasi-Optical Passive Beamforming Technology and Multi-Beam Array Antennas
3.1 Rotman Lens and Multi-Beam Antennas
3.2 R-kR Lens and Multi-Beam Antennas
3.3 Substrate-Integrated Parabolic Reflectors and Multi-Beam Antennas
3.4 Multi-Feed Lens Multi-Beam Antennas
Chapter 4: Other Types of Passive Beamforming Technology and Multi-Beam Array Antennas
4.1 Monopulse Antennas
4.2 Eight-Port Junction Substrate-Integrated Multi-Beam Antennas
4.3 Multi-Polarization Multi-Beam Array Antennas
Chapter 5: Millimeter-Wave and Terahertz Integrated Circuits
5.1 Millimeter-Wave and Terahertz Devices
5.2 Receiver Chips
5.3 Transmitter Chips
Chapter 6: Millimeter-Wave Multi-Channel Beamforming Chips
6.1 Analog Beamforming Chips
6.2 Multi-Channel Transceiver Chips Supporting Full-Digital Multi-Beam Array Systems
6.3 Multi-Channel RF Full- Connected Beamforming Chips
Chapter 7: Millimeter-Wave Large-Scale MIMO Hybrid Multi-Beam Arrays
7.1 Technical Specifications and Architecture
7.2 Antenna Element Design
7.3 Frequency Conversion Subsystem Design
7.4 Local Oscillator Subsystem Design
7.5 Far-Field Testing and Results of Active Array Antenna Systems
7.6 Array Self-Calibration Technology
Chapter 8: Millimeter-Wave Fully Digital Multi-Beam Large-Scale MIMO Arrays
8.1 Symmetric Full-Digital Multi-Beam Large-Scale MIMO Arrays
8.2 Asymmetric Full-Digital Multi-Beam Large-Scale MIMO Arrays
Chapter 9: n-Bit Reflectarrays and Transmitarrays Based on Semiconductor Devices
9.1 Fundamental Principles and Array Architectures of n-Bit Space-Fed Beamforming Arrays
9.2 n-Bit Reflective Beamforming Arrays
9.3 n-Bit Transmissive Beamforming Arrays
9.4 n-Bit Radiative Beamforming Arrays
Chapter 10: Phased Array Antennas Based on Nematic Liquid Crystal Materials
10.1 Liquid Crystal Materials and Their Electrical Properties
10.2 Liquid Crystal Phase Shifter Technology
10.3 Liquid Crystal Phased Arrays
10.4 Calibration Technologies for Liquid Crystal Phased Arrays
Chapter 11: Millimeter-Wave and Terahertz On-Chip Arrays
11.1 On-Chip Antennas
11.2 On-Chip Multi-Channel Phased Arrays
11.3 Terahertz Coherent Radiation Source Arrays
Chapter 12: Silicon-Based Terahertz High-Speed Wireless Transmission Technology
12.1 D-Band Silicon-Based Transceivers and Transmission Experiments
12.2 220 GHz Silicon-Based Transceivers and High-Speed Wireless Transmission Experiments
12.3 300 GHz Silicon-Based Transceivers and Wireless Transmission Experiments
Teaching Schedule:
Week | Course Content | Teaching Method |
1 | Overview of Research on Millimeter-Wave and Terahertz Large-Scale Array Technology | Lecture |
2 | Circuit-Based Passive Beamforming Technology and Multi-Beam Array Antennas | Lecture |
3 | Quasi-Optical Passive Beamforming Technology and Multi-Beam Array Antennas | Lecture |
4 | Other Types of Passive Beamforming Technology and Multi-Beam Array Antennas | Lecture |
5 | Millimeter-Wave and Terahertz Integrated Circuits | Lecture |
6 | Millimeter-Wave Multi-Channel Beamforming Chips | Lecture |
7 | Millimeter-Wave Large-Scale MIMO Hybrid Multi-Beam Arrays | Lecture |
8 | Millimeter-Wave Fully Digital Multi-Beam Large-Scale MIMO Arrays | Lecture |
9 | n-Bit Reflectarrays and Transmitarrays Based on Semiconductor Devices | Lecture |
10 | Phased Array Antennas Based on Nematic Liquid Crystal Materials | Lecture |
11 | Millimeter-Wave and Terahertz On-Chip Arrays | Lecture |
12 | Silicon-Based Terahertz High-Speed Wireless Transmission Technology | Lecture |
13 | Technologies Discussion | Investigation |
14 | Technologies Discussion | Investigation |
15 | Technologies Discussion | Investigation |
16 | Technologies Discussion | Investigation |
17 | ||
18 |
Note: 1.Above one, two, and three items are used as teaching Syllabus in Chinese and announced on the Chinese website of Graduate School. The four and five items are preserved in Graduate School.
2. Course terms: Spring, Autumn , and Spring-Autumn term.
3. The teaching languages for courses: Chinese, English or Chinese-English.
4. Applicable range of discipline: public, first-class discipline, second-class discipline, and third-class discipline.
5. Practice includes: experiment, investigation, research report, etc.
6. Teaching methods: lecture, seminar, practice, etc.
7. Examination for degree courses must be in paper.
8. Teaching material websites are those which have already been announced.
9. Brief introduction of chief lecturer should include: personal information (date of birth, gender, degree achieved, professional title), research direction, teaching and research achievements. (within 100-500 words)
Brief Introduction of Chief lecturer:
Zhang-ChengHao is a Chief Professor at Southeast University and a Distinguished Professor under the Changjiang Scholars Program of the Ministry of Education. He received his B.S. degree from the Department of Microwave Telecommunications Engineering at Xidian University in 1997, and his M.S. and Ph.D. degrees in Electromagnetic Field and Microwave Technology from the Department of Radio Engineering at Southeast University in March 2002 and January 2006, respectively. From 2006 to 2011, he served as a postdoctoral researcher at ENSTB in France and Heriot-Watt University in the UK, focusing on microwave and millimeter-wave circuits and antennas. He returned to China at the end of 2011. His primary research areas include microwave and millimeter-wave devices and circuits, as well as submillimeter-wave and terahertz devices and systems. In recent years, he has led over ten projects supported by the Organization Department of the CPC Central Committee, the Ministry of Education, the Ministry of Science and Technology, the Military Science Commission, and the National Natural Science Foundation of China. He has published over 200 papers in international core academic journals and major conferences, holds more than 20 authorized national invention patents, and has served as the Technical Program Committee Chair/Co-Chair for over ten international academic conferences, including ICMMT2019, ISAP2019, ACES2019, iWat2018, and IWS2018. He is a reviewer for over ten international core journals, such as IEEE T-AP and IEEE T-MTT, and serves as an Associate Editor for the international core journals IET Electronics Letters and IET Microwaves Antennas and Propagation. He has received academic awards, including the Second Prize of the National Natural Science Award in 2016 (ranked 2nd).
WeiHong is an Academician of the Chinese Academy of Sciences, a Fellow of the Chinese Institute of Electronics, the Deputy Director of the Microwave Branch of the Chinese Institute of Electronics, the Deputy Director of the Antenna Branch of the Chinese Institute of Electronics, and an IEEE Fellow. He previously served as the Director of the State Key Laboratory of Millimeter Waves (2003-2021) and was the first Mainland Chinese member of the IEEE MTT-S AdCom. He has made systematic and creative contributions to millimeter-wave fundamental theory, chips and systems, measurement techniques, and instrumentation. As one of the key contributors, he developed the new field of "substrate-integrated waveguide structures and devices," broke through a series of key technologies for millimeter-wave multi-channel large-bandwidth measurements, and pioneered the development of a series of silicon-based chips covering up to 800 GHz in China, achieving domestic substitution and large-scale application of key millimeter-wave chips. He has published over 480 papers in authoritative academic journals such as Science China, Engineering, IEEE journals, and Advanced Materials, authored two monographs, and has been cited over 37,000 times on Google Scholar with an H-index of 95. He has delivered plenary/keynote speeches at major international conferences held in the UK, Italy, Poland, Japan, Singapore, South Korea, and China 28 times. He has undertaken and completed numerous projects, including the National 973 Program, Key R&D Program, Innovation Group, and National Major Scientific Instrument Development Projects. His research findings have been applied in equipment models, 5G millimeter-wave base station AAUs, millimeter-wave satellite communication equipment, and Beidou satellite navigation testing. He has received awards, including the Second Prize of the National Natural Science Award (ranked 1st, 2016), the Second Prize of the National Science and Technology Progress Award (ranked 1st, 2023), the Fourth Prize of the National Natural Science Award (ranked 3rd, 1991), three First Prizes at the provincial and ministerial levels (all ranked 1st), the First National Innovation and Entrepreneurship Award, and the IEEE International Standard Outstanding Contribution Award.
Jun Xu, Ph.D., is an Associate Professor and Zijin Young Scholar. He received his Ph.D. from Southeast University at the end of 2019 and joined the State Key Laboratory of Millimeter Waves at Southeast University in 2022. His main research interests include microwave/millimeter-wave/terahertz antennas, circuits, and system integration technologies for communication, sensing, and imaging systems.
JixinChen is a Chief Professor at Southeast University and the Director of the Department of Electromagnetic Field and Microwave Engineering. He received his B.S. degree from the Department of Radio Engineering at Southeast University in 1998 and his M.S. and Ph.D. degrees from the School of Information Science and Engineering at Southeast University in 2002 and 2006, respectively. His main research interests are microwave and millimeter-wave chips and systems. He has published/co-authored over 100 papers and holds more than 20 invention patents. He previously served as the Technical Program Committee Chair for the 2021 National Microwave Millimeter Wave Conference and the IEEE RFIT2019 TPC Chair. He received the First Keysight Early Career Professor Award and the Second Prize of the National Natural Science Award in 2016. In 2021, he was selected for the Changjiang Scholars Award Program of the Ministry of Education.
Zhi HaoJiang is a Young Chief Professor at Southeast University and holds a Ph.D. from Pennsylvania State University in the United States. His main research interests include antenna theory and technology, electromagnetic metasurfaces, and electromagnetic semi-analytical methods. He has proposed new methods for shared-aperture multi-beam generation, developed metasurface antenna mode theory and multi-polarization array design methods, and developed China's first large-scale liquid crystal phased array for satellite communication. He has been selected for the National High-Level Young Talents Program.
JianyiZhou is a Professor at Southeast University and received his Ph.D. from the Department of Radio Engineering at Southeast University in 2001. Since April 1996, he has been affiliated with the School of Information Science and Engineering at Southeast University, engaging in research and teaching in electromagnetic field theory, microwave circuits, and mobile communication RF systems.
Peng Chen, Ph.D., is an Associate Professor. He received his Ph.D. from Southeast University in 2009, and his main research interests include passive and active multi-beam array systems.
Lecturer Information (include chief lecturer)
Lecturer | Discipline (major) | Office Phone Number | Home Phone Number | Mobile Phone Number | Address | Postcode | |
Zhang-Cheng Hao | Electromagnetic Field and Microwave Engineering | zchao@seu.edu.cn | No. 2 of Southeast University Road, Jiangning District, Nanjing | 211189 | |||
Wei Hong | Electromagnetic Field and Microwave Engineering | weihong@seu.edu.cn | No. 2 of Southeast University Road, Jiangning District, Nanjing | 211189 | |||
Jun Xu | Electromagnetic Field and Microwave Engineering | junxu@seu.edu.cn | No. 2 of Southeast University Road, Jiangning District, Nanjing | 211189 | |||
Jixin Chen | Electromagnetic Field and Microwave Engineering | jxchen@seu.edu.cn | No. 2 of Southeast University Road, Jiangning District, Nanjing | 211189 | |||
Zhi Hao Jiang | Electromagnetic Field and Microwave Engineering | Zhihao.jiang@seu.edu.cn | No. 2 of Southeast University Road, Jiangning District, Nanjing | 211189 | |||
Jianyi Zhou | Electromagnetic Field and Microwave Engineering | jyzhou@seu.edu.cn | No. 2 of Southeast University Road, Jiangning District, Nanjing | 211189 | |||
Peng Chen | Electromagnetic Field and Microwave Engineering | No. 2 of Southeast University Road, Jiangning District, Nanjing | 211189 |
