DB004301-工程电磁学与计算电磁学

发布者:王源发布时间:2018-04-23浏览次数:1729

研究生课程开设申请表

 开课院(系、所):信息科学与工程学院

 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

工程电磁学与计算电磁学

英文

Engineering Electromagnetics and Computational Electromagnetics

待分配课程编号

DB004301

课程适用学位级别

博士

硕士


总学时

32

课内学时

32

学分

2

实践环节


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()

信息科学与工程学院

开课学期

秋季

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

课程负责人

教师

姓名

崔铁军,张剑锋,程强

职称

教授,讲师,教授,讲师

e-mail

tjcui@seu.edu.cn

jfzhang@emfield.org

qiangcheng@emfield.org

qinyao@emfield.org

网页地址


授课语言

中文

课件地址

李文正搂6搂会议室

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

电磁场理论

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

Fast Algorithms in Computational Electromagnetics

崔铁军

内部使用

2003


主要参考书

Fast and Efficient Algorithms in Computational Electromagnetics

W.C.Chew et.al

Artech House Publisher

July 2001



一、课程介绍(含教学目标、教学要求等)300字以内)

 介绍国际相关领域的研究进展与现状,将国际上相关领域的最新研究成果介绍给学生,并与现有的科研项目紧密地结合起来。同时讲授本领域内的基础知识。在计算电磁学和工程电磁学领域培养一定的独立科研工作能力和创新能力。


二、教学大纲(含章节目录):(可附页)


1. Metamaterial的历史、现状与未来

  • Metamaterial的发展历史

  • 国际上相关领域的进展与现状

  • 国际上相关领域的最新研究成果

  • Metamaterial在工程的应用简介

  • 介绍目前尚未解决的、具有挑战性的问题


2. Metamaterial的结构单元设计

  • Metamaterial的基本单元介绍

  • 电谐振和磁谐振单元设计

  • 左手媒质结构单元设计

  • 宽带人工媒质单元设计


3. Metamaterial的媒质参数提取

  • 单个单元参数提取算法

  • 多单元媒质参数提取算法

  • 互补媒质结构的参数提取算法


4. 平面Metamaterial结构在微波工程中的应用

  • 基于复合左右手结构的传输线设计

  • 基于复合左右手结构的滤波器设计

  • 基于复合左右手结构的谐振器设计

  • 基于复合左右手结构的耦合器设计

  • 基于复合左右手结构的微波天线设计


5. 立体式Metamaterial结构的应用

  • 基于metamaterial的透镜天线设计

  • 基于metamaterial的极化偏转器设计

  • 基于metamaterial的隧穿结构设计


6. 光学变换理论及其实现

  • 光学变换理论简介

  • 线性和非线性光学变换

  • 光学变换理论的物理实现


7. 计算电磁学的历史、现状与未来

  • 国际上相关领域的进展与现状

  • 计算电磁学是一门涉及数学、物理学及计算机科学的学科

  • 介绍目前尚未解决的、具有挑战性的问题


8. Green函数与积分方程

  • 自由空间中的Green函数

  • 电场积分方程--- 介电体情况

  • 电场积分方程--- 理想导体情况

  • 磁场积分方程--- 理想导体情况

  • 混合积分方程--- 理想导体情况

  • 体积分方程


9. 积分方程的数值解法 ---- 矩量法

  • 介电体问题的矩量法(体基函数)

  • 理想导体问题的矩量法(表面RWG基函数)


10. 自由空间中平面理想导体结构的二维CG-FFT算法

  • 平面理想导体结构的剖分及二维矩形网格

  • 共扼梯度方法


11. 平面理想导体结构的二维预相关FFT算法及自适应积分方程法

  • RWG三角形网格向规则的矩形网格的变换

  • 自由空间中平面理想导体结构的二维预相关FFT算法及自适应积分方程法


12. 二维电磁问题的快速多极子方法

  • 二维Green函数的加法定理

  • Green函数的有效因子化

  • 转移算子的对角化

  • 对角化转移算子的另外一种推导方法

  • 聚集、转移及扩散的物理意义


三、教学周历

(113由崔铁军教授讲授,2-6由程强教授讲授,7-12由秦瑶讲师讲授,14-18由张剑锋讲师讲授)

 周次

 教学内容

 教学方式

1

Metamaterial的历史、现状与未来

 授课

2

Metamaterial的结构单元设计(I)

 授课

3

Metamaterial的结构单元设计(II)

 授课

4

Metamaterial的媒质参数提取(I)

 授课

5

Metamaterial的媒质参数提取(II)

 授课

6

 平面Metamaterial结构在微波工程中的应用(I)

 授课

7

 平面Metamaterial结构在微波工程中的应用(II)

 授课

8

 平面Metamaterial结构在微波工程中的应用(III)

 授课

9

 立体式Metamaterial结构的应用(I)

 授课

10

 立体式Metamaterial结构的应用(II)

 授课

11

 光学变换理论及其实现(I)

 授课

12

 光学变换理论及其实现(II)

 授课

13

 计算电磁学的历史、现状与未来

 授课

14

Green函数与积分方程

 授课

15

 积分方程的数值解法 ---- 矩量法

 授课

16

 自由空间中平面理想导体结构的二维CG-FFT算法

 授课

17

 平面理想导体结构的二维预相关FFT算法及自适应积分方程法

 授课

18

 二维电磁问题的快速多极子方法

 授课


四、主讲教师简介:

 崔铁军男,生于19659月。1987年毕业于西安电子科技大学,获工程学士学位。1989年和1993年分别在西安电子科技大学获硕士及博士学位,后留校从事教学与科研工作。199311月破格提升为副教授。1995年至1997年,获得德国Alexander von Humboldt Foundation(洪堡基金会)的资助,在德国Karlsruhe大学作为洪堡学者进行合作研究。1997年至1999年,在美国University of Illinois at Urbana-Champaign作博士后Research Associate2000年至2002年,被University of Illinois at Urbana-Champaign聘为Research Scientist200110月被聘为东南大学无线电工程系教授、博士生导师、教育部“长江学者奖励计划”特聘教授。现为东南大学信息科学与工程学院副院长、毫米波国家重点实验室副主任、东南大学目标特性与识别研究所所长,国际著名刊物IEEE Transactions on Geoscience and Remote Sensing的副主编。

 主要学术任职包括:国际著名刊物IEEE Transactions on Geoscience and Remote Sensing 的副主编;IEEE Antennas and Propagation Magazine编委会成员;IEEE高级会员;国际无线电联盟会员;中国电子学会天线学会电磁散射与逆散射专业委员会副主任委员;中国物理学会计算电磁学专业委员会副主任委员;中国兵工学会电磁专业委员会委员;南京市留学归国人员联谊会常务理事;江苏省侨界青年总会第一届理事会理事。曾任2004年大型国际会议“电磁研究进展(Progress in Electromagnetic Research SymposiumPIERS)”的技术委员会副主席、2005年“亚太微波会议(Asian Pacific Microwave Conference, APMC)”技术委员会联合主席、2008年“微波毫米波技术国际会议(International Conference on Microwave and Millimeter Wave Technology)”技术委员会联合主席、2008年“新型人工电磁材料国际研讨会(International Workshop on Metamaterials大会主席等。

张剑锋,男,生于19795月。2000年毕业于山东工业大学,获工程学士学位。2004年毕业于南京电子技术研究所,获硕士学位。2008年于东南大学获博士学位,后留校从事教学和科研工作。

 曾获中国兵工学会优秀论文一等奖,在IEEE Transactions on Antennas and Propagation Physical Review B 上各发表论文一篇,并在国际会议上发表论文多篇。主要研究方向为计算电磁学、快速算法、多层媒质理论等。

程强,男,生于197910月。2001年和2004年于南京航空航天大学电子工程系获学士及硕士学位,2008年获东南大学无线电系电磁场与微波技术专业博士学位,目前在东南大学从事科研和教学任务。博士期间在计算电磁学,射频电路和人工电磁材料领域做了很多前沿性的工作,在国际高水平刊物 Physics Review Letters, Physics Review B, Applied Physics Letters, Optics Express, Optics Letters等杂志发表论文二十余篇,其中23篇被SCI检索,17篇被EI检索,论文共被引用137次。曾经以主力开发人员的身份参与国家杰出青年科学基金、和国家自然科学基金重大项目子课题、973项目子课题等项目。在校期间多次参与国际合作,曾参与美国波音公司和日本丰田公司的基于新型人工材料的天线与射频系统设计,在该领域内已申请两项国际专利,在新型人工电磁材料的设计和应用方面做了很多领先性的工作。博士在读期间曾为Intellisense公司开发基于有限元方法的电磁分析模块,有着充分的产品开发经验,目前已经投入市场。曾获得东南大学华英基金和江苏省创新计划的资助。

秦瑶,女,生于198111月。2003年和2005年毕业于东南大学,获工程学士和硕士学位。2009年博士毕业于东南大学,随后留校从事教学和科研工作。主要研究方向为Metamerrial、多层媒质理论等。

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

崔铁军

电磁场与微波技术




tjcui@seu.edu.cn

东南大学无线电系

210096

张剑锋

电磁场与微波技术




jfzhang@emfield.org

东南大学无线电系

210096

程强

电磁场与微波技术




qiangcheng@emfield.org

东南大学无线电系

210096

秦瑶

电磁场与微波技术




yaoqin@emfield.org

东南大学无线电系

210096



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

工程电磁学与计算电磁学

English

Engineering Electromagnetics and Computational Electromagnetics

Course Number

DB004301

Type of Degree

Ph. D


Master

Total Credit Hours

32

In Class Credit Hours

32

Credit

2

Practice


Computer-using Hours


Course Type

Public Fundamental    □Major Fundamental    □Major CompulsoryMajor Elective

School (Department)

School of Information Science and Engineering

Term

Autumn

Examination

A. □PaperOpen-book   □ Closed-bookB. □Oral   

C. □Paper-oral Combination                       D. □ Others

Chief

Lecturer

Name

T. J. Cui

J. F. Zhang

Q. Cheng

Y. Qin

Professional Title

Professor

Lecture

Professor

Lecture

E-mail

tjcui@seu.edu.cn

jfzhang@emfield.org

qiangcheng@emfield.org

yaoqin@emfield.org

Website


Teaching Language used in Course


Teaching Material Website


Applicable Range of Discipline

Electromagnetics and Microwave Technology

Name of First-Class Discipline

Electronic Science and Technology

Number of Experiment


Preliminary Courses


Teaching Books

Textbook Title

Author

Publisher

Year of Publication

Edition Number

Main Textbook

Fast Algorithms in Computational Electromagnetics

T. J. Cui

Internal Use

2003


Main Reference Books

Fast and Efficient Algorithms in Computational Electromagnetics

W. C. Chew et.al

Artech House Publisher

July 2001





  1. Course Introduction (including teaching goals and requirements) within 300 words:


This course will give a brief introduction to the research progress and the latest research achievements in the related areas, which will be closely connected with the current research projects.  The fundamentals of this area will also be instructed. The research and innovation abilities will be disciplined for the students in the computational electromagnetics and engineering electromagnetics.


  1. Teaching Syllabus (including the content of chapters and sections. A sheet can be attached):


1. Metamateials: Past, present and future

  • History of the metamaterials    

  • Progress and status quo

  • Latest research achievements

  • Application of the metamaterial

  • Challenging problems in metamaterials


2. Unit Design for Metamaterials

  • Introduction to basic units for metamaterials   

  • Design for electric resonator and magnetic resonator

  • Units for left-handed materials

  • Broadband metamaterial units


3. Parameter Retrieval for Metamaterials

  • Retrieval algorithm for single- metamateiral- unit   

  • Retrieval algorithm for multi- metamateiral- unit

  • Retrieval algorithm for complmentary-metamaterial-unit


4. Application of Planar Metamateirals in Microwave Engineering

  • Design of transmission-line based on CRLH structure  

  • Design of filter based on CRLH structure

  • Design of resonator based on CRLH structure

  • Design of coupler based on CRLH structure

  • Design of microwave antenna based on CRLH structure


5. Application of Volumetric Metamateirals in Microwave Engineering

  • Design of lens antenna based on volumetric metamaterials  

  • Design of polarizer based on volumetric metamaterials

  • Design of tunneling structure based on volumetric metamaterials


6. Theory and Application for the Optical Transformation Theory

  • Introduction for the optical transformation theory  

  • Linear and nonlinear optical transformation

  • Physical Realization of the optical transformation theory

7. An Introduction: The History, Current Status, and Future

  • International research progresses and current status

  • International latest research achievement

  • Motivation of fast algorithm

  • The unresolved and more challengeable problems


8. Green's Functions and Integral Equations

  • Green's function in free space

  • Green's function in half-space

  • Green's function in multi-layered media

  • Electric field dyadic Green's function

  • Magnetic field dyadic Green's function

  • Combined field dyadic Green's function

  • Electric field integral equation for dielectric objects

  • Electric field integral equation for perfectly conductor

  • Magnetic field integral equation for perfectly conductor

  • Combined field integral equation for perfectly conductor

  • Volume integral equation

  • Surface integral equation


9. The Method of Moments

  • MoM for dielectric bodies

  • MoM for PEC bodies

  • MoM for wire structures


10. CG-FFT for 2D PEC Objects in Free Space

  • Discrete convolution and FFT in 2D case

  • Adjoint operator

  • Conjugate gradient method


11. Adaptive Integral Method and Precorrected FFT Algorithm for 2D Objects

  • Meshing strategy

  • Transforming triangular mesh to rectangular mesh

  • Adaptive integral method and precorrected FFT algorithm for 2D objects in free sapce

  • Adaptive integral method and precorrected FFT algorithm for 2D objects in half-sapce

12. Fast Multipole Method for 2D Problems

  • Addition theorem for 2D Green's functions

  • Effective factorize of 2D Green's functions

  • Diagonalization of the translator

  • An alternative derivation of the Green's function's factorization

  • Physical interpretation of aggregation, translation and disaggregation

  • Bandwidth of the radiation pattern

  • Error control

  • Applications






  1. Teaching Schedule:


Week

Course Content

Teaching Method

1

Metamateials: Past, present and future

Lecture

2

Unit Design for Metamaterials (I)

Lecture

3

Unit Design for Metamaterials (II)

Lecture

4

Parameter Retrieval for Metamaterials (I)

Lecture

5

Parameter Retrieval for Metamaterials (II)

Lecture

6

Application of Planar Metamateirals in Microwave Engineering (I)

Lecture

7

Application of Planar Metamateirals in Microwave Engineering (II)

Lecture

8

Application of Planar Metamateirals in Microwave Engineering (III)

Lecture

9

Application of Volumetric Metamateirals in Microwave Engineering (I)

Lecture

10

Application of Volumetric Metamateirals in Microwave Engineering (II)

Lecture

11

Theory and Application for the Optical Transformation Theory (I)

Lecture

12

Theory and Application for the Optical Transformation Theory (II)

Lecture

13

An Introduction: The History, Current Status, and Future

Lecture

14

Green's Functions and Integral Equations

Lecture

15

The Method of Moments

Lecture

16

CG-FFT for 2D PEC Objects in Free Space

Lecture

17

Adaptive Integral Method and Precorrected FFT Algorithm for 2D Objects

Lecture

18

Fast Multipole Method for 2D Problems

Lecture

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)







  1. Brief Introduction of Chief lecturer:

Tie Jun Cui was born in September 1965, in Hebei, China. He received the B.Sc., M.Sc., and Ph.D. degrees in electrical engineering from Xidian University, Xi'an, China, in 1987, 1990, and 1993, respectively.

In March 1993, he joined the Department of Electromagnetic Engineering, Xidian University, and was promoted to an Associate Professor in November 1993. From 1995 to 1997 he was a Research Fellow with the Institut fur Hochstfrequenztechnik und Elektronik (IHE) at the University of Karlsruhe, Germany. In July 1997, he joined the Center for Computational Electromagnetics, Department of Electrical and Computer Engineering, University of Illinois at Urbana-Champaign, first as a Postdoctoral Research Associate and then a Research Scientist. In September 2001, he became a Cheung-Kong Professor with the Department of Radio Engineering, Southeast University, Nanjing, P. R. China. Currently, he is the Associate Director of the State Key Laboratory of Millimeter Waves, and the Center for Computational Electromagnetics.

Dr. Cui is the author of four book chapters. He has published over 170 scientific articles in international journals, including 48 IEEE Transactions papers and over 80 physics/optics papers in Science, Physical Review Letters, Physical Review B, Physical Review E, Applied Physics Letters, Optics Letters, and Optics Express, etc. His research interests include metamaterials, wave propagations, scattering, inverse scattering, metamaterials, landmine detection, geophysical subsurface sensing, fast algorithms, microwave and millimeter wave circuits and antennas simulations. Currently, he is a principal investigator of several national projects.

Dr. Cui was awarded a Third Prize of Science and Technology Progress by the Ministry of Electronics, China, in 1991, and a Research Fellowship from the Alexander von Humboldt Foundation, Bonn, Germany, in 1995, received a Young Scientist Award from the International Union of Radio Science (URSI) in 1999, was awarded a Cheung Kong Professor under the Cheung Kong Scholar Program by the Ministry of Education, China, in 2001, and received the National Science Foundation of China for Distinguished Young Scholars in 2002. He received several Best Paper Awards from the National and International Conferences and Organizations, including a Best Paper Award in Natural Science (the first place) by Nanjing Government, China, in 2005.

Dr. Cui is a senior member of IEEE and a member of URSI (Commission B). He serves as an Editorial Staff in IEEE Antennas and Propagation Magazine, and is now an Associate Editor in IEEE Transactions on Geoscience and Remote Sensing.

Jian Feng Zhang was born in May 1979, in Shandong, China. He received the B.E. degree from Shandong University of Technology (now the Shandong University), Shandong, China, in 2000, the M. E. degree from the 14th Research Institute of CETC, China, 2004, and the Ph. D degree from Southeast University, Nanjing, China, 2008. His research interests include computational electromagnetics, fast algorithms, multilayered media, etc.

Qiang Cheng was born in October 1979. He received the B.Sc., M.Sc. degrees in electrical engineering from Nanjing University of Aeronautics and Astronautics, Nanjing, China, in 2001 and 2004, respectively.  In 2008, he received the Ph. D degree in Southeast University in Naning, China. He has published more than twenty journal papers in Physics Review Letters, Physics Review B, Applied Physics Letters, Optics Express, Optics Letters et. al. He has applied for two international patents, and has ever developed the commercial electromagnetic analysis module. .He has ever be funded by the Huaying fund and innovation project in Jiangsu Province.

Qin Yao was born in November 1981, in Jiangsu, China. He received the B.E., M. E. and Ph. D degrees all in  Southeast University, Nanjing, China, in 2003, 2005, and 2009, respectively. Her research interests include Metamaterial and multilayered media, etc.






  1. Lecturer Information (include chief lecturer)


Lecturer

Discipline

(major)

Office

Phone Number

Home Phone Number

Mobile Phone Number

Email

Address

Postcode

Tie Jun Cui

Electromagnetics and Microwave Technology




tjcui@seu.edu.cn

School of Information Science and Engineering

210096

Jiang Feng Zhang

Electromagnetics and Microwave Technology




jfzhang@emfield.org

School of Information Science and Engineering

210096

Qiang Cheng

Electromagnetics and Microwave Technology




qiangcheng@emfield.org

School of Information Science and Engineering

210096

Yao Qin

Electromagnetics and Microwave Technology




yaoqin@emfield.org

School of Information Science and Engineering

210096





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