3. 강의목표
Course Outcomes:
At the conclusion of EECE 584 students should be able to:
1) Visualize the behavior of electromagnetic fields as they propagate in materials, radiate from sources, and scatter from obstacles
2) Become familiar with in-depth quantitative analysis and solutions for a number of fundamental application problems
3) Learn electromagnetic Theorems and their applications to practical problems
4) Learn mathematical tools and approaches that will allow them to solve a wide range of problems in electromagnetics
4. 강의선수/수강필수사항
학부과정의 전자기학및 전자장
5. 성적평가
Midterm I 20%
Midterm II 20%
Projects or Final 30%
Homework 30%
6. 강의교재
| 도서명 |
저자명 |
출판사 |
출판년도 |
ISBN |
|
Advanced Engineering Electromagnetics
|
Constantine Balanis
|
John Wiley & Sons
|
1989
|
978-0-470-58948-9
|
|
Theory and Computation of Electromagnetic Fields
|
Jian-Ming Jin
|
Wiley-IEEE
|
2015
|
978-1119108047
|
|
(Official) Foundations of Applied Electromagnetics
|
|
|
0000
|
|
7. 참고문헌 및 자료
R. F. Harrington, Time Harmonic Electromagnetic Fields, McGraw Hill., 1961 & 2001.
J. A. Kong Electromagnetic Wave Theory, John Wiley & Sons, 1990
8. 강의진도계획
Tentative Course Schedule (Subject to Change):
Lecture 1
1.1 Introduction
1.2 Maxwell's Equation
1.3 Constitutive Parameters and Relations
Lecture 2
Electromagnetic material properties
(permittivity, permeability, conductivity)
Lecture 3
Linear, Homogeneous, isotropic, and Non-dispersive medium
Lecture 4
Anisotropic and Uniaxial Media
Lecture 5
Wave equation and solution
3.1 Introduction
3.2 Time Varying Electromagnetic Fields
3.3 Time Harmonic Electromagnetic Fields
Lecture 6
3.4.1 Solution of wave Equation (Rectangular Coordinate system)
Lecture 7
3.4.1 Solution of wave Equation (Cylindrical Coordinate system)
Lecture 8
3.4.3 Solution of wave Equation (Spherical Coordinate system)
Lecture 9
6.1 Introduction
6.2 The Vector Potential A
6.3 The Vector Potential F
Lecture 10
6.4 The Vector Potential A and F
6.5.1 Transverse EM Fields: Source Free Region
Lecture 11
6.5.2 Transverse EM Fields: Source Free Region
6.5.3 Transverse EM Fields: Source Free Region
Lecture 12
Solution of the inhomogeneous vector potential wave equation
Lecture 13
Far Field Radiation
Lecture 14 Midterm
Lecture 15
Radiation and Scattering Equation
Lecture 16
Radiation and Scattering Equation
Lecture 17
Internal Seminar (subject to change)
Lecture 18
Oblique incidence lossless media
Lecture 19
Oblique incidence lossy media
Lecture 20
Multiple interface reflection
Lecture 21
Multiple layer Reflection
Lecture 22
Duality Theorem
Uniqueness Theorem
Lecture 23
Image Theory
Reciprocity Theorem
Reaction Theorem
Lecture 24
7.7 Volume equivalence theorem
7.8 Huygen’s principle
Lecture 25
Green's Function (Scalar)
Lecture 26
Green's Function( Helmoltz)
Lecture 27
Green's Function (dyadic)
Lecture 28 Metamaterials
Lecture 29
Metamaterials
Lecture 30 TBD
9. 수업운영
We will combine Offline/Online for this semester due to travels but I will ensure your learning experience is not affected! Please ask for any improvements ANY TIME!
10. 학습법 소개 및 기타사항
Course Material: Maxwell’s Equation, circuit field relations, time harmonic electromagnetic fields, material properties, wave equation and solution, reflection and transmission of multiple interfaces, auxiliary vector potential, construction of solution, radiation and scattering equations, electromagnetic theorems and principles, Scattering, Green’s Function
11. 장애학생에 대한 학습지원 사항
- 수강 관련: 문자 통역(청각), 교과목 보조(발달), 노트필기(전 유형) 등
- 시험 관련: 시험시간 연장(필요시 전 유형), 시험지 확대 복사(시각) 등
- 기타 추가 요청사항 발생 시 장애학생지원센터(279-2434)로 요청