1	Course Title:	ELECTROMAGNETIC THEORY
2	Course Code:	FZK4009
3	Type of Course:	Compulsory
4	Level of Course:	First Cycle
5	Year of Study:	4
6	Semester:	7
7	ECTS Credits Allocated:	6
8	Theoretical (hour/week):	5
9	Practice (hour/week) :	0
10	Laboratory (hour/week) :	0
11	Prerequisites:	There is no course prerequisite
12	Recommended optional programme components:	None
13	Language:	Turkish
14	Mode of Delivery:	Face to face
15	Course Coordinator:	Doç. Dr. SEZER ERDEM
16	Course Lecturers:	Yok
17	Contactinformation of the Course Coordinator:	serdem@uludag.edu.tr, 0 224 2941772, Bursa Uludağ Üniversitesi, Fen-Edebiyat Fakültesi, Fizik Bölümü, Görükle Kampusü, 16059 Nilüfer/Bursa.
18	Website:
19	Objective of the Course:	The classical electromagnetism is the basic background of many current physical research area. So the aim of this course the teach the classical electromagnetism to the physics students with the detailed mathematical background in undergraduate level.
20	Contribution of the Course to Professional Development	known basic electromagnetic theory.

21

Learning Outcomes:

1 Learn the use of mathematical expressions required for the electromagnetic theory course.; 2 Performs different applications related to electrostatic force, field, potential and energy.; 3 Learn the concepts of electrostatics and magnetostatics in matter and apply them to problems.; 4 Solve the problems related to different applications of magnetic force, field, energy and magnetic dipole moment created by steady currents.; 5 Learn the concepts of mutual inductance, self-inductance and Maxwell's equations.; 6 Learn the electric field, magnetic field, Poynting vectors of an electromagnetic wave and the relationship between them.;

22	Course Content:

Week	Theoretical	Practical
1	Coulomb’s law, electrostatic field and potential.
2	Gauss’s law and applications.
3	Laplce’s and Poisson’s equations, electrostatic field energy.
4	Steady currents, Biot-Savart’s law and applications
5	Magnetostatic field laws, Ampere’s law.
6	Vector potential, gauge invariance, magnetic dipole moment, Lorentz force. Midterm exam I+repeating courses
7	Electrostatics and magnetostatics in materials.
8	Electromagnetic induction, Faraday’s law, gauge invariance, magnetic field energy.
9	Displacement current, Maxwell’s equations, electromagnetic waves, Poynting’s theorem.
10	Lorentz transformations, special relativity theory.
11	Geometry of space-time, relativistic mechanics.
12	Covariant form of the electrodynamics.
13	Electromagnetic field transformation relations. Midterm exam II+repeating courses
14	Electromagnetic radiation.

23	Textbooks, References and/or Other Materials:	1.C.A. Coulson, T.J.M. Boyd (1979), “Electricity”, Longman Mathematical Texts. 2.J.R. Reitz, F.J. Milford (1969), “Foundations of Electromagnetic Theory”, Addision-Wesley Pub. Co. 3.J.D. Jackson (1978), “Classical Electrodynamics”, John Wiley&Sons Inc.
24	Assesment

TERM LEARNING ACTIVITIES	NUMBER	PERCENT
Midterm Exam	1	40
Quiz	0	0
Homeworks, Performances	0	0
Final Exam	1	60
Total	2	100
Contribution of Term (Year) Learning Activities to Success Grade		40
Contribution of Final Exam to Success Grade		60
Total		100
Measurement and Evaluation Techniques Used in the Course	The system of relative evaluation is applied.
Information

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ECTS / WORK LOAD TABLE

Activites	NUMBER	TIME [Hour]	Total WorkLoad [Hour]
Theoretical	14	5	70
Practicals/Labs	0	0	0
Self Study and Preparation	12	5	60
Homeworks, Performances	0	0	0
Projects	0	0	0
Field Studies	0	0	0
Midtermexams	1	2	2
Others	12	4	48
Final Exams	1	2	2
Total WorkLoad			182
Total workload/ 30 hr			6,07
ECTS Credit of the Course			6

26	CONTRIBUTION OF LEARNING OUTCOMES TO PROGRAMME QUALIFICATIONS
PQ1 PQ2 PQ3 PQ4 PQ5 PQ6 PQ7 PQ8 PQ9 PQ10 PQ11 PQ12 LO1 5 5 5 0 0 5 5 0 5 5 0 0 LO2 5 5 5 0 0 5 5 0 5 5 0 0 LO3 5 5 5 0 0 5 5 0 5 5 0 0 LO4 5 5 5 0 0 5 5 0 5 5 0 0 LO5 5 5 5 0 0 5 3 0 3 4 0 0 LO6 4 4 4 0 0 4 3 0 3 3 0 0

LO: Learning Objectives

PQ: Program Qualifications

Contribution Level:

1 Very Low

2 Low

3 Medium

4 High

5 Very High