Course Information

Semester	Course Unit Code	Course Unit Title	T+P+L	Credit	Number of ECTS Credits
4	EEE 264	ELECTROMAGNETIC THEORY	4+0+0	4	6

Course Details

Language of Instruction	English
Level of Course Unit	Bachelor's Degree
Department / Program	ELECTRICAL-ELECTRONICS E.
Mode of Delivery	Face to Face
Type of Course Unit	Compulsory
Objectives of the Course	Students will be able to use vector calculus efficiently to solve electromagnetic problems, and comprehend and understand the electrostatic, steady current, magnetostatic, and electromagnetic induction phenomena, and finally be able to solve static electric field Students will comprehend the electrostatic phenomena and be able to solve problems related to these phenomena
Course Content	Review of vector analysis. Electrostatic fields in vacuum and material bodies. Dielectric properties of materials. Electrostatic energy and forces. Steady electric current and conductors. Static magnetic fields in vacuum and in materials. Magnetic energy and forces. Quasistatic fields and electromagnetic induction.
Course Methods and Techniques	2 Midterm Exams and 1 Final Exam
Prerequisites and co-requisities	( MATH152 ) and ( EP104 )
Course Coordinator	Prof.Dr. Uğur Cem Hasar https://akbis.gantep.edu.tr/detay/?A_ID=182085_prof-dr_ugur-cem-hasar uchasar@gantep.edu.tr
Name of Lecturers	Prof.Dr. UĞUR CEM HASAR
Assistants	Asist Prof.Dr. Musa Bute https://akbis.gantep.edu.tr/detay/?A_ID=183330_dr-ogr-uyesi_musa-bute mbute@gantep.edu.tr
Work Placement(s)	No

Recommended or Required Reading

Resources	Elements Of Electromagnetics
	1. M. Sadiku, Elements of Electromagnetics, 3rd Edition, Oxford Univ. Press 2. S.V. Marshall, R. E. DuBroff, Electromagnetic Concepts and Applications, 4th Ed., Prentice Hall 3. J. D. Krauss, Electromagnetics, 4th Edition, McGraw Hill 4. P. Lorrain and D.Corson, Electromagnetic Fields and Waves, 2nd Edition, Freeman

Course Category

Mathematics and Basic Sciences	%40
Engineering	%40
Engineering Design	%20

Planned Learning Activities and Teaching Methods

Activities are given in detail in the section of "Assessment Methods and Criteria" and "Workload Calculation"

Assessment Methods and Criteria

In-Term Studies	Quantity	Percentage
Mid-terms	2	% 60
Final examination	1	% 40
Total	3	% 100

ECTS Allocated Based on Student Workload

Activities	Quantity	Duration	Total Work Load
Mid-terms	2	60	120
Final examination	1	60	60
Total Work Load			Number of ECTS Credits 6 180

Course Learning Outcomes: Upon the successful completion of this course, students will be able to:

No	Learning Outcomes
1	Identifying, defining, formulating and solving Electrical and Electronics Engineering problems
2	Learning electromagnetic equations and applying them to problems

Weekly Detailed Course Contents

Week	Topics	Study Materials	Materials
1	Vector Analysis-1, vector addition and subtraction, vector and cross product, and orthogonal coordinate systems	-	Main Text Book
2	Vector Analysis-2, gradient of a scalar field, divergence of a vector field, and divergence theorem	Notes of Previous Lectures	Main Text book
3	Vector Analysis-3, curl of a vector field, Stokes’s theorem, null identities, and Helmholtz’s theorem	Notes of Previous Lectures	Main Text Book
4	Fundamentals postulates and Coulomb’s law	Notes of Previous Lectures	Main Text Book
5	Gauss’s law and applications and Electric potential	Notes of Previous Lectures	Main Text Book
6	Material media in static electric field, and electric flux density and dielectric constant	Notes of Previous Lectures	Main Text Book
7	Boundary conditions for electrostatic fields, and capacitances and capacitors	Notes of Previous Lectures	Main Text Book
8	Electrostatic energy and forces and solution of electrostatic boundary-value problems, and Poisson’s and Laplace’s equations	Notes of Previous Lectures	Main Text Book
9	Boundary-value problems in Cartesian (cylindrical and spherical) coordinates, and method of images	Notes of Previous Lectures	Main Text Book
10	Steady electric currents	Notes of Previous Lectures	Main Text Book
11	Fundamental postulates, vector magnetic potential, and Biot-Savart law and applications	Notes of Previous Lectures	Main Text Book
12	The magnetic dipole, magnetization and equivalent current densities, magnetic field intensity and relative permeability, and behavior of magnetic materials	Notes of Previous Lectures	Main Text Book
13	Boundary conditions for magnetostatic fields, and inductances and inductors	Notes of Previous Lectures	Main Text Book
14	Magnetic energy, and magnetic forces and torques	Notes of Previous Lectures	Main Text Book

Contribution of Learning Outcomes to Programme Outcomes

	P1	P2	P3	P4	P5	P6	P7	P8	P9	P10	P11
All	4	4	4	3	3	2	2	3	3	3	3
C1	4	4	4	3	3	2	2	3	3	3	3
C2	4	4	4	3	3	2	2	3	3	3	3

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