Course Information
SemesterCourse Unit CodeCourse Unit TitleT+P+LCreditNumber of ECTS CreditsLast Updated Date
5EEM331Electromagnetic Wave Theory3+0+03517.09.2023

 
Course Details
Language of Instruction Turkish
Level of Course Unit Bachelor's Degree
Department / Program Electrical-Electronics Engineering
Type of Program Formal Education
Type of Course Unit Compulsory
Course Delivery Method Face To Face
Objectives of the Course The goal of this course is to introduce the working knowledge of
electromagnetic wave theory .
Course Content Transmission lines. Maxwell equations. Boundary conditions theorem. Potential functions. Plane waves. Guided waves, waveguides. Resonators. Antennas.
Course Methods and Techniques
Prerequisites and co-requisities None
Course Coordinator Prof.Dr. Prof. Dr.
Name of Lecturers Prof.Dr. Namık Yener
Assistants None
Work Placement(s) No

Recommended or Required Reading
Resources David K Cheng, Fundamentals of Engineering Electromagnetics, Addison–Wesley, 1993
J. A.Kong, Electromagnetic Wave Theory, EMW Publishing, Cambridge, MA, 2005
Course Notes Lecture notes, presentation
Documents https://drive.google.com/drive/folders/1kVJk7kEdRP_bP7WbFT1p67mlvNvuIGEa

Course Category
Mathematics and Basic Sciences %80
Engineering %15
Engineering Design %5
Social Sciences %0
Education %0
Science %0
Health %0
Field %0

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 1 % 20
Assignment 1 % 20
Final examination 1 % 60
Total
3
% 100

 
ECTS Allocated Based on Student Workload
Activities Quantity Duration Total Work Load
Course Duration 14 3 42
Hours for off-the-c.r.stud 17 6 102
Mid-terms 1 3 3
Final examination 1 3 3
Total Work Load   Number of ECTS Credits 5 150

 
Course Learning Outcomes: Upon the successful completion of this course, students will be able to:
NoLearning Outcomes
1 Grasps the wave cıoncept in electromagnetics.
2 Can analyze plane waves.
3 Can compute guided waves
4 Can design cavity resonators.
5 Can make antenna computations.

 
Weekly Detailed Course Contents
WeekTopicsStudy MaterialsMaterials
1 Example of wave systems; transmission lines
2 Smith chart
3 Maxwell equations
4 Boundary conditions theorem
5 Potential functions
6 Power flow for monochromatic waves in simple medium
7 Plane waves
8 Plane waves
9 Fields in waveguides
10 Fields in waveguides
11 Guided waves, waveguide structures
12 Resonators
13 Antennas
14 Sample problems

 
Contribution of Learning Outcomes to Programme Outcomes
P1 P2 P3 P4 P5 P6 P7 P8 P9 P10 P11 P12 P99
All 5 5 5 1 4 2 2 2 2 4 2 2
C1
C2
C3
C4
C5

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  https://obs.gedik.edu.tr/oibs/bologna/progCourseDetails.aspx?curCourse=206247&curProgID=92&lang=en