At the end of this course, the students; 1) Gain problem solving ability. 2) Determine the field vectors caused by charge and current distributions in electrostatic and magnetostatic problems. 3) Know and use the laws constituting bases for the Maxwell's Laws in their differential and integral forms. 4) Calculate the capacitance and inductance values for given geometries. 5) Comment on some natural phenomena based on theoretical knowledge.
MODE OF DELIVERY
Face to face
PRE-REQUISITES OF THE COURSE
Yes(EEM226)
RECOMMENDED OPTIONAL PROGRAMME COMPONENT
MAT222
COURSE DEFINITION
Summary of vector algebra, coordinate systems and coordinate transformations. Time varying electric and magnetic fields, Faraday?s law of induction, transformers, sinusoidally time-varying (harmonic) electromagnetic (EM) fields, Maxwell?s equations, second order differential equations, EM wave equation, homogenous plane EM waves, Doppler effect, perfect or good conducting and insulating materials, EM polarization, power density, average power, EM waves near the boundaries, angles of incidence, transmission lines (TL), generalized TL equations, finite lines, reflection, standing waves
COURSE CONTENTS
WEEK
TOPICS
1st Week
Faraday law, quasi-static fields
2nd Week
Time varying fields, displacement current, potential functions
Waves in time and frequency domain, sinusoidal waves
5th Week
Plane waves
6th Week
Plane waves in lossy media, polarization
7th Week
Phase and group velocities, Poynting theorem
8th Week
Instantaneous and average power densities
9th Week
Perpendicular incidence to a planar free space - conducting boundary
10th Week
Perpendicular incidence to a planar dielectric - dielectric boundary
11th Week
Oblique incidence to a planar free space - conducting boundary
12th Week
Oblique incidence to a planar dielectric - dielectric boundary
13th Week
Introduction to transmission lines, transmission line equations, infinite line, reflection coefficient
14th Week
Impedance, standing wave ratio
RECOMENDED OR REQUIRED READING
1. Cheng, D.K. (1993) Fundamentals of Engineering Electromagnetics, Addison Wesley.
PLANNED LEARNING ACTIVITIES AND TEACHING METHODS
Face-to-face, demonstration of wave mechanism using musical instruments, visualization by projection of images and videos, discussion and review hours, homeworks and projects
ASSESSMENT METHODS AND CRITERIA
Quantity
Percentage(%)
Mid-term
1
30
Assignment
2
10
Quiz
2
20
Total(%)
60
Contribution of In-term Studies to Overall Grade(%)
60
Contribution of Final Examination to Overall Grade(%)
40
Total(%)
100
ECTS WORKLOAD
Activities
Number
Hours
Workload
Midterm exam
1
2
2
Preparation for Quiz
2
4
8
Individual or group work
14
5
70
Preparation for Final exam
1
17
17
Course hours
14
4
56
Preparation for Midterm exam
1
14
14
Laboratory (including preparation)
0
0
0
Final exam
1
2
2
Homework
2
6
12
Total Workload
181
Total Workload / 30
6,03
ECTS Credits of the Course
6
LANGUAGE OF INSTRUCTION
English
WORK PLACEMENT(S)
No
KEY LEARNING OUTCOMES (KLO) / MATRIX OF LEARNING OUTCOMES (LO)