Introduction To Electromagnetic Fields
Electrical Engineering
Faculty of Engineering
First Cycle (Bachelor's Degree)
| Course Unit Title | Course Unit Code | Type of Course Unit | Level of Course Unit | Year of Study | Semester | ECTS Credits |
|---|---|---|---|---|---|---|
| Introduction To Electromagnetic Fields | MEL206 | Compulsory | Bachelor's degree | 2 | Spring | 4 |
Name of Lecturer(s)
Prof. Dr. Gonca ÇAKIR
Prof. Dr. Sibel ÇİMEN
Prof. Dr. Doğan DİBEKÇİ
Prof. Dr. Namık YENER
Associate Prof. Dr. Hasbi İSMAİLOĞLU
Associate Prof. Dr. Ersoy KELEBEKLER
Learning Outcomes of the Course Unit
1) Interpreting field effects for various charge and current distributions
2) Defining sources of electric and magnetic fields and coupling between these fields.
3) Defining boundary conditions and relationships between fields in different material media
4) Interpreting the electric potential and its relationship with the electromagnetic fields
5) Obtaining the Maxwell’s Equations
Program Competencies-Learning Outcomes Relation
| Program Competencies | |||||||||||
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | ||
| Learning Outcomes | |||||||||||
| 1 | Middle | Middle | Low | No relation | No relation | No relation | No relation | No relation | Low | No relation | |
| 2 | Middle | Low | Low | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 3 | Middle | Middle | Middle | No relation | No relation | No relation | No relation | No relation | Low | No relation | |
| 4 | Low | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 5 | Middle | Middle | Low | No relation | No relation | No relation | No relation | No relation | Low | No relation | |
Mode of Delivery
Face to Face
Prerequisites and Co-Requisites
None
Recommended Optional Programme Components
physics
Course Contents
Vector analysis, static electric field, Coulomb law, Gauss law, Electric potential, Conductors and dielectrics in static field, boundary conditions for electrostatic fields, capacitance and capacitors, electrostatic energy and forces, Poisson’s and Laplace’s equations, static magnetic fields, Biot-Savart’s law and applications, Ampere’s force law, magnetic vector potential, Magnetic materials, boundary conditions for magnetic fields, energy in a magnetic field, time-varying electromagnetic fields, Maxwell’s equations, Poynting theorem, time-harmonic fields, applications of electromagnetic fields.
Recommended or Required Reading
Planned Learning Activities and Teaching Methods
Assessment Methods and Criteria
Contribution of Midterm Examination to Course Grade |
40% |
|---|---|
Contribution of Final Examination to Course Grade |
60% |
Total |
100% |
Language of Instruction
Turkish
Work Placement(s)
Not Required