Description of Individual Course Units
 Course Unit Code Course Unit Title Type of Course Unit Year of Study Semester Number of ECTS Credits 160103003104 THEORY OF ELECTROMAGNETICS - I Compulsory 2 3 5
Level of Course Unit
First Cycle
Objectives of the Course
Investigation of static electromagnetic field using mathematical methods. Instruction of Fundamentals, Laws and Methods of Electromagnetic Field Theory.
Name of Lecturer(s)
Dr. Öğr. Üyesi Ramazan Topkaya
Learning Outcomes
 1 Introduction, science history, basic concepts 2 Vektör analiz bilgilerinin alan teorisi dersinde önemini bilir. 3 Elektriksel alan hesaplama methodlarını bilir ve kullanır. 4 The student will have enough information about behaviour of static electromagnetic field under different media. 5
Mode of Delivery
Daytime Class
Prerequisites and co-requisities
No
Recommended Optional Programme Components
No
Course Contents
Introduction, science history, basic concepts, Vector analysis, Electrostatic: Coulomb law, electrostatic field and field lines, charge density and its distribution, Electrostatic: electric flux and flux density, Gauss law and Gauss surfaces, Electrostatic: divergence, divergence of a vector field, its properties and divergence theorem, Electrostatic: work, energy and potential, Electrostatic: capacity and dielectric materials / polarization / relative permeability / capacitor / electric dipole/ Laplace equation, Magnetostatic: Current field and Biot-Savart law / Ampere law, Magnetostatic: Rotational, magnetic flux density (B) / vector magnetic potential, Stokes theory, Magnetostatic: Lorentz force, magnetic force, magnetic force density, inductive media and Static electromagnetic field, magnetic dipole and permanent magnet, magnetic materials, Magnetostatic: Inductance / Faraday law / Magnetic and Electric Circuits and their comparison, Electromagnetism: Maxwell equations, Faraday Induction
Weekly Detailed Course Contents
 Week Theoretical Practice Laboratory 1 :Introduction, science history, basic concepts 2 : Vector analysis 3 Coordinate systems, Line, Surface and Volume Integrals 4 Gradient, Divergence and Rtational 5 Gradyan, Diverjans ve Stokes Teoremleri Problem çözümlü katılım 6 Electrostatic, Coulomb Law, Electric Field 7 Electric Flux, Gauss Law and Rotational of electric Field 8 Conductors in Electric Fields and Steady Current Flow, Continuity Equation in Conductors, Ohms Law 9 Computation the Capacity of Capacitors, Electrical Energy Storage 10 Fields in Dielectric Materials, Polarization, Boundary Conditions in Electrostatics 11 Midterm Exam 12 Magnetostatics, Biot-Savarts Law, Magnetic Field Intensity Computation, Magnetic Flux Density 13 Amperes Law and Applications, Gauss Law for Magnetic Fields, Magnetic Vector Potential 14 Inductance, the Energy Storage in Coil, Magnetically Coupling, Magnetic Force 15 Lorentz Force, Magnetism, Permeability, Classification of Magnetic Materials 16 Final exam
Recommended or Required Reading
• Elektromagnetik Alan Teorisi, Bayrakçı H.E., Birsen Yayınevi 2000 • Elektromagnetik Teori, David J. Griffiths (Basri Ünal), Gazi Kitabevi, 2005 • Field and Wave Electromagnetics, Cheng D.K., Addison – Wesley Publ. 1983
Planned Learning Activities and Teaching Methods
Assessment Methods and Criteria
 Term (or Year) Learning Activities Quantity Weight Midterm Examination 1 40 Quiz 1 20 Attending Lectures 14 20 Homework 5 20 SUM 100 End Of Term (or Year) Learning Activities Quantity Weight Final Examination 1 100 SUM 100 Term (or Year) Learning Activities 40 End Of Term (or Year) Learning Activities 60 SUM 100
Language of Instruction
Turkish
Work Placement(s)
No