# GAZI UNIVERSITY INFORMATION PACKAGE - 2019 ACADEMIC YEAR

COURSE DESCRIPTION
ELECTROMAGNETIC FIELD THEORY/EE 215
 Course Title: ELECTROMAGNETIC FIELD THEORY Credits 3 ECTS 5 Semester 3 Compulsory/Elective Compulsory
COURSE INFO
-- LANGUAGE OF INSTRUCTION
Turkish
-- NAME OF LECTURER(S)
Prof. Dr. Erol KURT
-- WEB SITE(S) OF LECTURER(S)
http://websitem.gazi.edu.tr/site/ekurt
-- EMAIL(S) OF LECTURER(S)
ekurt@gazi.edu.tr
-- LEARNING OUTCOMES OF THE COURSE UNIT
Gradient, divergence, Curl processes, line, surface and volume integrals and their theorems are learnt.
Electrical forces among the charge distributions are calculated.
Rectangular, cylindrical and spherical coordinates are learnt.
Boundary value problems can be solved.
Poisson and Laplace Equalities are learnt.
Electrical potential is known.
Magnetic force, magnetic Gauss law and its applications are learnt.
Magnetic field strenght is learnt.
Magnetic classification of materials and ferromagnetism, Hysterisis behaviour, boundary conditions in magnetic field, magnetic dipol moment are learnt
-- MODE OF DELIVERY
Face to face
-- PREREQUISITES AND CO-REQUISITES
Physics 1-2
-- RECOMMENDED OPTIONAL PROGRAMME COMPONENTS
Physics 1-2, Mathematics 1-2
 --COURSE CONTENT 1. Week Intro to Electromagnetic Field Theory, Field Concept, Vectoral analysis, scalar and vector fields 2. Week Rectangular, cylindrical and spherical coordinate systems, Line, Surface, Volume differential elements 3. Week Line, Surface, Volume integrations, Gradient, divergence, Curl operators 4. Week Divergence and Stokes theorems in rectangular, cyclindrical and spherical coordinates, Laplace operators in in rectangular, cyclindrical and spherical 5. Week Static electric fields, Coulomb's law, electric field strenght, charge distribution 6. Week Electric flux, flux density, Gauss's Law, electrical potential, Electrical dipol 7. Week Conductors in electric field, boundary conditions, Dielectrics in electrical field, electrical energy. 8. Week Exam 9. Week Boundary value problems, capacitors, capacitance, Poisson and Laplace equalities. 10. Week Image charge method, Steady electric currents, current density, conduction and transmission currents 11. Week Resistance concept, continuity equation, Joule's law, Intro to static magnetic fields, Biot-Savard's law and its applications 12. Week Ampère's law and its applications, magnetic force, magnetic torque and its applications 13. Week Magnetic Gauss law and its applications, Magnetic vector potential and its applications, Magnetic field strenght 14. Week Magnetic classification of materials and ferromagnetism, Hysterisis behaviour, boundary conditions in magnetic field, magnetic dipol moment 15. Week Intro to magnetic circuits 16. Week Applications of magnetic circuits