# GAZI UNIVERSITY INFORMATION PACKAGE - 2019 ACADEMIC YEAR

COURSE DESCRIPTION
ELECTROMAGNETIC FIELD THEORY/EE 215
 Course Title: ELECTROMAGNETIC FIELD THEORY Credits 3 ECTS 4 Course Semester 3 Type of The Course Compulsory
COURSE INFORMATION
-- (CATALOG CONTENT)
-- (TEXTBOOK)
-- (SUPPLEMENTARY TEXTBOOK)
-- (PREREQUISITES AND CO-REQUISITES)
-- LANGUAGE OF INSTRUCTION
Turkish
-- COURSE OBJECTIVES
-- COURSE LEARNING OUTCOMES
Gradient, divergance, curl and line, surface and volume integration, Gauss and Stokes theorems are taught.
Electrical forces among the charge distributions are learnt.
Rectangular, cylindrical and spherical charged geometries are analyzed.
Boundary value problems are solved.
Poisson and Laplace equations are learnt.
Electrical potential is known.
Magnetic force, magnetic Gauss law and their applications are learnt.
Magnetic field strenght is learnt.
Magnetic classification of the materials and ferromagnetism, hysterisis behavior, Boundary conditions in magnetic field and magnetic dipol moment are

-- MODE OF DELIVERY
Face to face, Question & Reply
 --WEEKLY SCHEDULE 1. Week Introduction to electromagnetics, field concept, vectoral analysis, scalar and vectoral fields 2. Week Rectangular, cylindrical and spherical coordinate systems, lenght, surface and volume elements 3. Week Line, surface and volume integrals, gradient, divergents and rotational processes 4. Week Divergence and Stokes theorems, Laplace operators, Green theorem, classification of the fields 5. Week Static electric fields, Coulomb's Law, electric field strenght, Charge distributions 6. Week electric flux, electric flux density, Gauss's Law, Electrical potential, Electrical dipol 7. Week Conductors in electric field, boundary conditions, Insulators in electric field, Stored energy in electrical field 8. Week Interim Exam,Boundary value problems 9. Week Capacitors and capacitance, Poisson and Laplace Equations 10. Week Image Charge Method, Stationary electric currents, current density, conductive and transport currents 11. Week Resistance concept, continuity equation, Joule's Law, Introduction to Static magnetic field, Biot-Savard's Law and their applications 12. Week Ampere's Law and its applications, magnetic force, magnetic torque and its applications 13. Week Magnetic Gauss's Law and its application, magnetic vector potential and its applications, magnetic field strenght, magnetic classification of materia 14. Week Hysterysis behavior, boundary conditions in magnetic field, magnetic dipol moment, Introduction to magnetic circuits, applications of magnetic circuit 15. Week 16. Week
-- TEACHING and LEARNING METHODS
-- ASSESSMENT CRITERIA
 Quantity Total Weighting (%) Midterm Exams 1 60 Assignment 0 0 Application 0 0 Projects 0 0 Practice 0 0 Quiz 0 0 Percent of In-term Studies 60 Percentage of Final Exam to Total Score 40