Course Name Code Semester T+U Hours Credit ECTS
Advaced Electromagnetic Theory FIZ 504 0 3 + 0 3 6
Precondition Courses
Recommended Optional Courses
Course Language Turkish
Course Level yuksek_lisans
Course Type Compulsory
Course Coordinator Prof.Dr. HÜSEYİN MURAT TÜTÜNCÜ
Course Lecturers Prof.Dr. HÜSEYİN MURAT TÜTÜNCÜ,
Course Assistants
Course Category
Course Objective Understanding electrostatic theory and practising to problems.
Course Content Electrostatic and boundary value problems at electrostatic, Multipoles, Electrostatic in macroscopic media, dielectrics, Magnetostatic, Field changing with time, Maxwell Equations.
# Course Learning Outcomes Teaching Methods Assessment Methods
1 Identifies concept of electric field in conductors and insulators and proposes solutions to problems. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
2 Applies Gauss law of electrostatic to charged objects. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
3 Interprets electrostatic potential and potential energy of charged objects. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
4 Knows solutions of electrostatic boundary value problems and compares the methods. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
5 Analyses 2-dimensional potential problem. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
6 Investigates solution of Laplace equation at spherical coordinates. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
7 Analyses and solves Green functions at cylindirical coordinates. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
8 Exemplifies electrostatic and multipole expansion. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
9 Finds a solution boundary value problems at dielectric media. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
10 Analyses Lorentz force and Biot-Savart law at magnetic media. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
11 Exemplifies Maxwell equations. Lecture, Question-Answer, Discussion, Drilland Practice, Self Study, Problem Solving, Testing, Homework, Performance Task,
Week Course Topics Preliminary Preparation
1 Introduction to Electrostatic: Gauss law, superfical charge and bipolar distributions, Poisson and Laplace equations, Gren Theory.
2 Uniqueness solution with drichlet or Neumann boundary conditions, solving electrostatic boundary value problems with Gren function.
3 Electrostatic potantial energy and anergy densiy.
4 Boundary value problems in electrostatic, Screen Charge Theory, periodical charge against a conductor sphere, conductor sphere at regular electric field with Screen Charges Method.
5 Semisphere are keep at apart potantial perpendicular function and expansions two dimensional potantial problem, summation of Fourier serial.
6 Laplace equation in spherical coordinates, Legendre equation,
7 Boundary value in cylindrical coordinates, solving potantial problems with Green functions expansion in cylindrical coordinates.
8 Multipole expansion, Electrostatic in material media, boundary value problems with dielectric.
9 Midterm exam
10 Molecular polarizability, Electrical susceptibility, Electrostatic energy in dielectric media.
11 Biot-Savart law, Amper law, Vector potential magnetic fields of a settled current distribution.
12 Magnetic moment, Macroscobic equations, regular magnetized sphere , magnetic screening spherical shell from pervious matter in a regular field.
13 Fields changing with time, Faraday’s induction law, Maxwell’s substitution current.
14 Maxwell equations, Gauge transformations, Poynting Theory, Conservation laws for macroscobic medium, Magnetic monopole problem.
Resources
Course Notes
Course Resources
Order Program Outcomes Level of Contribution
1 2 3 4 5
1 Using the knowledge of undergraduate and graduate education in postgraduate level. X
2 To be able to improve themselves by following the innovations in the field of Physics which are important in the development of science and technology. X
3 To be able to make literature search, presentation, experimental setup preparation, application and explication of results. X
4 To be able to join interdisciplinary and multidisciplinary team works.
5 Sharing their concepts in seminar, symposium, conference etc. by using the skills of self-study.
6 Having the scientific and vocational wafer and defending this apprehension in every medium.
Evaluation System
Semester Studies Contribution Rate
1. Ara Sınav 70
1. Kısa Sınav 15
2. Kısa Sınav 15
Total 100
1. Yıl İçinin Başarıya 50
1. Final 50
Total 100
ECTS - Workload Activity Quantity Time (Hours) Total Workload (Hours)
Course Duration (Including the exam week: 16x Total course hours) 16 3 48
Hours for off-the-classroom study (Pre-study, practice) 16 3 48
Mid-terms 1 5 5
Final examination 1 10 10
Quiz 2 20 40
Total Workload 151
Total Workload / 25 (Hours) 6.04
dersAKTSKredisi 6