Welcome, Guest. Return to Faculty. To teach the fundamentals of electromagnetic field theory 2. To teach electrostatic fields 3. To teach magnetostatic fields 4. To teach time varying fields Course Description Vector analysis, vectorial differential operators, static electric field, electric potential, electrostatic field analysis in conductors and dielectric media, electrostatic energy, electrostatic boundary conditions, magnetostatic field, vector potential, magnetic circuits, magnetic energy, magnetostatik boundary conditions, quasi-static fields, time varying fields and Maxwell equations Course Outcomes Students who pass the course will be able to: I.
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Name of Lecturer s Assist. Electrostatiscs: electric field, Gauss law, electric potential, work and energy, conductors. Potential calculation techniques: Laplace equation, separation of variables method, multipole expansion.
Basic Integral Theorems. Discrete and continuous charge distributions. Gauss Law. Boundary conditions. Energy of point charge and continuous charge distributions. Induced charges. Boundary conditions and uniqueness theorems. Separation of variables method. Monopol and dipole terms. Electric field of dipole. Elektromanyetik Teori, D. Elektromanyetik Teori, G. Pollack ve D. The aim of this course is to make the students to be able to identify the concepts necessary for electromagnetic theory, by using these concepts to derive physical quantities of magnetic systems and to have the ability of using calculation techniques available in this subject.
Identifying and using the mathematical tools necessary for the classical electromagnetic theory. Becoming familiar with the methods necessary for calculating electric potential in various systems. Describing the behavior of polarized objects by using physical concepts. Vector analysis and coordinate systems. Electric field and Coulomb law. Electric potential, Poisson and Laplace equations. Concepts of work and energy in electrostatics. Introduction to potential calculation techniques.
Multipole expansion. Zengin, Gazi Kitapevi, Ankara, Term or Year Learning Activities.
Elektromanyetik Teori - David J. GRIFFITHS Ders Notu
Information on the Instituion. Degree Programs. General Information For Stundents. No Learning Outcomes 1 Work with vector algebra and vector differential operators 2 Calculate electrostatic field, force and potential 3 Calculate the electrostatic fields in conductors and dielectric materials 4 Calculate magnetostatic field and force 5 Solve the problems related to magnetostatic fields in magnetic materials 6 Solve the problems related to electromagnetic fields using Faraday and Ampere Laws.
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