1 | Introduction to the course. History of electromagnetics. Basic concepts. Vector analysis. Review of partial derivatives. Integral calculus. |
2 | Cartesian, cylindrical, and spherical coordinate systems. Del operator. Gradient, divergence, curl operators. Product rules. Second derivatives. |
3 | Electrostatics: Electric field, electric force, Coulomb's Law for point charge and charge distribution sources. Boundary conditions for electric field. |
4 | Electrostatics: Electric potential for point charge and charge distributions. Laplace and Poisson's equations. Work done to move a charge. Boundary conditions for electric potential. |
5 | Electrostatics: Electric flux, electrostatic lines, Gauss's Law. Boundary conditions for displacement vector. |
6 | Electrostatics: Special Techniques. Laplace equations. Capacitor. Method of Images. |
7 | Magnetostatics: Lorentz Force Law. Magnetic fields, magnetic forces, Biot-Savart's Law. Steady current. Boundary conditions for magnetic field. |
8 | MIDTERM |
9 | Magnetostatics: Magnetic Flux. Vector potential. Circulation of magnetic field. Stoke's theorem. Boundary conditions of magnetic induction. Straight line currents. Ampère's Law. |
10 | Magnetostatics: Magnetic force. Current element. Work, power, energy. |
11 | Magnetostatics: Magnetization. Magnetic fields in matter. Diamagnets, Paramagnets, Ferromagnets, Ferrimagnets. Inductance. Torques, forces in magnetic dipoles. |
12 | Magnetostatics: Magnetic circuits. |
13 | Electromagnetics: Ohm's Law. Electromotive force. Motional emf. Faraday's Law. |
14 | Electromagnetics: Induced electric field. Electromagnetic induction. Maxwell's equations. Continuity equation. |