- Course Description
Vector Algebra, Orthogonal Coordinate Systems, Gradient, Divergence, Divergence Theorem, Curl, Stokes's Theorem, Helmholtz Theorem.
- STATIC ELECTRIC FIELDS
Coulomb's Law, Electric Field Intensity, Gauss Law, Electric Flux Density in Free Space, Electrostatic Potential, Work Done,Electric Dipole.
- ELECTRIC FIELDS IN MATERIAL SPACE
Conductors. Polarization and Dielectrics, Equivalent Polarizarion Volume and Surface Charge Densities, Suscebtibility and Dielectric Constant, Isotropic, Linear and Homogeneous Dielectrics, Boundary Conditions, Laplace and Poisson Equations, Capacitance and Capacitors, Energy Density, Potential Energy. Steady Currents, Current Density, Conductivity of Conductors,Ohm's Law and Resiarance. Power Dissipation and Joule's Law. Conservation of Charge, Continuity Equation, Kirchhoff's Current Law, Boundary Conditions for Steady Current Density, Leakage Resistance of a Lossy Dielectric Between to Conductors, Calculation of Resistance from the Capacitance.
Introduction, Biot-savart Law, Forces due to Magnetic Fields, Ampere's Circuidal Law, Magnetic Flux Density, Magnetic Vector Potential. Magnetization and Equivalent Current Densities, Magnetic Field Intensity, Hysterisis Loop, Boundary Conditions for B and H, Inductance and Inductors, Magnetic Energy.