This note covers the
following topics: Electrostatic energy calculations, Poisson equation and
Green's theorm, Green's functions for cartesian coordinates, Method of images,
Cylindrical and spherical geometries, Multipole analysis of charge
distributions, Dipoles and dielectrics, Magnetostatics, Maxwells equations,
Electromagnetic energy and force, Dynamic dielectric media and their effects,
Radiation from moving charges and Special Theory of Relativity.
This note explains the
following topics: Vectors and vector calculus, Multidimensional integration,
Dirac delta, Special functions, Overview of fields, Maxwell equations in free
space, The Wave, Electrostatics, Multipole expansion, Conductors, Laplace
equation in a semi-infinite stripe, Dielectrics, Magnetostatics, Energy in
magnetic field, Maxwell Equations.
This note explains the following topics: Introduction to the Theory of
Distributions, Differentiation of Distributions, Integration of Distributions,
The Laplace Operator and Green’s Function, Electrostatics, Boundary value
problems of electrostatics, Magnetism, Electromagnetic Waves and Harmonic plane
This set of lecture notes is designed to be used to teach graduate
students in classical electrodynamics. It covers the following topics in detail:
Mathematical Physics, Non Relativistic Electrodynamics and Relativistic
note is a one semester advanced note on Electrodynamics at the M.Sc.
Level. It will start by revising the behaviour of electric and magnetic fields,
in vacuum as well as matter, and casting it in the language of scalar and vector
lecture note covers the following topics: Introduction to
Electrostatics, Boundary-value Problems in Electrostatics, Multipoles,
Macroscopic Media, Dielectrics, Static and Stationary Magnetic
Fields,Maxwell's Equations, Plane Waves and Wave Propagation, Special Theory
of Relativity, Particle and Field Dynamics, Waveguides and Cavities.