This
note covers the following topics: Electric
charge, Electric fields, Dipoles, Continuous charge distributions, Coordinate
systems, Gradients, Line and surface integrals, electric
potential, E from V, equipotentials, Gauss's law, Conductors and capacitors,
Magnetic fields: Creating magnetic fields - Biot-Savart, Ampere's Law, Inductors
and magnetic energy, RL circuits, RC and RL circuits, LC and undriven LRC
circuits, Driven LRC circuits, Maxwell's equations, EM radiation and energy
flow, EM radiation.
The topics covered in this notes
include : Vector Algebra, Electric Force & Electric Field, Electric Flux and
Gauss’ Law, Electric Potential, Capacitance and DC Circuits, Magnetic Force,
Magnetic Field, Faraday’s Law of Induction, Inductance, AC Circuits,
Displacement Current and Maxwell’s Equations.
Author(s): Dr. Jason Chun Shing Pun, Department
of Physics, The University of Hong Kong
This book reports on recent progress in emerging technologies, modern
characterization methods, theory and applications of advanced magnetic
materials. It covers broad spectrum of topics: technology and characterization
of rapidly quenched nanowires for information technology, surface reconstruction
of magnetite for spintronics, synthesis of multiferroic composites for novel
biomedical applications, optimization of electroplated inductors for
microelectronic devices,fabrication and properties of hexagonal ferrite films
for microwave communication, theory of magnetism of Fe-Al alloys, and two
advanced analytical approaches for modeling of magnetic materials using Everett
integral and the inverse problem approach.
This
note explains the following topics: Vectors and Fields, Electric Charge,
Electric field, Gauss Theorem, Electrostatic potential, Properties of a
conductor in electrostatics, Capacitance, Current and Circuits.
This lecture note covers the following topics: Electrostatics,
Quantisation of charge and Coulombs law, Electric field and potential,
Dielectric properties of matter, Magnetism, Steady Current, Alternative
current.
This lecture note explains
the following topics: Electric Charge and Force, Electric Field and Simple
Distributions of Charge, Complex Distributions of Electric Charge, The Motion of
Electric Charge, Potential and the Storage of Energy, Capacitors, Electric
Current, Resistance to Electric Current, Magnetic Force, Magnetic Force between
Currents, Magnetic Dipole Moment, Magnetic Induction, Reflection and
Refraction.
This note gives an
introduction on quantum mechanical view on magnetism in real materials,
especially, consisting of transition metal elements and their compounds, and the
physical principles for the applications of magnetic materials as magnetic
sensors and memory devices.
This book
explains the following topics: Electricity and the Atom, The Nucleus, Circuits,
Fields of Force, Electromagnetism, A Capacitance and Inductance.
This lecture note covers the
following topics: Coulomb's law, superposition, energy of a system of charges,
Basic field concept, flux, Gauss's law, Fields and potentials around conductors,
the electrostatic uniqueness theorem,RC circuits, Thevenin equivalence, Forces
and fields in special relativity. Equivalence of the electric and magnetic
forces, RL circuits, undriven RLC circuits, Wave equation and radiation,Magnetic
fields and materials.
In this book, the author give an account of some recent electrical
researches, experimental as well as theoretical, in the hope that it may assist
students to gain some acquaintance with the recent progress of Electricity and
yet retain Maxwell's Treatise as the source from which they learn the great
principles of the science.
Topics
covered include: Electric and magnetic field and potential; introduction to
special relativity; Maxwell's equations, in both differential and integral form;
and properties of dielectrics and magnetic materials.
This
note covers the following topics: Electric
charge, Electric fields, Dipoles, Continuous charge distributions, Coordinate
systems, Gradients, Line and surface integrals, electric
potential, E from V, equipotentials, Gauss's law, Conductors and capacitors,
Magnetic fields: Creating magnetic fields - Biot-Savart, Ampere's Law, Inductors
and magnetic energy, RL circuits, RC and RL circuits, LC and undriven LRC
circuits, Driven LRC circuits, Maxwell's equations, EM radiation and energy
flow, EM radiation.