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This page provides comprehensive notes on EM Theory
http://www.intel.com/education/highered/curriculum/packaging/eee498.htm
Lectures are in PowerPoint format.
Lecture 0 - Course Overview
Lecture 1 - Introduction to Electrical Engineering
Lecture 2 - Introduction to Electromagnetic Fields;
Maxwell’s Equations; Electromagnetic Fields in Materials; Phasor Concepts;
Electrostatics: Coulomb’s Law, Electric Field, Discrete and Continuous Charge Distributions; Electrostatic Potential
Lecture 3 - Electrostatics: Electrostatic Potential; Charge Dipole; Visualization of Electric Fields; Potentials; Gauss’s Law and Applications; Conductors and Conduction Current
Lecture 4 - Electrostatics: Electrostatic Shielding; Poisson’s and Laplace’s Equations; Capacitance; Dielectric Materials and Permittivity
Lecture 5 - Electrostatics: Dielectric Breakdown, Electrostatic Boundary Conditions, Electrostatic Potential Energy; Conduction Current and Ohm’s Law
Lecture 6 - Electromotive Force; Kirchoff’s Laws; Redistribution of Charge; Boundary Conditions for Steady Current Flow
Lecture 7 - Magnetostatics: Ampere’s Law Of Force; Magnetic Flux Density; Lorentz Force; Biot-savart Law; Applications Of Ampere’s Law In Integral Form; Vector Magnetic Potential; Magnetic Dipole; Magnetic Flux
Lecture 8 - Magnetostatics: Mutual And Self-inductance; Magnetic Fields In Material Media; Magnetostatic Boundary Conditions; Magnetic Forces And Torques
Lecture 9 - Faraday’s Law Of Electromagnetic Induction; Displacement Current; Complex Permittivity and Permeability
Lecture 10 - Uniform Plane Wave Solutions to Maxwell’s Equations
Lecture 11 - Electromagnetic Power Flow; Reflection And Transmission Of Normally and Obliquely Incident Plane Waves; Useful Theorems
Lecture 12 - Overview Of Circuit Theory;
Lumped Circuit Elements; Topology Of Circuits; Resistors; KCL and KVL; Resistors in Series and Parallel; Energy Storage Elements; First-Order Circuits
http://www.intel.com/education/highered/curriculum/packaging/eee498.htm
Lectures are in PowerPoint format.
Lecture 0 - Course Overview
Lecture 1 - Introduction to Electrical Engineering
Lecture 2 - Introduction to Electromagnetic Fields;
Maxwell’s Equations; Electromagnetic Fields in Materials; Phasor Concepts;
Electrostatics: Coulomb’s Law, Electric Field, Discrete and Continuous Charge Distributions; Electrostatic Potential
Lecture 3 - Electrostatics: Electrostatic Potential; Charge Dipole; Visualization of Electric Fields; Potentials; Gauss’s Law and Applications; Conductors and Conduction Current
Lecture 4 - Electrostatics: Electrostatic Shielding; Poisson’s and Laplace’s Equations; Capacitance; Dielectric Materials and Permittivity
Lecture 5 - Electrostatics: Dielectric Breakdown, Electrostatic Boundary Conditions, Electrostatic Potential Energy; Conduction Current and Ohm’s Law
Lecture 6 - Electromotive Force; Kirchoff’s Laws; Redistribution of Charge; Boundary Conditions for Steady Current Flow
Lecture 7 - Magnetostatics: Ampere’s Law Of Force; Magnetic Flux Density; Lorentz Force; Biot-savart Law; Applications Of Ampere’s Law In Integral Form; Vector Magnetic Potential; Magnetic Dipole; Magnetic Flux
Lecture 8 - Magnetostatics: Mutual And Self-inductance; Magnetic Fields In Material Media; Magnetostatic Boundary Conditions; Magnetic Forces And Torques
Lecture 9 - Faraday’s Law Of Electromagnetic Induction; Displacement Current; Complex Permittivity and Permeability
Lecture 10 - Uniform Plane Wave Solutions to Maxwell’s Equations
Lecture 11 - Electromagnetic Power Flow; Reflection And Transmission Of Normally and Obliquely Incident Plane Waves; Useful Theorems
Lecture 12 - Overview Of Circuit Theory;
Lumped Circuit Elements; Topology Of Circuits; Resistors; KCL and KVL; Resistors in Series and Parallel; Energy Storage Elements; First-Order Circuits