Electromagnetic Field
Electromagnetism is a branch of physics involving the study of the electromagnetic force, a type of physical interaction that occurs between electrically charged particles. The electromagnetic force is carried by electromagnetic fields composed of electric fields and magnetic fields, and it is responsible for electromagnetic radiation such as light. It is one of the four fundamental interactions (commonly called forces) in nature, together with the strong interaction, the weak interaction, and gravitation.
References:
1. William Hayt, John Buck, “Engineering Electromagnetics” McGraw-Hill, 2001.
2. Sadiku, “Elements of Electromagnetic”.
3. Karl E., “Fundamental of Electromagnetics with MATLAB,” SciTech, 2005.
Table of Contents:
Lecture 1: electric field
1.1 Electrostatic Fields
1.2 Coulomb’s Law and Electric Field strength
Field Due to a Continuous Volume Charge Distribution
Field of a Line Charge
Field of a sheet of Charge
Lecture 2: electric flux density
2.1 Electric Flux Density, Flux Lines, Displacement Density
2.2 Gauss’s Law
2.3 Applications of Gauss’s Law
2.4 Application of Gauss’s Law: Differential Volume Element
2.5 Divergence and Maxwell’s First Equation
2.6 Vector Operator and the Divergence Theorem
Lecture 3: energy and potential
3.1 Energy Expanded in Moving a Point Charge in an Electric Field
3.2 Definition of Potential Difference and Potential
3.3 Potential Field of a Point Charge
3.4 Energy Density stored in the Electrostatic Field
Lecture 4: Conductors and dielectrics, Conductor, dielectric, dielectric polarization
4.1 Current and Current Density
4.2 Metallic Conductors, Valance band, Conduction band, Energy gap
4.3 Semiconductors
4.4 The Nature of Dielectric Materials, Polarization, Permittivity, Ferroelectric materials, Hysteresis effects
Lecture 5: capacitance, Capacitor, Inductor
5.1 Capacitance Defined
5.2 Parallel Plate Capacitor
5.3 Several Capacitance Examples
5.4 Poisson’s and Laplace’s Equations
Lecture 6: Steady Magnetic field, Magnetic field strength, Magnetic flux density
6.1 Applying curl to the Ampere’s Circuital Law
6.2 Stokes’ Theorem
6.3 Magnetic flux and Magnetic flux density, Permeability, Tesla, Gauss, Weber
Lecture 7: Magnetic Forces, Materials, and inductance
7.1 Force on a Moving Charge
7.2 The Nature of Magnetic Materials, Diamagnetic, Paramagnetic, Ferromagnetic, Antiferromagnetic, Ferrimagnetic, and Superparamagnetic, Antiferromagnetic materials
7.3 Magnetization and Permeability
7.4 The Magnetic Circuit, Magnetomotive force
7.5 Inductance
Lecture 8: Electromagnet fields
8.1 Field Theory
8.2 Electromagnetics
8.3 Induced Electromotive Force
8.4 Energy Stored in an Electromagnetic Field
8.5 Electromagnetic Induction
In
this course, the student learns about the field of electronics, how to deal
with behavior, issuance, and the impact of electronics using modern electronic
devices, and how electronics use active devices to control the flow of
electrons through amplification and correction.
Dynamics mechanical engineering is the branch of mechanics that deals with the study of objects in motion and the forces causing such motion. Dynamics can be further classified into two types: kinematics and kinetics. Kinematics is the study of the motion of bodies without consideration of the cause of the motion. Kinematics deals with the space-time relationship of the motion of a body. Some examples of kinematic concepts are displacement, velocity and acceleration.
While Kinetics is the branch of mechanics which deals with the study of the motion of bodies by considering the cause of motion.
Understanding this science requires knowledge of the Kinetics of Particles, Rectilinear Motion, Rectangular Components of Curvilinear Motion, Rotational Motion, Kinetics, Force, Mass and Acceleration, and Kinetic of Particle Newton's Second Law.