EE 224
ELECTROMAGNETIC
THEORY
2003-2004 Spring Semester
Instructors
Course Details Course
Outline Interested
Links
Instructors:
Section - 1 : Lale Alatan
(Room: C-209)
Section - 2 : Özlem
Aydın Çivi
(Room: C-202)
Section - 3 : Merih
Büyükdura
(Room: D-210)
Section - 4 : Şimşek Demir
(Room: C-207)
Section - 5 : Nilgün Günalp
(Room: D-213)
Section - 6 : Gönül T. Sayan
(Room: D-208)
Teaching Assistants:
Mehmet Ünlü (Room: D-223)
Kağan Topallı (Room: D-223)
Textbook:
1. Fundamentals of Engineering
Electromagnetics,
David K. Cheng, Addison - Wesley.
or
2. Field and Wave
Electromagnetics,
David K. Cheng, Addison - Wesley
References:
- Introductory Engineering
Electromagnetics,
Z. D. Popovic, B. D. Popovic, Prentice Hall.
- Engineering Electromagnetics,
U.S. Inan, A.S. Inan, Addison-Wesley.
- Principles and Applications
of
Electromagnetic Fields, R. Plonsey and R. Collin, McGraw-Hill.
- Electromagnetic Fields and
Waves,
P. Lorrain and D. Corson, Freeman.
- Electromagnetics, J. D.
Kraus,
McGraw-Hill.
- Elements of Engineering
Electromagnetics, N.N. Rao, Prentice Hall
- Vector Analysis, Schaum`s
outline
series.
- The Feynman Lectures on
Physics,
R. Feynman, Addison-Wesley.
Dates of Examinations:
First Midterm examination:
Second Midterm examination:
Final Examination :
Course
Outline
- Vector
Analysis (Ch.2
/ Ch.2)
- Vector
Algebra
- Addition
- Subtraction
- Multiplication
(Dot
Product, Cross Product, Product of Three Vectors)
- Orthogonal
Coordinate
Systems
- Cartesian
Coordinates
- Cylindrical
Coordinates
- Spherical
Coordinates
- Vector
Calculus
- Vector
and Scalar Fields
- Gradient
of a Scalar
Field
- Line
Integral, Surface
Integral, Volume Integral
- Divergence
of a Vector
Field
- Curl
of
a Vector Field
- Divergence
Theorem
- Stoke's
Theorem
- Null
Identities
- Helmholtz
Theorem
- Static
Electric Fields
( Ch.3 / Ch.3 and Ch.4)
- Coulomb's
Law
- Definition
of the electric
field
- Electric
field due
to a system of discrete charges
- Electric
field due
to a continuous distribution of charge
- Gauss'
Law in free
space and its applications
- Electrostatic
Potential
- Material
media in static
electric field
- Conductors
in static
electric field
- Dielectrics
in static
electric field
- Polarization
vector,
polarization charge densities
- Electric
flux density,
generalized form of Gauss' Law
- Electric
succeptibility,
permittivity
- Boundary
conditions
for electrostatic field
- Capacitances
and capacitors
- Parallel
plate capacitor
- Coaxial
cable capacitor
- Spherical
capacitor
- Poisson's
and Laplace's
Equations, 1D solutions
- Electrostatic
energy
and forces
- Electrostatic
energy
in terms of field quantities
- Electrostatic
forces
- Method
of virtual displacements
- Method
of Images
- Steady
Electric Currents
(Ch.4 / Ch.5)
- Equation
of continuity
and Kirchoff's current law
- Current
density and
types of current
- Power
dissipation
and Joule's Law
- Resistance
calculations
- Static
Magnetic Fields
(Ch.5 / Ch.6)
- Ampere's
force law
- Definition
of
field
- The
Biot-Savart Law
and applications
- Vector
Magnetic Potential
- Ampere's
Circuital
Law and applications
- Solenoidal
property
of field and flux conservation
- The
magnetic dipole
- Magnetization
and equivalent
current densities
- Magnetization
vector
- Equivalent
volume and
surface magnetization current densities
- Magnetic
field intensity
and generalized Ampere's Circuital Law
- Magnetic
susceptibility,
permeability
- Behavior
of magnetic
materials
- Boundary
conditions
for magnetostatic fields
- Inductances
and inductors
- Magnetic
energy
- Magnetic
energy in
terms of field quantities
- Magnetic
force and
torques
- Time
Varying Fields
(Ch.6 / Ch.7)
- Faraday's
law of electromagnetic
induction
- Lenz'
law
- Motional
and Transformer
EMF's
- A
moving conductor
in a magnetic field
- A
stationary circuit
in a time varying magnetic field
- A
moving circuit in
a time-varying magnetic field
Interesting
Links