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:

  1. Introductory Engineering Electromagnetics, Z. D. Popovic, B. D. Popovic, Prentice Hall.
  2. Engineering Electromagnetics, U.S. Inan, A.S. Inan, Addison-Wesley.
  3. Principles and Applications of  Electromagnetic Fields, R. Plonsey and R. Collin, McGraw-Hill.
  4. Electromagnetic Fields and Waves,  P. Lorrain and D. Corson,  Freeman.
  5. Electromagnetics,  J. D. Kraus, McGraw-Hill.
  6. Elements of Engineering Electromagnetics, N.N. Rao, Prentice Hall
  7. Vector Analysis, Schaum`s outline series.
  8. The Feynman Lectures on Physics, R. Feynman, Addison-Wesley.

Dates of Examinations:

First Midterm examination:
Second Midterm examination:
Final Examination :

 

Course Outline

  1. Vector Analysis  (Ch.2 / Ch.2)
    1.  Vector Algebra
      1.  Addition
      2.  Subtraction
      3.  Multiplication (Dot Product, Cross Product, Product of  Three Vectors)
    2.  Orthogonal Coordinate Systems
      1.  Cartesian Coordinates
      2.  Cylindrical Coordinates
      3.  Spherical Coordinates
    3.  Vector Calculus
      1.  Vector and Scalar Fields
      2.  Gradient of a Scalar Field
      3.  Line Integral, Surface Integral, Volume Integral
      4.  Divergence of a Vector Field
      5.  Curl of a Vector Field
      6.  Divergence Theorem
      7.  Stoke's Theorem
      8.  Null Identities
      9.  Helmholtz Theorem
  2.  Static Electric Fields  ( Ch.3 / Ch.3 and Ch.4)
    1.  Coulomb's Law
      1.  Definition of the electric field
      2.  Electric field due to a system of discrete charges
      3.  Electric field due to a continuous distribution of charge
    2.  Gauss' Law in free space and its applications
    3.  Electrostatic Potential
    4.  Material media in static electric field
      1.  Conductors in static electric field
      2.  Dielectrics in static electric field
      3.  Polarization vector, polarization charge densities
      4.  Electric flux density, generalized form of Gauss' Law
      5.  Electric succeptibility, permittivity
    5.  Boundary conditions for electrostatic field
    6.  Capacitances and capacitors
      1.  Parallel plate capacitor
      2.  Coaxial cable capacitor
      3.  Spherical capacitor
    7.  Poisson's and Laplace's Equations, 1D solutions
    8.  Electrostatic energy and forces
      1.  Electrostatic energy in terms of field quantities
      2.  Electrostatic forces
      3.  Method of virtual displacements
    9.  Method of  Images
  3.  Steady Electric Currents  (Ch.4 / Ch.5)
    1.  Equation of continuity and Kirchoff's current law
    2.  Current density and types of current
    3.  Power  dissipation and Joule's Law
    4.  Resistance calculations
  4.  Static Magnetic Fields  (Ch.5 / Ch.6)
    1.  Ampere's force law
    2.  Definition of  field
    3.  The Biot-Savart Law and applications
    4.  Vector Magnetic Potential
    5.  Ampere's Circuital Law and applications
    6.  Solenoidal property of   field and flux conservation
    7.  The magnetic dipole
    8.  Magnetization and equivalent current densities
    9.  Magnetization vector
    10.  Equivalent volume and surface magnetization current densities
    11.  Magnetic field intensity and generalized Ampere's Circuital Law
    12.  Magnetic susceptibility, permeability
    13.  Behavior of magnetic materials
    14.  Boundary conditions for magnetostatic fields
    15.  Inductances and inductors
    16.  Magnetic energy
    17.  Magnetic energy in terms of field quantities
    18.  Magnetic force and torques
  5.  Time Varying Fields  (Ch.6 / Ch.7)
    1.  Faraday's law of electromagnetic induction
      1.  Lenz' law
      2.  Motional and Transformer EMF's
      3.  A moving conductor in a magnetic field
      4.  A stationary circuit in a time varying magnetic field
      5.  A moving circuit in a time-varying magnetic field

Interesting Links