The University of Akron

Department of Electrical Engineering

**4400:353 Electromagnetics
I** Dr.
N. Ida

Fall 2018 Location: SCH South 229 MoTuWeFr Room
ASEC-252

Time
11:45 – 12.35 TEL:
330-972-6525

e-mail: ida@uakron.edu

**TEXT:** Engineering
Electromagnetics, 3^{rd} Edition, 2015, N. Ida, Springer Verlag.

**Office Hours:** To be decided by mutual agreement.
Suggested times: Monday Wednesday and Friday, 9-11 AM. However, I ask that you
come and see me any time (between 7:00 AM and 6:00 PM), regardless of office
hours. There will be instances in which I will be busy with other activities.
In such cases I ask that you either wait or see me at other times. My telephone
number is 972-6525. I will be glad to answer your questions over the phone but
it is almost impossible to help with homework assignments over the phone. It is
much more likely that we will misunderstand each other
than by talking face to face. So please come and see me with any questions you
may have. You may also communicate with me by e-mail. My e-mail is ida@uakron.edu.

**Course Outline**: We will follow the textbook rather closely. The material covered
includes chapters 1 and 2 (review only), chapters 3, 4, 5, 7, 8, 9 and 10. The
topics are:

**Chapter 1 and 2**: Review of Vector Algebra and Calculus. (Very short review; < one
week)

**Chapter 3**:
Coulomb's Law and the Electric Field

**Chapter 4**:
Gauss' Law and the Electric Potential

**Chapter 5**:
Boundary Value Problems

**Chapter 7**:
The Steady Electric Current

**Chapter 8**:
The Static Magnetic Field

**Chapter 9**:
Magnetic materials and Properties

**Chapter 10**:
Faraday's Law and Induction

**Grading:** 1st
Exam 20% (Tentative: Monday, October
1)

2nd
Exam 20% (Tentative: Monday, November
5)

3rd
Exam 20% (Firm: Tuesday, November 20–
see notes)

Homework 5%

Final
Exam 35% (optional, see below)

**Note:**
after the third exam, which will be given on the last week of the Semester,
your initial grade will be computed using the following weights:

** ** 1st
Exam 30%

2nd
Exam 35%

3rd
Exam 30%

Homework 5%

**Notes: **

**1. **The third exam is firm. I will be willing to move it
back to any day that same week but will not move it after Thanksgiving week.

**2. **After the third exam, your initial grade will be
computed using **Option B**. You will
have this grade before you decide if you need or want to take the final exam.

**3. **The final exam will be given at the scheduled time.
It is your choice to take it or not. If you do, your grade will be calculated
based on **Option A**. If you do not
take the final exam, your grade will be calculated based on **Option **B. There is no need to tell me
of your choice but you are welcome to discuss it with me. The higher grade of
the two options will be used. I will take the higher of **Option A** or **Option B**
grade as your final grade.

**4. **The two options are designed so that students that do
very well in mid-term exams do not need to take the final while those that did
not do well can still improve their grades by taking the final exam.

**5.** Before each exam, I will make available sample
exams. These will be posted on my web site - http://ee.ascs3.uakron.edu/ida/ under the heading Electromagnetics I, for
downloading. The number of exams may vary but usually there will be two exams
with solutions and one without solutions. The purpose of this third exam is for
you to try on your own.

**6.** Exams
are open book, open notes. You can use any material you wish. However, you are
not allowed any connected device (no cell phones, laptops, etc.)

**7.** The textbook for the class is listed above. If you
have a previous edition, you may still use that but please be aware that
homework will be assigned from the third edition.

**Homework:** Will be assigned on Mondays (or
the first class period we meet) and will be due on Monday (or the first class
of the week we meet) of the following week. Homework will be corrected, graded
and returned. Solutions to all homework problems will be posted. There will be
no homework assigned on thanksgiving week so that you may enjoy the
thanksgiving break. I will not accept late homework. Any homework that is not
submitted by class time will not be graded.

**Supporting material:** Additional material (previous exams with solutions,
some notes, etc.) will be made available from time to time. This material is
optional.

**Grader: **The
grader for this class is not yet known – I will
announce that in class. Any questions about grading of homework assignments
should be discussed with the grader. However, I will grade all exams so
any questions about exams should be addressed to me.

**Software:**
If you go to my website you will find two software programs you may download.
You should download the first one (Electromagnetic Simulations) and use it
throughout the semester. It deals with simulations to many of the issues we
will study and may help in understanding. The second program (The Smith Chart)
as well as parts of the first program deal with E&M II issues and will only
be useful during the Spring Semester. The programs are written in Matlab.

**The following is a detailed
outline of the material covered.**

Lecture 1. Introduction, vectors, scalars, sum and difference of vectors, products, scaling of vectors, scalar products

Lecture 2. Scalar and vector products, tropple scalar and vector producta, scalar and vector fields

Lecture 3. Cartesian and cylindrical coordinate systems, intro to spherical coordinates

Lecture
4. Spherical coordinates, position vectors (**end chapter 1**). Vector and scalar
integration, conservative and nonconservative fields,
introduction to gradient

Lecture 5. Gradient, divergence, curl, divergence theorem, StokesŐ theorem, null identities

Lecture 6. Helmholz theorem (**end chapter 2**). CoulombŐs law (point
charges), examples

Lecture 7. CoulombŐs law, examples, Electric field intensity of point charges, The electric dipole, line charge densities, examples , examples

Lecture 9. Line charge densities, semi-circular line of charge, examples

Lecture 10. Surface charge distributions, examples

Lecture 11. Volume charge distributions, examples,
electric flux density (**end of chapter 3**

Lecture 12. Postulates of the electrostatic field, GaussŐs law

Lecture 13. GaussŐs law – spherical and cylindrical geometries, examples

Lecture 14. GaussŐs law – examples, GaussŐs law – planar geometries, lines of charge, superposition

Lecture 15. GaussŐs law, planar geometries, superposition, Examples

Lecture 16. GaussŐ law, charge distributions, potential of point charges

Lecture 17. Potential due to charge distributions, examples, line, surface and volume charge distributions, examples

Lecture 18. Electric field intensity from potential, conductors, examples, electric field intensity in and around conductors, examples

Lecture 19. Conductors, examples, dielectrics, polarization, Electric flux density, dielectric strength, examples, interface conditions for the electric field, examples

Lecture 21. Interface conditions, examples, capacitance, parallel plate capacitor

Lecture 22. Capacitance, examples, capacitance per unit length, examples

Lecture 23. Capacitance, capacitors in series and in parallel, examples, energy in system of charges

Lecture 24. Energy in system of charges, examples, energy in charge distributions, examples

Lecture 25. Energy in charge distributions, superposition, examples, force from energy, examples (end of chapter 4)

Lecture 26. Boundary value problems, direct integration method, examples

Lecture 27. Method of images – point charges and line charge distributions, volume distributions, examples

Lecture 28. Method of images – multiple planes, general geometries, examples

Lecture 29. Method of images, general configurations, parallel plates, examples

Lecture 30. Method of images in cylindrical and spherical systems, examples

Lecture 31. Method of images, spherical systems and superposition, examples

Lecture 32. Separation of variables, Cartesian coordinates, 2D, examples

Lecture 33. Separation of variables, Cartesian coordinates, 3D, examples, cylindrical coordinates, 2D

Lecture 34. Separation of variables, cylindrical
coordinates, examples. (**end**** of chapter 5**)

Lecture 35. Law of conservation of charge, definition of current and current density, convection current, conduction current and current density, Examples, OhmŐs law, calculation of resistance of bodies

Lecture 37. Calculation of resistance, examples, JouleŐs law, examples, the continuity equation

Lecture 38. Continuity equation, examples, current
density as a vector field, interface conditions for current density, examples (**end of chapter 7**)

Lecture 39. The magnetic field, force and magnetic field, right hand rule, the Biot-Savart law

Lecture 40. Biot-Savart law examples

Lecture 41. Biot-Savart law examples

Lecture 42. Biot-Savart law examples, AmpereŐs law, examples

Lecture 43. AmpereŐs law examples

Lecture 44. AmpereŐs law examples

Lecture 45. Magnetic flux density, magnetic flux, postulates of the magnetic field

Lecture 46. Potential functions, magnetic vector potential, examples

Lecture 47. Magnetic vector potential examples, magnetic
scalar potential, (**end
of chapter 8)****, **magnetic
dipole

Lecture 48. Magnetic dipole moment, magnetic dipole, examples, magnetization

Lecture 49. Magnetization, examples

Lecture 50. Magnetization examples, behavior of magnetic materials, hysteresis curve

Lecture 51. Hysteresis, interface conditions for the magnetic field, examples

Lecture 52. Inductance, self and mutual inductance, examples

Lecture 53. Examples of inductance

Lecture 54. Examples of inductance, energy stored in the magnetic field, Energy in a system of

Lecture 57. Energy based on field variables, examples, magnetic circuits, examples

Lecture 58. Forces in the magnetic field, examples,
Neumann formula, examples Virtual displacement method, force from energy,
examples, Torque, examples (**end of chapter 9**)

Lecture 59. FaradayŐs law, emf, LenzŐs law, examples

Lecture 60. Transformer action emf,
examples, combined motion and transformer action emf,
principle of electric motors and generators, examples, the ideal transformer
Ideal transformer, real transformer, loosely coupled transformer, examples, (**end of chapter 10**)

**Notes: **

**1.
****Summaries of all chapters
(except chapters 1 and 2) are available. Please download them as needed.**

**2.
****If you have any doubts about
the course, schedule, assignments, exams, etc., please call or e-mail me
immediately.**

**3.
****Please consult the course
outline for additional information**