This course presents fundamentals of electromagnetic field theory and its applications. Analysis methods proper for static, stationary as well as dynamic fields and waves in free space and on basic transmission lines are presented as well. This course provides students with physics - based wiev on studied effects, which is applied then on engineering problems. At the end of the course, all effects should not only be described, but quantified as well. Basic knowledge and insight into communication devices, systems and techniques is provided, applicable not only to systems currently taught in other courses, but to future systems as well.
Basic knowledge and insight into communication devices, systems and techniques.
1. Basic principles, field sources, charge(s) and current(s).
2. Field caused by charges, Laplace and Poisson equation, polarisation, capacity.
3. Magnetic field caused by steady current. Self and mutual inductance.
4. Magnetic circuit analysis, ferromagnetics.
5. Induction law. Nonstationary fields. Maxwell equations, practical explanation.
6. Energy and force contained in/caused by electromagnetic field
7. Electromagnetic wave, wave equation and its solution in the case of planar harmonic wave
8. Planar waves in lossy media, waves at planar interfaces, Snell's law
9. Poynting theorem. Fields and waves in conductive media.
10.Analytic and numeric analysis and its applications
11. Guided waves, transmission lines and its parameters, transmission, reflection, impedance
12. Smith chart, parameters on display and its application in impedance matching
13.TEM transmission lines, coaxial, Lecher ad other line types
14. Waveguide with rectangular crossection, parameters, modes, resonators.
1. Scalar and vector fields, potential, electric field strength, fields at interfaces.
2. Charged ball and line, capacity.
3. Field inside a charged layer, capacitors composed of several dielectrics.
4. External inductance - self and mutual - calculus.
5. Magnetic circuit analysis.
6. Induced voltage. Application of Maxwell equations.
7. Forces, work, energy of the field.
8. Planar electromagnetic wave, reflection at interfaces.
11. Guided waves
12. Design of a narrowband impedance matching circuit
13. Coaxial line design, power handling, attenuation.
14. Dominant mode, dispersion, resonator design.
 Collin, R.E.: Field Theory of Guided Waves. 2nd Edit., IEEE Press, New York 1991
 Sadiku, M.N.O.: Elements of Electromagnetics. Saunders College Publishing. London, 1994