Learning objectives
Knowledge and understanding:
- Basic theoretic knowledge of guided electromagnetic propagation;
- Basic theoretic knowledge of electromagnetic propagation in free space;
- knowledge and understanding of analysis and design tools of transmission lines and free space radiofrequency links.
Applying knowledge and understanding:
- use and application of analysis and design tools of transmission lines;
- use and application of analysis and design tools of antennas and radiofrequency links.
Prerequisites
Fisica generale 2, Principi e applicazioni dell’ingegneria elettrica.
Course unit content
Maxwell’s equations in integral and differential form. Differential operators. Wave equation, propagating waves. Phase velocity. Frequency domain and Fourier transformation. Helmholtz equation. Properties of matter. Active and reactive power and Poynting theorem. Uniform and evanescent plane waves.
Guided propagation. Telegrapher’s equations and Telephone equations. Description of transmission lines and its parameters. Short and open circuit transmission lines. Smith’s Chart. Power and impedance matching. Stub, double stub and /4 matching network. Scattering parameters. Transients on transmission lines and Bounce diagrams. Overview on metallic waveguides, dielectric waveguides and optical fibers.
Different kinds of antennas. Characteristic antenna parameters. Design of a radio link and Friis transmission formula. Radar equation. The short dipole. Loop antenna. Antenna arrays. Boundary condition for electromagnetics. Yagi-Uda and Log-periodic antennas. Radiation by large aperture and parabolic antennas. Antenna bandwidth. Electromagnetic compatibility.
Full programme
Maxwell’s equations in integral and differential form. Differential operators. Wave equation, propagating waves. Phase velocity. Frequency domain and Fourier transformation. Helmholtz equation. Properties of matter. Active and reactive power and Poynting theorem. Uniform and evanescent plane waves.
Guided propagation. Telegrapher’s equations and Telephone equations. Description of transmission lines and its parameters. Short and open circuit transmission lines. Smith’s Chart. Power and impedance matching. Stub, double stub and /4 matching network. Scattering parameters. Transients on transmission lines and Bounce diagrams. Overview on metallic waveguides, dielectric waveguides and optical fibers.
Different kinds of antennas. Characteristic antenna parameters. Design of a radio link and Friis transmission formula. Radar equation. The short dipole. Loop antenna. Antenna arrays. Boundary condition for electromagnetics. Yagi-Uda and Log-periodic antennas. Radiation by large aperture and parabolic antennas. Antenna bandwidth. Electromagnetic compatibility.
Bibliography
- Stefano Selleri, “Propagazione Elettromagnetica Guidata”, Monte Università Parma Editore, Parma, 2006.
- Fawwaz T. Ulaby, “Fundamentals of Applied Electromagnetics”, Prentice Hall, Upper Saddle River, 2004.
- Fawwaz T. Ulaby, Fondamenti di Campi Elettromagnetici”, McGraw-Hill, Italian Edition, Milano, 2005. - John D. Kraus, Daniel A. Fleisch, “Electromagnetics with Applications”, McGraw-Hill, Singapore 1999.
- Constantine A. Balanis, “Antenna Theory”, Wiley, New York, 1982.
Teaching methods
Lessons (75%);
classroom exercise(15%);
group experimental and CAD experiences in laboratory (5%);
seminars given by external experts (5%).
Assessment methods and criteria
The exam comprises a written test and an oral discussion.
The written test will present exercises to allow the student to apply knowledge and understanding of analysis and design tools on transmission lines, antennas and radiofrequency links.
The oral discussion is aimed to verify the student knowledge and understanding of basic electromagnetic guided and free space propagation as well as the working principles of transmission lines and antennas. The discussion will also include a presentation of lab experiences.
Other information
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2030 agenda goals for sustainable development
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