- Docente: Franco Fuschini
- Credits: 9
- SSD: ING-INF/02
- Language: English
- Moduli: Franco Fuschini (Modulo 1) Franco Fuschini (Modulo 2)
- Teaching Mode: Traditional lectures (Modulo 1) Traditional lectures (Modulo 2)
- Campus: Bologna
- Corso: Second cycle degree programme (LM) in Telecommunications Engineering (cod. 9205)
Learning outcomes
Mastery in engineering electromagnetic topics related to wave propagation. Knowledge of the main properties of radio propagation in real environment, expertise on path-loss models, multipath propagation modeling and radio channel wideband characterization. General comprehension of MIMO systems, diversity and spatial multiplexing techniques. Awareness of the main coverage and planning strategies for cellular radio, broadcasting and wireless systems. Assessment of wireless systems efficiency.
Course contents
Part I – Fundamentals of Electromagnetic Theory (30 hours approx.)
Maxwell’s Equations
Complex representation of sinusoidal fields. Polarization of sinusoidal, vectorial fields. Maxwell’s equations in the time and frequency domain, boundary conditions.
Electromagnetic Waves
The wave concept and the electromagnetic radiation.
Solution of Maxwell’s equations in homogeneous medium: potential vectors, electromagnetic field generated by a point-source and by a volume-source. Far-field conditions and radiation field. Spherical, uniform waves. The reasons for attenuation of electromagnetic waves, propagation speed.
Plane waves: wave vector, uniform and evanescent plane waves.
Reflection of waves, standing waves.
Short hint to near-field communication.
Electromagnetic resonance.
Theorems
Poyinting and equivalence theorems, electromagnetic image principle.
Geometrical Theory of Propagation
Historical survey, definition of optical ray. Wave equation for an inhomogeneous medium. Eikonal and Transport equations. Rays equations and rays trajectory. Examples: planar and spherical stratified medium. Ray tube and spreading factor. General expression of the electromagnetic field along a ray.
Elettromagnetic Interactions
Rays reflection and refraction: Fresnel coefficients. Diffraction: diffracted ray and Keller’s law, GTD and UTD diffraction coefficients. Diffuse scattering.
Part II – Propagation in Wireless Systems (60 hours approx.)
Wireless propagation in real environment
From ideal (Friis formula) to real propagation. Fading effects: radio link obstruction and multipath propagation. Dependence of a wireless digital system performance on the propagation conditions. Signal attenuation and distortion, flat and selective fading.
Introduction to the environmental effects: atmospheric effects on wireless links, tropospheric propagation and impact of the terrain on the radio link (2-rays model).
Dispersive properties of the wireless channel: delay spread/coherence bandwidth, Doppler spread/coherence time, angle spread.
Radio channel modelling: narrowband and wideband characterization
Narrowband analyses of field distribution: path loss, shadowing and fast fading. Path Loss exponent and statistical distribution of fast/slow fluctuations. Narrowband propagation models (Okumura-Hata formula, Epstein-Peterson model, ...). Fading margin and radio coverage.
Multipath effects and input-output functions of the (mobile) radio channel
WSSUS channel and characterization of the wideband propagation parameters (Delay Spread, Angle Spread, etc.) and wideband propagation models (rays models).
Multi-antenna systems
MIMO solutions and techniques for fading mitigation / channel capacity increase: spatial diversity, beamforming and spatial multiplexing
Introduction to cellular wireless systems
Cellular tessellation and radio resource management, spatial reuse. Introduction to the multiple access techniques: TDMA, FDMA, CDMA and SDMA.
Readings/Bibliography
Course slides and notes.
D.A. McNamara. C.W.I Pistorius, J.A.G. Malherbe, Introduction to the uniform geometrical theory of diffraction, Artech House, 1990.
H. L. Bertoni, Radio Propagation for Modern Wireless Systems, Prentice Hall, 2000
S.J. Orfanidis, Electromagnetic Waves and Antennas, free download at: http://eceweb1.rutgers.edu/~orfanidi/ewa/
N. Costa, S. Haykin, Multiple-Input Multiple Output Channel Models – Theory and Practice, Wiley& Sons, 2010.
E. Björnson, J. Hoydis L. Sanguinetti, Massive MIMO Networks: Spectral, Energy, and Hardware Efficiency, free download at: https://massivemimobook.com/wp/free-pdf/
Teaching methods
The course includes lectures given by the professor, and exercises carried out by the professor as well as assigned to the students.
Assessment methods
The exam is organized into a written part and a following oral discussion.
The written test consists of a full exercise on the topics addressed throughout the course. The use of books, notes and pocket calculator is allowed. Access to the web and to any particular software tool is on the contrary strictly forbidden.
The outcome of the written exercise must be positive (i.e. at least 18 out of 30) in order to proceed with the oral discussion.
The oral discussion (15/20 minutes approx.) aims at assessing the comprehension of the main concepts explained during the course.
The final mark is a synthetic, weighted evaluation of the outcomes of the written and oral parts.
Taking the written and oral tests within the same exam session is strongly recommended; in any case the validity of the written test score is limited to the current academic year.
Teaching tools
Blackboard, PC, projector.
Office hours
See the website of Franco Fuschini