After successful completion of the course, students are able to model and simulate multipath propagation of electromagnetic waves for highly mobile users, as well as to answer systems engineering questions for ultrawideband radio systems.
In this course we will cover the fundamentals of linear-time variant systems to characterize wireless communication channels under strong time-variance and in non-stationary environments. We discuss the measurement of such non-stationary fading processes based on channel-sounding and their characterization and emulation with graded complexity form ray-tracing to tap delay line models.
For the transceiver design we focus on systems based on orthogonal frequency division multiplexing (IEEE 802.11p, LTE-A and 5G) and discuss advanced iterative channel estimation methods from the classical Wiener filter to two-dimensional adaptive subspace models.
To exploit the diversity in vehicular channels we introduce the concept of channel prediction as basis for antenna selection, coded cooperation and interference alignment for mobile users. Here we introduce the basic concepts as well as the complexity caused by the time-variant fading process.
For wireless communication from vehicle to vehicle as well as between the vehicles and the road infrastructure, several standard such as IEEE 802.11p and LTE vehicular exist. The new 5G communication standard is currently under intense international development.
For wireless connectivity of sensors on board of vehicles, ultrawideband radio technology is discussed which features high power efficiency. In this context, the standard IEEE 802.15.4a is analysed.
First lecture: Monday, 27.11.2023, 14:30 - 16:00, CG 0402.
This lecture is given twice a week:
Mondays 14:30 - 16:00, CG 0402
Wednesdays 15:00 - 16:30, CG 0402
