EE-200: Electromagnetics I : Transmission lines and waves

Lectures in this course (39)

Explores the response of transmission lines to sinusoidal signals and the use of complex phasors for simplifying analysis.

Explores the interpretation of wave equations using phasors and phase velocity.

Explains line impedance theory, source/load conditions, and boundary concepts.

Explores short-circuited and open transmission lines, analyzing impedance conditions and reactive behaviors.

Explores the behavior of short-circuited and open lines as reactive components.

Explores the effects of complex impedance on reflected waves and distribution of quantities.

Explores standing wave ratio, load impedance, reflection coefficient, and wave propagation analysis.

Explores antenna networks and standing wave ratios through practical exercises on impedance matching and system performance evaluation.

Explores conditions for voltage amplitude minima and maxima along a line.

Covers the transformation of impedance in transmission lines and determining unknown impedances from measurements.

Covers the properties of line impedance, focusing on extremal impedance.

Explains the calculation of V+ in C54-55 with mathematical formulas and examples.

Covers the analysis of power flow in electrical systems, focusing on concepts and formulas for calculating power flow and voltage.

Covers the theory and practical applications of impedance matching in series.

Covers the Smith Chart, a graphical tool for solving transmission line problems and impedance matching.

Covers losses and absorption in transmission lines, including phasors and infinite lines.

Covers the parameters and invariants of two-port systems.

Covers challenging exercises on transmission lines and reactive elements, emphasizing characteristic impedance and reflections theory.

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