Lectures in course MICRO-100: Electrotechnics I

Analysis and Resolution of Linear Circuits

Covers the analysis and resolution of linear circuits with a focus on parallel and serial elements, equivalent dipoles, and series connections.

Series-Parallel Combined Circuits

Covers the analysis of series-parallel combined circuits and voltage dividers with examples of resistive and inductive dividers.

Sinusoidal Quantities: Analytical Expressions and Parameters

Covers the analytical expressions and parameter definitions of sinusoidal quantities in electrical engineering.

Sinusoidal Circuits: Examples and Impedances

Covers examples in electrical engineering, impedance properties, and circuit components like resistance and reactance.

Resonant Circuits: Frequency Behavior and Equivalent Dipoles

Explores the frequency behavior of resonant circuits and equivalent dipoles.

Frequency Behavior, Geometric Loci

Covers the frequency behavior of electrical circuits and geometric loci representation in the complex plane.

Electrical Engineering: Conventions

Covers conventions in electrical engineering, focusing on instantaneous and average values.

Electrical Engineering: Microtechnology and Actuators

Explores the history and applications of electrical engineering in microtechnology and special actuators.

Electrotechnique I: Complex Apparent Power

Covers active, reactive, and apparent powers, as well as complex impedance properties.

Impedances and Impedance Networks

Covers the representation of impedances, voltage and current dividers, and impedance networks in electrical engineering.

The Wheatstone Bridge

Explains the equilibrium condition in electrical engineering using the Wheatstone bridge and practical applications.

Fundamental Laws of Electricity

Covers the fundamental laws of electricity, including properties of capacitors, electric current, Joule losses, Ohm's law, and circuit analysis.

Analysis and Resolution Methods

Covers the analysis of circuits, real voltage and current sources, and circuit processing.

Alternative Regime Methods: Maximum Power and Adaptation

Covers methods for adapting to alternative regimes in electrical engineering, focusing on achieving maximum power.

Alternative Regime Methods: Power Resolution

Explains alternative regime methods in electrical engineering, emphasizing power resolution through examples.

Thevenin and Norton Theorems in Alternating Regime: Superposition Principle

Explores Thevenin and Norton theorems in alternating regime, emphasizing superposition principle and complex time domains.

Voltage Sources in Circuits

Covers the main elements of circuit theory, focusing on voltage sources.

Superposition Principle: Circuits Analysis

Covers the superposition principle in circuit analysis, simplifying complex circuits for easier evaluation through individual component analysis and result summation.

Maximum Power and Adaptation

Explores the maximum power supplied by a real source in electrical engineering.

Active, Reactive, and Apparent Powers - Exercise 3

Covers the resolution of an exercise on active and reactive powers under an alternating voltage.