Lectures related to Magnetic Circuits: Introduction and Analysis

Magnetic Circuits: Understanding Inductance and Maxwell's Equations

Explains magnetic circuits, focusing on inductance and Maxwell's equations in electromechanical systems.

Explores energy storage in coils, magnetic fields, and capacitors, emphasizing the oscillation and decay of energy in circuits.

Magnetostatics: Magnetic Field and Force

Covers magnetic fields, Ampère's law, and magnetic dipoles with examples and illustrations.

Electromagnetism: Fundamentals and Applications

Explores the basics of electromagnetism, Ohm's law, Lenz's law, and Faraday's law, shedding light on electromagnetic devices.

Electromagnetism: UNIL-208

Covers Lenz's law, induced voltage, and electromagnetic circuits.

Inductance Coil and Accumulated Energy

Explores inductance coil, accumulated energy, coils in series, and RL circuits.

Energy Storage in Inductance

Explores energy storage in magnetic fields, LC circuits, ferromagnetic cores, and oscillating voltage signals.

LC Circuits: Magnetodynamics

Explores inductors' applications, LC circuit operation in radio clocks, energy oscillations, and harmonic oscillators.

Magnetic Fields and Currents

Explores magnetic fields, currents, Biot-Savart law, Ampère's law, and magnetic dipoles.

Circuit Analysis: Thevenin and Norton Theorems

Explores circuit analysis using Thevenin and Norton theorems to simplify complex circuits for analysis.

Electrical Circuit: Fixed Point Methods

Explores applying fixed point methods to solve electrical circuit equations and find diode voltage.

Magnetic Forces: Biot-Savart Law

Explores magnetic phenomena, current, charge conservation, Biot-Savart law, and Ampère's force law.

Mutual Inductance and Self-Inductance

Explains mutual inductance, self-inductance, magnetic energy, and 'cross-talk' in circuits.

Jarzynski Equation and Quantum Circuits

Explores the Jarzynski equation and the quantization of electrical circuits in quantum harmonic oscillators.

Harmonic Oscillator: LC Resonator Analysis

Analyzes an LC resonator as a harmonic oscillator, discussing transient behavior, oscillations in charge and current, and the interplay between electrical and magnetic energy.

Magnetostatics: Electric Current and Magnetic Fields

Explores the interaction between electric currents and magnetic fields, including Ampère's law and electromagnetic induction.

Magnetic Fields in Current-Carrying Wires

Explores magnetic fields in current-carrying wires and solenoids using Biot-Savart and Ampere's laws.

Magnetism: Basics and Phenomena

Explores the basics of magnetism, magnetic fields, and magnetic properties in materials.

Magnetic Circuits: Interruptions and Magnetic Fields

Delves into interruptions in magnetic circuits and the calculation of required current.

Electricity Fundamentals: Inductance and Complex Impedance

Explores the relationship between current and voltage, sinusoidal signals, and impedance in electrical circuits.