Lectures related to Electromagnetic Induction

Electromagnetism: UNIL-208

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

Magnetic Circuits: Understanding Inductance and Maxwell's Equations

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

Maxwell's Equations and Induction Phenomenon

Explores Maxwell's equations, induction in moving conductors, electromotive force, and electrical fields.

Sources of Magnetic Fields and Induction

Explores the generation of magnetic fields, induction, and practical applications in electromagnetism.

Electromagnetism Fundamentals

Introduces the fundamentals of electromagnetism, covering magnetic flux, inductance properties, energy transformations, and practical applications.

Electromagnetism: Fundamentals and Applications

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

Magnetic Fields and Induction

Explores magnetic dipoles, fields, induction, electromotive force, and applications like wireless energy transfer and magnetic levitation.

Magnetic Circuits: Inductances and Maxwell Equations

Explores magnetic circuits, inductances, and Maxwell's equations in the quasi-static regime, emphasizing Faraday's law and magnetic permeance.

Magnetostatics: Electric Current and Magnetic Fields

Explores the interaction between electric current and magnetic fields, covering Ampère's law, electromagnetic induction, and different materials' behavior in magnetic fields.

Magnetostatics: Magnetic Field and Force

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

Magnetostatics: Electric Current and Magnetic Fields

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

Faraday's Law of Induction

Explains how time-varying magnetic fields induce electric currents through Faraday's experiments and the third Maxwell's equation.

Magnetostatics: Drude Model and B-Field Circuits

Explores the Drude model, magnetostatics, B-field circuits, force on current elements, material conductivity, torque, and applications of B-fields.

Energy in Inductance & Capacitance

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

Maxwell's Equations: Magnetodynamics & Faraday-Henry Induction Law

Explores Maxwell's equations completion, Faraday-Henry law, induced emf, and experiments in magnetodynamics.

Magnetism: Basics and Phenomena

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

Understanding Displacement Vector and Plane Waves

Explores the displacement vector D, plane waves, and magnetic vector potential, addressing student questions and clarifying key concepts.

Self-inductance and EMF

Explores self-inductance, EMF, and the Lenz rule in Faraday's induction context.

AC Circuits: Impedance and Reactance

Explores reactances, impedance, rotating vectors, and complex components in AC circuits.

Electromagnetic Induction: Empirical Law and Mathematical Formulas

Explores electromagnetic induction, explaining how magnetic field changes induce current and electromotive force in conductors.