Lecture
Mechanical Energy Conservation
In course
DEMO: sit dolor
Excepteur cupidatat mollit et anim. Adipisicing nulla incididunt ea minim esse tempor minim elit sunt. Pariatur qui amet fugiat velit ad. Sit ullamco velit laboris consequat sit dolor deserunt magna ullamco quis occaecat incididunt officia tempor. Duis magna amet aliquip reprehenderit aliquip elit consequat exercitation. Sint adipisicing et pariatur sit deserunt eiusmod irure voluptate minim amet id exercitation adipisicing officia. Eu dolore excepteur pariatur mollit deserunt elit quis aute nisi anim magna.
Description
This lecture covers the concept of mechanical energy conservation, discussing how the mechanical energy is a first integral of the motion equations, the energy of a harmonic oscillator, and the motion of a particle in a potential. It also explores the equilibrium and small oscillations around stable equilibrium points, providing insights into the behavior of mechanical systems.
This video is available exclusively on Mediaspace for a restricted audience. Please log in to MediaSpace to access it if you have the necessary permissions.
Watch on MediaspaceInstructor
aliqua incididunt nisi
Ea ex irure veniam cillum quis ipsum irure incididunt eiusmod esse velit. Nostrud nulla cillum et quis est enim id nisi Lorem. Aute ut cillum magna aliquip nulla amet in. Aute deserunt sunt sint est sint duis sit mollit laboris cillum deserunt commodo.
Official source
About this result
This page is automatically generated and may contain information that is not correct, complete, up-to-date, or relevant to your search query. The same applies to every other page on this website. Please make sure to verify the information with EPFL's official sources.
Ontological neighbourhood
Related lectures (145)
Virtual Work in Structural Mechanics
Explores virtual work in structural mechanics, emphasizing equilibrium states and the application of virtual displacements.
Structural Mechanics Principles: Equilibrium and Stability
Explores the principles of structural mechanics, including internal loads, equilibrium stability, and the superposition principle.
Conservation of Mechanical Energy
Explores the conservation of mechanical energy and its application in solving physics problems involving work, stability, and energy transformations.
Eigenstate Thermalization Hypothesis
Explores the Eigenstate Thermalization Hypothesis in quantum systems, emphasizing the random matrix theory and the behavior of observables in thermal equilibrium.
Introduction to Plasma Physics
Introduces the basics of plasma physics, covering collective behavior, Debye length, and plasma conditions.