Covers non-inertial reference frames, constraints, and continuous systems, including angular velocity, linear and rotational acceleration, and modeling of merry-go-rounds, ropes, and pulleys.
Covers frames of reference in physics, emphasizing the importance of choosing a reference frame and the laws of physics in different frames.
Explains Galilean transformations, inertial reference frames, and Newton's first law of motion in classical mechanics.
Covers dynamics in non-inertial frames, including velocity and acceleration transformations and the concept of apparent forces.
Introduces Newton's laws of motion, covering force, mass, frames of reference, and practical examples like friction and springs.
Explores motion study in different reference frames, focusing on Galileo's transformation and Newton's laws.
Explores Newton's laws of motion, their applications, and experimental verifications in various contexts.
