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Kinetic energy (KE) is a form of energy that an object possesses due to its motion. It is expressed mathematically as \( KE = \frac{1}{2}mv^2 \), where \( m \) is the mass of the object and \( v \) is its velocity. When dealing with problems involving a ball in motion, such as a ball being dropped, understanding kinetic energy is crucial.
As a ball falls from a height, it accelerates due to gravity, and its potential energy (related to its height) is converted into kinetic energy. Just before the ball makes contact with the floor, all of its potential energy has been converted to kinetic energy. At this point, its velocity is at its maximum.
This conversion can be used to determine the velocity of the ball just before impact, helping us understand how energy is transformed and conserved in a system.

Potential energy (PE) in the context of gravitational fields is the energy an object possesses because of its position relative to a reference point, usually the ground. It is calculated as \( PE = mgh \), where \( m \) is the mass, \( g \) is the acceleration due to gravity, and \( h \) is the height above the reference point.
In the scenario of a ball being dropped, the ball starts with maximum potential energy at the height it is released (height \( h \)). Upon falling, this potential energy is transformed into kinetic energy. When the ball hits the ground, its potential energy is reduced to zero as it is at ground level.
Upon rebounding, the ball reaches a height of \( 0.65h \), at which point it possesses potential energy again. However, this potential energy is less than the initial potential energy because it does not reach the original height. Understanding this concept is key to analyzing the changes in energy throughout the ball's motion.

Velocity equations are essential tools for solving problems that involve motion, particularly when analyzing collision dynamics. These equations help us translate physical situations into mathematical expressions that can be manipulated to find unknown variables.
For the ball dropped and rebounding, initial and final velocities determine the kinetic energy and serve as a base for calculating the coefficient of restitution. Before impact, the velocity \( u_2 \) of the ball can be found with \( u_2 = \sqrt{2gh} \). Here, \( g \) is the gravitational acceleration, and \( h \) is the drop height.
After rebounding, the velocity \( v_2 \) is given by \( v_2 = \sqrt{2g(0.65h)} \). These equations stem from the energy principles, converting potential energy balances into kinetic energy terms. By evaluating these velocities, we can further investigate how energy is distributed in motion and contribute to calculating the coefficient of restitution, which is a measure of energy loss in a collision.