A solid sphere is released from the top of a ramp that is at a height h₁ = 2.00 m. It rolls down the ramp without slipping. The bottom of the ramp is at a height of h₂ = 1.49 m above the floor. The edge of the ramp is a short horizontal section from which the ball leaves to land on the floor. The diameter of the ball is 0.14 m.

(a)

Through what horizontal distance d, in meters, does the ball travel before landing? m

(b)

How many revolutions does the ball make during its fall?  rev

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### Description of the Diagram: The diagram illustrates a simple physics experiment involving potential energy, kinetic energy, and projectile motion. #### Components of the Diagram: 1. **Inclined Plane**: A sloped surface is shown, starting from a height \( h_1 \) to the point where an object becomes a projectile. 2. **Heights**: - \( h_1 \): The height from which the object begins its descent along the inclined plane. - \( h_2 \): The height of the platform from which the object becomes a projectile. 3. **Projectile Motion**: After leaving the inclined plane at the edge of the platform \( h_2 \), the object follows a parabolic trajectory, indicating projectile motion until it reaches the ground. 4. **Horizontal Distance \( d \)**: The horizontal distance covered by the object during its projectile motion from the point it leaves the inclined plane until it reaches the ground. ### Explanation: The diagram demonstrates the conversion of potential energy to kinetic energy as the object moves down the inclined plane and transitions into projectile motion. The object initially at rest at the height \( h_1 \) gains kinetic energy as it descends. Upon reaching the edge of the platform at height \( h_2 \), it is launched horizontally and exhibits projectile motion, traveling a distance \( d \) before hitting the ground. This setup can be used to explore concepts such as energy conservation, gravitational potential energy, and the equations governing projectile motion.