A Cyclist's Leap of Faith: Calculating Cliff Heights

How can we calculate the height of a cliff from which a cyclist has jumped with an initial velocity of 18 m/s and lands 16.6 m away? To calculate the height of the cliff, we first analyze the horizontal motion to find the time in the air. Then, we use this time to determine the vertical displacement. By utilizing the kinematic equations for projectile motion, we can accurately calculate the height of the cliff.

When faced with the task of determining the height of a cliff that a cyclist jumped from, it may initially seem like a daunting challenge. However, by breaking down the problem into its component parts and applying the principles of physics, we can unveil the answer with confidence.

Horizontal Motion Analysis

Initially, let's focus on the horizontal component of the motion. Given that the cyclist jumps off horizontally, the horizontal velocity (vx) remains constant and is equal to the initial velocity of 18 m/s. To find the time in the air (t), we can use the equation t = d / vx, where d is the horizontal distance traveled before touching down, which is 16.6 m in this case.

Vertical Displacement Calculation

Next, we shift our attention to the vertical component of the motion. Since the initial motion is purely horizontal, the vertical component of the initial velocity (vy) is 0 m/s. By utilizing the kinematic equation h = vy × t + (1/2) × g × t², where g is the acceleration due to gravity (9.81 m/s²), we can calculate the vertical displacement. The height of the cliff is then determined to be approximately 4.18 m.

Therefore, through a systematic analysis of the cyclist's leap and the application of fundamental physics principles, we have successfully calculated the height of the cliff to be approximately 4.18 meters. This showcases the beauty and power of physics in unraveling the mysteries of motion and height in seemingly complex scenarios.
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