Solveeit Logo
Login

Question

Question: A hang glider dropped his cell phone from a height of 350 feet. How many seconds did it take for the...

A hang glider dropped his cell phone from a height of 350 feet. How many seconds did it take for the cell phone to reach the ground?

Explanation

Solution

A cell phone falls from a certain height above the ground therefore, it is under the influence of gravity. Therefore we can use equations of motion to solve the problem. Substituting corresponding values in the equation, the time can be calculated. Convert the equations as required.

Formula used:
1ft=0.305m1ft=0.305m
s=ut+12at2s=ut+\dfrac{1}{2}a{{t}^{2}}

Complete answer:
Given, a cell phone falls freely from a height of 350 feet.
We know that,
1ft=0.305m1ft=0.305m
Using the above relation we convert 350 feet into metres as-
350ft=350×0.305m 350ft=106.75m \begin{aligned} & 350ft=350\times 0.305m \\\ & \Rightarrow 350ft=106.75m \\\ \end{aligned}
The cell phone is falling freely, therefore its acceleration will be 10ms210m{{s}^{-2}}.
Using the following equation of motion, we get,
s=ut+12at2s=ut+\dfrac{1}{2}a{{t}^{2}}
Here, ss is the distance travelled
uu is the initial velocity
tt is the time taken
aa is the acceleration of the body
Substituting given values in the above equation, we get,
106.75=0+12×10t2 106.75×210=t2 21.35=t2 t=4.62s t5s \begin{aligned} & 106.75=0+\dfrac{1}{2}\times 10{{t}^{2}} \\\ & \Rightarrow \dfrac{106.75\times 2}{10}={{t}^{2}} \\\ & \Rightarrow 21.35={{t}^{2}} \\\ & \Rightarrow t=4.62s \\\ & \therefore t\approx 5s \\\ \end{aligned}
The cell phone reached the ground in about 5s5s.
Therefore, it took about 5s5s for the cell phone to reach the ground.

Additional Information:
The equations of motions are used to describe the motion of an object in a straight line when the acceleration is constant. It gives us the relation between displacement, initial velocity, final velocity, acceleration and time taken. Some equations of motion are; v2=u2+2as{{v}^{2}}={{u}^{2}}+2as, v=u+atv=u+at and s=ut+12at2s=ut+\dfrac{1}{2}a{{t}^{2}}.

Note:
According to Newton’s second law, when a body undergoes acceleration, an external force is acting on it. The acceleration of the cell phone is constant therefore; equations of motions can be applied. In freely falling condition, the body is under acceleration due to gravity. The potential energy of the cell phone will be highest at the top which will then convert into kinetic energy throughout the motion.