Chapter 2.1, Problem 70E

(a)

To determine

To find: The value of $g$ .

Answer to Problem 70E

The value of $g$ is $1.25$ .

Explanation of Solution

Given information: On a small airless planet a rock is dropped from rest to fall is represented by $y=g{t}^2\text{m}$ in $t\sec$ , $g$ a constant. Assume that the rock falls 20 m below to the bottom of a crevasse and reaches the bottom in $4\sec$ .

Calculation:

As given that rock travels $20\text{m}$ in $4\sec$ .

Substitute $20$ for $y$ and $4$ for $t$ in the given equation.

  $\begin{array}{c}y=g{t}^2\\ 20=g\times 4^2\\ 20=16g\\ g=1.25\end{array}$

Therefore, the value of $g$ is $1.25$ .

(b)

To determine

To find: The average speed for the fall.

Answer to Problem 70E

The average speed for the fall is $5\text{m}/\sec$ .

Explanation of Solution

Given information: On a small airless planet a rock is dropped from rest to fall is represented by $y=g{t}^2\text{m}$ in $t\sec$ , $g$ a constant. Assume that the rock falls 20 m below to the bottom of a crevasse and reaches the bottom in $4\sec$ .

Calculation:

Use the formula for the speed of the object.

  $s=\frac{\Delta y}{\Delta t}$

Now substitute $4$ for $t$ in the equation of path for the distance travelled after $3$ seconds.

  $\begin{array}{c}y=g{t}^2\\ y=1.25t^2\\ y=1.25\times 4^2\\ y=20\end{array}$

Initially the object was at rest so $y=0$ at $t=0$ .

Now substitute these values in formula for speed.

  $\begin{array}{c}s=\frac{\Delta y}{\Delta t}\\ =\frac{y_2-y_1}{t_2-t_1}\\ =\frac{20-0}{4-0}\\ =5\text{m}/\sec \end{array}$

Therefore, the average speed for the fall is $5\text{m}/\sec$ .

(c)

To determine

To find: The speed of the rock when it hits the bottom.

Answer to Problem 70E

The speed of the rock when it hits the bottom is $10\text{m}/\sec$ .

Explanation of Solution

Given information: On a small airless planet a rock is dropped from rest to fall is represented by $y=g{t}^2\text{m}$ in $t\sec$ , $g$ a constant. Assume that the rock falls 20 m below to the bottom of a crevasse and reaches the bottom in $4\sec$ .

Calculation:

The speed of the rock when it hits the bottom is the instantaneous speed of the rock at $t=4\sec$ .

The instantaneous speed of an object at $t=a$ seconds is the average speed from time $t=a$ seconds to $t=a+h$ seconds.

Use the formula for average speed.

  $\begin{array}{c}s=\frac{\Delta y}{\Delta t}\\ =\frac{y_2-y_1}{t_2-t_1}\end{array}$

Substitute $4+h$ for $t$ in the given equation for the distance travelled.

  $y_2=1.25{\left(4+h\right)}^2$

Substitute $4$ for $t$ in the given equation for the distance travelled.

  $\begin{array}{c}{y}_1=1.25{\left(4\right)}^2\\ =1.25\times 16\\ =20\end{array}$

Substitute these values in the formula for average speed.

  $\begin{array}{c}s=\frac{y_2-y_1}{t_2-t_1}\\ =\frac{1.25{\left(4+h\right)}^2-20}{4+h-4}\\ =\frac{1.25{\left(4+h\right)}^2-20}{h}\\ =\frac{1.25\left(16+h^2+8h\right)-20}{h}\end{array}$

Further simplify,

  $\begin{array}{c}s=\frac{20+1.25h^2+10h-20}{h}\\ =\frac{h\left(1.25h+10\right)}{h}\\ =1.25h+10\end{array}$

Substitute $h=0$ for the exact instantaneous speed.

  $\begin{array}{c}s=1.25\times 0+10\\ =10\text{m}/\sec \end{array}$

Therefore, the speed of the rock when it hits the bottom is $10\text{m}/\sec$ .