Chapter 1, Problem 22TP

Solution

a.

To find: the maximum height of volley ball , where the height of the volleyball after $t$ is given by the function $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$ .

The maximum height is $20.0625ft.$

Given information:

The given function is $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$

Concept used:

The general function for the height of an object after launched is given by the function $h=-16t^2+v_{0}t+h_0\text{}\text{}\text{}\text{}\text{};{\text{t-time,h}}_{\text{0}}\text{-intial}height,v_0-\mathrm{i}\text{ntial}\text{velocity}$ .

Calculations:

The given function is $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$

Based on the function, the graph is a parabola and open downwards. Thus from the vertex of the parabola can find out the maximum height.

Since the function is in the standard form of the parabola then

  $x$ coordinate of the vertex:

  $\begin{array}{c}x=\frac{-b}{2a}\\ =\frac{-30}{-32}\\ =\frac{15}{16}\end{array}$

Then the maxium height is:

  $\begin{array}{c}h\left(\frac{15}{16}\right)=-16\times {\left(\frac{15}{16}\right)}^2+30\times \frac{15}{16}+6\\ =20.0625ft\end{array}$

Thus the maximum height is $20.0625ft.$

b.

To find: time in seconds when the volleyball reach the the maximum height, where the height of the volleyball after $t$ is given by the function $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$ .

At the time $t=0.94s$ when the volleyball height reach the maximum height.

Given information:

The given function is $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$

Concept used:

The general function for the height of an object after launched is given by the function $h=-16t^2+v_{0}t+h_0\text{}\text{}\text{}\text{}\text{};{\text{t-time,h}}_{\text{0}}\text{-intial}height,v_0-\mathrm{i}\text{ntial}\text{velocity}$ .

  $x$ coordinate of the vertex $x=\frac{-b}{2a}$ .

Calculations:

The given function is $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$

Based on the function, the graph is a parabola and open downwards. Thus from the vertex of the parabola can find out the maximum height.

Since the function is in the standard form of the parabola then

  $x$ coordinate of the vertex is the time when the vollyball height reach the maximum height.

  $\begin{array}{c}x=\frac{-b}{2a}\\ =\frac{-30}{-32}\\ =\frac{15}{16}\\ =0.94\mathrm{s}\end{array}$

Then at the time $t=0.94s$ when the vollyball height reach the maximum height.

c.

To find: time in seconds when the volleyball hits the ground where the height of the volleyball after $t$ is given by the function $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$ .

At the time $t=2.057s$ when the volleyball hits the ground.

Given information:

The given function is $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$

Concept used:

The general function for the height of an object after launched is given by the function $h=-16t^2+v_{0}t+h_0\text{}\text{}\text{}\text{}\text{};{\text{t-time,h}}_{\text{0}}\text{-intial}height,v_0-\mathrm{i}\text{ntial}\text{velocity}$ .

Calculations:

The given function is $h\left(t\right)=-16t^2+30t+6;h-\mathrm{in}feet.$

When the volleyball hits the ground then height of the volleyball reaches at zero.

  $\begin{array}{l}0=-16t^2+30t+6\\ -16t^2+30t+6=0\\ t=\frac{-30\pm \sqrt{{30}^2+16\times 6}}{2\times -16}\\ =-0.182,2.057\end{array}$

Then at the time $t=2.057s$ when the volleyball hits the ground.