Example: Writing a Formula for an Inversely Proportional Relationship

A tourist plans to drive 100 miles. Find a formula for the time the trip will take as a function of the speed the tourist drives.

Answer: Recall that multiplying speed by time gives distance. If we let $t$ represent the drive time in hours, and $v$ represent the velocity (speed or rate) at which the tourist drives, then $vt=$ distance. Because the distance is fixed at 100 miles, $vt=100$. Solving this relationship for the time gives us our function.

\begin{align}t\left(v\right)&=\dfrac{100}{v} \\[1mm] &=100{v}^{-1} \end{align}

We can see that the constant of variation is 100 and, although we can write the relationship using the negative exponent, it is more common to see it written as a fraction.

Example: Solving an Inverse Variation Problem

A quantity $y$ varies inversely with the cube of $x$. If $y=25$ when $x=2$, find $y$ when $x$ is 6.

Answer: The general formula for inverse variation with a cube is $y=\dfrac{k}{{x}^{3}}$. The constant can be found by multiplying $y$ by the cube of $x$.

\begin{align}k&={x}^{3}y \\[1mm] &={2}^{3}\cdot 25 \\[1mm] &=200 \end{align}

Now we use the constant to write an equation that represents this relationship.

\begin{align}y&=\dfrac{k}{{x}^{3}},\hspace{2mm}k=200 \\[1mm] y&=\dfrac{200}{{x}^{3}} \end{align}

Substitute $x=6$ and solve for $y$.

\begin{align}y&=\dfrac{200}{{6}^{3}} \\[1mm] &=\dfrac{25}{27} \end{align}

Analysis of the Solution

The graph of this equation is a rational function.

Example: Solving Problems Involving Joint Variation

A quantity $x$ varies directly with the square of $y$ and inversely with the cube root of $z$. If $x=6$ when $y=2$ and $z=8$, find $x$ when $y=1$ and $z=27$.

Answer: Begin by writing an equation to show the relationship between the variables.

$x=\dfrac{k{y}^{2}}{\sqrt[3]{z}}$

Substitute $x=6$, $y=2$, and $z=8$ to find the value of the constant $k$.

\begin{align}6&=\dfrac{k{2}^{2}}{\sqrt[3]{8}} \\[1mm] 6&=\dfrac{4k}{2} \\[1mm] 3&=k \end{align}

Now we can substitute the value of the constant into the equation for the relationship.

$x=\dfrac{3{y}^{2}}{\sqrt[3]{z}}$

To find $x$ when $y=1$ and $z=27$, we will substitute values for $y$ and $z$ into our equation.

\begin{align}x&=\dfrac{3{\left(1\right)}^{2}}{\sqrt[3]{27}} \\[1mm] &=1 \end{align}