Zeros of Rational Functions

$\newenvironment {prompt}{}{} \newcommand {\ungraded }[0]{} \newcommand {\mooculus }[0]{\textsf {\textbf {MOOC}\textnormal {\textsf {ULUS}}}} \newcommand {\av }[0]{\mathrm {AROC}} \newcommand {\tech }[0]{Desmos} \newcommand {\calcHW }[0]{\includegraphics [width=0.5cm,trim={0 4mm 0 0}]{calc.png} \,} \newcommand {\callout }[0]{\begin {remark}} \newcommand {\overview }[0]{\begin {remark}\textbf {Overview}~} \newcommand {\objectives }[0]{\begin {remark}\textbf {Objectives}\\} \newcommand {\motivatingQuestions }[0]{\begin {remark}\textbf {Motivating Questions}~} \newcommand {\MM }[0]{\begin {remark}\textbf {Metacognitive Moment}~} \newcommand {\licenseAcknowledgement }[0]{Licensed under Creative Commons 4.0} \newcommand {\licenseAPC }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} Active Prelude to Calculus (https://activecalculus.org/prelude) }} \newcommand {\licenseSZ }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} Stitz Zeager Open 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\pgfmathsetmacro {\nextphi }{\curphi + \tdplotsuperfudge *\viewphistep } \par \begin {scope}[opacity=1] \par \par \tdplotcheckdiff {\nextphi }{360}{\origviewphistep }{#2}{} \tdplotcheckdiff {\nextphi }{0}{\origviewphistep }{#2}{} \par \tdplotcheckdiff {\nextphi }{90}{\origviewphistep }{#3}{} \tdplotcheckdiff {\nextphi }{450}{\origviewphistep }{#3}{} \end {scope} \par \foreach \curtheta in{\viewthetastart ,\viewthetainc ,...,\viewthetaend } { \par \pgfmathsetmacro {\curlongitude }{90 -\curphi } \pgfmathsetmacro {\curlatitude }{90 -\curtheta } \par \ifthenelse {\equal {\leftright }{-1.0}}{\pgfmathsetmacro {\curphi }{\curphi -\origviewphistep } }{} \par \pgfmathsetmacro {\tdplottheta }{mod(\curtheta ,360)} \pgfmathsetmacro {\tdplotphi }{mod(\curphi ,360)} \par \pgfmathparse {\tdplotphi <0} \ifthenelse {\equal {\pgfmathresult }{1}}{ \pgfmathsetmacro {\tdplotphi }{\tdplotphi + 360} }{}\par \pgfmathparse {\tdplottheta >\tdplotuppertheta } \pgfmathsetmacro {\logictest }{1 -\pgfmathresult } 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<\tdplotlowerphi } \pgfmathsetmacro {\logictest }{\logictest * (1 -\pgfmathresult )} \par \par \pgfmathsetmacro {\tdplottheta }{\curtheta } \pgfmathsetmacro {\tdplotphi }{\curphi } \par \ifthenelse {\equal {#6}{parametricfill}}{\ifthenelse {\equal {\logictest }{1.0}}{\pgfmathsetmacro {\radius }{#1} \pgfmathsetmacro {\tdplotr }{\radius *360} \par \pgfmathlessthan {\radius }{0} \pgfmathsetmacro {\phaseshift }{180 * \pgfmathresult } \par \pgfmathsetmacro {\colorarg }{#5} \pgfmathsetmacro {\colorarg }{\colorarg + \phaseshift } \pgfmathsetmacro {\colorarg }{mod(\colorarg ,360)} \par \pgfmathlessthan {\colorarg }{0} \pgfmathsetmacro {\colorarg }{\colorarg + 360*\pgfmathresult } \par \pgfmathdivide {\colorarg }{360} \definecolor {tdplotfillcolor}{hsb}{\pgfmathresult ,1,1} \color {tdplotfillcolor} }{}}{\pgfsetfillcolor {#5} } \pgfsetstrokecolor {#4} \par \ifthenelse {\equal {\leftright }{-1.0}}{\pgfmathsetmacro {\curphi }{\curphi + \origviewphistep } }{} \par \ifthenelse {\equal {\logictest 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(\tdplotstopx ,\tdplotstopy ) {$2\pi $}; \par \pgfmathsetmacro {\tdplotstopy }{\tdploty + (360+\tdplothuestep )/2*\tdplotyscale } \node [tdplot_screen_coords,anchor=west,xshift=5pt] at (\tdplotstopx ,\tdplotstopy ) {$\pi $}; } \newcommand {\tdplotgetpolarcoords }[3]{\pgfmathsetmacro {\vxcalc }{#1} \pgfmathsetmacro {\vycalc }{#2} \pgfmathsetmacro {\vzcalc }{#3} \pgfmathsetmacro {\vcalc }{ sqrt((\vxcalc )^2 + (\vycalc )^2 + (\vzcalc )^2) } \par \pgfmathsetmacro {\vxycalc }{ sqrt((\vxcalc )^2 + (\vycalc )^2) } \par \pgfmathsetmacro {\tdplotrestheta }{asin(\vxycalc /\vcalc )} \pgfmathparse {\vzcalc <0} \ifthenelse {\equal {\pgfmathresult }{1}}{\pgfmathsetmacro {\tdplotrestheta }{180 -\tdplotrestheta } } {} \ifthenelse {\equal {\vxcalc }{0.0}}{\pgfmathparse {\vycalc <0} \ifthenelse {\equal {\pgfmathresult }{1}}{\pgfmathsetmacro {\tdplotresphi }{270} } {\pgfmathparse {\vycalc >0} \ifthenelse {\equal {\pgfmathresult }{1}}{\pgfmathsetmacro {\tdplotresphi }{90} } {\pgfmathsetmacro 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We find the zeros of a rational function.

Introduction

Suppose Julia is taking her family on a boat trip $12$ miles down the river and back. The river flows at a speed of $2$ miles per hour and she wants to drive the boat at a constant speed, $v$ miles per hour downstream and back upstream. Due to the current of the river, the actual speed of travel is $v+2$ miles per hour going downstream, and $v-2$ miles per hour going upstream. If Julia plans to spend $8$ hours for the whole trip, how fast should she drive the boat?

The time it takes Julia to drive the boat downstream is $\frac {12}{v+2}$ hours and upstream is $\dfrac {12}{v-2}$ hours. The function to model the whole trip’s time is $t(v)=\frac {12}{v-2}+\frac {12}{v+2}$ where $t$ stands for time in hours. The trip will take $8$ hours, so we want $t(v)$ to equal $8$ , and we have: $\frac {12}{v-2}+\frac {12}{v+2}=8.$

To solve this equation algebraically, we would start by subtracting $8$ from both sides to obtain: $\frac {12}{v-2}+\frac {12}{v+2}-8 = 0.$

This has taken our equation involving rational functions, and converted it into the problem of determining the zeros of a single rational function. Namely, we are really just finding the zeros of $s(v) = \frac {12}{v-2}+\frac {12}{v+2}-8$ . (Notice that the function was changed by subtracting the $8$ , so we had to use a new name for it.)

In the same way, whenever we are asked to find the solution of a rational equation, it is equivalent to finding the zeros of a rational function instead.

Zeros of Rational Functions

Let us finish the calculation started in the Introduction. Find the zeros of $s(v) = \frac {12}{v-2}+\frac {12}{v+2}-8$ .

We will begin by combining the left-hand side into a single fraction. Notice the fractions that appear have a common denominator of $(v-2)(v+2) = v^2 - 4$ .

$\begin{align*} s(v) &= \frac{12}{v-2}+\frac{12}{v+2}-8 \\ &= \frac{12}{v-2} \cdot \left(\frac{v+2}{v+2}\right)+\frac{12}{v+2}\cdot \left(\frac{v-2}{v-2}\right)-8\left(\frac{(v+2)(v-2)}{(v+2)(v-2)}\right) \\ &= \frac{12(v+2)}{(v-2)(v+2)}+\frac{12(v-2)}{(v+2)(v-2)}-\frac{8(v^2-4)}{(v+2)(v-2)} \\ &= \frac{12v+24}{(v+2)(v-2)}+\frac{12v-24}{(v+2)(v-2)}-\frac{8v^2-32}{(v+2)(v-2)} \\ &= \frac{(12v+24)+(12v-24)-(8v^2-32)}{(v+2)(v-2)}\\ &= \frac{-8v^2+(12v+12v)+(24-24+32)}{(v+2)(v-2)}\\ &= \frac{-8v^2+24v+32}{(v+2)(v-2)}. \end{align*}$ That means $s(v) = 0$ is equivalent to the equation $\frac {-8v^2+24v+32}{(v+2)(v-2)} = 0$ .

Since a fraction is zero if and only if the numerator is zero (and the denominator is nonzero), we need to look at $-8v^2+24v+32 = 0$ . We’ll start by factoring, since we see a common factor of $8$ in the coefficients. Actually, let’s factor out $-8$ to clean up the sign of the leading term: $-8v^2+24v+32 = -8( v^2 - 3v - 4 )$ . The quadratic factor $v^2-3v-4$ can be factored to $(v-4)(v+1)$ . That means:

$\begin{align*} \frac{-8v^2+24v+32}{(v+2)(v-2)} &= 0 \\ -8v^2+24v+32 &= 0\\ -8(v^2-3v-4) &= 0\\ -8(v-4)(v+1) &= 0. \end{align*}$ Setting each factor equal to $0$ we see that either $-8 = 0$ (which is impossible), $v-4=0$ (which gives a possible solution of $v=4$ ), and $v+1=0$ (which gives a possible solution of $v=-1$ .

There are two POSSIBLE solutions, $v=-1$ and $v=4$ . The process of solving a rational equation like this can sometimes introduce extraneous solution. That is, a number that appears to be a solution, but doesn’t actually satisfy the original equation.

Let’s plug both of these possibilities back into our original formula for $s(v)$ to verify that they are actually solutions.

$\begin{align*} s(-1) &= \frac{12}{(-1)-2}+\frac{12}{(-1)+2}-8\\ &= \frac{12}{-3} + \frac{12}{1}-8\\ &= -4 + 12 - 8 = 0 \\ \\ s(4) &= \frac{12}{(4)-2}+\frac{12}{(4)+2}-8\\ &= \frac{12}{2} + \frac{12}{6}-8\\ &= 6 + 2 - 8 = 0. \end{align*}$ That means both $v=-1$ and $v=4$ are solutions to the rational equation $\frac {12}{v-2}+\frac {12}{v+2}-8 = 0$ .

Let’s remember where this example came from. In the example, $v$ represented a speed, so it cannot be negative. The only solution is $v = 4$ miles per hour.

Let $f$ be the function given by $f(x) = \frac {1}{x-4} + x -\frac {x-3}{x-4}$ . Find the zeros of the rational function $f$ .

We are being asked to solve the equation $\frac {1}{x-4} + x -\frac {x-3}{x-4} =0$ Notice that the only denominators appearing in the fractions are $x-4$ , so the common denominator is $x-4$ . We start by combining these terms into a single fraction with that denominator.

$\begin{align*} f(x) & = \frac{1}{x-4} + x -\frac{x-3}{x-4} \\ & = \frac{1}{x-4} + x\cdot\left(\frac{x-4}{x-4}\right) -\frac{x-3}{x-4} \\ & = \frac{1}{x-4} + \frac{x(x-4)}{x-4} -\frac{x-3}{x-4} \\ & = \frac{1}{x-4} + \frac{x^2-4x}{x-4} -\frac{x-3}{x-4} \\ & = \frac{(1)+(x^2-4x)-(x-3)}{x-4}\\ & = \frac{x^2 + (-4x-x) + (1+3)}{x-4}\\ & = \frac{x^2 - 5x + 4}{x-4}\\ \end{align*}$ Setting the numerator equal to zero and factoring gives the following. $\begin{align*} f(x) & = 0 \\ \frac{x^2 - 5x + 4}{x-4} &= 0\\ x^2-5x+4 &= 0\\ (x-4)(x-1) &= 0. \end{align*}$

By setting each of these factors equal to $0$ we see that either $x-4=0$ (which gives a possible solution of $x=4$ ) and $x-1=0$ (which gives a possible solution of $x=1$ ). The two possible solutions are $x=4$ and $x=1$ . Let’s check them.

$\begin{align*} f(1) &= \frac{1}{(1)-4} + (1) -\frac{(1)-3}{(1)-4} \\ &= \frac{1}{-3} + 1 - \frac{-2}{-3}\\ &= -\frac{1}{3} + 1 - \frac{2}{3} = 0. \end{align*}$

However, $x=4$ is not in the domain of $f$ , since it makes the denominators of the first and third terms zero. That is, $x=4$ is an extraneous solution.

The only solution is $x=1$ .

Let $g$ be the function given by $g(p) = \frac {3}{p-2} + \frac {5}{p+2}- \frac {12}{p^2-4}$ . Find the zeros of the rational function $g$ .

Since $p^2-4 = (p+2)(p-2)$ , the least common denominator between these three fractions is $(p+2)(p-2) = p^2-4$ . As before, we start by combining into a single fraction with that denominator.

$\begin{align*} g(p) & = \frac{3}{p-2} + \frac{5}{p+2}- \frac{12}{p^2-4} \\ & = \frac{3}{p-2} \cdot \left( \frac{p+2}{p+2}\right)+ \frac{5}{p+2}\cdot \left( \frac{p-2}{p-2}\right)- \frac{12}{p^2-4} \\ & = \frac{3(p+2)}{(p-2)(p+2)}+ \frac{5(p-2)}{(p+2)(p-2)} - \frac{12}{p^2-4} \\ & = \frac{3p+6}{(p+2)(p-2)}+ \frac{5p-10}{(p+2)(p-2)} - \frac{12}{(p+2)(p-2)} \\ & = \frac{(3p+6)+(5p-10)-(12)}{(p+2)(p-2)}\\ & = \frac{(3p+5p)+(6-10-12)}{(p+2)(p-2)}\\ & = \frac{8p-16}{(p+2)(p-2)}\\ \end{align*}$ Setting the numerator equal to zero gives the following. $\begin{align*} 8p-16 & = 0 \\ 8p &= 16\\ p &= \frac{16}{8}=2. \end{align*}$

There is one possible solution, at $p = 2$ .

However, $p=2$ is not in the domain of $g$ , since it makes the denominators of the first and third terms zero. That is, $p=2$ is an extraneous solution.

The function $g$ does not have any zeros.

Let’s look at this last example a bit more. We combined the three terms of $g(p)$ into a single fraction, but that fraction was not in its reduced form.

$\begin{align*} g(p) &= \frac{3}{p-2} + \frac{5}{p+2}- \frac{12}{p^2-4} \\ &= \frac{8p-16}{(p+2)(p-2)} \\ &= \frac{8(p-2)}{(p+2)(p-2)} \\ &= \frac{8\cancel{(p-2)}}{(p+2)\cancel{(p-2)}} \\ &= \frac{8}{(p+2)} \, \text{ , for } p \neq 2. \end{align*}$ Why was $p=-2$ not a zero of the function? Because it was also a zero of the denominator. (Notice the common factor of $p-2$ in both the numerator and denominator.) Rewriting the fraction in lowest terms, we see that the numerator is never zero, since it’s a constant $8$ .

From this example, it may seem that reducing the rational function to lowest terms will always help you bypass the extraneous solutions. That is not the case.

Let $r$ be the function given by $r(t) = \frac {(t+3)(t^2-2t+1)}{t^2-1}$ . Find the zeros of $r$ .

Since we are already given the formula for $r$ as a single fraction, let us simplify.

$\begin{align*} r(t) &= \frac{(t+3)(t^2-2t+1)}{t^2-1}\\ &= \frac{(t+3)(t-1)^2}{(t+1)(t-1)}\\ &= \frac{(t+3)(t-1)(t-1)}{(t+1)(t-1)}\\ &= \frac{(t+3)(t-1)\cancel{(t-1)}}{(t+1)\cancel{(t-1)}}\\ &= \frac{(t+3)(t-1)}{(t+1)} \end{align*}$ The fraction will be zero when the numerator is zero. Setting each of the factors of the numerator equal to zero gives $t+3=0$ (which gives a possible solution of $t=-3$ ), and $t-1=0$ (which gives a possible solution of $t=1$ ).

When we cancelled out the common factor of $t-1$ from the numerator and the denominator, we changed the function without mentioning it. This new fraction $\frac {(t+3)(t-1)}{(t+1)}$ has $t=1$ in its domain, but it is not in the domain of $r$ . To be thorough, after that cancellation we should have written $r(t) = \frac {(t+3)(t-1)}{(t+1)} \, \text {, for } t \neq 1$ to indicate that we’re still using the original domain of $r$ .

The function $r$ has a single zero, at $x=-3$ .