Range

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Source Mathematics (https://www.stitz-zeager.com/) }} \newcommand {\licenseAPCSZ }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} Active Prelude to Calculus (https://activecalculus.org/prelude) and Stitz Zeager Open Source Mathematics (https://www.stitz-zeager.com/) }} \newcommand {\licenseORCCA }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} Original source material,products with readable and accessible math content,and other information freely available at pcc.edu/orcca.}} \newcommand {\licenseY }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} Yoshiwara Books (https://yoshiwarabooks.org/)}} \newcommand {\licenseOS }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} OpenStax College Algebra (https://openstax.org/details/books/college-algebra)}} \newcommand {\licenseAPCSZCSCC }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} Source material includes: Active Prelude to Calculus (https://activecalculus.org/prelude),Stitz Zeager Open Source Mathematics (https://www.stitz-zeager.com/),CSCC PreCalculus and Calculus texts (https://ximera.osu.edu/csccmathematics)}} \newcommand {\licenseAPCSZORCCA }[0]{\renewcommand {\licenseAcknowledgement }{\textbf {Acknowledgements:} Source material includes: Active Prelude to Calculus (https://activecalculus.org/prelude),Stitz Zeager Open Source Mathematics (https://www.stitz-zeager.com/),ORCCA: Original source material,products with readable and accessible math content,and other information freely available at pcc.edu/orcca.}} \newcommand {\sectionHeadStyle }[0]{\sffamily \bfseries } \newcommand {\thepart }[0]{\arabic {part}} \newcommand {\RR }[0]{\mathbb R} \newcommand {\R }[0]{\mathbb R} \newcommand {\N }[0]{\mathbb N} \newcommand {\Z }[0]{\mathbb Z} \newcommand {\sagemath }[0]{\textsf {SageMath}} \newcommand {\l }[0]{\ell } \newcommand {\ddx }[0]{\frac {d}{\d x}} \newcommand {\unit }[0]{\mathop {}\!\mathrm } 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{\tdplotresz }{\rcaeul * #1 + \rcbeul * #2 + \rcceul * #3} } \newcommand {\tdplottransformrotmain }[3]{\tdplotcalctransformrotmain \par \pgfmathsetmacro {\tdplotresx }{\raaeul * #1 + \rabeul * #2 + \raceul * #3} \pgfmathsetmacro {\tdplotresy }{\rbaeul * #1 + \rbbeul * #2 + \rbceul * #3} \pgfmathsetmacro {\tdplotresz }{\rcaeul * #1 + \rcbeul * #2 + \rcceul * #3} } \newcommand {\tdplottransformmainscreen }[3]{\tdplotcalctransformmainscreen \par \pgfmathsetmacro {\tdplotresx }{\raarot * #1 + \rabrot * #2 + \racrot * #3} \pgfmathsetmacro {\tdplotresy }{\rbarot * #1 + \rbbrot * #2 + \rbcrot * #3} } \newcommand {\tdplotsetrotatedcoords }[3]{\pgfmathsetmacro {\tdplotalpha }{#1} \pgfmathsetmacro {\tdplotbeta }{#2} \pgfmathsetmacro {\tdplotgamma }{#3} \tdplotcalctransformrotmain \par \tdplotmult {\raaeaa }{\raarot }{\raaeul } \tdplotmult {\rabeba }{\rabrot }{\rbaeul } \tdplotmult {\raceca }{\racrot }{\rcaeul } \tdplotmult {\raaeab }{\raarot }{\rabeul } \tdplotmult {\rabebb }{\rabrot }{\rbbeul } \tdplotmult {\racecb }{\racrot }{\rcbeul } \tdplotmult {\raaeac }{\raarot }{\raceul } \tdplotmult {\rabebc }{\rabrot }{\rbceul } \tdplotmult {\racecc }{\racrot }{\rcceul } \tdplotmult {\rbaeaa }{\rbarot }{\raaeul } \tdplotmult {\rbbeba }{\rbbrot }{\rbaeul } \tdplotmult {\rbceca }{\rbcrot }{\rcaeul } \tdplotmult {\rbaeab }{\rbarot }{\rabeul } \tdplotmult {\rbbebb }{\rbbrot }{\rbbeul } \tdplotmult {\rbcecb }{\rbcrot }{\rcbeul } \tdplotmult {\rbaeac }{\rbarot }{\raceul } \tdplotmult {\rbbebc }{\rbbrot }{\rbceul } \tdplotmult {\rbcecc }{\rbcrot }{\rcceul } \pgfmathsetmacro {\raarc }{\raaeaa + \rabeba + \raceca } \pgfmathsetmacro {\rabrc }{\raaeab + \rabebb + \racecb } \pgfmathsetmacro {\racrc }{\raaeac + \rabebc + \racecc } \pgfmathsetmacro {\rbarc }{\rbaeaa + \rbbeba + \rbceca } \pgfmathsetmacro {\rbbrc }{\rbaeab + \rbbebb + \rbcecb } \pgfmathsetmacro {\rbcrc }{\rbaeac + \rbbebc + \rbcecc } \tikzset {tdplot_rotated_coords/.append style={x={(\raarc cm,\rbarc cm)},y={(\rabrc cm,\rbbrc cm)},z={(\racrc cm,\rbcrc cm)}}}} \newcommand {\tdplotsetrotatedcoordsorigin }[1]{\tikzset {tdplot_rotated_coords/.append style={shift=#1}}} \newcommand {\tdplotresetrotatedcoordsorigin }[0]{\tikzset {tdplot_rotated_coords/.append style={shift={(0,0,0)}}}} \newcommand {\tdplotsetthetaplanecoords }[1]{\tdplotresetrotatedcoordsorigin \tdplotsetrotatedcoords {270 + #1}{270}{0}} \newcommand {\tdplotsetrotatedthetaplanecoords }[1]{\tdplotsetrotatedcoords {\tdplotalpha }{\tdplotbeta }{\tdplotgamma + #1}\tikzset {tdplot_rotated_coords/.append style={y={(\raarc cm,\rbarc cm)},z={(\rabrc cm,\rbbrc cm)},x={(\racrc cm,\rbcrc cm)}}}} \newcommand {\tdplotsetcoord }[4]{\tdplotsinandcos {\sinthetavec }{\costhetavec }{#3}\tdplotsinandcos {\sinphivec }{\cosphivec }{#4}\tdplotmult {\stcpv }{\sinthetavec }{\cosphivec }\tdplotmult {\stspv }{\sinthetavec }{\sinphivec }\coordinate (#1) at ($#2*(\stcpv ,\stspv ,\costhetavec )$); \coordinate (#1xy) at ($#2*(\stcpv ,\stspv ,0)$); \coordinate (#1xz) at ($#2*(\stcpv ,0,\costhetavec )$); \coordinate (#1yz) at ($#2*(0,\stspv ,\costhetavec )$); \coordinate (#1x) at ($#2*(\stcpv ,0,0)$); \coordinate (#1y) at ($#2*(0,\stspv ,0)$); \coordinate (#1z) at ($#2*(0,0,\costhetavec )$); } \newcommand {\tdplotsimplesetcoord }[4]{\tdplotsinandcos {\sinthetavec }{\costhetavec }{#3}\tdplotsinandcos {\sinphivec }{\cosphivec }{#4}\tdplotmult {\stcpv }{\sinthetavec }{\cosphivec }\tdplotmult {\stspv }{\sinthetavec }{\sinphivec }\coordinate (#1) at ($#2*(\stcpv ,\stspv ,\costhetavec )$); } \newcommand {\tdplotsetpolarplotrange }[4]{\pgfmathsetmacro {\tdplotlowerphi }{#3} \pgfmathsetmacro {\tdplotupperphi }{#4} \pgfmathsetmacro {\tdplotlowertheta }{#1} \pgfmathsetmacro {\tdplotuppertheta }{#2} } \newcommand {\tdplotresetpolarplotrange }[0]{\pgfmathsetmacro {\tdplotlowerphi }{0} \pgfmathsetmacro {\tdplotupperphi }{360} \pgfmathsetmacro {\tdplotlowertheta }{0} \pgfmathsetmacro {\tdplotuppertheta }{180} } \newcommand {\tdplotdosurfaceplot }[6]{\par \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 } \par \pgfmathparse {\tdplottheta <\tdplotlowertheta } \pgfmathsetmacro {\logictest }{\logictest * (1 -\pgfmathresult )} \par \pgfmathsetmacro {\tdplottheta }{\tdplottheta + \viewthetastep } \pgfmathparse {\tdplottheta >\tdplotuppertheta } \pgfmathsetmacro {\logictest }{\logictest * (1 -\pgfmathresult )} \par \pgfmathparse {\tdplottheta <\tdplotlowertheta } \pgfmathsetmacro {\logictest }{\logictest * (1 -\pgfmathresult )} \par \pgfmathparse {\tdplotphi >\tdplotupperphi } \pgfmathsetmacro {\logictest }{\logictest * (1 -\pgfmathresult )} \par \pgfmathparse {\tdplotphi <\tdplotlowerphi } \pgfmathsetmacro {\logictest }{\logictest * (1 -\pgfmathresult )} \par \pgfmathsetmacro {\tdplotphi }{\tdplotphi + \viewphistep } \par \pgfmathparse {\tdplotphi <0} \ifthenelse {\equal {\pgfmathresult }{1}}{ \pgfmathsetmacro {\tdplotphi }{\tdplotphi + 360} }{}\par \pgfmathparse {\tdplotphi >\tdplotupperphi } \pgfmathsetmacro {\logictest }{\logictest * (1 -\pgfmathresult )} \par \pgfmathparse {\tdplotphi <\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 }{1.0}}{\pgfmathsetmacro {\radius }{abs(#1)} \pgfpathmoveto {\pgfpointspherical {\curlongitude }{\curlatitude }{\radius }} \par \pgfmathsetmacro {\tdplotphi }{\curphi + \viewphistep } \pgfmathsetmacro {\radius }{abs(#1)} \pgfpathlineto {\pgfpointspherical {\curlongitude -\viewphistep }{\curlatitude }{\radius }} \par \pgfmathsetmacro {\tdplottheta }{\curtheta + \viewthetastep } \pgfmathsetmacro {\radius }{abs(#1)} \pgfpathlineto {\pgfpointspherical {\curlongitude -\viewphistep }{\curlatitude -\viewthetastep }{\radius }} \par \pgfmathsetmacro {\tdplotphi }{\curphi } \pgfmathsetmacro {\radius }{abs(#1)} \pgfpathlineto {\pgfpointspherical {\curlongitude }{\curlatitude -\viewthetastep }{\radius }} \pgfpathclose \par \pgfusepath {fill,stroke} }{} } } \newcommand {\tdplotshowargcolorguide }[4]{ \par \pgfmathsetmacro {\tdplotx }{#1} \pgfmathsetmacro {\tdploty }{#2} \pgfmathsetmacro {\tdplothuestep }{5} \pgfmathsetmacro {\tdplotxsize }{#3} \pgfmathsetmacro {\tdplotysize }{#4} \par \pgfmathsetmacro {\tdplotyscale }{\tdplotysize /360} \par \foreach \tdplotphi in {0,\tdplothuestep ,...,360} { \pgfmathdivide {\tdplotphi }{360} \definecolor {tdplotfillcolor}{hsb}{\pgfmathresult ,1,1} \color {tdplotfillcolor} \par \pgfmathsetmacro {\tdplotstarty }{\tdploty + \tdplotphi * \tdplotyscale } \pgfmathsetmacro {\tdplotstopy }{\tdplotstarty + \tdplothuestep * \tdplotyscale } \pgfmathsetmacro {\tdplotstartx }{\tdplotx } \pgfmathsetmacro {\tdplotstopx }{\tdplotx + \tdplotxsize } \filldraw [tdplot_screen_coords] (\tdplotstartx ,\tdplotstarty ) rectangle (\tdplotstopx ,\tdplotstopy ); } \par \pgfmathsetmacro {\tdplotstopy }{\tdploty + (360+\tdplothuestep )*\tdplotyscale } \pgfmathsetmacro {\tdplotstopx }{\tdplotx + \tdplotxsize } \par \draw [tdplot_screen_coords] (\tdplotx ,\tdploty ) rectangle (\tdplotstopx ,\tdplotstopy ); \par \node [tdplot_screen_coords,anchor=west,xshift=5pt] at (\tdplotstopx ,\tdploty ) {$0$}; \node [tdplot_screen_coords,anchor=west,xshift=5pt] at (\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 examine the outputs that are actually achieved.

Motivating Questions

If $f$ is a function from a set $A$ to a set $B$ , does every item in $B$ actually get related to something from $A$ ?

Introduction

In the last section, for a function from $A$ to $B$ , we called the set $A$ the domain and we called the set $B$ the codomain.

Let $f$ be the function defined by $f(x) = x^2$ . We can consider this a function from the set of all real numbers $(-\infty , \infty )$ to the set of all real numbers $(-\infty , \infty )$ . In this case, the domain is $(-\infty , \infty )$ and the codomain is also $(-\infty , \infty )$ . We know that for any real number $x$ , the value of $x^2$ is never negative. That means there is no input to $f$ that ever gives a negative output.

Let $g$ be the function from the set of capital letters to the set of natural numbers, which assigns each letter to its placement in the alphabet. This means $g(A)=1$ since ‘A’ is the first letter of the alphabet. Similarly $g(B) = 2$ and $g(Z)=26$ . In this case the domain is the set of capital letters $\{ A, B, C, \ldots , Z\}$ and the codomain is the set of natural numbers $\{1, 2, 3, 4, \ldots \}$ . For the function $g$ there are only 26 capital letters in the alphabet, so no number past greater than 26 is ever an output of $g$ .

For both the function $f$ and $g$ just given, not every number in the codomain is actually achieved as the output of the function. There is a difference between the codomain, which measures the “possible outputs” and the actual outputs that are achieved.

a.: Suppose the quadratic function $f$ is given by $f(x) = x^2$ . Are there any values that are never achieved as an output?
b.: Explain the difference in finding the domain of a function and finding the range of the function, if you are given the graph of the function. What if you’re given a formula for the function instead?

The Range of a Function

Let $f$ be a function from $A$ to $B$ . The range of $f$ is the collection of the outputs of $f$ .

This means the range consists of the outputs that are actually achieved. Not everything that is “possible”, but only those outputs that actually come out of the function. For each $b$ in the range of the function $f$ , there is actually an $a$ in the domain with $f(a) = b$ .

Let $f$ be the function defined by the following table. Find the range of $f$ . $\begin {array}{c|c} x & f(x)\\\hline 0 & 3\\ 1 & -2\\ 2 & 4\\ 3 & 3\\ 4 & 0 \end {array}$

The only outputs of this function are $-2$ , $0$ , $3$ , and $4$ . (Even though the output $3$ is identified twice, it only gets counted once here.) There are no intervals, just the separated points. The range of $f$ is $\{ -2, 0, 3, 4 \}$ . Including individual numbers in curly brackets means we are considering the set whose only members are those individual numbers.

Let $s$ be the function given by $s(t) = \dfrac {1}{t}$ . Is $-\frac {1}{2}$ in the range of $s$ ? What about $\sqrt {5}$ or $0$ ?

If we want to see if $-\frac {1}{2}$ is in the range of $s$ , that means we need to check whether there is a number $a$ in the domain of $s$ with $s(a) = -\frac {1}{2}$ .

$\begin{align*} s(a) &= -\frac{1}{2}\\ \frac{1}{a} &= -\frac{1}{2}\\ 2a \left( \frac{1}{a} \right) &= 2a \left( - \frac{1}{2} \right)\\ \frac{2a}{a} &= -\frac{2a}{2}\\ 2 &= -a \\ -2 &= a \end{align*}$ That means $s(-2) = -\frac {1}{2}$ . We found an input that gives the output value $-\frac {1}{2}$ , which means $-\frac {1}{2}$ is in the range of $s$ .

Let’s try the same calculation for $\sqrt {5}$ .

$\begin{align*} s(b) &= \sqrt{5}\\ \frac{1}{b} &= \sqrt{5}\\ b \left( \frac{1}{b} \right) &= b \left( \sqrt{5} \right)\\ 1 &= b\sqrt{5}\\ \frac{1}{\sqrt{5}} &= b \end{align*}$ That means $s\left (\frac {1}{\sqrt {5}} \right ) = \sqrt {5}$ , so that $\sqrt {5}$ is in the range of $s$ .

Now for $0$ :

$\begin{align*} s(c) &= 0\\ \frac{1}{c} &= 0\\ c \left( \frac{1}{c} \right) &= c \left( 0 \right)\\ 1 &= c(0) \end{align*}$ This statement is false for all choices of $c$ . That means there is no value of $c$ with $s(c)=0$ . In particular, $0$ is not in the range of $s$ .

The entire graph of a function $g$ is given in the graph below. Find the range of $g$ .

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Notice that as $x$ changes between $-6$ to $0$ , the graph takes all outputs from $6$ to $0$ (not including the endpoints). As $x$ changes from $0$ to $2$ , all the numbers from $-4$ to $0$ show up as outputs (including $0$ ). Together, this means that every number in the interval $(-4, 6)$ is in the range. The last two pieces of the graph have outputs $4$ and $-1$ , which are already included in this interval.

The range is $(-4, 6)$ .

Let $f$ be the function given by $f(x) = 3x-5$ . Find the range of $f$ .

We know the domain of $f$ is $(-\infty , \infty )$ , so any real number is a valid input. We also know that $f$ is a linear polynomial function (a polynomial of degree 1) so we know what its graph is a straight line with slope $m = 3$ .

Since this graph goes higher and higher as $x$ travels to the right, and lower as $x$ travels to the left, we believe that every number is eventually an output of this function.

Let’s make a calculation to be sure that’s true by taking an arbitrary real number and show that it’s actually an output of $f$ . If $a$ and $b$ are real numbers with $f(a)=b$ , then

$\begin{align*} f(a) &= b\\ 3a-5 &= b\\ 3a &= b + 5\\ a &= \dfrac{b+5}{3}. \end{align*}$

That means that if $b$ is any arbitrary real number, then $f\left ( \frac {b+5}{3} \right ) = b$ so that $b$ is achieved as an output of the function, so $b$ is in the range. In other words, this gives us a formula to identify an input that gives $b$ as an output. This means the range of $f$ is $(-\infty , \infty )$ .

The Range of Famous Functions

(a)

The Absolute Value function - The average value of a number is never negative. The Absolute Value function has range $[0, \infty )$ .

(b)

Polynomial functions - This depends on the degree of the polynomial.

(i)

Odd degree - The range is $(-\infty , \infty )$ .

(ii)

Even degree - We can only be precise with monomials (polynomials with only one term) like $5x^2$ or $-6x^8$ .

i.: If the monomial has positive coefficient, the range is $[0, \infty )$ .
ii.: If the monomial has negative coefficient, the range is $(-\infty , 0]$ .
iii.: If the monomial is a constant $c$ , the range is $\{c\}$ .

(c)

The Square Root function - Even-index radicals never have negative outputs. Their range is $[0, \infty )$ .

(d)

Exponential functions - Exponential functions $b^x$ , for $b >0$ with $b \neq 1$ , have range $(0, \infty )$ . Notice that $0$ is never an output for these kinds of functions.

(e)

Logarithms - Logarithms have range $(-\infty , \infty )$ .

(f)

The Sine function - The sine function $\sin (x)$ has range $[-1,1]$ .

For polynomials, if we know the turning points or maximum or minimum values of the polynomial (as in the case of a parabola), you can determine the range of the polynomial. Unfortunately, finding these in general requires calculus.

Spotting Values not in the Range

Finding the range of a function is quite a bit more involved than finding the domain. Here are some guidelines if you are given a formula for the function instead of its graph.

(a): The output of an even-index radical is never negative.
(b): The output of $x^n$ is never negative if $n$ is an even natural number.
(c): The output of an exponential function $b^x$ is always positive.

Find the range of the following functions

(a): $\displaystyle f(x) = 2 - 4 \sqrt {x}$ .
(b): $\displaystyle g(x) = e^x + \frac {1}{2}$ .
(c): $\displaystyle h(x) = 3 + 5\sin (x)$ .

You’ll notice in these calculations, that finding the range of a function is a great deal more complicated than finding the domain, unless we have an accurate graph of the function, as above.

For each of these calculations, we will follow the same two steps. The idea is that the first step shows that the range is “no more than” the interval we build, and the second step shows that the range is “no less than” that interval. The only possibility left to us is that the range is exactly the interval we have constructed.

More specifically, in the first step will find a bound on the range. We’ll determine if any numbers are too big or too small to be a valid output of the function. This will give us an interval that the range will have to be inside. In the second step, we’ll see that everything inside that interval is actually attained by the function, by constructing an input value that gets assigned to that output.

(a)

Let’s start by looking at the graph of $f$

Notice that the graph of $f$ looks similar to what we know for $\sqrt {x}$ , but upside down, stretched, and moved up. From the graph, we would say that the range should be $(-\infty , 2]$ . Let’s see how we can verify that with a few calculations.

We know that the range of $\sqrt {x}$ is $[0, \infty )$ so for any $x$ in the domain of $f$ ,

$\begin{align*} \sqrt{x} &\geq 0\\ -4 \sqrt{x} &\leq 0 \\ 2 - 4\sqrt{x} &\leq 2 \\ f(x) &\leq 2 \end{align*}$ The outputs of $f$ are never larger than $2$ , so the only numbers in the range are less than or equal to $2$ . That is, the range must be inside the interval $(-\infty , 2]$ .

Metacognitive Moment Notice that this process is just looking at how function transformations are changing the range by undoing the transformations one at a time.

To verify that the range is exactly $(-\infty , 2]$ , suppose $b \leq 2$ , then:

$\begin{align*} f(a) &= b\\ 2 - 4\sqrt{a} &= b\\ -4\sqrt{a} & = b-2\\ \sqrt{a} &= \frac{b-2}{-4}\\ \sqrt{a}&= \frac{-(b-2)}{4}\\ \sqrt{a}&= \frac{-b+2}{4}\\ \left(\sqrt{a}\right)^2&= \left(\frac{-b+2}{4}\right)^2\\ a &= \left( \frac{-b+2}{4} \right)^2. \end{align*}$

For this value of $a$ , we have $f\left ( a \right ) = b$ . That means $b$ is in the range of $f$ . That means every number in the interval $(-\infty , 2]$ is in the range of $f$ .

The range of $f$ is $(-\infty , 2]$ .

(b)

The graph of $g$ looks like this.

This graph looks exactly like the graph of our famous function $e^x$ , just moved vertically upward by $\frac {1}{2}$ . The range of $e^x$ is $(0, \infty )$ , so our range should be shifted by $\frac {1}{2}$ to be $\left ( \frac {1}{2}, \infty \right )$ .

To verify this with a calculation, the fact that $e^x$ has range $(0,\infty )$ means for any value of $x$ ,

$\begin{align*} e^x &> 0\\ e^x + \frac{1}{2} &> \frac{1}{2} \end{align*}$ The outputs of $g$ are greater than $\frac {1}{2}$ , so the range of $g$ is in the interval $\left ( \frac {1}{2}, \infty \right )$ .

To verify that the range is exactly $\left ( \frac {1}{2}, \infty \right )$ , suppose $b > \frac {1}{2}$ , then:

$\begin{align*} g(a) &= b\\ e^a + \frac{1}{2} &= b\\ e^a & = b-\frac{1}{2} \end{align*}$ Since the range of $e^x$ is $(0, \infty )$ , and $b-\frac {1}{2} > 0$ , there is a value for $a$ with $e^a = b-\frac {1}{2}$ .

(For instance, if $b=1$ , that would mean $b-\frac {1}{2} = \frac {1}{2}$ , so we would be looking to see if there is a value of $a$ with $e^a = \frac {1}{2}$ . This is illustrated in the graph below.)

For this value of $a$ , we have $g\left ( a \right ) = b$ , meaning that $b$ is in the range of $g$ . The range of $g$ is $\left ( \frac {1}{2}, \infty \right )$ .

(c)

The graph of $h$ is given below, from which it appears the range of $h$ is $[-2, 8]$ .

The range of our famous function $sine$ is $[-1, 1]$ . That means for any $x$

$\begin{align*} -1 &\leq \sin(x) \leq 1\\ -5 &\leq 5\sin(x) \leq 5\\ 3+(-5) &\leq 3+5\sin(x) \leq 3+5\\ -2 &\leq 3+5\sin(x) \leq 8 \end{align*}$ The outputs of $h$ are in the interval $[-2, 8]$ . To verify that the range is exactly $[-2, 8]$ , suppose $b$ is a number with $-2 \leq b \leq 8$ . Then: $\begin{align*} h(a) &= b\\ 3 + 5\sin(a) &= b\\ 5\sin(a)& = b-3\\ \sin(a) &= \frac{b-3}{5}. \end{align*}$ Because $-2 \leq b \leq 8$ , we know $-1 \leq \frac {b-3}{5} \leq 1$ . That means there is a number $a$ with $\sin (a) = \frac {b-3}{5}$ , since the range of sine is $[-1,1]$ .

(For instance, if $b=3$ then $\frac {b-3}{5} = 0$ so we would be looking for a value of $a$ with $\sin (a) = 0$ . We know that $\sin (0) = 0$ , so this means we’d take $a=0$ .) For this value of $a$ , we have $h(a) = b$ , so $b$ is in the range of $h$ . The range of $h$ is then $[-2, 8]$ .