Graphs of Exponential Functions

Graph exponential functions.
Graph exponential functions using transformations.

As we discussed in the previous section, exponential functions are used for many real-world applications such as finance, forensics, computer science, and most of the life sciences. Working with an equation that describes a real-world situation gives us a method for making predictions. Most of the time, however, the equation itself is not enough. We learn a lot about things by seeing their pictorial representations, and that is exactly why graphing exponential equations is a powerful tool. It gives us another layer of insight for predicting future events.

Graphing Exponential Functions

Before we begin graphing, it is helpful to review the behavior of exponential growth. Recall the table of values for a function of the form $f (x) = b^{x}$

whose base is greater than one. We’ll use the function $f (x) = 2^{x} .$

Observe how the output values in [link] change as the input increases by $1.$

$x$	$- 3$	$- 2$	$- 1$	$0$	$1$	$2$	$3$
$f (x) = 2^{x}$	$\frac{1}{8}$	$\frac{1}{4}$	$\frac{1}{2}$	$1$	$2$	$4$	$8$

Each output value is the product of the previous output and the base, $2.$

We call the base $2$

the constant ratio. In fact, for any exponential function with the form $f (x) = a b^{x},$

b

is the constant ratio of the function. This means that as the input increases by 1, the output value will be the product of the base and the previous output, regardless of the value of $a .$

Notice from the table that

the output values are positive for all values of $x;$
as $x$
increases, the output values increase without bound; and
as $x$
decreases, the output values grow smaller, approaching zero.

[link] shows the exponential growth function $f (x) = 2^{x} .$

Graph of the exponential function, 2^(x), with labeled points at (-3, 1/8), (-2, ¼), (-1, ½), (0, 1), (1, 2), (2, 4), and (3, 8). The graph notes that the x-axis is an asymptote.

The domain of $f (x) = 2^{x}$

is all real numbers, the range is $(0, \infty),$

and the horizontal asymptote is $y = 0.$

To get a sense of the behavior of exponential decay, we can create a table of values for a function of the form $f (x) = b^{x}$

whose base is between zero and one. We’ll use the function $g (x) = {(\frac{1}{2})}^{x} .$

Observe how the output values in [link] change as the input increases by $1.$

</math></strong> | $-3$

-2

-1

0

1

2

3

g (x) = (\frac{1}{2})^{x}

8

4

2

1

\frac{1}{2}

\frac{1}{4}

\frac{1}{8}

Again, because the input is increasing by 1, each output value is the product of the previous output and the base, or constant ratio $\frac{1}{2} .$

Notice from the table that

the output values are positive for all values of $x;$
as $x$
increases, the output values grow smaller, approaching zero; and
as $x$
decreases, the output values grow without bound.

[link] shows the exponential decay function, $g (x) = {(\frac{1}{2})}^{x} .$

Graph of decreasing exponential function, (1/2)^x, with labeled points at (-3, 8), (-2, 4), (-1, 2), (0, 1), (1, 1/2), (2, 1/4), and (3, 1/8). The graph notes that the x-axis is an asymptote.

The domain of $g (x) = {(\frac{1}{2})}^{x}$

is all real numbers, the range is $(0, \infty),$

and the horizontal asymptote is $y = 0.$

Characteristics of the Graph of the Parent Function *f*(*x*) = *b*^*x*

An exponential function with the form $f (x) = b^{x},$

b > 0,

b \neq 1,

has these characteristics:

one-to-one function
horizontal asymptote: $y = 0$
domain: $(- \infty, \infty)$
range: $(0, \infty)$
x-intercept: none
y-intercept: $(0, 1)$
increasing if $b > 1$
decreasing if $b < 1$

[link] compares the graphs of exponential growth and decay functions.

Graph of two functions where the first graph is of a function of f(x) = b^x when b>1 and the second graph is of the same function when b is 0<b<1. Both graphs have the points (0, 1) and (1, b) labeled.

**Given an exponential function of the form $f (x) = b^{x},$

graph the function.**

Create a table of points.
Plot at least $3$
point from the table, including the y-intercept
$(0, 1) .$
Draw a smooth curve through the points.
State the domain, $(- \infty, \infty),$
the range,
$(0, \infty),$
and the horizontal asymptote,
$y = 0.$

Sketching the Graph of an Exponential Function of the Form *f*(*x*) = *b*^*x*

Sketch a graph of $f (x) = {0.25}^{x} .$

State the domain, range, and asymptote.

Before graphing, identify the behavior and create a table of points for the graph.

Since $b = 0.25$
is between zero and one, we know the function is decreasing. The left tail of the graph will increase without bound, and the right tail will approach the asymptote
$y = 0.$
Create a table of points as in [link]. | x
</math></strong> | $- 3$

$- 2$

$- 1$

$0$

$1$

$2$

$3$

| |
f(x)= 0.25 x
</math></strong> | $64$

$16$

$4$

$1$

$0.25$

$0.0625$

$0.015625$
Plot the y-intercept, $(0, 1),$
along with two other points. We can use
$(- 1, 4)$
and
$(1, 0.25) .$

Draw a smooth curve connecting the points as in [link].

Graph of the decaying exponential function f(x) = 0.25^x with labeled points at (-1, 4), (0, 1), and (1, 0.25).

The domain is $(- \infty, \infty);$

the range is $(0, \infty);$

the horizontal asymptote is $y = 0.$

Sketch the graph of $f (x) = 4^{x} .$

State the domain, range, and asymptote.

The domain is $(- \infty, \infty);$

the range is $(0, \infty);$

the horizontal asymptote is $y = 0.$

Graph of the increasing exponential function f(x) = 4^x with labeled points at (-1, 0.25), (0, 1), and (1, 4).

Graphing Transformations of Exponential Functions

Transformations of exponential graphs behave similarly to those of other functions. Just as with other parent functions, we can apply the four types of transformations—shifts, reflections, stretches, and compressions—to the parent function $f (x) = b^{x}$

without loss of shape. For instance, just as the quadratic function maintains its parabolic shape when shifted, reflected, stretched, or compressed, the exponential function also maintains its general shape regardless of the transformations applied.

Graphing a Vertical Shift

The first transformation occurs when we add a constant $d$

to the parent function $f (x) = b^{x},$

giving us a vertical shift $d$

units in the same direction as the sign. For example, if we begin by graphing a parent function, $f (x) = 2^{x},$

we can then graph two vertical shifts alongside it, using $d = 3 :$

the upward shift, $g (x) = 2^{x} + 3$

and the downward shift, $h (x) = 2^{x} - 3.$

Both vertical shifts are shown in [link].

Graph of three functions, g(x) = 2^x+3 in blue with an asymptote at y=3, f(x) = 2^x in orange with an asymptote at y=0, and h(x)=2^x-3 with an asymptote at y=-3. Note that each functions’ transformations are described in the text.

Observe the results of shifting $f (x) = 2^{x}$

vertically:

The domain, $(- \infty, \infty)$
remains unchanged.
When the function is shifted up 3
units to
g(x)= 2 x +3:
- The y-intercept shifts up $3$
  units to
  $(0, 4) .$
- The asymptote shifts up $3$
  units to
  $y = 3.$
- The range becomes $(3, \infty) .$
When the function is shifted down 3
units to
h(x)= 2 x −3:
- The y-intercept shifts down $3$
  units to
  $(0, - 2) .$
- The asymptote also shifts down $3$
  units to
  $y = - 3.$
- The range becomes $(- 3, \infty) .$

Graphing a Horizontal Shift

The next transformation occurs when we add a constant $c$

to the input of the parent function $f (x) = b^{x},$

giving us a horizontal shift $c$

units in the opposite direction of the sign. For example, if we begin by graphing the parent function $f (x) = 2^{x},$

we can then graph two horizontal shifts alongside it, using $c = 3 :$

the shift left, $g (x) = 2^{x + 3},$

and the shift right, $h (x) = 2^{x - 3} .$

Both horizontal shifts are shown in [link].

Graph of three functions, g(x) = 2^(x+3) in blue, f(x) = 2^x in orange, and h(x)=2^(x-3). Each functions’ asymptotes are at y=0Note that each functions’ transformations are described in the text.

Observe the results of shifting $f (x) = 2^{x}$

horizontally:

The domain, $(- \infty, \infty),$
remains unchanged.
The asymptote, $y = 0,$
remains unchanged.
The y-intercept shifts such that:
- When the function is shifted left $3$
  units to
  $g (x) = 2^{x + 3},$
  the y-intercept becomes
  $(0, 8) .$
  This is because
  $2^{x + 3} = (8) 2^{x},$
  so the initial value of the function is
  $8.$
- When the function is shifted right $3$
  units to
  $h (x) = 2^{x - 3},$
  the y-intercept becomes
  $(0, \frac{1}{8}) .$
  Again, see that
  $2^{x - 3} = (\frac{1}{8}) 2^{x},$
  so the initial value of the function is
  $\frac{1}{8} .$

Shifts of the Parent Function *f*(*x*) = *b*^*x*

For any constants $c$

and $d,$

the function $f (x) = b^{x + c} + d$

shifts the parent function $f (x) = b^{x}$

vertically $d$
units, in the same direction of the sign of
$d .$
horizontally $c$
units, in the opposite direction of the sign of
$c .$
The y-intercept becomes $(0, b^{c} + d) .$
The horizontal asymptote becomes $y = d .$
The range becomes $(d, \infty) .$
The domain, $(- \infty, \infty),$
remains unchanged.

**Given an exponential function with the form $f (x) = b^{x + c} + d,$

graph the translation.**

Draw the horizontal asymptote $y = d .$
Identify the shift as $(- c, d) .$
Shift the graph of
$f (x) = b^{x}$
left
$c$
units if
$c$
is positive, and right
$c$
units if
$c$
is negative.
Shift the graph of $f (x) = b^{x}$
up
$d$
units if
$d$
is positive, and down
$d$
units if
$d$
is negative.
State the domain, $(- \infty, \infty),$
the range,
$(d, \infty),$
and the horizontal asymptote
$y = d .$

Graphing a Shift of an Exponential Function

Graph $f (x) = 2^{x + 1} - 3.$

State the domain, range, and asymptote.

We have an exponential equation of the form $f (x) = b^{x + c} + d,$

with $b = 2,$

c = 1,

and $d = - 3.$

Draw the horizontal asymptote $y = d$

, so draw $y = −3.$

Identify the shift as $(- c, d),$

so the shift is $(- 1, −3) .$

Shift the graph of $f (x) = b^{x}$

left 1 units and down 3 units.

Graph of the function, f(x) = 2^(x+1)-3, with an asymptote at y=-3. Labeled points in the graph are (-1, -2), (0, -1), and (1, 1).

The domain is $(- \infty, \infty);$

the range is $(- 3, \infty);$

the horizontal asymptote is $y = −3.$

Graph $f (x) = 2^{x - 1} + 3.$

State domain, range, and asymptote.

The domain is $(- \infty, \infty);$

the range is $(3, \infty);$

the horizontal asymptote is $y = 3.$

Graph of the function, f(x) = 2^(x-1)+3, with an asymptote at y=3. Labeled points in the graph are (-1, 3.25), (0, 3.5), and (1, 4).

**Given an equation of the form $f (x) = b^{x + c} + d$

for $x,$

use a graphing calculator to approximate the solution.**

Press [Y=]. Enter the given exponential equation in the line headed “Y₁=”.
Enter the given value for $f (x)$
in the line headed “Y₂=”.
Press [WINDOW]. Adjust the y-axis so that it includes the value entered for “Y₂=”.
Press [GRAPH] to observe the graph of the exponential function along with the line for the specified value of $f (x) .$
To find the value of $x,$
we compute the point of intersection. Press [2ND] then [CALC]. Select “intersect” and press [ENTER] three times. The point of intersection gives the value of x for the indicated value of the function.

Approximating the Solution of an Exponential Equation

Solve $42 = 1.2 {(5)}^{x} + 2.8$

graphically. Round to the nearest thousandth.

Press [Y=] and enter $1.2 {(5)}^{x} + 2.8$

next to Y₁=. Then enter 42 next to Y2=. For a window, use the values –3 to 3 for $x$

and –5 to 55 for $y .$

Press [GRAPH]. The graphs should intersect somewhere near $x = 2.$

For a better approximation, press [2ND] then [CALC]. Select [5: intersect] and press [ENTER] three times. The x-coordinate of the point of intersection is displayed as 2.1661943. (Your answer may be different if you use a different window or use a different value for Guess?) To the nearest thousandth, $x \approx 2.166.$

Solve $4 = 7.85 {(1.15)}^{x} - 2.27$

graphically. Round to the nearest thousandth.

x \approx - 1.608

Graphing a Stretch or Compression

While horizontal and vertical shifts involve adding constants to the input or to the function itself, a stretch or compression occurs when we multiply the parent function $f (x) = b^{x}$

by a constant $\| a \| > 0.$

For example, if we begin by graphing the parent function $f (x) = 2^{x},$

we can then graph the stretch, using $a = 3,$

to get $g (x) = 3 {(2)}^{x}$

as shown on the left in [link], and the compression, using $a = \frac{1}{3},$

to get $h (x) = \frac{1}{3} {(2)}^{x}$

as shown on the right in [link].

Two graphs where graph a is an example of vertical stretch and graph b is an example of vertical compression.

Stretches and Compressions of the Parent Function *f*(*x*) = *b*^*x*

For any factor $a > 0,$

the function $f (x) = a {(b)}^{x}$

is stretched vertically by a factor of $a$
if
$\| a \| > 1.$
is compressed vertically by a factor of $a$
if
$\| a \| < 1.$
has a y-intercept of $(0, a) .$
has a horizontal asymptote at $y = 0,$
a range of
$(0, \infty),$
and a domain of
$(- \infty, \infty),$
which are unchanged from the parent function.

Graphing the Stretch of an Exponential Function

Sketch a graph of $f (x) = 4 {(\frac{1}{2})}^{x} .$

State the domain, range, and asymptote.

Before graphing, identify the behavior and key points on the graph.

Since $b = \frac{1}{2}$
is between zero and one, the left tail of the graph will increase without bound as
$x$
decreases, and the right tail will approach the x-axis as
$x$
increases.
Since $a = 4,$
the graph of
$f (x) = {(\frac{1}{2})}^{x}$
will be stretched by a factor of
$4.$
Create a table of points as shown in [link]. | x
</math></strong> | $- 3$

$- 2$

$- 1$

$0$

$1$

$2$

$3$

$f (x) = 4 (\frac{1}{2})^{x}$

$32$

$16$

$8$

$4$

$2$

$1$

$0.5$
Plot the y-intercept, $(0, 4),$
along with two other points. We can use
$(- 1, 8)$
and
$(1, 2) .$

Draw a smooth curve connecting the points, as shown in [link].

Graph of the function, f(x) = 4(1/2)^(x), with an asymptote at y=0. Labeled points in the graph are (-1, 8), (0, 4), and (1, 2).

The domain is $(- \infty, \infty);$

the range is $(0, \infty);$

the horizontal asymptote is $y = 0.$

Sketch the graph of $f (x) = \frac{1}{2} {(4)}^{x} .$

State the domain, range, and asymptote.

The domain is $(- \infty, \infty);$

the range is $(0, \infty);$

the horizontal asymptote is $y = 0.$

Graph of the function, f(x) = (1/2)(4)^(x), with an asymptote at y=0. Labeled points in the graph are (-1, 0.125), (0, 0.5), and (1, 2).

Graphing Reflections

In addition to shifting, compressing, and stretching a graph, we can also reflect it about the x-axis or the y-axis. When we multiply the parent function $f (x) = b^{x}$

by $−1,$

we get a reflection about the x-axis. When we multiply the input by $−1,$

we get a reflection about the y-axis. For example, if we begin by graphing the parent function $f (x) = 2^{x},$

we can then graph the two reflections alongside it. The reflection about the x-axis, $g (x) = {−2}^{x},$

is shown on the left side of [link], and the reflection about the y-axis $h (x) = 2^{- x},$

is shown on the right side of [link].

Two graphs where graph a is an example of a reflection about the x-axis and graph b is an example of a reflection about the y-axis.

Reflections of the Parent Function *f*(*x*) = *b*^*x*

The function $f (x) = - b^{x}$

reflects the parent function $f (x) = b^{x}$
about the x-axis.
has a y-intercept of $(0, - 1) .$
has a range of $(- \infty, 0) .$
has a horizontal asymptote at $y = 0$
and domain of
$(- \infty, \infty),$
which are unchanged from the parent function.

The function $f (x) = b^{- x}$

reflects the parent function $f (x) = b^{x}$
about the y-axis.
has a y-intercept of $(0, 1),$
a horizontal asymptote at
$y = 0,$
a range of
$(0, \infty),$
and a domain of
$(- \infty, \infty),$
which are unchanged from the parent function.

Writing and Graphing the Reflection of an Exponential Function

Find and graph the equation for a function, $g (x),$

that reflects $f (x) = {(\frac{1}{4})}^{x}$

about the x-axis. State its domain, range, and asymptote.

Since we want to reflect the parent function $f (x) = {(\frac{1}{4})}^{x}$

about the x-axis, we multiply $f (x)$

by $- 1$

to get, $g (x) = - {(\frac{1}{4})}^{x} .$

Next we create a table of points as in [link].

$x$	$- 3$	$- 2$	$- 1$	$0$	$1$	$2$	$3$
$g (x) = - (\frac{1}{4})^{x}$	$- 64$	$- 16$	$- 4$	$- 1$	$- 0.25$	$- 0.0625$	$- 0.0156$

Plot the y-intercept, $(0, −1),$

along with two other points. We can use $(−1, −4)$

and $(1, −0.25) .$

Draw a smooth curve connecting the points:

Graph of the function, g(x) = -(0.25)^(x), with an asymptote at y=0. Labeled points in the graph are (-1, -4), (0, -1), and (1, -0.25).

The domain is $(- \infty, \infty);$

the range is $(- \infty, 0);$

the horizontal asymptote is $y = 0.$

Find and graph the equation for a function, $g (x),$

that reflects $f (x) = {1.25}^{x}$

about the y-axis. State its domain, range, and asymptote.

The domain is $(- \infty, \infty);$

the range is $(0, \infty);$

the horizontal asymptote is $y = 0.$

Graph of the function, g(x) = -(1.25)^(-x), with an asymptote at y=0. Labeled points in the graph are (-1, 1.25), (0, 1), and (1, 0.8).

Summarizing Translations of the Exponential Function

Now that we have worked with each type of translation for the exponential function, we can summarize them in [link] to arrive at the general equation for translating exponential functions.

Translations of the Parent Function $f (x) = b^{x}$
Translation	Form
Shift Horizontally $c$ units to the left Vertically $d$ units up	$f (x) = b^{x + c} + d$
Stretch and Compress Stretch if $\\| a \\| > 1$ Compression if $0 < \\| a \\| < 1$	$f (x) = a b^{x}$
Reflect about the x-axis	$f (x) = - b^{x}$
Reflect about the y-axis	$f (x) = b^{- x} = {(\frac{1}{b})}^{x}$
General equation for all translations	$f (x) = a b^{x + c} + d$

Translations of Exponential Functions

A translation of an exponential function has the form

f (x) = a b^{x + c} + d

Where the parent function, $y = b^{x},$

b > 1,

shifted horizontally $c$
units to the left.
stretched vertically by a factor of $\| a \|$
if
$\| a \| > 0.$
compressed vertically by a factor of $\| a \|$
if
$0 < \| a \| < 1.$
shifted vertically $d$
units.
reflected about the x-axis when $a < 0.$

Note the order of the shifts, transformations, and reflections follow the order of operations.

Writing a Function from a Description

Write the equation for the function described below. Give the horizontal asymptote, the domain, and the range.

$f (x) = e^{x}$
is vertically stretched by a factor of
$2$
, reflected across the y-axis, and then shifted up
$4$
units.

We want to find an equation of the general form $f (x) = a b^{x + c} + d .$

We use the description provided to find $a,$

b,

c,

and $d .$

We are given the parent function $f (x) = e^{x},$
so
$b = e .$
The function is stretched by a factor of $2$
, so
$a = 2.$
The function is reflected about the y-axis. We replace $x$
with
$- x$
to get:
$e^{- x} .$
The graph is shifted vertically 4 units, so $d = 4.$

Substituting in the general form we get,

\begin{array}{l} f (x) & = a b^{x + c} + d \\ = 2 e^{- x + 0} + 4 \\ = 2 e^{- x} + 4 \end{array}

The domain is $(- \infty, \infty);$

the range is $(4, \infty);$

the horizontal asymptote is $y = 4.$

Write the equation for function described below. Give the horizontal asymptote, the domain, and the range.

$f (x) = e^{x}$
is compressed vertically by a factor of
$\frac{1}{3},$
reflected across the x-axis and then shifted down
$2$
units.

f (x) = - \frac{1}{3} e^{x} - 2;

the domain is $(- \infty, \infty);$

the range is $(- \infty, 2);$

the horizontal asymptote is $y = 2.$

Access this online resource for additional instruction and practice with graphing exponential functions.

Graph Exponential Functions

Key Equations

General Form for the Translation of the Parent Function

f (x) = b^{x}

f (x) = a b^{x + c} + d

Key Concepts

The graph of the function $f (x) = b^{x}$
has a y-intercept at
$(0, 1),$
domain
$(- \infty, \infty),$
range
$(0, \infty),$
and horizontal asymptote
$y = 0.$
See [link].
If $b > 1,$
the function is increasing. The left tail of the graph will approach the asymptote
$y = 0,$
and the right tail will increase without bound.
If $0 < b < 1,$
the function is decreasing. The left tail of the graph will increase without bound, and the right tail will approach the asymptote
$y = 0.$
The equation $f (x) = b^{x} + d$
represents a vertical shift of the parent function
$f (x) = b^{x} .$
The equation $f (x) = b^{x + c}$
represents a horizontal shift of the parent function
$f (x) = b^{x} .$
See [link].
Approximate solutions of the equation $f (x) = b^{x + c} + d$
can be found using a graphing calculator. See [link].
The equation $f (x) = a b^{x},$
where
$a > 0,$
represents a vertical stretch if
$\| a \| > 1$
or compression if
$0 < \| a \| < 1$
of the parent function
$f (x) = b^{x} .$
See [link].
When the parent function $f (x) = b^{x}$
is multiplied by
$- 1,$
the result,
$f (x) = - b^{x},$
is a reflection about the x-axis. When the input is multiplied by
$- 1,$
the result,
$f (x) = b^{- x},$
is a reflection about the y-axis. See [link].
All translations of the exponential function can be summarized by the general equation $f (x) = a b^{x + c} + d .$
See [link].
Using the general equation $f (x) = a b^{x + c} + d,$
we can write the equation of a function given its description. See [link].

Section Exercises

Verbal

What role does the horizontal asymptote of an exponential function play in telling us about the end behavior of the graph?

An asymptote is a line that the graph of a function approaches, as $x$

either increases or decreases without bound. The horizontal asymptote of an exponential function tells us the limit of the function’s values as the independent variable gets either extremely large or extremely small.

What is the advantage of knowing how to recognize transformations of the graph of a parent function algebraically?

Algebraic

The graph of $f (x) = 3^{x}$

is reflected about the y-axis and stretched vertically by a factor of $4.$

What is the equation of the new function, $g (x) ?$

State its y-intercept, domain, and range.

g (x) = 4 {(3)}^{- x};

y-intercept: $(0, 4);$

Domain: all real numbers; Range: all real numbers greater than $0.$

The graph of $f (x) = {(\frac{1}{2})}^{- x}$

is reflected about the y-axis and compressed vertically by a factor of $\frac{1}{5} .$

What is the equation of the new function, $g (x) ?$

State its y-intercept, domain, and range.

The graph of $f (x) = 10^{x}$

is reflected about the x-axis and shifted upward $7$

units. What is the equation of the new function, $g (x) ?$

State its y-intercept, domain, and range.

g (x) = - 10^{x} + 7;

y-intercept: $(0, 6);$

Domain: all real numbers; Range: all real numbers less than $7.$

The graph of $f (x) = {(1.68)}^{x}$

is shifted right $3$

units, stretched vertically by a factor of $2,$

reflected about the x-axis, and then shifted downward $3$

units. What is the equation of the new function, $g (x) ?$

State its y-intercept (to the nearest thousandth), domain, and range.

The graph of $f (x) = 2 {(\frac{1}{4})}^{x - 20}$

is shifted left $2$

units, stretched vertically by a factor of $4,$

reflected about the x-axis, and then shifted downward $4$

units. What is the equation of the new function, $g (x) ?$

State its y-intercept, domain, and range.

g (x) = 2 {(\frac{1}{4})}^{x};

y-intercept: $(0, 2);$

Domain: all real numbers; Range: all real numbers greater than $0.$

Graphical

For the following exercises, graph the function and its reflection about the y-axis on the same axes, and give the y-intercept.

f (x) = 3 {(\frac{1}{2})}^{x}

g (x) = - 2 {(0.25)}^{x}

Graph of two functions, g(-x)=-2(0.25)^(-x) in blue and g(x)=-2(0.25)^x in orange. y-intercept: $(0, - 2)$

h (x) = 6 {(1.75)}^{- x}

For the following exercises, graph each set of functions on the same axes.

f (x) = 3 {(\frac{1}{4})}^{x},

g (x) = 3 {(2)}^{x},

and $h (x) = 3 {(4)}^{x}$

![Graph of three functions, g(x)=3(2)^(x) in blue, h(x)=3(4)^(x) in green, and f(x)=3(1/4)^(x) in orange.](/algebra-trigonometry-book/resources/CNX_PreCalc_Figure_04_02_204.jpg)

f (x) = \frac{1}{4} {(3)}^{x},

g (x) = 2 {(3)}^{x},

and $h (x) = 4 {(3)}^{x}$

For the following exercises, match each function with one of the graphs in [link].

Graph of six exponential functions.

f (x) = 2 {(0.69)}^{x}

f (x) = 2 {(1.28)}^{x}

f (x) = 2 {(0.81)}^{x}

f (x) = 4 {(1.28)}^{x}

f (x) = 2 {(1.59)}^{x}

f (x) = 4 {(0.69)}^{x}

For the following exercises, use the graphs shown in [link]. All have the form $f (x) = a b^{x} .$

Graph of six exponential functions.

Which graph has the largest value for $b ?$

Which graph has the smallest value for $b ?$

Which graph has the largest value for $a ?$

Which graph has the smallest value for $a ?$

For the following exercises, graph the function and its reflection about the x-axis on the same axes.

f (x) = \frac{1}{2} {(4)}^{x}

![Graph of two functions, f(x)=(1/2)(4)^(x) in blue and -f(x)=(-1/2)(4)^x in orange.](/algebra-trigonometry-book/resources/CNX_PreCalc_Figure_04_02_208.jpg)

f (x) = 3 {(0.75)}^{x} - 1

f (x) = - 4 {(2)}^{x} + 2

![Graph of two functions, -f(x)=(4)(2)^(x)-2 in blue and f(x)=(-4)(2)^x+1 in orange.](/algebra-trigonometry-book/resources/CNX_PreCalc_Figure_04_02_210.jpg)

For the following exercises, graph the transformation of $f (x) = 2^{x} .$

Give the horizontal asymptote, the domain, and the range.

f (x) = 2^{- x}

h (x) = 2^{x} + 3

Graph of h(x)=2^(x)+3. Horizontal asymptote: $h (x) = 3;$

Domain: all real numbers; Range: all real numbers strictly greater than $3.$

f (x) = 2^{x - 2}

For the following exercises, describe the end behavior of the graphs of the functions.

f (x) = - 5 {(4)}^{x} - 1

As $x \to \infty$

, $f (x) \to - \infty$

; * * *

As $x \to - \infty$

, $f (x) \to - 1$

f (x) = 3 {(\frac{1}{2})}^{x} - 2

f (x) = 3 {(4)}^{- x} + 2

As $x \to \infty$

, $f (x) \to 2$

; * * *

As $x \to - \infty$

, $f (x) \to \infty$

For the following exercises, start with the graph of $f (x) = 4^{x} .$

Then write a function that results from the given transformation.

Shift $f (x)$

4 units upward

Shift $f (x)$

3 units downward

f (x) = 4^{x} - 3

Shift $f (x)$

2 units left

Shift $f (x)$

5 units right

f (x) = 4^{x - 5}

Reflect $f (x)$

about the x-axis

Reflect $f (x)$

about the y-axis

f (x) = 4^{- x}

For the following exercises, each graph is a transformation of $y = 2^{x} .$

Write an equation describing the transformation.

Graph of f(x)=2^(x) with the following translations: vertical stretch of 4, a reflection about the x-axis, and a shift up by 1.

Graph of f(x)=2^(x) with the following translations: a reflection about the x-axis, and a shift up by 3.

y = - 2^{x} + 3

Graph of f(x)=2^(x) with the following translations: vertical stretch of 2, a reflection about the x-axis and y-axis, and a shift up by 3.

For the following exercises, find an exponential equation for the graph.

Graph of f(x)=3^(x) with the following translations: vertical stretch of 2, a reflection about the x-axis, and a shift up by 7.

y = - 2 {(3)}^{x} + 7

Graph of f(x)=(1/2)^(x) with the following translations: vertical stretch of 2, and a shift down by 4.

Numeric

For the following exercises, evaluate the exponential functions for the indicated value of $x .$

g (x) = \frac{1}{3} {(7)}^{x - 2}

for $g (6) .$

g (6) = 800 + \frac{1}{3} \approx 800.3333

f (x) = 4 {(2)}^{x - 1} - 2

for $f (5) .$

h (x) = - \frac{1}{2} {(\frac{1}{2})}^{x} + 6

for $h (- 7) .$

h (- 7) = - 58

Technology

For the following exercises, use a graphing calculator to approximate the solutions of the equation. Round to the nearest thousandth.

- 50 = - {(\frac{1}{2})}^{- x}

116 = \frac{1}{4} {(\frac{1}{8})}^{x}

x \approx - 2.953

12 = 2 {(3)}^{x} + 1

5 = 3 {(\frac{1}{2})}^{x - 1} - 2

x \approx - 0.222

- 30 = - 4 {(2)}^{x + 2} + 2

Extensions

Explore and discuss the graphs of $F (x) = {(b)}^{x}$

and $G (x) = {(\frac{1}{b})}^{x} .$

Then make a conjecture about the relationship between the graphs of the functions $b^{x}$

and ${(\frac{1}{b})}^{x}$

for any real number $b > 0.$

The graph of $G (x) = {(\frac{1}{b})}^{x}$

is the refelction about the y-axis of the graph of $F (x) = b^{x};$

For any real number $b > 0$

and function $f (x) = b^{x},$

the graph of ${(\frac{1}{b})}^{x}$

is the the reflection about the y-axis, $F (- x) .$

Prove the conjecture made in the previous exercise.

Explore and discuss the graphs of $f (x) = 4^{x},$

g (x) = 4^{x - 2},

and $h (x) = (\frac{1}{16}) 4^{x} .$

Then make a conjecture about the relationship between the graphs of the functions $b^{x}$

and $(\frac{1}{b^{n}}) b^{x}$

for any real number n and real number $b > 0.$

The graphs of $g (x)$

and $h (x)$

are the same and are a horizontal shift to the right of the graph of $f (x);$

For any real number n, real number $b > 0,$

and function $f (x) = b^{x},$

the graph of $(\frac{1}{b^{n}}) b^{x}$

is the horizontal shift $f (x - n) .$

Prove the conjecture made in the previous exercise.

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