6.2 Graphs of exponential functions (Page 3/6)

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A General Note

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.

How To

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 $y = −3.$

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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).

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How To

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 “ Y ₁ = ”.
Enter the given value for $f (x)$ in the line headed “ Y ₂ = ”.
Press [WINDOW] . Adjust the y -axis so that it includes the value entered for “ Y ₂ = ”.
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 Y ₁ =. 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, $x \approx 2.166.$

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Solve $4 = 7.85 {(1.15)}^{x} - 2.27$ graphically. Round to the nearest thousandth.

$x \approx - 1.608$

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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] .

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Source: OpenStax, College algebra. OpenStax CNX. Feb 06, 2015 Download for free at https://legacy.cnx.org/content/col11759/1.3

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6.2 Graphs of exponential functions (Page 3/6)

Shifts of the parent function f ( x ) = b x

Graphing a shift of an exponential function

Approximating the solution of an exponential equation

Graphing a stretch or compression

Read also:

Get Jobilize Job Search Mobile App in your pocket Now!

Shifts of the parent function f ( x ) = b ^x