6.01 Exponential functions

Complete the table of values and sketch f\left(x\right) = 2 \left(\dfrac{1}{3}\right)^x.

To find the table of values for the function f\left(x\right) = 2 \left(\dfrac{1}{3}\right)^x, substitute different values of x into the equation and calculate the corresponding y values. Then, plot these points on a graph to sketch the function.

Evaluate f(-2) : f(-2)=2 \left(\dfrac{1}{3}\right)^{-2}=2 \cdot (3)^{2}=18

Evaluate f(-1) : f(-1)=2 \left(\dfrac{1}{3}\right)^{-1}=2 \cdot (3)^{1}=6

Evaluate f(0) : f(0)=2 \left(\dfrac{1}{3}\right)^{0}=2 \cdot 1=2

Evaluate f(1) : f(1)=2 \left(\dfrac{1}{3}\right)^{1}=2 \cdot \dfrac{1}{3}=\dfrac{2}{3}

Evaluate f(2) : f(2)=2 \left(\dfrac{1}{3}\right)^{2}=2 \cdot \dfrac{1}{9}=\dfrac{2}{9}

Table of values:

Graph:

Sketch the graph of g\left(x\right) on the same plane as f\left(x\right).

To sketch the graph of g\left(x\right) = x^2+2, we can use the transformation of the parent function x^2, which is a parabola. The graph of x^2 is a parabola with its vertex at the origin and opening upward.

Since g\left(x\right) = x^2 + 2, the transformation from the parent function x^2 is a vertical shift upward by 2 units. This means that the vertex of the parabola for g\left(x\right) is at \left(0, 2\right). The shape of the parabola remains the same as the parent function, opening upward.

Compare the y-intercepts of both functions.

The y-intercept of a function is the point where it intersects the y-axis. We can find the y-intercepts from the graphs and compare their values.

Another way to find the y-intercepts of the functions is to substitute x=0 directly into their equations and evaluate them.

This confirms that both functions have the same y-intercept.

Compare the end behavior of both functions.

To compare the end behavior, we need to look at what happens to the y-values of each function as x approaches positive and negative infinity.

We can describe the end behavior of the functions in mathematical notation as:

As x \to -\infty , {f\left(x\right) \to \infty} and as x \to \infty , {f\left(x\right) \to 0}

As x \to -\infty , {g\left(x\right) \to \infty} and as x \to \infty , {g\left(x\right) \to \infty}

We can see that both functions have the same behavior on the left as x approaches negative infinity, but their behavior on the right as x approaches positive infinity differs.

To reasonably verify the behavior of the functions f\left(x\right) and g\left(x\right) algebraically, you can use a calculator to input very large and very small values for x.

For f\left(x\right), we can substitute a small value , like x=-100, into f\left(x\right) which gives us f\left(-100\right) = 1.0308 \cdot 10^{48}. This is a very large number which matches our end behavior of:\text{As }x \to -\infty,f\left(x\right) \to \infty

We can also substitute a large value, like x=100, into f\left(x\right) which gives us f\left(100\right) = 3.8807 \cdot 10^{-48}. This is a number very close to zero which matches our end behavior of:\text{As }x \to \infty,f\left(x\right) \to 0

For g\left(x\right), we can substitute a small value, like x=-100, into g\left(x\right) which gives us g\left(-100\right) = 10002. This is a very large number which matches our end behavior of:\text{As }x \to -\infty,g\left(x\right) \to \infty

We can also substitute a large value, like x=100, into g\left(x\right) which gives us g\left(100\right) = 10002. This is a very large number which matches our end behavior of:\text{As }x \to \infty,g\left(x\right) \to \infty

Compare the domain and range of both functions.

We can use the graphs to find the domain and range of each function and compare them. The domain of a function is the set of all possible x-values, and the range is the set of all possible y-values.

Comparing the domain and range of both functions, we can see that both functions have the same domain, (-\infty, \infty), but their ranges are different.

Compare the graph of the parent function with the graph of the transformed function. Notice that the parent function is shifted to the right to create g\left(x\right).

A horizontal translation is represented by g\left(x\right)=\left(\dfrac{1}{3}\right)^{x-h}. We have just found that h=3. Therefore, the equation of the transformed function isg\left(x\right)=\left(\dfrac{1}{3}\right)^{x-3}

Compare f\left(x\right) and g\left(x\right). Notice that it appears they are the same size and shape, but g\left(x\right) is a mirror image of f\left(x\right) over the x-axis.

In the function notation g\left(x\right)=a\cdot f\left(x\right), a reflection across the x-axis is represented by a=-1.

Therefore, the equation of g\left(x\right) is g\left(x\right) = -\left(\dfrac{1}{3}\right)^x

To check our solution, we can find points on f\left(x\right) and g\left(x\right) algebraically and compare them.

Let's compare the points on f\left(x\right) and g\left(x\right) when x=1.

When we substitute x=1 into f\left(x\right), we get f\left(1\right) = \left( \dfrac{1}{3}\right)^1= \dfrac{1}{3}. This gives us the point \left(1,\dfrac{1}{3}\right).

When we substitute x=1 into g\left(x\right), we get g\left(1\right) = - \left(\dfrac{1}{3}\right)^1=-\dfrac{1}{3}. This gives us the point \left(1,-\dfrac{1}{3}\right).

When we compare these two points, we see that they share the same x-value, but the y-value of g\left(x\right) is the negative of f\left(x\right). We can do this with every possible x-value and get the same result where the y-values of g\left(x\right) are the negative of the y-values of f\left(x\right).

This confirms that we have a reflection about the x-axis.

Compare f\left(x\right) and g\left(x\right). Notice that they have the same horizontal asymptote and y-intercept, so a translation has not occurred. The shape of the functions are different, indicating a dilation has occurred.

A horizontal dilation is represented by g\left(x\right)=\left(\dfrac{1}{3}\right)^{c\cdot x} where c=\dfrac{1}{\text{scale factor}}. We found the scale factor to be 2, so c=\dfrac{1}{2}.

Therefore, the equation of g\left(x\right) is g\left(x\right)=\left(\dfrac{1}{3}\right)^{0.5x}

It can sometimes be difficult to identify whether the dilation was vertical or horizontal, but checking more than one point on the graph can help us avoid mistakes.

g\left(x\right) = 4^{-x}

We can use a table of values to graph the parent function, then identify the transformation that occurred to create g\left(x\right). Then, we can use the transformation to graph g\left(x\right).

First, create a table of values to graph the parent function f\left(x\right) = 4^x:

Notice that the only change between the parent function, f\left(x\right) = 4^x, and the transformed function, g\left(x\right) = 4^{-x}, is the exponent of g\left(x\right) is negative. This indicates a reflection across the y-axis.

By reflecting each point of f\left(x\right) across the y-axis, we can create the graph of g\left(x\right):

Using technology, we can check that we have correctly identified and graphed the transformation.

Notice that the graph of g\left(x\right) is a reflection of f\left(x\right) across the y-axis. We can also see that the points on our graph match the points shown in the graphing calculator. This verifies our solution.

g\left(x\right) = -4^{x}+3

The parent function is f\left(x\right) = 4^x, and the transformed function is g\left(x\right) = -4^{x}+3. In the transformation notation, y=a\left(b\right)^{x-h}+k, the negative sign corresponds to a=-1 and constant of 3 corresponds to k=3.

Recall that the a-value indicates a vertical reflection or dilation, and the k-value indicates a vertical translation.

Recall that when graphing transformations, we always graph reflections and dilations before translations. If we had graphed the translation first, we would have gotten a different graph.

Notice that this graph is not the same as the one we found, which shows that the order in which we apply the transformations matters.

g\left(x\right) = - \left(\dfrac{1}{4}\right)\cdot 4^x

The parent function is f\left(x\right) = 4^x, and the transformed function is g\left(x\right) = - \left(\dfrac{1}{4}\right)\cdot 4^x. The differences between the two functions are the negative sign and the factor \dfrac{1}{4} in front of the exponential term. Both of these correspond to the a-value in the transformation notation y=a\left(b\right)^{x-h}+k.

For g\left(x\right) = - \left(\dfrac{1}{4}\right)\cdot 4^x, a=-\dfrac{1}{4}. Since a<0, the function has been reflected across the x-axis. Also, 0<\left|a\right|<1, so the function has been compressed vertically by a factor of \dfrac{1}{4}.

The order in which we apply reflections and dilations does not matter. If we had reflected the function first, then dilated it, we would have gotten the same graph. Again, we can verify our solution using technology.

Determine which function increases at a slower rate.

To help us visualize the functions, we can graph them on the same coordinate plane.

When we look at the graph, we can see g\left(x\right) does not seem as steep as f\left(x\right) and its curve is more rounded. This is a visual indication that g\left(x\right) increases at a slower rate.

Since the functions have not been translated, another way to determine the answer is by comparing the constant factors of the functions. We can find the constant factors by dividing the outputs of two consecutive values of x.

For f\left(x\right), we can use the points (-1, -8) and (0,-2).

b=\dfrac{-2}{-8}=\dfrac{1}{4}

For g\left(x\right), we can use the points (-2, -9) and (-1, -3).

b=\dfrac{-3}{-9}=\dfrac{1}{3}

Since \dfrac{1}{4}<\dfrac{1}{3}, f\left(x\right) gets multiplied by a smaller factor than g\left(x\right). Because of this, f\left(x\right) will get closer to 0 faster, so g\left(x\right) increases at a slower rate.

Identify the y-intercept for each function.

On the given graph of f\left(x\right), we will look for the point where the function intercepts the y-axis. In the table for g\left(x\right), we will look for the point where x=0.

The y-intercept of f\left(x\right) is (0,-2).

The y-intercept of g\left(x\right) is (0,-1).

Now that we know the y-intercept and constant factor for each function, we can build the equations.

f\left(x\right)=-2\left(\dfrac{1}{4}\right)^x

g\left(x\right)=-1\left(\dfrac{1}{3}\right)^x

Identify and compare f(-1) and g(-1).

To find f(-1), we can use the graph to locate the point (-1,y). For g(-1), we can use the table of values to find the corresponding y-value when x = -1. Then, we can compare the two functions.

Using the table of values for the function g\left(x\right), we can find the value of g(-1) by locating the row with x = -1 and reading its corresponding y-value. When x = -1,\, g\left(x\right) = -3.

We find that f(-1)=-8 and g(-1)=-3 which are different values and g(-1)> f(-1).

Sketch the inverse function on the same coordinate plane.

Swap the x and y-values on the curve of y=3^x to find the corresponding points on the curve of the inverse function.

Compare the key features of f\left(x\right) and its inverse including intercepts, zeros, asymptotes, domain, and range.

Use the graphs from part (a) to compare the y-intercepts, zeros, asymptotes, domain, range, and any increasing or decreasing intervals. Remember that the inverse function is created by swapping the inputs and outputs, so the features related to inputs and outputs will be affected in a similar way.

By observing the graphs of both functions, we can now compare their key features:

1. y-intercepts: The point where the graph crosses the y-axis.

   • f\left(x\right): y=1
   • g\left(x\right): none
2. Zeros: Zeros are the x-intercepts of the graph.
   • f\left(x\right): none
   • g\left(x\right): x=1

3. Asymptotes:

   • f\left(x\right): has a horizontal asymptote at y = 0 but no vertical asymptote.
   • g\left(x\right): has a vertical asymptote at x = 0 but no horizontal asymptote

4. Domain: The set of all possible x-values for which the function is defined.

   • f\left(x\right): all real numbers, (-\infty, \infty)
   • g\left(x\right): (0, \infty)
5. Range: The set of all possible y-values for which the function is defined.
   • f\left(x\right): (0, \infty)
   • g\left(x\right): all real numbers, (-\infty, \infty)

6. Increasing and Decreasing: Both functions are always increasing on their domain. They are never decreasing.

In general, the features of the original function are the opposite of the corresponding features on the inverse function.