We were first introduced to exponential function in Math 1 lesson  4.01 Exponential functions . We looked more specifically at growth and decay functions in the Math 1 lessons  4.02 Exponential growth and  4.03 Exponential decay . We will review these functions, their key features, and transformations in this lesson in preparation for finding the inverse function of exponentials in the next lesson.
Exponential functions can be classified as exponential growth functions or exponential decay functions based on the value of the constant factor.
Exponential functions can also be expressed in terms of their constant percent rate of change.
We can determine the key features of an exponential function from its equation or graph:
The exponential parent function y=b^{x} can be transformed to y=ab^{c\left(x-h\right)}+k
If a<0, the graph is reflected across the x-axis
The graph is stretched or compressed vertically by a factor of a
If c<0, the graph is reflected across the y-axis
The graph is stretched or compressed horizontally by a factor of c
The graph is translated horizontally by h units
The graph is translated vertically by k units
Consider the table of values for function f\left(x\right).
x | -1 | 0 | 1 | 2 | 3 | 4 |
---|---|---|---|---|---|---|
f\left(x\right) | \dfrac{5}{3} | 5 | 15 | 45 | 135 | 405 |
Determine whether the function represents an exponential function or not.
Write an equation to represent the exponential function.
Consider the following piecewise function:
f\left(x\right) = \begin{cases} \left(\frac{1}{3}\right)^x, & \enspace x \leq 0 \\ -x^{3}, & \enspace x \gt 0 \end{cases}
Sketch a graph of the piecewise function.
State the domain and range.
For each scenario, find the equation of the transformed function.
The graph of f\left(x\right) is translated to get the graph of g\left(x\right) show below.
The graph of y = \left(\dfrac{1}{2}\right)^{x} is reflected across the x-axis and stretched vertically by a factor of 2.
The graph of the function f\left(x\right) = 5\cdot 2^{x} is translated 10 units down to give a new function g\left(x\right).
Complete the table of values for f\left(x\right) and the transformed function g\left(x\right), then sketch the graphs of both functions.
x | -2 | -1 | 0 | 1 | 2 | 3 | 4 |
---|---|---|---|---|---|---|---|
f\left(x\right) | |||||||
g\left(x\right) |
Exponential functions grow or decay at a constant percent rate of change. The function increases when b>1 and decreases when 0<b<1.
The constant rate in decimal form can be found by solving b=1+r for r in growth functions or by solving b=1-r for r in decay functions.
We are familiar with the famous irrational constant, \pi, but there are other irrational constants that are just as valuable in upper-level mathematics. One of those was discovered by and named after mathematician Leonhard Euler (pronounced "oiler").
Euler's constant has many applications in natural growth and compound interest. We can evaluate powers of e using the button on our calculator.
Recall the formula for compound interest: A=P\left(1+\frac{r}{n}\right)^{nt} where A is the future value, P is in principle or initial amount, r is the interest rate, n is the number of times the interest is compounded, and t is the time in years.
Suppose you borrow money from someone charging 100\% interest for 1 year. This situation would be modeled by: A=P\left(1+\frac{1}{n}\right)^{n} Let's examine what happens as the number of times the interest is compounded during the year increases.
Complete the table of values.
\text{Compound}\\ \text{period} | \text{Annual} | \text{Quarter} | \text{Month} | \text{Biweekly} | \text{Week} | \text{Day} | \text{Hour} |
---|---|---|---|---|---|---|---|
n | 1 | 4 | 12 | 26 | 52 | 365 | 8760 |
\left(1+\frac{1}{n}\right)^{n} |
Create a hypothesis for what will happen to the value of \left(1+\frac{1}{n}\right)^{n} as the number of compounding periods increases.
Confirm or refute your hypothesis using the GeoGebra animation below. Either click the "Start Animation" button or slide the blue slider through the different values of n.
Euler's number can be used to model continuous growth and decay:
When k>0, the function represents continuous growth. When k<0, the function has been reflected across the y-axis and represents continuous decay.
Consider the exponential function f\left(x\right)=e^{-x}-2
Find the coordinates of the y-intercept.
State the domain and range.
Sketch a graph of the function.
A small town is experiencing a population boom and is currently growing continuously at a rate of 5\% every year. The mayor wants to ensure that the housing needs of the growing population are met and passes a bill to support housing for 1000 additional people every year.
The current town population is 5000 residents and the town currently has enough housing to support a population of 8000.
Create an algebraic model for the population and for the amount of housing in the town after x years.
Create a graph of both functions on the same coordinate plane to determine when the town will run out of available housing. Choose an appropriate scale and label the axes of your graph.
Euler's constant, e, is approximately 2.71828.
Euler's constant can be used to model continuous growth and decay:
The function f\left(x\right) represents exponential growth when k>0 and exponential decay when k<0.