1. Do Now:
Think about the function y = 2x. What do you think happens when x gets really big and positive? How about when x gets really big and negative?

2. Do Now:
Complete the table.
1. y  3x y  2x 3x

3. 6.1 Exponential Growth and Decay Functions
Algebra II
6.1 Exponential Growth and Decay Functions

4. Exponential Growth
An exponential function has the form y = abx where a ≠ 0 and b is a positive real number other than 1.

5. Asymptote Exponential functions have asymptotes.
An asymptote is a line that a graph approaches sooooo closely, but never touches.

6. Exponential Growth Function
If a > 0 and b > 1, then y = abx is an exponential growth function. We call b the growth factor.

7. x -2 -1 1 2 y
Domain:
Range:

8. Domain:
Range:

9. Exponential Decay Function
If a > 0 and 0 < b < 1, then y = abx is an exponential decay function. We call b the decay factor.

10. x -2 -1 1 2 y
Domain:
Range:

11. Domain:
Range:

12. Exponential Models
Some real-life quantities increase or decrease by a fixed percent each year (or some other time period).

13. Exponential Models
Exponential Growth Model y = a(1 + r)t Exponential Decay Model y = a(1 – r)t

14. Exponential Models
“a” is the initial amount “r” is the percent increase or decrease and is always written as a decimal “1 + r”/”1 – r” is the growth/decay factor.

15. Example 2
The value of a car y (in thousands of dollars) can be approximated by the model y = 25(0.85)t , where t is the number of years since the car was new.
a. Tell whether the model represents exponential growth or exponential decay.
b. Identify the annual percent increase or decrease in the value of the car.

16. Example 3
In 2000, the world population was about 6.09 billion. During the next 13 years, the world population increased by about 1.18% each year. a. Write an exponential growth model giving the population y (in billions) t years after Estimate the world population in 2005.

17. Example 3 Cont
b. Estimate the year when the world population was 7 billion.
Graph the model and use the table application.

18. Example 4
The amount y (in grams) of the radioactive isotope chromium-51 remaining after t days is y = a (0.5)t / 28, where a is the initial amount (in grams). What percent of the chromium-51 decays each day?

19. Compound Interest
Compound interest is interest paid on an initial investment, called principal, and on previously earned interest.

20. Compound Interest
Compound interest is interest paid on an initial investment, called principal, and on previously earned interest. Interest earned is often expressed as an annual percent so we can use our growth model to help us in this economics application

21. Compound Interest
Compound interest: interest paid on an initial investment, called principal, and on previously earned interest.
Interest earned is often expressed as an annual percent
Can use our growth model to help us in this economics application
However, interest is usually compounded more than once per year so we need to make a slight adjustment.

22. Compound Interest

23. Example 5
You deposit $9000 in an account that pays 1.46% annual interest. Find the balance after 3 years when the interest is compounded quarterly.