1. Logarithmic Functions
7-3
Logarithmic Functions
Warm Up
Lesson Presentation
Lesson Quiz
Holt McDougal Algebra 2
Holt Algebra 2

2. Use mental math to evaluate.
Opener-SAME SHEET-1/13
Use mental math to evaluate.
1. 4–3 2. 2
3. 10–5 4.
5. A power has a base of –2 and exponent of 4. Write and evaluate the power.
(–2)4 = 16

3. 7-2 Hmwk Quiz
1. Find Inverse
F(x) = 5x – 4
F(x) = x – 7 4

4. Objectives
Write equivalent forms for exponential and logarithmic functions.
Write, evaluate, and graph logarithmic functions.

5. Vocabulary
logarithm
common logarithm
logarithmic function

6. How many times would you have to double $1 before you had $8
How many times would you have to double $1 before you had $8? You could use an exponential equation to model this situation. 1(2x) = 8. You may be able to solve this equation by using mental math if you know 23 = 8. So you would have to double the dollar 3 times to have $8.

7. How many times would you have to double $1 before you had $512
How many times would you have to double $1 before you had $512? You could solve this problem if you could solve 2x = 8 by using an inverse operation that undoes raising a base to an exponent equation to model this situation. This operation is called finding the logarithm. A logarithm is the exponent to which a specified base is raised to obtain a given value.

8. You can write an exponential equation as a logarithmic equation and vice versa.
Read logb a= x, as “the log base b of a is x.” Notice that the log is the exponent.
Reading Math

9. Example 1: Converting from Exponential to Logarithmic Form
Write each exponential equation in logarithmic form.
Exponential Equation
Logarithmic Form
35 = 243
25 = 5
104 = 10,000
6–1 =
ab = c
log3243 = 5 1 2 1 2
log255 =
log1010,000 = 4 1 6
log = –1 1 6
logac =b

10. Write each exponential equation in logarithmic form. 92= 81 33 = 27
Check It Out! Example 1
Write each exponential equation in logarithmic form.
Exponential Equation
Logarithmic Form
92= 81
33 = 27
x0 = 1(x ≠ 0) a.
log981 = 2 b.
log327 = 3 c.
logx1 = 0

11. Example 2: Converting from Logarithmic to Exponential Form
Write each logarithmic form in exponential equation.
Logarithmic Form
Exponential Equation
log99 = 1
log = 9
log82 =
log = –2
logb1 = 0
91 = 9
29 = 512 1 3 1 3
8 = 2 1 1 16
4–2 = 16
b0 = 1 .

12. Opener-SAME SHEET-12/6
Describe the transformation
F(x) = x3 + 2
F(x)= -f(x)
F(x)= f(x - 3)
F(x)= 3f(x)
F(x)= f(x) + 7

13. Opener-SAME SHEET-12/6
Tell whether each function shows growth or decay. Then graph.
1. h(x) = 0.8(1.6)x 2. p(x) = 12(0.7)x
3. An initial amount of $40,000 increases by 8% per year. In how many years will the amount reach $60,000?

15. Opener-SAME SHEET-1/14 Find the zeros of each function
f(x)=x2 + 7x + 10
Use Quadractic function
2. f(x) = x2 + 10x + 2

16. Flash Cards Match Game

17. A logarithm is an exponent, so the rules for exponents also apply to logarithms. You may have noticed the following properties in the last example.

18. A logarithm with base 10 is called a common logarithm
A logarithm with base 10 is called a common logarithm. If no base is written for a logarithm, the base is assumed to be 10.
For example, log 5 = log105.
You can use mental math to evaluate some logarithms.

19. Example 3A: Evaluating Logarithms by Using Mental Math
Evaluate by using mental math.
log 0.01
log51
log5 125
log 0.01 = –2
log5125 = 3
log = 1 5

20. Opener-SAME SHEET-12/8 Calculate the following using mental math.
3. log 100,000 5
4. log864
5. log381 4

21. Because logarithms are the inverses of exponents, the inverse of an exponential function, such as y = 2x, is a logarithmic function, such as y = log2x.
You may notice that the domain and range of each function are switched.
The domain of y = 2x is all real numbers (R), and the range is {y|y > 0}. The domain of y = log2x is {x|x > 0}, and the range is all real numbers (R).

22. Example 4A: Graphing Logarithmic Functions
Use the x-values {–2, –1, 0, 1, 2}. Graph the function and its inverse. Describe the domain and range of the inverse function.
f(x) = 1.25x
Graph f(x) = 1.25x by using a table of values. 1
f(x) = 1.25x 2 –1 –2 x
0.64
0.8
1.25
1.5625

23. To graph the inverse, f–1(x) = log1.25x, by using a table of values.
Example 4A Continued
To graph the inverse, f–1(x) = log1.25x, by using a table of values. 2 1 –1 –2
f–1(x) = log1.25x
1.5625
1.25
0.8
0.64 x
The domain of f–1(x) is {x|x > 0}, and the range is R.

24. Example 4B: Graphing Logarithmic Functions
Use the x-values {–2, –1, 0, 1, 2}. Graph the function and its inverse. Describe the domain and range of the inverse function.
f(x) = x 1 2
Graph f(x) = x by using a table of values. 1 2 x –2 –1 1 2
f(x) =( ) x 4 1 2 4

25. To graph the inverse, f–1(x) = log x, by using a table of values.
Example 4B Continued
To graph the inverse, f–1(x) = log x, by using a table of values. 1 2 x 4 2 1
f –1(x) =log x –2 –1 1 2 4
The domain of f–1(x) is {x|x > 0}, and the range is R.

26. Graph by using a table of values.
Check It Out! Example 4
Use x = –2, –1, 1, 2, and 3 to graph Then graph its inverse. Describe the domain and range of the inverse function.
Graph by using a table of values. x –2 –1 1 2 3
f(x) = x 16 9 4 3 3 4 9 16 27 64 3 4

27. To graph the inverse, f–1(x) = log x, by using a table of values.
Check It Out! Example 4
To graph the inverse, f–1(x) = log x, by using a table of values. 3 4 x
f–1(x) = log x –2 –1 1 2 3 16 9 4 3 3 4 9 16 27 64 3 4
The domain of f–1(x) is {x|x > 0}, and the range is R.

28. The key is used to evaluate logarithms in base 10
The key is used to evaluate logarithms in base is used to find 10x, the inverse of log.
Helpful Hint

29. 1. Change 64 = 1296 to logarithmic form. log61296 = 4
Lesson Quiz: Part I
1. Change 64 = 1296 to logarithmic form.
log61296 = 4
27 = 9 2 3
2. Change log279 = to exponential form. 2 3
Calculate the following using mental math.
3. log 100,000 5
4. log648
0.5
5. log3 1 27 –3

30. D: {x > 0}; R: all real numbers
Lesson Quiz: Part II
6. Use the x-values {–2, –1, 0, 1, 2, 3} to graph f(x) =( )X. Then graph its inverse. Describe the domain and range of the inverse function. 5 4
D: {x > 0}; R: all real numbers