1. Logarithmic
Functions
3.2

2. Convert to exponential form:
The logarithmic function to the base b, where b > 0 and b  1 is defined:
y = logbx if and only if x = b y
logarithmic form
exponential form
Convert to exponential form:
Convert to log form:
When you convert an exponential to log form, notice that the exponent in the exponential becomes what the log is equal to.

3. LOGS = EXPONENTS
With this in mind, we can answer questions about the log:
2 to what power gives 16?
3 to what power gives 1/9?
4 to what power gives 1?
When working with logs, re-write any radicals as rational exponents.
3 to what power gives 3 to the 1/2? (hint: think rational)

4. Logs and exponentials are inverse functions of each other so let’s see what we can tell about the graphs of logs based on what we learned about the graphs of exponentials.
Recall that for functions and their inverses, x’s and y’s trade places. So anything that was true about x’s or the domain of a function, will be true about y’s or the range of the inverse function and vice versa.
Let’s look at the characteristics of the graphs of exponentials then and see what this tells us about the graphs of their inverse functions which are logarithms.

5. Characteristics about the Graph of an Exponential Function b > 1
Characteristics about the Graph of a Log Function where b > 1
1. Domain is all real numbers
1. Range is all real numbers
Range is positive real numbers
Domain is positive real numbers
There are no x intercepts because there is no x value that you can put in the function to make it = 0
3. There are no y intercepts
4. The x intercept is always (1,0) (x’s and y’s trade places)
The y intercept is always (0,1) because b 0 = 1
The graph is always increasing
The graph is always increasing
The x-axis (where y = 0) is a horizontal asymptote for x  - 
The y-axis (where x = 0) is a vertical asymptote

6. Logarithmic Graph
Exponential Graph
Graphs of inverse functions are reflected about the line y = x

7. Transformation of functions apply to log functions just like they apply to all other functions so let’s try a couple.
up 2
Reflect about x axis
left 1

8. ln Remember our natural base “e”? We can use that base on a log.
e to what power gives ? ln
Since the log with this base occurs in nature frequently, it is called the natural log and is abbreviated ln.
Your calculator knows how to find natural logs. Locate the ln button on your calculator. Notice that it is the same key that has ex above it. The calculator lists functions and inverses using the same key but one of them needing the 2nd (or inv) button.

9. Another commonly used base is base 10
Another commonly used base is base 10. A log to this base is called a common log. Since it is common, if we don't write in the base on a log it is understood to be base 10.
10 to what power gives 100?
10 to what power gives 1/1000?
This common log is used for things like the Richter scale for earthquakes and decibels for sound.
Your calculator knows how to find common logs. Locate the log button on your calculator. Notice that it is the same key that has 10x above it. Again, the calculator lists functions and inverses using the same key but one of them needing the 2nd (or inv) button.

10. To find x-intercepts of function
we need to solve the equation:
Convert this to exponential form
check:
This is true since 23 = 8