6.2: Evaluate and Graph Logarithmic Functions
The function \(f(x)=\log_{a}x\) is the logarithmic function with base \(a\), where \(a>0,x>0\), and \(a≠1\).
\(y=\log _{a} x\) is equivalent to \(x=a^{y}\)
Convert Between Exponential and Logarithmic Form
Since the equations \(y=\log _{a} x\) and \(x=a^{y}\) are equivalent, we can go back and forth between them. This will often be the method to solve some exponential and logarithmic equations. To help with converting back and forth let’s take a close look at the equations. See Figure 10.3.1 . Notice the positions of the exponent and base.
If we realize the logarithm is the exponent it makes the conversion easier. You may want to repeat, “base to the exponent give us the number.”
Convert to logarithmic form:
- \(2^{3}=8\)
- \(5^{\frac{1}{2}}=\sqrt{5}\)
- \(\left(\frac{1}{2}\right)^{x}=\frac{1}{16}\)
Solution :
Convert to logarithmic form:
- \(3^{2}=9\)
- \(7^{\frac{1}{2}}=\sqrt{7}\)
- \(\left(\frac{1}{3}\right)^{x}=\frac{1}{27}\)
- Answer
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- \(\log _{3} 9=2\)
- \(\log _{7} \sqrt{7}=\frac{1}{2}\)
- \(\log _{\frac{1}{3}} \frac{1}{27}=x\)
Convert to logarithmic form:
- \(4^{3}=64\)
- \(4^{\frac{1}{3}}=\sqrt[3]{4}\)
- \(\left(\frac{1}{2}\right)^{x}=\frac{1}{32}\)
- Answer
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- \(\log _{4} 64=3\)
- \(\log _{4} \sqrt[3]{4}=\frac{1}{3}\)
- \(\log _{\frac{1}{2}} \frac{1}{32}=x\)
In the next example we do the reverse—convert logarithmic form to exponential form.
Convert to exponential form:
- \(2=\log _{8} 64\)
- \(0=\log _{4} 1\)
- \(-3=\log _{10} \frac{1}{1000}\)
Solution :
Convert to exponential form:
- \(3=\log _{4} 64\)
- \(0=\log _{x} 1\)
- \(-2=\log _{10} \frac{1}{100}\)
- Answer
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- \(64=4^{3}\)
- \(1=x^{0}\)
- \(\frac{1}{100}=10^{-2}\)
Convert to exponential form:
- \(3=\log _{3} 27\)
- \(0=\log _{x} 1\)
- \(-1=\log _{10} \frac{1}{10}\)
- Answer
-
- \(27=3^{3}\)
- \(1=x^{0}\)
- \(\frac{1}{10}=10^{-1}\)
Evaluate Logarithmic Functions
We can solve and evaluate logarithmic equations by using the technique of converting the equation to its equivalent exponential equation.
Find the value of \(x\):
- \(\log _{x} 36=2\)
- \(\log _{4} x=3\)
- \(\log _{\frac{1}{2}} \frac{1}{8}=x\)
Solution :
a.
\(\log _{x} 36=2\)
Convert to exponential form.
\(x^{2}=36\)
Solve the quadratic.
\(x=6, \quad \cancel{x=-6}\)
The base of a logarithmic function must be positive, so we eliminate \(x=−6\).
\(x=6 \quad\) Therefore, \(\log _{6} 36=2\)
b.
\(\log _{4} x=3\)
Convert to exponential form.
\(4^{3}=x\)
Simplify.
\(x=64 \quad\) Therefore \(, \log _{4} 64=3\)
c.
\(\log _{\frac{1}{2}} \frac{1}{8}=x\)
Convert to exponential form.
\(\left(\frac{1}{2}\right)^{x}=\frac{1}{8}\)
Rewrite \(\frac{1}{8}\) as \(\left(\frac{1}{2}\right)^{3}\).
\(\left(\frac{1}{2}\right)^{x}=\left(\frac{1}{2}\right)^{3}\)
With the same base, the exponents must be equal.
\(x=3 \quad\) Therefore \(\log _{\frac{1}{2}} \frac{1}{8}=3\)
Find the value of \(x\):
- \(\log _{x} 64=2\)
- \(\log _{5} x=3\)
- \(\log _{\frac{1}{2}} \frac{1}{4}=x\)
- Answer
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- \(x=8\)
- \(x=125\)
- \(x=2\)
Find the value of \(x\):
- \(\log _{x} 81=2\)
- \(\log _{3} x=5\)
- \(\log _{\frac{1}{3}} \frac{1}{27}=x\)
- Answer
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- \(x=9\)
- \(x=243\)
- \(x=3\)
When see an expression such as \(log_{3}27\), we can find its exact value two ways. By inspection we realize it means “\(3\) to what power will be \(27\)”? Since \(3^{3}=27\), we know \(log_{3}27=3\). An alternate way is to set the expression equal to \(x\) and then convert it into an exponential equation.
Find the exact value of each logarithm without using a calculator:
- \(\log _{5} 25\)
- \(\log _{9} 3\)
- \(\log _{2} \frac{1}{16}\)
Solution :
a.
\(\log _{5} 25\)
\(5\) to what power will be \(25\)?
\(\log _{5} 25=2\)
Or
Set the expression equal to \(x\).
\(\log _{5} 25=x\)
Change to exponential form.
\(5^{x}=25\)
Rewrite \(25\) as \(5^{2}\).
\(5^{x}=5^{2}\)
With the same base the exponents must be equal.
\(x=2 \quad\) Therefore \(, \log _{5} 25=2\).
b.
\(\log _{9} 3\)
Set the expression equal to \(x\).
\(\log _{9} 3=x\)
Change to exponential form.
\(9^{x}=3\)
Rewrite \(9\) as \(3^{2}\).
\(\left(3^{2}\right)^{x}=3^{1}\)
Simplify the exponents.
\(3^{2 x}=3^{1}\)
With the same base the exponents must be equal.
\(2 x=1\)
Solve the equation.
\(x=\frac{1}{2} \quad\) Therefore \(, \log _{9} 3=\frac{1}{2}\).
c.
\(\log _{2} \frac{1}{16}\)
Set the expression equal to \(x\).
\(\log _{2} \frac{1}{16}=x\)
Change to exponential form.
\(2^{x}=\frac{1}{16}\)
Rewrite \(16\) as \(2^{4}\).
\(2^{x}=\frac{1}{2^{4}}\)
\(2^{x}=2^{-4}\)
With the same base the exponents must be equal.
\(x=-4 \quad\) Therefore \(, \log _{2} \frac{1}{16}=-4\).
Find the exact value of each logarithm without using a calculator:
- \(\log _{12} 144\)
- \(\log _{4} 2\)
- \(\log _{2} \frac{1}{32}\)
- Answer
-
- \(2\)
- \(\frac{1}{2}\)
- \(-5\)
Find the exact value of each logarithm without using a calculator:
- \(\log _{9} 81\)
- \(\log _{8} 2\)
- \(\log _{3} \frac{1}{9}\)
- Answer
-
- \(2\)
- \(\frac{1}{3}\)
- \(-2\)
Graph Logarithmic Functions
To graph a logarithmic function \(y=log_{a}x\), it is easiest to convert the equation to its exponential form, \(x=a^{y}\). Generally, when we look for ordered pairs for the graph of a function, we usually choose an \(x\)-value and then determine its corresponding \(y\)-value. In this case you may find it easier to choose \(y\)-values and then determine its corresponding \(x\)-value.
Graph \(y=\log _{2} x\).
Solution :
To graph the function, we will first rewrite the logarithmic equation, \(y=\log _{2} x\), in exponential form, \(2^{y}=x\).
We will use point plotting to graph the function. It will be easier to start with values of \(y\) and then get \(x\).
| \(y\) | \(2^{y}=x\) | \((x,y)\) |
|---|---|---|
| \(-2\) | \(2^{-2}=\frac{1}{2^{2}}=\frac{1}{4}\) | \((\frac{1}{4},2)\) |
| \(-1\) | \(2^{-1}=\frac{1}{2^{1}}=\frac{1}{2}\) | \((\frac{1}{2},-1)\) |
| \(0\) | \(2^{0}=1\) | \((1,0)\) |
| \(1\) | \(2^{1}=2\) | \((2,1)\) |
| \(2\) | \(2^{2}=4\) | \((4,2)\) |
| \(3\) | \(2^{3}=8\) | \((8,3)\) |
Graph: \(y=\log _{3} x\).
- Answer
Graph: \(y=\log _{5} x\).
- Answer
The graphs of \(y=\log _{2} x, y=\log _{3} x\), and \(y=\log _{5} x\) are the shape we expect from a logarithmic function where \(a>1\).
We notice that for each function the graph contains the point \((1,0)\). This make sense because \(0=log_{a}1\) means \(a^{0}=1\) which is true for any \(a\).
The graph of each function, also contains the point \((a,1)\). This makes sense as \(1=\log _{a} a\) means \(a^{1}=a\). which is true for any \(a\).
Notice too, the graph of each function \(y=\log _{a} x\) also contains the point \(\left(\frac{1}{a},-1\right)\). This makes sense as \(-1=\log _{a} \frac{1}{a}\) means \(a^{-1}=\frac{1}{a}\), which is true for any \(a\).
Look at each graph again. Now we will see that many characteristics of the logarithm function are simply ’mirror images’ of the characteristics of the corresponding exponential function.
What is the domain of the function? The graph never hits the \(y\)-axis. The domain is all positive numbers. We write the domain in interval notation as \((0,∞)\).
What is the range for each function? From the graphs we can see that the range is the set of all real numbers. There is no restriction on the range. We write the range in interval notation as \((−∞,∞)\).
When the graph approaches the \(y\)-axis so very closely but will never cross it, we call the line \(x=0\), the \(y\)-axis, a vertical asymptote.
| Domain | \((0, \infty)\) |
| Range | \((-\infty, \infty)\) |
| \(x\)-intercept | \((1,0)\) |
| \(y\)-intercept | None |
| Contains | \((a, 1),\left(\frac{1}{a},-1\right)\) |
| Asymptote | \(y\)-axis |
Our next example looks at the graph of \(y=log_{a}x\) when \(0<a<1\).
Graph \(y=\log _{\frac{1}{3}} x\).
Solution :
To graph the function, we will first rewrite the logarithmic equation, \(y=\log _{\frac{1}{3}} x\), in exponential form, \(\left(\frac{1}{3}\right)^{y}=x\).
We will use point plotting to graph the function. It will be easier to start with values of \(y\) and then get \(x\).
| \(y\) | \(\left(\frac{1}{3}\right)^{y}=x\) | \((x,y)\) |
|---|---|---|
| \(-2\) | \(\left(\frac{1}{3}\right)^{-2}=3^{2}=9\) | \((9,-2)\) |
| \(-1\) | \(\left(\frac{1}{3}\right)^{-1}=3^{1}=3\) | \((3,-1)\) |
| \(0\) | \(\left(\frac{1}{3}\right)^{0}=1\) | \((1,0)\) |
| \(1\) | \(\left(\frac{1}{3}\right)^{1}=\frac{1}{3}\) | \(\left(\frac{1}{3}, 1\right)\) |
| \(2\) | \(\left(\frac{1}{3}\right)^{2}=\frac{1}{9}\) | \(\left(\frac{1}{9}, 2\right)\) |
| \(3\) | \(\left(\frac{1}{3}\right)^{3}=\frac{1}{27}\) | \(\left(\frac{1}{27}, 3\right)\) |
Graph: \(y=\log _{\frac{1}{2}} x\).
- Answer
Graph: \(y=\log _{\frac{1}{4}} x\).
- Answer
Now, let’s look at the graphs \(y=\log _{\frac{1}{2}} x, y=\log _{\frac{1}{3}} x\) and \(y=\log _{\frac{1}{4}} x\), so we can identify some of the properties of logarithmic functions where \(0<a<1\).
The graphs of all have the same basic shape. While this is the shape we expect from a logarithmic function where \(0<a<1\).
We notice, that for each function again, the graph contains the points,\((1,0),(a, 1),\left(\frac{1}{a},-1\right)\). This make sense for the same reasons we argued above.
We notice the domain and range are also the same—the domain is \((0,∞)\) and the range is \((−∞,∞)\). The \(y\)-axis is again the vertical asymptote.
We will summarize these properties in the chart below. Which also include when \(a>1\).
| When \(a>1\) | When \(0<a<1\) | ||
|---|---|---|---|
| Domain | \((0, \infty)\) | Domain | \((0, \infty)\) |
| Range | \((-\infty, \infty)\) | Range | \((-\infty, \infty)\) |
| \(x\)-intercept | \((1,0)\) | \(x\)-intercept | \((1,0)\) |
| \(y\)-intercept | None | \(y\)-intercept | None |
| Contains | \((a, 1),\left(\frac{1}{a},-1\right)\) | Contains | \((a, 1),\left(\frac{1}{a},-1\right)\) |
| Asymptote | \(y\) -axis | Asymptote | \(y\) -axis |
| Basic shape | Increasing | Basic shape | Decreasing |
We talked earlier about how the logarithmic function \(f^{-1}(x)=\log _{a} x\) is the inverse of the exponential function \(f(x)=a^{x}\). The graphs in Figure 10.3.12 show both the exponential (blue) and logarithmic (red) functions on the same graph for both \(a>1\) and \(0<a<1\).
Notice how the graphs are reflections of each other through the line \(y=x\). We know this is true of inverse functions. Keeping a visual in your mind of these graphs will help you remember the domain and range of each function. Notice the \(x\)-axis is the horizontal asymptote for the exponential functions and the \(y\)-axis is the vertical asymptote for the logarithmic functions.
Use Logarithmic Models in Applications
There are many applications that are modeled by logarithmic equations. We will first look at the logarithmic equation that gives the decibel (dB) level of sound. Decibels range from \(0\), which is barely audible to \(160\), which can rupture an eardrum. The \(10^{−12}\) in the formula represents the intensity of sound that is barely audible.
Decibel Level of Sound
The loudness level, \(D\), measured in decibels, of a sound of intensity, \(I\), measured in watts per square inch is
\(D=10 \log \left(\frac{I}{10^{-12}}\right)\)
Extended exposure to noise that measures \(85\) dB can cause permanent damage to the inner ear which will result in hearing loss. What is the decibel level of music coming through ear phones with intensity \(10^{−2}\) watts per square inch?
Solution :
| Substitute in the intensity level, \(I\). | |
| Simplify. | |
| Since \(\log 10^{10}=10\). | |
| Multiply. | |
| The decibel level of music coming through earphones is \(100\) dB. |
What is the decibel level of one of the new quiet dishwashers with intensity \(10^{−7}\) watts per square inch?
- Answer
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The quiet dishwashers have a decibel level of \(50\) dB.
What is the decibel level heavy city traffic with intensity \(10^{−3}\) watts per square inch?
- Answer
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The decibel level of heavy traffic is \(90\) dB.
The magnitude \(R\) of an earthquake is measured by a logarithmic scale called the Richter scale . The model is \(R=\log I\), where \(I\) is the intensity of the shock wave. This model provides a way to measure earthquake intensity .
The magnitude \(R\) of an earthquake is measured by\(R=\log I\), where \(I\) is the intensity of its shock wave.
In 1906, San Francisco experienced an intense earthquake with a magnitude of \(7.8\) on the Richter scale. Over \(80\)% of the city was destroyed by the resulting fires. In 2014, Los Angeles experienced a moderate earthquake that measured \(5.1\) on the Richter scale and caused $\(108\) million dollars of damage. Compare the intensities of the two earthquakes.
Solution :
To compare the intensities, we first need to convert the magnitudes to intensities using the log formula. Then we will set up a ratio to compare the intensities.
Convert the magnitudes to intensities.
\(R=\log I\)
1906 earthquake
\(7.8=\log I\)
Convert to exponential form.
\(I=10^{7.8}\)
2014 earthquake
\(5.1=\log I\)
Convert to exponential form.
\(I=10^{5.1}\)
Form a ratio of the intensities.
\(\frac{\text { Intensity for } 1906}{\text { Intensity for } 2014}\)
Substitute in the values.
\(\frac{10^{7.8}}{10^{5.1}}\)
Divide by subtracting the exponents.
\(10^{2.7}\)
Evaluate.
\(501\)
The intensity of the 1906 earthquake was about \(501\) times the intensity of the 2014 earthquake.
In 1906, San Francisco experienced an intense earthquake with a magnitude of \(7.8\) on the Richter scale. In 1989, the Loma Prieta earthquake also affected the San Francisco area, and measured \(6.9\) on the Richter scale. Compare the intensities of the two earthquakes.
- Answer
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The intensity of the 1906 earthquake was about \(8\) times the intensity of the 1989 earthquake.
In 2014, Chile experienced an intense earthquake with a magnitude of \(8.2\) on the Richter scale. In 2014, Los Angeles also experienced an earthquake which measured \(5.1\) on the Richter scale. Compare the intensities of the two earthquakes.
- Answer
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The intensity of the earthquake in Chile was about \(1,259\) times the intensity of the earthquake in Los Angeles.
Access these online resources for additional instruction and practice with evaluating and graphing logarithmic functions.
Key Concepts
- Properties of the Graph of \(y=\log _{a} x\):
| When \(a>1\) | When \(0<a<1\) | ||
|---|---|---|---|
| Domain | \((0, \infty)\) | Domain | \((0, \infty)\) |
| Range | \((-\infty, \infty)\) | Range | \((-\infty, \infty)\) |
| \(x\)-intercept | \((1,0)\) | \(x\)-intercept | \((1,0)\) |
| \(y\)-intercept | None | \(y\)-intercept | None |
| Contains | \((a, 1),\left(\frac{1}{a},-1\right)\) | Contains | \((a, 1),\left(\frac{1}{a},-1\right)\) |
| Asymptote | \(y\) -axis | Asymptote | \(y\) -axis |
| Basic shape | Increasing | Basic shape | Decreasing |
- Decibel Level of Sound: The loudness level, \(D\), measured in decibels, of a sound of intensity, \(I\), measured in watts per square inch is \(D=10 \log \left(\frac{I}{10^{-12}}\right)\).
- Earthquake Intensity: The magnitude \(R\) of an earthquake is measured by \(R=\log I\), where \(I\) is the intensity of its shock wave.
Glossary
- common logarithmic function
-
The function \(f(x)=\log x\) is the common logarithmic function with base \(10\), where \(x>0\).
\(y=\log x\) is equivalent to \(x=10^{y}\)
- logarithmic function
-
The function \(f(x)=\log _{a} x\) is the logarithmic function with base \(a\), where \(a>0,x>0\), and \(a≠1\).
\(y=\log _{a} x\) is equivalent to \(x=a^{y}\)
- natural logarithmic function
-
The function \(f(x)=\ln x\) is the natural logarithmic function with base \(e\), where \(x>0\).
\(y=\ln x\) is equivalent to \(x=e^{y}\)