3.5: Change of Base
- Page ID
- 958
While it is possible to change bases by always going back to exponential form, it is more efficient to find out how to change the base of logarithms in general. since there are only base \(e\) and base 10 logarithms on most calculators, how would you evaluate an expression like \(\log _{3} 12\)?
Changing the Base of Logarithms
The change of base property states:
\(\log _{b} x=\frac{\log _{a} x}{\log _{a} b}\)
You can derive this formula by converting \(\log _{b} x\) to exponential form and then taking the log base \(x\) of both sides. This is shown below.
\(\begin{aligned} \log _{b} x &=y \\ b^{y} &=x \\ \log _{a} b^{y} &=\log _{a} x \\ y \log _{a} b &=\log _{a} x \\ y &=\frac{\log _{a} x}{\log _{a} b} \end{aligned}\)
Therefore, \(\log _{b} x=\frac{\log _{a} x}{\log _{a} b}\)
If you were to evaluate \(\log _{3} 4\) using your calculator, you may need to use the change of base formula since some calculators only have base 10 or base \(e\). The result would be:
\(\log _{3} 4=\frac{\log _{10} 4}{\log _{10} 3}=\frac{\ln 4}{\ln 3} \approx 1.262\)
Examples
Earlier, you were asked how to use a calculator to evaluate an expression like \(\log _{3} 12\). In order to evaluate an expression like \(\log _{3} 12\) you have some options on your calculator:
\(\frac{\ln 12}{\ln 3}=\frac{\log 12}{\log 3} \approx 2.26\)
Some graphing calculators also have another option. Press the MATH followed by the A buttons and enter \(\log _{3} 12\)
Prove the following log identity.
\(\log _{a} b=\frac{1}{\log _{b} a}\)
\(\log _{a} b=\frac{\log _{x} b}{\log _{x} a}=\frac{1}{\frac{\log _{x} a}{\log _{x} b}}=\frac{1}{\log _{b} a}\)
Simplify to an exact result: \(\left(\log _{4} 5\right) \cdot\left(\log _{3} 4\right) \cdot\left(\log _{5} 81\right) \cdot\left(\log _{5} 25\right)\)
\(\frac{\log 5}{\log 4} \cdot \frac{\log 4}{\log 3} \cdot \frac{\log 3^{4}}{\log 5} \cdot \frac{\log 5^{2}}{\log 5}=\frac{\log 5}{\log 4} \cdot \frac{\log 4}{\log 3} \cdot \frac{4 \cdot \log 3}{\log 5} \cdot \frac{2 \cdot \log 5}{\log 5}=4 \cdot 2=8\)
Evaluate: \(\log _{2} 48-\log _{4} 36\)
\(\begin{aligned} \log _{2} 48-\log _{4} 36 &=\frac{\log 48}{\log 2}-\frac{\log 36}{\log 4} \\ &=\frac{\log 48}{\log 2}-\frac{\log 6^{2}}{\log 2^{2}} \\ &=\frac{\log 48}{\log 2}-\frac{2 \cdot \log 6}{2 \cdot \log 2} \\ &=\frac{\log 48-\log 6}{\log 2} \\ &=\frac{\log \left(\frac{48}{6}\right)}{\log 2} \\ &=\frac{\log 8}{\log 2} \\ &=\frac{\log 2^{3}}{\log 2} \\ &=\frac{3 \cdot \log 2}{\log 2} \\ &=3 \end{aligned}\)
Given \(\log _{3} 5 \approx 1.465\) find \(\log _{25} 27\) without using a log button on the calculator.
\(\log _{25} 27=\frac{\log 3^{3}}{\log 5^{2}}=\frac{3}{2} \cdot \frac{1}{\left(\frac{\log 5}{\log 3}\right)}=\frac{3}{2} \cdot \frac{1}{\log _{3} 5} \approx \frac{3}{2} \cdot \frac{1}{1.465}=1.0239\)
Review
Evaluate each expression by changing the base and using your calculator.
1. \(\log _{6} 15\)
2. \(\log _{9} 12\)
3. \(\log _{5} 25\)
Evaluate each expression.
4. \(\log _{8}\left(\log _{4}\left(\log _{3} 81\right)\right)\)
5. \(\log _{2} 3 \cdot \log _{3} 4 \cdot \log _{6} 16 \cdot \log _{4} 6\)
6. \(\log 125 \cdot \log _{9} 4 \cdot \log _{4} 81 \cdot \log _{5} 10\)
7. \(\log _{5}\left(5^{\log _{5} 125}\right)\)
8. \(\log \left(\log _{6}\left(\log _{2} 64\right)\right)\)
9. \(10^{\log _{100} 9}\)
10. \(\left(\log _{4} x\right)\left(\log _{x} 16\right)\)
11. \(\log _{49} 49^{5}\)
12. \(3 \log _{24} 24^{8}\)
13. \(4^{\log _{2} 3}\)
Prove the following properties of logarithms.
14. \(\left(\log _{a} b\right)\left(\log _{b} c\right)=\log _{a} c\)
15. \(\left(\log _{a} b\right)\left(\log _{b} c\right)\left(\log _{c} d\right)=\log _{a} d\)