A-level Mathematics/CIE/Pure Mathematics 2/Logarithmic and Exponential Functions

A logarithm is the inverse function of an exponent.

e.g. The inverse of the function ${\displaystyle f(x)=3^{x}}$ is ${\displaystyle f^{-1}(x)=\log _{3}x}$.

In general, ${\displaystyle y=b^{x}\iff x=\log _{b}y}$, given that ${\displaystyle b>0}$.

The laws of logarithms can be derived from the laws of exponentiation:

${\displaystyle {\begin{aligned}x^{a+b}=x^{a}\times x^{b}&\iff \log a+\log b=\log ab\\x^{a-b}=x^{a}\div x^{b}&\iff \log a-\log b=\log a/b\\(x^{a})^{b}=x^{ab}&\iff \log a^{b}=b\log a\end{aligned}}}$

These laws apply to logarithms of any given base

The natural logarithm is a logarithm with base ${\displaystyle e}$, where ${\displaystyle e}$ is a constant such that the function ${\displaystyle e^{x}}$ is its own derivative.

The natural logarithm has a special symbol: ${\displaystyle \ln x}$

The graph ${\displaystyle y=e^{kx}}$ exhibits exponential growth when ${\displaystyle k>0}$ and exponential decay when ${\displaystyle k<0}$. The inverse graph is ${\displaystyle y={\frac {1}{k}}\ln x}$. Here is an interactive graph which shows the two functions as inverses of one another.

An exponential equation is an equation in which one or more of the terms is an exponential function. e.g. ${\displaystyle 5^{x}=2^{x+2}}$. Exponential equations can be solved with logarithms.

e.g. Solve ${\displaystyle 3^{x+1}=4^{2x-1}}$

${\displaystyle {\begin{aligned}3^{x+1}&=4^{2x-1}\\(x+1)\ln 3&=(2x-1)\ln 4\\x\ln 3+\ln 3&=2x\ln 4-\ln 4\\\ln 3+\ln 4&=x(2\ln 4-\ln 3)\\x&={\frac {\ln 3+\ln 4}{2\ln 4-\ln 3}}\\x&\approx 1.4844\end{aligned}}}$

A logarithmic equation is an equation wherein one or more of the terms is a logarithm.

e.g. Solve ${\displaystyle \lg x+\lg(x+2)=2}$ ^{[note 1]}

${\displaystyle {\begin{aligned}\lg x+\lg(x+2)&=2\\\lg(x(x+2))&=2\\x(x+2)&=100\\x^{2}+2x&=100\\(x+1)^{2}&=101\\x+1&={\sqrt {101}}\\x&=-1\pm {\sqrt {101}}\end{aligned}}}$

In maths and science, it is easier to deal with linear relationships than non-linear relationships. Logarithms can be used to convert some non-linear relationships into linear relationships.

An exponential relationship is of the form ${\displaystyle y=ab^{x}}$. If we take the natural logarithm of both sides, we get ${\displaystyle \ln y=\ln a+x\ln b}$. We now have a linear relationship between ${\displaystyle \ln y}$ and ${\displaystyle x}$.

e.g. The following data is related with an exponential relationship. Determine this exponential relationship, then convert it to linear form.

${\displaystyle {\begin{aligned}{\text{Exponential relationship }}\implies y&=ab^{x}\\5&=ab^{0}=a(1)\\a&=5\\y&=5b^{x}\\45&=5b^{2}\\9&=b^{2}\\b&=3\\y&=5(3^{x})\end{aligned}}}$

Now convert it to linear form by taking the natural logarithm of both sides:

${\displaystyle {\begin{aligned}y&=5(3^{x})\\\ln y&=\ln 5+x\ln 3\end{aligned}}}$

A power relationship is of the form ${\displaystyle y=ax^{b}}$. If we take the natural logarithm of both sides, we get ${\displaystyle \ln y=\ln a+b\ln x}$. This is a linear relationship between ${\displaystyle \ln y}$ and ${\displaystyle \ln x}$.

e.g. The amount of time that a planet takes to travel around the sun (its orbital period) and its distance from the sun are related by a power law. Use the following data^[1] to deduce this power law:

${\displaystyle {\begin{aligned}{\text{Power law}}\implies T&=aR^{b}\\{\text{Use Earth data}}\implies 365.2&=a(149.6^{b})\\\ln 365.2&=\ln a+b\ln 149.6\\{\text{Use Mars data}}\implies 687.0&=a(227.9^{b})\\\ln 687.0&=\ln a+b\ln 227.9\\\ln 687.0-\ln 365.2&=\ln a-\ln a+b\ln 227.9-b\ln 149.6\\\ln {\frac {687.0}{365.2}}&=0+b(\ln {\frac {227.9}{149.6}})\\b&={\frac {\ln {\tfrac {687.0}{365.2}}}{\ln {\tfrac {227.9}{149.6}}}}\approx 1.5011\\\ln 365.2&=\ln a+1.5011\ln 149.6\\\ln a&=\ln 365.2-\ln 1839.9\\\ln a&=\ln 0.1985\\a&=0.1985\\\therefore T&=0.1985R^{1.5011}\end{aligned}}}$

References

1. ↑ Retrieved from NASA's Planetary Fact Sheet

Notes

1. ↑ ${\displaystyle \lg }$ is another way of writing ${\displaystyle \log _{10}}$

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