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

Logarithms and Exponents[edit | edit source]

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 ${\displaystyle b>0}$.

Laws of Logarithms[edit | edit source]

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

Natural Logarithms[edit | edit source]

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.

Solving Logarithmic and Exponential Equations[edit | edit source]

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]}

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

Converting Relationships to a Linear Form[edit | edit source]

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.

Exponential Relationships[edit | edit source]

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:

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

Power Relationships[edit | edit source]

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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