Definition: Logarithm

Let $N$ and $b$ be positive real numbers, with $b \neq 1$. Then the logarithm of $N$ (with respect) to the base $b$ is the exponent by which $b$ must be raised to yield $N$, and is denoted by $\log _{b} N$

Rules of Logarithms

$\begin{array}{ll} \text{L}1. & N=b^{\log _{b} N}\\\\ \text{L}2. & x=\log _{b} b^{x}\\\\ \text{L}3. & \log _{b} b=1\\\\ \text{L}4. & \log _{b} 1=0\\\\ \text{L}5. & \log _{b}(M N)=\log _{b} M+\log _{b} N\\\\ \text{L}6. & \log _{b} N^{p}=p \log _{b} N\\\\ \text{L}7. & \log _{b}\left(\displaystyle\frac{M}{N}\right)=\log _{b} M-\log _{b} N\\\\ \text{L}8. & \log _{a} N=\displaystyle\frac{\log _{b} N}{\log _{b} N}\\\\ \text{L}9. & \log _{a} N=\displaystyle\frac{1}{\log _{N} a}\\\\ \text{L}10. & \log _{a^{p}} N=\displaystyle\frac{1}{p} \log _{a} N\\\\ \text{L}11. & a^{\log _{k} b}=b^{\log _{k} a} \end{array}$

Common Logarithm

The logarithm of $N$ to the base $10\left(\log _{10} N\right)$ is said to be a common logarithm, and is usually written as $\log N$ (omitting the base). where $n$ is called the characteristic and $\log a$ is called the mantissa of $\log N$.

$\begin{array}{|l|} \hline\log _{10} N=\log N\\ \hline \end{array}$

If $\quad N=a \times 10^{n}$,

then $\quad \log N=\log \left(a \times 10^{n}\right)=\log 10^{n}+\log a=n+\log a$ where $n$ is called the characteristic and $\log a$ is called the mantissa of $\log N$.

Note that $n$ is an integer and $1 \leq a<10$.

Euler's Number

As a positive integer $n$ become very large, the value of $\left(1+\displaystyle\frac{1}{n}\right)^{n}$ approaches an irrational number, which is denoted by $e$.

Natural Logarithm

The logarithm of $N$ to the base $e$ is called a natural logarithm, and is denoted by $\ln N$.

$\begin{array}{|l|} \hline\log _{e} N=\ln N\\ \hline \end{array}$

Write the following expressions in terms of $\log x$, $\log y$ and $\log z$.

(a)	$\log (x^{2} y)$	Show Solution
(b)	$\log \displaystyle\frac{x^{3} y^{2}}{z}$	Show Solution
(c)	$\log \displaystyle\frac{\sqrt{x} \sqrt[3]{y^{2}}}{z^{4}}$	Show Solution
(d)	$\log (x y z)$	Show Solution
(e)	$\log \left(\displaystyle\frac{x}{y z}\right)$	Show Solution
(f)	$\log \left(\displaystyle\frac{x}{y}\right)^{2}$	Show Solution
(g)	$\log \left(x y\right)^{\frac{1}{3}}$	Show Solution
(h)	$\log (x \sqrt{z})$	Show Solution
(i)	$\log \displaystyle\frac{\sqrt[3]{x}}{\sqrt[3]{y z}}$	Show Solution
(j)	$\log \sqrt[4]{\displaystyle\frac{x^{3} y^{2}}{z^{4}}}$	Show Solution
(k)	$\log \left(x \sqrt{\displaystyle\frac{\sqrt{x}}{z}}\right)$	Show Solution
(l)	$\log \sqrt{\displaystyle\frac{x y^{2}}{z^{8}}}$	Show Solution

Prove the following statements.

(a)	$\quad\log _{\sqrt{b}} x=2 \log _{b} x$		Show Solution
(b)	$\quad\log _{\frac{1}{\sqrt{b}}} \sqrt{x}=-\log _{b} x$		Show Solution
(c)	$\quad\log _{b^{4}} x^{2}=\log _{b} \sqrt{x}$		Show Solution

Given that $\log 2=x, \log 3=y$ and $\log 7=z$, express the following expressions in terms of $x, y$, and $z$.

(a)	$\log 12$	Show Solution
(b)	$\log 200$	Show Solution
(c)	$\log \displaystyle\frac{14}{3}$	Show Solution
(d)	$\log 0.3$	Show Solution
(e)	$\log 1.5$	Show Solution
(f)	$\log 10.5$	Show Solution
(g)	$\log 15$	Show Solution
(h)	$\log \displaystyle\frac{6000}{7}$	Show Solution

Solve the following logarithmic equations.

(a)	$\ln x=-3$	Show Solution
(b)	$\log (3 x-2)=2$	Show Solution
(c)	$2 \log x=\log 2+\log (3 x-4)$	Show Solution
(d)	$\log x+\log (x-1)=\log (4 x)$	Show Solution
(e)	$\log _{3}(x+25)-\log _{3}(x-1)=3$	Show Solution
(f)	$\log _{9}(x-5)+\log _{9}(x+3)=1$	Show Solution
(g)	$\log x+\log (x-3)=1$	Show Solution
(h)	$\log _{2}(x-2)+\log _{2}(x+1)=2$	Show Solution

Find the inverse of each of the following functions.

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Logarithm: Miscellaneous Exercise

Definition: Logarithm

Rules of Logarithms

Common Logarithm

Euler's Number

Natural Logarithm

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