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# Exponential and Index Functions

## Index laws

\begin{equation}\begin{split}
  a^m \times a^n & = a^{m+n} \\
  a^m \div a^n & = a^{m-n}4 \\
  (a^m)^n & = a^{_mn} \\
  (ab)^m & = a^m b^m \\
  {({a \over b})}^m & = {a^m \over b^m}
\end{split}\end{equation}

## Fractional indices

$$^n\sqrt{x}=x^{1/n}$$

## Logarithms

$$\log_b (x) = n \quad \operatorname{where} \hspace{0.5em} b^n=x$$

## Using logs to solve index eq's

Used for equations without common base exponent

Or change base:  
$$\log_b c = {{\log_a c} \over {\log_a b}}$$

If $a<1, \quad \log_{b} a < 0$ (flip inequality operator)

## Exponential functions

$e^x$ - natural exponential function


$$\lim_{h \rightarrow 0} {{e^h-1} \over h}=1$$

## Logarithm laws

\begin{equation}\begin{split}
  \log_a(mn) & = \log_am + \log_an \\
  \log_a({m \over n}) & = \log_am - \log_a \\
  \log_a(m^p) & = p\log_am \\
  \log_a(m^{-1}) & = -\log_am \\
  \log_a1 = 0 & \text{ and } \log_aa = 1
\end{split}\end{equation}


## Inverse functions

For $f: \mathbb{R} \rightarrow \mathbb{R}, f(x)=a^x$, inverse is:

$$f^{-1}: \mathbb{R}^+ \rightarrow \mathbb{R}, f^{-1}=log_ax$$

## Euler's number

$$e= \lim_{n \rightarrow \infty} (1 + {1 \over n})^n$$

## Literal equations

_Literal equation_ - no numerical solutions

## Exponential and logarithmic modelling

$$A = A_0 e^{kt}$$

where  
$A_0$ is initial value  
$t$ is time taken  
$k$ is a constant  
For continuous growth, $k > 0$  
For continuous decay, $k < 0$

## Graphing expomnential functions

$$f(x)=Aa^{k(x-b)} + c, \quad \vert \> a > 1$$

- **$y$-intercept** at $(0, A \cdot a^{-kb}+c)$
- **horizontal asymptote** at $y=c$
- **domain** is $\mathbb{R}$
- **range** is $(c, \infty)$
- dilation of factor $A$ from $x$-axis
- dilation of factor $1 \over k$ from $y$-axis

## Graphing logarithmic functions

$log_e x$ is the inverse of $e^x$ (reflection across $y=x$)

$$f(x)=A \log_a k(x-b) + c$$

where

- **domain** is $(b, \infty)$
- **range** is $\mathbb{R}^+$
- **vertical asymptote** at $x=b$
- $y$-intercept exists if $b<0$
- dilation of factor $A$ from $x$-axis
- dilation of factor $1 \over k$ from $y$-axis