\section{Logarithms} \definition{} The \textit{logarithm} is the inverse of the exponent. That is, if $b^p = c$, then $\log_b{c} = p$. \\ In other words, $\log_b{c}$ asks the question ``what power do I need to raise $b$ to to get $c$?'' \\ \medskip In both $b^p$ and $\log_b{c}$, the number $b$ is called the \textit{base}. \problem{} Evaluate the following by hand: \begin{enumerate} \item $\log_{10}{(1000)}$ \vfill \item $\log_2{(64)}$ \vfill \item $\log_2{(\frac{1}{4})}$ \vfill \item $\log_x{(x)}$ for any $x$ \vfill \item $log_x{(1)}$ for any $x$ \vfill \end{enumerate} \pagebreak \definition{} There are a few ways to write logarithms: \begin{itemize} \item[] $\log{x} = \log_{10}{x}$ \item[] $\lg{x} = \log_{10}{x}$ \item[] $\ln{x} = \log_e{x}$ \end{itemize} \definition{} The \textit{domain} of a function is the set of values it can take as inputs. \\ The \textit{range} of a function is the set of values it can produce. \medskip For example, the domain and range of $f(x) = x$ is $\mathbb{R}$, all real numbers. \\ The domain of $f(x) = |x|$ is $\mathbb{R}$, and its range is $\mathbb{R}^+ \cup \{0\}$, all positive real numbers and 0. \\ \medskip Note that the domain and range of a function are not always equal. \problem{} What is the domain of $f(x) = 5^x$? \\ What is the range of $f(x) = 5^x$? \vfill \problem{} What is the domain of $f(x) = \log{x}$? \\ What is the range of $f(x) = \log{x}$? \vfill \pagebreak \problem{} Prove the following identities: \\ \begin{enumerate}[itemsep=2mm] \item $\log_b{(b^x)} = x$ \item $b^{\log_b{x}} = x$ \item $\log_b{(xy)} = \log_b{(x)} + \log_b{(y)}$ \item $\log_b{(\frac{x}{y})} = \log_b{(x)} - \log_b{(y)}$ \item $\log_b{(x^y)} = y \log_b{(x)}$ \end{enumerate} \vfill \begin{instructornote} A good intro to the following sections is the linear slide rule: \begin{center} \begin{tikzpicture}[scale=1] \linearscale{2}{1}{} \linearscale{0}{0}{} \slideruleind {5} {1} {2 + 3 = 5} \end{tikzpicture} \end{center} Take two linear rulers, offset one, and you add. \\ If you do the same with a log scale, you multiply! \\ \vspace{1ex} Note that the slide rules above start at 0. \linehack{} After assembling the paper slide rule, you can make a visor with some transparent tape. Wrap a strip around the slide rule, sticky side out, and stick it to itself to form a ring. Cover the sticky side with another layer of tape, and trim the edges to make them straight. Use the edge of the visor to read your slide rule! \end{instructornote} \pagebreak