\section{} \definition{} A \textit{finite continued fraction} is an expression of the form \[ a_0 + \cfrac{1}{a_1+\cfrac{1}{a_2 + \cfrac{1}{a_3 + ... + \cfrac{1}{a_{k-1} + \cfrac{1}{a_k}}}}} \] where $a_0, a_1, ..., a_k$ are all in $\mathbb{Z}^+$. We'll denote this as $[a_0, a_1, ..., a_k]$. \problem{} Write each of the following as a continued fraction. \par \hint{Solve for one $a_n$ at a time.} \begin{itemize} \item $5/12$ \item $5/3$ \item $33/23$ \item $37/31$ \end{itemize} \vfill \problem{} Write each of the following continued fractions as a regular fraction in lowest terms: \par \begin{itemize} \item $[2,3,2]$ \item $[1,4,6,4]$ \item $[2,3,2,3]$ \item $[9,12,21,2]$ \end{itemize} \vfill \pagebreak \problem{} Let $\frac{p}{q}$ be a positive rational number in lowest terms. Perform the Euclidean algorithm to obtain the following sequence: \begin{align*} p \ &= \ q_0 q + r_1 \\ q \ &= \ q_1 r_1 + r_2 \\ r_1 \ &= \ q_2 r_2 + r_3 \\ &\vdots \\ r_{k-1} \ &= \ q_k r_k + 1 \\ r_k \ &= \ q_{k+1} \end{align*} We know that we will eventually get $1$ as the remainder because $p$ and $q$ are relatively prime. \par Show that $p/q = [q_0, q_1, ..., q_{k+1}]$. \vfill \problem{} Repeat \ref{num2cf} using the method outlined in \ref{euclid}. \vfill \pagebreak \definition{} An \textit{infinite continued fraction} is an expression of the form \[ a_0 + \cfrac{1}{a_1+\cfrac{1}{a_2 + \cfrac{1}{a_3 + \cfrac{1}{a_4 + ...}}}} \] where $a_0, a_1, a_2, ...$ are in $\mathbb{Z}^+$. To prove that this expression actually makes sense and equals a finite number is beyond the scope of this worksheet, so we assume it for now. This is denoted $[a_0, a_1, a_2, ...]$. \problem{} Using a calculator, compute the first five terms of the continued fraction expansion of the following numbers. Do you see any patterns? \begin{itemize} \item $\sqrt{2}$ \item $\pi \approx 3.14159...$ \item $\sqrt{5}$ \item $e \approx 2.71828...$ \end{itemize} \vfill \problem{} Show that an $\alpha \in \mathbb{R}^+$ can be written as a finite continued fraction if and only if $\alpha$ is rational. \par \hint{For one of the directions, use \ref{euclid}} \vfill \pagebreak \definition{} The continued fraction $[a_0, a_1, a_2, ...]$ is \textit{periodic} if it ends in a repeating sequence of digits. \par A few examples are below. We denote the repeating sequence with a line. \begin{itemize} \item $[1,2,2,2,...] = [1, \overline{2}]$ is periodic. \item $[1,2,3,4,5,...]$ is not periodic. \item $[1,3,7,6,4,3,4,3,4,3,...] = [1,3,7,6,\overline{4,3}]$ is periodic. \item $[1,2,4,8,16, ...]$ is not periodic. \end{itemize} \problem{} \begin{itemize} \item Show that $\sqrt{2} = [1, \overline{2}]$. \item Show that $\sqrt{5} = [1, \overline{4}]$. \end{itemize} \hint{use the same strategy as \ref{irrational} but without a calculator.} \vfill \problem{Challenge I} Express the following continued fractions in the form $\frac{a+\sqrt{b}}{c}$ where $a$, $b$, and $c$ are integers: \par \begin{itemize} \item $[~\overline{1}~]$ \item $[~\overline{2,5}~]$ \item $[~1, 3, \overline{2,3}~]$ \end{itemize} \vfill \problem{Challenge II} Let $\alpha = [~a_0,~ ...,~ a_r,~ \overline{a_{r+1},~ ...,~ a_{r+p}}~]$ be any periodic continued fraction. \par Prove that $\alpha$ is of the form $\frac{a+\sqrt{b}}{c}$ for some integers $a,b,c$ where $b$ is not a perfect square. \vfill \problem{Challenge III} Prove that any number of the form $\frac{a+\sqrt{b}}{c}$ where $a,b,c$ are integers and $b$ is not a perfect square can be written as a periodic continued fraction. %\begin{rmk} %Numbers of the form $\frac{a+\sqrt{b}}{c}$ where $a,b,c$ are integers and $b$ is not a perfect square are the ``simplest'' irrational numbers in the following sense. A number is rational if and only if it is the solution to a degree $1$ polynomial equation, $ax+b = 0$. Similarly, a number is of the form $\frac{a+\sqrt{b}}{c}$ if it is the solution to a degree $2$ polynomial equation, $ax^2 + bx + c = 0$ (Bonus exercise: prove this). Such numbers are called \textit{quadratic} irrational numbers or \textit{degree 2} irrational numbers. %\end{rmk} %\begin{rmk} %Notice that the results of this worksheet provide a very clean characterization of continued fraction expansions: %\begin{itemize} %\item $\alpha$ is a rational number if and only if it has a finite continued fraction expansion. %\item $\alpha$ is a degree $2$ irrational number if and only if it has an infinite periodic continued fraction expansion. %\end{itemize} %\end{rmk} \vfill \pagebreak