\section{Groups} \definition{} A \textit{group} $G = (S, \ast)$ consists of a set $S$ and a binary operator $\ast$. \par By definition, a group always has the following properties: \begin{enumerate} \item $G$ is closed under $\ast$. In other words, $a, b \in G \implies a \ast b \in G$. \item $\ast$ is associative: $(a \ast b) \ast c = a \ast (b \ast c)$ for all $a,b,c \in G$ \item There is an \textit{identity} $e \in G$, so that $a \ast e = a \ast e = a$ for all $a \in G$. \item Any $a \in G$ has an \textit{inverse} $a^{-1} \in G$ that satisfies $a \ast a^{-1} = a^{-1} \ast a = e$. \par \end{enumerate} \note[Note]{ Commutativity is \textit{not} a required property of a group! \\ In most cases, $a \ast b \neq b \ast a$. } \problem{} Is $(\znz{5}, +)$ a group? \par How about $(\znz{5}, -)$? \par \hint{In this problem, $+$ and $-$ work just as you'd expect.} \vfill \problem{} What is the smallest possible group? \begin{solution} Let $(G, \ast)$ be our group, where $G = \{e\}$ and $\ast$ is defined by the identity $e \ast e = e$ Verifying that the trivial group is a group is trivial. \end{solution} \vfill \problem{} How many distinct groups have two elements? \par \hint{ Two groups are \say{the same} if the elements of one can be renamed to get the other. \\ A group is fully defined by its multiplication table. } \vfill \pagebreak %\problem{} %Is $(\znz{17}, \times)$ a group? \par %How should we modify $\znz{17}$ to make it one? %\problem{} %Is $(\znz{6}, \times)$ a group? \par %How should we modify $\znz{6}$ to make it one? \par %\hint{ % Be careful, this isn't as easy as \ref{firstcross}. \\ % Which elements aren't invertible? %} %\definition{} %Building on problems \ref{num:firstcross} and \ref{num:secondcross}, we'll define $(\znz{n})^\times$ as the multiplicative %group of integers mod $n$. \par %Specifically, $(\znz{n})^\times$ is the set of all integers coprime to $n$. \par %\vspace{2mm} %For example, $(\znz{6})^\times = \{1, 5\}$ \par %and $(\znz{15})^\times = \{1, 2, 4, 7, 8, 11, 13, 14\}$ \par %\vspace{2mm} %Note that $0$ is the identity in $\znz{n}$ and $1$ is the identity in $(\znz{n})^\times$\hspace{-1.5ex}. \par %\note[Note]{ % Also, notice that we've omitted the operations $+$ and $\times$ in the two groups above. \\ % These operations are implicitly \say{attached} to $\znz{n}$ and $(\znz{n})^\times$\hspace{-1.5ex}, \\ % and we rarely write them for the sake of cleaner notation. %} \vfill \definition{} Let $G$ be a group, $a$ an element of $G$, and $n \in \mathbb{Z}^+$. \par $a^n$ is the defined as $a \ast a \ast ... \ast a$, repeated $n$ times. \vspace{1mm} Note that this is \textbf{not} \say{normal} exponentiation! \par If our group's operator is $+$ (for example, $\znz{5}$), $a^n = a + ... + a$, \par which you'll recognize as multipication. \vspace{1mm} Beware of this odd notation. By convention, we use \say{multiplicative} notation when working with groups---so, $a \ast b$ may also be written as $ab$, and $a \ast a \ast a$ may be written as $a^3$. \vspace{1mm} Again, remember that $a^n$ simply means \say{$\ast$ $a$ with itself $n$ times,} \par regardless of the specific operator our group uses. \problem{} Let $a$ be an element of a finite group. \par Show that there is a positive integer $n$ so that $a^n = e$. \par \vspace{2mm} The smallest such $n$ defines the \textit{order} of $g$. \vfill \problem{} Find the order of 5 in $(\znz{25}, +)$. \par %Find the order of 2 in $((\znz{17})^\times, \times)$. \par Find the order of 2 in $(\znz{7}, +)$. \par \vfill \pagebreak \definition{} Let $G$ be a group. \par We say a $g \in G$ is a \textit{generator} of $G$ if every element in $G$ can be written as some power of $g$. \vspace{2mm} If $G$ has a generator, we say $G$ is \textit{cyclic.} \problem{} Find a generator of $\znz{7}$. Then, find a generator of $(\znz{7})^\times$ \vfill \definition{} Let $G$ be a group. \par The \textit{order} of $G$ is the number of elements in $G$. \par We'll write this as $|G|$, using the same notation we use with sets. \par \note[Note]{ Don't confuse the order of an \textbf{element} with the order of a \textbf{group}! } \problem{} Let $G$ be a cyclic group, and let $g$ be any generator in $G$. \par Show that $\text{ord}(g) = |G|$. \par \hint{Contradiction.} \vfill \pagebreak