\section{The Geometry of Orthogonal Operators} \begin{definition} \hfill\\ Let $T$ be a linear operator on a finite-dimensional real inner product space $V$. The operator $T$ is called a \textbf{rotation} if $T$ is the identity on $V$ or if there exists a two-dimensional subspace $W$ of $V$, and orthonormal basis $\beta = \{x_1, x_2\}$ for $W$, and a real number $\theta$ such that \[T(x_1) = (\cos(\theta))x_1 + (\sin(\theta))x_2,\ \ \ \ T(x_2) = (-\sin(\theta))x_1 + (\cos(\theta))x_2,\] and $T(y) = y$ for all $y \in W^\perp$. In this context, $T$ is called a \textbf{rotation of $W$ about $W^\perp$}. The subspace $W^\perp$ is called the \textbf{axis of rotation}. \end{definition} \begin{definition} \hfill\\ Let $T$ be a linear operator on a finite-dimensional real inner product space $V$. The operator $T$ is called a \textbf{reflection} if there exists a one-dimensional subspace $W$ of $V$ such that $T(x) = -x$ for all $x \in W$ and $T(y) = y$ for all $y \in W^\perp$. In this context, $T$ is called a \textbf{reflection of $V$ about $W^\perp$}. \end{definition} \begin{theorem} \hfill\\ Let $T$ be an orthogonal operator on a two-dimensional real inner product space $V$. Then $T$ is either a rotation or a reflection. Furthermore, $T$ is a rotation if and only if $\det(T) = 1$, and $T$ is a reflection if and only if $\det(T) = -1$. \end{theorem} \begin{corollary} \hfill\\ Let $V$ be a two-dimensional real inner product space. The composite of a reflection and a rotation on $V$ is a reflection on $V$. \end{corollary} \begin{lemma} \hfill\\ If $T$ is a linear operator on a nonzero finite-dimensional real vector space $V$, then there exists a $T$-invariant subspace $W$ of $V$ such that $1 \leq \ldim{W} \leq 2$. \end{lemma} \begin{theorem}\label{Theorem 6.46} \hfill\\ Let $T$ be an orthogonal operator on a nonzero finite-dimensional real inner product space $V$. Then there exists a collection of pairwise orthogonal $T$-invariant subspaces $\{W_1, W_2, \dots, W_m\}$ of $V$ such that \begin{enumerate} \item $1 \leq \ldim(W_i) \leq 2$ for $i = 1, 2, \dots, m$. \item $V = W_1 \oplus W_2 \oplus \dots \oplus W_m$. \end{enumerate} \end{theorem} \begin{theorem} \hfill\\ Let $T,V,W_1,\dots,W_m$ be as in \autoref{Theorem 6.46}. \begin{enumerate} \item The number of $W_i$'s for which $T_{W_i}$ is a reflection is even or odd according to whether $\det(T) = 1$ or $\det(T) = -1$. \item It is always possible to decompose $V$ as in \autoref{Theorem 6.46} so that the number of $W_i$'s for which $T_{W_i}$ is a reflection is zero or one according to whether $\det(T) = 1$ or $\det(T) = -1$. Furthermore, if $T_{W_i}$ is a reflection, then $\ldim{W_i} = 1$. \end{enumerate} \end{theorem} \begin{corollary} \hfill\\ Let $T$ be an orthogonal operator on a finite-dimensional real inner product space $V$. Then there exists a collection $\{T_1, T_2, \dots, T_m\}$ of orthogonal operators on $V$ such that the following statements are true. \begin{enumerate} \item For each $i$, $T_i$ is either a reflection or a rotation. \item For at most one $i$, $T_i$ is a reflection. \item $T_iT_j = T_jT_i$ for all $i$ and $j$. \item $T = T_1T_2\dots T_m$. \item $\det(T) = \displaystyle\begin{cases} 1 & \text{if}\ T_i\ \text{is a rotation for each}\ i \\ -1 & \text{otherwise} \end{cases}$ \end{enumerate} \end{corollary}