Enderton (set). Revert Theorem 6A.
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@ -3023,7 +3023,7 @@ A set $A$ is \textbf{equinumerous} to a set $B$ (written $\equinumerous{A}{B}$)
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F \circ G = \{\tuple{u, v} \mid \exists t(uGt \land tFv)\}.
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\end{equation}
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By \nameref{sub:theorem-3h}, $F \circ G$ is a function.
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All that remains is proving $F \circ G$ is single-valued, i.e. for each
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All that remains is proving $F \circ G$ is single-rooted, i.e. for each
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$y \in \ran{F \circ G}$, there is only one $x$ such that
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$\tuple{x, y} \in F \circ G$.
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@ -8442,7 +8442,7 @@ A set $A$ is \textbf{equinumerous} to a set $B$ (written $\equinumerous{A}{B}$)
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\section{Equinumerosity}%
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\hyperlabel{sec:equinumerosity}
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\subsection{\verified{Theorem 6A}}%
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\subsection{\pending{Theorem 6A}}%
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\hyperlabel{sub:theorem-6a}
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\begin{theorem}[6A]
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@ -8477,19 +8477,12 @@ A set $A$ is \textbf{equinumerous} to a set $B$ (written $\equinumerous{A}{B}$)
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\paragraph{(b)}%
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Suppose $\equinumerous{A}{B}$.
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Then there exists a one-to-one function $f \colon A \rightarrow B$.
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By \nameref{sub:one-to-one-inverse}, $f^{-1} \colon B \rightarrow A$
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is also one-to-one.
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Thus $\equinumerous{B}{A}$.
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Then there exists a one-to-one function $f$ from $A$ onto $B$.
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TODO
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\paragraph{(c)}%
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Suppose $\equinumerous{A}{B}$ and $\equinumerous{B}{C}$.
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Then there exist one-to-one functions $f \colon A \rightarrow B$ and
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$g \colon B \rightarrow C$.
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Then, by \nameref{sub:one-to-one-composition},
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$g \circ f \colon A \rightarrow C$ is one-to-one.
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Thus $\equinumerous{A}{C}$.
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TODO
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\end{proof}
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