Enderton. Additional equivalence relation definitions.
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@ -71,8 +71,8 @@ There is a set having no members:
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\section{\pending{Equivalence Relation}}%
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\label{ref:equivalence-relation}
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Relation $R$ is an \textbf{equivalence relation} if and only if $R$ is a binary
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\nameref{ref:relation} that is \nameref{ref:reflexive},
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Relation $R$ is an \textbf{equivalence relation} on set $A$ if and only if
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$R$ is a binary \nameref{ref:relation} that is \nameref{ref:reflexive} on $A$,
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\nameref{ref:symmetric}, and \nameref{ref:transitive}.
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\section{\defined{Extensionality Axiom}}%
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@ -202,6 +202,16 @@ For any sets $u$ and $v$, there is a set having as members just $u$ and $v$:
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\end{axiom}
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\section{\pending{Partition}}%
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\label{ref:partition}
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A \textbf{partition} $\Pi$ of a set $A$ is a set of nonempty subsets of $A$ that
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is disjoint and exhaustive, i.e.
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\begin{enumerate}[(a)]
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\item no two different sets in $\Pi$ have any common elements, and
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\item each element of $A$ is in some set in $\Pi$.
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\end{enumerate}
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\section{\defined{Power Set}}%
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\label{ref:power-set}
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@ -226,6 +236,14 @@ For any set $a$, there is a set whose members are exactly the subsets of $a$:
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\end{axiom}
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\section{\pending{Quotient Set}}%
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\label{ref:quotient-set}
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If $R$ is an \nameref{ref:equivalence-relation} on set $A$, then we can define
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the \textbf{quotient set} $$A / R = \{[x]_R \mid x \in A\}$$ whose members are
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the equivalence classes.
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The expression $A / R$ is read "$A$ modulo $R$.
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\section{\defined{Range}}%
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\label{ref:range}
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@ -283,8 +301,8 @@ For each formula $\phi$ not containing $B$, the following is an axiom:
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\section{\pending{Symmetric}}%
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\label{ref:symmetric}
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A binary relation $R$ is \textbf{symmetric} on $A$ if and only if whenever
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$xRy$ then $yRx$.
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A binary relation $R$ is \textbf{symmetric} if and only if whenever $xRy$ then
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$yRx$.
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\section{\defined{Symmetric Difference}}%
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\label{ref:symmetric-difference}
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@ -301,15 +319,16 @@ The \textbf{symmetric difference} $A + B$ of sets $A$ and $B$ is the set
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\section{\pending{Transitive}}%
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\label{ref:transitive}
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A binary relation $R$ is \textbf{transitive} on $A$ if and only if whenever
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$xRy$ and $yRz$, then $xRz$.
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A binary relation $R$ is \textbf{transitive} if and only if whenever $xRy$ and
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$yRz$, then $xRz$.
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\section{\defined{Union Axiom}}%
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\label{ref:union-axiom}
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For any set $A$, there exists a set $B$ whose elements are exactly the members
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of the members of $A$:
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$$\forall A, \exists B, \forall x \left[ x \in B \iff (\exists b \in A) x \in b \right]$$
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$$\forall A, \exists B, \forall x
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\left[ x \in B \iff (\exists b \in A) x \in b \right]$$
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\begin{axiom}
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@ -3187,9 +3206,10 @@ For any one-to-one function $F$, $F^{-1}$ is also one-to-one.
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\nameref{ref:relation}.
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By definition, the \nameref{ref:field} of $R$ is given by
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$\fld{R} = \dom{R} \cup \ran{R}$.
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An \nameref{ref:equivalence-relation} is, by definition, a
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\nameref{ref:reflexive}, symmetric, and transitive relation.
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Thus all that remains is to show $R$ is reflexive on $\fld{R}$.
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An \nameref{ref:equivalence-relation} on $\fld{R}$ is, by definition, a
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binary relation \nameref{ref:reflexive} on $\fld{R}$, symmetric, and
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transitive.
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All that remains is to show $R$ is reflexive on $\fld{R}$.
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Let $x \in \fld{R}$.
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Then $x \in \dom{R}$ or $x \in \ran{R}$.
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@ -3203,6 +3223,69 @@ For any one-to-one function $F$, $F^{-1}$ is also one-to-one.
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\end{proof}
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\subsection{\pending{Lemma 3N}}%
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\label{sub:lemma-3n}
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\begin{lemma}[3N]
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Assume that $R$ is an equivalence relation on $A$ and that $x$ and $y$ belong
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to $A$.
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Then $$[x]_R = [y]_R \iff xRy.$$
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\end{lemma}
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\begin{proof}
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Suppose $R$ is an \nameref{ref:equivalence-relation} on set $A$.
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Let $x, y \in A$.
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\paragraph{($\Rightarrow$)}%
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Suppose $[x]_R = [y]_R$.
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Since $R$ is an equivalence relation, it is reflexive on $A$.
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Thus $yRy$ meaning $y \in [y]_R = \{t \mid yRt\}$.
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Since $[x]_R = [y]_R$, $y \in \{t \mid xRt\}$ as well.
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That is, $xRy$.
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\paragraph{($\Leftarrow$)}%
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Suppose $xRy$.
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We show $[x]_R \subseteq [y]_R$ and $[y]_R \subseteq [x]_R$.
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\subparagraph{($\subseteq$)}%
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Let $t \in [x]_R$.
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Then $xRt$.
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Since $R$ is symmetric, $xRy$ implies $yRx$.
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Since $R$ is transitive, $yRx$ and $xRt$ implies $yRt$.
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Thus $t \in [y]_R$.
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\subparagraph{($\supseteq$)}%
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Let $t \in [y]_R$.
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Then $yRt$.
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Since $R$ is transitive, $xRy$ and $yRt$ implies $xRt$.
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Thus $t \in [x]_R$.
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\end{proof}
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\subsection{\sorry{Theorem 3P}}%
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\label{sub:theorem-3p}
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\begin{theorem}[3P]
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Assume that $R$ is an equivalence relation on $A$.
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Then the set $\{[x]_R \mid x \in A\}$ of all equivalence classes is a
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partition of $A$.
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\end{theorem}
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\begin{proof}
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TODO
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\end{proof}
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\section{Exercises 3}%
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\label{sec:exercises-3}
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