Enderton. Draft theorems/exercises on arithmetic section.
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@ -22,6 +22,28 @@
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\chapter{Reference}%
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\chapter{Reference}%
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\hyperlabel{chap:reference}
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\hyperlabel{chap:reference}
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\section{\defined{Addition}}%
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\label{ref:addition}
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For each $m \in \omega$, there exists (by the
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\nameref{sub:recursion-theorem-natural-numbers}) a unique
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\nameref{ref:function} $A_m \colon \omega \rightarrow \omega$ for which
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\begin{align*}
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A_m(0) & = m, \\
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A_m(n^+) & = A_m(n)^+ & \text{for } n \text{ in } \omega.
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\end{align*}
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\textbf{Addition} ($+$) is the \nameref{ref:binary-operation} on $\omega$ such
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that for any $m$ and $n$ in $\omega$, $$m + n = A_m(n).$$
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Thus when written as a \nameref{ref:relation},
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$$+ = \{\pair{\pair{m, n}, p} \mid
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m \in \omega \land n \in \omega \land p = A_m(n)\}.$$
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\begin{definition}
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\lean*{Init/Prelude}{Add.add}
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\end{definition}
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\section{\defined{Axiom of Choice, First Form}}%
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\section{\defined{Axiom of Choice, First Form}}%
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\hyperlabel{ref:axiom-of-choice-1}
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\hyperlabel{ref:axiom-of-choice-1}
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@ -46,6 +68,12 @@ For any set $I$ and any function $H$ with domain $I$, if $H(i) \neq \emptyset$
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\end{axiom}
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\end{axiom}
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\section{\defined{Binary Operation}}%
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\hyperlabel{ref:binary-operation}
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A \textbf{binary operation} on a set $A$ is a \nameref{ref:function} from
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$A \times A$ into $A$.
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\section{\defined{Cartesian Product}}%
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\section{\defined{Cartesian Product}}%
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\hyperlabel{ref:cartesian-product}
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\hyperlabel{ref:cartesian-product}
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@ -341,6 +369,25 @@ A \textbf{linear ordering} on $A$ (also called a \textbf{total ordering} on $A$)
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\end{definition}
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\end{definition}
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\section{\defined{Multiplication}}%
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\hyperlabel{sec:multiplication}
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For each $m \in \omega$, there exists (by the
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\nameref{sub:recursion-theorem-natural-numbers}) a unique
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\nameref{ref:function} $M_m \colon \omega \rightarrow \omega$ for which
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\begin{align*}
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M_m(0) & = 0, \\
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M_m(n^+) = M_m(n) + m.
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\end{align*}
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\textbf{Multiplication} ($\cdot$) is the \nameref{ref:binary-operation} on
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$\omega$ such that for any $m$ and $n$ in $\omega$, $$m \cdot n = M_m(n).$$
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\begin{definition}
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\lean*{Init/Prelude}{Mul.mul}
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\end{definition}
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\section{\defined{Natural Number}}%
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\section{\defined{Natural Number}}%
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\hyperlabel{ref:natural-number}
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\hyperlabel{ref:natural-number}
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@ -6249,7 +6296,7 @@ Show that $<_L$ is a linear ordering on $A \times B$.
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$\dom{h} = \omega$, and (iv) $h$ is unique.
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$\dom{h} = \omega$, and (iv) $h$ is unique.
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\paragraph{(i)}%
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\paragraph{(i)}%
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\label{par:recursion-theorem-natural-numbers-i}
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\hyperlabel{par:recursion-theorem-natural-numbers-i}
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We prove that $h$ is a function.
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We prove that $h$ is a function.
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Consider set
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Consider set
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@ -6257,7 +6304,7 @@ Show that $<_L$ is a linear ordering on $A \times B$.
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We show (1) that $0 \in S$ and (2) if $n \in S$ then $n^+ \in S$.
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We show (1) that $0 \in S$ and (2) if $n \in S$ then $n^+ \in S$.
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\subparagraph{(1)}%
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\subparagraph{(1)}%
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\label{spar:recursion-theorem-natural-numbers-i-1}
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\hyperlabel{spar:recursion-theorem-natural-numbers-i-1}
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Suppose $0 \in \dom{h}$.
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Suppose $0 \in \dom{h}$.
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By construction, there must exist some $y_1 \in A$ and acceptable function
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By construction, there must exist some $y_1 \in A$ and acceptable function
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@ -6269,7 +6316,7 @@ Show that $<_L$ is a linear ordering on $A \times B$.
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Therefore $0 \in S$.
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Therefore $0 \in S$.
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\subparagraph{(2)}%
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\subparagraph{(2)}%
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\label{spar:recursion-theorem-natural-numbers-i-2}
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\hyperlabel{spar:recursion-theorem-natural-numbers-i-2}
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Suppose $n$ and $n^+$ are members of $\dom{h}$.
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Suppose $n$ and $n^+$ are members of $\dom{h}$.
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By construction, there must exist some $y_1 \in A$ and acceptable function
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By construction, there must exist some $y_1 \in A$ and acceptable function
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@ -6294,7 +6341,7 @@ Show that $<_L$ is a linear ordering on $A \times B$.
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In other words, $h$ is a function.
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In other words, $h$ is a function.
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\paragraph{(ii)}%
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\paragraph{(ii)}%
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\label{par:recursion-theorem-natural-numbers-ii}
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\hyperlabel{par:recursion-theorem-natural-numbers-ii}
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We now prove $h \in H$, i.e. $h$ is an acceptable function.
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We now prove $h \in H$, i.e. $h$ is an acceptable function.
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It trivially holds that $\dom{h} \subseteq \omega$ and
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It trivially holds that $\dom{h} \subseteq \omega$ and
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@ -6321,7 +6368,7 @@ Show that $<_L$ is a linear ordering on $A \times B$.
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Hence $h \in H$.
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Hence $h \in H$.
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\paragraph{(iii)}%
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\paragraph{(iii)}%
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\label{par:recursion-theorem-natural-numbers-iii}
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\hyperlabel{par:recursion-theorem-natural-numbers-iii}
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We now prove that $\dom{h} = \omega$.
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We now prove that $\dom{h} = \omega$.
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We show that (1) $0 \in \dom{h}$ and (2) if $n \in \dom{h}$ then
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We show that (1) $0 \in \dom{h}$ and (2) if $n \in \dom{h}$ then
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@ -6414,6 +6461,74 @@ Show that $<_L$ is a linear ordering on $A \times B$.
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\end{proof}
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\end{proof}
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\section{Arithmetic}%
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\hyperlabel{sec:arithmetic}
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\subsection{\sorry{Theorem 4I}}
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\hyperlabel{sub:theorem-4i}
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\begin{theorem}[4I]
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For natural numbers $m$ and $n$,
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\begin{align*}
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m + 0 & = m, \\
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m + n^+ & = (m + n)^+.
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\end{align*}
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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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\subsection{\sorry{Theorem 4J}}
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\hyperlabel{sub:theorem-4j}
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\begin{theorem}[4J]
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For natural numbers $m$ and $n$,
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\begin{align*}
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m \cdot 0 & = 0, \\
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m \cdot n^+ & = m \cdot n + m.
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\end{align*}
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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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\subsection{\sorry{Theorem 4K}}
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\hyperlabel{sub:theorem-4k}
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\begin{theorem}[4K]
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The following identities hold for all natural numbers.
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\begin{enumerate}
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\item Associative law for addition
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$$m + (n + p) = (m + n) + p.$$
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\item Commutative law for addition
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$$m + n = n + m.$$
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\item Distributive law
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$$m \cdot (n + p) = m \cdot n + m \cdot p.$$
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\item Associative law for multiplication
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$$m \cdot (n \cdot p) = (m \cdot n) \cdot p.$$
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\item Commutative law for multiplication
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$$m \cdot n = n \cdot m.$$
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\end{enumerate}
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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 4}%
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\section{Exercises 4}%
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\hyperlabel{sec:exercises-4}
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\hyperlabel{sec:exercises-4}
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@ -6781,4 +6896,62 @@ Formulate an analogue to Exercise 9 for a function
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\end{proof}
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\end{proof}
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\subsection{\sorry{Exercise 4.13}}%
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\hyperlabel{sub:exercise-4.13}
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Let $m$ and $n$ be natural numbers such that $m \cdot n = 0$.
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Show that either $m = 0$ or $n = 0$.
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\begin{proof}
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TODO
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\end{proof}
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\subsection{\sorry{Exercise 4.14}}%
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\hyperlabel{sub:exercise-4.14}
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Call a natural number \textit{even} if it has the form $2 \cdot m$ for some $m$.
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Call it \textit{odd} if it has the form $(2 \cdot p) + 1$ for some $p$.
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Show that each natural number is either even or odd, but never both.
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\begin{proof}
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TODO
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\end{proof}
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\subsection{\sorry{Exercise 4.15}}%
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\hyperlabel{sub:exercise-4.15}
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Complete the proof of part (1) of \nameref{sub:theorem-4k}.
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\begin{proof}
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TODO
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\end{proof}
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\subsection{\sorry{Exercise 4.16}}%
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\hyperlabel{sub:exercise-4.16}
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Complete the proof of part (5) of \nameref{sub:theorem-4k}.
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\begin{proof}
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TODO
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\end{proof}
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\subsection{\sorry{Exercise 4.17}}%
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\hyperlabel{sub:exercise-4.17}
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Prove that $m^{n+p} = m^n \cdot m^p$.
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\begin{proof}
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TODO
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\end{proof}
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\end{document}
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\end{document}
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