Add notion of "assumption"s and rename `pair` to a more general `tuple` macro.
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@ -35,6 +35,14 @@
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An \textbf{expression} is a finite sequence of symbols.
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\section{\defined{\texorpdfstring{$n$}{n}-tuple}}%
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\hyperlabel{ref:n-tuple}
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An \textbf{$n$-tuple} is recursively defined as
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$$\ltuple{x_1}{x_{n+1}} = \tuple{\ltuple{x_1}{x_n}, x_{n+1}}$$
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for $n > 1$.
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We also define $\tuple{x} = x$.
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\section{\defined{Well-Formed Formula}}%
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\hyperlabel{ref:well-formed-formula}
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@ -63,17 +71,52 @@
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\chapter{Useful Facts About Sets}%
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\hyperlabel{chap:useful-facts-about-sets}
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\section{\sorry{Lemma 0A}}%
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\section{\unverified{Lemma 0A}}%
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\hyperlabel{sec:lemma-0a}
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\begin{lemma}[0A]
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Assume that $\langle x_1, \ldots, x_m \rangle =
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\langle y_1, \ldots, y_m, \ldots, y_{m+k} \rangle$.
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Then $x_1 = \langle y_1, \ldots, y_{k+1} \rangle$.
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Assume that $\ltuple{x_1}{x_m} = \ltuple{y_1, \ldots, y_m}{y_{m+k}}$.
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Then $x_1 = \ltuple{y_1}{y_{k+1}}$.
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\end{lemma}
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\begin{proof}
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TODO
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For natural number $m$, let $P(m)$ be the statement:
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\begin{assumption}
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\hyperlabel{sec:lemma-0a-eq1}
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\text{If } \ltuple{x_1}{x_m} = \ltuple{y_1, \ldots, y_m}{y_{m+k}}
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\text{ then } x_1 = \ltuple{y_1}{y_{k+1}}.
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\end{assumption}
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\noindent
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We proceed by induction on $m$.
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\paragraph{Base Case}%
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Suppose $\tuple{x_1} = \ltuple{y_1}{y_{1 + k}}$.
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By definition of an \nameref{ref:n-tuple}, $\tuple{x_1} = x_1$.
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Thus $x_1 = \ltuple{y_1}{y_{k + 1}}$.
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Hence $P(1)$ holds true.
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\paragraph{Inductive Step}%
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Suppose for $m \geq 1$ that $P(m)$ is true and assume
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\begin{equation}
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\hyperlabel{sec:lemma-0a-eq2}
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\ltuple{x_1}{x_{m+1}} = \ltuple{y_1, \ldots, y_{m+1}}{y_{m+1+k}}.
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\end{equation}
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By definition of an \nameref{ref:n-tuple}, we can decompose
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\eqref{sec:lemma-0a-eq2} into the following two identities
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\begin{align*}
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x_{m+1} & = y_{m+1+k} \\
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\ltuple{x_1}{x_m} & = \ltuple{y_1}{y_{m+k}}.
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\end{align*}
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By \eqref{sec:lemma-0a-eq1}, $P(m)$ implies $x_1 = \ltuple{y_1}{y_{k+1}}$.
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Hence $P(m+1)$ holds true.
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\paragraph{Conclusion}%
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By induction, $P(m)$ holds true for all $m \geq 1$.
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\end{proof}
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\chapter{Sentential Logic}%
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File diff suppressed because it is too large
Load Diff
20
preamble.tex
20
preamble.tex
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@ -92,6 +92,22 @@
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% Admonitions
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% ========================================
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\newcommand\@assumptionbody[1]{
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\begin{equation}
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\setlength{\abovedisplayskip}{0pt}
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\setlength{\belowdisplayskip}{0pt}
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#1
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\end{equation}}
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\NewEnviron{assumption}[1][]{%
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\ifstrempty{#1}{%
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\begin{tcolorbox}[bottom=8pt]
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\@assumptionbody{\BODY}
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\end{tcolorbox}}{%
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\begin{tcolorbox}[title=#1,bottom=8pt]
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\@assumptionbody{\BODY}
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\end{tcolorbox}}}
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\NewEnviron{note}{%
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\begin{tcolorbox}[%
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sharp corners,
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@ -156,6 +172,7 @@
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\newcommand{\abs}[1]{\left|#1\right|}
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\newcommand{\ceil}[1]{\left\lceil#1\right\rceil}
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\newcommand{\ctuple}[2]{\left< #1, \cdots, #2 \right>}
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\newcommand{\dom}[1]{\textop{dom}{#1}}
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\newcommand{\fld}[1]{\textop{fld}{#1}}
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\newcommand{\floor}[1]{\left\lfloor#1\right\rfloor}
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@ -164,9 +181,12 @@
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\newcommand{\img}[2]{#1\!\left\llbracket#2\right\rrbracket}
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\newcommand{\ioc}[2]{\left(#1, #2\right]}
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\newcommand{\ioo}[2]{\left(#1, #2\right)}
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\newcommand{\ltuple}[2]{\left< #1, \ldots, #2 \right>}
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\newcommand{\powerset}[1]{\mathscr{P}#1}
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\newcommand{\ran}[1]{\textop{ran}{#1}}
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\newcommand{\textop}[1]{\mathop{\text{#1}}}
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\newcommand{\tuple}[1]{\left< #1 \right>}
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\newcommand{\ubar}[1]{\text{\b{$#1$}}}
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\let\oldemptyset\emptyset
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