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\begin{document}

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\section*{order-type}

\hypertarget{contents}{}\section*{{Contents}}\label{contents}

\noindent\hyperlink{idea}{Idea}\dotfill \pageref*{idea} \linebreak
\noindent\hyperlink{definition}{Definition}\dotfill \pageref*{definition} \linebreak
\noindent\hyperlink{examples}{Examples}\dotfill \pageref*{examples} \linebreak
\noindent\hyperlink{discussion}{Discussion}\dotfill \pageref*{discussion} \linebreak
\noindent\hyperlink{references}{References}\dotfill \pageref*{references} \linebreak


\hypertarget{idea}{}\subsection*{{Idea}}\label{idea}

The order type of a [[partially ordered set]] (poset) $P$ is an invariant $ot(P)$ of the poset which is finer than its [[cardinal number]] $|P|$. The cardinal numbers classify sets according to how many elements they contain, however they don't pay attention to any potential order-theoretic properties on the sets in question -- for example

$\backslash$begin\{centre\} $\omega+1\cong\omega$ $\backslash$end\{centre\}

in \textbf{Set} but not in \textbf{Pos} since the bijections in \textbf{Set} all send $\omega$ to some finite ordinal and thusly don't preserve ordering. This is expressed in terms of cardinalities and order types by observing that $|\omega+1|=|\omega|=\omega$ but $ot(\omega+1)=\omega+1\neq\omega=ot(\omega)$ since each ordinal is its own order type but generally not its own cardinal number.

\hypertarget{definition}{}\subsection*{{Definition}}\label{definition}

Let $P$ be a poset. We say that another poset $Q$ has the same \textbf{order type} as $P$ iff there exists an order preserving bijection $P\cong Q$. We define an equivalence relation $\sim$ on posets by

$\backslash$begin\{centre\} $P\sim Q\iff \exists f:P\cong Q(\text{f is an order-preserving bijection})$, $\backslash$end\{centre\}

and we define the \textbf{order type} of $P$, denoted $ot(P)$, to be either the equivalence class $\sim/P$ or an arbitrary representative of the equivalence class $\sim/P$ depending on context.

\hypertarget{examples}{}\subsubsection*{{Examples}}\label{examples}

We have that $ot(\alpha)\cong\alpha$ in \textbf{Pos} for each ordinal $\alpha$ by definition, and further the order type of any well-ordered set `is' the ordinal one would expect (up to iso):

\begin{displaymath}
ot(\{0,1,4,5\})\cong4,
\end{displaymath}
\begin{displaymath}
ot(\{0,2,4,6,\dots\omega,\omega+2,\omega+4,\omega+6\})\cong\omega+4,
\end{displaymath}
\begin{displaymath}
\vdots
\end{displaymath}
For well-ordered posets it seems natural to take the order type to be the ordinal representative of the equivalence class, yielding the literal equalities in the idea section above, however this is not strictly necessary.

The order type of the negative integers is denoted by $^*\omega$ and the order type of the rationals is denoted by $\eta$, and neither of these order types have representatives in the ordinals since they aren't well-ordered.

\hypertarget{discussion}{}\paragraph*{{Discussion}}\label{discussion}

The notion of cardinality for a set $X$ can be defined using the bijection equivalence relation $\sim$ in \textbf{Set} $\backslash$begin\{centre\} $X\sim Y\iff \exists f:X\cong Y\in Hom_{Set}$, $\backslash$end\{centre\} so $|X|$ is the [[cardinal number]] member of the equivalence class of all sets in bijection with $X$. Since all sets are in bijection with some cardinal number (assuming the [[axiom of foundation]] via Scott’s trick) and cardinal numbers are just particular ordinals (assuming the [[axiom of choice]], otherwise more care must be taken) we do not encounter the phenomenon above where some equivalence classes don't have ordinal representatives in a universe with choice.

The order type equivalence relation $\sim$ in \textbf{Pos} above is a finer parsing of the universe of partially ordered sets which doesn't admit an ordinal in each of its equivalence classes, and each ordinal defines its own unique equivalence class under this relation instead of only the cardinal numbers as with the bijection equivalence relation.

The increased `fineness' of this parsing can be attributed to the fact that we effectively restricted the iso equivalence relation in \textbf{Set} to the subcategory \textbf{Pos} where there are fewer isos between objects and thusly more equivalence classes.

\hypertarget{references}{}\subsection*{{References}}\label{references}

\begin{itemize}%
\item Cantor, Georg \href{https://gdz.sub.uni-goettingen.de/download/pdf/PPN243919689_0077/LOG_0014.pdf}{``Ueber eine Eigenschaft des Inbegriffes aller reellen algebraischen Zahlen''}

\end{itemize}


\end{document}