Add flip-symmetry paper with empirical density census through n=14
Introduces the maximal_planar_graph_edge_flipping paper, motivating flip-symmetry as a structural restriction on minimum-order five-chromatic counterexamples, and reports an exhaustive census showing |F_n|/|T_n| decays geometrically (factor ~1/2 per step from n=10 to n=14). The census driver lives in flip_symmetric_census.py. Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
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%% ====================================================================
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% AMS-LaTeX v.2 template for use with amsart
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%
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% Remove any commented or uncommented macros you do not use.
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\documentclass{amsart}
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\usepackage{tikz}
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\newtheorem{theorem}{Theorem}[section]
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\newtheorem{lemma}[theorem]{Lemma}
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\newtheorem{remark}[theorem]{Remark}
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\numberwithin{equation}{section}
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\begin{document}
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\title{Maximal Planar Graph Edge Flipping}
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% Remove any unused author tags.
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% author one information
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\author{Eric Bauerfeld}
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\address{}
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\curraddr{}
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\email{}
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\thanks{}
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\subjclass[2010]{Primary }
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\keywords{}
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\date{}
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\dedicatory{}
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\begin{abstract}
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\end{abstract}
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\maketitle
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\section{Motivation}
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The Four Color Theorem asserts that every planar graph is properly
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$4$-colorable, or equivalently that no maximal planar graph $G$
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satisfies $\chi(G) \geq 5$. Suppose, towards a contradiction, that
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such a graph exists; let $G_0$ be one of minimum order. Any structural
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property shared by every maximal planar graph $H$ with $|V(H)| =
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|V(G_0)|$ is then automatically inherited by $G_0$, and any property
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\emph{not} satisfied by $G_0$ excludes a portion of the class of
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maximal planar graphs from playing the role of a minimum
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counterexample.
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This paper investigates one such property: invariance under an
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admissible edge flip. We call a maximal planar graph $G$
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\emph{flip-symmetric} when some admissible flip at an edge of $G$
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returns a graph isomorphic to $G$. Our principal observation
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(Theorem~\ref{thm:min-five-chromatic-not-flip-symmetric}) is that a
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minimum-order $5$-chromatic maximal planar graph cannot be
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flip-symmetric, so the search for a counterexample to the Four Color
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Theorem may, in principle, be confined to the complement of the class
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$\mathcal{F}$ of flip-symmetric graphs. This raises a quantitative
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question --- how large is $\mathcal{F}$? --- which we address
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empirically in Section~\ref{sec:frequency} by an exhaustive census of
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maximal planar graphs of small order.
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\section{Preliminaries}
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Let $G$ be a maximal planar graph with $|V(G)| \geq 4$, embedded in the
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plane so that every face --- including the outer face --- is a triangle.
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Every edge $uv \in E(G)$ is then shared by exactly two triangular faces
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$uvw$ and $uvx$ whose union is a quadrilateral $uwvx$ with diagonal $uv$.
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\begin{definition}[Edge flip]
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Let $G$ be a maximal planar graph and let $uv \in E(G)$ be an edge whose
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two incident triangular faces are $uvw$ and $uvx$. The \emph{edge flip}
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(or \emph{diagonal flip}) at $uv$ is the operation that deletes the edge
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$uv$ and inserts the edge $wx$ in its place, replacing the two triangles
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$uvw$ and $uvx$ by the two triangles $uwx$ and $vwx$. The flip is
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\emph{admissible} if $wx \notin E(G)$; otherwise the resulting multigraph
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is not simple and the flip is forbidden.
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\end{definition}
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\begin{figure}[h]
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\centering
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\begin{tikzpicture}[
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every node/.style={circle, fill=black, inner sep=1.5pt},
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label distance=2pt,
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scale=1.2
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]
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% --- before flip ---
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\begin{scope}[xshift=0cm]
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\node[label=left:$u$] (u) at (0,0) {};
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\node[label=right:$v$] (v) at (2,0) {};
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\node[label=above:$w$] (w) at (1,1) {};
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\node[label=below:$x$] (x) at (1,-1) {};
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\draw (u) -- (w) -- (v) -- (x) -- (u);
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\draw[very thick] (u) -- (v);
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\node[draw=none, fill=none] at (1,-1.6) {before};
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\end{scope}
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% --- arrow ---
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\draw[->, very thick, shorten >=2pt, shorten <=2pt]
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(2.6,0) -- node[draw=none, fill=none, above]{flip $uv$} (3.8,0);
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% --- after flip ---
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\begin{scope}[xshift=4.4cm]
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\node[label=left:$u$] (u2) at (0,0) {};
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\node[label=right:$v$] (v2) at (2,0) {};
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\node[label=above:$w$] (w2) at (1,1) {};
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\node[label=below:$x$] (x2) at (1,-1) {};
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\draw (u2) -- (w2) -- (v2) -- (x2) -- (u2);
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\draw[very thick] (w2) -- (x2);
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\node[draw=none, fill=none] at (1,-1.6) {after};
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\end{scope}
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\end{tikzpicture}
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\caption{An edge flip replaces the diagonal $uv$ of the quadrilateral
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$uwvx$ with the diagonal $wx$.}
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\end{figure}
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\section{Flip-symmetric maximal planar graphs}
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For a maximal planar graph $G$ and an admissible edge $uv \in E(G)$
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with incident triangles $uvw$, $uvx$, write
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\[
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G^{\mathrm{flip}(uv)} \;=\; \bigl(V(G),\,(E(G)\setminus\{uv\})\cup\{wx\}\bigr)
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\]
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for the graph obtained from $G$ by flipping $uv$.
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\begin{definition}[Flip-symmetric graph]\label{def:flip-symmetric}
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A maximal planar graph $G$ is \emph{flip-symmetric} if there exists an
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admissible edge $uv \in E(G)$ such that
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$G^{\mathrm{flip}(uv)} \cong G$. We write $\mathcal{F}$ for the class
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of flip-symmetric maximal planar graphs.
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\end{definition}
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\section{A minimal four-colorable counterexample}
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\begin{theorem}\label{thm:min-five-chromatic-not-flip-symmetric}
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Let $G$ be a maximal planar graph of minimum order among all maximal
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planar graphs $H$ with $\chi(H) \geq 5$. Then $G \notin \mathcal{F}$;
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that is, $G$ is not flip-symmetric.
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\end{theorem}
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\section{Flip symmetry frequency}\label{sec:frequency}
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To gauge how restrictive flip-symmetry is, we performed an exhaustive
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census of maximal planar graphs of small order. For each
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$n \in \{4, 5, \dots, 14\}$ we enumerated every isomorphism class of
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maximal planar graph on $n$ vertices using \texttt{plantri} (invoked
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through SageMath as \texttt{graphs.planar\_graphs} with
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\texttt{minimum\_connectivity}~$=3$ and
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\texttt{maximum\_face\_size}~$=3$), and for each such $G$ we tested
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every admissible edge $uv \in E(G)$ for the existence of an isomorphism
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$G \cong G^{\mathrm{flip}(uv)}$. Writing $T_n$ for the total number of
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maximal planar graphs on $n$ vertices and
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$F_n = |\mathcal{F} \cap \{G : |V(G)| = n\}|$ for the number of
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flip-symmetric ones, the results are tabulated below.
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\begin{center}
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\begin{tabular}{r r r l}
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\hline
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$n$ & $T_n$ & $F_n$ & $F_n / T_n$ \\
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\hline
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$4$ & $1$ & $0$ & $0.000000$ \\
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$5$ & $1$ & $1$ & $1.000000$ \\
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$6$ & $2$ & $1$ & $0.500000$ \\
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$7$ & $5$ & $1$ & $0.200000$ \\
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$8$ & $14$ & $5$ & $0.357143$ \\
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$9$ & $50$ & $17$ & $0.340000$ \\
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$10$ & $233$ & $48$ & $0.206009$ \\
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$11$ & $1{,}249$ & $164$ & $0.131305$ \\
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$12$ & $7{,}595$ & $552$ & $0.072679$ \\
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$13$ & $49{,}566$ & $1{,}828$ & $0.036880$ \\
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$14$ & $339{,}722$& $6{,}164$ & $0.018144$ \\
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\hline
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\end{tabular}
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\end{center}
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From $n = 10$ onward the ratio $F_n / T_n$ decreases by a factor
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approaching $1/2$ at each step, suggesting that the density of
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flip-symmetric graphs among maximal planar graphs of order $n$ decays
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to zero --- empirically at a roughly geometric rate. In particular,
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the conclusion of
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Theorem~\ref{thm:min-five-chromatic-not-flip-symmetric} is consistent
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with the prevailing trend: as $n$ grows, almost every maximal planar
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graph on $n$ vertices is already excluded from flip-symmetry on
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purely structural grounds, and any putative counterexample to the
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Four Color Theorem is forced into a vanishingly small slice of the
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class.
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\end{document}
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