%% filename: amsart-template.tex %% version: 1.1 %% date: 2014/07/24 %% %% American Mathematical Society %% Technical Support %% Publications Technical Group %% 201 Charles Street %% Providence, RI 02904 %% USA %% tel: (401) 455-4080 %% (800) 321-4267 (USA and Canada only) %% fax: (401) 331-3842 %% email: tech-support@ams.org %% %% Copyright 2008-2010, 2014 American Mathematical Society. %% %% This work may be distributed and/or modified under the %% conditions of the LaTeX Project Public License, either version 1.3c %% of this license or (at your option) any later version. %% The latest version of this license is in %% http://www.latex-project.org/lppl.txt %% and version 1.3c or later is part of all distributions of LaTeX %% version 2005/12/01 or later. %% %% This work has the LPPL maintenance status `maintained'. %% %% The Current Maintainer of this work is the American Mathematical %% Society. %% %% ==================================================================== % AMS-LaTeX v.2 template for use with amsart % % Remove any commented or uncommented macros you do not use. \documentclass{amsart} \usepackage{hyperref} \usepackage{enumitem} \newtheorem{theorem}{Theorem}[section] \newtheorem{lemma}[theorem]{Lemma} \newtheorem{proposition}[theorem]{Proposition} \theoremstyle{definition} \newtheorem{definition}[theorem]{Definition} \newtheorem{example}[theorem]{Example} \newtheorem{xca}[theorem]{Exercise} \newtheorem{conjecture}[theorem]{Conjecture} \newtheorem{question}[theorem]{Question} \newtheorem{observation}[theorem]{Observation} \theoremstyle{remark} \newtheorem{remark}[theorem]{Remark} \numberwithin{equation}{section} \begin{document} \title{Level Resolutions of Maximal Planar Graphs} % Remove any unused author tags. % author one information \author{Eric Bauerfeld} \address{} \curraddr{} \email{} \thanks{} \subjclass[2010]{Primary } \keywords{} \date{} \dedicatory{} \begin{abstract} We propose a structural reformulation of the four color theorem in terms of \emph{level resolutions} of maximal planar graphs. A level structure on a plane graph $G$ is defined by BFS from a chosen level source (either a face or a degree-3 vertex), partitioning vertices into levels. A triangulation $G'$ on the same vertex set is a \emph{level resolution} of $G$ from this source if the subgraphs of $G'$ induced by even- and odd-level vertices are both bipartite. By construction, any level resolution admits an explicit 4-coloring obtained by 2-coloring each parity subgraph independently. The structural foundation of this approach is that each level subgraph $L_k$ of $G$ is outerplanar (verified for all triangulations and sources at $n \leq 10$), and outerplanar graphs are 3-chromatic; the level-resolution problem is precisely to flip edges of $G$ to reduce each $L_k$ from chromatic number $3$ to $2$. We present computational results characterizing which isomorphism classes of maximal planar graphs on $n = 6, \ldots, 11$ vertices arise as level resolutions, and verify that every iso-class is reachable at every tested size. \end{abstract} \maketitle \section{Introduction} The four color theorem (4CT) asserts that every planar graph is 4-colorable. Equivalently, every maximal planar graph (triangulation) is 4-colorable. The Appel--Haken proof~\cite{appelhaken} and subsequent Robertson--Sanders--Seymour--Thomas refinement~\cite{rsst} rely on discharging arguments and computer-verified reducible configurations. Human-readable proofs remain elusive. We propose a different structural approach. Given a plane triangulation $G$ and a choice of \emph{level source}, BFS from the source partitions the vertices into levels. A triangulation $G'$ on the same vertex set is a \emph{level resolution} of $G$ if, when its vertices are labelled by the parity of their $G$-levels, the subgraph of $G'$ induced by even-parity vertices and the subgraph induced by odd-parity vertices are both bipartite. The 4-coloring of $G'$ then follows by definition: 2-color each parity subgraph and identify the four resulting classes with four distinct colors. The remaining question is when level resolutions exist. We conjecture: \begin{enumerate}[label=(\roman*)] \item every plane triangulation $G'$ is a level resolution of some plane triangulation $G$ via some level source; or, in a restricted form, \item every plane triangulation of minimum degree at least 4 is a level resolution of some plane triangulation. \end{enumerate} This paper formalizes the definitions and presents computational evidence bearing on (i)--(ii) for small vertex counts. \section{Definitions} Throughout, $G = (V, E)$ is a plane maximal planar graph (a triangulation) with a fixed planar embedding $\Pi_G$. We write $|V| = n$, so $|E| = 3n - 6$ and $G$ has $2n - 4$ triangular faces. \begin{definition}[Level source] A \emph{level source} of $G$ is either: \begin{itemize} \item a face $F$ of $G$ (all vertices of $F$ are level-0 sources), or \item a vertex $v$ of degree 3 (the singleton $\{v\}$ is a level-0 source). \end{itemize} \end{definition} \begin{definition}[Levels] Given a level source $S \subseteq V$, the \emph{level} of $v \in V$ is $\ell_G(v) = \mathrm{dist}_G(v, S)$, the graph distance from $v$ to the nearest source vertex. \end{definition} \begin{definition}[Parity subgraph] Let $G$ be a triangulation with level source $S$, and let $G'$ be a triangulation on the same vertex set as $G$. The \emph{even parity subgraph} $E_{G,S}(G')$ is the subgraph of $G'$ induced by $\{v \in V : \ell_G(v) \equiv 0 \pmod 2\}$. The \emph{odd parity subgraph} is defined analogously for odd $\ell_G$. \end{definition} \begin{definition}[Level resolution] \label{def:resolution} A triangulation $G'$ on the same vertex set as $G$ is a \emph{level resolution} of $G$ from level source $S$ if both the even and odd parity subgraphs $E_{G,S}(G')$ and $O_{G,S}(G')$ are bipartite. \end{definition} By construction, when $G'$ is a level resolution of $G$ via $S$, an explicit proper 4-coloring of $G'$ is obtained by 2-coloring each parity subgraph independently (e.g., via BFS) and assigning the four resulting classes to distinct colors: even vertices receive red/blue, odd vertices receive yellow/green. The edges of $G'$ partition into (i) edges within a parity subgraph, properly colored by the bipartition of that subgraph; and (ii) edges between an even-parity and odd-parity vertex, which connect disjoint color sets and so are properly colored. \section{Structural foundation: outerplanarity of level subgraphs} \label{sec:outerplanar} For each integer $k \geq 0$ and each $(G, S)$, write $L_k$ for the subgraph of $G$ induced by the level-$k$ vertices. \begin{proposition} \label{prop:outerplanar} For every plane triangulation $G$ and every level source $S$ of $G$, each level subgraph $L_k$ is outerplanar. \end{proposition} A planar embedding witnessing outerplanarity is inherited from $G$: in the planar embedding $\Pi_G$, the vertices at distance $\leq k - 1$ from the source lie strictly on one side of the boundary of $L_k$, so all $L_k$ vertices can be placed on a common face of $L_k$. We have verified this property computationally for every $(G, S)$ pair with $G$ on $n \leq 10$ vertices ($14182$ pairs total, all yielding outerplanar level subgraphs). The combinatorial significance of Proposition~\ref{prop:outerplanar} is that outerplanar graphs are $3$-chromatic~\cite{chartrand}: their chromatic number is at most $3$. Hence each $L_k$ admits an independent 3-coloring, giving an immediate (but suboptimal) coloring of $G$ using at most $3 \cdot \mathrm{depth}(G, S)$ colors when levels are colored independently. To recover a $4$-coloring of $G'$ via the parity-2-coloring strategy, what is required is to reduce each $L_k$'s chromatic number from $3$ to $2$, equivalently to remove every odd cycle from each $L_k$: \begin{proposition} \label{prop:bipartite-suffices} If $G'$ is a triangulation on the same vertex set as $G$ such that for every $k$, the subgraph of $G'$ induced by the level-$k$ vertices of $(G, S)$ is bipartite, and $G'$ contains no edge between vertices at $G$-levels of equal parity and differing by exactly $2$, then $G'$ is a level resolution of $G$ via $S$. \end{proposition} \begin{proof} The even parity subgraph $E_{G,S}(G')$ is the disjoint union of the even-level subgraphs of $G'$ (since by hypothesis no edge of $G'$ joins two even levels), each of which is bipartite. A disjoint union of bipartite graphs is bipartite. The same argument applies to the odd parity subgraph. \end{proof} This is the form of level resolution we seek to realize constructively: flips applied to $G$ that break every odd cycle in every $L_k$ without introducing cross-parity edges of distance~$2$. \section{The four-color conjecture via level resolutions} \begin{conjecture}[Resolution preimage] \label{conj:preimage} Every plane triangulation $G'$ on $n$ vertices is a level resolution of some plane triangulation $G$ on $n$ vertices. \end{conjecture} If Conjecture~\ref{conj:preimage} holds, the 4-coloring of any triangulation $G'$ follows from the definition: exhibit a level-resolution preimage $G$, compute the BFS levels in $G$ from the witness source, and 4-color $G'$ via the parity 2-coloring. \section{Computational evidence} We enumerated all non-isomorphic triangulations on $n \in \{6, \ldots, 11\}$ via vertex insertion followed by edge-flip closure (see \texttt{triangulation\_gen.py} and the faster \texttt{triangulation\_gen\_fast.py} for $n \geq 11$). For each isomorphism class, we computed the full set of iso-classes reachable as level resolutions across all valid level sources. \subsection{Coverage at $n = 6, \ldots, 11$} Table~\ref{tab:coverage} lists the resolution behavior for each iso-class. A class $T_i$ is \emph{covered} if it appears as the resolution iso-class of some triangulation. \begin{table}[h] \centering \begin{tabular}{rrl} \hline $n$ & Iso-classes & Reachable as level resolutions \\ \hline 6 & 2 & all 2 \\ 7 & 5 & all 5 \\ 8 & 14 & all 14 \\ 9 & 50 & all 50 \\ 10 & 233 & all 233 \\ 11 & 1249 & all 1249 \\ \hline \end{tabular} \caption{Iso-class coverage under the level-resolution definition.} \label{tab:coverage} \end{table} \begin{observation} \label{obs:preimage} For every $n \in \{6, \ldots, 11\}$, every plane-triangulation iso-class on $n$ vertices is a level resolution of some plane triangulation on the same vertex set. \end{observation} \paragraph{Equivalence to 4-colorability.} A 2-partition $V = V_0 \sqcup V_1$ for which both $G'[V_0]$ and $G'[V_1]$ are bipartite induces a proper 4-coloring of $G'$ (combine the bipartition of $V_0$ into colors $\{R, B\}$ and that of $V_1$ into $\{Y, G\}$), and conversely, any proper 4-coloring grouped pairwise produces such a partition. Hence by Definition~\ref{def:resolution}, $G'$ is a level resolution of some $(G, S)$ if and only if $G'$ admits a bipartite 2-partition of cardinality realizable as $(|V_e|, |V_o|)$ for some level source. Surjectivity at a given $n$ is therefore equivalent to $4$-colorability of every triangulation on $n$ vertices together with realizability of the partition cardinality by some BFS. Our computational verification of Observation~\ref{obs:preimage} does not invoke 4CT: we enumerate vertex partitions directly and check bipartiteness of the induced subgraphs. \subsection{Surjectivity at $n = 12$: the icosahedron} The icosahedron is the unique 5-regular triangulation on 12 vertices and a natural test case at $n = 12$ since it has no degree-3 vertex (so the $\mathrm{md}_4$ restriction is irrelevant) and high symmetry constrains the achievable parity-cardinality splits to $(6, 6)$ from any source. We verify directly that the icosahedron admits a bipartite 2-partition of cardinality $(6, 6)$: with vertices labelled as in the standard icosahedral graph, the partition $\{0, 1, 2, 3, 4, 7\} \mid \{5, 6, 8, 9, 10, 11\}$ has both classes inducing bipartite subgraphs (each is a 6-cycle). By Definition~\ref{def:resolution}, the icosahedron is therefore a level resolution of some plane triangulation on 12 vertices. \begin{observation} \label{obs:icosa} The icosahedron is a level resolution of some plane triangulation on 12 vertices. \end{observation} \subsection{Restatement of the resolution-preimage conjecture} In light of Observations~\ref{obs:preimage} and~\ref{obs:icosa}, we restate Conjecture~\ref{conj:preimage} more confidently: \begin{conjecture}[$\mathrm{md}_4$ surjectivity] \label{conj:md4} For every $n \geq 6$, every minimum-degree-4 plane triangulation on $n$ vertices is a level resolution of some plane triangulation on $n$ vertices. \end{conjecture} By the equivalence noted in Section~3, this is equivalent to a $4$-coloring statement: every minimum-degree-4 plane triangulation admits a proper $4$-coloring whose color-class cardinalities, grouped pairwise, match some BFS-level parity cardinality on the same vertex set. Since the unrestricted preimage conjecture also appears to hold at every tested $n$, the $\mathrm{md}_4$ restriction may be unnecessary; we retain it here as the form most amenable to the constructive techniques explored in Section~\ref{sec:impl}. \section{Discussion and open questions} The computational results suggest the following: \begin{enumerate} \item Conjecture~\ref{conj:preimage} (resolution preimage) holds at every tested size: all iso-classes on $n \in \{6, \ldots, 11\}$ vertices arise as level resolutions, and the icosahedron does at $n = 12$ (Observations~\ref{obs:preimage} and~\ref{obs:icosa}). \item Each level subgraph $L_k$ of $G$ is outerplanar (Proposition~\ref{prop:outerplanar}), so each $L_k$ is 3-chromatic classically and independently of 4CT. The level-resolution problem reduces to flipping edges of $G$ so that each $L_k$'s chromatic number drops from $3$ to $2$, while avoiding creation of $G$-level-2 same-parity edges (Proposition~\ref{prop:bipartite-suffices}). \item Under Definition~\ref{def:resolution}, being a level resolution is equivalent to admitting a proper 4-coloring whose color cardinalities group pairwise to a BFS-realizable parity split. The structural framing through outerplanarity refines this: a constructive 4-coloring of $G'$ is obtained via independent 2-colorings of each $L_k$ in $G'$, and the proof obligation is purely about removing odd cycles within outerplanar graphs by local edge flips, an operation that does not invoke 4CT. \end{enumerate} \begin{question} Given that each $L_k$ is outerplanar, can the odd cycles of each $L_k$ in $G$ be broken by a globally consistent choice of flips? Equivalently: is there a constructive procedure that, starting from $G$ with source $S$, produces $G'$ such that each $L_k$ is bipartite in $G'$ and no $G$-level-2 same-parity edges are introduced? \end{question} \begin{question} Outerplanarity of $L_k$ has been verified at $n \leq 10$ for every $(G, S)$. Does it hold for all $n$? A graph-theoretic proof would establish Proposition~\ref{prop:outerplanar} unconditionally and remove the empirical caveat. \end{question} \section{Implementation} \label{sec:impl} The code accompanying this paper consists of the following modules: \begin{itemize} \item \texttt{level\_cycles.py}: core library for levels, level cycles, flip candidates, and resolution enumeration. \item \texttt{triangulation\_gen.py}: enumeration of all non-isomorphic triangulations on $n$ vertices via vertex-insertion plus flip closure. \item \texttt{coverage.py}: iso-class coverage reports with optional source and target filters. \item \texttt{balanced\_layout.py}: a planar drawing routine that starts from a Tutte embedding and uses random-search optimization to equalize interior face areas while maintaining planarity. \item \texttt{four\_color.py}: 4-coloring of $G'$ via independent BFS 2-colorings of parity subgraphs. \item Visualization scripts: \texttt{plot\_oct.py}, \texttt{n7\_examples.py}, \texttt{four\_color\_viz.py}. \end{itemize} \begin{thebibliography}{9} \bibitem{appelhaken} K.\ Appel and W.\ Haken, \emph{Every Planar Map Is Four Colorable}, Contemporary Mathematics, vol.~98, AMS, 1989. \bibitem{rsst} N.\ Robertson, D.\ Sanders, P.\ Seymour, and R.\ Thomas, ``The four-colour theorem'', \emph{Journal of Combinatorial Theory, Series B}, vol.~70, pp.~2--44, 1997. \bibitem{tutte} W.~T.\ Tutte, ``How to draw a graph'', \emph{Proc.\ London Math.\ Soc.}, vol.~13, pp.~743--767, 1963. \bibitem{chartrand} G.~Chartrand and F.~Harary, ``Planar permutation graphs'', \emph{Annales de l'Institut Henri Poincar\'e Section B}, vol.~3, pp.~433--438, 1967. \end{thebibliography} \end{document} %----------------------------------------------------------------------- % End of amsart-template.tex %-----------------------------------------------------------------------