coloring_nested_tire_graphs: prove no level-d pinches (Prop 1.7)
Adds Proposition 1.7 (Source-side simple-cycle property): in any
maximal planar graph G with single-vertex source v_0, for any vertex
v at level d and any connected component C' of G'_d incident to v,
the depth-d faces of F_{C'} at v form a single contiguous arc in v's
rotation in Pi_G. Equivalently: the source-side boundary of R_{C'}
is always a simple cycle in L_d, with no cut-vertices at level d.
Proof: contradiction via Jordan curve theorem. If two arcs of
depth-d faces at v exist, pick level-(d-1) neighbours p, q of v in
the two gaps. The BFS ball G[L_{<d}] is connected so admits a simple
path P from p to q. The closed walk v -> p -> P -> q -> v is a
simple cycle W (since v is the only vertex at level >= d on it). W
separates the plane into two regions; the two arcs at v lie on
opposite sides. Any dual path of depth-d faces from one arc to the
other must avoid v on its intermediate faces, but consecutive
intermediate faces share edges entirely in L_{>= d}, so the dual
path stays on one side of W. This contradicts the endpoints being
on opposite sides.
Lemma 1.8 (the tire-component lemma) now cites Proposition 1.7 to
justify that B_out is always a simple cycle. Level-(d+1) pinches
(cut-vertices of O) remain allowed and are accommodated by the
relaxed Definition 1.5.
The empirical search (n in [7, 12], 47k + 276k = 323k components,
13k+ pinches all level-(d+1) cut-vertices of O, zero level-d
pinches) is now subsumed by the structural proof.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
This commit is contained in:
@@ -0,0 +1,93 @@
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"""Attempt to construct a level-d pinch in a maximal planar graph.
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Construction:
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v_0 at center, pentagon a_1, ..., a_5 around v_0.
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Outside the pentagon, vertex v adjacent to a_1, a_3 (non-adjacent
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pentagon vertices). The "lobe" between v and the pentagon edge
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a_1-a_2-a_3 contains a_2 and is triangulated by adding vertex x
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in the lobe, x adjacent to a_1, a_2, a_3, v. On the OTHER side of
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v (outside the V formed by edges v-a_1, v-a_3), we triangulate by
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adding w_1 adjacent to a_1, a_3, a_4, a_5, v.
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Vertex labels:
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0 = v_0 (source)
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1..5 = a_1..a_5 (pentagon, level 1)
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6 = v (level 2)
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7 = x (level 2)
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8 = w_1 (level 2)
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If this is planar and is a maximal planar graph, then v has level-1
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neighbours a_1=1, a_3=3 in DIFFERENT arcs of v's rotation, separated
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by level-2 neighbours x=7 on the lobe side and w_1=8 on the outer side.
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This would be a level-d (d=2) pinch.
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"""
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import os
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import sys
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from collections import defaultdict
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from sage.all import Graph
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EDGES = [
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(0, 1), (0, 2), (0, 3), (0, 4), (0, 5),
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(1, 2), (2, 3), (3, 4), (4, 5), (5, 1),
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(6, 1), (6, 3), (6, 7), (6, 8),
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(7, 1), (7, 2), (7, 3),
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(8, 1), (8, 3), (8, 5), (8, 4),
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]
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def main():
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G = Graph(EDGES)
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print(f"n = {G.order()}, m = {G.size()}")
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print(f"Max planar would need m = 3n - 6 = {3 * G.order() - 6}")
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print(f"Planar: {G.is_planar()}")
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if not G.is_planar():
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print("Not planar -- construction failed.")
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return
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G.is_planar(set_embedding=True)
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emb = G.get_embedding()
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print(f"Rotation around v=6: {emb[6]}")
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dist = G.shortest_path_lengths(0)
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print(f"BFS distances from source v_0=0: {dict(dist)}")
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print()
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# Pretty-print rotation of vertex 6 with levels
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rot_6 = emb[6]
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print(f"v=6's rotation in Pi_G: {rot_6}")
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print(f" levels: {[dist[u] for u in rot_6]}")
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# Check faces around vertex 6
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faces = G.faces(embedding=emb)
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faces_at_6 = []
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for f in faces:
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verts = [e[0] for e in f]
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if 6 in verts:
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d = min(dist[v] for v in verts)
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faces_at_6.append((verts, d))
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print(f"\nFaces at vertex 6:")
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for f, d in faces_at_6:
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print(f" {f} depth={d}")
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# Check the depth-(d-1=1)? No, we want vertex 6 at level 2.
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# We're checking: vertex 6 (level 2) with level-1 neighbors {1, 3}.
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# Are they in the same arc of vertex 6's rotation?
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level1_nbrs = [u for u in rot_6 if dist[u] == 1]
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print(f"\nLevel-1 neighbours of v=6: {level1_nbrs}")
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if len(level1_nbrs) > 1:
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# Find arcs
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positions = [i for i, u in enumerate(rot_6) if dist[u] == 1]
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print(f" positions in rotation: {positions}")
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# Are they contiguous? Count runs
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in_l1 = [dist[u] == 1 for u in rot_6]
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n_runs = sum(1 for i in range(len(in_l1))
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if in_l1[i] and not in_l1[(i - 1) % len(in_l1)])
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print(f" number of arcs of level-1 neighbours: {n_runs}")
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if n_runs > 1:
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print(" ==> LEVEL-d PINCH! Counterexample constructed.")
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else:
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print(" ==> single contiguous arc. No pinch.")
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if __name__ == '__main__':
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main()
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@@ -4,19 +4,20 @@
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\@writefile{lof}{\contentsline {figure}{\numberline {1}{\ignorespaces Dual depth in a stacked-ring triangulation $G$ with level source $S = \{0\}$. Each $G$ vertex is labelled by its level $\ell $. Each bounded face carries a dual vertex (square, joined by dashed dual edges) coloured by its dual depth $\delta (d_f) = \qopname \relax m{min}_{v \in V(f)} \ell (v)$: the central fan has depth $0$, the inner annulus depth $1$, and the outer annulus depth $2$. The outer face (the level-$3$ triangle) is excluded from the inner dual and carries no dual vertex.}}{2}{}\protected@file@percent }
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\@writefile{lof}{\contentsline {figure}{\numberline {1}{\ignorespaces Dual depth in a stacked-ring triangulation $G$ with level source $S = \{0\}$. Each $G$ vertex is labelled by its level $\ell $. Each bounded face carries a dual vertex (square, joined by dashed dual edges) coloured by its dual depth $\delta (d_f) = \qopname \relax m{min}_{v \in V(f)} \ell (v)$: the central fan has depth $0$, the inner annulus depth $1$, and the outer annulus depth $2$. The outer face (the level-$3$ triangle) is excluded from the inner dual and carries no dual vertex.}}{2}{}\protected@file@percent }
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\newlabel{fig:dual-depth}{{1}{2}}
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\newlabel{fig:dual-depth}{{1}{2}}
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\newlabel{def:tire-graph}{{1.5}{2}}
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\newlabel{def:tire-graph}{{1.5}{2}}
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\citation{bauerfeld-pds}
|
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\@writefile{lof}{\contentsline {figure}{\numberline {2}{\ignorespaces A tire graph with non-degenerate boundaries: outer boundary $B_{\mathrm {out}}$ a $6$-cycle on vertices $0,\dots ,5$ (blue), inner boundary $B_{\mathrm {in}}$ a $4$-cycle on vertices $6,\dots ,9$ (red), inner outerplanar graph $O = B_{\mathrm {in}} \cup \{7\text {--}9\}$ (with one chord, orange), and $E_{\mathrm {ann}}$ (grey) tiling the annulus between $B_{\mathrm {out}}$ and $B_{\mathrm {in}}$ by ten triangular faces.}}{3}{}\protected@file@percent }
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\@writefile{lof}{\contentsline {figure}{\numberline {2}{\ignorespaces A tire graph with non-degenerate boundaries: outer boundary $B_{\mathrm {out}}$ a $6$-cycle on vertices $0,\dots ,5$ (blue), inner boundary $B_{\mathrm {in}}$ a $4$-cycle on vertices $6,\dots ,9$ (red), inner outerplanar graph $O = B_{\mathrm {in}} \cup \{7\text {--}9\}$ (with one chord, orange), and $E_{\mathrm {ann}}$ (grey) tiling the annulus between $B_{\mathrm {out}}$ and $B_{\mathrm {in}}$ by ten triangular faces.}}{3}{}\protected@file@percent }
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\newlabel{fig:tire-example}{{2}{3}}
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\newlabel{fig:tire-example}{{2}{3}}
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\newlabel{rem:tire-counts}{{1.6}{3}}
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\newlabel{rem:tire-counts}{{1.6}{3}}
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\newlabel{lem:tire-component}{{1.7}{3}}
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\newlabel{prop:no-level-d-pinch}{{1.7}{3}}
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\citation{bauerfeld-pds}
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\citation{bauerfeld-pds}
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\newlabel{lem:tire-component}{{1.8}{4}}
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\citation{bauerfeld-pds}
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\newlabel{rem:tire-component-degenerate}{{1.9}{5}}
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\bibcite{bauerfeld-pds}{1}
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\bibcite{bauerfeld-pds}{1}
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\newlabel{tocindent-1}{0pt}
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\newlabel{tocindent0}{12.7778pt}
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\newlabel{tocindent1}{17.77782pt}
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\newlabel{tocindent2}{0pt}
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\newlabel{tocindent3}{0pt}
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\newlabel{tocindent3}{0pt}
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\newlabel{rem:tire-component-degenerate}{{1.8}{5}}
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\newlabel{rem:tire-no-extra-hypotheses}{{1.10}{6}}
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\newlabel{rem:tire-no-extra-hypotheses}{{1.9}{5}}
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\@writefile{toc}{\contentsline {section}{\tocsection {}{}{References}}{6}{}\protected@file@percent }
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\@writefile{toc}{\contentsline {section}{\tocsection {}{}{References}}{5}{}\protected@file@percent }
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\gdef \@abspage@last{6}
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@@ -1,4 +1,4 @@
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This is pdfTeX, Version 3.141592653-2.6-1.40.24 (TeX Live 2022) (preloaded format=pdflatex 2022.10.5) 25 MAY 2026 16:37
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This is pdfTeX, Version 3.141592653-2.6-1.40.24 (TeX Live 2022) (preloaded format=pdflatex 2022.10.5) 25 MAY 2026 17:03
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@@ -207,36 +207,39 @@ File: fig_tire_example.png Graphic file (type png)
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[3 <./fig_tire_example.png>] [4] [5] (./paper.aux) )
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@@ -178,6 +178,68 @@ boundary is degenerate (so $\min(m, k) = 1$), there are $m + k - 1$
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triangular faces and $|E_{\mathrm{ann}}| = m + k - 1$.
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triangular faces and $|E_{\mathrm{ann}}| = m + k - 1$.
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\end{remark}
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\end{remark}
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\begin{proposition}[Source-side simple-cycle property]
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\label{prop:no-level-d-pinch}
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Let $G$ be a maximal planar graph with planar embedding $\Pi_G$ and
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single-vertex source $v_0$. Let $d \geq 1$, $v \in L_d$, and let
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$C'$ be a connected component of $G'_d$ such that $v$ is incident to
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some face in $F_{C'}$. Then the depth-$d$ faces in $F_{C'}$ incident
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to $v$ form a single contiguous arc in $v$'s rotation in $\Pi_G$.
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Equivalently: for any such component, the source-side boundary of
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$R_{C'}$ is a simple cycle in $L_d$ (no cut-vertices at level $d$).
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\end{proposition}
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\begin{proof}
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Suppose for contradiction that the depth-$d$ faces in $F_{C'}$ at $v$
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lie in two or more disjoint arcs of $v$'s rotation. Adjacent vertices
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in $G$ differ in level by at most $1$, so a face at $v$ has depth
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exactly $d$ iff both other vertices have level $\geq d$, and depth
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$\leq d-1$ iff at least one has level $d-1$. Hence the gaps between
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the depth-$d$ arcs at $v$ are populated by level-$(d-1)$ neighbours of
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$v$, occurring in at least two disjoint arcs of $v$'s rotation. Pick
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$p$ in one such gap and $q$ in another.
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The BFS ball $G[L_{<d}]$ is connected, so there exists a simple path
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$P$ in $G[L_{<d}]$ from $p$ to $q$. Define the closed walk
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\[
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W \;:=\; v \to p \to P \to q \to v.
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\]
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Every vertex of $P$ lies in $L_{<d}$, while $\ell(v) = d$, so $v$ is
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distinct from every vertex of $P$; $P$ is simple, so its internal
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vertices are distinct; and $p \neq q$ since they lie in different gaps.
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Hence $W$ is a simple cycle in $G$.
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By the Jordan curve theorem, the planar embedding of $W$ divides $\Pi_G$
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into two regions. In $v$'s rotation, the edges $v-p$ and $v-q$ lie at
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two specific positions, and they split the rotation into two arcs;
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each arc lies in one of the two regions determined by $W$. By choice
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of $p, q$, the two arcs of depth-$d$ faces at $v$ in $F_{C'}$ lie in
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different regions of $W$ (i.e., one arc on each side).
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Since $C'$ is connected in $G'$ and contains depth-$d$ faces in both
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arcs, there is a dual path $f_1, f_2, \ldots, f_k$ in $G'_d$ with
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$f_1, f_k \in F_{C'}$ incident to $v$ in different arcs, and with the
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|
intermediate faces $f_2, \ldots, f_{k-1}$ not incident to $v$ (a
|
||||||
|
shortest such dual path). Consecutive faces $f_i, f_{i+1}$ share an
|
||||||
|
edge $e_i$ of $G$; for $i \geq 2$, both endpoints of $e_i$ lie in
|
||||||
|
$L_{\geq d}$ (since neither $f_i$ nor $f_{i+1}$ is incident to $v$,
|
||||||
|
all six vertices of these two triangles lie in $L_{\geq d}$). In
|
||||||
|
particular, $e_i$ shares no endpoint with $W$ except possibly $v$ ---
|
||||||
|
and $v$ is excluded from $f_2, \ldots, f_{k-1}$.
|
||||||
|
|
||||||
|
A planar edge with neither endpoint on a simple closed planar curve
|
||||||
|
$W$ has both of its incident faces on the same side of $W$. Applying
|
||||||
|
this to each $e_i$ ($i \geq 2$) inductively: starting from $f_2$ on
|
||||||
|
the same side of $W$ as $f_1$ (their shared edge $e_1 = w-w'$ opposite
|
||||||
|
to $v$ in $f_1$ has $w, w' \in L_{\geq d}$ and hence is not on $W$),
|
||||||
|
the path $f_2 \to f_3 \to \cdots \to f_{k-1} \to f_k$ stays on one
|
||||||
|
side of $W$.
|
||||||
|
|
||||||
|
But $f_1$ and $f_k$ lie on different sides of $W$ (by construction),
|
||||||
|
contradicting the conclusion that the entire path lies on one side.
|
||||||
|
\end{proof}
|
||||||
|
|
||||||
\begin{lemma}[Tire-component lemma]
|
\begin{lemma}[Tire-component lemma]
|
||||||
\label{lem:tire-component}
|
\label{lem:tire-component}
|
||||||
Let $G$ be a maximal planar graph and let $S \subseteq V(G)$ be a level
|
Let $G$ be a maximal planar graph and let $S \subseteq V(G)$ be a level
|
||||||
@@ -249,11 +311,17 @@ is monochromatic in level.
|
|||||||
\emph{Boundary structure.} Each connected component of
|
\emph{Boundary structure.} Each connected component of
|
||||||
$\partial R_{C'}$ traces a closed walk in $G$ that, by the
|
$\partial R_{C'}$ traces a closed walk in $G$ that, by the
|
||||||
monochromaticity above, lies entirely in $L_d$ or entirely in
|
monochromaticity above, lies entirely in $L_d$ or entirely in
|
||||||
$L_{d+1}$. At a vertex $v \in V_{C'}$ where the faces of $F_{C'}$
|
$L_{d+1}$. By Proposition~\ref{prop:no-level-d-pinch}, the depth-$d$
|
||||||
split into multiple arcs of $v$'s rotation, the boundary walk visits
|
faces of $F_{C'}$ at any $v \in L_d \cap V_{C'}$ form a single
|
||||||
$v$ correspondingly many times; this occurs precisely when $v$ is a
|
contiguous arc in $v$'s rotation, so the source-side boundary walk
|
||||||
cut-vertex of the induced subgraph on its level (either $L_d$ or
|
visits each $L_d$-vertex of $V_{C'}$ exactly once: it is a simple
|
||||||
$L_{d+1}$).
|
cycle. At vertices $v \in L_{d+1} \cap V_{C'}$ the depth-$d$ faces
|
||||||
|
may split into multiple arcs of $v$'s rotation; this corresponds
|
||||||
|
exactly to $v$ being a cut-vertex of $O$, and the inner-side
|
||||||
|
boundary walk visits $v$ correspondingly many times --- which is
|
||||||
|
already accommodated by Definition~\ref{def:tire-graph} (where
|
||||||
|
$B_{\mathrm{in}}$ is the outer-face boundary closed walk of $O$, not
|
||||||
|
necessarily a simple cycle).
|
||||||
|
|
||||||
\emph{Outer boundary.} Because $S$ lies on the outer face of $\Pi_G$,
|
\emph{Outer boundary.} Because $S$ lies on the outer face of $\Pi_G$,
|
||||||
the boundary curve(s) of $R_{C'}$ on the $L_d$ side are closer to $S$
|
the boundary curve(s) of $R_{C'}$ on the $L_d$ side are closer to $S$
|
||||||
|
|||||||
Reference in New Issue
Block a user