Tetradecagon#Dissection

In geometry, a tetradecagon or tetrakaidecagon or 14-gon is a fourteen-sided polygon.

Regular tetradecagon

A regular tetradecagon has Schläfli symbol {14} and can be constructed as a quasiregular truncated heptagon, t{7}, which alternates two types of edges.

The area of a regular tetradecagon of side length a is given by

: $A = \frac{14}{4}a^2\cot\frac{\pi}{14} \approx 15.3345a^2$

=Construction=

As 14 = 2 × 7, a regular tetradecagon cannot be constructed using a compass and straightedge.{{cite journal|last=Wantzel|first=Pierre|title=Recherches sur les moyens de Reconnaître si un Problème de géométrie peau se résoudre avec la règle et le compas|journal=Journal de Mathématiques|date=1837|pages=366–372|url=http://sites.mathdoc.fr/JMPA/PDF/JMPA_1837_1_2_A31_0.pdf}} However, it is constructible using neusis with use of the angle trisector,{{cite journal|last=Gleason|first=Andrew Mattei|title=Angle trisection, the heptagon, p. 186 (Fig.1) –187 |journal=The American Mathematical Monthly|date=March 1988|volume=95|issue=3 |pages=185–194|url=http://apollonius.math.nthu.edu.tw/d1/ne01/jyt/linkjstor/regular/7.pdf#|archiveurl=https://web.archive.org/web/20160202015324/http://apollonius.math.nthu.edu.tw/d1/ne01/jyt/linkjstor/regular/7.pdf|doi= 10.2307/2323624|archive-date=2016-02-02 |url-status=dead}} or with a marked ruler,[http://mathworld.wolfram.com/Heptagon.html Weisstein, Eric W. "Heptagon." From MathWorld, A Wolfram Web Resource.] as shown in the following two examples.

[[File:01-Tetradecagon-Tomahawk.gif|left|600px|thumb|Tetradecagon with given circumcircle:

An animation (1 min 47 s) from a neusis construction with radius of circumcircle $\overline{OA} = 6$ ,

according to Andrew M. Gleason, based on the angle trisection by means of the tomahawk.]]

[[File:01-Vierzehneck-nach Johnson.gif|left|500px|thumb|Tetradecagon with given side length:

An animation (1 min 20 s) from a neusis construction with marked ruler, according to David Johnson Leisk (Crockett Johnson).]]

Symmetry

File:Symmetries_of_tetradecagon.png

The regular tetradecagon has Dih₁₄ symmetry, order 28. There are 3 subgroup dihedral symmetries: Dih₇, Dih₂, and Dih₁, and 4 cyclic group symmetries: Z₁₄, Z₇, Z₂, and Z₁.

These 8 symmetries can be seen in 10 distinct symmetries on the tetradecagon, a larger number because the lines of reflections can either pass through vertices or edges. John Conway labels these by a letter and group order.John H. Conway, Heidi Burgiel, Chaim Goodman-Strauss, (2008) The Symmetries of Things, {{isbn|978-1-56881-220-5}} (Chapter 20, Generalized Schaefli symbols, Types of symmetry of a polygon pp. 275-278) Full symmetry of the regular form is r28 and no symmetry is labeled a1. The dihedral symmetries are divided depending on whether they pass through vertices (d for diagonal) or edges (p for perpendiculars), and i when reflection lines path through both edges and vertices. Cyclic symmetries in the middle column are labeled as g for their central gyration orders.

Each subgroup symmetry allows one or more degrees of freedom for irregular forms. Only the g14 subgroup has no degrees of freedom but can be seen as directed edges.

The highest symmetry irregular tetradecagons are d14, an isogonal tetradecagon constructed by seven mirrors which can alternate long and short edges, and p14, an isotoxal tetradecagon, constructed with equal edge lengths, but vertices alternating two different internal angles. These two forms are duals of each other and have half the symmetry order of the regular tetradecagon.

Dissection

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14-cube projection

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84 rhomb dissection

Coxeter states that every zonogon (a 2m-gon whose opposite sides are parallel and of equal length) can be dissected into m(m-1)/2 parallelograms.Coxeter, Mathematical recreations and Essays, Thirteenth edition, p.141

In particular this is true for regular polygons with evenly many sides, in which case the parallelograms are all rhombi. For the regular tetradecagon, m=7, and it can be divided into 21: 3 sets of 7 rhombs. This decomposition is based on a Petrie polygon projection of a 7-cube, with 21 of 672 faces. The list {{OEIS2C|1=A006245}} defines the number of solutions as 24698, including up to 14-fold rotations and chiral forms in reflection.

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|+ Dissection into 21 rhombs

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Numismatic use

The regular tetradecagon is used as the shape of some commemorative gold and silver Malaysian coins, the number of sides representing the 14 states of the Malaysian Federation.The Numismatist, Volume 96, Issues 7-12, Page 1409, American Numismatic Association, 1983.

Related figures

File:Flag of Malaysia.svg

A tetradecagram is a 14-sided star polygon, represented by symbol {14/n}. There are two regular star polygons: {14/3} and {14/5}, using the same vertices, but connecting every third or fifth points. There are also three compounds: {14/2} is reduced to 2{7} as two heptagons, while {14/4} and {14/6} are reduced to 2{7/2} and 2{7/3} as two different heptagrams, and finally {14/7} is reduced to seven digons.

A notable application of a fourteen-pointed star is in the flag of Malaysia, which incorporates a yellow {14/6} tetradecagram in the top-right corner, representing the unity of the thirteen states with the federal government.

class="collapsible wikitable" !colspan=8\|Compounds and star polygons
n\|\|1\|\|2\|\|3\|\|4\|\|5\|\|6\|\|7
Form !Regular !Compound !Star polygon !Compound !Star polygon !colspan=2\|Compound
align=center !Image \|BGCOLOR="#ffe0e0"\|100px {14/1} = {14} {{CDD\|node_1\|14\|node}} \|100px {14/2} = 2{7} {{CDD\|node_h3\|14\|node}} \|BGCOLOR="#ffe0e0"\|100px {14/3} {{CDD\|node_1\|14\|rat\|3x\|node}} \|100px {14/4} = 2{7/2} {{CDD\|node_h3\|14\|rat\|2x\|node}} \|BGCOLOR="#ffe0e0"\|100px {14/5} {{CDD\|node_1\|14\|rat\|5\|node}} \|100px {14/6} = 2{7/3} {{CDD\|node_h3\|14\|rat\|3x\|node}} \|100px {14/7} or 7{2}
align=center ! Internal angle \| ≈154.286° \| ≈128.571° \| ≈102.857° \| ≈77.1429° \| ≈51.4286° \| ≈25.7143° \| 0°

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!colspan=8|Compounds and star polygons

n||1||2||3||4||5||6||7

Form

!Regular

!Compound

!Star polygon

!Compound

!Star polygon

!colspan=2|Compound

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!Image

|BGCOLOR="#ffe0e0"|100px
{14/1} = {14}
{{CDD|node_1|14|node}}

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{14/2} = 2{7}
{{CDD|node_h3|14|node}}

|BGCOLOR="#ffe0e0"|100px
{14/3}
{{CDD|node_1|14|rat|3x|node}}

|100px
{14/4} = 2{7/2}
{{CDD|node_h3|14|rat|2x|node}}

|BGCOLOR="#ffe0e0"|100px
{14/5}
{{CDD|node_1|14|rat|5|node}}

|100px
{14/6} = 2{7/3}
{{CDD|node_h3|14|rat|3x|node}}

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{14/7} or 7{2}

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! Internal angle

| ≈154.286°

| ≈128.571°

| ≈102.857°

| ≈77.1429°

| ≈51.4286°

| ≈25.7143°

| 0°

Deeper truncations of the regular heptagon and heptagrams can produce isogonal (vertex-transitive) intermediate tetradecagram forms with equally spaced vertices and two edge lengths. Other truncations can form double covering polygons 2{p/q}, namely: t{7/6}={14/6}=2{7/3}, t{7/4}={14/4}=2{7/2}, and t{7/2}={14/2}=2{7}.The Lighter Side of Mathematics: Proceedings of the Eugène Strens Memorial Conference on Recreational Mathematics and its History, (1994), Metamorphoses of polygons, Branko Grünbaum

class="wikitable collapsible collapsed" !colspan=5\|Isogonal truncations of heptagon and heptagrams
Quasiregular !colspan=3\|Isogonal !Quasiregular Double covering
align=center valign=top \|BGCOLOR="#ffe0e0"\|100px t{7}={14} \|100px \|100px \|100px \|BGCOLOR="#e0e0ff"\|100px {7/6}={14/6} =2{7/3}
align=center valign=top \|BGCOLOR="#ffe0e0"\|100px t{7/3}={14/3} \|100px \|100px \|100px \|BGCOLOR="#e0e0ff"\|100px t{7/4}={14/4} =2{7/2}
align=center valign=top \|BGCOLOR="#ffe0e0"\|100px t{7/5}={14/5} \|100px \|100px \|100px \|BGCOLOR="#e0e0ff"\|100px t{7/2}={14/2} =2{7}

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!colspan=5|Isogonal truncations of heptagon and heptagrams

Quasiregular

!colspan=3|Isogonal

!Quasiregular
Double covering

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|BGCOLOR="#ffe0e0"|100px
t{7}={14}

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|BGCOLOR="#e0e0ff"|100px
{7/6}={14/6}
=2{7/3}

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|BGCOLOR="#ffe0e0"|100px
t{7/3}={14/3}

|100px

|BGCOLOR="#e0e0ff"|100px
t{7/4}={14/4}
=2{7/2}

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|BGCOLOR="#ffe0e0"|100px
t{7/5}={14/5}

|100px

|BGCOLOR="#e0e0ff"|100px
t{7/2}={14/2}
=2{7}

= Isotoxal forms=

An isotoxal polygon can be labeled as {p_α} with outer most internal angle α, and a star polygon {(p/q)_α}, with q is a winding number, and gcd(p,q)=1, q<p. Isotoxal tetradecagons have p=7, and since 7 is prime all solutions, q=1..6, are polygons.

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{7_α}

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{(7/2)_α}

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{(7/3)_α}

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{(7/4)_α}

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{(7/5)_α}

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{(7/6)_α}

=Petrie polygons=

Regular skew tetradecagons exist as Petrie polygon for many higher-dimensional polytopes, shown in these skew orthogonal projections, including:

class="wikitable collapsible collapsed" !colspan=5\|Petrie polygons
colspan=2\|B₇ !colspan=2\|2I₂(7) (4D) !
align=center valign=center \|100px 7-orthoplex \|100px 7-cube \|100px 7-7 duopyramid \|100px 7-7 duoprism \|
A₁₃ !colspan=2\|D₈ !colspan=2\|E₈
align=center valign=center \|100px 13-simplex \|100px 5₁₁ \|100px 1₅₁ \|100px 4₂₁ \|100px 2₄₁

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!colspan=5|Petrie polygons

colspan=2|B₇

!colspan=2|2I₂(7) (4D)

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7-orthoplex

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7-cube

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7-7 duopyramid

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7-7 duoprism

A₁₃

!colspan=2|D₈

!colspan=2|E₈