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	{{~~Reg~~ ~~polyhedra db~~\|~~Reg nonconvex~~ polyhedron ~~stat table\|gD~~}}		{{short description\|Kepler-Poinsot polyhedron}}
			{{infobox polyhedron
	In ], the '''great dodecahedron''' is a ]</sub>, with ] {5,5/2} and ] of {{CDD\|node_1\|5\|node\|5\|rat\|d2\|node}}. It is one of four ] ]. It is composed of 12 pentagonal faces (six pairs of parallel pentagons), with five pentagons meeting at each vertex, intersecting each other making a ]mic path.
			\| name = Great dodecahedron
			\| image = GreatDodecahedron.gif
			\| type = ]
			\| faces = 12
			\| edges = 30
			\| vertices = 12
			\| symmetry = ] <math> I_\mathrm{h} </math>
			\| properties = ], non-]
			\| dual = ]
			\| vertex_figure = Great dodecahedron vertfig.png
			}}
			]

			In ], the '''great dodecahedron''' is one of four ]. It is composed of 12 ]al faces (six pairs of parallel pentagons), intersecting each other making a ]mic path, with five pentagons meeting at each vertex.
	== Images ==

			== Construction ==
	{\| class=wikitable width=480
			One way to construct a great dodecahedron is by ] the ]. In other words, it is constructed from the regular icosahedron by removing its polygonal faces without changing or creating new vertices.{{r\|inchbald}} Another way is to form a regular pentagon by each of the five vertices inside of a regular icosahedron, and twelve regular pentagons intersecting each other, making a ] as its ].{{r\|pugh\|barnes}}
	!Transparent model
	!]
	\|-
	\|]<BR> (])
	\|]<BR>This polyhedron represents a ] with a density of 3. (One spherical pentagon face is shown above in yellow)
	\|-
	!]
	!]
	\|-
	\|]<BR>Net for surface geometry
	\|]<BR>It can also be constructed as the second of three ]s of the dodecahedron, and referenced as ]].
	\|}

			The great dodecahedron may also be interpreted as the ''second stellation of dodecahedron''. The construction started from a ] by attaching 12 pentagonal pyramids onto each of its faces, known as the ''first stellation''. The second stellation appears when 30 ]s are attached to it.{{r\|cromwell}}
	== Related polyhedra ==
	It shares the same ] as the convex regular ].

			== Formulas ==
	If the ''great dodecahedron'' is considered as a properly intersected surface geometry, it has the same topology as a ] with concave pyramids rather than convex ones.
			Given a great dodecahedron with edge length E,
	<!-- UNCLEAR WHAT THIS MEANS: Shaving off the concave part results in a ]. -->

			<math display = block>\text{Inradius} = \frac{\text{E}\sqrt{10(5+\sqrt{5})}}{20}</math>

			<math display = block>\text{Midradius} = \frac{\text{E}(1+\sqrt{5})}{4}</math>

			<math display = block>\text{Circumradius} = \frac{\text{E}\sqrt{10+2\sqrt{5}}}{4}</math>

			<math display=block>\text{Surface Area} = 15\text{E}^2\sqrt{5-2\sqrt{5}}.</math>

			<math display=block>\text{Volume} = \frac{5(\sqrt{5}-1)\text{E}^3}{4}. </math>

			== Appearance ==
			{{multiple image
			\| image1 = Perspectiva Corporum Regularium 22c.jpg
			\| caption1 = Great dodecahedron in '']''
			\| image2 = Alexander's Star.jpg
			\| caption2 = Alexander's Star in solved state
			\| total_width = 300
			}}
			Historically, the great dodecahedron is one of two solids discovered by ] in 1810, with some people named it after him, ''Poinsot solid''. As for the background, Poinsot rediscovered two other solids that were already discovered by ]—the ] and the ].{{r\|barnes}} However, the great dodecahedron appeared in the 1568 '']'' by ], although its drawing is somewhat similar.{{r\|ss}}

			The great dodecahedron appeared in popular culture and toys. An example is ] puzzle, a ] that is based on a great dodecahedron.<ref>{{cite magazine\|url=https://archive.org/details/games-32-1982-October/page/n57/mode/2up\|title=Alexander's star\|magazine=Games\|issue=32\|date=October 1982\|page=56}}</ref>

			== Related polyhedra ==
			{{multiple image
			\| image1 = Compound of great dodecahedron and small stellated dodecahedron.png
			\| caption1 = Great dodecahedron shown solid, surrounding stellated dodecahedron only as wireframe
			\| image2 = Small stellated dodecahedron truncations.gif
			\| caption2 = Animated truncation sequence from {5/2, 5} to {5, 5/2}
			\| total_width = 300
			}}
			{{anchor\|Compound}}The ''compound of small stellated dodecahedron and great dodecahedron'' is a ] where the great dodecahedron is internal to its ], the ]. This can be seen as one of the two three-dimensional equivalents of the compound of two pentagrams ({10/4} "]"); this series continues into the fourth dimension as ].

	A ] process applied to the great dodecahedron produces a series of ]. Truncating edges down to points produces the ] as a rectified great dodecahedron. The process completes as a birectification, reducing the original faces down to points, and producing the ].		A ] process applied to the great dodecahedron produces a series of ]. Truncating edges down to points produces the ] as a rectified great dodecahedron. The process completes as a birectification, reducing the original faces down to points, and producing the ].

			It shares the same ] as the convex regular ]; the compound with both is the ].
	The ''truncated small stellated dodecahedron'' looks like a ] on the surface, but it has 24 ]al faces: 12 as the truncation facets of the former vertices, and 12 more (coinciding with the first set) as truncated pentagrams.

			==References==
	{\| class="wikitable" width=500
			{{Reflist\|refs=
	!Name
	!]
	!]
	!]
	!]
	!]
	\|- align=center
	!]
	\|{{CDD\|node\|5\|node\|5\|rat\|d2\|node_1}}
	\|{{CDD\|node\|5\|node_1\|5\|rat\|d2\|node_1}}
	\|{{CDD\|node\|5\|node_1\|5\|rat\|d2\|node}}
	\|{{CDD\|node_1\|5\|node_1\|5\|rat\|d2\|node}}
	\|{{CDD\|node_1\|5\|node\|5\|rat\|d2\|node}}
	\|- align=center
	!Picture
	\|]
	\|]
	\|]
	\|]
	\|]
	\|}

			<ref name=barnes>{{cite book
	== Usage ==
			\| last = Barnes \| first = John
			\| year = 2012
			\| title = Gems of Geometry
			\| edition = 2nd
			\| url = https://books.google.com/books?id=7YCUBUd-4BQC&pg=PA46
			\| page = 46
			\| publisher = Springer
			\| doi = 10.1007/978-3-642-30964-9
			\| isbn = 978-3-642-30964-9
			}}</ref>

			<ref name=cromwell>{{cite book
	* This shape was the basis for the ]-like ] puzzle.
			\| last = Cromwell \| first = Peter
			\| year = 1997
			\| title = Polyhedra
			\| url = https://books.google.com/books?id=OJowej1QWpoC&pg=PA265
			\| page = 265
			\| publisher = ]
			\| isbn = 978-0-521-66405-9
			}}</ref>

			<!--
	==See also==
			<ref name=fj>{{cite journal
	*]
			\| last1 = French \| first1 = Doug
			\| last2 = Jordan \| first2 = David
			\| year = 2010
			\| title = Dodecahedral slices and polyhedral pieces
			\| journal = ]
			\| volume = 92 \| issue = 529 \| pages = 5–17
			\| jstor = 27821883
			}}</ref>
			-->

			<ref name=inchbald>{{cite journal
			\| last = Inchbald \| first = Guy
			\| year = 2006
			\| title = Facetting Diagrams
			\| journal = ]
			\| volume = 90 \| issue = 518 \| pages = 253–261
			\| doi = 10.1017/S0025557200179653
			\| jstor = 40378613
			}}</ref>

			<ref name=pugh>{{cite book
			\| last = Pugh \| first = Anthony
			\| year = 1976
			\| title = Polyhedra: A Visual Approach
			\| url = https://books.google.com/books?id=IDDxpYQTR7kC&pg=PA85
			\| page = 85
			\| publisher = University of California Press
			\| isbn = 978-0-520-03056-5
			}}</ref>

			<ref name=ss>{{cite book
			\| last1 = Scriba \| first1 = Christoph
			\| last2 = Schreiber \| first2 = Peter
			\| year = 2015
			\| title = 5000 Years of Geometry: Mathematics in History and Culture
			\| url = https://books.google.com/books?id=6Kp9CAAAQBAJ&pg=PA305
			\| page = 305
			\| publisher = Springer
			\| doi = 10.1007/978-3-0348-0898-9
			\| isbn = 978-3-0348-0898-9
			}}</ref>

			}}

	== External links ==		== External links ==
	* {{mathworld2 \| urlname = GreatDodecahedron\| title =Great dodecahedron \| urlname2 = UniformPolyhedron \| title2 = Uniform polyhedron}}		* {{mathworld2 \| urlname = GreatDodecahedron\| title =Great dodecahedron \| urlname2 = UniformPolyhedron \| title2 = Uniform polyhedron}}
	** {{mathworld \| urlname = DodecahedronStellations\| title =Three dodecahedron stellations}}		* {{mathworld \| urlname = DodecahedronStellations\| title =Three dodecahedron stellations}}
	*		*
	*		*

	{{~~Nonconvex~~ polyhedron navigator}}		{{Star polyhedron navigator}}

	{{Dodecahedron stellations}}
	]		]
	]		]
	]		]
	]		]

	]
	]
	]
	]
	]

Latest revision as of 07:29, 16 December 2024

Kepler-Poinsot polyhedron

Great dodecahedron

Type	Kepler–Poinsot polyhedron
Faces	12
Edges	30
Vertices	12
Symmetry group	icosahedral symmetry $I_{\mathrm {h} }$
Dual polyhedron	small stellated dodecahedron
Properties	regular, non-convex
Vertex figure

In geometry, the great dodecahedron is one of four Kepler–Poinsot polyhedra. It is composed of 12 pentagonal faces (six pairs of parallel pentagons), intersecting each other making a pentagrammic path, with five pentagons meeting at each vertex.

Construction

One way to construct a great dodecahedron is by faceting the regular icosahedron. In other words, it is constructed from the regular icosahedron by removing its polygonal faces without changing or creating new vertices. Another way is to form a regular pentagon by each of the five vertices inside of a regular icosahedron, and twelve regular pentagons intersecting each other, making a pentagram as its vertex figure.

The great dodecahedron may also be interpreted as the second stellation of dodecahedron. The construction started from a regular dodecahedron by attaching 12 pentagonal pyramids onto each of its faces, known as the first stellation. The second stellation appears when 30 wedges are attached to it.

Formulas

Given a great dodecahedron with edge length E,

${\text{Inradius}}={\frac {{\text{E}}{\sqrt {10(5+{\sqrt {5}})}}}{20}}$

${\text{Midradius}}={\frac {{\text{E}}(1+{\sqrt {5}})}{4}}$

${\text{Circumradius}}={\frac {{\text{E}}{\sqrt {10+2{\sqrt {5}}}}}{4}}$

${\text{Surface Area}}=15{\text{E}}^{2}{\sqrt {5-2{\sqrt {5}}}}.$

${\text{Volume}}={\frac {5({\sqrt {5}}-1){\text{E}}^{3}}{4}}.$

Appearance

Great dodecahedron in Perspectiva Corporum Regularium

Alexander's Star in solved state

Historically, the great dodecahedron is one of two solids discovered by Louis Poinsot in 1810, with some people named it after him, Poinsot solid. As for the background, Poinsot rediscovered two other solids that were already discovered by Johannes Kepler—the small stellated dodecahedron and the great stellated dodecahedron. However, the great dodecahedron appeared in the 1568 Perspectiva Corporum Regularium by Wenzel Jamnitzer, although its drawing is somewhat similar.

The great dodecahedron appeared in popular culture and toys. An example is Alexander's Star puzzle, a Rubik's Cube that is based on a great dodecahedron.

Related polyhedra

Great dodecahedron shown solid, surrounding stellated dodecahedron only as wireframe

Animated truncation sequence from {5/2, 5} to {5, 5/2}

The compound of small stellated dodecahedron and great dodecahedron is a polyhedron compound where the great dodecahedron is internal to its dual, the small stellated dodecahedron. This can be seen as one of the two three-dimensional equivalents of the compound of two pentagrams ({10/4} "decagram"); this series continues into the fourth dimension as compounds of star 4-polytopes.

A truncation process applied to the great dodecahedron produces a series of nonconvex uniform polyhedra. Truncating edges down to points produces the dodecadodecahedron as a rectified great dodecahedron. The process completes as a birectification, reducing the original faces down to points, and producing the small stellated dodecahedron.

It shares the same edge arrangement as the convex regular icosahedron; the compound with both is the small complex icosidodecahedron.

References

Inchbald, Guy (2006). "Facetting Diagrams". The Mathematical Gazette. 90 (518): 253–261. doi:10.1017/S0025557200179653. JSTOR 40378613.
Pugh, Anthony (1976). Polyhedra: A Visual Approach. University of California Press. p. 85. ISBN 978-0-520-03056-5.
^ Barnes, John (2012). Gems of Geometry (2nd ed.). Springer. p. 46. doi:10.1007/978-3-642-30964-9. ISBN 978-3-642-30964-9.
Cromwell, Peter (1997). Polyhedra. Cambridge University Press. p. 265. ISBN 978-0-521-66405-9.
Scriba, Christoph; Schreiber, Peter (2015). 5000 Years of Geometry: Mathematics in History and Culture. Springer. p. 305. doi:10.1007/978-3-0348-0898-9. ISBN 978-3-0348-0898-9.
"Alexander's star". Games. No. 32. October 1982. p. 56.

External links

v t e Star-polyhedra navigator
Kepler-Poinsot polyhedra (nonconvex regular polyhedra)	small stellated dodecahedron great dodecahedron great stellated dodecahedron great icosahedron
Uniform truncations of Kepler-Poinsot polyhedra	dodecadodecahedron truncated great dodecahedron rhombidodecadodecahedron truncated dodecadodecahedron snub dodecadodecahedron great icosidodecahedron truncated great icosahedron nonconvex great rhombicosidodecahedron great truncated icosidodecahedron
Nonconvex uniform hemipolyhedra	tetrahemihexahedron cubohemioctahedron octahemioctahedron small dodecahemidodecahedron small icosihemidodecahedron great dodecahemidodecahedron great icosihemidodecahedron great dodecahemicosahedron small dodecahemicosahedron
Duals of nonconvex uniform polyhedra	medial rhombic triacontahedron small stellapentakis dodecahedron medial deltoidal hexecontahedron small rhombidodecacron medial pentagonal hexecontahedron medial disdyakis triacontahedron great rhombic triacontahedron great stellapentakis dodecahedron great deltoidal hexecontahedron great disdyakis triacontahedron great pentagonal hexecontahedron
Duals of nonconvex uniform polyhedra with infinite stellations	tetrahemihexacron hexahemioctacron octahemioctacron small dodecahemidodecacron small icosihemidodecacron great dodecahemidodecacron great icosihemidodecacron great dodecahemicosacron small dodecahemicosacron

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