Star polyhedron: Difference between revisions
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{{Short description|Polyhedron with some pattern of nonconvexity}} |
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{{no footnotes|date=March 2023}} |
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In [[geometry]], a '''star polyhedron''' is a [[polyhedron]] which has some repetitive quality of [[nonconvex polygon|nonconvexity]] giving it a star-like visual quality. |
In [[geometry]], a '''star polyhedron''' is a [[polyhedron]] which has some repetitive quality of [[nonconvex polygon|nonconvexity]] giving it a star-like visual quality. |
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===Regular star polyhedra=== |
===Regular star polyhedra=== |
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The regular star polyhedra |
The regular star polyhedra are self-intersecting polyhedra. They may either have self-intersecting [[Face (geometry)|faces]], or self-intersecting [[vertex figure]]s. |
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There are four [[ |
There are four [[List of regular polytopes and compounds#Three dimensions 2|regular star polyhedra]], known as the [[Kepler–Poinsot polyhedra]]. The [[Schläfli symbol]] {''p'',''q''} implies faces with ''p'' sides, and vertex figures with ''q'' sides. Two of them have [[pentagram]]mic {5/2} faces and two have pentagrammic vertex figures. |
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[[ |
[[File:Kepler-Poinsot solids.svg]]<BR>These images show each form with a single face colored yellow to show the visible portion of that face. |
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There are also an infinite number of regular star [[dihedra]] and [[hosohedra]] {2,''p/q''} and {''p/q'',2} for any star polygon {''p/q''}. While degenerate in Euclidean space, they can be realised spherically in nondegenerate form. |
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=== Uniform and uniform dual star polyhedra === |
=== Uniform and uniform dual star polyhedra === |
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Two important classes are the [[stellation]]s of convex polyhedra and their duals, the [[facetting]]s of the dual polyhedra. |
Two important classes are the [[stellation]]s of convex polyhedra and their duals, the [[facetting]]s of the dual polyhedra. |
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For example, the [[complete stellation of the icosahedron]] (illustrated) can be interpreted as a self-intersecting polyhedron composed of |
For example, the [[complete stellation of the icosahedron]] (illustrated) can be interpreted as a self-intersecting polyhedron composed of 20 identical faces, each a (9/4) wound polygon. Below is an illustration of this polyhedron with one face drawn in yellow. |
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[[Image:Echidnahedron with enneagram face.png|280px]] |
[[Image:Echidnahedron with enneagram face.png|280px]] |
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=== Star polytopes === |
=== Star polytopes === |
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A similarly self-intersecting [[polytope]] |
A similarly self-intersecting [[polytope]] in any number of dimensions is called a '''star polytope'''. |
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A regular polytope {p,q,r,...,s,t} is a star polytope if either its facet {p,q,...s} or its vertex figure {q,r,...,s,t} is a star polytope. |
A regular polytope {''p'',''q'',''r'',...,''s'',''t''} is a star polytope if either its facet {''p'',''q'',...''s''} or its vertex figure {''q'',''r'',...,''s'',''t''} is a star polytope. |
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In four dimensions, the [[ |
In four dimensions, the [[List of regular polytopes#Non-convex 3|10 regular star polychora]] are called the [[Schläfli–Hess polychoron|Schläfli–Hess polychora]]. Analogous to the regular star polyhedra, these 10 are all composed of facets which are either one of the five regular [[Platonic solid]]s or one of the four regular star [[Kepler–Poinsot polyhedra]]. |
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For example, the [[great grand stellated 120-cell]], projected orthogonally into 3-space, looks like this: |
For example, the [[great grand stellated 120-cell]], projected orthogonally into 3-space, looks like this: |
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:[[Image:Ortho solid 016-uniform polychoron p33-t0.png|320px]] |
:[[Image:Ortho solid 016-uniform polychoron p33-t0.png|320px]] |
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There are no regular star polytopes in dimensions higher than 4. |
There are no regular star polytopes in dimensions higher than 4{{Citation needed|reason=When was this proven and by whom?|date=November 2022}}. |
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== Star-domain star polyhedra == |
== Star-domain star polyhedra == |
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[[File:19. Moravian Star.JPG|alt=|thumb|A Moravian star hung outside a church]] |
[[File:19. Moravian Star.JPG|alt=|thumb|A Moravian star hung outside a church]] |
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A polyhedron which does not cross |
A polyhedron which does not cross itself, such that all of the interior can be seen from one interior point, is an example of a [[star domain]]. The visible exterior portions of many self-intersecting star polyhedra form the boundaries of star domains, |
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but despite their similar appearance, as [[abstract polyhedra]] these are different structures. For instance, the small stellated dodecahedron has 12 pentagram faces, but the corresponding star domain has 60 isosceles triangle faces, and correspondingly different numbers of vertices and edges. |
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Polyhedral star domains appear in various types of architecture, usually religious in nature. For example, they are seen on many baroque churches as symbols of the [[Pope]] who built the church, on Hungarian churches and on other religious buildings. These stars can also be used as decorations. [[Moravian star]]s are used for both purposes and can be constructed in various forms. |
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== See also == |
== See also == |
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* [[List of uniform polyhedra by Schwarz triangle]] |
* [[List of uniform polyhedra by Schwarz triangle]] |
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== |
==References== |
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{{reflist}} |
{{reflist}} |
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==References== |
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⚫ | * Tarnai, T., Krähling, J. and Kabai, S.; "Star polyhedra: from St. Mark's Basilica in Venice to Hungarian Protestant churches", Paper ID209, ''Proc. of the IASS 2007, Shell and Spatial Structures: Structural Architecture-Towards the Future Looking to the Past'', University of IUAV, 2007. [http://www.saintjohnsabbey.org/wenninger/seteight/PAP209tarnai.pdf] {{Webarchive|url=https://web.archive.org/web/20101129202720/http://saintjohnsabbey.org/wenninger/seteight/PAP209tarnai.pdf |date=2010-11-29 }} or [http://www.employees.csbsju.edu/mwenninger/seteight/PAP209tarnai.pdf]{{Dead link|date=February 2024 |bot=InternetArchiveBot |fix-attempted=yes }} |
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⚫ | * Tarnai, T., Krähling, J. and Kabai, S.; "Star polyhedra: from St. Mark's Basilica in Venice to Hungarian Protestant churches", Paper ID209, ''Proc. of the IASS 2007, Shell and Spatial Structures: Structural Architecture-Towards the Future Looking to the Past'', University of IUAV, 2007. [http://www.saintjohnsabbey.org/wenninger/seteight/PAP209tarnai.pdf] or [http://www.employees.csbsju.edu/mwenninger/seteight/PAP209tarnai.pdf] |
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==External links== |
==External links== |
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*{{Mathworld | urlname=StarPolyhedron | title=Star Polyhedron }} |
*{{Mathworld | urlname=StarPolyhedron | title=Star Polyhedron }} |
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[[Category:Polyhedra]] |
[[Category:Polyhedra]] |
Latest revision as of 17:52, 14 November 2024
This article includes a list of references, related reading, or external links, but its sources remain unclear because it lacks inline citations. (March 2023) |
In geometry, a star polyhedron is a polyhedron which has some repetitive quality of nonconvexity giving it a star-like visual quality.
There are two general kinds of star polyhedron:
- Polyhedra which self-intersect in a repetitive way.
- Concave polyhedra of a particular kind which alternate convex and concave or saddle vertices in a repetitive way. Mathematically these figures are examples of star domains.
Mathematical studies of star polyhedra are usually concerned with regular, uniform polyhedra, or the duals of the uniform polyhedra. All these stars are of the self-intersecting kind.
Self-intersecting star polyhedra
[edit]Regular star polyhedra
[edit]The regular star polyhedra are self-intersecting polyhedra. They may either have self-intersecting faces, or self-intersecting vertex figures.
There are four regular star polyhedra, known as the Kepler–Poinsot polyhedra. The Schläfli symbol {p,q} implies faces with p sides, and vertex figures with q sides. Two of them have pentagrammic {5/2} faces and two have pentagrammic vertex figures.
These images show each form with a single face colored yellow to show the visible portion of that face.
There are also an infinite number of regular star dihedra and hosohedra {2,p/q} and {p/q,2} for any star polygon {p/q}. While degenerate in Euclidean space, they can be realised spherically in nondegenerate form.
Uniform and uniform dual star polyhedra
[edit]There are many uniform star polyhedra including two infinite series, of prisms and of antiprisms, and their duals.
The uniform and dual uniform star polyhedra are also self-intersecting polyhedra. They may either have self-intersecting faces, or self-intersecting vertex figures or both.
The uniform star polyhedra have regular faces or regular star polygon faces. The dual uniform star polyhedra have regular faces or regular star polygon vertex figures.
Uniform polyhedron | Dual polyhedron |
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The pentagrammic prism is a prismatic star polyhedron. It is composed of two pentagram faces connected by five intersecting square faces. |
The pentagrammic dipyramid is also a star polyhedron, representing the dual to the pentagrammic prism. It is face-transitive, composed of ten intersecting isosceles triangles. |
The great dodecicosahedron is a star polyhedron, constructed from a single vertex figure of intersecting hexagonal and decagrammic, {10/3}, faces. |
The great dodecicosacron is the dual to the great dodecicosahedron. It is face-transitive, composed of 60 intersecting bow-tie-shaped quadrilateral faces. |
Stellations and facettings
[edit]Beyond the forms above, there are unlimited classes of self-intersecting (star) polyhedra.
Two important classes are the stellations of convex polyhedra and their duals, the facettings of the dual polyhedra.
For example, the complete stellation of the icosahedron (illustrated) can be interpreted as a self-intersecting polyhedron composed of 20 identical faces, each a (9/4) wound polygon. Below is an illustration of this polyhedron with one face drawn in yellow.
Star polytopes
[edit]A similarly self-intersecting polytope in any number of dimensions is called a star polytope.
A regular polytope {p,q,r,...,s,t} is a star polytope if either its facet {p,q,...s} or its vertex figure {q,r,...,s,t} is a star polytope.
In four dimensions, the 10 regular star polychora are called the Schläfli–Hess polychora. Analogous to the regular star polyhedra, these 10 are all composed of facets which are either one of the five regular Platonic solids or one of the four regular star Kepler–Poinsot polyhedra.
For example, the great grand stellated 120-cell, projected orthogonally into 3-space, looks like this:
There are no regular star polytopes in dimensions higher than 4[citation needed].
Star-domain star polyhedra
[edit]A polyhedron which does not cross itself, such that all of the interior can be seen from one interior point, is an example of a star domain. The visible exterior portions of many self-intersecting star polyhedra form the boundaries of star domains, but despite their similar appearance, as abstract polyhedra these are different structures. For instance, the small stellated dodecahedron has 12 pentagram faces, but the corresponding star domain has 60 isosceles triangle faces, and correspondingly different numbers of vertices and edges.
Polyhedral star domains appear in various types of architecture, usually religious in nature. For example, they are seen on many baroque churches as symbols of the Pope who built the church, on Hungarian churches and on other religious buildings. These stars can also be used as decorations. Moravian stars are used for both purposes and can be constructed in various forms.
See also
[edit]- Star polygon
- Stellation
- Polyhedral compound
- List of uniform polyhedra
- List of uniform polyhedra by Schwarz triangle
References
[edit]- Coxeter, H.S.M., M. S. Longuet-Higgins and J.C.P Miller, Uniform Polyhedra, Phil. Trans. 246 A (1954) pp. 401–450.
- Coxeter, H.S.M., Regular Polytopes, 3rd. ed., Dover Publications, 1973. ISBN 0-486-61480-8. (VI. Star-polyhedra, XIV. Star-polytopes) (p. 263) [1]
- John H. Conway, Heidi Burgiel, Chaim Goodman-Strauss, The Symmetries of Things 2008, ISBN 978-1-56881-220-5 (Chapter 26, Regular star-polytopes, pp. 404–408)
- Tarnai, T., Krähling, J. and Kabai, S.; "Star polyhedra: from St. Mark's Basilica in Venice to Hungarian Protestant churches", Paper ID209, Proc. of the IASS 2007, Shell and Spatial Structures: Structural Architecture-Towards the Future Looking to the Past, University of IUAV, 2007. [2] Archived 2010-11-29 at the Wayback Machine or [3][permanent dead link ]