Pentagonal cupola

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Pentagonal cupola
TypeJohnson
J4J5J6
Faces5 triangles
5 squares
1 pentagon
1 decagon
Edges25
Vertices15
Vertex configuration 10 × ( 3 × 4 × 10 ) {\displaystyle 10\times (3\times 4\times 10)} {\displaystyle 10\times (3\times 4\times 10)}
5 × ( 3 × 4 × 5 × 4 ) {\displaystyle 5\times (3\times 4\times 5\times 4)} {\displaystyle 5\times (3\times 4\times 5\times 4)}
Symmetry group C v {\displaystyle C_{\mathrm {v} }} {\displaystyle C_{\mathrm {v} }}
Propertiesconvex, elementary
Net

In geometry, the pentagonal cupola is one of the Johnson solids (J5). It can be obtained as a slice of the rhombicosidodecahedron. The pentagonal cupola consists of 5 equilateral triangles, 5 squares, 1 pentagon, and 1 decagon.

Properties

The pentagonal cupola's faces are five equilateral triangles, five squares, one regular pentagon, and one regular decagon.[1] It has the property of convexity and regular polygonal faces, from which it is classified as the fifth Johnson solid.[2] This cupola cannot be sliced by a plane without cutting within a face, so it is an elementary polyhedron.[3]

The following formulae for circumradius R {\displaystyle R} {\displaystyle R}, and height h {\displaystyle h} {\displaystyle h}, surface area A {\displaystyle A} {\displaystyle A}, and volume V {\displaystyle V} {\displaystyle V} may be applied if all faces are regular with edge length a {\displaystyle a} {\displaystyle a}:[4] h = 5 − 5 10 a ≈ 0.526 a , R = 11 + 4 5 2 a ≈ 2.233 a , A = 20 + 5 3 + 5 ( 145 + 62 5 ) 4 a 2 ≈ 16.580 a 2 , V = 5 + 4 5 6 a 3 ≈ 2.324 a 3 . {\displaystyle {\begin{aligned}h&={\sqrt {\frac {5-{\sqrt {5}}}{10}}}a&\approx 0.526a,\\R&={\frac {\sqrt {11+4{\sqrt {5}}}}{2}}a&\approx 2.233a,\\A&={\frac {20+5{\sqrt {3}}+{\sqrt {5\left(145+62{\sqrt {5}}\right)}}}{4}}a^{2}&\approx 16.580a^{2},\\V&={\frac {5+4{\sqrt {5}}}{6}}a^{3}&\approx 2.324a^{3}.\end{aligned}}} {\displaystyle {\begin{aligned}h&={\sqrt {\frac {5-{\sqrt {5}}}{10}}}a&\approx 0.526a,\\R&={\frac {\sqrt {11+4{\sqrt {5}}}}{2}}a&\approx 2.233a,\\A&={\frac {20+5{\sqrt {3}}+{\sqrt {5\left(145+62{\sqrt {5}}\right)}}}{4}}a^{2}&\approx 16.580a^{2},\\V&={\frac {5+4{\sqrt {5}}}{6}}a^{3}&\approx 2.324a^{3}.\end{aligned}}}


3D model of a pentagonal cupola

It has an axis of symmetry passing through the center of both top and base, which is symmetrical by rotating around it at one-, two-, three-, and four-fifth of a full-turn angle. It is also mirror-symmetric relative to any perpendicular plane passing through a bisector of the hexagonal base. Therefore, it has pyramidal symmetry, the cyclic group C 5 v {\displaystyle C_{5\mathrm {v} }} {\displaystyle C_{5\mathrm {v} }} of order ten.[3]

The pentagonal cupola can be applied to construct a polyhedron. A construction that involves the attachment of its base to another polyhedron is known as augmentation; attaching it to prisms or antiprisms is known as elongation or gyroelongation.[5][6] Some of the Johnson solids with such constructions are:

Relatedly, a construction from polyhedra by removing one or more pentagonal cupolas is known as diminishment[1]:

References

  1. Berman, Martin (1971). "Regular-faced convex polyhedra". Journal of the Franklin Institute. 291 (5): 329–352. doi:10.1016/0016-0032(71)90071-8. MR 0290245.
  2. Uehara, Ryuhei (2020). Introduction to Computational Origami: The World of New Computational Geometry. Springer. p. 62. doi:10.1007/978-981-15-4470-5. ISBN 978-981-15-4470-5. S2CID 220150682.
  3. Johnson, Norman W. (1966). "Convex polyhedra with regular faces". Canadian Journal of Mathematics. 18: 169–200. doi:10.4153/cjm-1966-021-8. MR 0185507. S2CID 122006114. Zbl 0132.14603.
  4. Braileanu1, Patricia I.; Cananaul, Sorin; Pasci, Nicoleta E. (2022). "Geometric pattern infill influence on pentagonal cupola mechanical behavior subject to static external loads". Journal of Research and Innovation for Sustainable Society. 4 (2). Thoth Publishing House: 5–15. doi:10.33727/JRISS.2022.2.1:5-15 (inactive 1 July 2025). ISSN 2668-0416.{{cite journal}}: CS1 maint: DOI inactive as of July 2025 (link) CS1 maint: numeric names: authors list (link)
  5. Demey, Lorenz; Smessaert, Hans (2017). "Logical and Geometrical Distance in Polyhedral Aristotelian Diagrams in Knowledge Representation". Symmetry. 9 (10): 204. Bibcode:2017Symm....9..204D. doi:10.3390/sym9100204.
  6. Slobodan, Mišić; Obradović, Marija; Ðukanović, Gordana (2015). "Composite Concave Cupolae as Geometric and Architectural Forms" (PDF). Journal for Geometry and Graphics. 19 (1): 79–91.