Deltoidal hexecontahedron

From HandWiki
Deltoidal hexecontahedron
Deltoidal hexecontahedron
(Click here for rotating model)
Type Catalan
Conway notation oD or deD
Coxeter diagram CDel node f1.pngCDel 5.pngCDel node.pngCDel 3.pngCDel node f1.png
Face polygon DU27 facets.png
kite
Faces 60
Edges 120
Vertices 62 = 12 + 20 + 30
Face configuration V3.4.5.4
Symmetry group Ih, H3, [5,3], (*532)
Rotation group I, [5,3]+, (532)
Dihedral angle 154° 7′ 17′′ arccos(-19-85/41)
Properties convex, face-transitive
Small rhombicosidodecahedron.png
rhombicosidodecahedron
(dual polyhedron)
Deltoidal hexecontahedron net
Net

File:Deltoidal hexecontahedron.stl In geometry, a deltoidal hexecontahedron (also sometimes called a trapezoidal hexecontahedron, a strombic hexecontahedron, or a tetragonal hexacontahedron[1]) is a Catalan solid which is the dual polyhedron of the rhombicosidodecahedron, an Archimedean solid. It is one of six Catalan solids to not have a Hamiltonian path among its vertices.[2]

It is topologically identical to the nonconvex rhombic hexecontahedron.

Lengths and angles

The 60 faces are deltoids or kites. The short and long edges of each kite are in the ratio 1:7 + 5/6 ≈ 1:1.539344663...

The angle between two short edges in a single face is arccos(-5-25/20)≈118.2686774705°. The opposite angle, between long edges, is arccos(-5+95/40)≈67.783011547435° . The other two angles of each face, between a short and a long edge each, are both equal to arccos(5-25/10)≈86.97415549104°.

The dihedral angle between any pair of adjacent faces is arccos(-19-85/41)≈154.12136312578°.

Topology

Topologically, the deltoidal hexecontahedron is identical to the nonconvex rhombic hexecontahedron. The deltoidal hexecontahedron can be derived from a dodecahedron (or icosahedron) by pushing the face centers, edge centers and vertices out to different radii from the body center. The radii are chosen so that the resulting shape has planar kite faces each such that vertices go to degree-3 corners, faces to degree-five corners, and edge centers to degree-four points.

Cartesian coordinates

The 62 vertices of the disdyakis triacontahedron fall in three sets centered on the origin:

  • Twelve vertices are of the form of a unit circumradius regular icosahedron.
  • Twenty vertices are of the form of a [math]\displaystyle{ \frac{3}{11}\sqrt {15 - \frac{6}{\sqrt{5}}}\approx 0.9571 }[/math] scaled regular dodecahedron.
  • Thirty vertices are of the form of a [math]\displaystyle{ 3\sqrt {1-\frac{2}{\sqrt{5}}}\approx0.9748 }[/math] scaled Icosidodecahedron.

These hulls are visualized in the figure below:

Deltoidal hexacontahedron hulls

Orthogonal projections

The deltoidal hexecontahedron has 3 symmetry positions located on the 3 types of vertices:

Orthogonal projections
Projective
symmetry
[2] [2] [2] [2] [6] [10]
Image Dual dodecahedron t02 v.png Dual dodecahedron t02 e34.png Dual dodecahedron t02 e45.png Dual dodecahedron t02 f4.png Dual dodecahedron t02 A2.png Dual dodecahedron t02 H3.png
Dual
image
Dodecahedron t02 v.png Dodecahedron t02 e34.png Dodecahedron t02 e45.png Dodecahedron t02 f4.png Dodecahedron t02 A2.png Dodecahedron t02 H3.png

Variations

This figure from Perspectiva Corporum Regularium (1568) by Wenzel Jamnitzer can be seen as a deltoidal hexecontahedron.

The deltoidal hexecontahedron can be constructed from either the regular icosahedron or regular dodecahedron by adding vertices mid-edge, and mid-face, and creating new edges from each edge center to the face centers. Conway polyhedron notation would give these as oI, and oD, ortho-icosahedron, and ortho-dodecahedron. These geometric variations exist as a continuum along one degree of freedom.

Deltoidal hexecontahedron on icosahedron dodecahedron.png

Related polyhedra and tilings

Spherical deltoidal hexecontahedron

When projected onto a sphere (see right), it can be seen that the edges make up the edges of an icosahedron and dodecahedron arranged in their dual positions.

This tiling is topologically related as a part of sequence of deltoidal polyhedra with face figure (V3.4.n.4), and continues as tilings of the hyperbolic plane. These face-transitive figures have (*n32) reflectional symmetry.


See also

References

External links