Chamfer (geometry)
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| A chamfered cube can be constructed by reducing the square faces, and connecting new edges to vertices at the original positions. Topologically: (v,e,f) --> (v+2e,4e,f+e) | |
In geometry, chamfering or edge-truncation is a Conway polyhedron notation operation that modifies one polyhedron into another. It is similar to expansion, moving faces apart and outward, but also maintain the original vertices. For polyhedra, this operation adds a new hexagonal face in place of each original edge.
A polyhedron with e edges will have a chamfered form containing 2e new vertices, 3e new edges, and e new hexagonal faces.
Chamfered regular and quasiregular polyhedra
| Class | Regular | Quasiregular | |||||
|---|---|---|---|---|---|---|---|
| Seed |  {3,3} |
 {4,3} |
 {3,4} |
 {5,3} |
 {3,5} |
 aC |
 aD |
| Chamfered |  cT |
 cC |
 cO |
 cD |
 cI |
 caC |
 caD |
Relation to Goldberg polyhedra
The chamfer operation applied in series creates progressively larger polyhedra with new hexagonal faces replacing edges from the previous one. The chamfer operator transforms G(m,n) to G(2m,2n).
A regular polyhedron, G(1,0), create a Goldberg polyhedra sequence: G(1,0), G(2,0), G(4,0), G(8,0), G(16,0)...
| G(1,0) | G(2,0) | G(4,0) | G(8,0) | G(16,0)... | |
|---|---|---|---|---|---|
| GIV | C |
cC |
 ccC |
 cccC |
|
| GV | D |
cD |
 ccD |
 cccD |
 ccccD |
| GVI |  H |
 cH |
 ccH |
cccH |
ccccH |
The truncated octahedron or truncated icosahedron, G(1,1) creates a Goldberg sequence: G(1,1), G(2,2), G(4,4), G(8,8)....
| G(1,1) | G(2,2) | G(4,4)... | |
|---|---|---|---|
| GIV |  tO |
 ctO |
 cctO |
| GV |  tI |
 ctI |
 cctI |
| GVI |  tH |
 ctH |
cctH |
A truncated tetrakis hexahedron or pentakis dodecahedron, G(3,0), creates a Goldberg sequence: G(3,0), G(6,0), G(12,0)...
| G(3,0) | G(6,0) | G(12,0)... | |
|---|---|---|---|
| GIV |  tkC |
ctkC | cctkC |
| GV |  tkD |
 ctkD |
cctkD |
| GVI |  tkH |
 ctkH |
cctkH |
Chamfered regular tilings
 Square tiling, Q {4,4} |
 Triangular tiling, Δ {3,6} |
Hexagonal tiling, H {6,3} | ||
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 |
 |
|
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| cQ | cΔ | cH | ||
Chamfered polytopes and honeycombs
Like the expansion operation, chamfer can be applied to any dimension. For polygons, it triples the number of vertices. For polychora, new cells are created around the original edges, The cells are prisms, containing two copies of the original face, with pyramids augmented onto the prism sides.
Chamfered tetrahedron
| Chamfered tetrahedron | |
|---|---|
| |
| Conway notation | cT |
| Goldberg polyhedron | GIII(2,0) |
| Faces | 4 triangles 6 hexagons |
| Edges | 24 (2 types) |
| Vertices | 16 (2 types) |
| Vertex configuration | (12) 3.6.6 (4) 6.6.6 |
| Symmetry group | Tetrahedral (Td) |
| Dual polyhedron | Alternate-triakis octahedron |
| Properties | convex, equilateral-faced |
The chamfered tetrahedron (or alternate truncated cube) is a convex polyhedron constructed as an alternately truncated cube or chamfer operation on a tetrahedron, replacing its 6 edges with hexagons.
It is the Goldberg polyhedron GIII(2,0), containing triangular and hexagonal faces.
It can look a little like a truncated tetrahedron, 
, which has 4 hexagonal and 4 triangular faces, which is the related Goldberg polyhedron: GIII(1,1).
Net
Chamfered cube
| Chamfered cube | |
|---|---|
| |
| Conway notation | cC = t4daC |
| Goldberg polyhedron | GIV(2,0) |
| Faces | 6 squares 12 hexagons |
| Edges | 48 (2 types) |
| Vertices | 32 (2 types) |
| Vertex configuration | (24) 4.6.6 (8) 6.6.6 |
| Symmetry | Oh, [4,3], (*432) |
| Dual polyhedron | Tetrakis cuboctahedron |
| Properties | convex, zonohedron, equilateral-faced |
 net | |
In geometry, the chamfered cube (also called truncated rhombic dodecahedron) is a convex polyhedron constructed from the rhombic dodecahedron by truncating the 6 (order 4) vertices.
The 6 vertices are truncated such that all edges are equal length. The original 12 rhombic faces become flattened hexagons, and the truncated vertices become squares.
The hexagonal faces are equilateral but not regular. They are formed by a truncated rhombus, have 2 internal angles of about 109.47 degrees () and 4 internal angles of about 125.26 degrees, while a regular hexagon would have all 120 degree angles.
Because all its faces have an even number of sides with 180 degree rotation symmetry, it is a zonohedron. It is also the Goldberg polyhedron GIV(2,0), containing square and hexagonal faces.
Coordinates
The chamfered cube is the Minkowski sum of a rhombic dodecahedron and a cube of side length 1 when eight vertices of the rhombic dodecahedron are at and its six vertices are at the permutations of .
This polyhedron looks similar to the uniform truncated octahedron:
| Chamfered cube |
Truncated octahedron |
|---|
We can construct a truncated octahedron model by twenty four chamfered cube blocks.[1] [2]
Chamfered octahedron
| Chamfered octahedron | |
|---|---|
| |
| Conway notation | cO = t3daO |
| Faces | 8 triangles 12 hexagons |
| Edges | 48 (2 types) |
| Vertices | 30 (2 types) |
| Vertex configuration | (24) 3.6.6 (6) 6.6.6 |
| Symmetry | Oh, [4,3], (*432) |
| Dual polyhedron | Triakis cuboctahedron |
| Properties | convex |
In geometry, the chamfered octahedron is a convex polyhedron constructed from the rhombic dodecahedron by truncating the 8 (order 3) vertices.
The 8 vertices are truncated such that all edges are equal length. The original 12 rhombic faces become flattened hexagons, and the truncated vertices become triangles.
The hexagonal faces are equilateral but not regular.
Chamfered dodecahedron
| Chamfered dodecahedron | |
|---|---|
| |
| Conway notation | cD=t5daD |
| Goldberg polyhedron | GV(2,0) |
| Fullerene | C80[3] |
| Faces | 12 pentagons 30 hexagons |
| Edges | 120 (2 types) |
| Vertices | 80 (2 types) |
| Vertex configuration | (60) 5.6.6 (20) 6.6.6 |
| Symmetry group | Icosahedral (Ih) |
| Dual polyhedron | Pentakis icosidodecahedron |
| Properties | convex, equilateral-faced |
The chamfered dodecahedron (also called truncated rhombic triacontahedron) is a convex polyhedron constructed as a truncation of the rhombic triacontahedron. It can more accurately be called a pentatruncated rhombic triacontahedron because only the order-5 vertices are truncated.
These 12 order-5 vertices can be truncated such that all edges are equal length. The original 30 rhombic faces become non-regular hexagons, and the truncated vertices become regular pentagons.
The hexagon faces can be equilateral but not regular with D2 symmetry. The angles at the two vertices with vertex configuration 6.6.6 are arccos(-1/sqrt(5)) = 116.565 degrees, and at the remaining four vertices with 5.6.6, they are 121.717 degrees each.
It is the Goldberg polyhedron GV(2,0), containing pentagonal and hexagonal faces.
This polyhedron looks very similar to the uniform truncated icosahedron which has 12 pentagons, but only 20 hexagons.
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Truncated rhombic triacontahedron
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cell-centered orthogonal projection of the 120-cell
It also represents the exterior envelope of a cell-centered orthogonal projection of the 120-cell, one of six (convex regular 4-polytopes).
Chemistry
This is the shape of the fullerene C80; sometimes this shape is denoted C80(Ih) to describe its icosahedral symmetry and distinguish it from other less-symmetric 80-vertex fullerenes. It is one of only four fullerenes found by Deza, Deza & Grishukhin (1998) to have a skeleton that can be isometrically embeddable into an L1 space.
Chamfered icosahedron
| Chamfered icosahedron | |
|---|---|
| |
| Conway notation | cI = t3daI |
| Faces | 20 triangles 30 hexagons |
| Edges | 120 (2 types) |
| Vertices | 72 (2 types) |
| Vertex configuration | (24) 3.6.6 (12) 6.6.6 |
| Symmetry | Ih, [5,3], (*532) |
| Dual polyhedron | triakis icosidodecahedron |
| Properties | convex |
In geometry, the chamfered icosahedron is a convex polyhedron constructed from the rhombic triacontahedron by truncating the 20 order-3 vertices. The hexagonal faces can be made equilateral but not regular.
See also
References
- Goldberg, Michael (1937). "A class of multi-symmetric polyhedra". Tohoku Mathematical Journal.
- Joseph D. Clinton, Clinton’s Equal Central Angle Conjecture
- Hart, George (2012). "Goldberg Polyhedra". In Senechal, Marjorie. Shaping Space (2nd ed.). Springer. pp. 125–138. doi:10.1007/978-0-387-92714-5_9.
- Hart, George (June 18, 2013). "Mathematical Impressions: Goldberg Polyhedra". Simons Science News.
- Antoine Deza, Michel Deza, Viatcheslav Grishukhin, Fullerenes and coordination polyhedra versus half-cube embeddings, 1998 PDF (p. 72 Fig. 26. Chamfered tetrahedron)
- Deza, A.; Deza, M.; Grishukhin, V. (1998), "Fullerenes and coordination polyhedra versus half-cube embeddings", Discrete Mathematics, 192 (1): 41–80, doi:10.1016/S0012-365X(98)00065-X, archived from the original on 2007-02-06.
External links
- Chamfered Tetrahedron
- Chamfered Solids
- Vertex- and edge-truncation of the Platonic and Archimedean solids leading to vertex-transitive polyhedra Livio Zefiro
- VRML polyhedral generator (Conway polyhedron notation)
- VRML model Chamfered cube
- 3.2.7. Systematic numbering for (C80-Ih) [5,6] fullerene
- Fullerene C80
- How to make a chamfered cube