Misplaced Pages

Möbius–Kantor polygon

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
Möbius–Kantor polygon

The 8 3-edges (4 in red, 4 in green) projected symmetrically into 8 vertices of a square antiprism.
Shephard symbol 3(24)3
Schläfli symbol 3{3}3
Coxeter diagram
Edges 8 3{}
Vertices 8
Petrie polygon Octagon
Shephard group 33, order 24
Dual polyhedron Self-dual
Properties Regular

In geometry, the Möbius–Kantor polygon is a regular complex polygon 3{3}3, , in C 2 {\displaystyle \mathbb {C} ^{2}} . 3{3}3 has 8 vertices, and 8 edges. It is self-dual. Every vertex is shared by 3 triangular edges. Coxeter named it a Möbius–Kantor polygon for sharing the complex configuration structure as the Möbius–Kantor configuration, (83).

Discovered by G.C. Shephard in 1952, he represented it as 3(24)3, with its symmetry, Coxeter called as 33, isomorphic to the binary tetrahedral group, order 24.

Coordinates

The 8 vertex coordinates of this polygon can be given in C 3 {\displaystyle \mathbb {C} ^{3}} , as:

(ω,−1,0) (0,ω,−ω) (ω,−1,0) (−1,0,1)
(−ω,0,1) (0,ω,−ω) (−ω,0,1) (1,−1,0)

where ω = 1 + i 3 2 {\displaystyle \omega ={\tfrac {-1+i{\sqrt {3}}}{2}}} .

As a configuration

The configuration matrix for 3{3}3 is: [ 8 3 3 8 ] {\displaystyle \left}

Its structure can be represented as a hypergraph, connecting 8 nodes by 8 3-node-set hyperedges.

Real representation

It has a real representation as the 16-cell, , in 4-dimensional space, sharing the same 8 vertices. The 24 edges in the 16-cell are seen in the Möbius–Kantor polygon when the 8 triangular edges are drawn as 3-separate edges. The triangles are represented 2 sets of 4 red or blue outlines. The B4 projections are given in two different symmetry orientations between the two color sets.

orthographic projections
Plane B4 F4
Graph
Symmetry

The 3{3}3 polygon can be seen in a regular skew polyhedral net inside a 16-cell, with 8 vertices, 24 edges, 16 of its 32 faces. Alternate yellow triangular faces, interpreted as 3-edges, make two copies of the 3{3}3 polygon.

Related polytopes


This graph shows the two alternated polygons as a compound in red and blue 3{3}3 in dual positions.
3{6}2, or , with 24 vertices in black, and 16 3-edges colored in 2 sets of 3-edges in red and blue.

It can also be seen as an alternation of , represented as . has 16 vertices, and 24 edges. A compound of two, in dual positions, and , can be represented as , contains all 16 vertices of .

The truncation , is the same as the regular polygon, 3{6}2, . Its edge-diagram is the cayley diagram for 33.

The regular Hessian polyhedron 3{3}3{3}3, has this polygon as a facet and vertex figure.

Notes

  1. Coxeter and Shephard, 1991, p.30 and p.47
  2. Coxeter and Shephard, 1992
  3. Coxeter, Complex Regular polytopes, p.117, 132
  4. Coxeter, Regular Complex Polytopes, p. 109

References

  • Shephard, G.C.; Regular complex polytopes, Proc. London math. Soc. Series 3, Vol 2, (1952), pp 82–97.
  • Coxeter, H. S. M. and Moser, W. O. J.; Generators and Relations for Discrete Groups (1965), esp pp 67–80.
  • Coxeter, H. S. M.; Regular Complex Polytopes, Cambridge University Press, (1974), second edition (1991).
  • Coxeter, H. S. M. and Shephard, G.C.; Portraits of a family of complex polytopes, Leonardo Vol 25, No 3/4, (1992), pp 239–244
Categories: