Möbius–Kantor polygon

Möbius–Kantor polygon
Orthographic projection

shown here with 4 red and 4 blue 3-edge triangles.
Shephard symbol3(24)3
Schläfli symbol3{3}3
Coxeter diagram
Edges8 3{}
Vertices8
Petrie polygonOctagon
Shephard group3[3]3, order 24
Dual polyhedronSelf-dual
PropertiesRegular

In geometry, the Möbius–Kantor polygon is a regular complex polygon 3{3}3, , in . 3{3}3 has 8 vertices, and 8 edges. It is self-dual. Every vertex is shared by 3 triangular edges.[1] Coxeter named it a Möbius–Kantor polygon for sharing the complex configuration structure as the Möbius–Kantor configuration, (83).[2]

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

Coordinates

The 8 vertex coordinates of this polygon can be given in , as:

(ω,−1,0)(0,ω,−ω2)(ω2,−1,0)(−1,0,1)
(−ω,0,1)(0,ω2,−ω)(−ω2,0,1)(1,−1,0)

where .

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 [8] [12/3]

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.[3]

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 3[3]3.

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, Regular Complex Polytopes, p. 109

References

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