| content |
Contents |
Description
The diagram can also represent polytopes by adding rings (circles) around nodes. Every diagram needs at least one active node to represent a polytope.
The rings express information on whether a generating point is on or off the mirror. Specifically a mirror is active (creates reflections) only when points are off the mirror, so adding a ring means a point is off the mirror and creates a reflection.
Hollow rings (holes) are also used. A polytope with an alternation operator applied has all the ringed nodes replaced by holes. If all the nodes are holes, the figure is considered a snub.
Edges are labeled with an integer n (or sometimes more generally a rational number p/q) representing a dihedral angle of 180/n. If an edge is unlabeled, it is assumed to be 3. If n=2 the angle is 90 degrees and the mirrors have no interaction, and the edge can be omitted. Two parallel mirrors can be marked with "∞".
In principle, n mirrors can be represented by a complete graph in which all n*(n-1)/2 edges are drawn. In practice interesting configurations of mirrors will include a number of right angles, and the corresponding edges can be omitted.
Polytopes and tessellations can be generating using these mirrors and a single generator point. Mirror images create new points as reflections. Edges can be created between points and a mirror image. Faces can be constructed by cycles of edges created, etc.
Examples
- A single node represents a single mirror. This is called group A1. If ringed this creates a line segment perpendicular to the mirror, represented as {}.
- Two unattached nodes represent two perpendicular mirrors. If both nodes are ringed, a rectangle can be created, or a square if the point is equal distance from both mirrors.
- Two nodes attached by an order-n edge can creates an n-gon if the point is on one mirror, and a 2n-gon if the point is off both mirrors. This forms the I1(n) group.
- Two parallel mirrors can represent an infinite polygon I1(∞) group, also called I~1.
- Three mirrors in a triangle form images seen in a traditional kaleidoscope and be represented by 3 nodes connected in a triangle. Repeating examples will have edges labeled as (3 3 3), (2 4 4), (2 3 6), although the last two can be drawn in a line with the 2 edge ignored. These will generate uniform tilings.
- Three mirrors can generate uniform polyhedrons, including rational numbers is the set of Schwarz triangles.
- Three mirrors with one perpendicular to the other two can form the uniform prisms.
In general all regular n-polytopes, represented by Schläfli symbol symbol {p,q,r,...} can have their fundamental domains represented by a set of n mirrors and a related in a Coxeter-Dynkin diagram in a line of nodes and edges labeled by p,q,r...
Finite Coxeter groups
Families of convex uniform polytopes are defined by Coxeter groups.
Notes:
- Three different symbols are given for the same groups - as a letter/number, as a bracketed set of numbers, and as the Coxeter diagram.
- The bifurcated Dn groups are also given an h[] notation representing the fact it is half or alternated version of the regular Cn groups.
- The bifurcated Dn and En groups are also labeled by a superscript form [3a,b,c where a,b,c are the number of segments in each of the 3 branches.
| n | A1+ | C2+ | D3+ | E4-8 | F4 | H2-4 | I2(p) |
|---|---|---|---|---|---|---|---|
| 1 | A1=[] |
||||||
| 2 | A2=[3] |
C2=[4] |
H2=[5] |
I2(p)=[p]
|
|||
| 3 | A3=[32
|
C3=[4,3] |
D3=A3=[30,1,1
|
H3=[5,3] |
|||
| 4 | A4=[33
|
C4=[4,32
|
D4=h[4,3,3]=[31,1,1
|
E4=A4=[30,2,1
|
F4=[3,4,3] |
H4=[5,3,3] |
|
| 5 | A5=[34
|
C5=[4,33
|
D5=h[4,33=[32,1,1
|
E5=B5=[31,2,1
|
|||
| 6 | A6=[35
|
C6=[4,34
|
D6=h[4,34=[33,1,1
|
E6=[32,2,1
|
|||
| 7 | A7=[36
|
C7=[4,35
|
D7=h[4,35=[34,1,1
|
E7=[33,2,1
|
|||
| 8 | A8=[37
|
C8=[4,36
|
D8=h[4,36=[35,1,1
|
E8=[34,2,1
|
|||
| 9 | A9=[38
|
C9=[4,37
|
D9=h[4,37=[36,1,1
|
||||
| 10+ | .. | .. | .. |
- An forms the simplex polytope family.
- Dn is the family of demihypercubes, beginning at n=4 with the 16-cell, and n=5 with the demipenteract. (Also named Bn)
- Bn or Cn forms the hypercube/orthoplex polytope family.
- I1n forms the regular polygons. (Also named D2n)
- E6,E7,E8 are the generators of the Gosset Semiregular polytopes
- F4 is the 24-cell polychoron family.
- H3 is the dodecahedron/icosahedron polyhedron family. (Also named G3)
- H4 is the 120-cell/600-cell polychoron family. (Also named G4)
Infinite Coxeter groups
Families of convex uniform tessellations are defined by Coxeter groups.
Note:
- A~n-1 is a cyclic group. (Also named Pn)
- B~n-1 forms the hypercube regular tessellation family {4,3,....,4} family. (Also named Rn)
- C~n-1 forms the alternated hypercubic tessellation family. (Also named Sn) Also labeled by a h[] notation as a half of the regular one.
- D~n-1 (Also named Qn) Also labeled by a q[] notation as a quarter of the regular one.
- E~6,E~7,E~8,E~9 are Gosset tessellations. (Also named T7,T8,T9,T10) T10 exists in hyperbolic space. Also labeled by a superscript form [3a,b,c where a,b,c are the number of segments in each of the 3 branches.
- F~4 is the 24-cell {3,4,3,3} regular tessellation. (Also named U5)
- H~2 is the Hexagonal tiling. (Also named V3)
- I~1 is two parallel mirrors. (Also named W2)
| n | A~2+ | B~2+ | C~3+ | D~4+ | E~6-9 | F~4 | H~2 | I~1 |
|---|---|---|---|---|---|---|---|---|
| 1 | I~1=[∞]
|
|||||||
| 2 | A~2=h[6,3]
|
B~2=[4,4]
|
H~2=[6,3]
|
|||||
| 3 | A~3=q[4,3,4]
|
B~3=[4,3,4]
|
C~3=h[4,3,4]
|
|||||
| 4 | A~4
|
B4=[4,32,4]
|
C~4=h[4,32,4]
|
D~4=q[4,32,4]
|
F~4=[3,4,3,3]
|
|||
| 5 | A~5
|
B~5=[4,33,4]
|
C~5=h[4,33,4]
|
D~5=q[4,33,4]
|
||||
| 6 | A~6
|
B~6=[4,34,4]
|
C~6=h[4,34,4]
|
D~6=q[4,34,4]
|
E~6=[32,2,2
|
|||
| 7 | A~7
|
B~7=[4,35,4] |
