Conway polyhedra

Groups of Symmetry edit

All of the solids and planar tilings below have point groups (as well as global rotation and translation groups, respectively), which are one of the following forms:

These are the dihedral groups of order 3, 4, 5, 6, and are formed by the semidirect product of incremental rotations and reflections. So $D_{3}\cong C_{2}\rtimes C_{3},\dots ,D_{6}\cong C_{2}\rtimes C_{6}$ by means of ${\text{ref}}\circ {\text{rot}}\circ {\text{ref}}^{-1}={\text{rot}}^{-1}$ . ^[1] Each right triangle is a fundamental domain which can be mapped to any other right triangle.

Tetrahedral symmetry edit

t6dtT
atT
tatT
stT
XT (10e)
dXT (10e)
m3T
b3T

Octahedral symmetry edit

daC (2e)
cC (4e) *
dcC (4e) *
cO (4e)
akC (6e) *
dakC (6e)
m3C (6e)
m3O (6e)
b3C (6e)
b3O (6e)
atC (6e)
qC (6e)
edaC (8e)
dktO=tkC (9e)
taaC (12e) *
XO (10e)
XC (10e)
dXO (10e)
dXC (10e)
L₀C
cdkC (12e)
ccC (16e)
tkdkC (18e)
tatO (18e)
tatC (18e)
l6l8taC (22e)
ccdkC (48e)
wrwC (49e)
cccC (64e)
tktkC (81e)

Chiral

wC (7e)
saC (10e)
gaC (10e)
saC (10e)
stO (15e)
stC (15e)

Icosahedral symmetry edit

kD = daD (2e)
kD (3e) *
dkD=tI (3e) *
cI (4e) *
t5daD=cD (4e) *
dcI (4e) *
dakD (6e) *
atD (6e)
atI=akD (6e) *
qD (6e)
m3D (6e)
m3I (6e)
b3D (6e)
b3I (6e)
edaD (8e) *
tkdD (9e) *
gaD (10e) *
XI (10e)
XD (10e)
dXI (10e)
dXD (10e)
teD (12e) *
cdkD (12e)
m3aI (12e)
tatI = takD (18e)
tatD (18e)
atkD (18e)
m3tD (18e)
qtI = t5t6otI (18e)
dqtI = k5k6etI (18e)
actI (24e)
kdktI (27e)
tktI (27e)
dctkD (36e)
ctkD (36e)
k6k5tI
kt5daD

Chiral

dsD (5e)
sD (5e)
wD (7e)
k5sD (7e)
saD (10e)
saD (10e)
g3D (11e)
s3D (11e)
g3I (11e)
s3I (11e)
stI (15e)
stD (15e)
wtI (21e)
k5k6stI (21e)

Dihedral symmetry edit

t4daA4=cA4
t4daA4=cA4 (side)
t4daA4=cA4 (top)
tA4
tA5
eP3 = aaP3
eA4 = aaA4

Toroidal symmetry edit

Torioidal tilings exist on the flat torus on the surface of a duocylinder in four dimensions but can be projected down to three dimensions as an ordinary torus. These tilings are topologically similar subsets of the Euclidean plane tilings.

A 1x1 regular square torus, {4,4}_1,0
A regular 4x4 square torus, {4,4}_4,0
tQ24×12 projected to torus
taQ24×12 projected to torus
actQ24×8 projected to torus
tH24×12 projected to torus
taH24×8 projected to torus
kH24×12 projected to torus

Euclidean square symmetry edit

tQ
cQ
akQ

Euclidean triangular symmetry edit

tH
cΔ
cH
ctH
dakH
aaaH
aaaH, equilateral (close to 3-4-6-12 tiling and 3.4.6.4; 3².4.3.4)

Canonicalization edit

aaaH = aeH = eaH
Similar to 3.4.6.4; 3²4.3.4	(triangles smaller than midpoint)	Midpoint-connecting 3.4.6.4	Expanding (3.6)²

atQ = akQ
Using equilateral triangles (but not regular octagons)	Midpoint-connecting 4.8² (using regular octagons)

Special Tilings (Expand and Ortho) edit

Below are the expand and ortho results of a basis of planar tilings: 11 uniform tilings, 4 semiregular tilings, one 4-uniform tiling ('gem' tiling), and one 92-uniform tiling with 14 distinct planigons ('take all' tiling). To expand a uniform tiling, take the midpoints of all regular polygons (ambo), take the midpoints of the resulting regular polygons, take the midpoints of the vertex-figure polygons (in the gaps), and alternate between shrunk regular polygons and shrunk planigons connected by vertices in checkerboard fashion (since e=aa).^[2]^[3] There will be new gap polygons in the expand tilings of lesser significance. This operation tends to form rings around larger regular polygons, with smaller regular polygons acting as ring borders. To ortho a uniform tiling, merely superimpose its dual. Note that '—' stands for elongation, which is not officially a Conway operation.

Expand and Ortho Versions of a Basis of Planar Tilings
eΔ	eQ	eH	eaH	etH	eeH=eeΔ

oΔ	oQ	oH	oaH	otH	oeH=oeΔ

ebH=etaH	esQ	e—Q	esH	etQ	e[3.4.3.12; 3.12²]

obH=otaH	osQ	o—Q	osH	otQ	o[3.4.3.12; 3.12²]

e[3².4.12; 3⁶]	e[3.4².6; (3.6)²]₁	e[3².6²; (3.6)²]	e[3².4.12; 3.12²; 3².4.3.4; 3⁶]	e[3⁶; 3³.4²; 3².4.3.4; 3⁴.6; 3.4².6; 3².4.12; 4.6.12]	e[92-uniform tiling]

o[3².4.12; 3⁶]	o[3.4².6; (3.6)²]₁	o[3².6²; (3.6)²]	o[3².4.12; 3.12²; 3².4.3.4; 3⁶]	o[3⁶; 3³.4²; 3².4.3.4; 3⁴.6; 3.4².6; 3².4.12; 4.6.12]	o[92-uniform tiling]

Note that the canonically expanded triangular and hexagonal tilings are not identical to the rhombitrihexagonal tiling (more appropriately called the rectrihexagonal tiling), but have thin rectangles of ratio $w=h{\sqrt {3}}$ instead of (regular) squares.

↑ Armstrong, M. A. (Mark Anthony) (1988) Groups and symmetry, Category:New York: Springer-Verlag ISBN: 0387966757. OCLC: 17354658.
↑ "Chapter 21: Naming the Archimedean and Catalan polyhedra and Tilings" in (2008) The Symmetries of Things ISBN: 978-1-56881-220-5.
↑ Anselm Levskaya. polyHédronisme.

[1] Armstrong, M. A. (Mark Anthony) (1988) Groups and symmetry, Category:New York: Springer-Verlag ISBN: 0387966757. OCLC: 17354658.

[SoT2-2] "Chapter 21: Naming the Archimedean and Catalan polyhedra and Tilings" in (2008) The Symmetries of Things ISBN: 978-1-56881-220-5.

[Levskaya2-3] Anselm Levskaya. polyHédronisme.

[1]

[2]

[3]