Conway polyhedron notation

Conway polyhedron notation is used to describe polyhedra based on a seed polyhedron modified by various operations.

The seed polyhedra are the Platonic solids, represented by their first letter of their name (T,O,C,I,D); the prisms (Pn), antiprisms (An) and pyramids (Yn). Any convex polyhedron can serve as a seed, as long as the operations can be executed on it.

John Conway extended the idea of using operators, like truncation defined by Kepler, to build related polyhedra of the same symmetry. His descriptive operators can generate all the Archimedean solids and Catalan solids from regular seeds. Applied in a series, these operators allow many higher order polyhedra to be generated.

Contents

Operations on polyhedra

Elements are given from the seed (v,e,f) to the new forms, assuming seed is a convex polyhedron: (a topological sphere, Euler characteristic=2)

Operator Name Alternate
construction
vertices edges faces Description
Seed v e f Seed form
r Reflect
(Hart)
v e f Mirror image for chiral forms
d dual f e v dual of the seed polyhedron - each vertex creates a new face
a ambo e 2e 2+e The edges are new vertices, while old vertices disappear. (rectify)
j join da e+2 2e e The seed is augmented with pyramids at a height high enough so that 2 coplanar triangles from 2 different pyramids share an edge.
t truncate dkd 2e 3e e+2 truncate all vertices.
-- -- dk 2e 3e e+2 Dual of kis, (bitruncation)
-- -- kd e+2 3e 2e Kis of dual
k kis dtd e+2 3e 2e raises a pyramid on each face.
c chamfer e+v 4e 2e+f New hexagonal faces are added in place of edges.
- - dc 2e+f 4e e+v
e expand aa 2e 4e 2e+2 Each vertex creates a new face and each edge creates a new quadrilateral. (cantellate)
o ortho de 2e+2 4e 2e Each n-gon faces are divided into n quadrilaterals.
p propellor
(Hart)
v+2e 4e e+f A face rotation that creates quadrilaterals at vertices (self-dual)
- - dp e+f 4e v+2e
s snub dg 2e 5e 3e+2 "expand and twist" - each vertex creates a new face and each edge creates two new triangles
g gyro ds 3e+2 5e 2e Each n-gon face is divided into n pentagons.
b bevel ta 4e 6e 2e+2 New faces are added in place of edges and vertices, Omnitruncation (Known as cantitruncation in higher polytopes).
m meta db & kj 2e+2 6e 4e n-gon faces are divided into 2n triangles

Special forms

The kis operator has a variation, kn, which only adds pyramids to n-sided faces.
The truncate operator has a variation, tn, which only truncates order-n vertices.

The operators are applied like functions from right to left. For example:

All operations are symmetry-preserving except twisting ones like s and g which lose reflection symmetry.

Examples

The cube can generate all the convex Octahedral symmetry uniform polyhedra. The first row generates the Archimedean solids and the second row the Catalan solids, the second row forms being duals of the first. Comparing each new polyhedron with the cube, each operation can be visually understood. (Two polyhedron forms don't have single operator names given by Conway.)

Cube
"seed"
ambo
(rectify)
truncate bitruncate expand
(cantellate)
bevel
(omnitruncate)
snub

C

aC = djC

tC = dkdC

tdC = dkC

eC = aaC = doC

bC = taC = dmC = dkjC

sC = dgC
dual join kis
(vertex-bisect)
ortho
(edge-bisect)
meta
(full-bisect)
gyro

dC

jC = daC

kdC = dtC

kC = dtdC

oC = deC = daaC

mC = dbC = kjC

gC = dsC

Generating regular seeds

All of the five regular polyhedra can be generated from prismatic generators with zero to two operators:

Extensions to Conway's symbols

The above operations allow all of the semiregular polyhedrons and Catalan solids to be generated from regular polyhedrons. Combined many higher operations can be made, but many interesting higher order polyhedra require new operators to be constructed.

For example, geometric artist George W. Hart created an operation he called a propellor, and another reflect to create mirror images of the rotated forms.

Geometric coordinates of derived forms

In general the seed polyhedron can be considered a tiling of a surface since the operators represent topological operations so the exact geometric positions of the vertices of the derived forms are not defined in general. A convex regular polyhedron seed can be considered a tiling on a sphere, and so the derived polyhedron can equally be assumed to be positioned on the surface of a sphere. Similar a regular tiling on a plane, such as a hexagonal tiling can be a seed tiling for derived tilings. Nonconvex polyhedra can become seeds if a related topological surface is defined to constrain the positions of the vertices. For example torus-shaped polyhedra can derive other polyhedra with point on the same torus surface.

Example: A dodecahedron seed as a spherical tiling

D

tD

aD

tdD

eD

teD

sD

dD

dteD
Example: An Euclidean hexagonal tiling seed (H)

H

tH

aH

tdH = H

eH

teH

sH

dH

dtH

daH

dtdH = dH

deH

dteH

dsH
Example: A transparent Tetrahedron seed (T)

T

tT

aT

tdT

eT

bT

sT

dT

dtT

jT

kT

oT

mT

gT
Example: A hyperbolic heptagonal tiling seed
{7,3}
"seed"
truncate ambo
(rectify)
bitruncate expand
(cantellate)
bevel
(omnitruncate)
snub
dual join kis
(vertex-bisect)
ortho
(edge-bisect)
meta
(full-bisect)
gyro

Other polyhedra

Iterating operators on simple forms can produce progressively larger polyhedra, maintaining the fundamental symmetry of the seed element. The vertices are assumed to be on the same spherical radius. Some generated forms can exist as spherical tilings, but fail to produce polyhedra with planar faces.

Tetrahedral symmetry

Octahedral symmetry

Icosahedral symmetry

Rhombic:

Triangular:

Dual triangular:

Triangular chiral:

Dual triangular chiral:

See also

References

External links and references