There can be seven origins defined in CCP,^[3] where n = {1, 2, 3, …}:

• Origin 1: offset 0,0,0, radius ${\displaystyle {\sqrt {2n}}}$ 
• Origin 2: offset 1/2,1/2,0, radius ${\displaystyle {\tfrac {1}{2}}{\sqrt {2+4n}}}$ 
• Origin 3: offset 1/3,1/3,2/3, radius ${\displaystyle {\tfrac {1}{3}}{\sqrt {6(n+1)}}}$ 
• Origin 3*: offset 1/3,1/3,1/3, radius ${\displaystyle {\tfrac {1}{3}}{\sqrt {3+6n}}}$ 
• Origin 4: offset 1/2,1/2,1/2, radius ${\displaystyle {\tfrac {1}{2}}{\sqrt {3+8(n-1)}}}$ 
• Origin 5: offset 0,0,1/2, radius ${\displaystyle {\tfrac {1}{2}}{\sqrt {1+4n}}}$ 
• Origin 6: offset 1,0,0, radius ${\displaystyle {\sqrt {1+2(n-1)}}}$ 

Depending on the origin of the sweeping, a different shape and resulting polyhedron are obtained.

Some Waterman polyhedra create Platonic solids and Archimedean solids. For this comparison of Waterman polyhedra they are normalized, e.g. W2 O1 has a different size or volume than W1 O6, but has the same form as an octahedron.^{[citation needed]}

Platonic solids edit

• Tetrahedron: W1 O3*, W2 O3*, W1 O3, W1 O4
• Octahedron: W2 O1, W1 O6
• Cube: W2 O6
• Icosahedron and dodecahedron have no representation as Waterman polyhedra.^{[citation needed]}

Archimedean solids edit

• Cuboctahedron: W1 O1, W4 O1
• Truncated octahedron: W10 O1
• Truncated tetrahedron: W4 O3, W2 O4
• The other Archimedean solids have no representation as Waterman polyhedra.^{[citation needed]}

The W7 O1 might be mistaken for a truncated cuboctahedron, as well W3 O1 = W12 O1 mistaken for a rhombicuboctahedron, but those Waterman polyhedra have two edge lengths and therefore do not qualify as Archimedean solids.^{[citation needed]}

Generalized Waterman polyhedra are defined as the convex hull derived from the point set of any spherical extraction from a regular lattice.^{[citation needed]}

Included is a detailed analysis of the following 10 lattices – bcc, cuboctahedron, diamond, fcc, hcp, truncated octahedron, rhombic dodecahedron, simple cubic, truncated tet tet, truncated tet truncated octahedron cuboctahedron.^{[citation needed]}

Each of the 10 lattices were examined to isolate those particular origin points that manifested a unique polyhedron, as well as possessing some minimal symmetry requirement.^{[citation needed]} From a viable origin point, within a lattice, there exists an unlimited series of polyhedra.^{[citation needed]} Given its proper sweep interval, then there is a one-to-one correspondence between each integer value and a generalized Waterman polyhedron.^{[citation needed]}

• Steve Waterman's Homepage
• Waterman Polyhedra Java applet by Mark Newbold
• Maurice Starck's write-up
• hand-made models by Magnus Wenninger
• write-up by Paul Bourke
• on-line generator by Paul Bourke
• program to make Waterman polyhedron by Adrian Rossiter in Antiprism
• Waterman projection and write up by Carlos Furiti
• rotating globe by Izidor Hafner
• real time winds and temperature on Waterman projection by Cameron Beccario
• Solar Termination (Waterman) by Mike Bostock
• interactive Waterman butterfly map by Jason Davies
• write-up by Maurice Starck
• first 1000 Waterman polyhedra and sphere clusters by Nemo Thorx
• OEIS sequence A119870 (Number of vertices of the root-n Waterman polyhedron)
• Steve Waterman's Waterman polyhedron (WP)
• Generalized Waterman polyhedron by Ed Pegg jr of Wolfram
• various Waterman sphere clusters by Ed Pegg jr of Wolfram
• app to make 4d waterman polyhedron in Great Stella by Rob Webb
• Waterman polyhedron app in Matlab needs a workaround as shown on the following reference page
• Waterman polyhedron in Mupad