Final stellation of the icosahedron Information
Final stellation of the icosahedron  

Two symmetric orthographic projections  
Symmetry group  icosahedral (I_{h})  
Type  Stellated icosahedron, 8th of 59  
Symbols  Du Val H Wenninger: W_{42}  
Elements (As a star polyhedron) 
F = 20, E = 90 V = 60 (χ = −10)  
Elements (As a simple polyhedron) 
F = 180, E = 270, V = 92 (χ = 2)  
Properties (As a star polyhedron) 
Vertextransitive, facetransitive  

In geometry, the complete or final stellation of the icosahedron^{ [1]}^{ [2]} is the outermost stellation of the icosahedron, and is "complete" and "final" because it includes all of the cells in the icosahedron's stellation diagram. That is, every three intersecting face planes of the icosahedral core intersect either on a vertex of this polyhedron, or inside of it.
This polyhedron is the seventeenth stellation of the icosahedron, and given as Wenninger model index 42.
As a geometrical figure, it has two interpretations, described below:
 As an irregular star (selfintersecting) polyhedron with 20 identical selfintersecting enneagrammic faces, 90 edges, 60 vertices.
 As a simple polyhedron with 180 triangular faces (60 isosceles, 120 scalene), 270 edges, and 92 vertices. This interpretation is useful for polyhedron model building.
Johannes Kepler researched stellations that create regular star polyhedra (the KeplerPoinsot polyhedra) in 1619, but the complete icosahedron, with irregular faces, was first studied in 1900 by Max Brückner.
History
Brückner's model (Taf. XI, Fig. 14, 1900)^{ [3]} 
The echidna 
 1619: In Harmonices Mundi, Johannes Kepler first applied the stellation process, recognizing the small stellated dodecahedron and great stellated dodecahedron as regular polyhedra.^{ [4]}
 1809: Louis Poinsot rediscovered Kepler's polyhedra and two more, the great icosahedron and great dodecahedron as regular star polyhedra, now called the Kepler–Poinsot polyhedra.^{ [5]}
 1812: AugustinLouis Cauchy made a further enumeration of star polyhedra, proving there are only 4 regular star polyhedra.^{ [6]}
 1900: Max Brückner extended the stellation theory beyond regular forms, and identified ten stellations of the icosahedron, including the complete stellation.^{ [3]}
 1924: A.H. Wheeler in 1924 published a list of 20 stellation forms (22 including reflective copies), also including the complete stellation.^{ [7]}
 1938: In their 1938 book The Fifty Nine Icosahedra, H. S. M. Coxeter, P. Du Val, H. T. Flather and J. F. Petrie stated a set of stellation rules for the regular icosahedron and gave a systematic enumeration of the fiftynine stellations which conform to those rules. The complete stellation is referenced as the eighth in the book.
 1974: In Wenninger's 1974 book Polyhedron Models, the final stellation of the icosahedron is included as the 17th model of stellated icosahedra with index number W_{42}.
 1995: Andrew Hume named it in his Netlib polyhedral database as the echidnahedron^{ [8]} (the echidna, or spiny anteater is a small mammal that is covered with coarse hair and spines and which curls up in a ball to protect itself).
Interpretations
As a stellation
The stellation of a polyhedron extends the faces of a polyhedron into infinite planes and generates a new polyhedron that is bounded by these planes as faces and the intersections of these planes as edges. The Fifty Nine Icosahedra enumerates the stellations of the regular icosahedron, according to a set of rules put forward by J. C. P. Miller, including the complete stellation. The Du Val symbol of the complete stellation is H, because it includes all cells in the stellation diagram up to and including the outermost "h" layer.^{ [6]}
As a simple polyhedron
A polyhedral model can be constructed by 12 sets of faces, each folded into a group of five pyramids. 
As a simple, visible surface polyhedron, the outward form of the final stellation is composed of 180 triangular faces, which are the outermost triangular regions in the stellation diagram. These join along 270 edges, which in turn meet at 92 vertices, with an Euler characteristic of 2.^{ [9]}
The 92 vertices lie on the surfaces of three concentric spheres. The innermost group of 20 vertices form the vertices of a regular dodecahedron; the next layer of 12 form the vertices of a regular icosahedron; and the outer layer of 60 form the vertices of a nonuniform truncated icosahedron. The radii of these spheres are in the ratio^{ [10]}
Inner  Middle  Outer  All three 

20 vertices  12 vertices  60 vertices  92 vertices 
Dodecahedron 
Icosahedron 
Nonuniform truncated icosahedron 
Complete icosahedron 
When regarded as a threedimensional solid object with edge lengths a, φa, φ^{2}a and φ^{2}a√2 (where φ is the golden ratio) the complete icosahedron has surface area^{ [10]}
and volume^{ [10]}
As a star polyhedron
Twenty 9⁄4 polygon faces (one face is drawn yellow with 9 vertices labeled.) 
2isogonal 9⁄4 faces 
The complete stellation can also be seen as a selfintersecting star polyhedron having 20 faces corresponding to the 20 faces of the underlying icosahedron. Each face is an irregular 9/4 star polygon, or enneagram.^{ [6]} Since three faces meet at each vertex it has 20 × 9 / 3 = 60 vertices (these are the outermost layer of visible vertices and form the tips of the "spines") and 20 × 9 / 2 = 90 edges (each edge of the star polyhedron includes and connects two of the 180 visible edges).
When regarded as a star icosahedron, the complete stellation is a noble polyhedron, because it is both isohedral (facetransitive) and isogonal (vertextransitive).
See also
Notes
 ^ Coxeter et al. (1938), pp 30–31
 ^ Wenninger, Polyhedron Models, p. 65.
 ^ ^{a} ^{b} Brückner, Max (1900)
 ^ Weisstein, Eric W. "KeplerPoinsot Solid". MathWorld.
 ^ Louis Poinsot, Memoire sur les polygones et polyèdres. J. de l'École Polytechnique 9, pp. 16–48, 1810.
 ^ ^{a} ^{b} ^{c} Cromwell (1999) (p. 259)
 ^ Wheeler (1924)

^ The name echidnahedron may be credited to Andrew Hume,
developer of the
netlib
polyhedron database:
"... and some odd solids including the echidnahedron (my name; its actually the final stellation of the icosahedron)." geometry.research; "polyhedra database"; August 30, 1995, 12:00 am.
 ^ Echidnahedron Archived 20081007 at the Wayback Machine at polyhedra.org
 ^ ^{a} ^{b} ^{c} Weisstein, Eric W. "Echidnahedron". MathWorld.
References
 Brückner, Max (1900). Vielecke und Vielflache: Theorie und Geschichte. Leipzig: B.G. Treubner. ISBN 9781418165901. (in German) WorldCat English: Polygons and Polyhedra: Theory and History. Photographs of models: Tafel VIII (Plate VIII), etc. High res. scans.
 A. H. Wheeler, Certain forms of the icosahedron and a method for deriving and designating higher polyhedra, Proc. Internat. Math. Congress, Toronto, 1924, Vol. 1, pp 701–708
 H.S.M. Coxeter, Regular Polytopes, (3rd edition, 1973), Dover edition, ISBN 0486614808, 3.6 6.2 Stellating the Platonic solids, pp. 96–104
 Coxeter, Harold Scott MacDonald; Du Val, P.; Flather, H. T.; Petrie, J. F. (1999), The fiftynine icosahedra (3rd ed.), Tarquin, ISBN 9781899618323, MR 0676126 (1st Edn University of Toronto (1938))
 Wenninger, Magnus J., Polyhedron models; Cambridge University Press, 1st Edn (1983), Ppbk (2003). ISBN 9780521098595. (Model 42, p 65, Final stellation of the icosahedron)
 Cromwell, Peter R. (1997). Polyhedra. Cambridge University Press. ISBN 0521664055.
 Jenkins, Gerald, and Magdalen Bear. The Final Stellation of the Icosahedron: An Advanced Mathematical Model to Cut Out and Glue Together. Norfolk, England: Tarquin Publications, 1985. ISBN 9780906212486.
External links
 With instructions for constructing a model of the echidnahedron ( .doc) by Ralph Jones
 Towards stellating the icosahedron and faceting the dodecahedron by Guy Inchbald
 Weisstein, Eric W. "Fifty nine icosahedron stellations". MathWorld.
 Stellations of the icosahedron
 59 Stellations of the Icosahedron
 VRML model: http://www.georgehart.com/virtualpolyhedra/vrml/echidnahedron.wrl
 Netlib: Polyhedron database, model 141
Notable stellations of the icosahedron  
Regular  Uniform duals  Regular compounds  Regular star  Others  
(Convex) icosahedron  Small triambic icosahedron  Medial triambic icosahedron  Great triambic icosahedron  Compound of five octahedra  Compound of five tetrahedra  Compound of ten tetrahedra  Great icosahedron  Excavated dodecahedron  Final stellation 

The stellation process on the icosahedron creates a number of related polyhedra and compounds with icosahedral symmetry. 