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Trapezohedron

An-trapezohedron, also called an antidipyramid, antibipyramid, or deltohedron (not to be confused with adeltahedron), is a solid composed of interleaved symmetric quadrilateralkites, half of which meet in a top vertex and half in a bottom vertex. A regular-trapezohedron can be constructed from two sets of points placed around two regular-gons displaced relative to one another in the direction perpendicular to the plane of the polygons and rotated relative to one another by an angle of 180 degrees/n degrees. Two additional equally spaced points are then added along symmetry axis of the polygons, one above the top circle of points and the other below the bottom one. The trapezohedron is then theconvex hull of these 2(n+1) points. The top faces are constructed from of adjacent points in the upper circle, the corresponding point between them in the lower circle, and the upper vertex, and the bottom faces analogously but with upper/lower reversed. Unfortunately, the name "trapezohedron" is not particularly well chosen since the faces can be seen to benottrapezoids but ratherkites.

The-trapezohedron has 2(n+1) vertices, edges (half short and half long), and faces.

The 3-trapezohedron (trigonal trapezohedron) is arhombohedron having all six faces congruent. A special case is thecube (oriented along a space diagonal), corresponding to the dual of the equilateral 3-antiprism (i.e., theoctahedron).

A 4-trapezohedron (tetragonal trapezohedron) appears in the upper left as one of the polyhedral "stars" in M. C. Escher's 1948 wood engraving "Stars" (Forty 2003, Plate 43).

The trapezohedra areisohedra.

Thecanonical-trapezohedron is thedual polyhedra of thecanonical (i.e., equilateral)-antiprism. In particular, thecanonical-trapezohedron can be constructed from an-antiprism as theconvex hull of the set of points obtained by extending the centroids of the lateral triangular faces by a factor

(1)

and the centroids of the top and bottom regular-gons by a factor of

(2)

Alternately, the canonical-trapezoid of unitmidradius can be constructed from rotated circles of points at radius

(3)

at heights

h=+/-(sqrt(4-sec^2(pi/(2n))))/(4+8cos(pi/n))

(4)

with apices at vertical positions

z=+/-1/4cos(pi/(2n))cot(pi/(2n))csc((3pi)/(2n))sqrt(4-sec^2(pi/(2n))).

(5)

The kites forming the faces of a canonical-trapezohedron have three equal angles nearest of the central plane

(6)

and angles at the apices of

theta_2=cos^(-1)(2-3cos(pi/n)+3cos((2pi)/n)-cos((3pi)/n)).

(7)

Nets for canonical-trapezohedra are illustrated above for n=3 to 8.

For a canonical-trapezohedron normalized to have short edge length 1, the long edge length, (half-)height,inradius,midradius,surface area, andvolume are given by

			(8)
			(9)
			(10)
			(11)
			(12)
			(13)

Theskeleton of a trapezohedron may be termed atrapezohedralgraph.

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References

Cundy, H. and Rollett, A.Mathematical Models, 3rd ed. Stradbroke, England: Tarquin Pub., p. 117, 1989.Escher, M. C. "Stars." Wood engraving. 1948.http://www.mcescher.com/Gallery/back-bmp/LW359.jpg.Forty, S.M.C. Escher. Cobham, England: TAJ Books, 2003.Pedagoguery Software.Poly.http://www.peda.com/poly/.Webb, R. "Prisms, Antiprisms, and their Duals."http://www.software3d.com/Prisms.html.

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Trapezohedron

Cite this as:

Weisstein, Eric W. "Trapezohedron." FromMathWorld--A Wolfram Resource.https://mathworld.wolfram.com/Trapezohedron.html

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