Truncated triangular trapezohedron

Truncated triangular trapezohedron
Type	Truncated trapezohedron
Faces	6 pentagons, 2 triangles
Edges	18
Vertices	12
Symmetry group	D3d, [2+,6], (2*3)
Dual polyhedron	Gyroelongated triangular bipyramid
Properties	convex

In geometry, the truncated triangular trapezohedron is the first in an infinite series of truncated trapezohedra. It has 6 pentagon and 2 triangle faces.

Geometry

This polyhedron can be constructed by truncating two opposite vertices of a cube, of a trigonal trapezohedron (a convex polyhedron with six congruent rhombus sides, formed by stretching or shrinking a cube along one of its long diagonals), or of a rhombohedron or parallelepiped (less symmetric polyhedra that still have the same combinatorial structure as a cube). In the case of a cube, or of a trigonal trapezohedron where the two truncated vertices are the ones on the stretching axes, the resulting shape has three-fold rotational symmetry.

Dürer's solid

Melencolia I.

This polyhedron is sometimes called Dürer's solid, from its appearance in Albrecht Dürer's 1514 engraving Melencolia I. The graph formed by its edges and vertices is called the Dürer graph.

The shape of the solid depicted by Dürer is a subject of some academic debate.^[1] According to (Lynch 1982), the hypothesis that the shape is a misdrawn truncated cube was promoted by (Strauss 1972); however most sources agree that it is the truncation of a rhombohedron. Despite this agreement, the exact geometry of this rhombohedron is the subject of several contradictory theories:

• (Richter 1957) claims that the rhombi of the rhombohedron from which this shape is formed have 5:6 as the ratio between their short and long diagonals, from which the acute angles of the rhombi would be approximately 80°.
• (Schröder 1980) and (Lynch 1982) instead conclude that the ratio is √3:2 and that the angle is approximately 82°.
• (MacGillavry 1981) measures features of the drawing and finds that the angle is approximately 79°. She and a later author, Wolf von Engelhardt (see Hideko 2009) argue that this choice of angle comes from its physical occurrence in calcite crystals.
• (Schreiber 1999) argues based on the writings of Dürer that all vertices of Dürer's solid lie on a common sphere, and further claims that the rhombus angles are 72°. (Hideko 2009) lists several other scholars who also favor the 72° theory, beginning with Paul Grodzinski in 1955. He argues that this theory is motivated less by analysis of the actual drawing, and more by aesthetic principles relating to regular pentagons and the golden ratio.
• (Weitzel 2004) analyzes a 1510 sketch by Dürer of the same solid, from which he confirms Schreiber's hypothesis that the shape has a circumsphere but with rhombus angles of approximately 79.5°.
• (Hideko 2009) argues that the shape is intended to depict a solution to the famous geometric problem of doubling the cube, which Dürer also wrote about in 1525. He therefore concludes that (before the corners are cut off) the shape is a cube stretched along its long diagonal. More specifically, he argues that Dürer drew an actual cube, with the long diagonal parallel to the perspective plane, and then enlarged his drawing by some factor in the direction of the long diagonal; the result would be the same as if he had drawn the elongated solid. The enlargement factor that is relevant for doubling the cube is 2^1/3 ≈ 1.253, but Hideko derives a different enlargement factor that fits the drawing better, 1.277, in a more complicated way.
• (Futamura Frantz) classify the proposed solutions to this problem by two parameters: the acute angle and the level of cutting, called the cross ratio. Their estimate of the cross ratio is close to MacGillavry's, and has a numerical value close to the golden ratio. Based on this they posit that the acute angle is [math]\displaystyle{ 2\arctan(\varphi/2)\approx 78^\circ }[/math] and that the cross ratio is exactly [math]\displaystyle{ \varphi }[/math].

See also

• Chamfered tetrahedron, another shape formed by truncating a subset of the vertices of a cube

Notes

References

• Lynch, Terence (1982), "The geometric body in Dürer's engraving Melencolia I", Journal of the Warburg and Courtauld Institutes (The Warburg Institute) 45: 226–232, doi:10.2307/750979 .
• MacGillavry, C. (1981), "The polyhedron in A. Dürers Melencolia I", Nederl. Akad. Wetensch. Proc. Ser. B 84: 287–294 . As cited by (Weitzel 2004).
• Richter, D. H. (1957), "Perspektive und Proportionen in Albrecht Dürers "Melancholie"", Z. Vermessungswesen 82: 284–288 and 350–357 . As cited by (Weitzel 2004).
• Schreiber, Peter (1999), "A new hypothesis on Dürer's enigmatic polyhedron in his copper engraving "Melencolia I"", Historia Mathematica 26 (4): 369–377, doi:10.1006/hmat.1999.2245 .
• Schröder, E. (1980), Dürer, Kunst und Geometrie, Dürers künstlerisches Schaffen aus der Sicht seiner "Underweysung", Basel . As cited by (Weitzel 2004).
• Strauss, Walter L. (1972), The Complete Engravings of Dürer, New York, p. 168, ISBN 0-486-22851-7 . As cited by (Lynch 1982).
• Weber, P. (1900), Beiträge zu Dürers Weltanschauung—Eine Studie über die drei Stiche Ritter, Tod und Teufel, Melancholie und Hieronymus im Gehäus, Strassburg . As cited by (Weitzel 2004).
• Weitzel, Hans (2004), "A further hypothesis on the polyhedron of A. Dürer's engraving Melencolia I", Historia Mathematica 31 (1): 11–14, doi:10.1016/S0315-0860(03)00029-6 .
• Hideko, Ishizu (2009), "Another solution to the polyhedron in Dürer's Melencolia: A visual demonstration of the Delian problem", Aesthetics (The Japanese Society for Aesthetics) 13: 179–194, http://www.bigakukai.jp/aesthetics_online/aesthetics_13/text/text13_ishizu.pdf .
• Ziegler, Günter M. (December 3, 2014), "Dürer's polyhedron: 5 theories that explain Melencolia's crazy cube", The Guardian, https://www.theguardian.com/science/alexs-adventures-in-numberland/2014/dec/03/durers-polyhedron-5-theories-that-explain-melencolias-crazy-cube .
• Futamura, F.; Frantz, M.; Crannell, A. (2014), "The cross ratio as a shape parameter for Dürer's solid", Journal of Mathematics and the Arts 8 (3–4): 111–119, doi:10.1080/17513472.2014.974483 .

External links

• Weisstein, Eric W.. "Dürer's Solid". http://mathworld.wolfram.com/DuerersSolid.html. 
• How to build Dürer's Polyhedron - by DUPLICON (in German)
• Open-source 3D models of Dürer's Solid

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