Golden rhombus

In geometry, a golden rhombus is a rhombus whose diagonals are in the golden ratio:[1]

{D \over d}=\varphi ={{1+{\sqrt {5}}} \over 2}\approx 1.618~034

The golden rhombus.

Equivalently, it is the Varignon parallelogram formed from the edge midpoints of a golden rectangle.[1] Rhombi with this shape form the faces of several notable polyhedra. The golden rhombus should be distinguished from the two rhombi of the Penrose tiling, which are both related in other ways to the golden ratio but have different shapes than the golden rhombus.[2]

Angles

(See the characterizations and the basic properties of the general rhombus for angle properties.)

The internal supplementary angles of the golden rhombus are:[3]

Acute angle: $\alpha =2\arctan {1 \over \varphi }$ ;

by using the arctangent addition formula (see inverse trigonometric functions):

\alpha =\arctan {{2 \over \varphi } \over {1-({1 \over \varphi })^{2}}}=\arctan {{2 \over \varphi } \over {1 \over \varphi }}=\arctan 2\approx 63.43495^{\circ }.

Obtuse angle: $\beta =2\arctan \varphi =\pi -\arctan 2\approx 116.56505^{\circ },$

which is also the dihedral angle of the dodecahedron.[4]

Note: an "anecdotal" equality:

\pi -\arctan 2=\arctan 1+\arctan 3~.

Edge and diagonals

By using the parallelogram law (see the basic properties of the general rhombus):[5]

The edge length of the golden rhombus in terms of the diagonal length $d$ is:

$a={1 \over 2}{\sqrt {d^{2}+(\varphi d)^{2}}}={1 \over 2}{\sqrt {1+\varphi ^{2}}}~d={{\sqrt {2+\varphi }} \over 2}~d={1 \over 4}{\sqrt {10+2{\sqrt {5}}}}~d\approx 0.95106~d~.~$ Hence:

The diagonal lengths of the golden rhombus in terms of the edge length $a$ are:[3]

$d={2a \over {\sqrt {2+\varphi }}}=2{\sqrt {{3-\varphi } \over 5}}~a={\sqrt {2-{2 \over {\sqrt {5}}}}}~a\approx 1.05146~a~.$

$D={2\varphi a \over {\sqrt {2+\varphi }}}=2{\sqrt {{2+\varphi } \over 5}}~a={\sqrt {2+{2 \over {\sqrt {5}}}}}~a\approx 1.70130~a~.$

Area

By using the area formula of the general rhombus in terms of its diagonal lengths $D$ and $d$ :

The area of the golden rhombus in terms of its diagonal length

d

is:[6]

A={{(\varphi d)\cdot d} \over 2}={{\varphi } \over 2}~d^{2}={{1+{\sqrt {5}}} \over 4}~d^{2}\approx 0.80902~d^{2}~.

By using the area formula of the general rhombus in terms of its edge length $a$ :

The area of the golden rhombus in terms of its edge length

a

is:[3][6]

A=(\sin(\arctan 2))~a^{2}={2 \over {\sqrt {5}}}~a^{2}\approx 0.89443~a^{2}~.

Note: $\alpha +\beta =\pi$ , hence: $\sin \alpha =\sin \beta ~.$

As the faces of polyhedra

Several notable polyhedra have golden rhombi as their faces. They include the two golden rhombohedra (with six faces each), the Bilinski dodecahedron (with 12 faces), the rhombic icosahedron (with 20 faces), the rhombic triacontahedron (with 30 faces), and the nonconvex rhombic hexecontahedron (with 60 faces). The first five of these are the only convex polyhedra with golden rhomb faces, but there exist infinitely many nonconvex polyhedra having this shape for all of their faces.[7]

References

Senechal, Marjorie (2006), "Donald and the golden rhombohedra", in Davis, Chandler; Ellers, Erich W. (eds.), The Coxeter Legacy, American Mathematical Society, Providence, RI, pp. 159–177, ISBN 0-8218-3722-2, MR 2209027
For instance, an incorrect identification between the golden rhombus and one of the Penrose rhombi can be found in Livio, Mario (2002), The Golden Ratio: The Story of Phi, the World's Most Astonishing Number, New York: Broadway Books, p. 206
Ogawa, Tohru (January 1987), "Symmetry of three-dimensional quasicrystals", Materials Science Forum, 22–24: 187–200, doi:10.4028/www.scientific.net/msf.22-24.187. See in particular table 1, p. 188.
Gevay, G. (June 1993), "Non-metallic quasicrystals: Hypothesis or reality?", Phase Transitions, 44 (1–3): 47–50, doi:10.1080/01411599308210255
Weisstein, Eric W. "Rhombus". MathWorld.
Weisstein, Eric W. "Golden Rhombus". MathWorld.
Grünbaum, Branko (2010), "The Bilinski dodecahedron and assorted parallelohedra, zonohedra, monohedra, isozonohedra, and otherhedra" (PDF), The Mathematical Intelligencer, 32 (4): 5–15, doi:10.1007/s00283-010-9138-7, MR 2747698, archived from the original (PDF) on 2015-04-02.

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[senechal-1] Senechal, Marjorie (2006), "Donald and the golden rhombohedra", in Davis, Chandler; Ellers, Erich W. (eds.), The Coxeter Legacy, American Mathematical Society, Providence, RI, pp. 159–177, ISBN 0-8218-3722-2, MR 2209027

[2] For instance, an incorrect identification between the golden rhombus and one of the Penrose rhombi can be found in Livio, Mario (2002), The Golden Ratio: The Story of Phi, the World's Most Astonishing Number, New York: Broadway Books, p. 206

[ogawa-3] Ogawa, Tohru (January 1987), "Symmetry of three-dimensional quasicrystals", Materials Science Forum, 22–24: 187–200, doi:10.4028/www.scientific.net/msf.22-24.187. See in particular table 1, p. 188.

[4] Gevay, G. (June 1993), "Non-metallic quasicrystals: Hypothesis or reality?", Phase Transitions, 44 (1–3): 47–50, doi:10.1080/01411599308210255

[5] Weisstein, Eric W. "Rhombus". MathWorld.

[Mathworld-6] Weisstein, Eric W. "Golden Rhombus". MathWorld.

[7] Grünbaum, Branko (2010), "The Bilinski dodecahedron and assorted parallelohedra, zonohedra, monohedra, isozonohedra, and otherhedra" (PDF), The Mathematical Intelligencer, 32 (4): 5–15, doi:10.1007/s00283-010-9138-7, MR 2747698, archived from the original (PDF) on 2015-04-02.