Inverted snub dodecadodecahedron

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In geometry, the inverted snub dodecadodecahedron (or vertisnub dodecadodecahedron) is a nonconvex uniform polyhedron, indexed as U₆₀.^[1] It is given a Schläfli symbol Template:Math

Cartesian coordinates

Let ${\displaystyle \xi \approx 2.109759446579943}$ be the largest real zero of the polynomial ${\displaystyle P=2x^4-5x^3+3x+1}$. Denote by ${\displaystyle \varphi }$ the golden ratio. Let the point ${\displaystyle p}$ be given by

${\displaystyle p=\left(\begin{array}{c}{\varphi }^{-2}{\xi }^2-{\varphi }^{-2}\xi +{\varphi }^{-1}\\ -{\varphi }^2{\xi }^2+{\varphi }^2\xi +\varphi \\ {\xi }^2+\xi \end{array}\right)}$.

Let the matrix ${\displaystyle M}$ be given by

${\displaystyle M=\left(\begin{array}{ccc}1/2& -\varphi /2& 1/(2\varphi )\\ \varphi /2& 1/(2\varphi )& -1/2\\ 1/(2\varphi )& 1/2& \varphi /2\end{array}\right)}$.

${\displaystyle M}$ is the rotation around the axis ${\displaystyle (1,0,\varphi )}$ by an angle of ${\displaystyle 2\pi /5}$, counterclockwise. Let the linear transformations ${\displaystyle T_0,\dots ,T_{11}}$ be the transformations which send a point ${\displaystyle (x,y,z)}$ to the even permutations of ${\displaystyle (\pm x,\pm y,\pm z)}$ with an even number of minus signs. The transformations ${\displaystyle T_i}$ constitute the group of rotational symmetries of a regular tetrahedron. The transformations ${\displaystyle T_i{M}^j}$ ${\displaystyle (i=0,\dots ,11}$, ${\displaystyle j=0,\dots ,4)}$ constitute the group of rotational symmetries of a regular icosahedron. Then the 60 points ${\displaystyle T_i{M}^{j}p}$ are the vertices of a snub dodecadodecahedron. The edge length equals ${\displaystyle 2(\xi +1)\sqrt{{\xi }^2-\xi }}$, the circumradius equals ${\displaystyle (\xi +1)\sqrt{2{\xi }^2-\xi }}$, and the midradius equals ${\displaystyle {\xi }^2+\xi }$.

For a great snub icosidodecahedron whose edge length is 1, the circumradius is

${\displaystyle R=\frac{1}{2}\sqrt{\frac{2\xi -1}{\xi -1}}\approx 0.8516302281174128}$

Its midradius is

${\displaystyle r=\frac{1}{2}\sqrt{\frac{\xi }{\xi -1}}\approx 0.6894012223976083}$

The other real root of P plays a similar role in the description of the Snub dodecadodecahedron

Related polyhedra

Medial inverted pentagonal hexecontahedron

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The medial inverted pentagonal hexecontahedron (or midly petaloid ditriacontahedron) is a nonconvex isohedral polyhedron. It is the dual of the uniform inverted snub dodecadodecahedron. Its faces are irregular nonconvex pentagons, with one very acute angle.

Proportions

Denote the golden ratio by ${\displaystyle \varphi }$, and let ${\displaystyle \xi \approx -0.23699384345}$ be the largest (least negative) real zero of the polynomial ${\displaystyle P=8x^4-12x^3+5x+1}$. Then each face has three equal angles of ${\displaystyle \arccos (\xi )\approx 103.70918221953^{\circ }}$, one of ${\displaystyle \arccos ({\varphi }^2\xi +\varphi )\approx 3.99013042341^{\circ }}$ and one of ${\displaystyle 360^{\circ }-\arccos ({\varphi }^{-2}\xi -{\varphi }^{-1})\approx 224.88232291799^{\circ }}$. Each face has one medium length edge, two short and two long ones. If the medium length is ${\displaystyle 2}$, then the short edges have length $${\displaystyle 1-\sqrt{\frac{1-\xi }{{\varphi }^3-\xi }}\approx 0.47412646054,}$$ and the long edges have length $${\displaystyle 1+\sqrt{\frac{1-\xi }{{\varphi }^{-3}-\xi }}\approx 37.55187944854.}$$ The dihedral angle equals ${\displaystyle \arccos (\xi /(\xi +1))\approx 108.09571935234^{\circ }}$. The other real zero of the polynomial ${\displaystyle P}$ plays a similar role for the medial pentagonal hexecontahedron.

See also

• List of uniform polyhedra
• Snub dodecadodecahedron

References

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External links

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