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Superegg

{{short description|Special type of superellipsoid}}

Image:Superaeg.jpg.]]

File:Piet Hein Superegg.stl

In geometry, a superegg is a solid of revolution obtained by rotating an elongated superellipse with exponent greater than 2 around its longest axis. It is a special case of superellipsoid.

Unlike an elongated ellipsoid, an elongated superegg can stand upright on a flat surface, or on top of another superegg.{{cite book | last=Gardner | first=Martin | author-link=Martin Gardner | chapter=Piet Hein’s Superellipse | year=1977 | title=Mathematical Carnival. A New Round-Up of Tantalizers and Puzzles from Scientific American | location=New York | publisher=Vintage Press | pages=[https://archive.org/details/mathematicalcarn00gard/page/240 240–254] | isbn=978-0-394-72349-5 | chapter-url-access=registration | chapter-url=https://archive.org/details/mathematicalcarn00gard/page/240 }} This is due to its curvature being zero at the tips. The shape was popularized by Danish poet and scientist Piet Hein (1905–1996). Supereggs of various materials, including brass, were sold as novelties or "executive toys" in the 1960s.

Mathematical description

The superegg is a superellipsoid whose horizontal cross-sections are circles. It is defined by the inequality

:\left|\frac{\sqrt{x^2 + y^2}}{R}\right|^p + \left|\frac{z}{h}\right|^p \leq 1 \, ,

where R is the horizontal radius at the "equator" (the widest part as defined by the circles), and h is one half of the height. The exponent p determines the degree of flattening at the tips and equator. Hein's choice was p = 2.5 (the same one he used for the Sergels Torg roundabout), and R/h = 6/5.{{Cite web|url=https://www.matematiksider.dk/piethein.html|title=Piet Heins Superellipse|website=www.matematiksider.dk|lang=da}}

The definition can be changed to have an equality rather than an inequality; this changes the superegg to being a surface of revolution rather than a solid.{{Cite web |last=Weisstein |first=Eric W. |author-link=Eric W. Weisstein |title=Superegg |url=https://mathworld.wolfram.com/ |access-date=2023-10-02 |website=mathworld.wolfram.com |language=en}}

Volume

The volume of a superegg can be derived via squigonometry, a generalization of trigonometry to squircles.{{cite journal |author=Robert D. Poodiack |date=April 2016 |title=Squigonometry, Hyperellipses, and Supereggs |url=https://www.jstor.org/stable/10.4169/math.mag.89.2.92 |journal=Mathematics Magazine |volume=89 |issue=2 |pages=100–101|doi=10.4169/math.mag.89.2.92 |jstor=10.4169/math.mag.89.2.92 |s2cid=123959015 }} It is related to the gamma function:

V = \frac{4\pi hR^2}{3p}\frac{\Gamma(1/p) \Gamma(2/p)}{\Gamma(3/p)} \, .

See also

{{Portal|Denmark|Mathematics|Toys}}

References

{{Reflist}}

External links

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Category:Algebraic curves

Category:Surfaces

Category:Office toys

Category:Educational toys

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