If there’s a perfect time to write about eggy shapes, this must the the Holy Week. This article reads best while munching on your chocolate egg hunt loot.
Let me take you to centre of Stockholm – back in 1959. The capital of Sweden was being rebuilt after World War II. As a part of this program, two big arteries had been built and they intersected in the heart of the city: Sergels torg (Sergel’s Square). This place appeared to be a big problem for city planners, as its shape wasn’t really a square, but a rectangle.
The idea was to plan a roundabout around it. But what shape should this roundabout have? A circle?
Such a waste of space! Ellipse?
Too narrow for the traffic in the red parts.
Desperate times call for desperate measures, i.e., for mathematicians. More precisely, the team of architects asked for help Piet Hein, a Danish mathematician, inventor, designer, author, and poet (what else?!). And he invented a superellipse.
To simplify the task, let’s start with a circle. Just a standard x^2+y^2=1, nothing fancy.
Have you ever wondered, what happens if we enlarge the exponents in this familiar equation? So what does, for example, x^6+y^6=1 look like?
Is it a cirlce or a square? Or maybe a squircle? The higher the exponent, the closer to a square we get: x^100+y^100=1 is almost indistinguishable from a square.
Now let’s complicate things, just a little bit, and look at a more general shape: an ellipse. For example, (x/3)^2+(y/2)^2=1 looks like this
Again, as we enlarge the exponents, we get closer and closer to a rectangle. So here’s (x/3)^10+(y/2)^10=1
and (x/3)^100+(y/2)^100=1
. Almost a rectangle, right? These interesting shapes are called superellipses.
Remember that our original problem was to build a roundabout rectangular enough to fill most of the available space and circular enough to allow a smooth traffic flow. Hein found out that the perfect shape was an ellipse with exponent equal 2.5 (precisely, the Sergels torg roundabout can be described by and (x/6)^2.5+(y/5)^2.5=1).
Superellipses quickly became popular among architects all over the world. For example, famous Mexican Azteca Olympic Stadium has such a shape.
Other applications include:
- A shape of the table for negotiators after the Vietnam War, as a compromise between a circular one (“everyone’s equal”) and a rectangular one (“two sides on the conflict”); unfortunately, this amazing idea was rejected.
- Tobler hyperelliptical projection (one of the methods of drawing maps) uses arcs of superellipses as meridians.
- In mobile operating system iOS app icons have superellipse curves.
Don’t get impatient, I haven’t forgotten about Easter! Take your favourite superllipse, rotate it along its longest axis and you’ll get a superegg! Why is it so super? Well, it can just stand upright on a flat surface or on top of another superegg. This is a proper solution to the egg of Columbus problem!
Happy Easter!
http://m.wolframalpha.com/input/?i=bunny+curve&x=0&y=0
Happy Easter! 🙂
LikeLike
Wolfram doesn’t provide the curve equation 😦
LikeLike
Hmm, parametric equations are provided at the bottom of the page 😉
LikeLike
True story, thanks 🙂
LikeLike
🙂 Look at this one:
http://www.wolframalpha.com/input/?i=bunny+lamina
😀
LikeLike
Hello Paula, nice blog. Piet Hein’s Superellipses are known as Lamé curves after Gabriel Lamé (1795-1870). You can find a lot of info on the internet. It was generalized in the 1990’s to any symmetry (see e.g.
https://euro-math-soc.eu/review/geometrical-beauty-plants ). At that time I was working on bamboo, and in joint projects with the biology department of Imperial College.
This has quite a number of applications.
https://researchoutreach.org/articles/superellipses-superformula-impact-gielis-transformations/
One of my recent favorites is https://maxseeger.de/jewels-of-the-sea
All the best
Johan
LikeLike