Real-world examples of more "obscure" geometric figures

Question

As part of my secondary geometry class I like to hook students by presenting real-world examples (usually images I find online or have taken myself) of different geometric shapes from real life. For instance, a lesson on the area of a circle might start out with a picture of a pizza pie or a lesson on the midsegments of triangles might start out with a picture of the Triforce. However, there are some geometric figures that I have had a hard time finding interesting, real-world examples of. Those figures (and I know I am forgetting a bunch..) are:

• Segment of a circle
• Secant line
• Trapezoid (Isosceles or not)
• Inscribed angle
• Parallel lines cut by a transversal

I was wondering if anyone had any ideas for these geometric figures of interesting, real world examples? Also, I think it would be great that if people are aware of really cool real world examples for the more "standard" geometric figures to post those as answers as well. For instance, the Dockland Building at the Port of Hamburg is an astoundingly perfect parallelogram :) Having a collection would be very helpful for teachers because I have not found a better way to get my students right into the groove by starting class off with a brief discussion about an interesting picture!

Answer 1

Trapezoid

Native Peruvian architecture makes heavy use of the trapezoid for stability in earthquakes. (The Spaniards thought they were primitive as they didn't use arches ... but most of the Spanish buildings have collapsed or had to be rebuilt).

It's especially apparent in their doorways and windows.

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Other examples with licensing such that I don't want to embed it:

• http://russellbevan.photoshelter.com/image/I0000rB5g1TrtY8E
• http://www.travel-images.com/photo/photo-peru194.html

Trapezoids are also found in cabinet joinery, specifically dovetail joints.

Segment of a Circle

Most architectural arches are based on segments of circles, particularly those in Roman architecture:

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Chinese architecture tends to favor segmental arches (which the Romans also used), rather than full rounded arches:

(more images)

See also arch bridges and barrel vaults. If you want sophomoric humor, also consider the groin vault (when made with round barrel vaults, not pointed barrel vaults).

Parabola

There are also Parabolic Arches:

Parallel lines cut by a transversal

Runways at large airports. They typically have taxiway parallel to the runway, and in windy areas have a second (or even third) pair to avoid takeoffs/landings into a cross wind. BWI is a good example, but I was having difficulty finding public domain images. Here's one of O'Hare:

(hi res)

Answer 2

The National Library of Belarus, a rhombicuboctahedron:

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Answer 3

I like the Gateway Arch in St. Louis as an example of a catenary with a formula of the form $y= A \cosh(\frac{C X}{L}) -A$. More information on the wiki: Gateway Arch: Mathematical Elements.

Answer 4

Dice

You get all Platonic solids, some trapecohedrons and bipyramids, and the tetrahexahedron and the rhombic triacontahedron:

Answer 5

There's a fair attempt at a Hypercube with the Grande Arche de la Défense in Paris.

Answer 6

The hexagon at the north pole of Saturn:

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It is known that

"[regular shapes] form in an area of turbulent flow between ... two different rotating fluid bodies with dissimilar speeds."

and this has been proposed as an explanation for the phenomenon.

Incidentally, the Earth could easily fit inside the pole hexagon.

Added (23Sep15). An article in space.com cites a new and apparently thorough explanation of Saturn's polar hexagon, in The Astrophysical Journal Letters:

Here we present numerical simulations showing that instabilities in shallow jets can equilibrate as meanders closely resembling the observed morphology and phase speed of Saturn's northern Hexagon.

Added (10Dec16). New images taken by Cassini:

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Answer 7

A corkscrew (for a helix):

A donut (for a torus):

A football (for a spheroid)

And then, there's also the atomium (for which I am not sure exists a geometric name)

cooling towers (for a hyperboloid)

and the pentagon (well, for a pentagon):

A pyramid is, of course, a pyramid.

Lastly, a soccer ball is a truncated icosahedron

(Images by wiki, pedia)

Answer 8

"Turning Torso," an apartment building in Malmö, Sweden designed by architect Santiago Calatrava, following a twisting spiral. It consists of "nine segments of five-story pentagons that twist relative to each other as it rises; the topmost segment is twisted 90 degrees clockwise with respect to the ground floor."

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Answer 9

Sphere or hemisphere: Pantheon

Answer 10

One other poster mentioned arches; I'd like to add in the Gothic arch as an example of circular segments. These are great examples of arcs as well. I find them much more interesting, and they don't always have to have the angle shown here; the location of the circle's center can vary depending on the "slope" of the arch that is desired. There are also three- and four-centered arches. I can imagine that you could differentiate for your more advanced students by having them try to figure out how the more complicated arch structures were designed. Calculations related to the complicated structures could be somewhat intense but a fun challenge for a gifted student. The area underneath one of the simpler arches would be an interesting problem more at the level of the majority of the class.

Answer 11

Really great answers! I just found this while making a lesson on annuli, an Annular Eclipse, very beautiful! and it also has interesting math behind why the sun is not entirely covered by the moon!

Answer 12

At Wikipedia: Saddle roof you can see images of rooftops which are a Hyperbolic Paraboloid. Other "saddle-like" objects may also be this shape - the primary advantage of which (like its cousin the one-sheet hyperboloid i.e. nuclear plant cooling tower) is that it can be formed from supports that are straight lines in a grid.

At Hyperboloid structure you can see some radio towers that use the one-sheet hyperboloid as their shape.

Answer 13

As constrast to the catenary in Chris's answer, you could show a suspension bridge, which has a parabola...

LINK

added
According to LINK, the curve in a suspension bridge is generally a curve intermediate between a catenary and a parabola.

Answer 14

A (cata)caustic is the envelope of lines reflected in a curve. The caustic formed by parallels lines reflected in a semicircle is a cardioid, such as can be seen in the bottom of this MSE coffee mug.

Other envelopes include evolutes. An evolute is the envelope of the normal lines to a given curve; the given curve is the involute of the evolute.

A famous involute is the cycloid, which the involute of itself (and therefore the evolute of itself, too). Because the cycloid is a tautochrone, Huygens used it to design a clock (left, Fig. II), which Coster made (right):

The involute of a circle (the smaller ones) can be used to design gear teeth that roll off each other without slipping (thus minimizing heating due to friction):

Answer 15

(Inspired by Gerhard's comment) Trapezoid:

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            ^{(Image from Parth Chandran @emaze.com.)}

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Answer 16

The stone spheres (or stone balls) of Costa Rica are an assortment of over three hundred petrospheres in Costa Rica, located on the Diquís Delta and on Isla del Caño. Locally, they are known as Las Bolas (literally The Balls). The spheres are commonly attributed to the extinct Diquís culture and are sometimes referred to as the Diquís Spheres.

The Palmar Sur Archeological Excavations are a series of excavations of a site located in the southern portion of Costa Rica, known as the Diquís Delta. The excavations have centered on a site known as "Farm 6", dating back to the Aguas Buenas Period (300-800AD) and Chiriquí Period (800-1550 AD).

They are almost perfectly round, developed by a culture without any knowledge on geometry?

Answer 17

For a super-ellipse, one example would be the fountain at Sergels torg, in Stockholm, Sweden.

For a circular segment, one example would be the cross-section of liquid in a horizontal-axis circular cylinder tank. (Another picture is here.)

Answer 18

So called tensile structures in architectures are indeed minimal surfaces. Popular examples are

• the Olympiastadium in Munich: or
• the former Millenium Dome in London:

Answer 19

An ellipse as a cylindric section: The top surface of the Tycho Brahe Planetariun, Copenhagen, Denmark.

The building itself is a cylindrical segment.

Answer 20

Reggio Emilia Calatrava's railway station follows some very interesting geometrical patterns, building pairs of sinusoids in phase and out of phase

Answer 21

The Mito Art Tower consists of $28$ congruent, stacked regular tetrahedra, each with edge length about $10$m. It is in Mito, Ibaraki, Japan. Architect: Arata Isozaki.

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^{Left image from [www.panoramio.com](http://www.panoramio.com/).
Right figure from Elgersma & Wagon. "The Quadrahelix: A Nearly Perfect Loop of Tetrahedra." 2016. [arXiv abstract](https://arxiv.org/abs/1610.00280).}

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Known as the Boerdjik-Coxeter helix.

Answer 22

Water towers:

The form comes from the need to (approximately) maintain a constant pressure.

Answer 23

The Puerta de Europa (Gate of Europe) in Madrid consists of two $26$-floor prisms inclined $15^\circ$:

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^{(Image from archiseek.com.)}

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Designed by architects Philip Johnson and John Burgee.

Answer 24

Minimal surfaces was mentioned. Another example of minimal surfaces is soap bubbles:

Answer 25

Spiral = snail shell.

Broccoli = fractal

-or- broccoli = decision tree (but a tree can also be a decision tree). Note that the slang term in the Navy for broccoli is "trees" (like sliders for burgers).

Wankel engine rotor has a similar curve-y triangle shape to the criticized coin above.

Saddle = saddle (3rd semester calc)

Drill chuck = truncated cone (also some of the internals of an automotive differential)

"Stadiums" for trapezoidal cylindrical shells (calculus volume of rotation problems)

Lots of other cool gear-type shapes (prop screw for a ship, pump lobes, camshaft, chevronic separators in boilers, tricone rotary drill bit). Not a 100% sure what they all correspond to math-name wise, but they definitely engage some wonder about shape to function.

Answer 26

I've found that students are not very clear on the image that is being invoked when I call $z = x^2-y^2$ by its traditional name of "saddle point", but they are all very clear on what a Pringles potato chip looks like.

Answer 27

A nice challenge for a calculus class with a little physics: If particles are thrown out from a common point in all directions at the same speed, then allowed to fall freely, the shape they will sweep out is a parabola. (Of course, the trajectory of each particle is also a parabola, that's a simpler fact.) The Fourth of July might suggest some examples:

When I was in high school, I saw a cutting board lying on an angle in a sink with the water pouring from the faucet onto a point on it. The water splashed out to form a parabolic arc. I wonder if you could actually bring something like that into the classroom and trace the edge of the water?

Answer 28

A just-released image of a crudely—but recognizably hexagonal—crater (the "Haulani Crater") on the dwarf planet Ceres (between Mars & Jupiter), taken by the Dawn spacecraft.

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One article says it "look[s] oddly like a stop sign," but we know stop signs (in the U.S.) are octagons. How a physical process (asteroid collision) could result in an approximate hexagon is (I think?) not yet understood.

Cf. Saturn's north-pole hexagon, which is better understood (at least conjecturally).

Answer 29

Curves of constant width, the simplest of which is the Reuleaux Triangle, occur in a variety of applications. As a shape it consists of pieces of three circles. To construct a Reuleaux Triangle start with an equilateral triangle of side length h and with a compass from each vertex draw a circular arc with radius h between the other two vertices. The resulting set, like a circle has constant width h. Read more about the Reuleaux Triangle and its interesting properties here:

https://en.wikipedia.org/wiki/Reuleaux_triangle

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          ^{(Image from de.ucoin.net.)}

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Answer 30

A square antiprism at One World Trade Center

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