# Math for a geodesic sphere

I'm trying to create a very specific geodesic tessellation, but I can't find anything online about it.

It is normal to subdivide the triangles of an icosahedron into triangle patches and project them onto the sphere. However, I noticed an animated GIF on the Wikipedia entry for Geodesic Domes that appears not to follow this scheme. Geodesic spheres generally comprise a mixture of mostly hexagonal triangle patches, with pentagonal patches forming at the vertices of the original icosahedron; in most cases, these pentagons are linked together; that is, following a straight edge from the center of one pentagon leads to the center of another pentagon. In the Wikipedia animation, however, the edge from the center of one pentagon doesn't appear to intersect the center of an adjacent pentagons; instead it intersects the side of the other pentagon. Hopefully the drawing below makes this clear:

Where can I go to learn about the math behind this particular geometry? Ideally, I'd like to know of an algorithm for generating such tessellations.

EDIT: The following picture illustrates the more conventional scheme, whereby the centers of adjacent pentagons are linked by edges:

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Thurston gave a parameterization of these, as lattice points in a complex hyperbolic space: emis.ams.org/journals/UW/gt/ftp/main/m1/m1s25.pdf In fact, they exist in a continuum if one considers cone metrics on the 2-sphere with cone points of order $2\pi/5$. –  Ian Agol Jun 30 '14 at 23:30

Marcelo,

The most-commonly employed geodesic tessellations are either Class-I or Class-II. The image you reference is of a Class-III tessellation, more-specifically, 4v{3,1}. The classes can be diagrammed, so:

Class-III tessellations are chiral, and can have left-handed or right-handed twist. Here's the mirror-image of the sample you referenced:

You can find some 3D models of Class-III spheres, at Google's 3D Warehouse: http://sketchup.google.com/3dwarehouse/cldetails?mid=b926c2713e303860a99d92cd8fe533cd

Being properly identified should get you off to a good start.

Feel free to stop by the Geodesic Help Group; http://groups.google.com/group/GeodesicHelp?hl=en

TaffGoch

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Here's an image from one of Joe Clinton's NASA publications:

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I believe it is actually just a matter of resolution (i.e., number of sub-divisions). The tessellation you show does seem to emanate from an icosahedron scheme: cf p.7 here, mid-page example. Check out the rest of the document for some calculation details - also its cited references, and some further code samples here.

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Thanks for the reply, Ofek, but the cited examples don't exhibit the peculiarity I describe. I've amended my question with a snapshot of the example you refer to, highlighting the key features. Note how centers of the pentagonal groups line up, which they don't do in the first picture. –  Marcelo Cantos Jun 13 '10 at 11:18
I see now, thanks. Sorry, no further insights here.. –  Ofek Shilon Jun 13 '10 at 11:27

Marcelo,

If you want to devise algorithms to generate any class of geodesic spheres, you can do it here:

http://thomson.phy.syr.edu/thomsonapplet.htm

Start by using the "custom(m,n)" option, select your desired parameters, then hit the "pause" button. Switch to "lattice energy" and hit the "Auto" button.

If you're intimately familiar with java, you can save the "jar" file(s) for this app, and examine the contents, to back-engineer the algorithms.

BTW, this java app also has a "File" menu option, which can activate a new window, listing the "Point set" (vertex coordinates.) I copy & paste them into an Excel spreadsheet, from which I can generate a "csv" file that can be, subsequently, imported into 3D-graphic programs.

Taff

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Thank you, @TaffGoch. That's a great little applet! You've been extremely helpful with my question. –  Marcelo Cantos Jun 18 '10 at 12:41