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Is there a formula that generates a set of coordinates of triangles whose vertices are located on a sphere?

I am probably looking for something that does something similar to gluSphere. Yet, I need to color the different triangles in specfic colors so that it seems I can't use gluSphere.

Also: I do understand that gluSphere draws edges along lines with equal longitudes and lattitudes which entails the triangles being small at the poles compared to their size at the equator. Now, if such a formula would generate the triangles such that their difference in size is minimized, that would be great.

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You are looking for "geosphere generation". Google finds a lot of info with those two words. –  Virne Dec 29 '10 at 22:21
priceless page: blog.andreaskahler.com/2009/06/… –  Joe Blow Dec 8 '11 at 7:39

2 Answers 2

up vote 3 down vote accepted

Start with a unit icosahedron. Then apply muliple homogenous subdivisions of the triangles, normalizing the resulting vertices distance to the origin.

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Octahedron is a good choice for first model too. More info here: local.wasp.uwa.edu.au/~pbourke/miscellaneous/sphere_cylinder –  Virne Dec 29 '10 at 22:19

Here's an all-time-classic web page that beautifully explains how to build an icosphere. (This is the process Datenwolf mentions.)


Hope it helps.

By the way .. you are also going to need to calculate the normals and the uv map.

Fortunately there is an amazing trick for calculating the normals, on a sphere -- happily the normals are, of course, nothing more than the direction from the centre of the sphere, to that point!!!! If you think about it, in fact furthermore that means the normals literally equal the point! i.e., it's the same vector! - just don't forget to normalise the length, for the normal.

You can win bar bets on that one: "is there a shape where all the normals happen to exactly .. equal the vertices?" At first glance you think, that's impossible, no such coincidental shape could exist. But of course the answer is simply "a sphere with radius one!" Heh!

Regarding the UVs it's relatively easy on a sphere (assuming you're projecting to 2D in the "obvious" manner, a "rectangle" map projection) .. the u and v is basically just the longitude / latitude of any point, normalised to 0,1.

Hope it helps!

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I want to go to bars where that's a valid bet. –  David Souther Jun 24 '14 at 11:51
You, me, and Neal Stephenson, dude! That "other" D. Souther would provide the music :) –  Joe Blow Jun 24 '14 at 12:37
Hell yeah he would - we'll call it Hemingway's Whiskey –  David Souther Jun 24 '14 at 16:41

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