# Projecting a sphere onto a cube

I'm currently working on building a game which is on a planet, the way in which I'm planning to store the data is in 6 2dimensional arrays, which are heightmaps around the sphere (on the faces of a cube). The problem I have is this, given a normalised vector which points outwards from the centre of the sphere how can I determine these two things:
1) The plane which it intersects
2) The x/y coordinates I should look up in my 2d array to get the height.

My current solution is this (using XNA):
1) Construct a ray pointing out from [0,0] along the direction vector supplied. Loop through each surface and do a ray/plane intersection (which is a method supplied by the XNA framework) to get the distance to the intersection point. Select the closest plane (shortest distance to intersection)
2) Take the 3D point, and convert it to a 2D point which can be used as an array lookup to find the radius (this is the bit I cannot work out the maths for, or find any references to through google).

A helpful constraint is that the sphere/cube system is around the origin.

So, the problem which needs solving is this: Given a direction vector, how do I determine where it intersects the surrounding cube. Using this result how do I then get the correct value in a 2D array which is "painted" on the face of this cube?

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Martin, could you edit your post to include a more explicit question? –  JoshJordan Jun 14 '09 at 17:18
Sure, I suppose it's not perfectly clear. –  Martin Jun 14 '09 at 19:31
You should look at starting with a cube and tessellating it. You may notice a singularity if your sphere is one derived from trigonometric functions (the landscape will 'pinch' at the poles). If you do it that way your mapping problem disappears. –  Jonathan C Dickinson Jun 24 '09 at 12:32
the sphere in this case doesn't really exist, I've simply got a dataset of unit vectors and I want to map them onto a cube for easy storage (6 cubes faces, each is a 2d array) –  Martin Jun 24 '09 at 22:38

Look at the magnitude of each of the 3 components of the direction. The one with the largest magnitude tells you which face of the cube you hit (and its sign tells you if it's the + or - face.)

The other two coordinates give you your 2D mapping values. We need to normalize them, though. If your XYZ direction has X as the highest magnitude, then your 2D face coordinates are just U=Y/X and V=Z/X. These both range from -1 to 1.

Be careful of flips from positive to negative sides, you may need to flip the 2D U and/or V values to match your coordinate system.

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Aha, that sounds like a somewhat simpler technique than the one I'm already using! I'll have a go at implementing this as see what happens. Thanks! –  Martin Jun 14 '09 at 17:18
``````# edges are called X_AXIS_POS, X_AXIS_NEG, Y_AXIS_POS, Y_AXIS_NEG, Z_AXIS_POS, Z_AXIS_NEG
if (x*x >= y*y) && (x*x >= z*z) :
return ( (x>0) ? X_AXIS_POS : X_AXIS_NEG, y/abs(x), z/abs(x))
if (y*y >= z*z) && (y*y >= x*x) :
return ( (y>0) ? Y_AXIS_POS : Y_AXIS_NEG, x/abs(y), z/abs(y))
return ( (z>0) ? Z_AXIS_POS : Z_AXIS_NEG, x/abs(z), y/abs(z))
``````
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Not the simplest code I've ever seen ;) However thankyou, I now know exactly how it works :D –  Martin Jun 14 '09 at 17:36