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I would like to write a function that takes a 3d triangle (as 3 points (vector3ds)) and returns a 2d triangle (as 3 points (vector2ds)):

When given a 3d triangle, it should return the 2 dimensional coordinates of its points as they lie on its plane. (By 'its plane' I mean the plane that all three points lie on).

I can think a long winded way todo this:

  • rotate the triangle until its normal is equal to +z (0,0,1), then construct a triangle from the (x, y) coords of each point.

I cant help but think there must be an easier way to achieve the same thing.

If posting code examples please try not to use Greek alphabet. Some pseudo code in a C/java style language would be ideal.

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how are the triangles to be represented? i.e. you hand me a 3-d triangle, but what is that? is it a bunch of 3-space points? –  Jordan Nov 8 '11 at 13:38
    
The answer is ambiguous. You have to specify some arbitrary coordinate system in the plane of the triangle. You can always choose this coordinate system in a way that the answer is (0, 0), (1, 0), (0, 1). –  Sven Marnach Nov 8 '11 at 13:39
    
what's the desired origin of this plane? If not one of the vertices then it has to be some other arbitrary point. –  Alnitak Nov 8 '11 at 13:40
1  
What's wrong with the Greek alphabet? –  Kris Harper Nov 8 '11 at 13:40
3  
@root45 maybe it's a protest against their fiscal situation? –  Alnitak Nov 8 '11 at 13:41

2 Answers 2

up vote 3 down vote accepted

From your comments I infer that you can choose the coordinate system of the plane in an arbitrary way, as long as the Euclidean metric of this coordinate system is the same as the metric induced by the Euclidean metric of your three-dimensional coordinate system. (That is, Euclidean distances will stay the same.)

One possible solution:

x0' = 0
y0' = 0

x1' = sqrt((x1 - x0)^2 + (y1 - y0)^2 + (z1 - z0)^2)
y1' = 0

x2' = ((x1 - x0) * (x2 - x0) + 
       (y1 - y0) * (y2 - y0) + 
       (z1 - z0) * (z2 - z0)) / x1'
y2' = sqrt((x2 - x0)^2 + (y2 - y0)^2 + (z2 - z0)^2 - x2'^2)
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you appear to be using the dot product to work out cos(theta) - doesn't this run the risk of the resulting triangle having its normal 'flipped' (not withstanding that the new coordinate system is somewhat arbitrary) ? –  Alnitak Nov 8 '11 at 14:16
    
@Alnitak Why should it? A triangle's angle is always < 180 degrees. –  Christian Rau Nov 8 '11 at 14:28
    
@ChristianRau because it could also be -180 < theta < 0 (i.e. if v3 is on the "right" of the vector from v1 to v2). –  Alnitak Nov 8 '11 at 15:04
    
@Alnitak: The only condition I was able to infer from the OP's comments was that the coordinate system should be chosen in a way that preserves the Euclidean distance. Conservation of orientation was not requested. –  Sven Marnach Nov 8 '11 at 15:20
    
@SvenMarnach indeed I don't think it matters too much, as the orientation is somewhat arbitrary anyway. I only queried it since I had intentionally used the cross product sine rule rather than the dot product cosine rule specifically to mitigate the effect. –  Alnitak Nov 8 '11 at 15:46

There is no singular answer to this problem.

The plane in which the triangle sits has no defined origin, and no defined orientation.

The best you can do is define one of the vertices as the origin, and one of the edges laying along the X axis:

v1 = (0, 0)

You will need to calculate vectors A (i.e. v2 - v1) and B (i.e. v3 - v1).

Vertex 2 will then be at:

v2 = (|A|, 0)

The position of vertex 3 can be worked out by using the vector cross product rule, e.g.:

A x B = |A| * |B| sin(theta)

So, work out A x B and from that you can work out the sine of the angle theta between A and B:

sin(theta) = | A x B | / (|A| * |B|)

Vertex 3 is then at coordinates:

v3 = |B| (cos(theta), sin(theta)) 

You can take advantage of cos(theta) = sqrt(1 - sin(theta) ^ 2) to avoid any inverse trig operations.

You should also see that |B| sin(theta) is just | A x B | / | A |

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You can also take advantage of |B| * cos(theta) = (A . B) / |A| and don't even need a sqrt. So v3 = (A.B, |AxB|) / |A|. –  Christian Rau Nov 8 '11 at 14:19
    
@ChristianRau yes, that's correct. –  Alnitak Nov 8 '11 at 14:22
    
And +1 for the greek letter, of course. –  Christian Rau Nov 8 '11 at 14:24

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