17

So I have a 3D Plane described by 2 Vectors:

P : a point which lies on the Plane
N : the surface normal for the Plane

And i have a very large, flat square Polygon, which I want to render to represent this Plane. I can easily translate the polygon to the given point, but then I need to find the proper rotation to apply to make the surface normal actually be the surface normal.

I tried a method mentioned else where which was:

1) Take any none parallel vector (V) to the normal (N), and take the cross product (W1)
2) Take the cross product of (W1) and (N) now (W2) and that is a Vector (V') which lies on the Plane

I then generate a rotation matrix based on (V') laying on the Plane, so that my polygon would be aligned with (V'). that worked, but it's clear that this method is not working correctly as a whole. The Polygon is not perfectly perpendicular to the surface normal.

Any ideas on how to generate the proper rotation?

14

Some useful things about rotations:

  • Any three orthonormal vectors arranged as rows define a transformation into a new basis (a rotation into that basis).
  • The transpose of any rotation is its inverse.
  • So, any three orthonormal vectors arranged as columns define a rotation from some basis into your "world" reference frame.

So, the problem is to find any set of three orthonormal vectors and arrange them as

| x1 x2 x3  0 |
| y1 y2 y3  0 |
| z1 z2 z3  0 |
|  0  0  0  1 |

this is exactly what the method you described tries to do, if it doesn't work then there is a problem with your implementation.

We can obviously use your normal as (x1,y1,z1), but the problem is the system has infinitely many solutions for the remaining two vectors (although knowing one of them gives you the other, as the cross product). The following code ought to give a stable vector perpendicular to (x1,y1,z1):

float normal[3] = { ... };

int imin = 0;
for(int i=0; i<3; ++i)
    if(std::abs(normal[i]) < std::abs(normal[imin]))
        imin = i;

float v2[3] = {0,0,0};
float dt    = normal[imin];

v2[imin] = 1;
for(int i=0;i<3;i++)
    v2[i] -= dt*normal[i];

This basically uses Gram-Schmidt orthogonalisation with the dimension that is already most orthogonal to the normal vector. v3 can then be obtained by taking the cross product of normal and v2.

You may need to take some care setting up the rotation, it's about the origin so you need to apply the translation after the rotation and it's for column vectors rather than row vectors. If you're using OpenGL watch that OpenGL takes arrays in column major order (rather than C's row major order) so you may need to transpose.

I'm afraid I haven't tested the above, I've merely nabbed it from some code I wrote a while ago and adapted it to your problem! Hopefully I haven't forgotten any details.

Edit: I did forget something :)

The matrix above assumes your normal to the polygon is along the x-axis, and I have a sneaking suspicion it won't be, all you need to do is put the "normal" vector in the correct column of the rotation matrix, and v2/v3 in the other two columns. So if the normal to your polygon is along the z axis, then the normal goes in the 3rd column and v2/v3 go in the first two columns.

Sorry if that causes any confusion.

  • 2
    For a random reason I find myself revisiting this answer, when I select the most orthogonal dimension I should have used the absolute value of the normal vector components - I've corrected this in the answer. – Adam Bowen Sep 22 '11 at 9:09
  • What if the normal isn't along any of the axes? If, instead, it's something like <1, 1, 1>? – Ren Jun 29 '15 at 13:20
  • The algorithm maps an arbitrary normal to lie along one of the axes (or the other way through the inverse), if you want to rotate a normal onto another normal I would find a rotation about the cross product of the two normals. – Adam Bowen Jun 29 '15 at 15:03
2

Not sure what method you are using to render, but borrowing from OpenSceneGraph's matrix:

void Matrix_implementation::makeLookAt(const Vec3d& eye,const Vec3d& center,const Vec3d& up)
{
    Vec3d f(center-eye);
    f.normalize();
    Vec3d s(f^up);
    s.normalize();
    Vec3d u(s^f);
    u.normalize();

    set(
        s[0],     u[0],     -f[0],     0.0,
        s[1],     u[1],     -f[1],     0.0,
        s[2],     u[2],     -f[2],     0.0,
        0.0,     0.0,     0.0,      1.0);

    preMultTranslate(-eye);
}

inline void Matrixd::preMultTranslate( const Vec3d& v )
{
    for (unsigned i = 0; i < 3; ++i)
    {
        double tmp = v[i];
        if (tmp == 0)
            continue;
        _mat[3][0] += tmp*_mat[i][0];
        _mat[3][1] += tmp*_mat[i][1];
        _mat[3][2] += tmp*_mat[i][2];
        _mat[3][3] += tmp*_mat[i][3];
    }
}

Hopefully this will give you an idea for your implementation. I'm not very good with quaternions which might have a simpler solution, but this method works well for me.

  • Hhhmmm... So this would give a rotation matrix for pointing a camera at a specific point? Adapting this to my problem, I would need a vector to rotate to no? – Adam Jan 19 '10 at 20:36
  • This would give a rotation for the camera, you need the eye position (vectors are also positions in OSG), the center position (your P), and then your up vector (N). You say you need to make the surface normal actually the surface normal and I'm not sure what you mean by that. Do you want to be looking directly at the center of the plane from a point on the normal vector? If so, make your eye position a scale of the normalized up. P.S. anyone else think it's funny everyone is named Adam here :) – Adam W Jan 19 '10 at 21:38
  • Ya it does seem to be a common name here :P Sorry if my question is confusing, I don't actually want to do anything with my camera. I want to rotate my polygon so that my Surface Normal, which is calculated some where else, is the same as the Polygon's (if I were to calculate it) – Adam Jan 20 '10 at 2:12
  • Ah right, I probably just jumped to conclusions. Adam Bowen appears to have exactly what you want. – Adam W Jan 20 '10 at 20:11

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