# 3D rotations of a plane

I'm doing something where I have a plane in a coord sys A with a set of points already on it. I also have a normal vector in space N. How can I rotate the points on coord sys A so that the underlying plane will have the same normal direction as N?

Wondering if any one has a good idea on how to do this. Thanks

If you have, or can easily compute, the normal vector to the plane that your points are currently in, I think the easiest way to do this will be to rotate around the axis common to the two planes. Here's how I'd go about it:

1. Let `M` be the vector normal to your current plane, and `N` be the vector normal to the plane you want to rotate into. If `M == N` you can stop now and leave the original points unchanged.
2. Calculate the rotation angle as

``````costheta = dot(M,N)/(norm(M)*norm(N))
``````
3. Calculate the rotation axis as

``````axis = unitcross(M, N)
``````

where `unitcross` is a function that performs the cross product and normalizes it to a unit vector, i.e. `unitcross(a, b) = cross(a, b) / norm(cross(a, b))`. As user1318499 pointed out in a comment, this step can cause an error if `M == N`, unless your implementation of `unitcross` returns `(0,0,0)` when `a == b`.

4. Compute the rotation matrix from the axis and angle as

``````c = costheta
s = sqrt(1-c*c)
C = 1-c
rmat = matrix([ x*x*C+c    x*y*C-z*s  x*z*C+y*s ],
[ y*x*C+z*s  y*y*C+c    y*z*C-x*s ]
[ z*x*C-y*s  z*y*C+x*s  z*z*C+c   ])
``````

where `x`, `y`, and `z` are the components of `axis`. This formula is described on Wikipedia.

5. For each point, compute its corresponding point on the new plane as

``````newpoint = dot(rmat, point)
``````

where the function `dot` performs matrix multiplication.

This is not unique, of course; as mentioned in peterk's answer, there are an infinite number of possible rotations you could make that would transform the plane normal to `M` into the plane normal to `N`. This corresponds to the fact that, after you take the steps described above, you can then rotate the plane around `N`, and your points will be in different places while staying in the same plane. (In other words, each rotation you can make that satisfies your conditions corresponds to doing the procedure described above followed by another rotation around `N`.) But if you don't care where in the plane your points wind up, I think this rotation around the common axis is the simplest way to just get the points into the plane you want them in.

If you don't have `M`, but you do have the coordinates of the points in your starting plane relative to an origin in that plane, you can compute the starting normal vector from two points' positions `x1` and `x2` as

``````M = cross(x1, x2)
``````

(you can also use `unitcross` here but it doesn't make any difference). If you have the points' coordinates relative to an origin that is not in the plane, you can still do it, but you'll need three points' positions:

``````M = cross(x3-x1, x3-x2)
``````
• +1 Good answer. The only gripe (to the extent it rises to the level of a gripe, which is questionable) I have is you didn't mention Quaternion Rotation as a possible alternative to steps 4 and 5. They are somewhat more efficient. Feb 24, 2012 at 3:26
• @andand: usually I'm doing this sort of thing analytically, so I'm not completely familiar with quaternions. But if I have time I'll edit that in. Feb 24, 2012 at 6:22
• where do you use axis? May 12, 2014 at 18:28
• @cagirici the components of `axis` are the `x`, `y`, and `z` that appear in the formula for the rotation matrix. May 12, 2014 at 18:30
• @DavidZ one more question: What do I do if I want to shift the plane with respect to the `d` component? May 12, 2014 at 18:31

A single vector (your normal - N) will not be enough. You will need another two vectors for the other two dimensions. (Imagine that your 3D space could still rotate/spin around the normal vector, and you need another 2 vectors to nail it down). Once you have the normal and another one on the plane, the 3rd one should be easy to find (left- or right-handed depending on your system).

Make sure all three are normalized (length of 1) and put them in a matrix; use that matrix to transform any point in your 3D space (use matrix multiplication). This should give you the new coordinates.

• Makes sense! I will need to figure out a way to get the other vector :S Thanks! Feb 24, 2012 at 0:53

I'm thinking make a unit vector [0,0,1] and use the dot-product along two planes to find the angle of difference, and shift all your points by those angles. This is assuming you want the z-axis to align with the normal vector, else just use [1,0,0] or [0,1,0] for x and y respectively.

• Wouldn't this align the z-axis only? there will be more Dof's in either x or y Feb 24, 2012 at 0:41