Given the old normal
N and the new normal
N' you can obtain the rotation by:
RotationAxis = cross(N, N')
RotationAngle = arccos(dot(N, N') / (|N| * |N'|))
cross(x, y) is the cross product of the vectors
dot(x, y) is the dot product of the vectors
|x| is the length of the vector
This will rotate the old normal onto the new one by the shortest way possible.
RotationAngle will be in radians (if arccos returns radians as it does in most implementations)
arccos is the inverse of the cosine function. It is necessary because
dot(N, N') = |N| * |N'| * cos(RotationAngle) where
RotationAngle is the angle between the vectors.
RotationAxis is not normalized
- If both normals are normalized the division by
(|N| * |N'|) becomes unnecessary (in fact if
N is normalized you can leave out
|N| of the product and if
N' is normalized then leave out
- This method will fail if
N' = -N (as there are infinite many shortest ways)
How does it work?
The first observation is that the two normals will always define (at least) one plane in which both are lying. The smallest angle that parts them will be measured inside this plane too.
RotationAxis vector will be the normal of the plane that encloses both
N' and the
RotationAngle is the smallest angle between the two mentioned earlier.
So by rotating around
RotationAxis by the
RotationAngle the old normal
N is rotated inside the plane, on the shortest path towards