I'm having trouble finding any good information on this topic. Basically I want to find the component of a quaternion rotation, that is around a given axis (not necessarily X, Y or Z  any arbitrary unit vector). Sort of like projecting a quaternion onto a vector. So if I was to ask for the rotation around some axis parallel to the quaternion's axis, I'd get the same quaternion back out. If I was to ask for the rotation around an axis orthogonal to the quaternion's axis, I'd get out an identity quaternion. And inbetween... well, that's what I'd like to know how to work out :)

1Orthogonal and perpendicular is the same for vectors. You probably meant parallel for the identity quaternion case. – angularsen Sep 29 '11 at 13:57

1Wow; well noticed! I've read this several times (and have had colleagues independently search for the same thing and find this question) and have never noticed that before. I meant parallel for the nochange case (e.g. the component of a rotation around the Y axis, around the Y axis, will remain unchanged), and have updated the question to reflect that. Thanks! – Ben Hymers Oct 1 '11 at 9:39
I spent the other day trying to find the exact same thing for an animation editor; here is how I did it:
 Take the axis you want to find the rotation around, and find an orthogonal vector to it.
 Rotate this new vector using your quaternion.
 Project this rotated vector onto the plane the normal of which is your axis
The acos of the dot product of this projected vector and the original orthogonal is your angle.
public static float FindQuaternionTwist(Quaternion q, Vector3 axis) { axis.Normalize(); // Get the plane the axis is a normal of Vector3 orthonormal1, orthonormal2; ExMath.FindOrthonormals(axis, out orthonormal1, out orthonormal2); Vector3 transformed = Vector3.Transform(orthonormal1, q); // Project transformed vector onto plane Vector3 flattened = transformed  (Vector3.Dot(transformed, axis) * axis); flattened.Normalize(); // Get angle between original vector and projected transform to get angle around normal float a = (float)Math.Acos((double)Vector3.Dot(orthonormal1, flattened)); return a; }
Here is the code to find the orthonormals however you can probably do much better if you only want the one for the above method:
private static Matrix OrthoX = Matrix.CreateRotationX(MathHelper.ToRadians(90));
private static Matrix OrthoY = Matrix.CreateRotationY(MathHelper.ToRadians(90));
public static void FindOrthonormals(Vector3 normal, out Vector3 orthonormal1, out Vector3 orthonormal2)
{
Vector3 w = Vector3.Transform(normal, OrthoX);
float dot = Vector3.Dot(normal, w);
if (Math.Abs(dot) > 0.6)
{
w = Vector3.Transform(normal, OrthoY);
}
w.Normalize();
orthonormal1 = Vector3.Cross(normal, w);
orthonormal1.Normalize();
orthonormal2 = Vector3.Cross(normal, orthonormal1);
orthonormal2.Normalize();
}
Though the above works you may find it doesn't behave as you'd expect. For example, if your quaternion rotates a vector 90 deg. around X and 90 deg. around Y you'll find if you decompose the rotation around Z it will be 90 deg. as well. If you imagine a vector making these rotations then this makes perfect sense but depending on your application it may not be desired behaviour. For my application  constraining skeleton joints  I ended up with a hybrid system. Matrices/Quats used throughout but when it came to the method to constrain the joints I used euler angles internally, decomposing the rotation quat to rotations around X, Y, Z each time.
Good luck, Hope that helped.


I'm at work at the moment, I'll try this later and if it works I'll be somewhat chuffed :) (meant to put that on a separate line in the previous comment but apparently 'enter' means 'submit' in this particular text box) – Ben Hymers Dec 3 '10 at 10:57

Thank you (though check the first question I asked and its answer and see if you still think so! ;)). Just in case, if you need to decompose a quaternion to eulers (which makes it much easier to recreate), ed022 has a really good implementation here: forums.create.msdn.com/forums/p/4574/62520.aspx (17th post). Good luck with your app! – sebf Dec 4 '10 at 21:09

there is a small problem, the returned value is always positive. which means that if I have a rotation of
PI/4
(or7*PI/4
) I getPI/4
as a result. Am I missing something here? – João Portela Jul 13 '12 at 11:48 
1@João, you are not missing anything but maybe misunderstand slightly how this works :) The core of this method is the acos of the dot product of the resulting vectors  to put it another way  this method does not operate 'directly' on the quaternion but rather 'observes the results' of the application of that quaternion. Therefore, the angle returned will always be the smallest between the two vectors, and will be limited to 0360 deg. You can recover whether the angle of transformation was negative or positive however using the cross product. Good luck! – sebf Jul 13 '12 at 17:20
There is an elegant solution for this problem, specially suited for quaternions. It is known as the "swing twist decomposition":
in pseudocode
/**
Decompose the rotation on to 2 parts.
1. Twist  rotation around the "direction" vector
2. Swing  rotation around axis that is perpendicular to "direction" vector
The rotation can be composed back by
rotation = swing * twist
has singularity in case of swing_rotation close to 180 degrees rotation.
if the input quaternion is of nonunit length, the outputs are nonunit as well
otherwise, outputs are both unit
*/
inline void swing_twist_decomposition( const xxquaternion& rotation,
const vector3& direction,
xxquaternion& swing,
xxquaternion& twist)
{
vector3 ra( rotation.x, rotation.y, rotation.z ); // rotation axis
vector3 p = projection( ra, direction ); // return projection v1 on to v2 (parallel component)
twist.set( p.x, p.y, p.z, rotation.w );
twist.normalize();
swing = rotation * twist.conjugated();
}
And the long answer and derivation of this code can be found here http://www.euclideanspace.com/maths/geometry/rotations/for/decomposition/

This looks like a much better solution with fewer edge cases, and much more efficient... I like it! When I get time I'll compare with the answer I accepted. – Ben Hymers Mar 15 '14 at 12:38

1Please note paper "SWINGTWIST DECOMPOSITION IN CLIFFORD ALGEBRA" with general derivation – minorlogic Aug 5 '15 at 13:08

1@minorlogic this looks great, but how do we deal with the singularity? I probably misunderstand something, but if this solution breaks some small percentage of the time, then surely it's not very useful? – user993683 Sep 14 '15 at 2:54

1singularity can be easy catched checking "twist " length is not zero. it is not present in code above (to simplify code). – minorlogic Sep 21 '15 at 8:07

I tried to implement sebf's answer, it seems good, except that the choice of the choice of vector in step 1:
 Take the axis you want to find the rotation around, and find an orthogonal vector to it.
is not sufficient for repeatable results. I have developed this on paper, and I suggest the following course of action for the choice of the vector orthogonal to the "axis you want to find the rotation around", i.e. axis of observation. There is a plane orthogonal to the axis of observation. You have to project the axis of rotation of your quaternion onto this plane. Using this resulting vector as the vector orthogonal to the axis of observation will give good results.
Thanks to sebf for setting me down the right course.

1If axis of observation equals axis of rotation then that would produce a zerolength vector, so this case would have to be checked. – angularsen Sep 29 '11 at 13:53
Code for Unity3d
// We have some given data
Quaternion rotation = ...;
Vector3 directionAxis = ...;
// Transform quaternion to angleaxis form
rotation.ToAngleAxis(out float angle, out Vector3 rotationAxis);
// Projection magnitude is what we found  a component of a quaternion rotation around an axis to some direction axis
float proj = Vector3.Project(rotationAxis.normalized, directionAxis.normalized).magnitude;