Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I have the following problem: A quaternion (q1) from a motion capturing device needs to be corrected by the yaw angle (and only yaw!) from another orientation quaternion (q2) derived by a second tracked object, so that the pitch and roll of q1 is the same as before but q1 has the yaw of q2.

The working solution is converting the quats to matrices, then I do the calculations to extract the rotation angle and then I do the heading correction. But this results in a "flipping" when directly in direction of a certain axis (e.g. after 0° - 359°). Also tried other conversions which are not convenient.

Is there any possibility to do the math directly on the quaternions without conversions to matrices or euler angles (i.e. so I can set the corrected quaternion as quaternion for the tracked object)?

As said - the correction should include only the rotation around the up-axis (yaw). I have not many programming possibilities regarding math classes (VSL Script from Virtools is unfortunately pretty limited in this direction). Anyone has some advice?

share|improve this question
I think this is something for math.stackexchange.com – Ishtar May 30 '11 at 15:22
Thanks for this hint - didn´t know that a special math board exists :) – Raboon May 31 '11 at 10:14

Short answer: Yes it is possible. You can formulate rotations (about an arbitrary axis) and perform it with quaternion operations.

Long answer: See the Wikipedia article on Quaternions and rotations. I guess the problem you describe is the gimbal lock.

share|improve this answer
Thanks for the answer. I know that it has to be possible - i also know some of the quaternion math. However, for the special problem stated above I don´t know the best solution to start with it. – Raboon May 31 '11 at 10:16

For this task euler angles are the best thing to use, as their advantage (the only advantage at all) lies in the separation into individual roations around orthogonal axes. So convert both quaternions to an euler angle convention that fits your needs and just substitute q1's yaw angle by q2's.

Of course you need to use a matching euler angle convention, one where the other rotations don't depend on the yaw angle (so the yaw rotation is applied first when transforming a point?), so that you can just change the angle without influencing the other axes. When converting the resulting euler angle triple back to a quaternion, you should get a unique representation again, or am I missing something?

share|improve this answer
Thanks for that answer. But with the conversion to the Euler-Angles and back I have the definition problem +90 to -90 degrees. What I need is a solution defined for 360°. Maybe I´m just getting it wrong. – Raboon Jun 15 '11 at 10:21
@Raboon It's just about factoring out the rotation about one axis and then changing this rotation. I'm not sure if you really run into ambiguity or gimbal lock problems, but I'm ready to be convinced of the opposite. – Christian Rau Jun 15 '11 at 10:49

If you have quaternions Q1 and Q2 and your 'up' direction is y, then if you take out the y component of Q1 and renormalize, then you get a quaternion with no yaw component. Likewise, if you take out the x and z components of Q2, then you get a quaternion with only the yaw component. Multiply the second to the first (using quaternion multiplication) and you're there.

Q1[2] = 0;
Q2[1] = 0;
Q2[3] = 0;
Q3 = quatMult(Q2,Q1);

Of course, you might want to check the special case where there has been a rotation by exactly (or close to) 180 degrees since that can make things numerically unstable when you try to normalize a vector with very small magnitude.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.