Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Is there any possibility to limit quaternions to move only in x & y axis (like in Eulers- yaw and pitch, without rolling)? I's there any equation or something similar to do this?

Some example:

Movement should behave like this: http://360.art.pl/experimental/1/
But when I build my player on quaternions it has no limits and I don't know how to fix it http://360.art.pl/experimental/2/

share|improve this question
I'd love to help but quaternions totally do my head in. You might find some useful stuff regarding this over on Gamedev.se: gamedev.stackexchange.com/search?q=quaternion –  glenatron Jul 25 '12 at 9:43

2 Answers 2

Let me first describe the kind of constraint you're talking about. Given an world_up vector, you want to limit your rotation such that it appears vertical with respect to the camera. If the camera view coordinates are labeled camera_up, camera_right, and camera_forward:

constrain rotation matrix R such that:  dot(R*world_up, camera_right) == 0

This can be done straightforwardly (e.g., in LookAt()-like functions) by constructing a set of perpendicular coordinate vectors as a function of the view direction, view_forward:

given vectors:  view_forward, world_up

Rot_forward = normalize(view_forward)
Rot_right = normalize( cross(view_forward, world_up) )
Rot_up = cross(Rot_right, Rot_forward)

To answer the question: I could be wrong, but I don't think this kind of constraint is straightforward to implement in terms of quaternions. It would be easier to generate the rotation matrix as above, and convert it to a quaternion.

That does raise a question: what problem are you trying to solve by using quaternions here?

  • if you need quaternions to interface with some other system or library, that's fine.
  • if you're trying to fix bad behavior, where the scene rotates quickly when your viewpoint is near the zenith, note that this is a consequence of your constraint: it will happen regardless of how you implement it.
  • if you're trying to use quaternions to get a more natural interpolation, note that your constraint renders this moot: a natural quaternion interpolation will violate the constraint. Given the constraint, it would be more natural to interpolate your view_forward vector, instead of your quaternion.
share|improve this answer

You can try to construct quaternions directly from yaw/pitch:

q = quat_from_axis_angle(up_vector, yaw) * quat_from_axis_angle(local_right, pitch)

(you may have to multiply these in the reverse order depending on how exactly you turn them into rotation matrices), or realign them every time you change them:

rotated_right = apply_rotation(q, local_right);
projected_right = rotated_right - dot(rotated_right, up_vector) * up_vector;
realign = quat_align_vector(rotated_right, normalized(projected_right));
q = realign * q

projected_right here is a projection of rotated_right onto the horizontal plane. Without rolling, these two vectors must be the same, which implies dot(rotated_right, up_vector) = 0. The last equation is the actual constraint that must be satisfied. It is quadratic in q. E.g. for local_right=(1,0,0), and up_vector=(0,0,1), it becomes dot(q*(1i+0j+0k)*conj(q), 0i+0j+1k)=2*x*z-2*w*y=0, with q=w+xi+yi+zk.

You can find formulas for quat_from_axis_angle and apply_rotation at http://en.wikipedia.org/wiki/Quaternion and http://en.wikipedia.org/wiki/Quaternions_and_spatial_rotation. As for quat_align_vector, one way would be

quat_align_vector(src, dst) = sqrt([dot(src, dst), cross(src, dst)])

with [a, b] beign a quaternion with a real part a, and an imaginary part b. Sqrt(x) can be calculated as exp(ln(x)/2) (these functions are on the wiki, too). You could also try replacing sqrt with exp(ln(x)/2*tick*realign_rate) for a smooth restoration of the up-vector :) . Or go the opposite way and simplify the formula a bit:

quat_align_vector(src, dst) = [dot(halfway, dst), cross(halfway, dst)],
halfway = normalized(normalized(src) + normalized(dst))

See also http://stackoverflow.com/a/1171995.

EDIT: corrected vectors, added the constraint.

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.