I need to flip a quaternion from right:
x = left to right
y = front to back
z = top to bottom
to left handed coordinates where:
x = left to right
y = top to bottom
z = front to back
How would I go about doing this?
I need to flip a quaternion from right:
x = left to right
y = front to back
z = top to bottom
to left handed coordinates where:
x = left to right
y = top to bottom
z = front to back
How would I go about doing this?
I don't think any of these answers is correct.
Andres is correct that quaternions don't have handedness (*). Handedness (or what I'll call "axis conventions") is a property that humans apply; it's how we map our concepts of "forward, right, up" to the X, Y, Z axes.
These things are true:
mat_to_quat()
routine may not blow up, but it won't give you the right answer (in the sense that quat_to_mat(mat_to_quat(M)) == M
).To change the basis of a quaternion, say from ROS (right-handed) to Unity (left-handed), we can use the method of .
mat3x3 ros_to_unity = /* construct this by hand */;
mat3x3 unity_to_ros = ros_to_unity.inverse();
quat q_ros = ...;
mat3x3 m_unity = ros_to_unity * mat3x3(q_ros) * unity_to_ros ;
quat q_unity = mat_to_quat(m_unity);
Lines 1-4 are simply the method of https://stackoverflow.com/a/39519079/194921: "How do you perform a change-of-basis on a matrix?"
Line 5 is interesting. We know mat_to_quat()
only works on pure-rotation matrices. How do we know that m_unity
is a pure rotation? It's certainly conceivable that it's not, because unity_to_ros
and ros_to_unity
both have determinant -1 (as a result of the handedness switch).
The hand-wavy answer is that the handedness is switching twice, so the result has no handedness switch. The deeper answer has to do with the fact that similarity transformations preserve certain aspects of the operator, but I don't have enough math to make the proof.
Note that this will give you a correct result, but you can probably do it more quickly if unity_to_ros
is a simple matrix (say, with just an axis swap). But you should probably derive that faster method by expanding the math done here.
(*) Actually, there is the distinction between Hamilton and JPL quaternions; but everybody uses Hamilton so there's no need to muddy the waters with that.
I think that the solution is:
Given: Right Hand: {w,x,y,z}
Convert: Left Hand: {-w,z,y,x}
In unity:
new Quaternion(rhQz,rhQy,rhQx,-rhQw)
Ok, just to be clear, quaternions don't actually have handedness. They are handless(see wikipedia article on quaternions). HOWEVER, the conversion to a matrix from a quaternion does have handedness associated with it. See http://osdir.com/ml/games.devel.algorithms/2002-11/msg00318.html If your code performs this conversion, you may have to have two separate functions to convert to a left handed matrix or a right handed matrix.
Hope that helps.
Once you do that, you no longer have a quaternion, i.e. the usual rules for multiplying them won't work. The identity i^2 = j^2 = k^2 = ijk = -1 will no longer hold if you swap j and k (y and z in your right handed system).
http://www.gamedev.net/community/forums/topic.asp?topic_id=459925
To paraphrase, negate the axis.
I know this question is old, but the method below is tested and works. I used pyquaternion to manipulate the quaternions.
To go from right to left. Find the axis and angle of the right hand quaternion. Then convert the axis to left hand coordinates. Negate the right hand angle to get the left hand angle. Construct quaternion with left handed axis and left hand angle.