Difference between revisions of "Realization of transformations"
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\begin{align} | \begin{align} | ||
q'' &= e_2\ q'\ e_2^*+ p_2 \\ | q'' &= e_2\ q'\ e_2^*+ p_2 \\ | ||
− | &= e_2\Big(e_1qe_1^*+ p_1\Big)e_2^*+ p_2 \qquad &\text{as | + | &= e_2\Big(e_1qe_1^*+ p_1\Big)e_2^*+ p_2 \qquad &\text{as multiplication of quaternions is distributive} \\ |
&= \Big(e_2e_1qe_1^*+ e_2p_1\Big)e_2^*+ p_2 | &= \Big(e_2e_1qe_1^*+ e_2p_1\Big)e_2^*+ p_2 | ||
\end{align} | \end{align} | ||
</math> | </math> |
Revision as of 16:18, 15 October 2015
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Quaternion notation for general transformations
Up to now transformations have been defined by homogeneous matrices combining a rotation matrix and a translation vector . Now a new notation is introduced to represent a transformation using two quaternions and :
The quaternion is equivalent to and describes the rotation while is defined as and so equivalent to the translation.
Applying such a transformation to a quaternion is done by first rotating with corresponding to the rotation equation and then adding :
Combination of transformations
It is known that a combination of transformations is defined as:
But how can the two quaternions and of the quaternion notation be calculated based on the quaternions of individual transformations? The first transformation leads to
Now the second transformation is applied on :