I am trying to find the Euler angles that allow the transformation from point `A`

to point `B`

in 3D space.

Consider the normalized vectors `A = [1, 0, 0]`

and `B = [0.32 0.88 -0.34]`

.

I understand that by computing the **cross product** `A × B`

I get the rotation axis. The **angle** between `A`

and `B`

is given by `tan⁻¹(||cross||, A·B)`

, where `A·B`

is the **dot product** between `A`

and `B`

.

This gives me the rotation vector `rotvec = [0 0.36 0.93 1.24359531111]`

, which is `rotvec = [A × B; angle]`

(the cross product is normalized).

Now my question is: *How do I move from here to get the Euler angles that correspond to the transformation from A to B*?

In MATLAB the function vrrotvec2mat receives as input a rotation vector and outputs a rotation matrix. Then the function rotm2eul should return the corresponding Euler angles. I get the following result (in radians): `[0.2456 0.3490 1.2216]`

, according to the `XYZ`

convention. Yet, this is not the expected result.

The correct answer is `[0 0.3490 1.2216]`

that corresponds to a rotation of `20°`

and `70°`

in `Y`

and `Z`

, respectively.

When I use `eul2rot([0 0.3490 1.2216])`

(with `eul2rot`

taken from here) to verify the resulting rotation matrix, this one is different from the one I obtain when using `vrrotvec2mat(rotvec)`

.

I also have a Python spinet that yields the exactly same results as described above.

--- Python (2.7) using transform3d ---

```
import numpy as np
import transforms3d
cross = np.cross(A, B)
dot = np.dot(A, B.transpose())
angle = math.atan2(np.linalg.norm(cross), dot)
rotation_axes = sklearn.preprocessing.normalize(cross)
rotation_m = transforms3d.axangles.axangle2mat(rotation_axes[0], angle, True)
rotation_angles = transforms3d.euler.mat2euler(rotation_m, 'sxyz')
```

What I am missing here? What should I be doing instead?

Thank you