# dot product of two quaternion rotations

I understand that the dot (or inner) product of two quaternions is the angle between the rotations (including the axis-rotation). This makes the dot product equal to the angle between two points on the quaternion hypersphere.
I can not, however, find how to actually compute the dot product.

Any help would be appreciated!

current code:

``````public static float dot(Quaternion left, Quaternion right){
float angle;

//compute

return angle;
}
``````

Defined are Quaternion.w, Quaternion.x, Quaternion.y, and Quaternion.z.

Note: It can be assumed that the quaternions are normalised.

The dot product for quaternions is simply the standard Euclidean dot product in 4D:

``````dot = left.x * right.x + left.y * right.y + left.z * right.z + left.w * right.w
``````

Then the angle your are looking for is the `arccos` of the dot product (note that the dot product is not the angle): `acos(dot)`.

However, if you are looking for the relative rotation between two quaternions, say from `q1` to `q2`, you should compute the relative quaternion `q = q1^-1 * q2` and then find the rotation associated with`q`.

Just NOTE: acos(dot) is very not stable from numerical point of view.

as was said previos, q = q1^-1 * q2 and than angle = 2*atan2(q.vec.length(), q.w)

Should it be 2 x acos(dot) to get the angle between quaternions.

• Are you sure about that? I think this is incorrect. Please double-check. (Reference: 3dgep.com/understanding-quaternions) – code_dredd Aug 30 '18 at 5:30
• quaternion dot product will range from 1.0 to 0.0 whereas a 3d orientation vector dot product will range from 1.0 to -1.0 ..so doubling the arcos(dot) seems logical – Isometriq Nov 14 '18 at 17:14