I have been trying to find the difference between the 2 but to no luck minus this

The primary diff erence between the two representations is that a quaternion’s axis of rotation is scaled by the sine of the half angle of rotation, and instead of storing the angle in the fourth component of the vector, we store the cosine of the half angle.

I have no idea what

sine of the half angle of rotation


cosine of the half angle



Quaternios and Axis-angle are both 4D representations of 3D rotations/orientations and both have pro's and cons.

Axis-angle: represents the rotation by its angle a and the rotation axis n. For example, a rotation of 180 degrees around the Y-Axis would be represented as a = 180, n= {0,1,0}. The representation is very intuitive, but for actually applying the rotation, another representation is required, such as a quaternion or rotation matrix.

Quaternion: represents a rotation by a 4D vector. Requires more math and is less intuitive, but is a much more powerful representation. Quaternions are easily interpolated (blending) and it is easy to apply them on 3D point. These formula's can easily be found on the web. Given a rotation of a radians about a normalized axis n, the quaternion 4D vector will be {cos a/2, (sin a/2) n_x, (sin a/2) n_y, (sin a/2) n_z}. That's where the sine and cosine of the half angle come from.

  • Out of curiosity, are there any powerful representations that use less math but maybe use more numbers? I assume that you could pile up Axis-Angle representations to mimic Euclidean for example. – Aaron Franke Aug 5 '18 at 4:50
  • @Aaron Franke I sometimes use a vector representation where the direction of the vector is the rotation axis and the norm of the vector the rotation. I believe this is sometimes called the Exponential Map or Quaternion Log. If two of these are close together, you can actually Euclidean interpolate between them. – Ben Sep 27 '19 at 19:04

It means that if you, for example, want to make a 180deg rotation around the Z axis (0,0,1), then the quaternion's real part will be cos(180deg/2)=0, and its imaginary part will be sin(180deg/2)*(0,0,1)=(0,0,1). That's q=0+0i+0j+1k. 90-degree rotation will give you q=cos(90deg/2)+sin(90deg/2)*(0i+0j+1k)=sqrt(2)/2+0i+0j+sqrt(2)/2*k, and so on.

OTOH, if you're asking what sine and cosine are, check if your languange provides sin() and cos() functions (their arguments will probably be in radians, though), and check out http://en.wikipedia.org/wiki/Sine.

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