- Axis angle
The axis angle representation of a rotation, also known as the exponential coordinates of a rotation, parameterizes a
rotation by two values: aunit vector indicating the direction of a directed axis (straight line), and anangle describing the magnitude of the rotation about the axis. The rotation occurs in the sense prescribed by theright hand rule .This representation evolves from
Euler's rotation theorem , which implies that any rotation or sequence of rotations of a rigid body in a three-dimensional space is equivalent to a pure rotation about a single fixed axis.The axis angle representation is equivalent to the more concise rotation vector representation. In this case, both the axis and the angle are represented by a non-normalized vector codirectional with the axis whose magnitude is the rotation angle.
Uses
The axis angle representation is convenient when dealing with rigid body dynamics. It is useful to both characterize rotations, and also for converting between different representations of rigid body motion, such as homogeneous transformations and twists.
Example
Say you are standing on the ground and you pick the direction of gravity to be the negative "z" direction. Then if you turn to your left, you will travel radians (or 90 degrees) about the "z" axis. In axis angle representation, this would be:
This can be represented as a rotation vector with a magnitude of pointing in the "z" direction.
:
Relationship to other representations
There are many ways to represent a rotation. It is useful to understand how different representation relate to one another, and how to convert between them.
Exponential map from so(3) to SO(3)
The
exponential map is used as a transformation from axis angle representation of rotations to rotation matrices.:
Essentially, by using a
Taylor expansion you can derive a closed form relationship between these two representations. Given an axis, having length 1, and an angle, , an equivalent rotation matrix is given by the following::
:
:
where R is a 3x3
rotation matrix and thehat operator gives theantisymmetric matrix equivalent of thecross product .Log map from SO(3) to so(3)
To retrieve the axis angle representation of a
rotation matrix calculate the angle of rotation::and then use it to find the normalized axis::Quaternions
To transform from axis angle coordinates to quaternions use the following expression:
:
Given a unit quaternion, the axis angle coordinates can be extracted using the following:
::
See also
*
SO(3) - the group of all rotations in three dimensional space
*rotation group - a mathematical look at rotations
*homogeneous coordinate transformations - a mathematical representation of rigid body motions, including both translation and rotation.
*screw theory - a representation of rigid body motions and velocities using the concepts of twists, screws and wrenches
*Rotation around a fixed axis
*Rotation representation (mathematics)
Wikimedia Foundation. 2010.