Here is an elegant method using quaternions that are blazingly fast; I can calculate 10 million rotations per second with appropriately vectorised numpy arrays. It relies on the quaternion extension to numpy found here.
A quaternion is a number with one real and 3 imaginary dimensions usually written as
q = w + xi + yj + zk where 'i', 'j', 'k' are imaginary dimensions. Just as a unit complex number 'c' can represent all 2d rotations by
c=exp(i * theta), a unit quaternion 'q' can represent all 3d rotations by
q=exp(p), where 'p' is a pure imaginary quaternion set by your axis and angle.
We start by converting your axis and angle to a quaternion whose imaginary dimensions are given by your axis of rotation, and whose magnitude is given by half the angle of rotation in radians. The 4 element vectors
(w, x, y, z) are constructed as follows:
import numpy as np
import quaternion as quat
v = [3,5,0]
axis = [4,4,1]
theta = 1.2 #radian
vector = np.array([0.] + v)
rot_axis = np.array([0.] + axis)
axis_angle = (theta*0.5) * rot_axis/np.linalg.norm(rot_axis)
First, a numpy array of 4 elements is constructed with the real component w=0 for both the vector to be rotated
vector and the rotation axis
rot_axis. The axis angle representation is then constructed by normalizing then multiplying by half the desired angle
theta. See here for why half the angle is required.
Now create the quaternions
qlog using the library, and get the unit rotation quaternion
q by taking the exponential.
vec = quat.quaternion(*v)
qlog = quat.quaternion(*axis_angle)
q = np.exp(qlog)
Finally, the rotation of the vector is calculated by the following operation.
v_prime = q * vec * np.conjugate(q)
print(v_prime) # quaternion(0.0, 2.7491163, 4.7718093, 1.9162971)
Now just discard the real element and you have your rotated vector!
v_prime_vec = v_prime.imag # [2.74911638 4.77180932 1.91629719] as a numpy array
Note that this method is particularly efficient if you have to rotate a vector through many sequential rotations, as the quaternion product can just be calculated as q = q1 * q2 * q3 * q4 * ... * qn and then the vector is only rotated by 'q' at the very end using v' = q * v * conj(q).
This method gives you a seamless transformation between axis angle <---> 3d rotation operator simply by
log functions (yes
log(q) just returns the axis-angle representation!). For further clarification of how quaternion multiplication etc. work, see here