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.

Quaternion Theory:
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 `v`

and `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 `exp`

and `log`

functions (yes `log(q)`

just returns the axis-angle representation!). For further clarification of how quaternion multiplication etc. work, see here