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I have two vectors as Python lists and an angle. E.g.:

v = [3,5,0]
axis = [4,4,1]
theta = 1.2 #radian

What is the best/easiest way to get the resulting vector when rotating the v vector around the axis?

The rotation should appear to be counter clockwise for an observer to whom the axis vector is pointing. This is called the right hand rule

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I find it very surprising that there is no functionality for this in SciPy (or similar easily accessible package); vector rotation isn't that exotic. – Mads Skjern Jul 23 '11 at 19:51
up vote 3 down vote accepted

Take a look at http://vpython.org/contents/docs/visual/VisualIntro.html.

It provides a vector class which has a method A.rotate(theta,B). It also provides a helper function rotate(A,theta,B) if you don't want to call the method on A.


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Using the Euler-Rodrigues formula:

import numpy as np
import math

def rotation_matrix(axis, theta):
    Return the rotation matrix associated with counterclockwise rotation about
    the given axis by theta radians.
    axis = np.asarray(axis)
    theta = np.asarray(theta)
    axis = axis/math.sqrt(np.dot(axis, axis))
    a = math.cos(theta/2.0)
    b, c, d = -axis*math.sin(theta/2.0)
    aa, bb, cc, dd = a*a, b*b, c*c, d*d
    bc, ad, ac, ab, bd, cd = b*c, a*d, a*c, a*b, b*d, c*d
    return np.array([[aa+bb-cc-dd, 2*(bc+ad), 2*(bd-ac)],
                     [2*(bc-ad), aa+cc-bb-dd, 2*(cd+ab)],
                     [2*(bd+ac), 2*(cd-ab), aa+dd-bb-cc]])

v = [3, 5, 0]
axis = [4, 4, 1]
theta = 1.2 

print(np.dot(rotation_matrix(axis,theta), v)) 
# [ 2.74911638  4.77180932  1.91629719]
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@bougui: Using np.linalg.norm instead of np.sqrt(np.dot(...)) seemed like a nice improvement to me, but timeit tests showed np.sqrt(np.dot(...)) was 2.5x faster than np.linalg.norm, at least on my machine, so I'm sticking with np.sqrt(np.dot(...)). – unutbu Oct 9 '12 at 12:51
sqrt from the Python math module is even faster on scalars. scipy.linalg.norm may be faster than np.linalg.norm; I've submitted a patch to NumPy that changes linalg.norm to use dot, but it hasn't been merged yet. – Fred Foo Dec 29 '13 at 13:54
@larsman: Thanks for the info. I didn't know math.sqrt is (at the moment) so much faster than np.sqrt on scalars (about 18x on my machine). – unutbu Dec 29 '13 at 14:17
I suppose math.sqrt will always be faster than np.sqrt when operating on scalars since np.sqrt's overall performance would be slowed if it had to check its input for scalars. – unutbu Dec 29 '13 at 14:28
This is very neat, would you be so kind to add the equivalent for 2D? I know that for rotating w.r.t OX axis we can just compute new coords as: (x*np.cos(theta)-y*np.sin(theta), x*np.sin(theta)+y*np.cos(theta)), but how should this be modified when the axis of rotation is not OX any longer? thanks for any tips. – user929304 May 18 at 14:33

A one-liner, with numpy/scipy functions.

We use the following:

let a be the unit vector along axis, i.e. a = axis/norm(axis)
and A = I × a be the skew-symmetric matrix associated to a, i.e. the cross product of the identity matrix with a

then M = exp(θ A) is the rotation matrix.

from numpy import cross, eye, dot
from scipy.linalg import expm3, norm

def M(axis, theta):
    return expm3(cross(eye(3), axis/norm(axis)*theta))

v, axis, theta = [3,5,0], [4,4,1], 1.2
M0 = M(axis, theta)

# [ 2.74911638  4.77180932  1.91629719]

expm3 (code here) computes the taylor series of the exponential:
\sum_{k=0}^{20} \frac{1}{k!} (θ A)^k , so it's time expensive, but readable and secure. It can be a good way if you have few rotations to do but a lot of vectors.

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This is my favorite solution by far. Though I don't understand why such a seemingly simple operation requires 2 libraries. – NcAdams Jul 28 '15 at 20:52
that is the strangest thing I have seen in a while, it works though! – jason Jan 24 at 7:51

I just wanted to mention that if speed is required, wrapping unutbu's code in scipy's weave.inline and passing an already existing matrix as a parameter yields a 20-fold decrease in the running time.

The code (in rotation_matrix_test.py):

import numpy as np
import timeit

from math import cos, sin, sqrt
import numpy.random as nr

from scipy import weave

def rotation_matrix_weave(axis, theta, mat = None):
    if mat == None:
        mat = np.eye(3,3)

    support = "#include <math.h>"
    code = """
        double x = sqrt(axis[0] * axis[0] + axis[1] * axis[1] + axis[2] * axis[2]);
        double a = cos(theta / 2.0);
        double b = -(axis[0] / x) * sin(theta / 2.0);
        double c = -(axis[1] / x) * sin(theta / 2.0);
        double d = -(axis[2] / x) * sin(theta / 2.0);

        mat[0] = a*a + b*b - c*c - d*d;
        mat[1] = 2 * (b*c - a*d);
        mat[2] = 2 * (b*d + a*c);

        mat[3*1 + 0] = 2*(b*c+a*d);
        mat[3*1 + 1] = a*a+c*c-b*b-d*d;
        mat[3*1 + 2] = 2*(c*d-a*b);

        mat[3*2 + 0] = 2*(b*d-a*c);
        mat[3*2 + 1] = 2*(c*d+a*b);
        mat[3*2 + 2] = a*a+d*d-b*b-c*c;

    weave.inline(code, ['axis', 'theta', 'mat'], support_code = support, libraries = ['m'])

    return mat

def rotation_matrix_numpy(axis, theta):
    mat = np.eye(3,3)
    axis = axis/sqrt(np.dot(axis, axis))
    a = cos(theta/2.)
    b, c, d = -axis*sin(theta/2.)

    return np.array([[a*a+b*b-c*c-d*d, 2*(b*c-a*d), 2*(b*d+a*c)],
                  [2*(b*c+a*d), a*a+c*c-b*b-d*d, 2*(c*d-a*b)],
                  [2*(b*d-a*c), 2*(c*d+a*b), a*a+d*d-b*b-c*c]])

The timing:

>>> import timeit
>>> setup = """
... import numpy as np
... import numpy.random as nr
... from rotation_matrix_test import rotation_matrix_weave
... from rotation_matrix_test import rotation_matrix_numpy
... mat1 = np.eye(3,3)
... theta = nr.random()
... axis = nr.random(3)
... """
>>> timeit.repeat("rotation_matrix_weave(axis, theta, mat1)", setup=setup, number=100000)
[0.36641597747802734, 0.34883809089660645, 0.3459300994873047]
>>> timeit.repeat("rotation_matrix_numpy(axis, theta)", setup=setup, number=100000)
[7.180983066558838, 7.172032117843628, 7.180462837219238]
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I made a fairly complete library of 3D mathematics for Python{2,3}. It still does not use Cython, but relies heavily on the efficiency of numpy. You can find it here with pip:

python[3] -m pip install math3d

Or have a look at my gitweb http://git.automatics.dyndns.dk/?p=pymath3d.git and now also on github: https://github.com/mortlind/pymath3d .

Once installed, in python you may create the orientation object which can rotate vectors, or be part of transform objects. E.g. the following code snippet composes an orientation that represents a rotation of 1 rad around the axis [1,2,3], applies it to the vector [4,5,6], and prints the result:

import math3d as m3d
r = m3d.Orientation.new_axis_angle([1,2,3], 1)
v = m3d.Vector(4,5,6)
print(r * v)

The output would be

<Vector: (2.53727, 6.15234, 5.71935)>

This is more efficient, by a factor of approximately four, as far as I can time it, than the oneliner using scipy posted by B. M. above. However, it requires installation of my math3d package.

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