Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

We have a gazillion spatial coordinates (x, y and z) representing atoms in 3d space, and I'm constructing a function that will translate these points to a new coordinate system. Shifting the coordinates to an arbitrary origin is simple, but I can't wrap my head around the next step: 3d point rotation calculations. In other words, I'm trying to translate the points from (x, y, z) to (x', y', z'), where x', y' and z' are in terms of i', j' and k', the new axis vectors I'm making with the help of the euclid python module.

I think all I need is a euclid quaternion to do this, i.e.

>>> q * Vector3(x, y, z)
Vector3(x', y', z')

but to make THAT i believe I need a rotation axis vector and an angle of rotation. But I have no idea how to calculate these from i', j' and k'. This seems like a simple procedure to code from scratch, but I suspect something like this requires linear algebra to figure out on my own. Many thanks for a nudge in the right direction.

share|improve this question
just to clarify, you want a linear transformation from one euclidean 3-space to another euclidean 3-space? – ThomasMcLeod Feb 2 '11 at 3:11
Here's a hint: What would the vectors (0, 0, 1), (0, 1, 0) and (1, 0, 0) be translated to? – Anon. Feb 2 '11 at 3:13
up vote 32 down vote accepted

Using quaternions to represent rotation is not difficult from an algebraic point of view. Personally, I find it hard to reason visually about quaternions, but the formulas involved in using them for rotations are quite simple. I'll provide a basic set of reference functions here; see this page for more.

You can think of quaternions (for our purposes) as a scalar plus a 3-d vector -- abstractly, w + xi + yj + zk, here represented by a simple tuple (w, x, y, z). The space of 3-d rotations is represented in full by a sub-space of the quaternions, the space of unit quaternions, so you want to make sure that your quaternions are normalized. You can do so in just the way you would normalize any 4-vector (i.e. magnitude should be close to 1; if it isn't, scale down the values by the magnitude):

def normalize(v, tolerance=0.00001):
    mag2 = sum(n * n for n in v)
    if abs(mag2 - 1.0) > tolerance:
        mag = sqrt(mag2)
        v = tuple(n / mag for n in v)
    return v

Please note that for simplicity, the following functions assume that quaternion values are already normalized. In practice, you'll need to renormalize them from time to time, but the best way to deal with that will depend on the problem domain. These functions provide just the very basics, for reference purposes only.

Every rotation is represented by a unit quaternion, and concatenations of rotations correspond to multiplications of unit quaternions. The formula1 for this is as follows:

def q_mult(q1, q2):
    w1, x1, y1, z1 = q1
    w2, x2, y2, z2 = q2
    w = w1 * w2 - x1 * x2 - y1 * y2 - z1 * z2
    x = w1 * x2 + x1 * w2 + y1 * z2 - z1 * y2
    y = w1 * y2 + y1 * w2 + z1 * x2 - x1 * z2
    z = w1 * z2 + z1 * w2 + x1 * y2 - y1 * x2
    return w, x, y, z

To rotate a vector by a quaternion, you need the quaternion's conjugate too. That's easy:

def q_conjugate(q):
    w, x, y, z = q
    return (w, -x, -y, -z)

Now quaternion-vector multiplication is as simple as converting a vector into a quaternion (by setting w = 0 and leaving x, y, and z the same) and then multiplying q * v * q_conjugate(q):

def qv_mult(q1, v1):
    q2 = (0.0,) + v1
    return q_mult(q_mult(q1, q2), q_conjugate(q1))[1:]

Finally, you need to know how to convert from axis-angle rotations to quaternions. Also easy! It makes sense to "sanitize" input and output here by calling normalize.

def axisangle_to_q(v, theta):
    v = normalize(v)
    x, y, z = v
    theta /= 2
    w = cos(theta)
    x = x * sin(theta)
    y = y * sin(theta)
    z = z * sin(theta)
    return w, x, y, z

And back:

def q_to_axisangle(q):
    w, v = q[0], q[1:]
    theta = acos(w) * 2.0
    return normalize(v), theta

Here's a quick usage example. A sequence of 90-degree rotations about the x, y, and z axes will return a vector on the y axis to its original position. This code performs those rotations:

x_axis_unit = (1, 0, 0)
y_axis_unit = (0, 1, 0)
z_axis_unit = (0, 0, 1)
r1 = axisangle_to_q(x_axis_unit, numpy.pi / 2)
r2 = axisangle_to_q(y_axis_unit, numpy.pi / 2)
r3 = axisangle_to_q(z_axis_unit, numpy.pi / 2)

v = qv_mult(r1, y_axis_unit)
v = qv_mult(r2, v)
v = qv_mult(r3, v)

print v
# output: (0.0, 1.0, 2.220446049250313e-16)

Keep in mind that this sequence of rotations won't return all vectors to the same position; for example, for a vector on the x axis, it will correspond to a 90 degree rotation about the y axis. (Keep the right-hand-rule in mind here; a positive rotation about the y axis pushes a vector on the x axis into the negative z region.)

v = qv_mult(r1, x_axis_unit)
v = qv_mult(r2, v)
v = qv_mult(r3, v)

print v
# output: (4.930380657631324e-32, 2.220446049250313e-16, -1.0)

As always, please let me know if you find any problems here.

1. The quaternion multiplication formula looks like a crazy rat's nest, but the derivation is simple (if tedious). Just note first that ii = jj = kk = -1; then that ij = k, jk = i, ki = j; and finally that ji = -k, kj = -i, ik = -j. Then multiply the two quaternions, distributing out the terms and rearranging them based on the results of each of the 16 multiplications. This also helps to illustrate why you can use quaternions to represent rotation; the last six identities follow the right-hand rule, creating bijections between rotations from i to j and rotations around k, and so on.

share|improve this answer
I hope you don't mind, I fixed a couple of code typos (see edits). In addition, for qv_mult to be useful it should return a vector, not a quaternion so I've dropped the first component (which is zero anyways!). – Hooked Oct 11 '12 at 20:06
@Hooked, quite right, thanks! – senderle Oct 11 '12 at 20:19
I think the first line of qv_mult should be q1 = normalize(q1) (not v1)? – Racing Tadpole Mar 9 '15 at 0:53
@RacingTadpole, I guess it depends on what needs to be normalized? For simplicity I wrote the multiplication routines under the assumption that incoming quaternions are already normalized. And I believe the incoming vector needs to be normalized so that it doesn't blow up over the course of several multiplications (which is why I included it in that case). – senderle Mar 9 '15 at 2:47
Hi, thanks @senderle. I'm not across all the details, so I may have missed something, but I'm using qv_mult to rotate an arbitrary vector v through a rotation defined by q. In this case, the vector's length is important - I want a length 2 vector to remain a length 2 vector after rotation. – Racing Tadpole Mar 9 '15 at 5:10

Note that the inversion of matrix is not that trivial at all! Firstly, all n (where n is the dimension of your space) points must be in general position (i.e. no individual point can be expressed as a linear combination of rest of the points [caveat: this may seem to be a simple requirement indeed, but in the realm of numerical linear algebra, it's nontrivial; final decison wheter such configuration really exist or not, will eventually be based on the 'actual domain' specific knowledge]).

Also the 'correspondence' of the new and old points may not be exact (and then you should utilize the best possible approximator of the 'true correspondence', i.e.:). Pseudo inverse (instead of trying to utilize the plain inverse) is recommend allways when your lib provides it.

The pseudo inverse has the advantage that you'll be able to use more points for your transformation, hence increasing the probability that at least n points will be in general position.

Here is an example, rotation of unit square 90 deg. ccw in 2D (but obviously this determination works in any dim), with numpy:

In []: P=  matrix([[0, 0, 1, 1],
                   [0, 1, 1, 0]])
In []: Pn= matrix([[0, -1, -1, 0],
                   [0,  0,  1, 1]])
In []: T= Pn* pinv(P)
In []: (T* P).round()
matrix([[ 0., -1., -1.,  0.],
        [ 0.,  0.,  1.,  1.]])

P.S. numpy is also fast. Transformation of 1 million points in my modest computer:

In []: P= matrix(rand(2, 1e6))
In []: %timeit T* P
10 loops, best of 3: 37.7 ms per loop
share|improve this answer
thank you for this, numpy looks like a very attractive alternative to euclid. my main roadblock was simply figuring out the math without a background in linear algebra. [xyz]*[i'j'k']^-1=[x'y'z'] was the missing part. – Fancypants_MD Feb 2 '11 at 20:02

Quaternions are the old school (very old school, it went out of favor a century ago) to do this kind of operation. The standard way to do it these days is to use matrices.

The easiest way to generate the right matrix is the following. You have figured out what i', j', and k' are. Let's assume that you're writing those as columns (the i coordinate on top, j in the middle, k at the bottom). Then the matrix A to convert from (i', j', k') coordinates to (i, j, k) is just the matrix [i' j' k']. (This is, in fact, a square 3x3 matrix.) Then the inverse of this matrix is the matrix that maps from (i, j, k) coordinates to (i', j', k') coordinates.

share|improve this answer
Quaternions are currently used to generate rotations in computer graphics, because they interpolate nicely, while rotation matrices do not. After interpolation, though, they are usually converted into matrix form in order to transform points. – comingstorm Feb 2 '11 at 7:16
thanks! this seems to be working great. i continue to learn about quaternions, matrices and linear algebra, but this is an excellent step in the right direction. – Fancypants_MD Feb 2 '11 at 8:50

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.