Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I'm using Electro in Lua for some 3D simulations, and I'm running in to something of a mathematical/algorithmic/physics snag.

I'm trying to figure out how I would find the "spin" of a sphere of a sphere that is spinning on some axis. By "spin" I mean a vector along the axis that the sphere is spinning on with a magnitude relative to the speed at which it is spinning. The reason I need this information is to be able to slow down the spin of the sphere by applying reverse torque to the sphere until it stops spinning.

The only information I have access to is the X, Y, and Z unit vectors relative to the sphere. That is, each frame, I can call three different functions, each of which returns a unit vector pointing in the direction of the sphere model's local X, Y and Z axes, respectively. I can keep track of how each of these change by essentially keeping the "previous" value of each vector and comparing it to the "new" value each frame. The question, then, is how would I use this information to determine the sphere's spin? I'm stumped.

Any help would be great. Thanks!

share|improve this question
Is it just me, or might it be able to spin on more than one axis at once? That is, a "spin vector" might not be so simple? –  jtbandes Nov 14 '09 at 4:39
A single spin vector is sufficient. even if it seems to be spinning around multiple axes, the resultant of these will be the spin vector. Conversely, a single spin vector can be resolved into spin components along independent axes. –  sykora Nov 14 '09 at 4:45
The "spins" will combine. Try grabbing the closest spherical object to you and rotate it along it's X axis (that is, the horizontal axis). Then rotate it along it's z axis (that is, the axis going directly away from you). Then do your best to do both at the same time. You'll notice, now, that it is rotating along an axis 45 degrees between the x and z axes. –  Ben Torell Nov 14 '09 at 4:48
Ninja'd by sykora. –  Ben Torell Nov 14 '09 at 4:49
I suspected as much, but I'm too tired to come up with that on my own. :) –  jtbandes Nov 14 '09 at 6:42

2 Answers 2

up vote 8 down vote accepted

My first answer was wrong. This is my edited answer.

Your unit vectors X,Y,Z can be put together to form a 3x3 matrix:

A = [[x1 y1 z1],
     [x2 y2 z2],
     [x3 y3 z3]]

Since X,Y,Z change with time, A also changes with time.

A is a rotation matrix! After all, if you let i=(1,0,0) be the unit vector along the x-axis, then A i = X so A rotates i into X. Similarly, it rotates the y-axis into Y and the z-axis into Z.

A is called the direction cosine matrix (DCM).

So using the DCM to Euler axis formula


theta = arccos((A_11 + A_22 + A_33 - 1)/2)

theta is the Euler angle of rotation.

The magnitude of the angular velocity, |w|, equals

w = d(theta)/dt ~= (theta(t+dt)-theta(t)) / dt

The axis of rotation is given by e = (e1,e2,e3) where

e1 = (A_32 - A_23)/(2 sin(theta))
e2 = (A_13 - A_31)/(2 sin(theta))
e3 = (A_21 - A_12)/(2 sin(theta))
share|improve this answer
Exactly right. +1 –  Drew Hall Nov 14 '09 at 4:49
You saved me from typing out a horribly convoluted answer. +1. –  sykora Nov 14 '09 at 4:54
Perfect! Thanks! –  Ben Torell Nov 14 '09 at 5:14
Actually, I don't think this is correct; it is only true if the chosen vector heppens to be on the "equator" of the rotation. Notice that the proposed rotation vector w is always perpendicular to the chosen vector r, even though r can be anything! –  comingstorm Nov 14 '09 at 21:59
Ack. You are correct. Thanks for pointing this out, comingstorm. Care to write up the correct solution? –  unutbu Nov 14 '09 at 22:41

I applaud ~unutbu's, answer, but I think there's a simpler approach that will suffice for this problem.

Take the X unit vector at three successive frames, and compare them to get two deltas:

deltaX1 = X2 - X1
deltaX2 = X3 - X2

(These are vector equations. X1 is a vector, the X vector at time 1, not a number.)

Now take the cross-product of the deltas and you'll get a vector in the direction of the rotation vector.

Now for the magnitude. The angle between the two deltas is the angle swept out in one time interval, so use the dot product:

dx1 = deltaX1/|deltaX1|
dx2 = deltax2/|deltaX2|
costheta = dx1.dx2
theta = acos(costheta)
w = theta/dt

For the sake of precision you should choose the unit vector (X, Y or Z) that changes the most.

share|improve this answer
Correct me if I'm wrong, but I think this solution might suffer from the same problem that ~unutbu's previous solution suffered from, that is, that this assumes X (or whichever axis is chosen) is on the equator of the unit sphere. That means the axis of rotation would be calculated as being perpendicular to the chosen axis, which may not necessarily be the case. The problem may be partially alleviated by choosing the axis that changes the most (i.e. the axis closest to the equator), but that wouldn't be an exact solution. –  Ben Torell Nov 16 '09 at 13:42
Now that I think about it more, you might be right after all. 7:30am is never a good time for me to be on SO. :-/ –  Ben Torell Nov 16 '09 at 15:09
The calculated axis of rotation won't (necessarily) be perpendicular to X, it will be perpendicular to the change in X, which is correct. If you can't wait for two time intervals you could do it in one, using the fact that it must be perpendicular to the change in X and the change in Y... Come to think of it, that's a pretty good method. –  Beta Nov 16 '09 at 17:05

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.