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Let's say I have a point A in a 3d space, and I want to move it with a uniform circular motion around the unit vector n.

So I know the position vector of A, O and the unit vector n (normal to the plane where O, A and B resides), and I know the angle AOB.

What is the quickest way to find the position of B ?

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+1 for the pretty picture alone :-) –  Damon Jul 6 '11 at 16:21

4 Answers 4

up vote 4 down vote accepted

How about just applying the rotation matrix about an axis and angle?

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How it would translate if the origin is outside the plane ? –  St0rM Jul 6 '11 at 16:41
    
@St0rM: I am not sure what you mean. Your picture suggests n is anchored at the same origin as A... Maybe you could update your question? –  Nemo Jul 6 '11 at 17:14
    
I mean that the space in which the circle (and the plane on which it resides) have NOT the origin in point O. The point O could be everywhere, and the plane could be oblique in any way. Would that system works anyway ? –  St0rM Jul 6 '11 at 22:01
    
Ok, I guess I can just find OB, then add it to O to find B in the space. –  St0rM Jul 7 '11 at 9:31

In mathspeak, that would be OB = OA * cos(theta) + (OAxn) * sin(theta)

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+1, but that should be -, not + (or make it (nxOA).) –  Beta Jul 6 '11 at 19:24

You will probably want to use Rodrigues' rotation formula. It is well suited for your very constrained problem (rigid body motion?). You probably won't need any more general, but also more complicated methods.

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To answer the slightly more general question that your comment to Nemo poses, I'll assume that you have global points A and O and that you have a unit vector N and angle Φ and you want B. Here's how I'd do it. First find the projection of OA onto N (anchored on O). Then find O', which is the point you'll be rotating around. Then use the equations given by Jack V:

O' = O  + dotP((A-O),N)N
B  = O' + cos(Φ)(A-O') + sin(Φ)crossP(N,A-O')

Where dotP and crossP are dot and cross products.

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