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I am developing a rotate-around-axis algorithm in 3 dimensions. My inputs are

  • the axis I am revolving around, as a vector from my center point
  • the center point (obviously)
  • the angle I wish to rotate around
  • my current position

I am wondering if there is a way to do this without trigonometry, just with vector operations. Does anyone have a potential solution?

EDIT: Is there a way that I could rotate by pi/4 radians (45 degrees) each time, rather than an inputted angle theta? This might simplify things a bit, I don't know.

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What vector operations do you have available? –  David Z Oct 29 '11 at 5:20
    
I have cross, dot, add, subtract, and normalize available. –  Nathan Moos Oct 30 '11 at 21:34
    
In that case I have a pretty strong feeling you can't implement a rotation without using trigonometry in some form. You might be able to get away with one trig function evaluation, the cosine (or sine) of the rotation angle, but you have to have at least the one. The only case in which you could do without that would be if you had a "rotation" vector operation available (and even then, it would probably be doing trig behind the scenes). –  David Z Oct 30 '11 at 21:40
    
Is there a way to find a perpendicular and cut it? Possibly? –  Nathan Moos Oct 31 '11 at 2:34
    
You need trig functions to do that too. –  David Z Oct 31 '11 at 3:00
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4 Answers

up vote 7 down vote accepted

Rotations are inherently well-described by \sin and \cos.

It's a handy trick that unit quaternions nicely represent 3-D rotations just as well as (and in some senses, better than) rotation matrices. Converting a rotation by angle \theta about a normal axis \hat n=\left<x,y,z\right> where x^2+y^2+z^2=1, does require a little bit of trigonometry: \left(\cos\left(\frac12\theta\right)\right)+\left(x\sin\left(\frac12\theta\right)\right)i+\left(y\sin\left(\frac12\theta\right)\right)j+\left(z\sin\left(\frac12\theta\right)\right)k.

But from there on it's simple arithmetic. A quaternion q=a+bi+cj+dk can be directly applied to rotate a vector with q(xi+yj+zk)q^{-1}, or converted to a rotation matrix \left(\begin{matrix}a^2+b^2-c^2-d^2&2bc-2ad&2bd+2ac\2bc+2ad&a^2-b^2+c^2-d^2&2cd-2ab\2bd-2ac&2cd+2ab&a^2-b^2-c^2+d^2\end{matrix}\right).

This is a rotation around the origin, of course. To rotate around an arbitrary point o in space, simply translate by -o to the origin, rotate, then translate by o to return.

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Excellent! Quaternions are really very useful with describing 3D rotations! –  Nathan Moos Nov 1 '11 at 3:50
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use matrices: http://en.wikipedia.org/wiki/Rotation_matrix#Rotations_in_three_dimensions

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Those matrix operations use trig (although I don't see a way to do this in any reasonable fashion without it). –  ssube Oct 29 '11 at 5:23
    
Rotation matrices still use sin() and cos() though. I don't really see anything involving rotation avoiding these computations though. –  Nick Oct 29 '11 at 5:26
    
true. it is a rotation at some angle. i can't think of a way that does not involve those. –  Ray Tayek Oct 29 '11 at 6:22
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If this is some sort of dumb homework problem, you can use Taylor Series approximation of the sine/consine functions. Whether or not this "counts" as trigonometry is I guess up for debate. You could then use these values in a rotation matrix or quarternion, if you want to use vector operations.

But again, there's no practical reason to do this.

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This question is just to see if there's any way to avoid trig. I know about the Taylor Series, I'm just trying to see if there's any other way. –  Nathan Moos Oct 30 '11 at 21:35
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Are there other techniques that don't use trig functions? Possibly, but there are no know efficient, general (i.e. for arbitrary angles) ways to perform rotations without use of trig functions.

However, based on your edit, you can precompute the sin and cos for a collection of angles you're interested in and store them in a lookup table. You need not be constrained in such a circumstance to π/4 increments, but you can do π/256 or π/1024 increments if you want. Also, you don't need two tables, since cos(θ) = sin(θ+π/2).

From there, you can use any of a number of interpolation methods to include simple rounding, linear interpolation or some sort of polynomial interpolation based on your needs.

You would then use either the matrix or quaternion based transformation to compute the rotated vector.

This will be faster than computing the sin and cos for general angles, though will require some additional space, and there will be an accuracy penalty as well. But if it satisfies your needs...

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