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I am writing a 3d vector class for OpenGL. How do I rotate a vector v1 about another vector v2 by an angle A?

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What do you mean by rotating "along" a vector? –  ChrisF Sep 28 '11 at 11:20
    
i mean "against" or "around",sorry for my weak english. –  YAHOOOOO Sep 28 '11 at 11:24
    
I would recommend reading introductionary book to 3d math instead of asking such questions here every time you find a problem. One very good introduction to subject is amazon.com/Primer-Graphics-Development-Wordware-Library/dp/… –  Jukka Dahlbom Sep 28 '11 at 11:27
    
@YAHOOOOO: Why aren't you using an existing vector / matrix library such as Eigen (eigen.tuxfamily.org/index.php?title=Main_Page) or GLM (glm.g-truc.net)? –  andand Sep 28 '11 at 14:35

5 Answers 5

up vote 4 down vote accepted

The easiest-to-understand way would be rotating the coordinate axis so that vector v2 aligns with the Z axis, then rotate by A around the Z axis, and rotate back so that the Z axis aligns with v2.

When you have written down the rotation matrices for the three operations, you'll probably notice that you apply three matrices after each other. To reach the same effect, you can multiply the three matrices.

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I'm not going to downvote, but this is overly complex. A simpler solution, which I would argue is actually easier to understand (but that's just me) is to use the quaternion based approach Brett Hale suggests. –  andand Sep 28 '11 at 14:41
    
@andand: Quaternions are nice and simple, sure, once you have understood quaternions. The OP seems to have had difficulties with normal 3D linear algebra, quaternions are probably three steps too high on the ladder for now. –  thiton Sep 28 '11 at 14:50

Use a 3D rotation matrix.

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You may find quaternions to be a more elegant and efficient solution.

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+1: I personally think this is the best approach for a variety of reasons. Shame you didn't answer sooner, you might have been the chosen answer. –  andand Sep 28 '11 at 14:37

This may prove useful:

double c = cos(A);
double s = sin(A);
double C = 1.0 - c;

double Q[3][3];
Q[0][0] = v2[0] * v2[0] * C + c;
Q[0][1] = v2[1] * v2[0] * C + v2[2] * s;
Q[0][2] = v2[2] * v2[0] * C - v2[1] * s;

Q[1][0] = v2[1] * v2[0] * C - v2[2] * s;
Q[1][1] = v2[1] * v2[1] * C + c;
Q[1][2] = v2[2] * v2[1] * C + v2[0] * s;

Q[2][0] = v2[0] * v2[2] * C + v2[1] * s;
Q[2][1] = v2[2] * v2[1] * C - v2[0] * s;
Q[2][2] = v2[2] * v2[2] * C + c;

v1[0] = v1[0] * Q[0][0] + v1[0] * Q[0][1] + v1[0] * Q[0][2];
v1[1] = v1[1] * Q[1][0] + v1[1] * Q[1][1] + v1[1] * Q[1][2];
v1[2] = v1[2] * Q[2][0] + v1[2] * Q[2][1] + v1[2] * Q[2][2];
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+1 For dead simple code –  Lennart Rolland Feb 27 '13 at 23:08

I found this here: http://steve.hollasch.net/cgindex/math/rotvec.html

let
    [v] = [vx, vy, vz]      the vector to be rotated.
    [l] = [lx, ly, lz]      the vector about rotation
          | 1  0  0|
    [i] = | 0  1  0|           the identity matrix        
          | 0  0  1|

          |   0  lz -ly |
    [L] = | -lz   0  lx |
          |  ly -lx   0 |

    d = sqrt(lx*lx + ly*ly + lz*lz)
    a                       the angle of rotation

then

matrix operations gives:

[v] = [v]x{[i] + sin(a)/d*[L] + ((1 - cos(a))/(d*d)*([L]x[L]))} 

I wrote my own Matrix3 class and Vector3Library that implemented this vector rotation. It works absolutely perfectly. I use it to avoid drawing models outside the field of view of the camera.

I suppose this is the "use a 3d rotation matrix" approach. I took a quick look at quaternions, but have never used them, so stuck to something I could wrap my head around.

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