# Circular rotation around an arbitrary axis

I am programming Starcraft 2 custom maps and got some proglems with math in 3D. Currently I am trying to create and rotate a point around an arbitrary axis, given by x,y and z (the xyz vector is normalized).

I've been trying around a lot and read through a lot of stuff on the internet, but I just cant get how it works correctly. My current script (you probably dont know the language, but it's nothing special) is the result of breaking everything for hours (doesn't work correctly):

``````    point CP;
fixed AXY;
point D;
point DnoZ;
point DXY_Z;
fixed AZ;
fixed LXY;
missile[Missile].Angle = (missile[Missile].Angle + missile[Missile].Acceleration) % 360.0;
missile[Missile].Acceleration += missile[Missile].AirResistance;
if (missile[Missile].Parent > -1) {
D = missile[missile[Missile].Parent].Direction;
DnoZ = Point(PointGetX(D),0.0);
DXY_Z = Normalize(Point(SquareRoot(PointDot(DnoZ,DnoZ)),PointGetHeight(D)));
AZ = MaxF(ACos(PointGetX(DXY_Z)),ASin(PointGetY(DXY_Z)))+missile[Missile].Angle;
DnoZ = Normalize(DnoZ);
AXY = MaxF(ACos(PointGetX(DnoZ)),ASin(PointGetY(DnoZ)));
CP = Point(Cos(AXY+90),Sin(AXY+90));
LXY = SquareRoot(PointDot(CP,CP));
if (LXY > 0) {
CP = PointMult(CP,Cos(AZ)/LXY);
PointSetHeight(CP,Sin(AZ));
} else {
CP = Point3(0.0,0.0,1.0);
}
} else {
CP = Point(Cos(missile[Missile].Angle),Sin(missile[Missile].Angle));
}
missile[Missile].Direction = Normalize(CP);
``````

I just cant get my mind around the math. If you can explain it in simple terms that would be the best solution, a code snipped would be good as well (but not quite as helpful, because I plan to do more 3D stuff in the future).

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http://en.wikipedia.org/wiki/Rotation_matrix. Look under the section Rotation matrix from axis and angle. For your convenience, here's the matrix you need. It's a bit hairy. theta is the angle, and ux, uy, and uz are the x, y, and z components of the normalized axis vector

If you don't understand matrices and vectors, post back and I'll help you.

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I found that matrix too, my problem is that I do not understand how to use it. What I do not understand either is how to create the point that I want to rotate. Thanks for your help. –  Alexander Jul 17 '11 at 12:34
After thinking a lot more about it, the rotation isn't the problem, I think I do understand the rotation. What I just cannot do is finding an perpendicular vector to my axis, at least none that rotates with the axis (the axis changes every 0.0625 seconds and I want a rotation around it with a constant distance). –  Alexander Jul 17 '11 at 14:40
It works now, I use an UP vector that I have to compute on every rotation etc. Would be better if there was a way to compute it when needed. –  Alexander Jul 17 '11 at 15:15
I realize there may be many reasons you're using an up vector, but the matrix I posted has all the necessary information to accomplish the rotation. Do you have the coordinates of the point you're rotating? Do you have the axis in (x, y, z) form? Do you have theta and can compute sin(theta) and cos(theta)? If so, this formula should be sufficient to achieve what you want. –  Gravity Jul 18 '11 at 2:12
No, I do not have the coordinates. I wanted them to be computed and then rotated by the angle. And I have no idea how to compute a point that is always in the same direction from my axis (if I turn my axis and display the point, it should look like it is connected). –  Alexander Jul 18 '11 at 14:46
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A useful method for doing such rotations is to do them with quaternions. In practice, I've found them to be easier to use and have the added bonus of avoiding Gimbal lock.

Here is a nice walk through that explains how and why they are used for rotation about an arbitrary axis (it's the response to the user's question). It's a bit higher level and would be good for someone who is new to the idea, so I recommend starting there.

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Here is what you can use to rotate about any axis, be it x,y or z. Rx, Ry and Rz denote rotation about the aces x,y,z respectively.

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I've found this link to be very helpful. It defines how to perform individual rotations about the X, Y and Z axes.

Mathematically, you can define the set of operations like so:

To perform a 3D rotation, you simply need to offset the point of rotation to the origin and sequentially rotate around each axis, storing the results between each axis rotation for use with the next rotation operation. The algorithm looks like as follows:

Offset the point to the origin.

``````Point of Rotation = (X1, Y1, Z1)
Point Location    = (X1+A, Y1+B, Z1+C)

(Point Location - Point of Rotation) = (A, B, C).
``````

Perform rotation about the Z Axis.

``````    A' = A*cos ZAngle - B*sin ZAngle
B' = A*sin ZAngle + B*cos ZAngle
C' = C.
``````

Next, perform a rotation about the Y Axis.

``````    C'' = C'*cos YAngle - A'*sin YAngle
A'' = C'*sin YAngle + A'*cos YAngle
B'' = B'
``````

Now perform the last rotation, about the X Axis.

``````    B''' = B''*cos XAngle - C''*sin XAngle
C''' = B''*sin XAngle + C''*cos XAngle
A''' = A''
``````

Finally, add these values back to the original point of rotation.

``````Rotated Point = (X1+A''', Y1+B''', Z1+C''');
``````
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