# Understanding the math behind rotating around an arbitrary axis in WebGL

Recently, I have been studying a number of matrix libraries used for WebGL to better understand the math that goes into the various transforms performed on matrices. Currently, I am trying to better understand the math used for rotational transforms.

Specifically, I already understand the transforms used for rotating around the three axes as well as how to generate these matrices (shown below).

However, I don't get the equations used to rotate around an arbitrary axis that isn't the x-, y- or z-axis.

I'm currently reading through WebGL Programming Guide, and in the provided library, they use the following JS to rotate around an arbitrary axis (where `e` is the array that contains the 4x4 matrix):

``````len = Math.sqrt(x*x + y*y + z*z);
if (len !== 1) {
rlen = 1 / len;
x *= rlen;
y *= rlen;
z *= rlen;
}
nc = 1 - c;
xy = x * y;
yz = y * z;
zx = z * x;
xs = x * s;
ys = y * s;
zs = z * s;

e[ 0] = x*x*nc +  c;
e[ 1] = xy *nc + zs;
e[ 2] = zx *nc - ys;
e[ 3] = 0;

e[ 4] = xy *nc - zs;
e[ 5] = y*y*nc +  c;
e[ 6] = yz *nc + xs;
e[ 7] = 0;

e[ 8] = zx *nc + ys;
e[ 9] = yz *nc - xs;
e[10] = z*z*nc +  c;
e[11] = 0;

e[12] = 0;
e[13] = 0;
e[14] = 0;
e[15] = 1;
``````

From what I can tell, the first part of the code is used to normalize the 3D vector, but other than that, I honestly cannot make any sense of it.
For example, what do `nc`, `xy`, `yz`, `zx`, `xs`, `ys` and `zs` mean? Also, as an example, how did they come up with the formula `x*x*nc + c` to calculate `e[0]`?

As per a related SO post, I did find a reference to the following matrix for rotating about an arbitrary axis:

This seems to be related to (if not the same as) what the JS code above is doing.

How is this matrix generated? I've thought a lot about how to rotate around an arbitrary axis, but the only thing I could come up with was to break the 3D vector extending from the origin into its x, y and z components, and then perform three different rotations, which seems pretty inefficient.

Having one matrix to do all of that for you seems best, but I really want to understand that matrix and how it's generated.

Lastly, while I'm not sure, it seems like the matrix above does not account for a translation of the axis away from the origin. Could that be easily handled by simply using a 4x4 matrix instead with Tx, Ty and Tz values in the appropriate locations?

Thank you.

-

Please find the math overview here:

http://paulbourke.net/geometry/rotate/

There is a detailed explanation here:

http://inside.mines.edu/~gmurray/ArbitraryAxisRotation/ArbitraryAxisRotation.html

You are correct about that rotation matrix not accounting for translation.

Yes, you can create a rotate-then-translate matrix by multiplying translation x rotation:

``````    1 0 0 t1      r11 r12 r13 0
T = 0 1 0 t2  R = r21 r22 r23 0
0 0 1 t3      r31 r32 r33 0
0 0 0 1       0   0   0   1

1 0 0 t1   r11 r12 r13 0   r11 r12 r13 t1
T x R = 0 1 0 t2 x r21 r22 r23 0 = r21 r22 r23 t2
0 0 1 t3   r31 r32 r33 0   r31 r32 r33 t3
0 0 0 1    0   0   0   1   0   0   0   1
``````

If you only want to rotate around an arbitrary axis away from origin (that is, around a line), look for the item "6.2 The normalized matrix for rotation about an arbitrary line" in the 2nd URL (http://inside.mines.edu/~gmurray/ArbitraryAxisRotation/ArbitraryAxisRotation.html).

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Well it explains the complex matrix is the product of 7 matrices (T-1 Rx-1 Ry-1 Rz Ry Rx T) but it does not show the full math. You can find more detailed math here: inside.mines.edu/~gmurray/ArbitraryAxisRotation/… –  Everton Apr 1 '14 at 14:23
Edited answer to show how to add translation. –  Everton Apr 1 '14 at 17:52
Consider the full transformation (Txz^-1 Tz^-1 Rz(θ) Tz Txz). Rz(θ) means the matrix to rotate by θ around the axis z. This is the matrix Rz(γ) from section 3, while the parameter θ is the desired rotation around the arbitrary axis (u,v,w). The trick is the compound transformation preceding Rz(θ) -- the matrices mutiplied at the right side of Rz(θ) -- moves the space in order to make the arbitrary axis (u,v,w) coincide with the axis Z (0,0,1). Then Rz(θ) can be used to rotate by θ around it. –  Everton Apr 2 '14 at 3:09
1) Notice that: 4.1 Txz : uses Rz with sin and cos calculated from the axis vector components (u,v,w) 4.2 Tz : uses Ry with sin and cos calculated from the axis vector components (u,v,w) 2) How to find the inverse matrix: mathsisfun.com/algebra/matrix-inverse.html –  Everton Apr 3 '14 at 13:44
3) No, the author used the correct order. When you apply the combined transform matrix to a vector/point (that is, a row-matrix), you will find the effect is like applying each individual transform BUT beginning from the right (last matrix) to the left (first matrix). –  Everton Apr 3 '14 at 13:45