# Reset rotation matrix without losing scale

I have a case where I need a method to rotate a model matrix in OpenGL to absolute value. Most of the rotate() methods out there add rotation to a current one multiplying the current matrix with the new rotation. I need to rotate the model matrix to some value without keeping the old rotation. What I currently do is to destroy the current matrix to identity. Then calculate its scale from scratch based on scale variables I set before. Then multiply it with rotation matrix acquired from quaternion and eventually again translating it.

It looks to me as too many calculations for such a task. Is there a shorter way to reset matrix rotation while keeping its scale and translation parts intact? Here is my current method (Java):

`````` public void rotateTo3( float xr,float yr,float zr) {

Quaternion  xrotQ=   Glm.angleAxis( (xr),Vec3.X_AXIS);
Quaternion  yrotQ=   Glm.angleAxis( (yr),Vec3.Y_AXIS);
Quaternion  zrotQ=   Glm.angleAxis( (zr),Vec3.Z_AXIS);
xrotQ= Glm.normalize(xrotQ);
yrotQ= Glm.normalize(yrotQ);
zrotQ= Glm.normalize(zrotQ);

Quaternion acumQuat=new Quaternion();
acumQuat= Quaternion.mul(xrotQ,yrotQ);
acumQuat= Quaternion.mul(acumQuat,zrotQ);

Mat4 rotMat=new Mat4(1);
rotMat=Glm.matCast(acumQuat);

_model = new Mat4(1);

scaleTo(_scaleX, _scaleY, _scaleZ);//reconstruct scale
_model = Glm.translate(_model, new Vec3(_pivot.x, _pivot.y, 0));

_model=rotMat.mul(_model); ///add new rotation

_model = Glm.translate(_model, new Vec3(-_pivot.x, -_pivot.y, 0));

translateTo(_x, _y, _z);//reconstruct translation
``````

}

-
What's wrong with rotating back, in the opposite direction? Or just keeping the original scale (non-rotated) matrix around, if it doesn't change much? –  BlueRaja - Danny Pflughoeft Jul 10 '12 at 20:17

This is actually done rather easy. The key insight is, that a homogenous transformation matrix consists 3 parts: The upper left 3×3 matrix is a rotation-scaling, the rightmost top 1×3 column is the translation, the bottom left 3×1 allows for affine scaling and the bottom right is 1.

So we can write it as

``````RS T
A 1
``````

Now what you want to do is decomposing a given RS into R and S. Now rotations are always orthogonal, which means R^T = R^-1. But scalings are not, as for a scaling S^T = S != S^-1, hence we can write

``````(RS)^T * RS = S^T * R^T * R * S = S^T * R^-1 * R * S = S^T * S = S^2
``````

scaling happens only on the diagonal, so you can extract the x, y and z scaling factors by taking the square root of the elements on the diagonal.

-
I don't think this is correct (or I didn't understand). Take a pure rotation matrix, say `R_x` from basic rotation matrix. Now you're saying that `sqrt(cos(phi)) == 1`, being not true. –  Stefan Hanke Jul 11 '12 at 6:59
If you multiply a "pure" rotation matrix, like R_x with it's transpose, you'll end up with `cos²(…) + sin²(…) == 1` on the diagonal (do the math!). –  datenwolf Jul 11 '12 at 7:30
@StefanHanke: On a side note: Just knowing that for any orthonormal matrix R^T = R^-1 holds, does suffice to understand this. And rotation matrices are always orthonormal. Any non orthonormality in a rotate-scale matrix is purely due to the scaling. Which makes it possible to separate this. –  datenwolf Jul 11 '12 at 7:36
Sigh; too long has been the time I've had the last look at those equations. You just start with `RS` and just want to know the scale; so transpose it, do some matrix foo, and there it presents itself: the scale matrix, multiplied with itself. That's it. +1 –  Stefan Hanke Jul 11 '12 at 13:02

I don't think there's any matrix magic to do this, but could you just store your rotation and scale in separate matrices?

``````void init() {
_modelScale = some_scale_matrix;
}

void update() {