Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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);

    _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


share|improve this question
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

2 Answers 2

up vote 4 down vote accepted

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

 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.

share|improve this answer
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() {
    _modelRot = LoadIdentity();

    _model = _modelRot * _modelScale;

You could also extend this to a third matrix for translation if you wanted to.

share|improve this answer
Of course there's matrix "magic" to do this. –  datenwolf Jul 10 '12 at 22:11
I just added an answer showing the matrix magic. –  datenwolf Jul 10 '12 at 22:20

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.