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.

In my project I give an orientation to an object by applying the normal to the model matrix. My model matrix is the product of the scaling, rotation and translation matrices.

obj.UpVector = p22.Normal;
obj.RightVector = Vector3.Cross(obj.ForwardVector, obj.UpVector);
obj.RightVector = Vector3.Normalize(obj.RightVector);

obj.ForwardVector = Vector3.Cross(obj.UpVector, obj.RightVector);
obj.ForwardVector = Vector3.Normalize(obj.ForwardVector);

Every time the object is updated the model matrix is calculated. But because of that I am loosing the orientation of the object, since the rotation matrix doesn't contain information about the orientation. Besides when I apply the normal to the model matrix, the object looses its scale.

Orientation's Up vector to be the terrain's normal, so that covers one axis. The other two can be calculated using cross products.Object facing direction (Forward) and the terrain's normal (Normal). Since the cross product produces a vector that is perpendicular to both vectors, I can calculate the Right vector.

I tried to apply the above solution to the rotation matrix but it gives the wrong result. How do I apply the normal to the rotation Matrix?

Object.Scale(10,new Vector3(1,0,0));
Object.Update() is equal to modelMatrix=scaleMatrix*rotationMatrix*translationMatrix;
*calculeting normal from highmap*

modelMatrix.UpVector = p22.Normal;
modelMatrix.RightVector = Vector3.Cross(obj.ForwardVector, obj.UpVector);
modelMatrix.RightVector = Vector3.Normalize(obj.RightVector);

modelMatri.ForwardVector = Vector3.Cross(obj.UpVector, obj.RightVector);
modelMatri.ForwardVector = Vector3.Normalize(obj.ForwardVector);
//the scale is lost.

object.Update(); //orientation applied to model matrix is lost.

The whole question is why applying normal to rotation matrix doesn't give same result

share|improve this question
There are an infinite number of orientations that can be calculated by applying 1 vector to an orientation. It is like saying I want an orientation that makes my airplane to point north. well, you could point it north but apply any amount of roll causing different orientations but its still always pointing north. You need a 2nd vector to finalize an orientation. So what is your 2nd criteria for setting your orientation? –  Steve H Jan 24 '13 at 15:49
In general, the calculation should be fine. If you use the default left-handed coordinate system, cross(forward, up) yields the left direction and not the right direction. Similarly, cross(up, right) yields the back vector. For a right-handed coordinate system, the calculations should be correct. You can use Matrix.Decompose to get the scaling of the old matrix. I'm not entirely sure what you are asking. If this comment does not help you, please clarify your question. –  Nico Schertler Jan 24 '13 at 16:11
+1 for title that confuses programmers because of OOP. –  ja72 Jan 24 '13 at 19:50

1 Answer 1

up vote 0 down vote accepted

Stave H comment gave me an idea what I was doing wrong. In my case Rotation matrix contains 2D rotation without inclination! After adding additional matrix everything works correctly.

    public void Update()
        ModelMatrix = scaleMatrix * (orientationMatrix * rotateMatrix) * translateMatrix;

share|improve this answer

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.