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 3D point in space. The point's exact orientation/position is expressed through a 4x4 transformation matrix.

I want to draw a billboard (3D Sprite) to this point. I know the projected position (i.e. 3D->2D) of the point; the billboard is facing the camera so that's very helpful too. What I don't know is the scaling that the billboard should have!

To make things more complex, the 4x4 matrix may have all sorts of transformations: 3D rotation, 3D scaling, 3D transposition. Assume that the camera is as simple as it can be: position at (0,0,0), no rotation.

So, can I "extract" the scaling of the billboard sprite from this 4x4 matrix?



I have a 3D affine transformation 4x4 matrix. I need to convert it (project) to a 2D affine transformation 3x3 matrix, which looks like this:

enter image description here

3D rotations are irrelevant and if present may be discarded; I am only interested in translation and most importantly scaling.

Can anyone help with the equations for each of the six 4 values? (lets say tx, ty are also known)

Additional info:

The Matrix3D is the global transformation of a 3D point, say (0,0,0). Its purpose is to be projected on a 2D plane (the computer screen).

I know how to project a 3D point to 2D space, what I am looking for is to preserve additional transformation information beyond position, i.e. scaling: as you may know, the scaling property is also altered when projecting the point on a 2D plane.

I also forgot to mention that the perspective projection properties are also known, i.e.:

field of view (single value)
focal length (single value)
projection center (viewpoint position - 2D value)

enter image description here

share|improve this question

2 Answers 2

up vote 1 down vote accepted

if you not using spherical coordinate system then this task is not solvable

  • because discarting Z-coordinate before projection
  • will remove the distance form the projection point
  • and therefore you do not know how to apply perspective

You have two choices (unless I overlooked something):

1.apply 3D transform matrix

  • and then use only x,y - coordinates of the result

2.create 3x3 transformation matrix for rotation/projection

  • and add offset vector before or after applying it
  • be aware that this approach do not use homogenous coordinates !!!

[Edit1] - equations for clarity

3x3 vs. 4x4 transform matrix

  • do not forget that 3x3 matrix + vector transforms are not cumulative !!!
  • that is the reason why 4x4 transforms are used instead
  • now you can throw away the last row of matrix/vector (Xz,Yz,Zz), (z0)
  • and then the output vector is just (x', y')
  • of course after this you cannot use the inverse transform because you lost Z coordinate
  • scaling is done by changing the size of axis direction vectors

Btw. if your projection plane is also XY-plane without rotations then:

x' = (x-x0)*d/(z-z0)
y' = (y-y0)*d/(z-z0)
  • (x,y,z) - point to project
  • (x',y') - projected point
  • (x0,y0,z0) - projection origin
  • d - focal length

[Edit2] well after question edit the meaning is completely different

  • I assume you want sprite always facing camera
  • ugly but simplifies things like grass,trees,...

  • M - your matrix

  • P - projection matrix inside M
  • if you have origin of M = (0,0,0) without rotations/scaling/skew then M=P
  • pnt - point of your billboard (center I assume) (w=1) [GCS]
  • dx,dy - half sizes of billboard [LCS]
  • A,B,C,D - projected edges of your billboard [GCS]
  • [GCS] - global coordinate system
  • [LCS] - local coordinate system

1.if you know the projection matrix (I assume it is glFrustrum or gluPerspective ... )

(x,y,z,w)=(M*(P^-1))*pnt  // transformed center of billboard without projection

2.If your M matrix is too complex for 1. to work

MM=(M*(P^-1))     // transform matrix without projection
XX=MM(Xx,Xy,Xz)   // X - axis vector from MM [GCS](look at the image above on the right for positions inside matrix)
YY=MM(Yx,Yy,Yz)   // Y - axis vector from MM [GCS]
X =(M^-1)*XX*dx   // X - axis vector from MM [LCS] scaled to dx
Y =(M^-1)*YY*dy   // Y - axis vector from MM [LCS] scaled to dy
A = M*(pnt-X-Y)
B = M*(pnt-X+Y)
C = M*(pnt+X+Y)
D = M*(pnt+X-Y)

[Edit3] scalling only

MM=(M*(P^-1))     // transform matrix without projection
sx=|MM(Xx,Xy,Xz)|  // size of X - axis vector from MM [GCS] = scale x
sy=|MM(Yx,Yy,Yz)|  // size of Y - axis vector from MM [GCS] = scale y
share|improve this answer
Can you please elaborate a little on (2)? I don't want to discard Z, I just want to project SCALING alongside X,Y coords –  Bill Kotsias Feb 6 at 21:33
@Bill Kotsias edited my answer. –  Spektre Feb 7 at 8:52
That's a greatly extensive answer... but AFAICS, you have given me the equations for getting the projected point. As I originally said, I know how to get the projected point. I am re-editing the whole question because I think I have caused confusion. –  Bill Kotsias Feb 7 at 21:33
@Bill Kotsias reedited my answer look for Edit2. –  Spektre Feb 8 at 9:08
Thank you Spektre! But I feel that you will flame me for this: You have given me the 4 edges of the billboard, though I am not using OpenGL but Flash. In order to render my billboard correctly, I need to pass 2 things: the projected point (I have this already) and SCALING factors (scaleX & scaleY). From your math, I suppose a way to calculate the scaling is this: scaleX=(D-A)/(billboard_original_sizeX) . But is there a "shortcut" to your math so that I get the SCALING without calculating all four edges of the billboard? Sorry for keeping bothering you!!! –  Bill Kotsias Feb 8 at 13:13

Scale matrix S looks like this:

sx 0  0  0
0  sy 0  0
0  0  sz 0
0  0  0  1

Translation matrix T looks like this:

1  0  0  0
0  1  0  0
0  0  1  0
tx ty tz 1

Z-axis rotation matrix Rlooks like this:

 cos(a) sin(a)  0  0
-sin(a) cos(a)  0  0
   0      0     1  0
   0      0     0  1

If you have a transformation matrix M, it is a result of a number of multiplications of R, T and S matrices. Looking at M, the order and number of those multiplications is unknown. However, if we assume that M=S*R*T we can decompose it into separate matrices. Firstly let's calculate S*R*T:

        ( sx*cos(a) sx*sin(a) 0  0)       (m11 m12 m13 m14)
S*R*T = (-sy*sin(a) sy*cos(a) 0  0) = M = (m21 m22 m23 m24)
        (     0         0     sz 0)       (m31 m32 m33 m34)
        (     tx        ty    tz 1)       (m41 m42 m43 m44)

Since we know it's a 2D transformation, getting translation is straightforward:

translation = vector2D(tx, ty) = vector2D(m41, m42)

To calculate rotation and scale, we can use sin(a)^2+cos(a)^2=1:

(m11 / sx)^2 + (m12 / sx)^2 = 1
(m21 / sy)^2 + (m22 / sy)^2 = 1

m11^2 + m12^2 = sx^2
m21^2 + m22^2 = sy^2

sx = sqrt(m11^2 + m12^2)
sy = sqrt(m21^2 + m22^2)

scale = vector2D(sx, sy)

rotation_angle = atan2(sx*m22, sy*m12)


Hope this help you

share|improve this answer
Very helpful indeed, but not the answer to my question. I have re-edited the question in hope that I'll get the correct answer... –  Bill Kotsias Feb 7 at 21:33

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.