# What are the maths behind 3D billboard sprites? (was: 3D transformation matrix to 2D matrix)

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?

## WAS:

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:

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)

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)
``````

-

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

• 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,...

• 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
A=P*(x-dx,y-dy,z,w)
B=P*(x-dx,y+dy,z,w)
C=P*(x+dx,y+dy,z,w)
D=P*(x+dx,y-dy,z,w)
``````

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
``````
-
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 `R`looks 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)
``````

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