I am looking to compute the axis-aligned bounding box (AABB) of a 2D ellipse on which a tranformation matrix was applied (rotation, scale, translation, etc.)

Something similar to this solution : Calculating an AABB for a transformed sphere

So far, it doesn't seem to work for 2D ellipses.

This is what I got (in pseudo-code) :

```
Matrix M; // Transformation matrix (already existing)
Matrix C = new Matrix( // Conic matrix
radiusX, 0, 0,
0, radiusY, 0,
0, 0, -1
);
Matrix MT = M.transpose();
Matrix CI = C.inverse();
Matrix R = M*CI*MT;
int minX = (R13 + sqrt(R13^2 - (R11 * R33))) / R33;
int minY = (R23 + sqrt(R23^2 - (R22 * R33))) / R33;
// maxX etc...
// Build AABB Rectangle out of min & max...
```

**Simple demo of the current behavior**

```
radiusX = 2
radiusY = 2 // To keep it simple, M is identity
// (no transformation on the ellipse)
M = /1 0 0\ // /M11 M21 M31\
|0 1 0| // |M12 M22 M32| Transform matrix format
\0 0 1/ // \0 0 1 /
C = /2 0 0\ // C as conic
|0 2 0|
\0 0 -1/
CI =/0.5 0 0\ // CI as dual conic
|0 0.5 0|
\0 0 -1/
R = /1 0 0\ * /0.5 0 0\ * /1 0 0\ // R = M*CI*MT
|0 1 0| |0 0.5 0| |0 1 0|
\0 0 1/ \0 0 -1/ \0 0 1/
= /0.5 0 0\ // /R11 R12 R13\
|0 0.5 0| // |R12 R22 R23| (R is symmetric)
\0 0 -1/ // \R13 R23 R33/
minX = (0 + sqrt(0^2 - (0.5 * -1))) / -1
= -0.7071 // Should be -2
// Also, using R = MIT*C*MI
// leads to -1.4142
```

# Solution (using dual conic matrix)

```
Matrix M;
Matrix C = new Matrix(
1/radiusX^2, 0, 0,
0, 1/radiusY^2, 0,
0, 0, -1
);
Matrix MT = M.transpose();
Matrix CI = C.inverse();
Matrix R = M*CI*MT;
int minX = (R13 + sqrt(R13^2 - (R11 * R33))) / R33;
int minY = (R23 + sqrt(R23^2 - (R22 * R33))) / R33;
```

# Final solution (no direct use of conic matrix)

Here's a simplified version.

```
Matrix M;
int xOffset = sqrt((M11^2 * radiusX^2) + (M21^2 * radiusY^2));
int yOffset = sqrt((M12^2 * radiusX^2) + (M22^2 * radiusY^2));
int centerX = (M11 * ellipse.x + M21 * ellipse.y) + M31; // Transform center of
int centerY = (M12 * ellipse.x + M22 * ellipse.y) + M32; // ellipse using M
// Most probably, ellipse.x = 0 for you, but my implementation has an actual (x,y) AND a translation
int xMin = centerX - xOffset;
int xMax = centerX + xOffset;
int yMin = centerY - yOffset;
int yMax = centerY + yOffset;
```