## The setup

Draw XY-coordinate axes on a piece of paper. Write a word on it along X-axis, so that the word's centerpoint is at origo (half on positive side of X/Y, the other half on negative side of X/Y).

Now, if you flip the paper upside down you'll notice that the word is mirrored in relation to both X- and Y-axis. If you look from behind the paper, it's mirrored in relation to Y-axis. If you look at it from behind and upside down, it's mirrored in relation to X-axis.

Ok, I have points in 2D-plane (*vertices*) that are created in similar way at the origo and I need to apply exactly the same rule for them. To make things interesting:

- The 2D plane is actually 3D, each point (
*vertex*) being (x, y, 0). Initially the vertices are positioned to the origo and their normal is**Pn**(0,0,1). => Correctly seen when looked at from point**Pn**towards origo. - The vertex-plane has it's own rotation matrix
**[Rp]**and position**P**(x,y,z) in the 3D-world. The rotation is applied before positioning. - The 3D world is "right handed". The viewer would be looking towards origo from some distance along positive Z-axis but the world is also oriented by rotation matrix
**[Rw]**.**[Rw]*** (0,0,1) would point directly to the viewer's eye.

From those I need to calculate when the vertex-plane should be mirrored and by which axis. The mirroring itself can be done before applying **[Rp]** and **P** by:

```
Vertices vertices = Get2DPlanePoints();
int MirrorX = 1; // -1 to mirror, 1 NOT to mirror
int MirrorY = 1; // -1 to mirror, 1 NOT to mirror
Matrix WorldRotation = GetWorldRotationMatrix();
MirrorX = GetMirrorXFactor(WorldRotation);
MirrorY = GetMirrorYFactor(WorldRotation);
foreach(Vertex v in vertices)
{
v.X = v.X * MirrorX * MirrorY;
v.Y = V.Y * MirrorY;
}
// Apply rotation...
// Add position...
```

## The question

So I need GetMirrorXFactor() & ..YFactor() -functions that return -1 if the viewer's eyepoint is at greater "X/Y"-angle than +-90 degrees in relation to the vertex-plane's normal after the rotation and world orientation. **I have already solved this, but I'm looking for more "elegant" mathematics.** I know that rotation matrices somehow contain info about how much is rotated by which axis and I believe that can be utilized here.

## My Solution for MirrorX:

```
// Matrix multiplications. Vectors are vertical matrices here.
Pnr = [Rp] * Pn // Rotated vertices's normal
Pur = [Rp] * (0,1,0) // Rotated vertices's "up-vector"
Wnr = [Rw] * (0,0,1) // Rotated eye-vector with world's orientation
// = vector pointing directly at the viewer's eye
// Use rotated up-vector as a normal some new plane and project viewer's
// eye on it. dot = dot product between vectors.
Wnrx = Wnr - (Wnr dot Pur) * Pur // "X-projected" eye.
// Calculate angle between eye's X-component and plane's rotated normal.
// ||V|| = V's norm.
angle = arccos( (Wnrx dot Pnr) / ( ||Wnrx|| * ||Pnr|| ) )
if (angle > PI / 2)
MirrorX = -1; // DO mirror
else
MirrorX = 1; // DON'T mirror
```

Solution for mirrorY can be done in similar way using viewer's up and vertex-plane's right -vectors.

Better solution?

`arccos`

is possible, but your terminology is unclear (e.g. it is unclear what`Rw`

is or does). How about "mirroring" X if ([Rp](1,0,0)) dot (1,0,0) < 0? – Beta Sep 4 '13 at 3:31