This is really easy, all you have to do is find the perpendicular (abbr here `|_`

) distance from the point `P`

to the plane, then *translate* `P`

**back** by the perpendicular distance *in the direction of the plane normal*. The result is the translated `P`

sits in the plane.

Taking an easy example (that we can verify by inspection) :

Set n=(0,1,0), and P=(10,20,-5).

The projected point should be (10,10,-5). You can see by inspection that Pproj is 10 units perpendicular from the plane, and if it were in the plane, it would have y=10.

So how do we find this analytically?

The plane equation is Ax+By+Cz+d=0. What this equation means is **"in order for a point (x,y,z) to be in the plane, it must satisfy Ax+By+Cz+d=0"**.

What is the Ax+By+Cz+d=0 equation for the plane drawn above?

The plane has normal n=(0,1,0). The d is found simply by using a test point *already in the plane*:

```
(0)x + (1)y + (0)z + d = 0
```

The point (0,10,0) is in the plane. Plugging in above, we find, d=-10. The plane equation is then 0x + 1y + 0z - 10 = 0 (if you simplify, you get y=10).

A nice interpretation of `d`

is it speaks of the **perpendicular distance you would need to translate the plane along its normal to have the plane pass through the origin**.

Anyway, once we have `d`

, we can find the |_ distance of *any* point to the plane by the following equation:

There are 3 possible classes of results for |_ distance to plane:

- 0: ON PLANE EXACTLY (almost never happens with floating point inaccuracy issues)
- +1: >0: IN FRONT of plane (on normal side)
- -1: <0: BEHIND plane (ON OPPOSITE SIDE OF NORMAL)

Anyway,

Which you can verify as correct by inspection in the diagram above