The equation will be

```
n_x x + n_y y + n_z z + d = 0
```

where `N[n_x, n_y, n_z]`

is the normal vector. Then you can substitute any point `B(b_x, b_y, b_z)`

known to be on the plane to solve for `d`

,

```
d = -( n_x b_x + n_y b_y + n_z b_z )
```

Why does this work? Let `P(x,y,z)`

be an arbitrary point in the plane. Then the vector `P-B`

must be parallel to the plane and perpendicular to its normal. The dot product of perpendiculars is zero. Consequently,

```
N dot (P - B) = (N dot P - N dot B)
= n_x x + n_y y + n_z z - (n_x b_x + n_y b_y + n_z b_z) = 0
```

In the last line you can recognize

```
a = n_x b = n_y c = n_z d = -(n_x b_x + n_y b_y + n_z b_z)
```

as already stated.