If your world is rotated and shifted such that the camera is at `x=y=z=0`

(world coordinates), the world `z`

coordinate increases away from the viewer (into the screen), and the projection plane is parallel to the screen and is at `z=d`

(world coordinate; `d > 0`

), then you determine screen coordinates from world coordinates this way:

`xs = d * xw / zw`

`ys = d * yw / zw`

And that's pretty intuitive: the farther the object from the viewer/projection plane, the bigger its `zw`

and the smaller `xs`

and `ys`

, closer to the vanishing point of `xw=yw=0`

and `zw=+infinity`

, which projects onto the center of the projection plane `xs=ys=0`

.

By rearranging each of the above you get `xw`

and `zw`

back:

`xw = xs * zw / d`

`zw = d * yw / ys`

Now, if your object (the land) is a plane at a certain `yw`

, then, well, that `yw`

is known, so you can substitute it and get `zw`

:

`zw = d * yw / ys`

Having found `zw`

, you can now get `xw`

by, again, substitution:

`xw = xs * zw / d = xs * (d * yw / ys) / d = xs * yw / ys`

So, there, given the setup described in the beginning and screen coordinates `xs`

and `ys`

of the mouse pointer (0,0 being the screen/window center), the distance between the camera and the projection plane `d`

, and the land plane's `yw`

you get the location of the land spot the mouse points at:

`xw = xs * yw / ys`

`zw = d * yw / ys`

Of course, these `xw`

and `zw`

are in the rotated and shifted world coordinates and if you want the original absolute coordinates in the "map" of the land, you un-rotate and un-shift them.

That's the gist of it.