Unfortunately you don't have enough information to solve the problem. Let's see if I can make a drawing here to show you why:

```
/
cam1 < (1) (2) (3)
\
\ /
v
cam2
```

I hope this is clear. Let's say you take three pictures from `cam1`

, with some object located at `(1)`

, `(2)`

and `(3)`

. In all three cases the object is located exactly in the center of the picture.

Now you move the camera to the `cam2`

location, which involves a 90 degree counter clockwise rotation on Y plus some translation on X and Z.

For simplicity, let's say your `Px,Py`

is the center of the picture. The three pictures that you took with `cam1`

have the same object at that pixel, so whatever equations and calculations you come up with to locate that pixel in the `cam2`

pictures, they will have the same input for the three pictures, so they will also produce the same output. But clearly, that will be wrong, since from the `cam2`

location each of the three pictures that you take will see the object in a very different position, moving horizontally across the frame.

Do you see what's missing?

If you wanted to do this properly, you would need your `cam1`

device to also capture a depth map, so that for each pixel you also know how far away from the camera the object represented by it was. This is what will differentiate the three pictures where the object moves farther away from the camera.

If you had the depth for `Px,Py`

, then you can then do an inverse perspective projection from `cam1`

and obtain the 3D location of that pixel relative to `cam1`

. You will then apply the inverse rotation and translation to convert the point to the 3D space relative to `cam2`

, and then do a perspective projection from `cam2`

to find what will be the new pixel location.

Sorry for the bad news, I hope this helps!