Let's assume your camera is some sort of a pyramid. It has a bottom face which I'll refer to as the "camera screen", and the height of the pyramid, also known as the focal length, will be marked as F (or in your equations, Ws).

```
T(op)
*---------*
|\ /|
| \ / |
| \ / |
| \ / |
L(eft) | *E(ye| R(ight)
| / \ |
| / \ |
| / \ |
|/ \|
*---------*
B(ottom)
```

Let's assume `j`

goes from the bottom to the top (from `-Ny/2`

to `+Ny/2`

in steps of `1/Ny`

), and `i`

goes from left to right (from `-Nx/2`

to `+Nx/2`

in steps of `1/Nx`

). Note that if Ny is even, j goes up to `Nx/2-1`

(and similar when `Nx`

is even).

As you go from bottom to top in the image, **on the screen**, you move from the `B`

value to the `T`

value. At the fraction `d`

(between 0=bottom and 1=top) of your way from bottom to top, your height is

```
Vs = T + (B-T) * d
```

A bit of messing around shows that the fraction `d`

is actually:

```
d = (j + 0.5) / Ny
```

So:

```
Vs = T + (B-T) * (j + 0.5) / Ny
```

And similarly:

```
Us = L + (R-L) * (i + 0.5) / Nx
```

Now, let's denote `U`

as the vector going from left to right, `V`

from bottom to top, 'W' going from the eye forward. All these vectors are normalized.

Now, assume the eye is located directly above `(0,0)`

where that is exactly above the center of the rectangular face of the pyramid.

To go from the eye directly to `(0,0)`

you would go:

```
Ws * W
```

And then to go from that point to another point on the screen at indexes `(i,j)`

you would go:

```
Us * U + Vs * V
```

You will be able to see that `Us = 0`

for `i = 0`

and `Vs = 0`

for `j = 0`

(since `B = -T`

and `L = -R`

, as the eye is directly above the center of the rectangle).

And finally, if we compose it together, a point on the screen at indexes `(i,j)`

is

```
S = E + Us * U + Vs * V + Ws * W
```

Enjoy!