# Converting XYZ to XY (world coords to screen coords)

Is there a way to convert that data:

• Object position which is a 3D point (X, Y, Z),
• Camera position which is a 3D point (X, Y, Z),
• Camera yaw, pitch, roll (-180:180, -90:90, 0)
• Field of view (-45°:45°)
• Screen width & height

into the 2D point on the screen (X, Y)?

I'm looking for proper math calculations according to this exact set of data.

It's difficult, but it's possible to do it for yourself.

There are lots of libraries that do this for you, but it is more satisfying if you do it yourself:

This problem is possible and I have written my own 3D engine to do this for objects in `javascript` using the `HTML5 Canvas`. You can see my code here and solve a 3D maze game I wrote here to try and understand what I will talk about below...

The basic idea is to work in steps. To start, you have to forget about camera angle `(yaw, pitch and roll)` as these come later and just imagine you are looking down the `y axis`. Then the basic idea is to calculate, using trig, the pitch angle and yaw to your object coordinate. By this I mean imagining that you are looking through a letterbox, the yaw angle would be the angle in degrees left and right to your coordinate (so both positive and negative) from the center/ mid line and the yaw up and down from it. Taking these angles, you can map them to the x and y 2D coordinate system.

The calculations for the angles are:

``````pitch = atan((coord.x - cam.x) / (coord.y - cam.y))
yaw   = atan((coord.z - cam.z) / (coord.y - cam.y))
``````

with `coord.x, coord.y and coord.z` being the coordinates of the object and the same for the cam (`cam.x, cam.y and cam.z)`. These calculations also assume that you are using a Cartesian coordinate system with the different axis being: `z up`, `y forward` and `x right`.

From here, the next step is to map this angle in the 3D world to a coordinate which you can use in a 2D graphical representation.

To map these angles into your screen, you need to scale them up as distances from the mid line. This means multiplying them by your `screen width / fov`. Finally, these distances will now be positive or negative (as it is an angle from the mid line) so to actually draw it on a canvas, you need to add it to half of the screen width.

So this would mean your canvas coordinate would be:

``````x = width / 2 + (pitch * (width / fov)
y = height / 2 + (yaw * (height / fov)
``````

where `width` and `height` are the dimensions of you screen, `fov` is the camera's fov and `yaw` and `pitch` are the respective angles of the object from the camera.

You have now achieved the first big step which is mapping a 3D coordinate down to 2D. If you have managed to get this all working, I would suggest trying multiple points and connecting them to form shapes. Also try moving your cameras position to see how the perspective changes as you will soon see how realistic it already looks.

In addition, if this worked fine for you, you can move on to having the camera be able to not only change its position in the 3D world but also change its perspective as in `yaw, pitch and roll` angles. I will not go into this entirely now, but the basic idea is to use 3D world transformation matrices. You can read up about them here but they do get quite complicated, however I can give you the calculations if you get this far.

• I am facing the similar issue. I have detected a face from a webcam and identified the Pitch and Yaw of the gaze. Now, I would like to project the same on to my laptop screen which is at certain distance (not constant). Would the above answer help me? – pavan subhash Oct 22 '18 at 15:54

It might help to read (old style) OpenGL specs:

https://www.khronos.org/registry/OpenGL/specs/gl/glspec14.pdf

See section 2.10

Also:

https://www.khronos.org/opengl/wiki/Vertex_Transformation

Might help with more concrete examples.

Also, for "proper math" look up 4x4 matrices, projections, and homogeneous coordinates.

https://en.wikipedia.org/wiki/Homogeneous_coordinates