Why do orthogonal coordinates have to be normalized?

They don't. You can set the limits of the orthogonal projection volume however you desire. The left, right, bottom, top, near and far parameters of the glOrtho call define the limits of the viewport volume. If you chose them left=0, right=win_pixel_width, bottom=0, top=win_pixel_height you end up with a pixel unit projection volume as you're used to. However why bother with pixels? You'd just have to compensate for the actual window size later. Just choose the ortho projection volume extents to match the scene you want to draw.

Maybe you're confusing this with normalized device coordinates. And for those it simply has been defined that it is the value range [-1, 1] that's mapped to the viewport extents.

### Update

BTW, I'm not quite sure what the Vertex vec4 represents. I thought all vertices of a model were inside Model. Any ideas?

I'm getting quite fatigued right now, because I've been answering several questions like this numerous times over the last few days. So, here it goes again:

**In OpenGL there is no camera.**

**In OpenGL there is no scene.**

**In OpenGL there are no models.**

"Wait, what?!" you may wonder now. But it's true.

All OpenGL cares about is, that there is some target framebuffer, i.e. a canvas it can draw to, and a stream of vertex attributes that make geometric primitives. The primitives are points, lines and triangles. Somehow the vertex attributes for, say a triangle, must be mapped to a position on the framebuffer canvas. For this an vertex attribute we call *position* goes through a number of affine transformations.

The first is from a local *model* space into world space , the *Model* transform.

From world space into eye space, the *View* transform. It is this view transform, which acts like placing the camera in a scene.

After that it put through the equivalent of a camera's lens, which is a Projection transform.

After the Projection transform the position is in *clip space* where it undergoes some operations, that are not essential to understand for the time being. After clipping the so called homogenous divide is applied to reach normalized device coordinate space, by dividing the clip space position vector by its own w-component.

```
v_position_ndc = v_position_clip / v_position_clip.w
```

This step is, what makes a perspective projection actually work. The z-distance of a vertex' position is worked into the clip space w-component. And by the homogenous divide vertices with a larger position w get scaled proportionally to 1/w in the XY plane which creates a perspective effect.

*You mistook this operation as normalization, but it is not!*

After the homogenous divide vertex position has been mapped from clip to NDC space. And OpenGL defines, that the visible volume of NDC space is the box [-1, 1]^3 ; vertices outside this box are clipped.

It's crucial to understand that View transform and Projection are different. For a position it's not so obvious, but another vertex attribute called the normal, which is an important ingredient for lighting calculations, must be transformed in a slightly different way (instead of `Projection · View · Model`

it must be transformed by `inverse(transpose(View · Model))`

, i.e. the Projection takes no part in it but the viewpoint does).

The matrices itself are 4×4 grids of real valued scalars (ignore for the time being that numbers in a computer are always rational numbers). So the rank of the matrix is 4 and hence it must be multiplied of vectors of dimension 4 (hence the type *vec4*)

OpenGL treats vertex attributes as column vectors so matrix multiplication is left associative i.e. a vector enters an expression on the right side and comes out on the left. **The order of matrix multiplication matters. You can not freely reorder things!**

The statement

```
gl_Position = Projection * View * Model * vertex_position; // note the order
```

makes the vertex shader perform this very transformation process I just described.