# How perspective matrix works?

I started to read lesson 1 in learningwebgl blog, and I noticed this part:

``````var pMatrix = mat4.create();
mat4.perspective(45, gl.viewportWidth / gl.viewportHeight, 0.1, 100.0, pMatrix);
``````

I roughly understand how matrices (translation/rotation/multiple) works, but I have no idea what `mat4.perspective(...)` means. What is it used for? What is the result, if I multiply a vector with this matrix?

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The perspective matrix is used to scale, and possibly translate or flip the coordinate system in preparation for the perspective divide. Since the the perspective projection operation involves a divide, it cannot be represented by a linear matrix transformation alone.

In a programmable graphics pipeline (see pixel shaders) you cannot see the divide operation - it is still one of the fixed-function parts. The programmer controls it by tweaking the variables involved in the operation. In the case of the perspective divide it is the projection matrix that gives you this control.

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Thanks, but then how to convert `(x,y,z)` coordinates from inside the perspective pyramid, to `(x',y',z')` coordinates inside the 1*1*1 cube? – defunct Mar 11 '13 at 15:27
Sounds like you've done some reading since you posted the original question. Open another question if you want a proper answer, there's not enough space in the comments. – user1157123 Mar 11 '13 at 15:38

The projection matrix is used to convert world-coordinates to screen coordinates.

The positions in your three-dimensional virtual world are triplets of x, y and z coordinates. When you want to draw something (or rather tell OpenGL to draw something) it needs to calculation where these coordinates are on the users screen.

This calculation is implemented with matrix multiplication.

A vector consisting of x, y and z (and a fourth value of 1 which is necessary to allow the matrix to do some operations like scaling) is multiplied with a matrix to receive a new set of x, y and z coordinates (4th value is discarded) which represent where this point is on the users screen (the z-coordinate is required to determine which objects are in front of others).

The function mat4.perspective generates a projection matrix which generates a matrix which does exactly that. The arguments are:

• The field-of-view in degree (45)
• the aspect ratio of the field of view (the aspect ratio of the viewport)
• the minimal distance from the viewer which is still drawn (0.1 world units)
• the maximum distance from the viewer which is still drawn (100.0 world units)
• the array in which the generated matrix is stored (pMatrix)

When a point is multiplied with this matrix, the result are the screen coordinates where this point has to be drawn.

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Can the person who downvoted this please explain what's wrong with my answer? – Philipp Mar 11 '13 at 13:57
I didn't downvote it, but your description of how the homogeneous coordinates work isn't very good. – andrewmu Mar 11 '13 at 14:04
This answer is wrong. For one thing, a projection matrix does not actually do the projection - it does not produce "screen coordinates", and that "4th value" is not "discarded" (ok, that was three things...) – JasonD Mar 11 '13 at 14:05
I agree. Multiplying by the projection matrix does not transform a point to screen-space. – user1157123 Mar 11 '13 at 14:06
@JasonD Just curious: can you clarify what you mean by a `a projection matrix does not actually do the projection`? I suspect we're differing on the definition of "projection", otherwise the folks who developed OpenGL (and other graphics libraries) wouldn't have chosen the term. Projection matrices transform eye coordinates into normalized device coordinates (NDCs), and then the viewport transform converts NDCs (post clipping) into viewport coordinates (which people often [incorrectly] label as window or screen coordinates). – radical7 Mar 11 '13 at 19:30