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I have defined a matrix that contains the position and orientation of the camera similar to the GL_MODELVIEW matrix:


(m3 = 0; m7 = 0; m11 = 0; m15 = 1)

I'm trying to load this data into the ModelViewMatrix. I'm thinking in this two possibilites:

  • Using the function glLoadTransposeMatrixf():

    If I use this solution I'm obtaining the correct position and orientation. The problem is that I need to use the second solution because I'm modifying the Left/Up/Forward/Translation vectors on my code to modify the view.

  • Using the function gluLookAt():


    My problem is that the GL_MODELVIEW matrix that I'm obtaining with that is different from the other case. Specifically, the Translation vector is wrong, but the Left/Up/Forward vectors are correct.

I'm really confused with that. Can someone explain if there are differences between this two options and what I'm doing wrong, please?


Obtained results:

I'm using a matrix M like this:

M = (Lx   Upx   Fwx   tx)
    (Ly   Upy   Fwy   ty)
    (LZ   Upz   Fwz   tz)
    (0     0     0    1 )

With the first method i'm obtaining the correct GL_MODELVIEW matrix:

N = (Lx   Upx   Fwx   tx)
    (Ly   Upy   Fwy   ty)
    (Lz   Upz   Fwz   tz)
    (0     0     0    1 )

but with the second method i'm obtaining the next GL_MODELVIEW matrix:

N = (Lx   Upx   Fwx   tx')
    (Ly   Upy   Fwy   ty')
    (Lz   Upz   Fwz   tz')
    (0     0     0    1 )

Note that tx'!=tx, ty'!=ty, tz'!=tz. This is very confusing...

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1 Answer 1

up vote 0 down vote accepted

There are differences between the two options. Let's call your matrix M. What does M actually do? It does not transform from world space to eye space, but exactly the inverse. Think about it. You assume your camera is at point "translation". Let's assume the rest of M is identity, so a point exactly at the camera location should be translated to the origin. But it will end up at translation.xyz+translation.xyz, so actually, your camera is at the point -translation.xyz.

If your first method actually gives the "correct" results, you seem to have something else wrong.

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So you are saying that I should use -Translation instead of Translation on my gluLookAtFunction, right? Anyway, I'm not obtaining the expected result with that, so there is something else wrong. –  Escucum May 12 '13 at 14:17
@Escucum: I'm saying much more than that. You won't get the xepected result that way, as your matrix M is still the inverse of what gluLookAt does. You could achieve the same result as M^-1 with lookAt if you did a gluLookAt(Transpose, Transpose + Forward, Up); If you wanted to get exactly your matrix back, you would not only have to negate Translate, but also specify completely diffferent vectors. –  derhass May 12 '13 at 15:01
Ok, now I got you. But I'm already using the correct Transpose matrix of M on the gluLookAt solution. I have edited the question including a specific example with the obtained results with both possibilites to clarify my problem. –  Escucum May 12 '13 at 15:23
@Escucum: well, if your upper 3x3 submatrix is an orthonormal basis (and this might be not unlikely in this scenario), the transpose of it will be its inverse. But that does not consider the translation part. Basically, you have a rotation R and translation T. Your M = T*R, but M^-1=R^-1*T^-1 (note the swapped order), which explain the differences in the translation part, and cannot be fixed by a simple transpose. –  derhass May 12 '13 at 15:32
That was really helpful and solved my problem. Thank you very much for your time. =) –  Escucum May 12 '13 at 16:31

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