Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

Talking about bump mapping, specular highlight and these kind of things in OpenGL Shading Language (GLSL)

I have:

  • An array of vertices (e.g. {0.2,0.5,0.1, 0.2,0.4,0.5, ...})
  • An array of normals (e.g. {0.0,0.0,1.0, 0.0,1.0,0.0, ...})
  • The position of a point light in world space (e.g. {0.0,1.0,-5.0})
  • The position of the viewer in world space (e.g. {0.0,0.0,0.0}) (assume the viewer is in the center of the world)

Now, how can I calculate the Binormal and Tangent for each vertex? I mean, what is the formula to calculate the Binormals, what I have to use based on those informations? And about the tangent?

I'll construct the TBN Matrix anyway, so if you know a formula to construct the matrix directly based on those informations will be nice!

Oh, yeh, I have the texture coordinates too, if needed. And as I'm talking about GLSL, would be nice a per-vertex solution, I mean, one which doesn't need to access more than one vertex information at a time.

---- Update -----

I found this solution:

vec3 tangent;
vec3 binormal;

vec3 c1 = cross(a_normal, vec3(0.0, 0.0, 1.0));
vec3 c2 = cross(a_normal, vec3(0.0, 1.0, 0.0));

if (length(c1)>length(c2))
{
    tangent = c1;
}
else
{
    tangent = c2;
}

tangent = normalize(tangent);

binormal = cross(v_nglNormal, tangent);
binormal = normalize(binormal);

But I don't know if it is 100% correct.

share|improve this question
    
mayebe a question for gamedev.stackexchange.com ? – nkint Mar 10 '11 at 8:18
11  
@user464230: No, it's okay here, too. 3D graphics isn't limited to games. – datenwolf Mar 10 '11 at 8:37
1  
That "solution" assumes you'll apply your normal map texture on a planar face with the normal = x. This will not work if applied to an arbitrary model. What you really need to do is solve the system of equations I gave you down there for each face and use the mean values for the vertices. If you want to do serious 3D programming you'll have to learn, how to translate linear algebra - like I showed below - into source code. – datenwolf Mar 10 '11 at 14:27
    
"If you want to do serious 3D programming you'll have to learn, how to translate linear algebra - like I showed below - into source code."... Man, really, You don't meet me!!! Don't tell me "you'll to learn"... You don't have any idea of what I've done... Take care with your words! – user464230 Mar 10 '11 at 14:43
2  
@user464230: No, I've no knowledge of what you've actually done. But you asked about how to calculate tangent and binormal. So what you can expect is a mathematical description of the process. If you just want some source code you can copy and paste, well, there's plenty of it out there. But to understand how to use it effectively you must understand what it does on a mathematical level. Which requires you to learn to read and understand linear algebra. The way you ask your question(s) and commented on my post clearly shows me, that you've not learned how to properly read math, yet. – datenwolf Mar 10 '11 at 15:19

The relevant input data to your problem are the texture coordinates. Tangent and Binormal are vectors locally parallel to the object's surface. And in the case of normal mapping they're describing the local orientation of the normal texture.

So you have to calculate the direction (in the model's space) in which the texturing vectors point. Say you have a triangle ABC, with texture coordinates HKL. This gives us vectors:

D = B-A
E = C-A

F = K-H
G = L-H

Now we want to express D and E in terms of tangent space T, U, i.e.

D = F.s * T + F.t * U
E = G.s * T + G.t * U

This is a system of linear equations with 6 unknowns and 6 equations, it can be written as

| D.x D.y D.z |   | F.s F.t | | T.x T.y T.z |
|             | = |         | |             |
| E.x E.y E.z |   | G.s G.t | | U.x U.y U.z |

Inverting the FG matrix yields

| T.x T.y T.z |           1         |  G.t  -F.t | | D.x D.y D.z |
|             | = ----------------- |            | |             |
| U.x U.y U.z |   F.s G.t - F.t G.s | -G.s   F.s | | E.x E.y E.z |

Together with the vertex normal T and U form a local space basis, called the tangent space, described by the matrix

| T.x U.x N.x |
| T.y U.y N.y |
| T.z U.z N.z |

Transforming from tangent space into object space. To do lighting calculations one needs the inverse of this. With a little bit of exercise one finds:

T' = T - (N·T) N
U' = U - (N·U) N - (T'·U) T'

Normalizing the vectors T' and U', calling them tangent and binormal we obtain the matrix transforming from object into tangent space, where we do the lighting:

| T'.x T'.y T'.z |
| U'.x U'.y U'.z |
| N.x  N.y  N.z  |

We store T' and U' them together with the vertex normal as a part of the model's geometry (as vertex attributes), so that we can use them in the shader for lighting calculations. I repeat: You don't determine tangent and binormal in the shader, you precompute them and store them as part of the model's geometry (just like normals).

(The notation between the vertical bars above are all matrices, never determinants, which normally use vertical bars instead of brackets in their notation.)

share|improve this answer
    
Your matrix inversion is wrong. The inverse of a matrix is not a scalar but a matrix. So should be (1/fsgt-ftgs)((gt, -ft)(-gs, gs)) – Gottfried Nov 25 '12 at 14:21
    
@Gottfried: Where do you see a scalar there? What you see there is the determinant method for inverting a matrix. The denominator in the scaling factor is the determinant of the matrix [F G] (F, G are column vectors). You could use Gauss-Jordan elimination as well, yielding the very same result. – datenwolf Nov 25 '12 at 19:29
    
BTW, you can find the very same derivation as I did it here in most 3D programming textbooks – datenwolf Nov 25 '12 at 19:34
    
I know that you are doing inversion via determinant, but if you look at your post you'll see that you've forgotten the matrix part. You only divide by the determinant which is a scalar. Compare e.g. with link I hope I could clear this up and I'm sure it was just an oversight. – Gottfried Nov 28 '12 at 9:09
    
@Gottfried: Ah, I was looking at the wrong side of the equation. Yes, I totally missed that. Thanks – datenwolf Nov 28 '12 at 11:57

Generally, you have 2 ways of generating the TBN matrix: off-line and on-line.

  • On-line = right in the fragment shader using derivative instructions. Those derivations give you a flat TBN basis for each point of a polygon. In order to get a smooth one we have to re-orthogonalize it based on a given (smooth) vertex normal. This procedure is even more heavy on GPU than initial TBN extraction.

    // compute derivations of the world position
    vec3 p_dx = dFdx(pw_i);
    vec3 p_dy = dFdy(pw_i);
    // compute derivations of the texture coordinate
    vec2 tc_dx = dFdx(tc_i);
    vec2 tc_dy = dFdy(tc_i);
    // compute initial tangent and bi-tangent
    vec3 t = normalize( tc_dy.y * p_dx - tc_dx.y * p_dy );
    vec3 b = normalize( tc_dy.x * p_dx - tc_dx.x * p_dy ); // sign inversion
    // get new tangent from a given mesh normal
    vec3 n = normalize(n_obj_i);
    vec3 x = cross(n, t);
    t = cross(x, n);
    t = normalize(t);
    // get updated bi-tangent
    x = cross(b, n);
    b = cross(n, x);
    b = normalize(b);
    mat3 tbn = mat3(t, b, n);
    
  • Off-line = prepare tangent as a vertex attribute. This is more difficult to get because it will not just add another vertex attrib but also will require to re-compose all other attributes. Moreover, it will not 100% give you a better performance as you'll get an additional cost of storing/passing/animating(!) vector3 vertex attribute.

The math is described in many places (google it), including the @datenwolf post.

The problem here is that 2 vertices may have the same normal and texture coordinate but different tangents. That means you can not just add a vertex attribute to a vertex, you'll need to split the vertex into 2 and specify different tangents for the clones.

The best way to get unique tangent (and other attribs) per vertex is to do it as early as possible = in the exporter. There on the stage of sorting pure vertices by attributes you'll just need to add the tangent vector to the sorting key.

As a radical solution to the problem consider using quaternions. A single quaternion (vec4) can successfully represent tangential space of a pre-defined handiness. It's easy to keep orthonormal (including passing to the fragment shader), store and extract normal if needed. More info on the KRI wiki.

share|improve this answer
    
@user464230: It is not very elegant. It's a brute force approach utilizing the abundant computing power of a modern GPU, kind of the "if I don't grok the math, do it the tedious way"-method. @kvark already told that it will perform worse. – datenwolf Mar 10 '11 at 15:36
    
@datenwolf. I didn't say the GLSL approach is slower, even if it is :). I like it for the universality: you don't need to do your own exporter (or mesh attributes re-computation), you don't need to care about tangents during skeletal animations. It just works. – kvark Mar 10 '11 at 15:49
    
@kvark: You write "it's more heavy on the GPU", and yes it is. Extracting the partial derivates is really hard work for the GPU (it boils down to that for each fragment the computations of the neighbours have to be emulated, or it must wait for them (not always with a result if the fragment gets killed or another code branch is executed). Yes it just works, but at the price of reduced fill rate. – datenwolf Mar 10 '11 at 15:59
    
@datenwolf. Citing myself "This procedure is even more heavy on GPU than initial TBN extraction" - I meant not what you read :). Nevertheless, I agree with your sentence. – kvark Mar 10 '11 at 16:05
1  
@user464230: Those quaternios are just a more compact representation of the TBN matrix. Tangent space can be understood as the local transformation required to align (rotate) the surface local tangent space with the (global) object space. I.e. the TBN matrix is a rotation matrix. Now, rotations can be expressed as a quaternion, too. So the way to get this tangent quaternion (@kvark: nice idea BTW!) is to determine the TBN matrix and derive its equivalent quaternion, which is a eigenvalue problem. Wikipedia has the math: en.wikipedia.org/wiki/Quaternions_and_spatial_rotation – datenwolf Mar 11 '11 at 0:59

protected by datenwolf Nov 25 '12 at 20:32

Thank you for your interest in this question. Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site (the association bonus does not count).

Would you like to answer one of these unanswered questions instead?

Not the answer you're looking for? Browse other questions tagged or ask your own question.