Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

A linear algebra question;

Given a k-variate normed vector u (i.e. u : ||u||_2=1) how do you construct \Gamma_u, any arbitrary k*(k-1) matrix of unit vectors such that (u,\Gamma_u) forms an orthogonal basis ?

I mean: from a computationnal stand point of view: what algorithm do you use to construct such matrices ?

Thanks in advance,

share|improve this question
up vote 4 down vote accepted

The naive approach would be to apply Gram Schmidt orthogonalisation of u_0, and k-1 randomly generated vectors. If at some point the GS algorithm generates a zero vector, then you have a linear dependency in which case choose the vector randomly again.

However this method is unstable, small numerical errors in the representation of the vectors gets magnified. However there exists a stable modification of this algorithm:

Let a_1 = u, a_2,...a_k be randomly chosen vectors

for i = 1 to k do 
        vi = ai
end for 

for i = 1 to k do
    rii = |vi| 
    qi = vi/rii
    for j = i + 1 to k do
       rij =<qi,vj>
       vj =vj −rij*qi 
    end for
end for

The resulting vectors v1,...vk will be the columns of your matrix, with v1 = u. If at some point vj becomes zero choose a new vector aj and start again. Note that the probability of this happening is negligible if the vectors a2,..,ak are chosen randomly.

share|improve this answer
Thank you: i go back home and try it and let you know, Best. – user189035 Jun 29 '10 at 11:41
Instead of starting with a random base, you could. 1) Check if the starting vector is a multiple of one in the canonical base. 2) if it is, select the other n-1 vectors in the canonical base. 3) If it is not, check any n-1 vectors of the caninical base. /// No probability of choosing a wrong base. – Dr. belisarius Jun 29 '10 at 16:15
@belisarius, you could still end up with linear dependence. Consider the trivial case u = (1,1,0), and e1=(1,0,0), e2=(0,1,0), e3=(0,0,1), then u is not a linear multiple of any one but choosing e1 and e2 as the other two vectors would result in a linear combination. In general detecting linear combinations is not cheap, so its probably cheaper to just restart the Gram-schmidt method with a new random vector since this is such a rare event – Il-Bhima Jun 29 '10 at 17:05
@Il-Bhima yep. shame on me – Dr. belisarius Jun 29 '10 at 17:18
shouldn't it be for i in 1 to (k-1) do ??? – user189035 Jun 30 '10 at 17:20

You can use Householder matrices to do this. See for example http://en.wikipedia.org/wiki/Householder_reflection and http://en.wikipedia.org/wiki/QR_decomposition

One can find a Householder matrix Q so that Q*u = e_1 (where e_k is the vector that's all 0s apart from a 1 in the k-th place) Then if f_k = Q*e_k, the f_k form an orthogonal basis and f_1 = u. (Since Q*Q = I, and Q is orthogonal.)

All this talk of matrices might make it seem that the routine would be expensive, but this is not so. For example this C function, given a vector of length 1 returns an array with the required basis in column order, ie the j'th component of the i'th vector is held in b[j+dim*i]

   double*  make_basis( int dim, const double* v)
    double* B = calloc( dim*dim, sizeof * B);
    double* h = calloc( dim, sizeof *h);
    double  f, s, d;
    int i, j;

    /* compute Householder vector and factor */
    memcpy( h, v, dim*sizeof *h);
    s = ( v[0] > 0.0) ? 1.0 : -1.0;
    h[0] += s;  
    f = s/(s+v[0]);

    /* compute basis */
    memcpy( B, v, dim * sizeof *v); /* first one is v */
    /* others by applying Householder matrix */
    for( i=1; i<dim; ++i)
    {   d = f*h[i];
        for( j=0; j<dim; ++j)
        {   B[dim*i+j] = (i==j) - d*h[j];
    free( h);
    return B;
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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