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# matrix that forms an orthogonal basis with a given vector

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 ?

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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.

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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;
}
``````
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