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.