There is no need to do repeated solves IF you can afford to do ONE computation of the null space. Just one call to null will suffice. Given a new vector V, if the dot product with V and the nullspace basis is non-zero, then V will increase the rank of the matrix. For example, suppose we have the matrix M, which of course has a rank of 2.

```
M = [1 1;2 2;3 1;4 2];
nullM = null(M')';
```

Will a new column vector [1;1;1;1] increase the rank if we appended it to M?

```
nullM*[1;1;1;1]
ans =
-0.0321573705742971
-0.602164651199413
```

Yes, since it has a non-zero projection on at least one of the basis vectors in nullM.

How about this vector:

```
nullM*[0;0;1;1]
ans =
1.11022302462516e-16
2.22044604925031e-16
```

In this case, both numbers are essentially zero, so the vector in question would not have increased the rank of M.

The point is, only a simple matrix-vector multiplication is necessary once the null space basis has been generated. If your matrix is too large (and the matrix nearly of full rank) that a call to null will fail here, then you will need to do more work. However, n = 4096 is not excessively large as long as the matrix does not have too many columns.

One alternative if null is too much is a call to svds, to find those singular vectors that are essentially zero. These will form the nullspace basis that we need.

`A`

always the same and you check against many vectors`v`

? Or are`A`

and`v`

different for every run? – Florian Brucker Feb 1 '12 at 15:17`v`

. – Jonas Feb 1 '12 at 17:27