One quick and easy optimzation is to use `np.linalg.eigh`

. (And `np.linalg.eigvalsh`

if you just want the eigenvalues.)

Because you have a symmetric matrix (assuming you take the absolute value), you can "tell" numpy to use a more efficient algorithm this way.

```
import numpy as np
x = np.random.random(1000)
A = np.subtract.outer(x, x)
A = np.abs(A)
w, v = np.linalg.eigh(A)
```

Comparing timings, `eigh`

takes ~5.3 seconds while `eig`

takes ~23.4 seconds.

The performance of `np.linalg.eig`

, etc is going to be strongly dependent on which libraries numpy is linked to. Using a heavily optimized blas library (e.g. ATLAS or Intel's MKL) can have a very dramatic difference, especially in this case.

Also, depending on how numpy is built, (e.g. whether or not a fortran compiler was availabe) `scipy.linalg.eigh`

etc may be faster. There's also a chance that scipy and numpy may be linked against different blas libraries, though this is rather unlikely.