I am finding that scipy.linalg.eig sometimes gives inconsistent results. But not every time.
>>> import numpy as np >>> import scipy.linalg as lin >>> modmat=np.random.random((150,150)) >>> modmat=modmat+modmat.T # the data i am interested in is described by real symmetric matrices >>> d,v=lin.eig(modmat) >>> dx=d.copy() >>> vx=v.copy() >>> d,v=lin.eig(modmat) >>> np.all(d==dx) False >>> np.all(v==vx) False >>> e,w=lin.eigh(modmat) >>> ex=e.copy() >>> wx=w.copy() >>> e,w=lin.eigh(modmat) >>> np.all(e==ex) True >>> e,w=lin.eigh(modmat) >>> np.all(e==ex) False
While I am not the greatest linear algebra wizard, I do understand that the eigendecomposition is inherently subject to weird rounding errors, but I don't understand why repeating the computation would result in a different value. But my results and reproducibility are varying.
What exactly is the nature of the problem -- well, sometimes the results are acceptably different, and sometimes they aren't. Here are some examples:
>>> d (9.8986888573772465+0j) >>> dx (9.8986888573772092+0j)
The difference above of ~3e-13 does not seem like an enormously big deal. Instead, the real problem (at least for my present project) is that some of the eigenvalues cannot seem to agree on the proper sign.
>>> np.all(np.sign(d)==np.sign(dx)) False >>> np.nonzero(np.sign(d)!=np.sign(dx)) (array([ 38, 39, 40, 41, 42, 45, 46, 47, 79, 80, 81, 82, 83, 84, 109, 112]),) >>> d (-6.4011617320002525+0j) >>> dx (6.1888785138080209+0j)
Similar code in MATLAB does not seem to have this problem.