# positive semi-definite matrices and numerical stability?

Facebook and Stack Exchange are now working together to support the Facebook developer community. Facebook engineers participate here along with the best Facebook developers in the world. If you have a technical question about Facebook, this is the best place to ask.

i'm trying to do factor analysis for a co-occurrence matrix(C) , which is computed from the term-document matrix(TD) as follows: C=TD*TD'

In theory C should be positive semi-definite , but it isn't and the factor analysis algorithm can't work with it because of this.I can't change the algo because of speed reasons).

I look it up and it might be a numerical stability issue : http://stackoverflow.com/questions/619335/a-simple-algorithm-for-generating-positive-semidefinite-matrices - answer 2.

What's a good way to proceed here ?

-
by definition `A*A'` is always pos semi-def.. what is the exact error you get with your factor analysis implementation? – Amro Jan 22 '10 at 11:58

I would do an eigendecomposition of the matrix:

``````C=Q D Q^-1
``````

If your matrix really is positive semidefinite, then all of the eigenvalues (the entries on the diagonal of D) should be non-negative. (This is probably the test that your factor analysis algorithm is doing as well to see if the matrix is positive semidefinite.)

If you're suffering numeric problems, some of the eigenvalues will probably be barely smaller than zero. Try setting these entries to zero, compute `Q D Q^-1` to get a new, corrected C, then submit that to your factor analysis algorithm.

On the other hand, if you find that your matrix C has truly negative eigenvalues, then you know that you're going wrong somewhere in the construction of C.

-
thanks. how small the eigenvalues need to be to be considered a numerical error ? i get negative values between -9e-15 to -1e-32. – yaniv Jan 22 '10 at 10:41
That's definitely within the range of numerical error. Do you have access to the source code of your factor analysis routine? It's likely it's doing an eigendecomposition itself -- in which case, you could simply modify the code to allow slighly negative eigenvalues. Otherwise, use the method I suggested above -- but beware that after multiplying `Q D Q^-1` together again, you may get new numerical errors that take your eigenvalues slightly below zero again. One thing you could try in that case is to make the eigenvalues very slightly positive instead of exactly zero. – Martin B Jan 22 '10 at 11:40
I am a little late to the ball here, but I thought I would post a comment. You need to be careful computing the eigen-decomposition of C, as when forming C you are doubling the condition number of of TD, which could lead to numerical instabilities. With that in mind, I would look at the condition number of TD. It may be that when forming these matrices, they are very badly conditions, leading to poor results when forming and using C. – SplittingField Feb 27 '10 at 17:12

Not being able to comment, I will have to echo SplittingField's comment, with the nitpick that forming C=TD*TD' squares the condition number of TD, not double it. Equivalent and much more stable to finding the eigendecomposition of C would be to perform singular value decomposition (SVD) on TD. You get the condition number as a bonus: the ratio of the largest singular value to the smallest singular value is the condition number of the matrix, and the base-10 logarithm of that is an estimate on how much decimal digits you stand to lose had you gone through with using C in your calculations (of course, if the tiniest singular value is 0, your problem is singular!)

-
 Not to mention that performing factor decomposition exactly amounts to performing the SVD on TD ! Good point about the bad condition number of TD TD^t. – Alexandre C. Aug 30 '11 at 12:39

First of all, there are techniques for repairing "pathologies" of matrices with negative eigenvalues -- recall, the matrix originates through a series of computations and its commonly these steps which result in the pathologies in the first place. It's not really appropriate to accept the fact that because a matrix has small, near-zero negative eigenvalues, it's a "bad" matrix. Rather, do some work on repairing the pathologies. With regard to SVD, I agree that it is one of the better approaches -- however, I don't commonly use it in work so much because it's so expensive computationally. However, if you have one or more matrix elements that are zero, i.e. the matrix is sparse, then you must use SVD since it will be one of the only methods that will work.

-