I want to check if a matrix is positive definite or positive semidefinite using Python.

How can I do that? Is there a dedicated function in SciPy for that or in other modules?


I assume you already know your matrix is symmetric.

A good test for positive definiteness (actually the standard one !) is to try to compute its Cholesky factorization. It succeeds iff your matrix is positive definite.

This is the most direct way, since it needs O(n^3) operations (with a small constant), and you would need at least n matrix-vector multiplications to test "directly".

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  • i was asking if there is a direct method for that. Thanks anyway – sramij Apr 6 '11 at 11:58
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    @sramij this is the most direct way to test – David Heffernan Apr 6 '11 at 12:15
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    @sramij: This is a direct method, and is faster than anything else, unless you have additional a priori information about the matrix. – Stephen Canon Apr 6 '11 at 18:14
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    For the positive semi-definite case it remains true as an abstract proposition that a real symmetric (or complex Hermitian) matrix is positive semi-definite if and only if a Cholesky factorization exists. With a positive definite matrix the usual algorithm succeeds because all the diagonal entries of L s.t. A =LL' are positive (a square root being taken). If we hit a zero pivot, the computation halts, but the theory holds. – hardmath Apr 6 '11 at 23:57
  • @hardmath: indeed, the existence of the cholesky decomposition for semidefinite matrices holds by a limiting argument. – Alexandre C. Apr 7 '11 at 7:13

Cholesky decomposition is a good option if you're working with positive definite (PD) matrices.

However, it throws the following error on positive semi-definite (PSD) matrix, say,

A = np.zeros((3,3)) // the all-zero matrix is a PSD matrix
LinAlgError: Matrix is not positive definite -
Cholesky decomposition cannot be computed

For PSD matrices, you can use scipy/numpy's eigh() to check that all eigenvalues are non-negative.

>> E,V = scipy.linalg.eigh(np.zeros((3,3)))
>> E
array([ 0.,  0.,  0.])

However, you will most probably encounter numerical stability issues. To overcome those, you can use the following function.

def isPSD(A, tol=1e-8):
  E = np.linalg.eigvalsh(A)
  return np.all(E > -tol)

Which returns True on matrices that are approximately PSD up to a given tolerance.

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    Actually, you can probably accelerate isPSD() by replacing eigh() with eigvalsh() which only computes the eigenvalues (I have not tested this). – Tomer Levinboim Jun 23 '13 at 22:29
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    I believe that scipy.linalg.eigh(A) should be altered to np.linalg.eigh(A) – Vincent Russo Aug 4 '14 at 20:05
Check whether the whole eigenvalues of a symmetric matrix A are non-negative is time-consuming if A is very large, while the module scipy.sparse.linalg.arpack provides a good solution since one can customize the returned eigenvalues by specifying parameters.(see Scipy.sparse.linalg.arpack for more information)

As we know if both ends of the spectrum of A are non-negative, then the rest eigenvalues must also be non-negative. So we can do like this:

from scipy.sparse.linalg import arpack
def isPSD(A, tol = 1e-8):
    vals, vecs = arpack.eigsh(A, k = 2, which = 'BE') # return the ends of spectrum of A
    return np.all(vals > -tol)

By this we only need to calculate two eigenvalues to check PSD, I think it's very useful for large A

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  • Would it be ok with 'SA' and k=1? – user2660966 Aug 7 at 13:13

an easier method is to calculate the determinants of the minors for this matrx.

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    Computing the determinants requires n LU/QR/Cholesky decompositions, so just checking if Cholesky of the whole matrix succeeds should be faster. – pv. Apr 6 '11 at 13:21
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    It is true that a real symmetric (resp. complex Hermitian) matrix is positive semi-definite if and only if all its principal minors are nonnegative. See the note by John Prussing here correcting the misstatement sometimes made that it suffices to check the leading principal minors are nonnegative. The latter is necessary but not sufficient for positive semi-definiteness. – hardmath Apr 7 '11 at 0:10

One good solution is to calculate all the minors of determinants and check they are all non negatives.

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  • Only the principal minors. – Rodrigo de Azevedo Jun 6 '18 at 10:36
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    Isn´t this O(n!)? Cholesky factorization is faster – DarK_FirefoX Sep 30 '19 at 13:04

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