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When I use the linear algebra module in scipy to calculate the matrix logarithm of a hermitian matrix, the matrix that it outputs isn't hermitian. I first define a vector using:

n = np.random.uniform(size = 3) + 1j*np.random.uniform(size = 3)

Then I define the respective hermitian matrix:

N = np.outer(n,n.conj())

However, linalg.logm(N) doesn't return a hermitian matrix. Why is this happening?

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N is not a matrix when I run this code. –  askewchan Apr 13 '13 at 16:06
Sorry, I meant np.random.uniform(size = 3). I've corrected the OP. –  WiFO215 Apr 13 '13 at 16:08
Your matrix is singular; in fact, it has rank 1. It doesn't have a logarithm. –  Warren Weckesser Apr 13 '13 at 16:24

1 Answer 1

up vote 2 down vote accepted

All but one eigenvalues of the random matrix are zero. Since functions on matrices can be written as functions on the eigenvalues of a matrix, I see why the logarithm has a problem there, because log(0) is not defined. Maybe the function doesn't see this problem and just returns garbage.

I guess that you just need to make sure that your random Hermitian matrix has nonzero eigenvalues.

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And to the question why the result is not Hermitian: the algorithm used in logm here is not written in a way that it preserves hermiticity as an exact property. Since the input matrix is at a singular point, due to rounding error the result corresponds to the logm of some matrix eps-close to the input matrix. Since hermiticity is not exactly preserved, the eps-close matrix is usually non-hermitian. Now, a good question would be: Why is the error estimate computed in funm(N, np.log, disp=0) not accurate in this case? –  pv. Apr 13 '13 at 16:39
Yes, I shall try that. Thank you! –  WiFO215 Apr 14 '13 at 4:26

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