I am facing an issue when using MATLAB eig function to compute the eigenvalues and eigenvectors of a symmetric matrix.

The matrix D is

10x10

all diagonal elements = 0.45

all off-diagonal elements = -0.05

When using [vec, val] = eig(D) some of the resulting eigenvectors contain complex numbers (i.e 0.3384 + 0.0052i). I have searched online and I found two related posts on similar issue, but did not help me in finding a solution.

So I tried the same subroutine in Python numpy (numpy.linalg.eigh(D)) and it gave me all real eigenvalues and eigenvectors. The results from Python are correct as I was able to verify my final results with a published paper.

My question is what causes MATLAB to give complex eigenvalues and eigenvectors for a symmetric matrix? Is there a way around it? I can certainly re-write my algorithm in Python, but I would rather avoid that.

Note: if I try 4x4 matrix with all diagonal elements = 0.375 and all off-diagonal elements = -0.125 then MATLAB eig(D) gave all real eigenvalues and eigenvectors.

Thanks in advance for any advice on this issue.

Follow up. The code used to generate D and the eigenvalues/vectors:

```
P = eye(10) - 1/10;
delta = 1 - eye(10);
A = -0.5 * delta;
D = P*A*P;
[vec val] =eig(D)
```

`isreal(vec)`

returns`0`

for the code above for you? Is that actually the code you used when you got the complex values? How big are the imaginary parts? Are they virtually zero? What version of Matlab are you using (type`version`

in your command window)? – horchler Nov 18 '13 at 16:04`cdf2rdf`

which converts complex matricies to real analogues without losing any precision mathworks.com/help/matlab/ref/cdf2rdf.html – icherevkov Oct 12 '15 at 22:07