How can we randomly create a real squared matrix A and all of its eigenvalues are complex number λ=a+bi in Matlab?

I'll first take a random n X 2 data matrix, A, with n > 2. We want the columns of A to have similar variance and there to be some correlation between the columns. You can achieve this using the choleski decomposition of a 2x2 covariance matrix. Then we'll take the sample covariance matrix of A, lets call this B. If we change B(1,2) = B(1,2) then B will have complex eigen values with high probability. The reason for this is a covariance matrix is of the form [a,b;b,c] and the fundamental equation for the matrix is (alam)*(clam)  b^2. In order for this to have complex eigen values we need 4*a*c 4*b^2 > (a+c)^2. Which can be written as 4*b^2 > (ac)^2. This can't happen, unless we change B(1,2) = B(1,2) then the requirement becomes 4*b^2 > (ac)^2. So since a and c are the variances of the columns of A, if they have similar variance (ac)^2 will be close to zero. and if the columns of A have decent correlation then 4b^2 will be far from zero and positive. Therefore you get complex eigen values. This shouldn't be too hard to extend to general nxn matrices. 


I have tried to extend to general nxn matrices. One issue is that if n is odd, Matlab always generates at least one real eigenvalues e.g : n = 3 random_matrix = cov(rand(3));
random_matrix =
0.0578 0.0257 0.0614 eig(random_matrix) = 0.1457 + 0.1483i 0.1457  0.1483i 0.0752 + 0.0000i is there any better way to randomly generate a real stable matrix which only has imaginary part of eigenvalues ? 


Note the eigenvalues are conjugates of one another and so are the eigenvectors. Note that the resulting matrix A has all real entries.
Thus, suppose you want a real matrix with eigenvalues 1+i and 1i and eigenvectors (1,1+i) and (1,1i).
And we can check our answer.
At first, we think it didn't return the same eigenvectors that we entered. However, any multiple of an eigenvector is still an eigenvector, and look what happens when we multiply matrix v by 1+i.
Those are the eigenvectors we entered. If you don't have Matlab's Symbolic Toolbox, I did this in the editor.
And this is the output.


