I have a matrix such as this example (my actual matrices can be much larger)
A = [-1 -2 -0.5; 0 0.5 0; 0 0 -1];
that has only two linearly-independent eigenvalues (the eigenvalue -1 is repeated). I would like to obtain a complete basis with generalized eigenvectors. One way I know how to do this is with Matlab's
jordan function in the Symbolic Math toolbox, but I'd prefer something designed for numeric inputs (indeed, with two outputs,
jordan fails for large matrices: "Error in MuPAD command: Similarity matrix too large."). I don't need the Jordan canonical form, which is notoriously unstable in numeric contexts, just a matrix of generalized eigenvectors. Is there a function or combination of functions that automates this in a numerically stable way or must one use the generic manual method (how stable is such a procedure)?
NOTE: By "generalized eigenvector," I mean a non-zero vector that can be used to augment the incomplete basis of a so-called defective matrix. I do not mean the eigenvectors that correspond to the eigenvalues obtained from solving the generalized eigenvalue problem using
qz (though this latter usage is quite common, I'd say that it's best avoided). Unless someone can correct me, I don't believe the two are the same.
UPDATE 1 – Five months later:
See my answer here for how to obtain generalized eigenvectors symbolically for matrices larger than 82-by-82 (the limit for my test matrix in this question).
I'm still interested in numeric schemes (or how such schemes might be unstable if they're all related to calculating the Jordan form). I don't wish to blindly implement the linear algebra 101 method that has been marked as a duplicate of this question as it's not a numerical algorithm, but rather a pencil-and paper method used to evaluate students (I suppose that it could be implemented symbolically however). If anyone can point me to either an implementation of that scheme or a numerical analysis of it, I'd be interested in that.
UPDATE 2 – Feb. 2015: All of the above is still true as tested in R2014b.