Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

How expensive is it to compute the eigenvalues of a matrix?

What is the complexity of the best algorithms?

How long might it take in practice if I have a 1000 x 1000 matrix? I assume it helps if the matrix is sparse?

Are there any cases where the eigenvalue computation would not terminate?

In R, I can compute the eigenvalues as in the following toy example:

m<-matrix( c(13,2, 5,4), ncol=2, nrow=2 )
eigen(m, only.values=1)
[1] 14  3

Does anyone know what algorithm it uses?

Are there any other (open-source) packages that compute the eigenvalue?

share|improve this question
If I'm not mistaken the magic in Google PageRank is (at least partley) a giant eigenvalue calculation. It would be nice to see how they do it. We used power iteration or QR decomposition when doing it in MATLAB during a course in numerical analysis. –  sris Apr 3 '09 at 13:45
The Google Pagerank computation corresponds to a very specific eigenvalue problem: computing the eigenvector associated with the dominant unit eigenvalue of a stochastic matrix. In that case, a specialized algorithm is used (probably based on some variant of the power method) . –  Fanfan Apr 6 '09 at 18:38

7 Answers 7

Most of the algorithms for eigen value computations scale to big-Oh(n^3), where n is the row/col dimension of the (symmetric and square) matrix.

For knowing the time complexity of the best algorithm till date you would have to refer to the latest research papers in Scientific Computing/Numerical Methods.

But even if you assume the worse case, you would still need at least 1000^3 operations for a 1000x1000 matrix.

R uses the LAPACK routine's (DSYEVR, DGEEV, ZHEEV and ZGEEV) implementation by default. However you could specify the EISPACK=TRUE as a parameter to use a EISPACK's RS, RG, CH and CG routines.

The most popular and good open source packages for eigenvalue computation are LAPACK and EISPACK.

share|improve this answer
EISPACK is now defunct and ignored. See stat.ethz.ch/R-manual/R-devel/library/base/html/eigen.html –  Randel Feb 26 '14 at 17:21

With big matrices you usually don't want all the eigenvalues. You just want the top few to do (say) a dimension reduction.

The canonical algorithm is the Arnoldi-Lanczos iterative algorithm implemented in ARPACK:


There is a matlab interface in eigs:


eigs(A,k) and eigs(A,B,k) return the k largest magnitude eigenvalues.

And there is now an R interface as well:


share|improve this answer

I assume it helps if the matrix is sparse?

Yes, there are algorithms, that perform well on sparse matrices.

See for example: http://www.cise.ufl.edu/research/sparse/

share|improve this answer
Is there algorithm for finding eigenvalues? I search for a while and get nothing... –  Marek May 28 '10 at 20:00
@Marak: see Lanczos, Jacobi-Davidson, and other iterative methods, which work particularly well if you are only interested in a subset of eigenvalues. –  Jim Garrison Sep 30 '13 at 17:07

How long might it take in practice if I have a 1000x1000 matrix?

MATLAB (based on LAPACK) computes on a dual-core 1.83 GHz machine all eigenvalues of a 1000x1000 random in roughly 5 seconds. When the matrix is symmetric, the computation can be done significantly faster and requires only about 1 second.

share|improve this answer

I would take a look at Eigenvalue algorithms, which link to a number of different methods. They'll all have different characteristics, and hopefully one will be suitable for your purposes.

share|improve this answer

Apache Mahout is an open-source framework built on map-reduce (i.e. it works for really really big matrices). Note that for a lot of matrix stuff the question isn't "whats the big-o runtime" but rather "how parallelizable is it?" Mahout says they use Lanczos, which can essentially be run in parallel on as many processors as you care to give it.

share|improve this answer

It uses the QR algo. See Wilkinson, J. H. (1965) The Algebraic Eigenvalue Problem. Clarendon Press, Oxford. It does not exploit sparsity.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.