I have a ~3000x3000 covariance-alike matrix on which I compute the eigenvalue-eigenvector decomposition (it's a OpenCV matrix, and I use cv::eigen() to get the job done).

However, I actually only need the, say, first 30 eigenvalues/vectors, I don't care about the rest. Theoretically, this should allow to speed up the computation significantly, right? I mean, that means it has 2970 eigenvectors less that need to be computed.

Which C++ library will allow me to do that? Please note that OpenCV's eigen() method does have the parameters for that, but the documentation says they are ignored, and I tested it myself, they are indeed ignored :D

UPDATE: I managed to do it with ARPACK. I managed to compile it for windows, and even to use it. The results look promising, an illustration can be seen in this toy example:

#include "ardsmat.h"
#include "ardssym.h"
int     n = 3;           // Dimension of the problem.
    double* EigVal = NULL;  // Eigenvalues.
    double* EigVec = NULL; // Eigenvectors stored sequentially.

    int lowerHalfElementCount = (n*n+n) / 2;
    //whole matrix:
    2  3  8
    3  9  -7
    8  -7 19
    double* lower = new double[lowerHalfElementCount]; //lower half of the matrix
    //to be filled with COLUMN major (i.e. one column after the other, always starting from the diagonal element)
    lower[0] = 2; lower[1] = 3; lower[2] = 8; lower[3] = 9; lower[4] = -7; lower[5] = 19;
    //params: dimensions (i.e. width/height), array with values of the lower or upper half (sequentially, row major), 'L' or 'U' for upper or lower
    ARdsSymMatrix<double> mat(n, lower, 'L');

    // Defining the eigenvalue problem.
    int noOfEigVecValues = 2;
    //int maxIterations = 50000000;
    //ARluSymStdEig<double> dprob(noOfEigVecValues, mat, "LM", 0, 0.5, maxIterations);
    ARluSymStdEig<double> dprob(noOfEigVecValues, mat);

    // Finding eigenvalues and eigenvectors.

    int converged = dprob.EigenValVectors(EigVec, EigVal);
    for (int eigValIdx = 0; eigValIdx < noOfEigVecValues; eigValIdx++) {
        std::cout << "Eigenvalue: " << EigVal[eigValIdx] << "\nEigenvector: ";

        for (int i = 0; i < n; i++) {
            int idx = n*eigValIdx+i;
            std::cout << EigVec[idx] << " ";
        std::cout << std::endl;

The results are:

9.4298, 24.24059

for the eigenvalues, and

-0.523207, -0.83446237, -0.17299346
0.273269, -0.356554, 0.893416

for the 2 eigenvectors respectively (one eigenvector per row) The code fails to find 3 eigenvectors (it can only find 1-2 in this case, an assert() makes sure of that, but well, that's not a problem).

  • 2
    By the 'first 30 eigenvalues/vectors', do you mean the eigenvalues with largest moduli, largest real parts, or something else? After googling, it looks like SLEPc might have what you are looking for. – James Jun 16 '12 at 15:29
  • 2
    I'd use ARPACK for this. You'll get your 30 eigenvectors instantly. – David Heffernan Jun 16 '12 at 15:41
  • 5
    "Theoretically, this should allow to speed up the computation significantly, right?" That depends on the algorithm that's used, it's at least not trivially true. But yes, there are algorithms that allow fast calculation of only eigenvectors in some eigenvalue range. Arnoldi/Lanczos being the most prominent, so ARPACK is kind of canonical. That it's so old doesn't mean it's bad, it's certainly great if you really want performance; but I agree that these Fortran libraries are rather horrible to use. – leftaroundabout Jun 16 '12 at 16:30
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    Ah, I think you mean that eigen doesn't do what you want rather than ARPACK. Sorry. Anyway, all I can say is that I was formerly using a direct algo that could take many minutes and often consume all system memory to produce any results at all. With ARPACK I can get the first few hundred eigen pairs in a second or two without needed a lot of system resources. – David Heffernan Jun 16 '12 at 16:36
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    @NameZero912, if you have the answer and nobody has provided it, make an answer yourself and accept it. It will get this question off the list of unanswered questions. :) – Yakk - Adam Nevraumont Dec 24 '12 at 4:10

In this article, Simon Funk shows a simple, effective way to estimate a singular value decomposition (SVD) of a very large matrix. In his case, the matrix is sparse, with dimensions: 17,000 x 500,000.

Now, looking here, describes how eigenvalue decomposition closely related to SVD. Thus, you might benefit from considering a modified version of Simon Funk's approach, especially if your matrix is sparse. Furthermore, your matrix is not only square but also symmetric (if that is what you mean by covariance-like), which likely leads to additional simplification.

... Just an idea :)

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