You can rapidly compute a low-rank approximation based on SVD, using the
[U,S,V] = svds(A,r); %# only first r singular values are computed
eigs to compute a subset of the singular values - it will be especially fast for large, sparse matrices. See the documentation; you can set tolerance and maximum number of iterations or choose to calculate small singular values instead of large.
eigs could be faster than
eig for dense matrices, but then I did some benchmarking. They are only faster for large matrices when sufficiently few values are requested:
n k svds svd eigs eig comment
10 1 4.6941e-03 8.8188e-05 2.8311e-03 7.1699e-05 random matrices
100 1 8.9591e-03 7.5931e-03 4.7711e-03 1.5964e-02 (uniform dist)
1000 1 3.6464e-01 1.8024e+00 3.9019e-02 3.4057e+00
2 1.7184e+00 1.8302e+00 2.3294e+00 3.4592e+00
3 1.4665e+00 1.8429e+00 2.3943e+00 3.5064e+00
4 1.5920e+00 1.8208e+00 1.0100e+00 3.4189e+00
4000 1 7.5255e+00 8.5846e+01 5.1709e-01 1.2287e+02
2 3.8368e+01 8.6006e+01 1.0966e+02 1.2243e+02
3 4.1639e+01 8.4399e+01 6.0963e+01 1.2297e+02
4 4.2523e+01 8.4211e+01 8.3964e+01 1.2251e+02
10 1 4.4501e-03 1.2028e-04 2.8001e-03 8.0108e-05 random pos. def.
100 1 3.0927e-02 7.1261e-03 1.7364e-02 1.2342e-02 (uniform dist)
1000 1 3.3647e+00 1.8096e+00 4.5111e-01 3.2644e+00
2 4.2939e+00 1.8379e+00 2.6098e+00 3.4405e+00
3 4.3249e+00 1.8245e+00 6.9845e-01 3.7606e+00
4 3.1962e+00 1.9782e+00 7.8082e-01 3.3626e+00
4000 1 1.4272e+02 8.5545e+01 1.1795e+01 1.4214e+02
2 1.7096e+02 8.4905e+01 1.0411e+02 1.4322e+02
3 2.7061e+02 8.5045e+01 4.6654e+01 1.4283e+02
4 1.7161e+02 8.5358e+01 3.0066e+01 1.4262e+02
n square matrices,
k singular/eigen values and runtimes in seconds. I used Steve Eddins'
timeit file exchange function for benchmarking, which tries to account for overhead and runtime variations.
eigs are faster if you want a few values from a very large matrix. It also depends on the properties of the matrix in question (
edit svds should give you some idea why).