I'd like to compute a low-rank approximation to a matrix which is optimal under the Frobenius norm. The trivial way to do this is to compute the SVD decomposition of the matrix, set the smallest singular values to zero and compute the low-rank matrix by multiplying the factors. Is there a simple and more efficient way to do this in MATLAB?

  • What do you mean by "simple", "efficient"?
    – Oli
    Jan 9, 2012 at 16:37
  • by simple I mean that a reference to a 30 page research paper whose implementation requires writing 500 lines of code is not the answer I'm looking for. By efficient I mean that I'd like to improve the runtime over the trivial approach. Jan 9, 2012 at 16:41
  • 1
    I doubt that there is a trivial answer.. After all, if it were, why would Mathworks "forget" about it? Jan 9, 2012 at 16:46
  • By any chance, is your matrix "symmetric definite positive"?
    – Oli
    Jan 9, 2012 at 17:23
  • 1
    Can you describe why the SVD method you outlined is not good enough? Are you working with very large matrices or many matrices?
    – Kavka
    Jan 9, 2012 at 19:55

2 Answers 2


If your matrix is sparse, use svds.

Assuming it is not sparse but it's large, you can use random projections for fast low-rank approximation.

From a tutorial:

An optimal low rank approximation can be easily computed using the SVD of A in O(mn^2 ). Using random projections we show how to achieve an ”almost optimal” low rank pproximation in O(mn log(n)).

Matlab code from a blog:

% preparing the problem
% trying to find a low approximation to A, an m x n matrix
% where m >= n
m = 1000;
n = 900;
%// first let's produce example A
A = rand(m,n);
% beginning of the algorithm designed to find alow rank matrix of A
% let us define that rank to be equal to k
k = 50;
% R is an m x l matrix drawn from a N(0,1)
% where l is such that l > c log(n)/ epsilon^2
l = 100;
% timing the random algorithm
trand =cputime;
R = randn(m,l);
B = 1/sqrt(l)* R' * A;
Ak = A*b(:,1:k)*b(:,1:k)';
trandend = cputime-trand;
% now timing the normal SVD algorithm
tsvd = cputime;
% doing it the normal SVD way
[U,S,V] = svd(A,0);
Aksvd= U(1:m,1:k)*S(1:k,1:k)*V(1:n,1:k)';
tsvdend = cputime -tsvd;

Also, remember the econ parameter of svd.

  • Is this an exact method or an approximation? Is it numerically backward-stable? Jan 10, 2012 at 7:21
  • I've done some benchmarking and the function svds can be (significantly) faster than svd for dense matrices as well, for a low enough rank. If you'll include that in the answer, I'll accept it. Jan 10, 2012 at 8:05
  • You can post and accept your own answer regarding svds for a dense matrix. Note that Matlab documentation states:"d = eigs(A,k) is not a substitute for d = eig(full(A)); d = sort(d); d = d(end-k+1:end); but is most appropriate for large sparse matrices. If the problem fits into memory, it may be quicker to use eig(full(A))." eigs is called by svds.
    – cyborg
    Jan 10, 2012 at 8:44

You can rapidly compute a low-rank approximation based on SVD, using the svds function.

[U,S,V] = svds(A,r); %# only first r singular values are computed

svds uses 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.

I thought svds and eigs could be faster than svd and 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

With size-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.

svds and 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).

  • Interesting to hear that svds works faster than svd for some dense matrices when searching for the first singular values. Is it because 500x100 is not large enough?
    – cyborg
    Jan 11, 2012 at 9:39
  • The larger the matrix, the faster svds and eigs can be. I had to eat my words a little - see my latest edit above. Jan 14, 2012 at 5:40

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