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I need to compute the eigenvalues and eigenvectors of a big matrix (about 1000*1000 or even more). Matlab works very fast but it does not guaranty accuracy. I need this to be pretty accurate (about 1e-06 error is ok) and within a reasonable time (an hour or two is ok).

My matrix is symmetric and pretty sparse. The exact values are: ones on the diagonal, and on the diagonal below the main diagonal, and on the diagonal above it. Example:

Example Matrix

How can I do this? C++ is the most convenient to me.

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This isn't a programming question so much as a math question. Take a look at: mathoverflow.net/questions/131527/… –  Dang Khoa Oct 29 '13 at 3:32
look into armadillo or eigen and use which best suits your needs –  pyCthon Oct 29 '13 at 3:40
eigen is too slow (or maybe it has configuration options which I'm not aware of?). And it is a programming question because I'm not trying to write it on my own, I want to use something ready. –  Ella Shar Oct 29 '13 at 14:03

3 Answers 3

up vote 1 down vote accepted

Your system is tridiagonal and a (symmetric) Toeplitz matrix. I'd guess that eigen and Matlab's eig have special cases to handle such matrices. There is a closed-form solution for the eigenvalues in this case (reference (PDF)). In Matlab for your matrix this is simply:

n = size(A,1);
k = (1:n).';
v = 1-2*cos(pi*k./(n+1));

This can be further optimized by noting that the eigenvalues are centered about 1 and thus only half of them need to be computed:

n = size(A,1);
if mod(n,2) == 0
    k = (1:n/2).';
    u = 2*cos(pi*k./(n+1));
    v = 1+[u;-u];
    k = (1:(n-1)/2).';
    u = 2*cos(pi*k./(n+1));
    v = 1+[u;0;-u];

I'm not sure how you're going to get more fast and accurate than that (other than performing a refinement step using the eigenvectors and optimization) with simple code. The above should be able to translated to C++ very easily (or use Matlab's codgen to generate C/C++ code that uses this or eig). However, your matrix is still ill-conditioned. Just remember that estimates of accuracy are worst case.

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@horchler Nice analytical answer, +1. However, shouldn't there be a plus sign instead of a minus sign in the expression v = 1-2*cos(pi*k./(n+1))? (according to the article) –  Eitan T Oct 29 '13 at 18:17
@EitanT: The PDF article and Wikipedia use different signs. I'm guessing it's convention as it just changes the order of the eigenvalues (cos is an even function), which only matters if the eigenvectors are needed. –  horchler Oct 29 '13 at 18:35
That sounds right. –  Eitan T Oct 29 '13 at 18:37
Wow that's really great! I wonder why eigen does not do that (I assume so because it's too slow). The PDF has analytical formula for the eigenvectors either. –  Ella Shar Oct 29 '13 at 18:39
@EllaShar Although I hold absolutely no hard feelings for unaccepting my answer, I really don't see a practical difference between eig(A) and an explicit computation. While eig(A) is not as lightning fast (but still rather fast), it manages to produce the same results (and probably uses the same optimizations), and it is the more comprehensible way to do that. Perhaps I'm missing something here, but why resort to re-implementing this when you have it already done for you by a built-in function? –  Eitan T Oct 29 '13 at 18:45

MATLAB does not guarrantee accuracy

I find this claim unreasonable. On what grounds do you say that you can find a (significantly) more accurate implementation than MATLAB's highly refined computational algorithms?

AND... using MATLAB's eig, the following is computed in less than half a second:

%// Generate the input matrix
X = ones(1000);
A = triu(X, -1) + tril(X, 1) - X;

%// Compute eigenvalues
v = eig(A);

It's fast alright!

I need this to be pretty accurate (about 1e-06 error is OK)

Remember that solving eigenvalues accurately is related to finding the roots of the characteristic polynomial. This specific 1000x1000 matrix is very ill-conditioned:

>> cond(A)

ans =

A general rule of thumb is that for a condition number of 10k, you may lose up to k digits of accuracy (on top of what would be lost to the numerical method due to loss of precision from arithmetic method).

So in your case, I'd expect the results to be accurate up to an approximate error of 10-3.

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How does this answer the question? The OP wants to calculate eigenvalues in C++, you showed him that MATLAB is accurate. –  Tyler Jandreau Oct 29 '13 at 11:56
@TylerJandreau The question is about computing eigenvalues accurately, and I infer that had MATLAB been accurate enough, it would suffice. It appears to be impossible to compute eigenvalues numerically for this type of matrix with the requested accuracy, so there's no reason not to be satisfied with MATLAB's answer. Why did you downvote my answer? –  Eitan T Oct 29 '13 at 12:32
Thanks! But why does [V,D]=eig(A) and d=eig(A) give different eigenvalues as an answer and which should I use? Also, I think that the loss of precision to the numerical method can be big, can I set that? Matlab does not say anywhere how accurate the answer will be so I can't really trust it.. –  Ella Shar Oct 29 '13 at 14:49
@EllaShar As mentioned in the answer, you can estimate the accuracy using the condition number. I doubt that you can find a numerical algorithm noticeably better than MATLAB's. The most accurate method would probably be solving this analytically, but it's not always feasible. –  Eitan T Oct 29 '13 at 15:18
Helped a lot! Do you know what's the reason for this difference? –  Ella Shar Oct 29 '13 at 17:09

If you're not opposed to using a third party library, I've had great success using the Armadillo linear algebra libraries.

For the example below, arma is the namespace they like to use, vec is a vector, mat is a matrix.

arma::vec getEigenValues(arma::mat M) {
    return arma::eig_sym(M);

You can also serialize the data directly into MATLAB and vice versa.

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Can you try running this for me? I tried using eigen and it was too slow. Thanks! –  Ella Shar Oct 29 '13 at 14:08
It would be faster to use arma::eig_sym() directly instead of wrapping in into a function. Simply use vec v = eig_sym(M);. Armadillo also has more forms of the eig_sym() function, eg. using the "divide & conquer" algorithm, which is much faster for large matrices. –  mtall Oct 29 '13 at 15:49
Thanks but I do not want to download armadillo for nothing, is it supposed to be faster than the eigen library? It will be best if you can run it and check. What are the cons of the 'dc' algorithm, how inaccurate will it be? And is there something similar in eigen (which I already have)? Thanks again! –  Ella Shar Oct 29 '13 at 15:57

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