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.

I'm trying to write a program that gets a matrix A of any size, and SVD decomposes it:

A=USV'

Where A is the matrix the user enters, U is an orthogonal matrix composes of the eigenvectors of AA', S is a diagonal matrix of the singular values, and V is an orthogonal matrix of the eigenvectors of A'A.

Problem is: the matlab function eig sometimes returns the wrong eigenvectors.

This is my code:

function [U,S,V]=badsvd(A)
W=A*A';
[U,S]=eig(W);
max=0;
for i=1:size(W,1) %%sort
    for j=i:size(W,1)
        if(S(j,j)>max)
            max=S(j,j);
            temp_index=j;
        end
    end
    max=0;
    temp=S(temp_index,temp_index);
    S(temp_index,temp_index)=S(i,i);
    S(i,i)=temp;
    temp=U(:,temp_index);
    U(:,temp_index)=U(:,i);
    U(:,i)=temp;
end
W=A'*A;
[V,s]=eig(W);
max=0;
for i=1:size(W,1) %%sort
    for j=i:size(W,1)
        if(s(j,j)>max)
            max=s(j,j);
            temp_index=j;
        end
    end
    max=0;
    temp=s(temp_index,temp_index);
    s(temp_index,temp_index)=s(i,i);
    s(i,i)=temp;
    temp=V(:,temp_index);
    V(:,temp_index)=V(:,i);
    V(:,i)=temp;
end
s=sqrt(s);
end

My code returns the correct s matrix, and also "nearly" correct U and V matrices. but some of the columns are multiplied by -1. obviously if t is an eigenvector, then also -t is an eigenvector, but with the signs inverted (for some of the columns, not all) i don't get A=USV'.

Is there any way to fix this?

example: for the matrix A=[1,2;3,4] my function returns:

U=[0.4046,-0.9145;0.9145,0.4046]

and the built-in Matlab svd function returns:

u=[-0.4046,-0.9145;-0.9145,0.4046]
share|improve this question
    
I got it wrong. Sorry. I'm deleting my answer –  Luis Mendo Aug 9 '13 at 17:55
    

1 Answer 1

up vote 8 down vote accepted

Note that eigenvectors are not unique. Multiplying by any constant, including -1 (which simply changes the sign), gives another valid eigenvector. This is clear given the definition of an eigenvector:

A·v = λ·v

MATLAB chooses to normalize the eigenvectors to have a norm of 1.0, the sign is arbitrary:

For eig(A), the eigenvectors are scaled so that the norm of each is 1.0. For eig(A,B), eig(A,'nobalance'), and eig(A,B,flag), the eigenvectors are not normalized

Now as you know, SVD and eigendecomposition are related. Below is some code to test this fact. Note that svd and eig return results in different order (one sorted high to low, the other in reverse):

% some random matrix
A = rand(5);

% singular value decomposition
[U,S,V] = svd(A);

% eigenvectors of A'*A are the same as the right-singular vectors
[V2,D2] = eig(A'*A);
[D2,ord] = sort(diag(D2), 'descend');
S2 = diag(sqrt(D2));
V2 = V2(:,ord);

% eigenvectors of A*A' are the same as the left-singular vectors
[U2,D2] = eig(A*A');
[D2,ord] = sort(diag(D2), 'descend');
S3 = diag(sqrt(D2));
U2 = U2(:,ord);

% check results
A
U*S*V'
U2*S2*V2'

I get very similar results (ignoring minor floating-point errors):

>> norm(A - U*S*V')
ans =
   7.5771e-16
>> norm(A - U2*S2*V2')
ans =
   3.2841e-14

EDIT:

To get consistent results, one usually adopts a convention of requiring that the first element in each eigenvector be of a certain sign. That way if you get an eigenvector that does not follow this rule, you multiply it by -1 to flip the sign...

share|improve this answer
    
The norm will not change a lot, also in my code. But the difference between U2*S2*V2 and A is too big to ignore. I know that if t is an eigenvector then -t is also an eigenvector, but i need the specific sign for it to be exactly A. How do i fix that in my code? –  Oria Gruber Aug 9 '13 at 18:10
    
@OriaGruber: see my edit about the sign convention. I'm not sure what convention MATLAB follows with regards to the sign.. –  Amro Aug 9 '13 at 18:15
    
Another thing: eig and svd return the eigenvalues (and corresponding eigenvectors) and principal values in different orders. I'm not sure about eig, but svd conveniently return them "in decreasing order." –  horchler Aug 9 '13 at 18:26
    
@horchler: yes, svd are definitely sorted in decreasing order (according to the docs), while eig appears to be sorted in ascending order (the docs doesnt explicitly mention this), so fliplr might also work. Either way I am explicitly sorting the eigenvalues and corresponding eigenvectors of eig in my code above. Here is a related question: stackoverflow.com/a/3293855/97160 –  Amro Aug 9 '13 at 18:31
    
@OriaGruber: regarding the sign convention, you might be interested in these submissions: eigenshuffle, eigenshuffle2. Here are some related discussions as well: mathworks.com/matlabcentral/newsreader/view_thread/77590, mathworks.com/matlabcentral/newsreader/view_thread/306717. You'll find many more with a quick search... –  Amro Aug 9 '13 at 18:33

Your Answer

 
discard

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

Not the answer you're looking for? Browse other questions tagged or ask your own question.