Singular Value Decomposition - Social Network Analysis

I have a very large network of nodes represented by an adjacency matrix. I would like to reduce the amount of nodes in the network to include the more important nodes. I am aware that SVD can help me achieve this and I have used the ILNumerics library to run the svd() method on the adjacency matrix.

Could someone explain simply to me how the output is mean to help me reduce the dimensions of my network? The SVD process leaves me with a matrix of the same size with descending values diagonally ranging from ~2 to many 0s. How do I know which dimensions to remove which are deemed unimportant?

I am likely doing this process incorrectly overall so any help would be greatly appreciated! Many of the explanations online get very confusing very quickly.

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What exactly is an important node for you? Perhaps an SVD isn't what you want. –  steve Feb 16 '13 at 17:03

Edit: In your example data, your original matrix A has been decomposed as A = outU svdOut outV. The diagonal matrix svdOut constists of the eigenvalues singular values of A whereas the columns/rows of outU and outV are the left- and right-singular vectors of A, respectively. In your example, the singular values are 1.61803, 1.41421, 0.61803 and 0 (two times). The rank of your original matrix is thus given by the number of non-zero singular values (three, in your example). So, you can define a matrix B = outU svdOut* outV where the asterisk indicates that the least significant singular values have been removed. For instance, you could decide that you want to neglect the smallest eigenvalue, thus

``````svdOut* =
| 1.61803  0        0  0  0 |
| 0        1.41421  0  0  0 |
| 0        0        0  0  0 |
| 0        0        0  0  0 |
| 0        0        0  0  0 |
``````

However, after thinking about it again, I think that an SVD of your adjacency matrix will not directly give you what you're looking for. You have to define somehow what an important node actually is in your context.

Edit2 (in response to the comments below): The SVD doesn't give you direct information about your nodes, but about your matrix. The singular vectors form an orthonormal basis that can be used to express your original matrix in a different form. The singular values give you information about how strong the influence of each of these vectors is. Again, Wikipedia might help you getting a feeling how this can be interpreted. Coming back to your original question, I would suppose that a simple SVD is not really what you're looking for.

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Thanks for the quick reply, that helps a lot, my confusion just lies in the output from the process. Here is a link to the matrices produced from the below method on a small 5x5 matrix: pastie.org/6195368 (apologies for the formatting, matrices are quite awkward as text). 'ILRetArray<double> svdOut = ILMath.svd(A, outU, outV);' Based on what is said in the Range, null space and rank section from the Wikipedia article, how does the output from svdOut and the vector matrices help me determine which dimensions to keep and which to discard? –  user1842853 Feb 16 '13 at 15:37
This is really helpful stuff. From my understanding, SVD helps to reduce the dimensionality of data just like my adjacency matrix. An "important" node I expected would be one with a high eigenvalue singular value for that vector. In this format where the singular values simply descend, I do not see how it allows me to compare say svdOut* with my adjacency matrix A to identify which dimensions to remove. Would you have any advice in using SVD for this purpose? My knowledge regarding linear algebra for this purpose is very new so if you think I am going about this the wrong way do say! –  user1842853 Feb 16 '13 at 21:04
Thanks for all your help. After some thought and now that I better understand SVD, I think a process such as spectral clustering or comunity detection will be more along the lines of what I want! –  user1842853 Feb 19 '13 at 12:28