# Storing a large but low-rank matrix efficiently

I know there are packages in R to store sparse matrices efficiently. Is there also a way to store a low-rank matrix efficiently? For example:

``````A <- matrix(rnorm(1e6), nrow=1e5, ncol=1e1)
B <- A %*% t(A)
``````

Now, `B` is too large to store in memory, but it is low in rank. Is there any way to construct and store `B` in an efficient way, such that some basic read methods (`rowSums`, `colSums`, etc) are performed on the fly, in order to trade for cpu or memory?

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Interesting question- what applications would it have? (Where do low rank matrices generally appear?) –  David Robinson Mar 14 '13 at 2:09
@DavidRobinson: Those matrices are used, for instance, as approximations of large dense matrices (too large to compute, or even to store), in some optimization algorithms. –  Vincent Zoonekynd Mar 14 '13 at 9:33
If you are willing to approximate B, could you use a low-dimensional approximation, e.g. use a SVD and keep the first n dimensions of the SVD? Not sure this is quite what you want, but might be worth considering. –  Kevin Wright Mar 15 '13 at 14:47
While it doesn't answer your question, the following seems somewhat relevant: mathoverflow.net/questions/92328/low-rank-matrix-factorization –  NPE Mar 15 '13 at 15:00
Yes, I agree with above comment. Factor it, and it will become sparse. –  10flow Mar 19 '13 at 17:27

Your question is already the answer: To store such a low rank matrix efficiently, you make a data structure containing both factors. If matrix-vector multiplication is required, it can be done from right to left using matrix-vector products of the factors.

One application of this strategy and data structure can be found in implementations of limited-memory Broyden or BFGS quasi-Newton methods.

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Here's another approach, although I miss the experience to know how efficient this would be for large matrices:

If the rank is low, it means the matrix contains many irrelevant lines, which are linear combinations of others. If the matrix represents a linear system of equations, one could design an algorithm, which successively removes those lines.

To check if a line is irrelevant, check if the rank of the matrix without that line is still the same. For computing the matrix rank, see this and that answer.

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That basically sounds like a very expensive way of factoring :-) –  Jeroen Mar 29 '13 at 22:52
Sorry, but a terribly poor idea that works only for a simple case, with replicated rows. In fact, it is TRIVIAL to generate a matrix of rank 1, that has NO replicate rows or columns. Thus pick random row vectors U and V, then U'*V has rank 1. –  user85109 Sep 6 '13 at 14:23