Consider the following dense matrix:
1 2 3
4 5 6
7 8 9
If I store it in a contiguous block:
1 2 3 4 5 6 7 8 9
I can directly access the elements of the matrix given the row and column number with some basic arithmetic.
Now consider this sparse matrix:
1 0 0
0 0 2
0 3 0
In order to efficiently store this matrix, I discard non-zero elements so it now becomes
1 2 3
But this is obviously not enough information to do operations like a matrix vector multiplication! So we need to add additional information to extract the elements from the matrix.
But you can see that irrespective of the storage method used, we need to
- Do extra work to access the elements
- Store more information to keep the structure of the matrix
So as you can see, the benefits of storage arises only if there are enough zeros in the matrix to compensate for the extra information we store to preserve the structure of the matrix. For example, in the Yale format, we only save on memory when the number of non-zero (NNZ) values is less than
(m(n − 1) − 1) / 2 where
m = number of rows and
n = number of columns.