I'm working with an adjacency matrix summarizing a bipartate graph, such that rows are one group in the graph and columns are the second group. If a row and column have an edge between them, the value is 1, and if not, it is 0. So, my matrices look at follows
X Y Z A 0 1 0 B 0 0 1 C 1 1 1
I want to quantify distribution of overlap in the rows for 1...S selected rows. So, for example, in the above matrix, the average pairwise overlap would be (0+1/3+1/3)/3 = 2/9, the three-wise overlap (there must be a better word for this) would be 0.
I'm searching for an efficient algorithm to do this for N rows and M columns. So far, nothing that I've come up with can typically outperform just doing all possible row combinations.
I can do something like look at the probability of overlap for each column - so, something like the number of possible combinations in each column of length S that will include at least 1 item divided by the total number of combinations of rows. But I've not figured out a way to use this information to arrive at the proper answer.
I've been thinking there must be some sort of scanning algorithm or otherwise that will address this problem for arbitrary values of S, but lack the training in algorithms to know it off of the top of my head. Any thoughts or references?