How can I find the minimum number of lines needed to cover all the zeros in a 2 dimensional array?

I'm trying to make a decent implementation of the hungarian algorithm however I'm stuck at how to find the minimum number of lines that cover all the zeros in an array

also I need to know these lines to make some computations later

here is the explanation:

http://www.ams.jhu.edu/~castello/362/Handouts/hungarian.pdf

in step 3 it says

Use as few lines as possible to cover all the zeros in the matrix. There is no easy rule to do this - basically trial and error.

what does trial and error mean in terms of computation? If I have for example an 2d array of 5 rows and 5 columns then

The first row can cover all the zeros, the first and second, the first row and first column, etc etc too many combinations

isn't there something more efficient than this?

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You need to implement bipartite matching algorithm here. You have two partitions in the graph- the vertices in one of them represent the rows and the vertices in the other one represent the columns in the table. There is an edge between rowi and columnj iff there is a 1 in cell (i,j). Then you create maximum bipartite matching. After the last iteration of the bipartite matching algorithm you need to figure out which vertices are connected via a incremental path with the source for your matching. An incremental path is path using only edges with positive capacity. You should have picture like:

``````         row_1                  col_1
/                             \
/ - row_2                col_2 -\
source  - ....     some_edges           \ sink
\                                /
\ - row_n                col_n /
.... /
col_m
``````

After you find the maximum bipartite matching, find which rows and columns are reachable via positive-capacity edges from sink. Now the minimum number of rows and columns you need to scratch is found using the following algorithm - you cross out all the rows that are not reachable from the source and all the columns that are reachable and this is your optimal solution.

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While it will give a set of lines that covers all the zeros, this will not give the smallest number of lines; try the algorithm out with a 3x3 matrix with zeros in the second row and second column. You can cover all the zeros with 2 lines, but this algorithm will tell you to use 3 lines. – gwilkins Apr 9 '12 at 16:08
I had a typo - you need to find the vertices reachable from the source not from the sink. In your example after doing the max matching(let's say it is r_1 -> c_2, r_2 -> c_1) then reachable from the source are r_1, r_3, c_2 and therefor you choose r_2 and c_2 according to what I have explained. This solution is not just speculation - this is the way hungarian algorithm is implemented and I have solved problems with the approach(for instance: acm.timus.ru/problem.aspx?space=1&num=1076) – Ivaylo Strandjev Apr 9 '12 at 19:14
I think I'm misunderstanding what you mean by "reachable from the source." If you have r_1->c_2, r_2->c_1 as your matching then how is r_3 reachable from the source? – gwilkins Apr 9 '12 at 21:04
Oh, never mind, you were talking about reachable in the residual graph. – gwilkins Apr 9 '12 at 22:19

I'm not quite sure why they told you to do trial and error. The Hungarian algorithm, however, does not take exponential time. Take a look at wikipedia, which walks you through an example of how to figure out the minimum number of lines (look at Step 3):

http://en.wikipedia.org/wiki/Hungarian_algorithm#Matrix_interpretation

The article also includes links to implementations, and some online course notes which give more complete (although also more technical) descriptions of the Hungarian algorithm than the one you're using.

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Trial and error means O((n+m)!) complexity.

At most you will only need to pick min(n,m) lines, as selecting all rows or columns will cover all 0s.

I would implement a dynamic programming algorithm to solve this step for large problems.

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