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There's a bipartite graph B(E, V1, V2) such that e = (v1, v2) for e ∈ E, v1 ∈ V1, v2 ∈ V2. Edges in B are directional.

I'd like to make a graph G(E ∪ E', V2 ∪ V2) such that the graph G is strongly-connected component, with minimum sizeof(E'). (sizeof(A) is the number of elements in the set A) E' doesn't have to be V1 -> V2.

For an example, with V1 = {1, 2, 3} and V2 = {a, b}, there's a bipartite graph B(E, V1, V2) with E = {(1, a), (2, a), (2, b), (3, b)}. Then E' = {(a, 3), (a, 1), (b, 2)} makes all vertices in G(E ∪ E', V2 ∪ V2) strongly-connected.(whenever I choose vertex pair v1 and v2, there exists a path from v1 to v2)

Can someone give me some idea? Or is there a well-known algorithm about this?

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Must the resulting graph be bipartite? –  jpalecek Jun 28 '12 at 10:45
A problem with non-bipartite graph can be reduced into the problemwith bipartite graph so it doesn't matter –  aqjune Aug 12 '12 at 15:42

1 Answer 1

A theorem by Eswaran and Tarjan says that an acyclic digraph with r sources (i.e., vertices without incoming edges) and s sinks (i.e., vertices without outgoing edges) can be made strongly connected by adding max(r, s) edges (see e.g. here). Thus, you need to add max(sizeof(A), sizeof(B)) edges. The book also explains how to find a solution (a simple system of matching up vertices).

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