# Find bipartite graph vertex cover with a Very Important Vertex

I know that I can find the minimum vertex cover of a bipartite graph by first finding the maximum matching and then using Konig's Theorem to turn this matching into a vertex cover of the same order.

However, the result obtained is only one of what could be many valid vertex covers. In the following graph, {A,B}, {C,D}, and {B,C} are all valid covers. Applying the Konig method yields the cover {A,B}.

``````(A)=====(C)
/
/
/
(B)=====(D)
``````

How would you check for the existence of a minimum vertex cover that includes a given important vertex, say, vertex D?

My first guess is to flip the graph and find another minimum vertex cover. In the above case, this would yield {C,D}. If neither solution contains the important vertex, it's not part of any minimum cover. However, I haven't thought deeply enough to really prove this to myself.

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I would suggest the following method

1. Find the size of the minimum vertex cover (Let a vertex cover be \$C\$ )
2. Remove the "Very Important Vertex" and all the edges covered by the same (Vertex be \$v\$)
3. Repeat the process and let the new vertex cover be \$C'\$

If \$|C' + V| = |C|\$ then report the minimum vertex cover else report no minimum vertex cover exists with the given vertex.

I guess you have the same answer the proof is also along the same lines.

The new vertex cover cannot be smaller since it would violate the condition that \$C\$ was one of the minimum vertex cover.

Also \$C'\$ is the minimum cover covering the rest of the graph.

If there is atleast one minimum vertex cover including the vertex \$V\$ then the rest of the vertices in that set would cover all the vertices except the ones adjacent to \$V\$, but then it would mean that \$|C'|\$ is not larger than \$|C|-1\$ hence a faliure to do this would imply no minimum vertex cover exists including the VIP edge.

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