# Subset of vertices

I have a homework problem and i don't know how to solve it. If you could give me an idea i would be very grateful.

This is the problem: "You are given a connected undirected graph which has N vertices and N edges. Each vertex has a cost. You have to find a subset of vertices so that the total cost of the vertices in the subset is minimum, and each edge is incident with at least one vertex from the subset."

P.S: I have tought about a solution for a long time, and the only ideas i came up with are backtracking or an minimum cost matching in bipartite graph but both ideas are too slow for N=100000.

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Try to work out the solution yourself first of all. – Coding Mash Dec 16 '12 at 9:36
"N vertices and N edges" - is that correct? The same number of vertices and edges? That would mean the graph is a tree with one "extra" edge. – AnT Dec 16 '12 at 9:39
Yes "N vertices and N edges" is correct. – user1907615 Dec 16 '12 at 9:40
en.wikipedia.org/wiki/Vertex_cover – AnT Dec 16 '12 at 9:44
Oh, yes. Note that the problem in the general case (not restricted to N edges) is vertex cover problem, a classic NP-Complete problem. However, my gut tells me it is not the case for the simpler problem. – amit Dec 16 '12 at 9:44

This may be solved in linear time using dynamic programming.

A connected graph with N vertices and N edges contains exactly one cycle. Start with detecting this cycle (with the help of depth-first search).

Then remove any edge on this cycle. Two vertices incident to this edge are u and v. After this edge removal, we have a tree. Interpret it as a rooted tree with the root u.

Dynamic programming recurrence for this tree may be defined this way:

• w0[k] = 0 (for leaf nodes)
• w1[k] = vertex_cost (for leaf nodes)
• w0[k] = w1[k+1] (for nodes with one descendant)
• w1[k] = vertex_cost + min(w0[k+1], w1[k+1]) (for nodes with one descendant)
• w0[k] = sum(w1[k+1], x1[k+1], ...) (for branch nodes)
• w1[k] = vertex_cost + sum(min(w0[k+1], w1[k+1]), min(x0[k+1], x1[k+1]), ...)

Here `k` is the node depth (distance from root), w0 is cost of the sub-tree starting from node w when w is not in the "subset", w1 is cost of the sub-tree starting from node w when w is in the "subset".

For each node only two values should be calculated: w0 and w1. But for nodes that were on the cycle we need 4 values: wi,j, where i=0 if node v is not in the "subset", i=1 if node v is in the "subset", j=0 if current node is not in the "subset", j=1 if current node is in the "subset".

Optimal cost of the "subset" is determined as min(u0,1, u1,0, u1,1). To get the "subset" itself, store back-pointers along with each sub-tree cost, and use them to reconstruct the subset.

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Due to the number of edges are strict to the same number of vertices, so it's not the common Vertex cover problem which is NP-Complete. I think there's a polynomial solution here:

1. An N vertices and (N-1) edges graph is a tree. Your graph has N vertices and N edges. Firstly find the awful edge causing a loop and make the graph to a tree. You could use DFS to find the loop (`O(N)`). Removing any one of the edges in the loop would make a possible tree. In extreme condition you would get N possible trees (the raw graph is a circle).

2. Apply a simple dynamic planning algorithm (`O(N)`) to each possible tree (`O(N^2)`), then find the one with the least cost.

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Could not multiple edges be possible candidate for eviction ? I am thinking about a "circle" here for an extreme example. In this case, you would need to apply the DPA to each possible tree... – Matthieu M. Dec 16 '12 at 15:58
@MatthieuM. Oh yes, the choice of the edge to be removed does matter. I have modified my answer. Thank you! – Skyler Dec 16 '12 at 17:33