# Proof that Dominating Set is NP-Complete

here is the question. I am wondering if there is a clear and efficient proof:

Vertex Cover: input undirected G, integer k > 0. Is there a subset of vertices S, |S|<=k, that covers all edges?

Dominating Set: input undirected G, integer k > 0. Is there a subset of vertices S, |S|<= k, that dominates all vertices?

A vertex covers it's incident edges and dominates it's neighbors and itself.

Assuming that VC is NPC, prove that DS is NPC.

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This might help en.wikipedia.org/wiki/… –  Mahesh Velaga Mar 15 '11 at 15:28
The dominating set problem that is NP-Complete is minimum-size-dominating-set, not just if a graph has a dominating set or not. For proving NPC its a yes or no problem, so using all the vertices in a connected graph is a dominating set by nature. Which is not NPC. –  Paul Apr 9 '11 at 20:51

There is a quite nice and well known reduction:

Given an instance (G,k) of Vertex Cover build an instance of Dominating Set (H,k), where for H you take G and for every edge (u,v) add an additional vertex x connected to u and v.

First realize that a Vertex Cover of G is a Dominating Set of H (it's clearly a DS of G and the new vertices are also dominated). So if G has a VC smaller k, then H has a DS smaller k.

For the converse, consider D, a Dominating Set of H.

Notice that if one of the new vertices is in D, we can replace it with one of it's two neighbors and still get an Dominating Set: it's only neighbors are are the two original vertices and they are also connected - everything x can possible dominate is also dominated by u or v.

So we can assume that D contains only vertices from G. Now for every edge (u,v) in G the new vertex x is dominated by D, so either u or v is in D. But this means D is a Vertex Cover of G.

And there we have it: G has a Vertex Cover smaller k if and only if H has a Dominating Set smaller k.

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I think that second problem is not NP. Let's try the following algorithm.

1. Get the original Graph
2. Run any algorithm which checks if a graph is connected or not.
3. mark all used edges of step 2
4. if the graph is connected then return the set of marked edges otherwise there is no such a set.

If I understood correctly your problem then it is not NP Complete.

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by textbook CLRS,it should be NPC, :( –  SecureFish Mar 15 '11 at 17:13
Which problem is NPC in CLRS? –  Luixv Mar 15 '11 at 17:16
See en.wikipedia.org/wiki/Connectivity_(graph_theory) for a greedy connectivity algorithm. –  Luixv Mar 15 '11 at 17:19
vertex cover is NPC in CLRS, chapter 34 –  SecureFish Mar 15 '11 at 17:51
@Luixv, after more thought, I think maybe you are right because I once resolve the problem "find minimum size dominating set using greedy algorithm" confused –  SecureFish Mar 15 '11 at 22:23