# Construct a minimum spanning tree covering a specific subset of the vertices

I have an undirected, positive-edge-weight graph (V,E) for which I want a minimum spanning tree covering a subset k of vertices V.

I'm not limiting the size of the spanning tree to k vertices; rather I know exactly which *k* vertices must be included in the MST.

Starting from the entire MST I could pare down edges/nodes until I get the smallest MST that contains all k.

I can use Prim's algorithm to get the entire MST, and start deleting edges/nodes while the MST of subset k is not destroyed; alternatively I can use Floyd-Warshall to get all-pairs shortest paths and somehow union the paths. Are there better ways to approach this?

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Not sure I understand, but can't you just run your favorite MST algo on `(k,E)`? –  Mat Oct 7 '11 at 9:24
Uhm, how is this different from removing the unwanted vertices and running Prim (or Kruskal) on the remaining ones? –  Savino Sguera Oct 7 '11 at 9:25
i'd be thinking 'subgraphs' there –  sehe Oct 7 '11 at 9:30
If I remove the unwanted vertices I might also lose intermediate edges that connect `k` vertices that are far apart. For example if I have: `k--o--o--o--k` where `o` represents an unnecessary vertex and `k` represents one I need, if I deleted the middle `o` there would be no way to construct the MST between my `k` vertices. –  ash Oct 7 '11 at 9:32
So you interested in the minimum spanning tree, which doesn't necessarily span all vertices, only the vertices in k? –  aioobe Oct 7 '11 at 9:35

I suggest you do the following:

1. Create a copy of the graph.
2. While there are edges left in the graph, which are not in k
1. Remove an arbitrary vertex v which is not in k
2. For all pairs (a,b) of neighbors of v
1. Add an edge (a, b) with weight Weight((a,v)) + Weight((v,b))
3. Run Prim's algorithm on the resulting graph.

The intuition is that we "short-circuit" the nodes which are connected through a vertex not in k. The cost of going via any such node, v is the cost of going from the first node to v plus the cost of going from v to the second node.

The MST in the resulting graph, will be the minimum spanning tree covering the vertices in k in the original graph.

Note that if you have many nodes in V but not in k, then you may have quite a blow-up in the number of edges. Lot's of edges will presumably be redundant however, so there's probably room for some optimizations...

Related problem:

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Foiled. You're right about the K-minimum spanning tree. Thanks for the link, I'll take a look at the approximations. –  ash Oct 7 '11 at 9:42
Hmm.. I removed that part completely. K-minimum spanning tree was for k arbitrary number of nodes. (I suppose you have k fixed nodes, which actually makes the problem easier. See my updated answer.) –  aioobe Oct 7 '11 at 9:47
This algorithm is faulty: Let k1,..,kN denote nodes from the set k and v1,...,vM denote nodes not in k. Let d(x,y) denote the weight of the edge between nodes x and y (if existing). Take the graph d(k1,v1)=1; d(v1,k2)=2; d(v1,k3)=3 and d(k1,k3)=4. The MST that uses all nodes from k is {(k1,v1);(v1,k2);(v1,k3)}. Shrinking this graph we get d'(k1,k2)=3;d'(k1,k3)=4 and d'(k2,k3)=5. MST here is {(k1,k2);(k1,k3)} which includes (k1,k3) which is not present in the optimal case. Hence the algorithm is not producing the optimal spanning tree. –  LiKao Oct 8 '11 at 13:57

Run Prim's algorithm on the restricted graph (k, E') where E' = {(x, y) ∈ V : xk and yk}). Constructing that graph takes O(|E|).

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