Given a weighted undirected graph G(V,E), and a set S subset of V find the Minimum-Cost tree that spans the nodes in S. This problem is known in the literature as the Steiner tree problem.
The problem is NP-complete, which means that there is no known *polynomial* algorithm that will find the exact solution of the problem. However, there are algorithms that solve the Steiner problem in exponential time (O(2^N) or O(2^M)).

The Naive or Shortest Paths algorithm.

```
Find the Shortest path tree from one participant node to the rest of the graph.
Prune the parts of the tree that do not lead to a participant.
```

Complexity O(N^2), CR = O(M).

The Greedy or Nearest Participant First algorithm. (Takahashi, Matsuyama 1980)
Start from a participant.

```
Find the participant that is closest to the current tree.
Join the closest participant to the closest part of the tree.
Repeat until you have connected all nodes.
```

Complexity O(M N^2), CR = O(1), actually CR <= 2.

The Kou, Markowsky and Berman algorithm (KMB 1981).

```
1. Find the complete distance graph G'
(G' has V' = S , and for each pair of nodes (u,v) in VxV there is an edge with weight equal to the weight of the min-cost path between these nodes p_(u,v) in G)
2. Find a minimum spanning tree T' in G'
3. Translate tree T' to the graph G: substitute every edge of T', which is an edge of G' with the corresponding path of G. Let us call T the result of the translation.
4. Remove any possible cycles from T.
```

Complexity O(M N^2), CR = O(1), actually CR <= 2.