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I'm writing an algorithm for finding the second min cost spanning tree. my idea was as follows:

  1. Use kruskals to find lowest MST.
  2. Delete the lowest cost edge of the MST.
  3. Run kruskals again on the entire graph.
  4. return the new MST.

My question is: Will this work? Is there a better way perhaps to do this?

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well i have a another idea......but i am not pretty sure that works.....add the minimum weight among previous avoiding edges to the newest Mst. if my idea is wrong.anyone can give any example? –  user941355 Sep 12 '11 at 20:57
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7 Answers

You can do it in O(V2). First compute the MST using Prim's algorithm (can be done in O(V2)).

Compute max[u, v] = the cost of the maximum cost edge on the (unique) path from u to v in the MST. Can be done in O(V2).

Find an edge (u, v) that's NOT part of the MST that minimizes abs(max[u, v] - weight(u, v)). Can be done in O(E) == O(V2).

Return MST' = MST - {the edge that has max[u, v] weight} + {(u, v)}, which will give you the second best MST.

Here's a link to pseudocode and more detailed explanations.

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Consider this case:

------100----
|           |
A--1--B--3--C
      |     |
      |     3
      |     |
      2-----D

The MST consists of A-B-D-C (cost 6). The second min cost is A-B-C-D (cost 7). If you delete the lowest cost edge, you will get A-C-B-D (cost 105) instead.

So your idea will not work. I have no better idea though...

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Also if the min edge happens to be connecting a pendant vertex, deleting it and computing the MST again will not even get you an MST. –  csprajeeth Sep 11 '13 at 17:20
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You can do this -- try removing the edges of the MST, one at a time from the graph, and run the MST, taking the min from it. So this is similar to yours, except for iterative:

  1. Use Kruskals to find MST.
  2. For each edge in MST:
    1. Remove edge from graph
    2. Calculate MST' on MST
    3. Keep track of smallest MST
    4. Add edge back to graph
  3. Return the smallest MST.
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Thank you. I have drawn out some examples and this idea appears to work for all my examples. :) –  Evil Apr 22 '10 at 18:10
    
This works - but it is an extensive search that will take O(N^2*logN) compared to the O(NlogN) complexity of Kruskal. –  Anders Abel Apr 22 '10 at 18:14
    
It's just a way of saying that the MST and the MST_2 is different by exactly one edge -- there are better algorithms than this, but it is a way to think about it. There's also O(VE) algorithm -- Kruskal is actually O(V log E), making the above O(V^2 log E). –  Larry Apr 22 '10 at 18:29
    
Kruskal's is actually O(E log E) because you are sorting the edges - ignoring disjoint sets, which is basically constant if done right. This algorithm is therefore O(VE log E) since you have O(V) edges in the MST. So the worst case is O(V^3 log V). (log E = log V^2 = 2log V = O(log V)). –  IVlad Apr 22 '10 at 20:24
    
You're right. Generally for graph problems, I leave in the E's, since log E and log V is a constant difference, but it might point to different algorithms. I've been getting downvotes for giving too much away in my answer and I got downvotes for not giving away answer, but I do know this is not optimal! –  Larry Apr 22 '10 at 20:31
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This is similar to Larry's answer.

After finding MST,

For each new_edge =not a edge in MST

  1. Add new_edge to MST.
  2. Find the cycle that is formed.
  3. Find the edge with maximum weight in cycle that is not the non-MST edge you added.
  4. Record the weight increase as W_Inc = w(new_edge) - w(max_weight_edge_in_cycle).
  5. If W_Inc < Min_W_Inc_Seen_So_Far Then
    • Min_W_Inc_Seen_So_Far = W_Inc
    • edge_to_add = new_edge
    • edge_to_remove = max_weight_edge_in_cycle

Solution from following link.
http://web.mit.edu/6.263/www/quiz1-f05-sol.pdf

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Here is an algorithm which compute the 2nd minimum spanning tree in O(n^2)

  1. First find out the mimimum spanning tree (T). It will take O(n^2) without using heap.
  2. Repeat for every edge e in T. =O(n^2)
  3. Lets say current tree edge is e. This tree edge will divide the tree into two trees, lets say T1 and T-T1. e=(u,v) where u is in T1 and v is in T-T1. =O(n^2)

    Repeat for every vertex v in T-T1. =O(n^2)

    Select edge e'=(u,v) for all v in T-T1 and e' is in G (original graph) and it is minimum

  4. Calculate the weight of newly formed tree. Lets say W=weight(T)-weight(e)+weight(e')

  5. Select the one T1 which has a minimum weight
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Your approach will not work, as it might be the case that min. weight edge in the MST is a bridge (only one edge connecting 2 parts of graph) so deleting this edge from the set will result in 2 new MST as compared to one MST.

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slight edit to your algo.

    Use kruskals to find lowest MST.
    for all edges i of MST
        Delete edge i of the MST.
        Run kruskals again on the entire graph.
        loss=cost new edge introduced - cost of edge i
    return MST for which loss is minimum
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