# Update minimum spanning tree with modification of edge

A graph (positive weight edges) with a MST If some edge, e is modified to a new value, what is the best way to update the MST without completely remaking it. I think this can be done in linear time. Also, it seems that I would need a different algorithm based on whether 1) e is already a part of the MST and 2) whether the new edge, e is larger or smaller than the original

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There are 4 cases:

1. Edge is in MST and you decreasing value of edge:
Current MST is still MST

2. Edge is not in MST and you decreasing value of edge:
Add this edge to the MST. Now you've got exactly 1 cycle.
Based on cycle property in MST you need to find and remove edge with highest value that is on that cycle. You can do it using dfs or bfs. Complexity O(n).

3. Edge is in MST and you increasing its value of edge:
Remove this edge from MST. Now you have 2 connected components that should be connected. You can calculate both components in O(n) (bfs or dfs). You need to find edge with smallest value that connects these components. Iterate over edges in ascending order by their value. Complexity O(n).

4. Edge is not in MST and you increasing its value of edge:
Current MST is still MST

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CASE 3. IS NOT O(N). to iterate over edges in ascending order. we need to sort them. there are O(n^2) edges. even if we are taking sorted edges that we calculated during making mst, it would still have to go through these (all may in worst case) edges. –  Ashish Negi Apr 11 '13 at 6:53
It could be O(n). 1. Remove the edge whose weight was increased and keep track of the two nodes that were connected by this edge 2. Run bfs/dfs starting with these two nodes which are now in 2 disjoint sets. You should somehow hash the vertices visited so you can access them in O(1). I would create two hashtables, one for each disjoint set. 3. Loop through all the edges in E-E' where G=(V,E) and MST=(V,E'). If any edge contains 1 node from each hashtable, it connects the two disjoint sets. Maintain a min variable to determine which edge connected the two sets and had the lowest weight. O(E) –  Olshansk Apr 26 '13 at 22:49
Olshansk, O(E) is O(n^2), as Ashish pointed out. As far as I can tell, removal requires O(n^2), because for each edge (assume sorted already in a list), we need to find the smallest edge which connects the two spanning trees. This can take up to O(n^2) if the only edge that connects them is also the edge with the highest value. –  Aurum510 Feb 26 at 17:16