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There is a custom implementation of KSPA which needs to be re-written. The current implementation uses a modified Dijkstra's algorithm whose pseudocode is roughly explained below. It is commonly known as KSPA using edge-deletion strategy i think so. (i am a novice in graph-theory).

Step:-1.  Calculate the shortest path between any given pair of nodes using the Dijkstra algorithm. k = 0 here.
Step:-2.   Set k = 1
Step:-3.   Extract all the edges from all the ‘k-1’ shortest path trees. Add the same to a linked list Edge_List.
Step:-4.  Create a combination of ‘k’ edges from Edge_List to be deleted at once such that each edge belongs to a different SPT (Shortest Path Tree). This can be done by inspecting the ‘k’ value for each edge of the combination considered. The ‘k’ value has to be different for each of the edge of the chosen combination.
Step:-5.   Delete the combination of edges chosen in the above step temporarily from the graph in memory.
Step:-6.   Re-run Dijkstra for the same pair of nodes as in Step:-1.
Step:-7.   Add the resulting path into a temporary list of paths. Paths_List.
Step:-8.   Restore the deleted edges back into the graph.
Step:-9.   Go to Step:-4 to get another combination of edges for deletion until all unique combinations are exhausted. This is nothing but choosing ‘r’ edges at a time among ‘n’ edges => nCr.
Step:-10. The ‘k+1’ th shortest path is = Minimum(Paths_List).
Step:-11. k = k + 1 Go to Step:-3, until k < N.
Step:-12. STOP

As i understand the algorithm, to get kth shortest path, ‘k-1’ SPTs are to be found between each source-destination pair and ‘k-1’ edges each from one SPT are to be deleted simultaneously for every combination. Clearly this algorithm has combinatorial complexity and clogs the server on large graphs. People suggested me Eppstein's algorithm (http://www.ics.uci.edu/~eppstein/pubs/Epp-SJC-98.pdf). But this white paper cites a 'digraph' and I did not see a mention that it works only for digraphs. I just wanted to ask folks here if anyone has used this algorithm on an undirected graph?

If not, are there good algorithms (in terms of time-complexity) to implement KSPA on an undirected graph?

Thanks in advance,

share|improve this question
    
Undirected graphs are basically digraphs with every edge doubled, right? There shouldn't be a problem with the algorithm you linked to. –  v3. May 11 '09 at 20:51
    
Yes. But somebody who worked on the algo told me that it uses a special distribution technique that may not work on undirected graphs. So, i thought of checking out if somebody had indeed applied it to an undirected graph. But i will check out. The implementation is underway... –  Abhay May 12 '09 at 3:15
    
The Eppstein algorithm works on acyclic graphs only. Though an undirected graph is a directed graph with edges in both directions, the distriution technique fails because of cycles. –  Abhay Jun 22 '09 at 6:36

1 Answer 1

up vote 5 down vote accepted

Time complexity: O(K*(E*log(K)+V*log(V)))

Memory complexity of O(K*V) (+O(E) for storing the input).

We perform a modified Djikstra as follows:

  • For each node, instead of keeping the best currently-known cost of route from start-node. We keep the best K routes from start node
  • When updating a nodes' neighbours, we don't check if it improves the best currently known path (like Djikstra does), we check if it improves the worst of the K' best currently known path.
  • After we already processed the first of a nodes' K best routes, we don't need to find K best routes, but only have K-1 remaining, and after another one K-2. That's what I called K'.
  • For each node we will keep two priority queues for the K' best currently known path-lengths.
    • In one priority queue the shortest path is on top. We use this priority queue to determine which of the K' is best and will be used in the regular Djikstra's priority queues as the node's representative.
    • In the other priority queue the longest path is on top. We use this one to compare candidate paths to the worst of the K' paths.
share|improve this answer
    
Hmm, definitely better than what i could think of here. For large graphs the saving seems to be significant. Could you make this answer complete by refactoring the common logic and stating the two optimizations in a single answer. We'l see if anyone has better ideas; else +25 from me already! –  Abhay Aug 25 '09 at 11:06
    
@Abhay: The optimization for the previous algorithm isn't relevant for this one, so I'm not sure what you mean by "stating the two optimizations in a single answer".. –  yairchu Aug 25 '09 at 11:52
    
Just state them separately as optimization approach-1 and 2. The only reason i suggest this is to have a single comprehensive answer rather than have to read both of them. –  Abhay Aug 25 '09 at 12:32
    
@Abhay: I guess the best thing is to delete my previous answer. This algorithm beats the previous one, so not much use in describing the worse algorithm –  yairchu Aug 25 '09 at 15:31

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