# Which algorithm can I use to find the next to shortest path in a graph?

I want to find the next shortest path between 2 vertices in a graph and the path has a positive cost.The next shortest path is allowed to share edges of the shortest path .Which algorithm can I use?

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i.e. not the shortest path itself, but the shortest path excluding the actual shortest path? – Joe Green Feb 11 '11 at 17:08
I assume you are asking about shortest path between two fixed vertices. What type of graph? DAG with positive edges? – ThomasMcLeod Feb 11 '11 at 17:19
Presumably you mean the "shortest path between two given Nodes on the graph" and not "the shortest path visiting all the Nodes of the graph", because that is a LITTLE bit harder. – GrahamS Feb 11 '11 at 17:21
Can the second shortest path share common edges with the shortest path, or only common nodes? – IVlad Feb 11 '11 at 17:43

I doubt this is optimal in terms of running time but:

1. Use Dijkstra's algorithm on graph G to get path P
2. For all edges E in path P:
3. -- If G - E is not connected, continue for next edge (go to 2)
4. -- Use Dijkstra's algorithm on G - E to find path X_i
5. -- If length of current X_i is shorter than all other X_i, save it
6. The X_i at the end of the for loop is the second shortest path

The second-shortest path can't go through all edges in P, but it could go through all but one of them, potentially. I assume by "second-shortest" that you don't use edges more than once, otherwise the second-shortest path could contain P.

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+1 This sounds right and it's faster than my answer – dfb Feb 11 '11 at 17:24
Couldn't G-E result in two, disjoint graphs? I think your algorithm will work in a completely connected graph, but what happens if there is only one edge which connects to a node to the rest of the graph? – Davidann Feb 11 '11 at 17:27
OP does not say wha type of graph this is. If it's undirected and/or cyclic, second shortest path could contain shortest path. – ThomasMcLeod Feb 11 '11 at 17:27
Note that this only works if the next shortest path is allowed to share common edges with the shortest path. – IVlad Feb 11 '11 at 17:48
I think there is bug in the algorithm: you can have a second shortest path that contains the shortest path even without using the same edge twice. Consider the graph: V={s,m,t}, E={s-->m, m-->t, m-->m}, and weight function that assigns 1 to all edges. The shortest path between s and t is: s-->m-->t and the second shortest path is: s-->m-->m-->t. Your algorithm won't catch it. – Guy Jun 12 '11 at 16:13

Use the K-shortest path algorithm, where k=2 for you, some sample reference:

Finding the k shortest paths. D. Eppstein. 35th IEEE Symp. Foundations of Comp. Sci., Santa Fe, 1994, pp. 154-165. Tech. Rep. 94-26, ICS, UCI, 1994. SIAM J. Computing 28(2):652-673, 1998.

http://www.ics.uci.edu/~eppstein/pubs/Epp-TR-94-26.pdf

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Use the shortest path algorithm to find the shortest path, P.

You then can view this problem as a constraint satisfaction problem (where the constraint is "the shortest path which is not P") and, use a backtracking algorithm to find the shortest path which is not the shortest path you already found.

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I'm not sure I understand how this works. If you use a backtracking algorithm, you potentially are evaluating a much large portion of the graph - how does the initial path help you ; there may be cases when the 2nd shortest path is not a subpath of the first. – dfb Feb 11 '11 at 17:19
The initial, shortest path is part of the constraints: you want the shortest path which is has not already been taken. – Davidann Feb 11 '11 at 17:24
You've constrained a single path amongst a possibility of an exponential number of paths - I don't see how this is different from a brute force approach or, if we're looking for a disjoint path, different from the answers below. – dfb Feb 11 '11 at 18:02
You're right, I've turned this into a search problem (whose time complexity could be exponential in the number of edges); but that does not make my solution wrong. Improvements could be made by propagating the constraints, or something else. This solution may not be different than the others, but I think I posted a solution first. – Davidann Feb 11 '11 at 18:19
Sorry - if that came across as 'you're answer is wrong', it wasn't meant to, my quibble was over its generality. My thought was that very general algorithms such as backtracking and other 'enumeration' type algorithms (all paths) can be applied to most graph related problems but with worst case exponential time when there are specific algorithms that do much better. These can be conceptualized in a similar way - Dijsktra's algorithm can be thought of using the triangle inequality, for example. – dfb Feb 16 '11 at 18:37

One way is to use Floyd-Warshall's algorithm to find all pairs shortest path and then testing all intermediate edges is a sure - but perhaps not optimal way - to solve this. Here's a great explanation http://hatemabdelghani.wordpress.com/2009/07/04/second-shortest-path/

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This answer assumes you are looking for the edge-disjoint second shortest path, which means the second shortest path cannot share any common edges with the shortest path.

Recall that the maximum flow in a network between two nodes `A` and `B` gives you the number of edge-disjoint paths between those two nodes. Also recall that algorithms such as Edmonds-Karp work by sending flow over a shortest path at each step.

So this problem only has a solution if the max flow between your two nodes is > 1, where each edge has a capacity of 1. If it does, find two augmenting paths as described in the Edmonds-Karp algorithm, and the second one is your second shortest.

See this problem and this solution to it (The description is in Chinese. I can't translate it, and babelfish can't really do it either, but won't admit it. The code is easy to follow though) for an example.

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This is assuming you can reuse edges and nodes:

A straightfoward solution is do make an extension of the Djikstra Algorithm.

• Instead of storing for each node the smallest cost and its respective parent, store the two smallest costs (and their respective parents).

• For the priority queue, intead of storing nodes, store (node, i) pairs, so you know wether to use the 1st or 2nd path during propagation.

• Take care during the propagation phases to keep the multiple path values correctly updated.

(I might be missing some important details but the basic idea is here...)

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When you prefer a practical solution to an academic one, here is one.

I solved this by setting a penalty to the shortest path edges and running the search again.

E.g. shortest path has length 1000, penalty is 10%, so I search for a 2nd shortest path with 1000<=length<=1100.

In the worst case I find the previous shortest path.
In the best case I find a disjunct path with the same length.
In most cases I find a path sharing some locally optimal subpaths.

Increasing the penalty forces the algorithm to find alternative routes, while decreasing makes it sharing tolerant.

When I find the 2nd shortest path, I have to subtract the sum of penalties on shared edges from the computed length to get the real length.

For k-th shortest path I set the penalty to all edges used in previous k-1 shortest paths.

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