# Find path with minimum cost and maximum length given a maximum cost

I'm searching for an algorithm to find a path between two nodes with minimum cost and maximum length given a maximum cost in an undirected weighted complete graph. Weights are non negative.

As I stand now I'm using DFS, and it's pretty slow (high number of nodes and maximum length too). I already discard all the impossible nodes in every iteration of the DFS.

Could someone point me to a known algorithm for better handling of this problem?

To clarify: ideally the algorithm should search for the path of minimum cost, but is allowed to add cost if this means visiting more nodes. It should end when it concludes that it's impossible to reach more than n nodes without crossing the cost limit and it's impossible to reach n nodes with less cost.

Update

Example of a graph. We have to go from A to B. Cost limit is set to 5:

This path (in red) is ok, but the algorithm should continue searching for better solutions

This is better because although the cost is increased to 4, it contains 1 more node

Here the path contains 3 nodes so it's a lot better than before and the cost is an acceptable 5

Finally this solution is even better because the path also contains 3 nodes but with cost 4, with is less than before.

Hope images explain better than text

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Ah, I misread. Why not switch to a BFS (breadth first) and discard paths above the cost threshold? Since you'll (I think) need to visit all paths under the cost threshold to find the "maximum length" anyway. – user2246674 Sep 18 '13 at 0:07
Omg why the downvotes. My question is sincere. Maybe it's difficult to read..? – Inuart Sep 18 '13 at 0:16
This is a slight variation on the longest path problem: en.wikipedia.org/wiki/Longest_path_problem Unfortunately it's known to be NP-hard. – jacobm Sep 18 '13 at 1:08
This problem looks like Knapsack problem. Quote from wiki - Given a set of items, each with a mass and a value, determine the number of each item to include in a collection so that the total weight is less than or equal to a given limit and the total value is as large as possible.Weight limit=cost limit, value=number of visited nodes. Values are all edges (i,j) where both i,j!=source,target. Solution looks like-`min_edge(s,others)+knapsack(all edges besides edges starting on s or t)+min_edge(t,others)`.Boundary case -edge `(source,target)`. – Baurzhan Sep 18 '13 at 11:19
@IvayloStrandjev Suppose you have a polynomial-time algorithm to solve OP's problem. Then pass in an arbitrary graph and a cost budget of infinity (or some other number larger than the max possible path weight, e.g. the sum of all edge weights). Now your poly-time algorithm returns a path of maximal length (and incidentally lowest cost), thereby solving the longest-path problem in poly time -- a contradiction. What am I missing? – jacobm Sep 26 '13 at 22:34

Idea 1:

In my opinion your problem is a variation of the pareto optimal shortest path search problem. Because you refer to 2 different optimality metrics:

1. Longest Path by edge count
2. Shortest Path by edge weight

Of course some side constraints just make the problem more easy to calculate.

You have to implement a multi criteria dijkstra for pareto optimal results. I found two promising paper in english for this problem:

• A multicriteria Pareto-optimal path algorithm
• On a multicriteria shortest path problem

Unfortunately I wasn't able to find the pdf files for those papers and the papers I read before where in german :( Nevertheless this should be your entry point and will lead you to an algorithm to solve your problem nice and smoothly.

Idea 2:

Another way to solve this problem could lie in the calculation of hamilton path, because the longest path in a complete graph is indeed the hamilton path. After calculation of all such path you still have to find the one with the smallest total edge weight cost. This scenario is useful if the length of the path is in every case more relevant than the cost.

Idea 3:

If the cost of the edges is the more important fact you should calculate all paths between those two nodes of a given maximum length and search for the one with the most used edges.

Conclusion:

I think the best results will be obtained by using idea 1. But I didn't know your scenario to well, therefore the other ideas might be an option two.

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Thank you! Do you have the links to the german pdf? – Inuart Sep 20 '13 at 18:37
– Inuart Sep 20 '13 at 18:43
Hm, it seems they translated it :D found those two paper: algo.informatik.tu-darmstadt.de/fileadmin/user_upload/… ; coga.tu-berlin.de/fileadmin/i26/download/AG_DiskAlg/… – Matthias Kricke Sep 21 '13 at 1:05