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I have a weighted Graph G={V,E,ETW} where V is the node set, E the edge set and ETW is a set of edge time windows. A edge time window is a 3-Tuple (edge, starttime, endtime) with the meaning that in the intervall [starttime, endtime] the given edge is not available. The problem now is to find a shortest path from a start node to an end node in which it is allowed to wait at the nodes (to use a edge after it´s time window).

Does anybody know a algorithm for this problem? (and in the best case the paper in which the algorithm was published)

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You could have more luck by crossposting to: – Vitalij Zadneprovskij Apr 18 '12 at 20:20
You'll have to have some additional info about the time needed to cross an edge. Or else you could just go through any path at light-speed. – ypercube Apr 19 '12 at 8:46
It is a weighted graph. So the time needed for crossing an edge is the weight of the edge. Sorry, thought that would be clear... – user1093356 Apr 19 '12 at 12:12

1 Answer 1

Assuming the edge values are non-negative, this is still dijkstra's algorithm. You simply have to modify it a little bit.

You have to do the following modification - if the current node v you are looking at has an outgoing edge e, that is not allowed due to the edge's time window, add the time required to get to the end of the time window form the current moment(the moment you reached node v) to the weight of the edge. otherwise the algorithm remains unchanged.

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That is how i do it right now. But since the time windows are changing over time, i have to calculate this each time i do a search and this isn´t fast... – user1093356 Apr 19 '12 at 12:11
No - you only care about the time window once you are at some vertex and want to update the minimum distances for its neighbors. The complexity is exactly the same as regular dijkstra. – Ivaylo Strandjev Apr 19 '12 at 12:23

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