# Shortest path in “two-graph” with limited number of changes

Let's say we have two directed and positive-weighted graphs on one set of vertices (first graph represents for example rail-roads and the second one - bus lanes; vertices are bus stops or rail-road stations or both). We need to find the shortest path from A to B, but we can't change the type of transport more than N times.

I was trying to modify the Dijkstra's algorithm, but it's working only on a few "not-so-mean-and-complicated" graphs and I think I need to try something different.

How to best represent that "two-graph" and how to manage the limited amount of changes in traversing the graph? Is there a possibility to adapt Dijkstra's algorithm in this one? Any ideas and clues will be helpful.

Edit: Well I forgot one thing (I think it's quite important): N = 0,1,2,...; we can come up with any graph representation we like and of course there can exist maximum 4 edges between every two nodes (1 bus lane and 1 railroad in one direction, and 1 bus lane and 1 railroad in the second direction).

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"digraph" also is a letter pair like "ae", retagged. – MSalters Jan 3 '14 at 12:29
How are the two graphs related? Are they two graphs? – Electro Jan 3 '14 at 12:30
I don't see any problems with modifying Dijkstra. You simply add a branch-and-bound component to Dijkstra, removing those paths that exceed the number of allowable changes from the list of paths permanently. – arne Jan 3 '14 at 12:30
Or just not add such neighbors in the successor function in the first place. – Electro Jan 3 '14 at 12:31
@arne unless I am missing something there is no obvious naive way to modify Dijkstra that works in reasonable time complexity. If you really have such a modification do you mind describing it briefly, in more detail? – Andrey Jan 3 '14 at 15:00

I don't think it is the best way, but you can create Nodes as follow:

``````Node:(NodeId, GraphId, correspondenceLeftCount)
``````

(the total number of nodes will be `number_of_initial_nodes * number_of_graphs * number_of_correspondences_allowed`)

So:

For edge where `GraphId` doesn't change, `correspondenceLeftCount` doesn't change neither. You add a new Edge for correspondance:

`(NodeId, Graph1, correspondenceLeftCount)` -> (NodeId, Graph2, correspondenceLeftCount - 1)`

And for the request A->B: Your start point are `(A, graph1, maxCorrespondenceLeftCount)` and `(A, graph2, maxCorrespondenceLeftCount)`.
And your end points are `(B, graph1, 0)`, ... , `(B, graph1, maxCorrespondenceLeftCount)`, `(B, graph2, 0)`, ... , `(B, graph2, maxCorrespondenceLeftCount)`.

So you may to have to adapt your Dijkstra implementation for the end condition, and to be able to insert more than one start point.

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