# How to find shortest path in dynamic situation

Some days ago, Someone ask me, If we have some agents in our environment, and they want go from their sources to their destinations, how we can find the total shortest path for all of them such that they shouldn't have conflict during their walk.

The point of problem is all agents simultaneously walking in environment (which can be modeled by undirected weighted graph), and we shouldn't have any collision. I thought about this but I couldn't find optimum path for all of them. But sure there are too many heuristic ideas for this problem.

Assume input is graph G(V,E), m agents which are in: S1, S2,...,Sm nodes of graph in startup and they should go to nodes D1,...Dm at the end. Also may be there is conflict in nodes Si or Di,... but these conflicts are not important they shouldn't have conflict when they are in their internal nodes of their path.

If their path shouldn't have same internal node, It will be kind of `k-disjoint paths` problem which is NPC, but in this case paths can have same nodes, but agent shouldn't be in same node in same time. I don't know I can tell the exact problem statement or not. If is confusing tell me in comments to edit it.

Is there any optimal and fast algorithm (by optimal I mean sum of length of all paths be as smallest as possible, and by fast I mean good polynomial time algorithm).

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Are the agents allowed to stay at a given node? Or do they have to walk in every iteration? (You could model a cost for staying by creating an edge going to the node itself) – Zeta Feb 18 '12 at 16:20
@Zeta, In fact Yes, but I didn't say this because I thought it would be more complicated. But if you have solution for this it would be nice. – Saeed Amiri Feb 18 '12 at 16:29
I don't have a solution (yet), sorry, but this will change the best possible solutions: Example. If waiting is not allowed, then the min sum of all lengths is `100+100+2=202`. If waiting is allowed and costs less than 66 (say 40), then the min sum of all lengths is `40+1+1 + 40+40+1+1 + 2 = 42+82+2 = 126`. – Zeta Feb 18 '12 at 16:40
@Zeta, good sample, but I think algorithm which is solves our current problem, can solve stay-in problem (as you said just adding loop to each node of graph). – Saeed Amiri Feb 18 '12 at 16:43
I can almost guarantee you this is an NP-complete problem. I'd take a look at trying to prove it's NP complete. – ldog Feb 19 '12 at 3:32

Edit: From the book chapter (first link):

There are various approaches to path planning in multi-robot system [sic], however, finding the optimal solution is NP-hard. Hopcraft et al. (1984) simplify the planning problem to the problem of moving rectangles in a rectangular container. They proved the NP-hardness of finding a plan from a given configuration to a goal configuration with the least amount of steps. Hence, all feasible approaches to path planning are a compromise between efficiency and accuracy of the result.

I can't find the original paper by Hopcroft online, but given that quote, I suspect the problem they reduced the navigation task to is similar to Rush Hour, which is PSPACE-complete.

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Your referenced papers talk about different heuristics, which is not hard (I mentioned that in my question), I'd asking about exact algorithm. May be for first OP (who asked me this question), heuristics are nice, but for me exact algorithm or NP-Completeness is interesting. – Saeed Amiri Feb 20 '12 at 12:41
I updated the answer with a quote from the first link; the problem appears to be NP-hard. – DataWraith Feb 20 '12 at 14:53
Right, it'd be NP-hard, not NP-complete, makes sense. – ldog Feb 29 '12 at 19:16

If it's just a matter of getting from point a to point b for each robot, you could just use a search algorithm like A* (A Star) or Best-First.

Give it a simple heuristic like the sum of distances from goal.

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Simpler heuristic is finding shortest path for all of them, then run algorithm, if any robot has collision with others by some priority stop it, and run other robots, this algorithm is fast and terminates soon (is not hard to show this), I'm looking for exact algorithm. – Saeed Amiri Feb 20 '12 at 12:32