Will Dijkstra's Algorithm work if the digraph has only one negative weight edge and does not contain negative weight cycles?
Not necessarily. In this earlier answer, I gave an example of a graph with no negative cycles and one negative edge where Dijkstra's algorithm doesn't produce the correct answer. Therefore, Dijkstra's algorithm doesn't always work in this case.
Hope this helps!
Since Dijkstra's algorithm is greedy, it won't work with negative weights. U need some other algorithm like Bellman-Ford Algorithm for this purpose.
But, if you still want to use Dijkstra's Algo, there is a known way. In this method, you need to reassign costs, so that all become positive.
Here it is:
Suppose there is an edge from u to v. And the cost of the edge is cost(u,v).
new_cost(u,v) = cost(u,v) + d(u) - d(v)
This is guaranteed to be positive since,
d(v) < d(u) + cost(u,v)
Now, we can apply Dijkstra's algorithm normally, only difference being, in the cost of the new path, which will be (say the path is in between s' and t')
= original cost of the same path + d(s') - d(t')
You can not apply Dijkstra's algorithm directly to a graph with a negative edge as some of the other answers have correctly noted.
There is a way to reweigh the graph edges given that there are no negative cycles in the original graph. It's the same technique used in Johnson's algorithm where first you run one instance of Bellman-Ford's algorithm to get the weights
h(v) for each vertex
v. Then you modify each edge
w(u,v) + h(u) − h(v) which is guaranteed to be positive so you end up with a new graph with only positive edges on which you can run Dijkstra's algorithm.
Section XV. from the Coursera Algorithms class explains it much better than me.
The only issue with applying that technique for the single source shortest path problem is that reweighting with Bellman-Ford takes
O(mn) time which is slower than Dijkstra's
O(m log(n)). So you are better off just running Bellman-Ford for your original graph.
Dijkstra's algorithm will work with a single negative edge as long as you start from the node which has that negative edge as an outgoing edge.
By starting with the smallest valued edge of the graph, you can no longer decrease the total cost by considering other edge weights (Which is how Dijkstra's algorithm works)