# Modifying shortest path to get a min-cost path

If we modify the shortest path problem such that the cost of a path between two vertices is the maximum of the costs of the edges on it, then for any pair of vertices u and v, the path between them that follows a minimum-cost spanning tree is a min-cost path.

How can I prove this approach is true? It makes sense but I am not sure. Does anyone know if this algorithm exists in the literature? Is there a name for it?

-
The shortest-path problem is the min-cost problem, where "cost" is defined as a distance. Are you talking about a problem where there is both distance and some other cost, which is the one you want to minimize? Traffic/Driving is such a problem, where you may have two costs: distance and time. A shorter but busier street has a lower distance cost but a higher time cost, and you can minimize for one or the other, or some weighted combination of the two. (Not entirely relevant to constructing a proof) – Stephen P Nov 1 '11 at 22:50

You can use some basic facts of MST (that are usually discussed in the correctness proof for Prim's & Kruskal's algorithms). The one that matters now is that

Lema 1:

Given a graph cut (a partitioning of the vertices into two disjoint sets) the edge in the MST connecting the two parts will be the cheapest of the edges connecting the two parts.

(The proof is straighfoward, if there were a cheaper edge we would be able to easily contruct a cheaper spanning tree)

We can now prove that the paths in a MST are all min-cost paths if you consider the maximum-cost:

Take any two vertices `s` and `t` in `G` and the path `p` that connects them in a MST of G. Now let `uv` be the most expensive edge in this path. We can describe a graph cut over this edge, with one partition with the vertices on the `u` side of the MST and the other partition with the vertices on the `v` side. We know that any path connecting `s` and `t` must pass this cut, therefore we can determine that the cost of any path from `s` to `t` must be at least the cost of the cheapest edge on this cut. But Lemma 1 tells us that uv is the cheapest edge on this cut so `p` must be a min-cost path.

-
There is always a minimum spanning tree (there are a finite number of possible trees - a subset of them must be minimal) and there is always a path between any two nodes in any spanning tree (because the tree spans all the vertices). The proof then basically says that those paths in the MSTs are also min-cost paths if the cost is determined by maximum. – hugomg Nov 2 '11 at 21:47

The approach you mentioned is discussed in detail in literatures that discuss the relationship between Prim's algorithm and Dijkstra's algorithm, as usual wikipedia is a good place to start your research:

The process that underlies Dijkstra's algorithm is similar to the greedy process used in Prim's algorithm. Prim's purpose is to find a minimum spanning tree that connects all nodes in the graph; Dijkstra is concerned with only the lowest cost path beteen two nodes.

-