I am given a directed acyclic graph G = (V,E), which can be assumed to be topologically ordered (if needed). The edges in G have two types of costs - a nominal cost w(e) and a spiked cost p(e).
The goal is to find the shortest path from a node s to a node t which minimizes the following cost: sum_e (w(e)) + max_e (p(e)), where the sum and maximum are taken over all edges in the path.
Standard dynamic programming methods show that this problem is solvable in O(E^2) time. Is there a more efficient way to solve it? Ideally, an O(E*polylog(E,V)) algorithm would be nice.
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This is the O(E^2) solution I found using dynamic programming.
First, order all costs p(e) in an ascending order. This takes O(Elog(E)) time.
Second, define the state space consisting of states (x,i) where x is a node in the graph and i is in 1,2,...,|E|. It represents "We are in node x, and the highest edge weight p(e) we have seen so far is the i-th largest".
Let V(x,i) be the length of the shortest path (in the classical sense) from s to x, where the highest p(e) encountered was the i-th largest. It's easy to compute V(x,i) given V(y,j) for any predecessor y of x and any j in 1,...,|E| (there are two cases to consider - the edge y->x is has the j-th largest weight, or it does not).
At every state (x,i), this computation finds the minimum of about deg(x) values. Thus the complexity is O(|E| * sum_(x\in V) deg(x)) = O(|E|^2), as each node is associated to |E| different states.