I have a weighted graph, no negative weights, and I would like to find the path from one node to another, trying to minimize the cost for the single step. I don't need to minimize the total cost of the trip (as e.g. Dijkstra does) but the average step-cost. However, I have a constraint: K, the maximum number of nodes in the path.

So for example to go from A to J maybe Dijkstra would find this path (between parenthesis the weight)

```
A (4) D (6) J -> total cost: 10
```

and the algorithm I need, setting K = 10, would find something like

```
A (1) B (2) C (2) D (1) E (3) F (2) G (1) H (3) J -> total cost: 15
```

Is there any well known algorithm for this problem?

Thanks in advance.

Eugenio

Edit as answer to templatetypedef. Some questions:

1) The fact that it can happen to take a cycle multiple times to drive down the average is not good for my problem: maybe I should have mentioned it but I don' want to visit the same node more than once

2) Is it possible to exploit the fact that I don't have negative weights?

3) When you said O(kE) you meant for the whole algorithm or just for the additional part?

Let's take this simple implementation in C where n=number of nodes e=number of edges, d is a vector with the distances, p a vector with the predecessor and a structure edges (u,v,w) memorize the edges in the graphs

```
for (i = 0; i < n; ++i)
d[i] = INFINITY;
d[s] = 0;
for (i = 0; i < n - 1; ++i)
for (j = 0; j < e; ++j)
if (d[edges[j].u] + edges[j].w < d[edges[j].v]){
d[edges[j].v] = d[edges[j].u] + edges[j].w;
p[edges[j].v] = u;
}
```

I'm not sure how I should modify the code according to your answer; to take into consideration the average instead of the total cost should this be enough?

```
for (i = 0; i < n; ++i)
d[i] = INFINITY;
d[s] = 0;
for (i = 0; i < n - 1; ++i)
steps = 0;
for (j = 0; j < e; ++j)
if ( (d[edges[j].u]+ edges[j].w)/(steps+1) < d[edges[j].v]/steps){
d[edges[j].v] = d[edges[j].u] + edges[j].w;
p[edges[j].v] = u;
steps++;
}
```

But anyway I don't know how take into consideration the K limit at the same time...Thanks again in advance for your help.

**Edit**
Since I can afford some errors I'm thinking about this naif solution:

- precompute all the shortest paths and memorize in A
- precompute all the shortest paths on a modified graph, where I cut the edges over a certain weight and memorize them in B

When I need a path, I look in A, e.g. from x to y this is the path x->z->y then for each step I look in B, so for x > z I see if there is a connection in B, if not I keep x > z otherwise I fill the path x > z with the subpath provided by B, that could be something like x->j->h->z; then I do the same for z->y. Each time I will also check if I'm adding a cyclic path.

Maybe I will get some weird paths but it could work in most of the case. If I extend the solution trying with different "cut thresholds" maybe I can also be close to respect the K constrain.