If I undestood you right, there are start city, finish-city, and we need to find way with minimum flights to reach destination city from start city. Is that ok?

How I see solution with dynamical programming, lets in `dp[i][j]`

will be stored best time we can get to reach city with number `i`

using only `j`

flights.
At beginning all elements of `dp`

is set to `infinity`

. We will try to update it on each step.
So, algorithm will be smth like this below :

```
dp[0][0] = 0;
priority_queue< pair<int,int> > q;
q.Add( make_pair(0,0) );
/*in q we store pair, where first is time of arrival in city,
and the second is THAT city.*/
while there are element is queue {
x = the first one element ( where time is the smallest )
remove first element from queue
if x.city == destination city
break cycle;
then
for all j
if dp[x.city][j] < x.time + 50
for all flights(from, to) where from==x.city we try to update
if( dp[to][j+1] < dp[x.city][j] + 50 + jurney_duration ) {
dp[to][j+1] = dp[x.city][j] + 50 + jurney_duration ;
q.add( make_pair(dp[x.city][j] + 50 + jurney_duration, to) );
}
}
```

so, to find answers, we only need to find the smallest `x`

where `dp[final_dest][x] != infinity`

, and this `x`

will be the answer.

The efficiency will be `O(n*n*m)`

, because the body of `while-cycle`

we will run only `n`

times ( where `n - number of cities`

), and cycle has two cycles of `n`

and `m`

.
We will run first `for-cycle`

only n times, because the path will use less than `N`

flights - there are no reason to get back to city where you was before.

**EDIT:**
Actually, if we will store information of flights like Adjacency list we can get efficiency even better : O(n*m), because, for example, if city with number `i`

is adjacent to m_{i}, we will get N*m_{0} + N*m_{1} + ... + N*m_{N} = N*(m_{0} + m_{1} + ... + m_{n}) = N*M, because sum of m_{i} th == M. (M stands for the total number of flights).
More details about priority queue

anystart or headway on the problem? – Deestan Jan 15 '13 at 14:13