**If** you are looking for the shortest path, and **each path is penaltised if using c** then:

Create a modified weightning function:

```
w'(u,v) = w(u,v) + C if v == c
w'(u,v) = w(u,v) otherwise
```

It is easy to see that when running dijkstra's algorithm or Bellman Ford, with `w'`

any path that uses `c`

is penaltized by exactly `C`

, since if `c`

appears in the path - it appears exactly once, so `C`

is added to the total weight [note that `c`

cannot appear more then once in a shortest path], and of course there is no penalty if `c`

is not used in this path.

**EDIT:** I am not sure I understood correctly, if what @SaeedAmiri is mentioning is correct, and **if you want to give the penalty only once [and minimize the total sum of paths to t1,...,tk]** Then you should use a different solution - with a similar idea:

create a weightning function w' such that:

```
w'(u,v) = w(u,v) + C + epsilon if v == c
w'(u,v) = w(u,v) otherwise
```

Note that it is important epsilon is a small size that can be achieved only on w', and is the smallest possible size.

- Run dijkstra or BF on the graph with
`w`

, let's denote the weights as
`W1`

- Run dijkstra or BF in the graph with
`w'`

let's denote the weights as `W2`

- If
`W1[ti] == W2[ti]`

for each ti ∈ { t1, ..., tk } - then you don't need `c`

in the shortest paths, and the total result is `SUM(W1[ti])`

- Otherwise - the result is min { SUM(W1[ti]) + C , SUM(W2[ti])`

The idea behind step 4 is you got two possibilities:

- You can get to all of t1, ... , tk without using c, and it will be cheaper then using a path with it, so you return the sum of W2.
- Or, if ignoring
`c`

- will only be more expansive - thus you use it freely [and return the sum of W1], and add the penalty only once.