# Finding 'bottleneck edges' in a graph

Given a random unidirected graph, I must find 'bottleneck edges' to get from one vertex to another.

What I call 'bottleneck edges' (there must be a better name for that!) -- suppose I have the following unidirected graph:

``````    A
/ | \
B--C--D
|     |
E--F--G
\ | /
H
``````

To get from A to H independently of the chosen path edges BE and DG must always be traversed, therefore making a 'bottleneck'.

Is there a polynomial time algorithm for this?

edit: yes, the name is 'minimum cut' for what I meant witch 'bottleneck edges'.

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Would HE HF and HG also be considered bottlenecks? Do you have a different definition? –  Aryabhatta Apr 27 '11 at 21:19
This sounds very much like the Travelling salesman problem except replace distances with computational time. Specifically related to your question is the Bottleneck traveling salesman problem –  osknows Apr 27 '11 at 21:24
You mean edge BE or DG must always be traversed? –  sawa Apr 28 '11 at 12:19
sawa: Yes, saying BE or DG could be more correct –  Noros Apr 28 '11 at 20:23

Sounds like you need minimum cut, the minimal set of edges removing which will separate your graph into two pieces.

http://en.wikipedia.org/wiki/Minimum_cut

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This might well be it. And use Max flow = min-cut :-) –  Aryabhatta Apr 27 '11 at 21:23
Thanks, yes, minimum cut it is! :) –  Noros Apr 28 '11 at 20:05

What you are looking for is a cut. Given a graph, a cut is a set of edges that partitions the vertices into two disjoint subsets.

Assuming you are trying to get the smallest cut possible, this is the classic min-cut problem. Here is a pseudo code version of the Ford-fulkerson algorithm, reworked for your case (undirected, unweighted graphs). I'm pretty sure it should work, but I am not sure I'm being the most efficient / idiomatic here.

``````reorganize your graph into a directed graph,
with two directed edges (u->v, v->u) for each original edge (u-v)

while there is a path P from A to H:
(hint: use breadth first search to find paths - long story here)
//augment the path P:
for each edge (u->v) in P:
remove (u->v) from the graph and add (v->u) to it