# Biconnected Graph

How do you find out whether an undirected graph is Biconnected or not using its depth first search traversal. Is there any other way than traversing the whole graph to find disconnected pieces of the graph.

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You calculate the `low(v)` for every vertex in linear time (i.e. during the execution of the DFS). And there exists a bridge (i.e. an edge whose removal will disconnect the graph ==> not biconnected) iff there's a non-root vertex whose `low` value is itself OR if the root has more than one child.

It's explained here on point 5.2 http://www.cse.ohio-state.edu/~lai/780/graph.pdf

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I have no answer to this, but my gut feeling would suggest that you would have to do the depth first search traversal as the biconnected property of the graph is a property of the whole graph and not any subset of the graph.

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Or may be we can check for the number of nodes reachable from the the current node before and after removal of an articulated node. –  Atishay Jul 31 '11 at 12:21
If the test fails for the current removed node then good => Graph is not biconnected. But need to repeat over all nodes when they pass (or until it fails) => Graph is biconnected –  Brett Walker Jul 31 '11 at 12:24
Agreed (assuming that this is a general graph without any special properties). Proof outline: Let's say that there is an algorithm that doesn't traverse the entire graph - for instance, in a specific graph G, it doesn't look at the edge e1. Then, the algorithm must necessarily give the same answer for the graph G' that you get by removing e1 from G as it did for G. However, the removal of e1 could have been the only edge that made G biconnected, such that G' is not biconnected. Then, the algorithm produces an incorrect answer for either G or G'. –  Aasmund Eldhuset Jul 31 '11 at 12:25
Yeah DFS is conspicuous but simply applying DFS will of `O(n(n+m))` where `n`=number of vertices and `m`=number of edges –  username_4567 Jun 7 '12 at 17:36