Is there a straightforward algorithm for generating a random undirected biconnected graph (given a number of vertices as input)? I understand how to determine if a given graph is biconnected, but I'm struggling to generate one programatically.
You can do a very simple probabilistic approach:
1. Create an empty graph with n nodes 2. For each pair of nodes: -Flip a fifty-fifty-coin to decide whether to put an edge in there or not
Hence, in the end to make sure your graph really is bi-connected you just run the regular procedure which you already know.
For the (very unlikely) scenario where the check returns "graph is not bi-connected", just repeat the procedure.
The really intriguing question is "why will I get a biconnected graph w.h.p.?". I will omit the formal proof which is a bit tedious and by how you are asking, I assume you just want something that works and you don't care too much about why it works. If I'm wrong and you actually need a proof I suggest you either ask on mathoverflow or you drop me a comment - maybe I'll try to make it formal if I find the time.
For the moment, just to give you an intuition for why this will work, consider the following approach of how a proof could go:
Note that the number of graphs which is not bi-connected is equal to the number of graphs with at least one articulation-vertex.
Let us roughly compute the probability of a single vertex of being an articulation point: The idea is that if
vis an articulation vertex then it splits the
nvertices into two disjoint sets of size
n-ksuch that there is no edge between those sets. Now intuitively it should be more or less clear that
k*(n-k)coin flips which all have to result in "no-edge" is not very probable (basically
(1/2)^(k*(n-k))). We still have to multiply by
n(since for each node) but this will still not make a significant difference, and as you might see now it is very unlikely for graph with large enough 'n' to not being bi-connected.
(What's still missing is to consider "for each possible partitioning", i.e. for the different choices of
k, and then maybe be more careful since it would actually be
k, rather than
k because the vertex under consideration is not part of any of the 2 sets... I'm just saying these things to illustrate the kind of details one would still have to worry about for a formal proof...)
A simple way to is to create a random maximal planar (tri-connected) graph:
- Start with 3 vertices connected in a cycle which forms 2 triangular faces (interior and exterior of the cycle).
- To add each subsequent vertex pick a random face and trisect it with a vertex and 3 edges.
You could stop here - since the graph is tri-connected it is also bi-connected.
However, if you want to remove edges and ensure that you still have a biconnected graph then only remove edges where both incident vertices are degree 3-or-more and test each edge prior to removal using Hopcroft & Tarjan's Depth-First Search Algorithm to find Biconnected Components to check for biconnectivity without that edge.
Note - this will always create a planar graph.