# Generate a large random planar graph

What is the most efficient way to generate a large (~ 300k vertices) random planar graph ("random" here means uniformly distributed)?

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Have you looked at Boltzmann sampling? See the paper by Eric Fusy "Uniform random sampling of planar graphs in linear time". The paper and the implementation are available in his homepage which the paper says can generate instances of size 100K in a few seconds.

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Another possibility consists in randomly choosing coordinates and then compute a Delaunay Triangulation, which is a planar graph (and looks nice as well). See http://en.wikipedia.org/wiki/Delaunay_triangulation There are O(n log(n)) algorithms to compute such a triangulation.

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but it will have fixed degree 3? –  andrew cooke Jan 15 '13 at 11:36
It will not have fixed degree 3, but it will be planar. –  Ivo Blöchliger Jan 23 '13 at 18:11
oh, sorry, you're right - i'm thinking of the dual. –  andrew cooke Jan 24 '13 at 0:52

Since I stumbled up on this question - even though it is quite late:

If by uniform you mean uniformly distributed in space, then this is a pretty fast algorithm I developed for generating planar graphs for a spatial ecological/evolutionary simulator. It will generate random planar graphs with an expected degree you specify, of course with some variation around it. You could extend it to pick the expected degree based on a uniform random number if instead you wanted uniform random degrees in your planar graph.

https://github.com/briandconnelly/seeds/blob/master/seeds/plugins/topology/CartesianTopology.py

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It seems this algorithm can generate graphs whose edges cross ? That is not a planar graph. For example, if there are 4 points in a circle of the given radius, they will all connect to each other and the diagonals will cross, making the graph non-planar. –  Sid Datta Nov 29 '12 at 21:10

Without any other requirements, I'd say look up random maze generation. If you want cycles in the graph, remove some walls at random from a simple maze. The intersections in the maze become the nodes in your graph and the removed walls are the edges. That means you can select the number of nodes by choosing the size of the maze.

Mazes are typically done on a 2d grid with at most 4 connections from one point to another, but there is nothing stopping you from doing a maze on hex tiles, or something else.

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