I'm trying to take a dense graph of points such as this, and turn it into a graph of connected convex polygons. The polygons should be as large and as simple as possible while staying connected. The resultant graph will be used for pathfinding. Can anyone point me in the right direction?

  • I can't imagine this wasn't asked before. Please search SO first, this will probably give you some ideas. Or you can formulate your question better by explaining why the found solutions don't fit your requirements. – user180326 Jan 20 '11 at 21:35
  • Looks suspiciously like a starcraft map... – Keith Randall Jan 20 '11 at 21:54
  • It is exactly a StarCraft map. It's a top-down view of their navigation mesh, setup for use as a 2D collision map. I can do local collision avoidance through this using potential fields, but I need a real pathfinding solution to avoid local optima. Essentially I need convex polygons so that I can use the midpoints of the shared edges to pathfind through. Triangles would work as well, but result in more points. – Anthony Jan 20 '11 at 21:59

It is very annoying that I can't post links. Makes it hard to be a lurker & only occasional participator.

I ended up using the following techniques:

First, create a distance transform. I used the algorithm described here [can't link], resulting in an image like this [can't link]. Then, create a watershed transform of the DT to partition it into areas. This needs some work, but currently looks like this [can't link] Then, use the midpoints of the polylines connecting each pair of areas, to create a waypoint graph.


The watershed partitioning isn't perfect yet, note the aliasing causing banding but I end up with 181 areas and 281 waypoints for this 128x128 map.


This is not what you asked for, but here are some other ideas for solving this 2D path planning problem:

  • Use A*. This yields the shortest collision free path. Performance might be OK, even with no simplification of the bitmap.

  • Use a sampling-based roadmap. This is another discretized representation than polygons. Since your search space is small, you can traverse the entire bitmap to verify that every point can be connected to the roadmap. If a compact roadmap is important (but short paths are not), the visibility roadmap technique can be used.

Since you have to deal with graph representation and graph searching anyway, these techniques seem much easier than polygon extraction. I dug up some SO questions for that problem:

When the space has been mapped by polygons (possibly using a tool), it can be split into convex polygons or some other representation that can be searched. This is also discussed by LaValle:

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