I think this is essentially Larsmans' answer made a bit more algorithmic:

Nodes of the graph are the obstacle vertices. Each internal vertex actually represents two nodes: the concave and the convex side.

- Push the start node onto the priority queue with a Euclidean heuristic distance.
- Pop the top node from the priority queue.
- Do a line intersection test from the node to the goal(possibly using ray-tracing data-structure techniques for speedup). If it fails,
- Consider a ray from the current node to every other vertex. If there are no intersections between the current node the vertex under consideration, and the vertex is convex from the perspective of the current node, add the vertex to the priority queue, sorted using the accumulated distance in the current node plus the distance from the current node to the vertex plus the heuristic distance.
- Return to 2.

You have to do extra pre-processing work if there are things like 'T' junctions in the obstacles and I wouldn't be surprised to discover that it breaks in a number of cases. You might be able to make things faster by only considering the vertices of the connected component that lies between the current node and the goal.

So in your example, after first attempting **A,B**, you'd push **A,8**, **A,5**, **A,1**, **A,11**, and **A,2**. The first nodes of consideration would be **A,8**, **A,1**, and **A,5**, but they can't get out and the nodes they can reach are already pushed on the queue with shorter accumulated distance. **A,2** and **A,11** will be considered and things will go from there.

can'tgo. Is there any other cost besides the distance? E.g., is the terrain sloped, and it's harder to go uphill? – JCooper Jul 22 '11 at 16:03