So I have triangular mesh approximating a surface.
It's like a graph with the following properties:
- The vertices on the graph border are trivially identifiable. (Number of neighbor vertices > number of containing triangles)
- You can trivially calculate the distance between any two vertices. (Euclidean distance)
- For any vertex v, any vertex that is not a neighbor of v must have a greater distance to v than at least one of v's neighbors. In other words, no non-neighbor vertices may appear within v's neighborhood ring.
For each vertex v, I want to calculate the smallest distance from v to any border vertex.
I can do this by brute force, build a list of all border vertices, compare v's distance to each, and keep the minimum. But this is inefficient.
I believe the most efficient way for each single vertex v is to do have a priority queue where the top element is the closest to v. The queue is initialized with v's neighbors. While the top of the queue is not a border vertex, pop the top and push all the neighbors of the popped vertex.
Let's say vertex v has 6 neighbors, and I calculate the minimum border distance for each of the 6, and I recorded the exact border vertex that gave the minimum for the 6 neighbors. I know that one of these must also give v's minimum border value. I can't really prove this, but I think it's intuitive. If v's surrounded by it's neighbors, the closest border vertex to v must also be the closest border vertex to one of its neighbors.
I want to know if there is a way to use this knowledge to efficiently computing the minimum for each point in the graph. More efficient than a breadth first search from each vertex.