I have a can of liquid that is partically polluted. I want to select out clean regions with a minimized total surface area. I watched the density of pollution in the container and selected manually.
The process soon becomes boring. Therefore I want an algorithm to automate it. First trial:
slice the whole volume into elements
assign a number representing pollution for each volume elements (ve), called 'count'
construct a graph G, vertices being ve, and edges connecting neighboring ve's
assign edge weights using absolute difference between the counts of its two vertices
get the minimum spanning tree of G, called H
with H, while there exists a vertex V with count larger than C:
6.1 travel through from V with beneath first search order
6.2 if we encounter a vertex W whose count is smaller than 0.7*C then delete the edge (W, W's parent)
6.3 keep the subtree not containing V as new H, goto step 6
output final H
Problem is, the algorithm regard the surface area poorly. I could not find an easy way to calculate surface area of outputed H.
Is there an extension foreseeable to extend the algorithm to keep surface area into consideration?
a. I am thinking of getting the subgraph of G with the same vertices as H in step 7, and then deleting recursively the vertices with small degrees (outliers in the geometrical shape)
b. convex hull peeling?
OR, am I on the right path? Is there a different and much better algorithm for my problem?
Looking forward to your advice. Thanks.
PS: My algorithm is implemented in python-igraph.