I'm looking at a special subset of SAT optimization problem. For those not familiar with SAT and related topics, here's the related Wikipedia article.
TRUE=(a OR b OR c OR d) AND (a OR f) AND ...
There are no NOTs and it's in conjunctive normal form. This is easily solvable. However I'm trying to minimize the number of true assignments to make the whole statement true. I couldn't find a way to solve that problem.
I came up with the following ways to solve it:
- Convert to a directed graph and search the minimum spanning tree, spanning only a subset of vertices. There's Edmond's algorithm but that gives a MST for the complete graph instead of a subset of the vertices.
- Maybe there's a version of Edmond's algorithm that solves the problem for a subset of the vertices?
- Maybe there's a way to construct a graph out of the original problem that's solvable with other algorithms?
- Use a SAT solver, a LIP solver or exhaustive search. I'm not interested in those solutions as I'm trying to use this problem as lecture material.
Do you have any ideas/comments? Can you come up with other approaches that might work?