## Problem

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.

## Possible solutions

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.

## Question

Do you have any ideas/comments? Can you come up with other approaches that might work?