Counting of Teams in First-Order Team Logics
We study descriptive complexity of counting complexity classes in the range from #P to #·NP. A corollary of Fagin's characterization of NP by existential second-order logic is that #P can be logically described as the class of functions counting satisfying assignments to free relation variables in first-order formulae. In this paper we extend this study to classes beyond #P and extensions of first-order logic with team semantics. These team-based logics are closely related to existential second-order logic and its fragments, hence our results also shed light on the complexity of counting for extensions of FO in Tarski's semantics. Our results show that the class #·NP can be logically characterized by independence logic and existential second-order logic, whereas dependence logic and inclusion logic give rise to subclasses of #·NP and #P , respectively. Our main technical result shows that the problem of counting satisfying assignments for monotone Boolean Σ_1-formulae is #·NP-complete as well as complete for the function class generated by dependence logic.
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