English

Finitely unstable theories and computational complexity

Logic 2014-10-21 v1 Computational Complexity Logic in Computer Science

Abstract

The complexity class NPNP can be logically characterized both through existential second order logic SOSO\exists, as proven by Fagin, and through simulating a Turing machine via the satisfiability problem of propositional logic SAT, as proven by Cook. Both theorems involve encoding a Turing machine by a formula in the corresponding logic and stating that a model of this formula exists if and only if the Turing machine halts, i.e. the formula is satisfiable iff the Turing machine accepts its input. Trakhtenbrot's theorem does the same in first order logic FOFO. Such different orders of encoding are possible because the set of all possible configurations of any Turing machine up to any given finite time instant can be defined by a finite set of propositional variables, or is locally represented by a model of fixed finite size. In the current paper, we first encode such time-limited computations of a deterministic Turing machine (DTM) in first order logic. We then take a closer look at DTMs that solve SAT. When the length of the input string to such a DTM that contains effectively encoded instances of SAT is parameterized by the natural number MM, we proceed to show that the corresponding FOFO theory SATMSAT_M has a lower bound on the size of its models that grows almost exponentially with MM. This lower bound on model size also translates into a lower bound on the deterministic time complexity of SAT.

Keywords

Cite

@article{arxiv.1410.4925,
  title  = {Finitely unstable theories and computational complexity},
  author = {Tuomo Kauranne},
  journal= {arXiv preprint arXiv:1410.4925},
  year   = {2014}
}
R2 v1 2026-06-22T06:28:03.747Z