English

Natural Proofs Versus Derandomization

Computational Complexity 2015-07-23 v3

Abstract

We study connections between Natural Proofs, derandomization, and the problem of proving "weak" circuit lower bounds such as NEXP⊄TC0{\sf NEXP} \not\subset {\sf TC^0}. Natural Proofs have three properties: they are constructive (an efficient algorithm AA is embedded in them), have largeness (AA accepts a large fraction of strings), and are useful (AA rejects all strings which are truth tables of small circuits). Strong circuit lower bounds that are "naturalizing" would contradict present cryptographic understanding, yet the vast majority of known circuit lower bound proofs are naturalizing. So it is imperative to understand how to pursue un-Natural Proofs. Some heuristic arguments say constructivity should be circumventable: largeness is inherent in many proof techniques, and it is probably our presently weak techniques that yield constructivity. We prove: \bullet Constructivity is unavoidable, even for NEXP\sf NEXP lower bounds. Informally, we prove for all "typical" non-uniform circuit classes C{\cal C}, NEXP⊄C{\sf NEXP} \not\subset {\cal C} if and only if there is a polynomial-time algorithm distinguishing some function from all functions computable by C{\cal C}-circuits. Hence NEXP⊄C{\sf NEXP} \not\subset {\cal C} is equivalent to exhibiting a constructive property useful against C{\cal C}. \bullet There are no P\sf P-natural properties useful against C{\cal C} if and only if randomized exponential time can be "derandomized" using truth tables of circuits from C{\cal C} as random seeds. Therefore the task of proving there are no P\sf P-natural properties is inherently a derandomization problem, weaker than but implied by the existence of strong pseudorandom functions. These characterizations are applied to yield several new results, including improved ACC0{\sf ACC}^0 lower bounds and new unconditional derandomizations.

Keywords

Cite

@article{arxiv.1212.1891,
  title  = {Natural Proofs Versus Derandomization},
  author = {Ryan Williams},
  journal= {arXiv preprint arXiv:1212.1891},
  year   = {2015}
}

Comments

32 pages, major revision for special issue of STOC'13

R2 v1 2026-06-21T22:51:06.013Z