English

d-QBF with Few Existential Variables Revisited

Computational Complexity 2026-03-11 v1

Abstract

Quantified Boolean Formula (QBF) is a notoriously hard generalization of \textsc{SAT}, especially from the point of view of parameterized complexity, where the problem remains intractable for most standard parameters. A recent work by Eriksson et al.~[IJCAI 24] addressed this by considering the case where the propositional part of the formula is in CNF and we parameterize by the number kk of existentially quantified variables. One of their main results was that this natural (but so far overlooked) parameter does lead to fixed-parameter tractability, if we also bound the maximum arity dd of the clauses of the given CNF. Unfortunately, their algorithm has a \emph{double-exponential} dependence on kk (22k2^{2^k}), even when dd is an absolute constant. Since the work of Eriksson et al.\ only complemented this with a SETH-based lower bound implying that a 2O(k)2^{O(k)} dependence is impossible, this left a large gap as an open question. Our main result in this paper is to close this gap by showing that the double-exponential dependence is optimal, assuming the ETH: even for CNFs of arity 44, QBF with kk existential variables cannot be solved in time 22o(k)ϕO(1)2^{2^{o(k)}}|\phi|^{O(1)}. Complementing this, we also consider the further restricted case of QBF with only two quantifier blocks (\forall\exists-QBF). We show that in this case the situation improves dramatically: for each d3d\ge 3 we show an algorithm with running time kOd(kd1)ϕO(1)k^{O_d(k ^{d-1})}|\phi|^{O(1)} and a lower bound under the ETH showing our algorithm is almost optimal.

Cite

@article{arxiv.2603.08826,
  title  = {d-QBF with Few Existential Variables Revisited},
  author = {Andreas Grigorjew and Michael Lampis},
  journal= {arXiv preprint arXiv:2603.08826},
  year   = {2026}
}
R2 v1 2026-07-01T11:11:01.393Z