English

A composition theorem for randomized query complexity via max conflict complexity

Computational Complexity 2018-11-28 v1

Abstract

Let Rϵ()R_\epsilon(\cdot) stand for the bounded-error randomized query complexity with error ϵ>0\epsilon > 0. For any relation f{0,1}n×Sf \subseteq \{0,1\}^n \times S and partial Boolean function g{0,1}m×{0,1}g \subseteq \{0,1\}^m \times \{0,1\}, we show that R1/3(fgn)Ω(R4/9(f)R1/3(g))R_{1/3}(f \circ g^n) \in \Omega(R_{4/9}(f) \cdot \sqrt{R_{1/3}(g)}), where fgn({0,1}m)n×Sf \circ g^n \subseteq (\{0,1\}^m)^n \times S is the composition of ff and gg. We give an example of a relation ff and partial Boolean function gg for which this lower bound is tight. We prove our composition theorem by introducing a new complexity measure, the max conflict complexity χˉ(g)\bar \chi(g) of a partial Boolean function gg. We show χˉ(g)Ω(R1/3(g))\bar \chi(g) \in \Omega(\sqrt{R_{1/3}(g)}) for any (partial) function gg and R1/3(fgn)Ω(R4/9(f)χˉ(g))R_{1/3}(f \circ g^n) \in \Omega(R_{4/9}(f) \cdot \bar \chi(g)); these two bounds imply our composition result. We further show that χˉ(g)\bar \chi(g) is always at least as large as the sabotage complexity of gg, introduced by Ben-David and Kothari.

Keywords

Cite

@article{arxiv.1811.10752,
  title  = {A composition theorem for randomized query complexity via max conflict complexity},
  author = {Dmitry Gavinsky and Troy Lee and Miklos Santha and Swagato Sanyal},
  journal= {arXiv preprint arXiv:1811.10752},
  year   = {2018}
}

Comments

26 pages

R2 v1 2026-06-23T06:21:22.207Z