English

Randomised Composition and Small-Bias Minimax

Computational Complexity 2022-08-30 v1 Quantum Physics

Abstract

We prove two results about randomised query complexity R(f)\mathrm{R}(f). First, we introduce a "linearised" complexity measure LR\mathrm{LR} and show that it satisfies an inner-optimal composition theorem: R(fg)Ω(R(f)LR(g))\mathrm{R}(f\circ g) \geq \Omega(\mathrm{R}(f) \mathrm{LR}(g)) for all partial ff and gg, and moreover, LR\mathrm{LR} is the largest possible measure with this property. In particular, LR\mathrm{LR} can be polynomially larger than previous measures that satisfy an inner composition theorem, such as the max-conflict complexity of Gavinsky, Lee, Santha, and Sanyal (ICALP 2019). Our second result addresses a question of Yao (FOCS 1977). He asked if ϵ\epsilon-error expected query complexity Rˉϵ(f)\bar{\mathrm{R}}_{\epsilon}(f) admits a distributional characterisation relative to some hard input distribution. Vereshchagin (TCS 1998) answered this question affirmatively in the bounded-error case. We show that an analogous theorem fails in the small-bias case ϵ=1/2o(1)\epsilon=1/2-o(1).

Keywords

Cite

@article{arxiv.2208.12896,
  title  = {Randomised Composition and Small-Bias Minimax},
  author = {Shalev Ben-David and Eric Blais and Mika Göös and Gilbert Maystre},
  journal= {arXiv preprint arXiv:2208.12896},
  year   = {2022}
}

Comments

41 pages. To appear in FOCS 2022

R2 v1 2026-06-25T02:01:14.515Z