English

A Strong Direct Sum Theorem for Distributional Query Complexity

Computational Complexity 2024-05-28 v1

Abstract

Consider the expected query complexity of computing the kk-fold direct product fkf^{\otimes k} of a function ff to error ε\varepsilon with respect to a distribution μk\mu^k. One strategy is to sequentially compute each of the kk copies to error ε/k\varepsilon/k with respect to μ\mu and apply the union bound. We prove a strong direct sum theorem showing that this naive strategy is essentially optimal. In particular, computing a direct product necessitates a blowup in both query complexity and error. Strong direct sum theorems contrast with results that only show a blowup in query complexity or error but not both. There has been a long line of such results for distributional query complexity, dating back to (Impagliazzo, Raz, Wigderson 1994) and (Nisan, Rudich, Saks 1994), but a strong direct sum theorem had been elusive. A key idea in our work is the first use of the Hardcore Theorem (Impagliazzo 1995) in the context of query complexity. We prove a new "resilience lemma" that accompanies it, showing that the hardcore of fkf^{\otimes k} is likely to remain dense under arbitrary partitions of the input space.

Cite

@article{arxiv.2405.16340,
  title  = {A Strong Direct Sum Theorem for Distributional Query Complexity},
  author = {Guy Blanc and Caleb Koch and Carmen Strassle and Li-Yang Tan},
  journal= {arXiv preprint arXiv:2405.16340},
  year   = {2024}
}

Comments

34 pages, 4 figures, CCC 2024

R2 v1 2026-06-28T16:40:25.472Z