English

New Direct Sum Tests

Computational Complexity 2024-09-17 v1

Abstract

A function f:[n]dF2f:[n]^{d} \to \mathbb{F}_2 is a \defn{direct sum} if there are functions Li:[n]F2L_i:[n]\to \mathbb{F}_2 such that f(x)=iLi(xi){f(x) = \sum_{i}L_i(x_i)}. In this work we give multiple results related to the property testing of direct sums. Our first result concerns a test proposed by Dinur and Golubev in 2019. We call their test the Diamond test and show that it is indeed a direct sum tester. More specifically, we show that if a function ff is ϵ\epsilon-far from being a direct sum function, then the Diamond test rejects ff with probability at least Ωn,ϵ(1)\Omega_{n,\epsilon}(1). Even in the case of n=2n = 2, the Diamond test is, to the best of our knowledge, novel and yields a new tester for the classic property of affinity. Apart from the Diamond test, we also analyze a broad family of direct sum tests, which at a high level, run an arbitrary affinity test on the restriction of ff to a random hypercube inside of [n]d[n]^d. This family of tests includes the direct sum test analyzed in \cite{di19}, but does not include the Diamond test. As an application of our result, we obtain a direct sum test which works in the online adversary model of \cite{KRV}. Finally, we also discuss a Fourier analytic interpretation of the diamond tester in the n=2n=2 case, as well as prove local correction results for direct sum as conjectured by Dinur and Golubev.

Cite

@article{arxiv.2409.10464,
  title  = {New Direct Sum Tests},
  author = {Alek Westover and Edward Yu and Kai Zheng},
  journal= {arXiv preprint arXiv:2409.10464},
  year   = {2024}
}

Comments

21 pages

R2 v1 2026-06-28T18:46:29.647Z