English

A Dense Model Theorem for the Boolean Slice

Combinatorics 2024-08-02 v3

Abstract

The (low soundness) linearity testing problem for the middle slice of the Boolean cube is as follows. Let ε>0\varepsilon>0 and ff be a function on the middle slice on the Boolean cube, such that when choosing a uniformly random quadruple (x,y,z,xyz)(x,y,z ,x\oplus y\oplus z) of vectors of 2n2n bits with exactly nn ones, the probability that f(xyz)=f(x)f(y)f(z)f(x\oplus y \oplus z) = f(x) \oplus f(y) \oplus f(z) is at least 1/2+ε1/2+\varepsilon. The linearity testing problem, posed by David, Dinur, Goldenberg, Kindler and Shinkar, asks whether there must be an actual linear function that agrees with ff on 1/2+ε1/2+\varepsilon' fraction of the inputs, where ε=ε(ε)>0\varepsilon' = \varepsilon'(\varepsilon)>0. We solve this problem, showing that ff must indeed be correlated with a linear function. To do so, we prove a dense model theorem for the middle slice of the Boolean hypercube for Gowers uniformity norms. Specifically, we show that for every kNk\in\mathbb{N}, the normalized indicator function of the middle slice of the Boolean hypercube {0,1}2n\{0,1\}^{2n} is close in Gowers norm to the normalized indicator function of the union of all slices with weight t=n(mod2k1)t = n\pmod{2^{k-1}}. Using our techniques we also give a more general `low degree test' and a biased rank theorem for the slice.

Keywords

Cite

@article{arxiv.2402.05217,
  title  = {A Dense Model Theorem for the Boolean Slice},
  author = {Gil Kalai and Noam Lifshitz and Dor Minzer and Tamar Ziegler},
  journal= {arXiv preprint arXiv:2402.05217},
  year   = {2024}
}
R2 v1 2026-06-28T14:42:11.905Z