English

On generalized corners and matrix multiplication

Combinatorics 2023-09-12 v1 Discrete Mathematics Data Structures and Algorithms

Abstract

Suppose that S[n]2S \subseteq [n]^2 contains no three points of the form (x,y),(x,y+δ),(x+δ,y)(x,y), (x,y+\delta), (x+\delta,y'), where δ0\delta \neq 0. How big can SS be? Trivially, nSn2n \le |S| \le n^2. Slight improvements on these bounds are obtained from Shkredov's upper bound for the corners problem [Shk06], which shows that SO(n2/(loglogn)c)|S| \le O(n^2/(\log \log n)^c) for some small c>0c > 0, and a construction due to Petrov [Pet23], which shows that SΩ(nlogn/loglogn)|S| \ge \Omega(n \log n/\sqrt{\log \log n}). Could it be that for all ε>0\varepsilon > 0, SO(n1+ε)|S| \le O(n^{1+\varepsilon})? We show that if so, this would rule out obtaining ω=2\omega = 2 using a large family of abelian groups in the group-theoretic framework of Cohn, Kleinberg, Szegedy and Umans [CU03,CKSU05] (which is known to capture the best bounds on ω\omega to date), for which no barriers are currently known. Furthermore, an upper bound of O(n4/3ε)O(n^{4/3 - \varepsilon}) for any fixed ε>0\varepsilon > 0 would rule out a conjectured approach to obtain ω=2\omega = 2 of [CKSU05]. Along the way, we encounter several problems that have much stronger constraints and that would already have these implications.

Keywords

Cite

@article{arxiv.2309.03878,
  title  = {On generalized corners and matrix multiplication},
  author = {Kevin Pratt},
  journal= {arXiv preprint arXiv:2309.03878},
  year   = {2023}
}

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R2 v1 2026-06-28T12:15:32.263Z