Strong Bounds for 3-Progressions

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United States Simons Institute for the Theory of Computing
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Published on ● Video Link: https://www.youtube.com/watch?v=JuLkBGe0AB8


Duration: 1:03:56
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Zander Kelley (University of Illinois Urbana-Champaign)
https://simons.berkeley.edu/talks/zander-kelley-university-illinois-urbana-champaign-2023-06-28
Beyond the Boolean Cube

Suppose you have a set A of integers from {1, 2, …, N} that contains at least N / C elements. Then for large enough N, must A contain three equally spaced numbers (i.e., a 3-term arithmetic progression)? In 1953, Roth showed that this is indeed the case when C ≈ log log N, while Behrend in 1946 showed that C can be at most 2^√log(N) by giving an explicit construction of a large set with no 3-term progressions. Since then, the problem has been a cornerstone of the area of additive combinatorics. Following a series of remarkable results, a celebrated paper from 2020 due to Bloom and Sisask improved the lower bound on C to C = (log N)^(1 + c), for some constant c > 0. This talk will describe a new work which shows that the same holds when C ≈ 2^(log N)^(1/12), thus getting closer to Behrend's construction. Based on a joint work with Raghu Meka.



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Tags:
Simons Institute
theoretical computer science
UC Berkeley
Computer Science
Theory of Computation
Theory of Computing
Beyond the Boolean Cube
Zander Kelley