Kneser's theorem for codes and -divisible set families
Abstract
A k-wise -divisible set family is a collection F of subsets of \1,…,n \ such that any intersection of k sets in F has cardinality divisible by . If k==2, it is well-known that |F|≤ 2 n/2 . We generalise this by proving that |F|≤ 2 n/p if k==p, for any prime number p. For arbitrary values of , we prove that 42-wise -divisible set families F satisfy |F|≤ 2 n/ and that the only families achieving the upper bound are atomic, meaning that they consist of all the unions of disjoint subsets of size . This improves upon a recent result by Gishboliner, Sudakov and Timon, that arrived at the same conclusion for k-wise -divisible families, with values of k that behave exponentially in . Our techniques rely heavily upon a coding-theory analogue of Kneser's Theorem from additive combinatorics.
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