The Erdos-Moser sum-free set problem

We show that if A is a finite set of integers then it has a subset S of size \log^{1+c} |A| (c>0 absolute) such that s+s' is never in A when s and s' are distinct elements of S.Comment: 47 pages. Corrections and clarification

Probabilistic construction of small strongly sum-free sets via large Sidon sets

We give simple randomized algorithms leading to new upper bounds for combinatorial problems of Choi and Erdős: For an arbitrary additive group G let $P_n(G)$ denote the set of all subsets S of G with n elements having the property that 0 is not in S+S. Call a subset A of G admissible with respect to a set S from $P_n(G)$ if the sum of each pair of distinct elements of A lies outside S. Suppose first that S is a subset of the positive integers in the interval [2n,4n). Denote by f(S) the number of elements in a maximum subset of [n,2n) admissible with respect to S. Choi showed that $f(n):=min{|S|+f(S)| S ⊆ [2n,4n)} = On^{3/4})$. We improve this bound to $O(n ln(n))^{2/3})$. Turning to a problem of Erdős, suppose that S is an element of $P_n(G)$, where G is an arbitrary additive group, and denote by h(S) the maximum cardinality of a subset A of S admissible with respect to S. We show $h(n):=min{h(S) | G a group, S ∈ P_n(G)}=O(ln(n))^2)$. Our approach relies on the existence of large Sidon sets