The number of multiplicative Sidon sets of integers
arXiv:1808.06182
Abstract
A set $S$ of natural numbers is multiplicative Sidon if the products of all pairs in $S$ are distinct. ErdÅs in 1938 studied the maximum size of a multiplicative Sidon subset of $\{1,\ldots, n\}$, which was later determined up to the lower order term: $Ï(n)+Î(\frac{n^{3/4}}{(\log n)^{3/2}})$. We show that the number of multiplicative Sidon subsets of $\{1,\ldots, n\}$ is $T(n)\cdot 2^{Î(\frac{n^{3/4}}{(\log n)^{3/2}})}$ for a certain function $T(n)\approx 2^{1.815Ï(n)}$ which we specify. This is a rare example in which the order of magnitude of the lower order term in the exponent is determined. It resolves the enumeration problem for multiplicative Sidon sets initiated by Cameron and ErdÅs in the 80s. We also investigate its extension for generalised multiplicative Sidon sets. Denote by $S_k$, $k\ge 2$, the number of multiplicative $k$-Sidon subsets of $\{1,\ldots, n\}$. We show that $S_k(n)=(β_k+o(1))^{Ï(n)}$ for some $β_k$ we define explicitly. Our proof is elementary.
20 pages