GCD sums and complete sets of square-free numbers
classification
🧮 math.NT
keywords
sqrtaistleitnerberkesfracnumbersseipsetssquare-free
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It is proved that \[ \sum_{k,{\ell}=1}^N\frac{\gcd(n_k,n_{\ell})}{\sqrt{n_k n_{\ell}}} \ll N\exp\left(C\sqrt{\frac{\log N \log\log\log N}{\log\log N}}\right) \] holds for arbitrary integers $1\le n_1<\cdots < n_N$. This bound is essentially better than that found in a recent paper of Aistleitner, Berkes, and Seip and can not be improved by more than possibly a power of $1/\sqrt{\log\log\log N}$. The proof relies on ideas from classical work of G\'{a}l, the method of Aistleitner, Berkes, and Seip, and a certain completeness property of extremal sets of square-free numbers.
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