Sums of square roots that are close to an integer

Abstract

Let k ∈ N and suppose we are given k integers 1 ≤ a1, …, ak ≤ n. If a1 + … + ak is not an integer, how close can it be to one? When k=1, the distance to the nearest integer is n-1/2. Angluin-Eisenstat observed the bound n-3/2 when k=2. We prove there is a universal c>0 such that, for all k ≥ 2, there exists a ck > 0 and k integers in \1,2,…, n\ with 0 <\|a1 + … + ak \| ≤ ck· n-c · k1/3, where \| · \| denotes the distance to the nearest integer. This is a case of the square-root sum problem in numerical analysis where the usual cancellation constructions do not apply: even for k=3, constructing explicit examples of integers whose square root sum is nearly an integer appears to be nontrivial.