The Frobenius problem, rational polytopes, and Fourier-Dedekind Sums

Abstract

We study the number of lattice points in integer dilates of the rational polytope P = (x1,...,xn) ∈ ≥ 0n : Σk=1n xk ak ≤ 1, where a1,...,an are positive integers. This polytope is closely related to the linear Diophantine problem of Frobenius: given relatively prime positive integers a1,...,an, find the largest value of t (the Frobenius number) such that m1 a1 + ... + mn an = t has no solution in positive integers m1,...,mn. This is equivalent to the problem of finding the largest dilate tP such that the facet Σk=1n xk ak = t contains no lattice point. We present two methods for computing the Ehrhart quasipolynomials of P which count the integer points in the dilated polytope and its interior. Within the computations a Dedekind-like finite Fourier sum appears. We obtain a reciprocity law for these sums, generalizing a theorem of Gessel. As a corollary of our formulas, we rederive the reciprocity law for Zagier's higher-dimensional Dedekind sums. Finally, we find bounds for the Fourier-Dedekind sums and use them to give new bounds for the Frobenius number.

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