Universal Fourier-inertia bounds for prescribed even distances

Abstract

The study of set families with restricted Hamming distances is a classical topic of extremal combinatorics and coding theory. Let \(H=\A⊂eq[n]: |A| is even\\) be the even subcube. Let \(1,…,t\) be distinct positive integers and set \( L=\21,…,2t\\). We prove that, for all sufficiently large \(n\), every family \( F⊂eq H\) satisfying \( |A B|∈ L \) for all \(A B∈ F\) has \[ | F| Σi=0tn-1i. \] This is best possible as a universal bound, with equality attained at the distance set \( L=\2,4,…,2t\\). Our proof uses a Fourier-inertia argument based on a universal low/high boundary-layer sign pattern for the Fourier transform of the distance-polynomial kernel on the even subcube: the prescribed distances enter only through lower-order Fourier terms, while the leading boundary-layer signs depend solely on \(t\). This even-subcube result immediately yields an odd-subcube analogue and, through parity reductions, provides bounds for arbitrary distance sets. In particular, this approach recovers the classical interval bounds of Kleitman and the corresponding interval bounds of Huang--Klurman--Pohoata, while offering a direct spectral proof of the maximality of \(\2,4,…,2t\\) among all fixed \(t\)-distance sets.