Euclidean sets with only one distance modulo a prime ideal

Abstract

Let X be a finite set in the Euclidean space Rd. If the squared distance between any two distinct points in X is an odd integer, then the cardinality of X is bounded above by d+2, as shown by Rosenfeld (1997) or Smith (1995). They proved that there exists a (d+2)-point set X in Rd having only odd integral squared distances if and only if d+2 is congruent to 0 modulo 4. The distances can be interpreted as an element of the finite field Z/2Z. We generalize this result for a local ring (Ap,pAp) as follows. Let K be an algebraic number field that can be embedded into R. Fix an embedding of K into R, and K is interpreted as a subfield of R. Let A=OK be the ring of integers of K, and p a prime ideal of OK. Let (Ap,pAp) be the local ring obtained from the localization (A p)-1 A, which is interpreted as a subring of R. If the squared distances of X⊂ Rd are in Ap and each squared distance is congruent to some constant k 0 modulo p Ap, then |X| ≤ d+2, as shown by Nozaki (2023). In this paper, we prove that there exists a set X⊂ Rd attaining the upper bound |X| ≤ d+2 if and only if d+2 is congruent to 0 modulo 4 when the finite field Ap/ p Ap is of characteristic 2, and d+2 is congruent to 0 modulo p when Ap/ p Ap is of characteristic p odd. We also provide examples attaining this upper bound.