Extremal Deletion-Ball Intersections under Run-Count and Lower-Order Deletion-Ball Intersection Constraints

Abstract

Motivated by sequence reconstruction and reconstruction codes, we study extremal intersections of deletion balls over a fixed q-ary alphabet. Let Σqn be the set of sequences of length n over Σq, and let Dt(x) denote the set of all sequences obtained from x∈Σqn by deleting exactly t symbols. Our first result gives a finite upper bound under a lower-order deletion-correction constraint. We prove that if x,y∈Σqn satisfy Ds-1(x) Ds-1(y)=, then \[ |Dt(x) Dt(y)| 2ssn-st-s. \] For binary alphabets, this strengthens a recent asymptotic upper bound of Pham, Goyal, and Kiah (2025, JCTA). We then investigate deletion-ball intersections under simultaneous constraints on run counts and lower-order deletion-ball intersections. For fixed 0<γ1, integers 1 s t, and m1, we show that if x,y∈Σqn have at most γn runs and satisfy |Ds(x) Ds(y)| m, then \[ |Dt(x) Dt(y)| mγt-s(t-s)!nt-s+Os,t,m(nt-s-1). \] Moreover, the leading term can be attainable whenever m is realized by a fixed finite-length seed pair. As a consequence, we obtain a direct lifting theorem for deletion reconstruction codes, transferring reconstruction properties from radius s to larger radii t. Finally, we establish a parallel insertion theory and derive corresponding results for insertion-ball intersections and insertion reconstruction codes.