Classification of independent sets in signed Johnson graphs and applications to kissing arrangements

Abstract

Johnson graph are a family of graphs that play an important role in the theory of constant-weight codes, extremal combinatorics, and combinatorial geometry. We study signed analogues of classical Johnson graphs, denoted by J(n,k), whose vertices are vectors of the form ei1·s eik, where two vertices are adjacent whenever their dot product equals k-1. We are particularly interested in maximum independent sets in the case k=4. An example of such an independent set in J(n,4), which we call classical, is obtained by lifting an arbitrary optimal (n,4,4)-code. Such independent sets naturally define kissing arrangements in Rn. We develop an algorithm that is practical for computing all maximum independent sets in J(n,4) up to signed permutations for n 12, n 11. In addition to obtaining complete lists, we provide structural characterizations of all types of maximum independent sets in these dimensions, excluding n=5 and n=11. Our most striking results concern the case n=12. We identify 1579 non-isomorphic maximum independent sets in J(12,4), all corresponding to non-isometric kissing arrangements of size 840 in R12. Structurally, 1575 of these independent sets arise from three different constructions, the rest are liftings of one of four (12,4,4)-codes. To our knowledge, this is the first dimension in which such a large diversity of potentially optimal kissing arrangements has been observed. Beyond this finite range, we prove that for n 2 or 4 6, every maximum independent set arises from a Steiner quadruple system. We also obtain a characterization of the so-called nontrivially self-compatible codes, namely optimal (n,4,4)-codes from which non-classical maximum independent sets can be constructed.