On perfect flag-rank metric codes

Abstract

Flag-rank-metric codes arise as a natural generalization of rank-metric codes in the context of network communication. While recent research has mainly focused on algebraic and structural properties of these codes, the combinatorial geometry underlying the flag-rank metric remains largely unexplored. In this paper, we initiate a detailed investigation of this geometry. We explicitly determine the size of spheres of small flag-rank radius in the space U(n,Fq) of upper triangular matrices over the finite field Fq, and consequently obtain formulas for the size of balls of radius at most 3. Using these enumerative results, we derive a sphere-packing bound for flag-rank-metric codes and introduce the notion of perfect codes with respect to the flag-rank metric. We observe that no non-trivial perfect flag-rank-metric codes exist in U(n,Fq) for n∈\2,3\. We then investigate the possible parameters of perfect codes in higher dimensions. For minimum distance 3, we obtain a characterization in terms of the codimension of the code, and show that suitable maximum flag-rank distance codes with minimum distance 3 yield non-trivial perfect codes. For minimum distances 5 and 7, we derive explicit quadratic and cubic conditions, respectively, that any perfect code must satisfy. Finally, using asymptotic estimates for balls of fixed radius, we prove that for fixed length n and δ∈\3,5,7,9,11\, perfect linear flag-rank-metric codes with minimum distance δ do not exist over Fq for all sufficiently large q.