Elias-type Bounds for Codes in the Symmetric Limited-Magnitude Error Channel

Abstract

We study perfect error-correcting codes in Zn for the symmetric limited-magnitude error channel, where at most e coordinates of an integer vector may be altered by a value whose magnitude is at most s. Geometrically, such codes correspond to tilings of Zn by the symmetric limited-magnitude error ball B(n,e,s,s). Given n and s, we adapt the geometric ideas underlying the Elias bound for the Hamming metric to the distance ds tailed for this channel, and derive new necessary conditions on e for the existence of perfect codes / tilings, without assuming any lattice structure. Our main results identify two distinct regimes depending on the error magnitude. For small error magnitudes (s ∈ \1, 2\), we prove that if the number of correctable errors does not exceed a certain fraction of n, then it is asymptotically bounded by e = O(n n). In contrast, for larger magnitudes (s ≥ 3), we establish a significantly sharper bound of e < 12.36n, which holds without any restriction on e being below a given fraction of n. Finally, by extending our method to non-perfect codes, we derive an upper bound on packing density, showing that for codes correcting a linear or (n) number of errors, the density is bounded by a factor inversely proportional to the error magnitude s.