The Incidence-Multiplicity Bound for Linear Exact Repair in MDS Array Codes

Abstract

We study linear exact repair for (n,k,) MDS array codes over Fq, with redundancy r=n-k, in the regime where q, r, and are fixed and the code length n varies. A recent projective counting argument gives a general lower bound on repair bandwidth and repair I/O in this setting. While this bound is attained over a broad interval of code lengths in the two-parity case, it is not attained once r 3 and 2. In this paper, we refine the counting argument behind this bound and establish a sharper lower bound, which we call the incidence-multiplicity bound. We prove that for every (n,k,) MDS array code over Fq with r 2, both the average and worst-case repair bandwidth, as well as the average and worst-case repair I/O, are at least (n-1)-(r-1)q-1q-1.This bound agrees with the earlier projective counting bound when r=2, and is strictly stronger for every r 3. We also show that the incidence-multiplicity bound is sharp in a broad parameter range. Assume that 2, r 2, (r-1)(q-1), and (q-1)/(r-1) 2. Then for every integer n satisfying 2(r-1)q-1q-1 n q+1, there exists an (n,n-r,) MDS array code over Fq that attains the incidence-multiplicity bound simultaneously for both repair bandwidth and repair I/O. These codes arise from field reduction of a normal rational curve. Together, these results reveal incidence multiplicity as the governing geometric principle for linear exact repair in MDS array codes beyond the two-parity case.