Linear Exact Repair in MDS Array Codes: A General Lower Bound and Its Attainability
Abstract
For an MDS array code over , how small can the repair bandwidth and repair I/O be under linear exact repair? We study this question in the regime where the field size , the redundancy , and the sub-packetization level are fixed, while the code length varies, and we develop a geometric approach to this setting. Our starting point is an intrinsic reformulation of linear exact repair for MDS array codes in terms of subspace intersections and, for repair I/O, the projective point configurations induced by a parity-check realization. This viewpoint yields a simple projective counting argument establishing the general lower bound for linear exact repair of every MDS array code over with redundancy . To our knowledge, this is the first lower bound of this form that applies to arbitrary redundancy and sub-packetization level . At first glance, the projective counting bound appears rather coarse and therefore unlikely to be attained. We prove that this intuition is correct whenever and . For , the picture changes completely. Using Desarguesian spreads from finite geometry, we construct MDS array codes that attain the bound over a broad interval of code lengths, up to the maximum possible length , and do so simultaneously for both repair bandwidth and repair I/O. In the smallest nontrivial case , we also prove a converse within the regular-spread model. Together, these results identify a uniform obstruction governing linear exact repair and show that, in the two-parity case, this obstruction is tight.
Cite
@article{arxiv.2604.04519,
title = {Linear Exact Repair in MDS Array Codes: A General Lower Bound and Its Attainability},
author = {Hai Liu and Huawei Wu},
journal= {arXiv preprint arXiv:2604.04519},
year = {2026}
}