English

An Improved Sub-Packetization Bound for Minimum Storage Regenerating Codes

Information Theory 2013-05-16 v1 math.IT

Abstract

Distributed storage systems employ codes to provide resilience to failure of multiple storage disks. Specifically, an (n,k)(n, k) MDS code stores kk symbols in nn disks such that the overall system is tolerant to a failure of up to nkn-k disks. However, access to at least kk disks is still required to repair a single erasure. To reduce repair bandwidth, array codes are used where the stored symbols or packets are vectors of length \ell. MDS array codes have the potential to repair a single erasure using a fraction 1/(nk)1/(n-k) of data stored in the remaining disks. We introduce new methods of analysis which capitalize on the translation of the storage system problem into a geometric problem on a set of operators and subspaces. In particular, we ask the following question: for a given (n,k)(n, k), what is the minimum vector-length or sub-packetization factor \ell required to achieve this optimal fraction? For \emph{exact recovery} of systematic disks in an MDS code of low redundancy, i.e. k/n>1/2k/n > 1/2, the best known explicit codes \cite{WTB12} have a sub-packetization factor \ell which is exponential in kk. It has been conjectured \cite{TWB12} that for a fixed number of parity nodes, it is in fact necessary for \ell to be exponential in kk. In this paper, we provide a new log-squared converse bound on kk for a given \ell, and prove that k2log2(logδ+1)k \le 2\log_2\ell\left(\log_{\delta}\ell+1\right), for an arbitrary number of parity nodes r=nkr = n-k, where δ=r/(r1)\delta = r/(r-1).

Keywords

Cite

@article{arxiv.1305.3498,
  title  = {An Improved Sub-Packetization Bound for Minimum Storage Regenerating Codes},
  author = {Sreechakra Goparaju and Itzhak Tamo and Robert Calderbank},
  journal= {arXiv preprint arXiv:1305.3498},
  year   = {2013}
}
R2 v1 2026-06-22T00:16:59.762Z