Minimum Storage Regenerating Codes for All Parameters

Goparaju, Sreechakra; Fazeli, Arman; Vardy, Alexander

doi:10.1109/tit.2017.2690662

Cited by 88 publications

(59 citation statements)

References 23 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Similarly to Theorem 7 in [10] and Lemma 7 in [15], by virtue of Lemma 2 we have the following result to ensure the non-singularity of the related sub-block matrices. Proof.…”

Section: A Generic Transformationmentioning

confidence: 86%

“…Theorem 3. Choosing the Ye-Barg code 1, defined by the coding matrices (15), as the base code for the generic transformation in Section III, we can get an (n = sn ′ , k) MDS code C 1 over F q with q > N n−1 r−1 , where k = n − r. Specifically, the subpacketization level of the MDS code C 1 is r n ′ while the repair bandwidth is (1 + (s−1)(r−1) n−1 ) times the optimal value. B.…”

Section: Mds Code Constructions By Directly Applying the Generic mentioning

confidence: 99%

See 1 more Smart Citation

Systematic Construction of MDS Codes with Small Sub-packetization Level and Near Optimal Repair Bandwidth

Tang

2019

2019 IEEE International Symposium on Information Theory (ISIT)

View full text Add to dashboard Cite

In the literature, all the known high-rate MDS codes with the optimal repair bandwidth possess a significantly large subpacketization level, which may prevent the codes to be implemented in practical systems. To build MDS codes with small sub-packetization level, existing constructions and theoretical bounds imply that one may sacrifice the optimality of the repair bandwidth. Partly motivated by the work of Tamo et al. (IEEE Trans. Inform. Theory, 59(3), 1597-1616, in this paper, we present a powerful transformation that can greatly reduce the sub-packetization level of any MDS codes with respect to the same code length n. As applications of the transformation, four high-rate MDS codes having both small sub-packetization level and near optimal repair bandwidth can be obtained, where two of them are also explicit and the required field sizes are comparable to the code length n. Additionally, we propose another explicit MDS code that have small sub-packetization level, near optimal repair bandwidth, and the optimal update property. The required field size is also comparable to the code length n. Index TermsDistributed storage, high-rate, MDS codes, sub-packetization, repair bandwidth. J. Li is with the

show abstract

“…Similarly to Theorem 7 in [10] and Lemma 7 in [15], by virtue of Lemma 2 we have the following result to ensure the non-singularity of the related sub-block matrices. Proof.…”

Section: A Generic Transformationmentioning

confidence: 86%

Section: Mds Code Constructions By Directly Applying the Generic mentioning

confidence: 99%

Systematic Construction of MDS Codes with Small Sub-packetization Level and Near Optimal Repair Bandwidth

Tang

2019

2019 IEEE International Symposium on Information Theory (ISIT)

View full text Add to dashboard Cite

show abstract

“…In particular, the problem of constructing high rate MSR codes, i.e., with a constant number of parity nodes, has received a great deal of attention [4,22,24,29,30]. Implementing our techniques for high rate MSR codes is one of our future research directions.…”

Section: Previous Workmentioning

confidence: 99%

Asymptotically Optimal Regenerating Codes Over Any Field

Raviv

2018

IEEE Trans. Inform. Theory

View full text Add to dashboard Cite

The study of regenerating codes has advanced tremendously in recent years. However, most known constructions require large field size, and hence may be hard to implement in practice. By using notions from the theory of extension fields, we obtain two explicit constructions of regenerating codes. These codes approach the cut-set bound as the reconstruction degree increases, and may be realized over any given field if the file size is large enough. Since distributed storage systems are the main purpose of regenerating codes, this file size restriction is trivially satisfied in most conceivable scenarios. The first construction attains the cut-set bound at the MBR point asymptotically for all parameters, whereas the second one attains the cut-set bound at the MSR point asymptotically for low-rate parameters.

show abstract

“…Towards constructing high-rate exact-repairable MDS codes with optimal repair-bandwidth, Cadambe et al [3] show the existence of such codes when subpacketization level approaches infinity. Motivated by this result, the problem of designing high-rate exactrepairable MDS codes with finite sub-packetization level and optimal repair bandwidth is explored in [2,8,17,22,23,28,32,34,36] and references therein.…”

Section: Background and Related Workmentioning

confidence: 99%

“…The problem of constructing MDS codes with optimal repair-bandwidth (cf. (1.1)) has been explored in [3,8,17,18,22,23,28,36] and references therein. Note that as the number of the nodes contacted during the repair process d gets larger, the optimal repair bandwidth defined by the cut-set bound becomes significantly smaller than the naive repair bandwidth of k symbols (over F) or k symbols (over B).…”

Section: Introductionmentioning

confidence: 99%

MDS Code Constructions with Small Sub-packetization and Near-optimal Repair Bandwidth

Rawat

Tamo

Guruswami

et al. 2017

Proceedings of the Twenty-Eighth Annual ACM-SIAM Symposium on Discrete Algorithms

View full text Add to dashboard Cite

An (n, M ) vector code C ⊆ F n is a collection of M codewords where n elements (from the field F) in each of the codewords are referred to as code blocks. Assuming that F ∼ = B , the code blocks are treated as -length vectors over the base field B. Equivalently, the code is said to have the sub-packetization level . This paper addresses the problem of constructing MDS vector codes which enable exact reconstruction of each code block by downloading small amount of information from the remaining code blocks. The repair bandwidth of a code measures the information flow from the remaining code blocks during the reconstruction of a single code block. This problem naturally arises in the context of distributed storage systems as the node repair problem [4]. Assuming that M = |B| k , the repair bandwidth of an MDS vector code is lower bounded by (n − 1)/(n − k) · symbols (over the base field B) which is also referred to as the cut-set bound [4]. For all values of n and k, the MDS vector codes that attain the cut-set bound with the sub-packetization level = (n − k) n/(n−k) are known in the literature [23,36].This paper presents a construction for MDS vector codes which simultaneously ensures both small repair bandwidth and small sub-packetization level. The obtained codes have the smallest possible sub-packetization level = O(n − k) for an MDS vector code and the repair bandwidth which is at most twice the cut-set bound. The paper then generalizes this code construction so that the repair bandwidth of the obtained codes approach the cut-set bound at the cost of increased sub-packetization level. The constructions presented in this paper give MDS vector codes which are linear over the base field B.

show abstract

Minimum Storage Regenerating Codes for All Parameters

Cited by 88 publications

References 23 publications

Systematic Construction of MDS Codes with Small Sub-packetization Level and Near Optimal Repair Bandwidth

Systematic Construction of MDS Codes with Small Sub-packetization Level and Near Optimal Repair Bandwidth

Asymptotically Optimal Regenerating Codes Over Any Field

MDS Code Constructions with Small Sub-packetization and Near-optimal Repair Bandwidth

Contact Info

Product

Resources

About