• DocumentCode
    1607479
  • Title

    Byzantine fault tolerance of regenerating codes

  • Author

    Oggier, Frédérique ; Datta, Anwitaman

  • Author_Institution
    Div. of Math. Sci., Nanyang Technol. Univ., Singapore, Singapore
  • fYear
    2011
  • Firstpage
    112
  • Lastpage
    121
  • Abstract
    Recent years have witnessed a slew of coding techniques custom designed for networked storage systems. Network coding inspired regenerating codes are the most prolifically studied among these new age storage centric codes. A lot of effort has been invested in understanding the fundamental achievable trade-offs of storage and bandwidth usage to maintain redundancy in presence of different models of failures, showcasing the efficacy of regenerating codes with respect to traditional erasure coding techniques. For practical usability in open and adversarial environments, as is typical in peer-to-peer systems, we need however not only resilience against erasures, but also from (adversarial) errors. In this paper, we study the resilience of generalized regenerating codes (supporting multi-repairs, using collaboration among newcomers) in the presence of two classes of Byzantine nodes, relatively benign selfish (non-cooperating) nodes, as well as under more active, malicious polluting nodes. We give upper bounds on the resilience capacity of regenerating codes, and show that the advantages of collaborative repair can turn to be detrimental in the presence of Byzantine nodes. We further exhibit that system mechanisms can be combined with regenerating codes to mitigate the effect of rogue nodes.
  • Keywords
    computer network reliability; computer network security; fault tolerance; network coding; peer-to-peer computing; storage area networks; Byzantine fault tolerance; Byzantine nodes; malicious polluting nodes; network coding; networked storage systems; peer-to-peer systems; regenerating codes; storage centric codes; Bandwidth; Collaboration; Encoding; Maintenance engineering; Network coding; Peer to peer computing; Redundancy; Byzantine faults; distributed storage; pollution; regenerating codes; resilience capacity;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Peer-to-Peer Computing (P2P), 2011 IEEE International Conference on
  • Conference_Location
    Kyoto
  • ISSN
    2161-3559
  • Print_ISBN
    978-1-4577-0150-4
  • Electronic_ISBN
    2161-3559
  • Type

    conf

  • DOI
    10.1109/P2P.2011.6038668
  • Filename
    6038668