Successive Omniscience

Chung Chan; Ali Al-Bashabsheh; Qiaoqiao Zhou; Ni Ding; Tie Liu; Alex Sprintson

doi:10.1109/TIT.2016.2555923

Successive Omniscience

Chung Chan
, Ali Al-Bashabsheh
, Qiaoqiao Zhou
, Ni Ding
, Tie Liu
, Alex Sprintson

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

23 Citations (Scopus)

Abstract

Because the exchange of information among all the users in a large network can take a long time, a successive omniscience protocol is proposed. Namely, subgroups of users first recover the information of other users in the same subgroup at an earlier stage called local omniscience. Then, the users recover the information of all other users at a later stage called global omniscience. To facilitate the information exchange, a distributed storage system is used, so that users can conveniently upload and download messages through some reliable central servers. The minimum upload bandwidth is characterized and a bandwidth-storage trade-off is discovered. The results reveal the new connections to the problem of secret key agreement and, consequently, provide meaningful interpretations of a recently proposed multivariate mutual information measure that was inspired by the secret key agreement problem.

Original language	English
Pages (from-to)	3270-3289
Journal	IEEE Transactions on Information Theory
Volume	62
Issue number	6
Online published	21 Apr 2016
DOIs	https://doi.org/10.1109/TIT.2016.2555923
Publication status	Published - Jun 2016
Externally published	Yes

Research Keywords

data storage
multivariate mutual information
secret key agreement
Successive omniscience

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10.1109/TIT.2016.2555923

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title = "Successive Omniscience",

abstract = "Because the exchange of information among all the users in a large network can take a long time, a successive omniscience protocol is proposed. Namely, subgroups of users first recover the information of other users in the same subgroup at an earlier stage called local omniscience. Then, the users recover the information of all other users at a later stage called global omniscience. To facilitate the information exchange, a distributed storage system is used, so that users can conveniently upload and download messages through some reliable central servers. The minimum upload bandwidth is characterized and a bandwidth-storage trade-off is discovered. The results reveal the new connections to the problem of secret key agreement and, consequently, provide meaningful interpretations of a recently proposed multivariate mutual information measure that was inspired by the secret key agreement problem.",

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author = "Chung Chan and Ali Al-Bashabsheh and Qiaoqiao Zhou and Ni Ding and Tie Liu and Alex Sprintson",

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T1 - Successive Omniscience

AU - Chan, Chung

AU - Al-Bashabsheh, Ali

AU - Zhou, Qiaoqiao

AU - Ding, Ni

AU - Liu, Tie

AU - Sprintson, Alex

PY - 2016/6

Y1 - 2016/6

N2 - Because the exchange of information among all the users in a large network can take a long time, a successive omniscience protocol is proposed. Namely, subgroups of users first recover the information of other users in the same subgroup at an earlier stage called local omniscience. Then, the users recover the information of all other users at a later stage called global omniscience. To facilitate the information exchange, a distributed storage system is used, so that users can conveniently upload and download messages through some reliable central servers. The minimum upload bandwidth is characterized and a bandwidth-storage trade-off is discovered. The results reveal the new connections to the problem of secret key agreement and, consequently, provide meaningful interpretations of a recently proposed multivariate mutual information measure that was inspired by the secret key agreement problem.

AB - Because the exchange of information among all the users in a large network can take a long time, a successive omniscience protocol is proposed. Namely, subgroups of users first recover the information of other users in the same subgroup at an earlier stage called local omniscience. Then, the users recover the information of all other users at a later stage called global omniscience. To facilitate the information exchange, a distributed storage system is used, so that users can conveniently upload and download messages through some reliable central servers. The minimum upload bandwidth is characterized and a bandwidth-storage trade-off is discovered. The results reveal the new connections to the problem of secret key agreement and, consequently, provide meaningful interpretations of a recently proposed multivariate mutual information measure that was inspired by the secret key agreement problem.

KW - data storage

KW - multivariate mutual information

KW - secret key agreement

KW - Successive omniscience

UR - https://www.scopus.com/pages/publications/84976350909

UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-84976350909&origin=recordpage

U2 - 10.1109/TIT.2016.2555923

DO - 10.1109/TIT.2016.2555923

M3 - RGC 21 - Publication in refereed journal

SN - 0018-9448

VL - 62

SP - 3270

EP - 3289

JO - IEEE Transactions on Information Theory

JF - IEEE Transactions on Information Theory

IS - 6

ER -

Successive Omniscience

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Research Keywords

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GRF: Matroidal Network Link Model

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Successive Omniscience

Abstract

Research Keywords

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GRF: Matroidal Network Link Model

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