Distributed Computing: A Locality-Sensitive ApproachSIAM, 1 בינו׳ 2000 - 359 עמודים Presents the locality-sensitive approach to distributed network algorithms-the utilization of locality to simplify control structures and algorithms and reduce their costs. The author begins with an introductory exposition of distributed network algorithms focusing on topics that illustrate the role of locality in distributed algorithmic techniques. He then introduces locality-preserving network representations and describes sequential and distributed techniques for their construction. Finally, the applicability of the locality-sensitive approach is demonstrated through several applications. Gives a thorough exposition of network spanners and other locality-preserving network representations such as sparse covers and partitions. The book is useful for computer scientists interested in distributed computing, electrical engineers interested in network architectures and protocols, and for discrete mathematicians and graph theorists. |
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מהדורות אחרות - הצג הכל
Distributed Computing: A Locality-Sensitive Approach <span dir=ltr>David Peleg</span> תצוגה מקדימה מוגבלת - 2000 |
Distributed Computing: A Locality-Sensitive Approach <span dir=ltr>David Peleg</span> אין תצוגה מקדימה זמינה - 2000 |
Distributed Computing: A Locality-Sensitive Approach <span dir=ltr>David Peleg</span> אין תצוגה מקדימה זמינה - 2000 |
מונחים וביטויים נפוצים
allowed applies approach arbitrary assume basic bits broadcast Chapter claim cluster collection coloring communication computation connecting Consider consists construction contains controller cost cover defined definition denote described discussed distance distributed algorithm edges elements example execution Exercise exists fact Figure first fragment function given graph G hence identifiers initial input integer iteration labels layer least Lemma locality lower bound maximum measures memory message complexity n-vertex namely neighbors Note operation optimal original parameter partial particular partition path performed phase possible presented problem Proc Procedure processor Proof properties protocol prove pulse radius received representations requires resource resulting root round routing scheme selected sends single spanner spanning tree Specifically step stored stretch structure subgraph Suppose synchronizer Theorem tree unit unweighted update vertex vertices weight weighted graph