2015
DOI: 10.14778/2757807.2757809
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An efficient similarity search framework for SimRank over large dynamic graphs

Abstract: SimRank is an important measure of vertex-pair similarity according to the structure of graphs. The similarity search based on Sim-Rank is an important operation for identifying similar vertices in a graph and has been employed in many data analysis applications. Nowadays, graphs in the real world become much larger and more dynamic. The existing solutions for similarity search are expensive in terms of time and space cost. None of them can efficiently support similarity search over large dynamic graphs. In th… Show more

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Cited by 56 publications
(78 citation statements)
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“…Third, although the semantics in the direction of links is lost, it is advantageous to disregard the direction of links in similarity computation. Finally, since the computation of C-Rank is fundamentally the same as that of SimRank, except that C-Rank disregards the direction of links, many of the methods [8,9,14,22,35,43,45,49,50] to improve the time complexity of SimRank can be applied to C-Rank.…”
Section: Discussionmentioning
confidence: 99%
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“…Third, although the semantics in the direction of links is lost, it is advantageous to disregard the direction of links in similarity computation. Finally, since the computation of C-Rank is fundamentally the same as that of SimRank, except that C-Rank disregards the direction of links, many of the methods [8,9,14,22,35,43,45,49,50] to improve the time complexity of SimRank can be applied to C-Rank.…”
Section: Discussionmentioning
confidence: 99%
“…However, the worst-case time complexity of all existing iterative measures including C-Rank is O(n 4 ). Many methods have been proposed to improve the time complexity of SimRank [8,9,14,22,35,43,45,49,50]. These methods can be applied to C-Rank because the computation of C-Rank is fundamentally the same as that of SimRank except that C-Rank disregards the direction of links.…”
Section: Algorithmmentioning
confidence: 99%
“…READS [12] precomputes √ c-walks and compresses the walks into trees. During query processing, READS retrieves the walks originating from the query node u, and finds all the √ c-walks that meet with the √ c-walks of u. TSF [28] builds an index consisting of one-way graphs by sampling one in-neighbor from each node's in-coming edges. During query processing, the one-way graphs are used to simlulate random walks to estimate SimRank.…”
Section: Given Twomentioning
confidence: 99%
“…Several recent approaches, notably [12,15,21,28,31,33], have demonstrated promising results for single source Sim-Rank processing, by solving the approximate version of the problem with rigorous result quality guarantees, as elaborated in Section 2. The majority of these methods, however, require extensive pre-processing to index the input graph G; as explained in Section 2.2, such indexes cannot be easily updated when the underlying graph G changes, meaning that these methods are not suitable for our target scenarios described above.…”
Section: Introductionmentioning
confidence: 99%
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