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Yuzhou Zhang ﹡, Jianyong Wang #, Yi Wang §, Lizhu Zhou ¶ Presented by Nam Nguyen Parallel Community Detection on Large Networks with Propinquity Dynamics.

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Presentation on theme: "Yuzhou Zhang ﹡, Jianyong Wang #, Yi Wang §, Lizhu Zhou ¶ Presented by Nam Nguyen Parallel Community Detection on Large Networks with Propinquity Dynamics."— Presentation transcript:

1 Yuzhou Zhang ﹡, Jianyong Wang #, Yi Wang §, Lizhu Zhou ¶ Presented by Nam Nguyen Parallel Community Detection on Large Networks with Propinquity Dynamics § Google Beijing Research Beijing 100084, China ﹡ # ¶ Department of Computer Science and Technology Tsinghua University Beijing 100084, China

2 Introduction to Community Detection Problem Graph(Network) can model many real life data. Community structure: Highly intra connected subgraphs with relatively sparse connections to the leaving parts. Coherent. Ubiquitous, distinguishing property of real-life graph. Applications include: Online Social network Web linkage graph Biological network Wikipedia graph

3 How to Define the Community Structure Clique(complete connected graph): too strict to be realistic. Quasi-Clique: a relaxed version. Edge density: inner community edges exceed the inter community edges. Implicit definition: Optimize a quality function. Modularity: a popular one. Even no quality function: depends on the heuristic.

4 Related Works Graph partitioning: several parameters must be specified. Edge cutting: the key is defining edge centrality. Betweenness: edge betweenness; current-flow betweenness; Random-walk betweenness; Information centrality. Edge clustering coefficient. Modularity optimization: greedy algorithm; simulated annealing; extremal optimization; spectral optimization; Spectral(laplacian matrix, normal matrix). Other…

5 Motivation Many algorithms exist, why we propose another?? We need a more efficient one for web scale data. Existing algorithm ≥ O(|V| 2 ) on sparse graph. Ours ≈ O(k·|V|). We emphasize the scalability aspect. Parallelized. Incremental.

6 Brainstorm The community structures are right there, why mine? Can the communities claim themselves by increase the graph contrast? How…? Observation: In social network, communities are progressively and spontaneously formed by the collaborative local decision of each individual. Our solution: Continue with more aggressive criterion. Community structures can emerge naturally. Simulation of this process: Propinquity Dynamics.

7 Overview Input Network (Graph with low contrast) Refined Network (Graph with higher contrast) Propinquity dynamics Network communities Finding connected components Parallelization

8 Example Propinquity dynamics Finding networks communities: Via connected components

9 Propinquity Dynamics Propinquity: evaluate the probability that a pair of vertices are involved in a coherent community. Denoted by In global view: Contradict propinquity and topology. Update the topology to keep consistent with propinquity. In local view: Edge deletion and insertion. Local topology update criteria: α: cutting threshold β: emerging threshold

10 Propinquity Dynamics (high level description) Init: Term condition: The incremental version: Init: Converge condition: Not yet proven

11 Overlapping Community Extraction Connected components are simply the communities we want. We have a chance to extract the community overlap: Micro clustering the neighbors at each vertex. Breadth-first-search.

12 Coherent Neighborhood Propinquity A concrete propinquity definition. It reflects the connectivity of the maximum coherent sub graph involving a vertex pair; Locality; Three parts: Direct connection; Common neighbors; Conjugates;

13 Propinquity Calculation Complexity by definition: Efficient way: Angle propinquity: for-each-vertex; Conjugate propinquity: for-each-edge; The overall complexity can be reduced to Can the propinquity be updated via an adaptive algorithm?

14 Incremental Propinquity Update Single edge delete and insert is easy to handle. What if overall topology update is considered? Let N n (v) be the neighboring vertex set of v in topology T n. All the following formulations will be mapped to operations on the three set. Given two disjoint vertex sets, S 1, S 2 (S 1 ⊓ S 2 = ∅ ), : for each v i ∈ S 1 and each v j ∈ S 2, increase P(v i, v j ) by a unit propinquity; : for each v i, v j ∈ S(v i ≠v j ), add a unit propinquity to P(v 1, v 2 )

15 Update overview

16 Angle Propinquity Update Angle propinquity w.r.t a specific vertex v(omitted):

17 Conjugate Propinquity Update(D,I) It seems that, we have covered all the cases… Really? Conjugate propinquity update brought by a… Deleted edge: Inserted edge:

18 Conjugate Propinquity Update(R) The answer is NO!! The conjugate propinquity contributed by a remained edge may partly change by updated local neighborhood… Let : be the remained common neighbor set between v 1 and v 2 and can be similarly defined. This part of propinquity update can be calculated by: Which can be further calculated by………

19 Conjugate Propinquity Update(R)

20 Incremental propinquity update(all)

21 Parallelization Time complexity without sparse graph assumption: Real datasets are large and dense; Degree distribution is highly skewed; So we need HPC’s help…

22 Parallel Model (Vertex oriented BSP) Virtual processor(vertex); Physical machine execute virtual processor; Message passing; Bulk synchronous parallel (BSP) model: Computation proceeds in consecutive supersteps (1)Accessing the messages sent to it in the previous superstep; (2)Carrying out local computation and accessing local memory; (3)Send other processors messages, which will be available to the destination processor later in the next superstep. Barrier: Dump both memory and messages for fault recovery;

23 Parallel Implementation Message type: : propinquity update; : donate neighbors;

24 Parallel Implementation We use C XY to refer the resulting set calculated from operation at X column and Y row:

25 Performance issues Message flow control: Divide the macro superstep into micro superstep; Message size estimate & flow control strategy; Propinquity map buffering;

26 Experiments Dataset statistics: Different  and  for each network Wikipedia:  =400,  = 1000 eatRS:  = 5,  = 180 Erdos02:  =2,  = 20 Hep-th-new:  =20,  = 300

27 Experiments Overlapping community structures mined from word association network eatRS.

28 Experiments Overlapping community structures mined from the Erdos02 co-authorship network.

29 Experiments Selected community structures mined from Wikipedia linkage graph.

30 Experiments Speedups while running on neural-sized hep-thnew paper citation network. Speedups while running on large scale Wikipedia linkage graph.

31 Experiments The effectiveness of the incremental propinquity update(Wikipedia linkage graph). Topology and propinquity evolves with iteration.

32 Thank you for your attention

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