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Όλ¬Έ(λ°μ¬) -- μμΈλνκ΅λνμ : 곡과λν μ»΄ν¨ν°κ³΅νλΆ, 2022. 8. λ¬Έλ΄κΈ°.Given the prevalence of mobile and IoT devices, continuous clustering against streaming data has become an essential tool of increasing importance for data analytics. Among many clustering approaches, density-based clustering has garnered much attention due to its unique advantage that it can detect clusters of an arbitrary shape when noise exists. However, when the clusters need to be updated continuously along with an evolving input dataset, a relatively high computational cost is required. Particularly, deleting data points from the clusters causes severe performance degradation.
In this dissertation, the performance limits of the incremental density-based clustering over sliding windows are addressed. Ultimately, two algorithms, DISC and DenForest, are proposed. The first algorithm DISC is an incremental density-based clustering algorithm that efficiently produces the same clustering results as DBSCAN over sliding windows. It focuses on redundancy issues that occur when updating clusters. When multiple data points are inserted or deleted individually, surrounding data points are explored and retrieved redundantly. DISC addresses these issues and improves the performance by updating multiple points in a batch. It also presents several optimization techniques. The second algorithm DenForest is an incremental density-based clustering algorithm that primarily focuses on the deletion process. Unlike previous methods that manage clusters as a graph, DenForest manages clusters as a group of spanning trees, which contributes to very efficient deletion performance. Moreover, it provides a batch-optimized technique to improve the insertion performance. To prove the effectiveness of the two algorithms, extensive evaluations were conducted, and it is demonstrated that DISC and DenForest outperform the state-of-the-art density-based clustering algorithms significantly.λͺ¨λ°μΌ λ° IoT μ₯μΉκ° λ리 보κΈλ¨μ λ°λΌ μ€νΈλ¦¬λ° λ°μ΄ν°μμμ μ§μμ μΌλ‘ ν΄λ¬μ€ν°λ§ μμ
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λ°μ΄νΈλ‘ μ΄ λ¬Έμ λ₯Ό ν΄κ²°νμ¬ μ±λ₯μ ν₯μμν€λ©° μ¬λ¬ μ΅μ ν λ°©λ²λ€μ μ μν©λλ€. λ λ²μ§Έ μκ³ λ¦¬μ¦μΈ DenForest λ μμ κ³Όμ μ μ΄μ μ λ μ μ§μ λ°λ κΈ°λ° ν΄λ¬μ€ν°λ§ μκ³ λ¦¬μ¦μ
λλ€. ν΄λ¬μ€ν°λ₯Ό κ·Έλνλ‘ κ΄λ¦¬νλ μ΄μ λ°©λ²λ€κ³Ό λ¬λ¦¬ DenForest λ ν΄λ¬μ€ν°λ₯Ό μ μ₯ νΈλ¦¬μ κ·Έλ£ΉμΌλ‘ κ΄λ¦¬ν¨μΌλ‘μ¨ ν¨μ¨μ μΈ μμ μ±λ₯μ κΈ°μ¬ν©λλ€. λμκ° λ°°μΉ μ΅μ ν κΈ°λ²μ ν΅ν΄ μ½μ
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μ¦νκΈ° μν΄ κ΄λ²μν νκ°λ₯Ό μννμμΌλ©° DISC λ° DenForest λ μ΅μ μ λ°λ κΈ°λ° ν΄λ¬μ€ν°λ§ μκ³ λ¦¬μ¦λ€λ³΄λ€ λ°μ΄λ μ±λ₯μ 보μ¬μ£Όμμ΅λλ€.1 Introduction 1
1.1 Overview of Dissertation 3
2 Related Works 7
2.1 Clustering 7
2.2 Density-Based Clustering for Static Datasets 8
2.2.1 Extension of DBSCAN 8
2.2.2 Approximation of Density-Based Clustering 9
2.2.3 Parallelization of Density-Based Clustering 10
2.3 Incremental Density-Based Clustering 10
2.3.1 Approximated Density-Based Clustering for Dynamic Datasets 11
2.4 Density-Based Clustering for Data Streams 11
2.4.1 Micro-clusters 12
2.4.2 Density-Based Clustering in Damped Window Model 12
2.4.3 Density-Based Clustering in Sliding Window Model 13
2.5 Non-Density-Based Clustering 14
2.5.1 Partitional Clustering and Hierarchical Clustering 14
2.5.2 Distribution-Based Clustering 15
2.5.3 High-Dimensional Data Clustering 15
2.5.4 Spectral Clustering 16
3 Background 17
3.1 DBSCAN 17
3.1.1 Reformulation of Density-Based Clustering 19
3.2 Incremental DBSCAN 20
3.3 Sliding Windows 22
3.3.1 Density-Based Clustering over Sliding Windows 23
3.3.2 Slow Deletion Problem 24
4 Avoiding Redundant Searches in Updating Clusters 26
4.1 The DISC Algorithm 27
4.1.1 Overview of DISC 27
4.1.2 COLLECT 29
4.1.3 CLUSTER 30
4.1.3.1 Splitting a Cluster 32
4.1.3.2 Merging Clusters 37
4.1.4 Horizontal Manner vs. Vertical Manner 38
4.2 Checking Reachability 39
4.2.1 Multi-Starter BFS 40
4.2.2 Epoch-Based Probing of R-tree Index 41
4.3 Updating Labels 43
5 Avoiding Graph Traversals in Updating Clusters 45
5.1 The DenForest Algorithm 46
5.1.1 Overview of DenForest 47
5.1.1.1 Supported Types of the Sliding Window Model 48
5.1.2 Nostalgic Core and Density-based Clusters 49
5.1.2.1 Cluster Membership of Border 51
5.1.3 DenTree 51
5.2 Operations of DenForest 54
5.2.1 Insertion 54
5.2.1.1 MST based on Link-Cut Tree 57
5.2.1.2 Time Complexity of Insert Operation 58
5.2.2 Deletion 59
5.2.2.1 Time Complexity of Delete Operation 61
5.2.3 Insertion/Deletion Examples 64
5.2.4 Cluster Membership 65
5.2.5 Batch-Optimized Update 65
5.3 Clustering Quality of DenForest 68
5.3.1 Clustering Quality for Static Data 68
5.3.2 Discussion 70
5.3.3 Replaceability 70
5.3.3.1 Nostalgic Cores and Density 71
5.3.3.2 Nostalgic Cores and Quality 72
5.3.4 1D Example 74
6 Evaluation 76
6.1 Real-World Datasets 76
6.2 Competing Methods 77
6.2.1 Exact Methods 77
6.2.2 Non-Exact Methods 77
6.3 Experimental Settings 78
6.4 Evaluation of DISC 78
6.4.1 Parameters 79
6.4.2 Baseline Evaluation 79
6.4.3 Drilled-Down Evaluation 82
6.4.3.1 Effects of Threshold Values 82
6.4.3.2 Insertions vs. Deletions 83
6.4.3.3 Range Searches 84
6.4.3.4 MS-BFS and Epoch-Based Probing 85
6.4.4 Comparison with Summarization/Approximation-Based Methods 86
6.5 Evaluation of DenForest 90
6.5.1 Parameters 90
6.5.2 Baseline Evaluation 91
6.5.3 Drilled-Down Evaluation 94
6.5.3.1 Varying Size of Window/Stride 94
6.5.3.2 Effect of Density and Distance Thresholds 95
6.5.3.3 Memory Usage 98
6.5.3.4 Clustering Quality over Sliding Windows 98
6.5.3.5 Clustering Quality under Various Density and Distance Thresholds 101
6.5.3.6 Relaxed Parameter Settings 102
6.5.4 Comparison with Summarization-Based Methods 102
7 Future Work: Extension to Varying/Relative Densities 105
8 Conclusion 107
Abstract (In Korean) 120λ°
Fast filtering and animation of large dynamic networks
Full text linkDetecting and visualizing what are the most relevant changes in an evolving
network is an open challenge in several domains. We present a fast algorithm
that filters subsets of the strongest nodes and edges representing an evolving
weighted graph and visualize it by either creating a movie, or by streaming it
to an interactive network visualization tool. The algorithm is an approximation
of exponential sliding time-window that scales linearly with the number of
interactions. We compare the algorithm against rectangular and exponential
sliding time-window methods. Our network filtering algorithm: i) captures
persistent trends in the structure of dynamic weighted networks, ii) smoothens
transitions between the snapshots of dynamic network, and iii) uses limited
memory and processor time. The algorithm is publicly available as open-source
software.Comment: 6 figures, 2 table
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