TSF-DBSCAN: a Novel Fuzzy Density-based Approach for Clustering Unbounded Data Streams. Bechini, A., Marcelloni, F., & Renda, A. IEEE Transactions on Fuzzy Systems, 2020. Conference Name: IEEE Transactions on Fuzzy Systems
doi  abstract   bibtex   
In recent years, several clustering algorithms have been proposed with the aim of mining knowledge from streams of data generated at a high speed by a variety of hardware platforms and software applications. Among these algorithms, density-based approaches have proved to be particularly attractive, thanks to their capability of handling outliers and capturing clusters with arbitrary shapes. The streaming setting poses additional challenges that need to be addressed as well: data streams are potentially unbounded and affected by concept drift, i.e. a modification over time in the underlying data generation process. In this paper, we propose Temporal Streaming Fuzzy DBSCAN (TSF-DBSCAN), a novel fuzzy clustering algorithm for streaming data. TSF-DBSCAN is an extension of the well-known DBSCAN algorithm, one of the most popular density-based clustering approaches. Fuzziness is introduced in TSF-DBSCAN to model the uncertainty about the distance threshold that defines the neighborhood of an object. As a consequence, TSF-DBSCAN identifies clusters with fuzzy overlapping borders. A fading model, which makes objects less relevant as they become more remote in time, endows TSF-DBSCAN with the capability of adapting to evolving data streams. The integration of the model in a two-stage approach ensures computational and memory efficiency: during the online stage continuously arriving objects are organized in proper data structures that are later exploited in the offline stage to determine a fine-grained partition. An extensive experimental analysis on synthetic and real world datasets shows that TSF-DBSCAN yields competitive performance when compared to other clustering algorithms recently proposed for streaming data.
@article{bechini_tsf-dbscan_2020,
	title = {{TSF}-{DBSCAN}: a {Novel} {Fuzzy} {Density}-based {Approach} for {Clustering} {Unbounded} {Data} {Streams}},
	issn = {1941-0034},
	shorttitle = {{TSF}-{DBSCAN}},
	doi = {10.1109/TFUZZ.2020.3042645},
	abstract = {In recent years, several clustering algorithms have been proposed with the aim of mining knowledge from streams of data generated at a high speed by a variety of hardware platforms and software applications. Among these algorithms, density-based approaches have proved to be particularly attractive, thanks to their capability of handling outliers and capturing clusters with arbitrary shapes. The streaming setting poses additional challenges that need to be addressed as well: data streams are potentially unbounded and affected by concept drift, i.e. a modification over time in the underlying data generation process. In this paper, we propose Temporal Streaming Fuzzy DBSCAN (TSF-DBSCAN), a novel fuzzy clustering algorithm for streaming data. TSF-DBSCAN is an extension of the well-known DBSCAN algorithm, one of the most popular density-based clustering approaches. Fuzziness is introduced in TSF-DBSCAN to model the uncertainty about the distance threshold that defines the neighborhood of an object. As a consequence, TSF-DBSCAN identifies clusters with fuzzy overlapping borders. A fading model, which makes objects less relevant as they become more remote in time, endows TSF-DBSCAN with the capability of adapting to evolving data streams. The integration of the model in a two-stage approach ensures computational and memory efficiency: during the online stage continuously arriving objects are organized in proper data structures that are later exploited in the offline stage to determine a fine-grained partition. An extensive experimental analysis on synthetic and real world datasets shows that TSF-DBSCAN yields competitive performance when compared to other clustering algorithms recently proposed for streaming data.},
	journal = {IEEE Transactions on Fuzzy Systems},
	author = {Bechini, Alessio and Marcelloni, Francesco and Renda, Alessandro},
	year = {2020},
	note = {Conference Name: IEEE Transactions on Fuzzy Systems},
	keywords = {Adaptation models, Clustering algorithms, DBSCAN, Data models, Data stream clustering, Fading channels, Partitioning algorithms, Proposals, Shape, density-based clustering, fuzzy clustering, streaming data},
	pages = {1--1},
}
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