Porovnat metody
Prohlédněte si vybrané metody vedle sebe; řádky, které se liší, jsou zvýrazněny.
| Robustní HDBSCAN× | DBSCAN× | HDBSCAN× | K-means Shlukování× | Spektrální shlukování× | |
|---|---|---|---|---|---|
| Obor | Strojové učení | Strojové učení | Strojové učení | Strojové učení | Strojové učení |
| Rodina | Machine learning | Machine learning | Machine learning | Machine learning | Machine learning |
| Rok vzniku≠ | 2015 | 1996 | 2013 | 1967 (formalized 1982) | 2002 |
| Tvůrce≠ | Campello, R.J.G.B.; Moulavi, D.; Zimek, A.; Sander, J. | Ester, M., Kriegel, H.-P., Sander, J. & Xu, X. | Campello, R. J. G. B.; Moulavi, D.; Sander, J. | MacQueen, J. B.; Lloyd, S. P. | Ng, A. Y.; Jordan, M. I.; Weiss, Y. |
| Typ≠ | Hierarchical density-based clustering with robust single-linkage | Density-based clustering algorithm | Hierarchical density-based clustering | Partitional clustering | Graph-based clustering (spectral method) |
| Původní zdroj≠ | Campello, R.J.G.B., Moulavi, D., Zimek, A. & Sander, J. (2015). Hierarchical Density Estimates for Data Clustering, Visualization, and Outlier Detection. ACM Transactions on Knowledge Discovery from Data, 10(1), 5. DOI ↗ | Ester, M., Kriegel, H.-P., Sander, J. & Xu, X. (1996). A Density-Based Algorithm for Discovering Clusters in Large Spatial Databases with Noise. Proceedings of the 2nd KDD, 226–231. link ↗ | Campello, R. J. G. B., Moulavi, D., & Sander, J. (2013). Density-Based Clustering Based on Hierarchical Density Estimates. In J. Pei et al. (Eds.), Advances in Knowledge Discovery and Data Mining. PAKDD 2013. Lecture Notes in Computer Science, vol. 7819 (pp. 160–172). Springer, Berlin, Heidelberg. DOI ↗ | Lloyd, S. P. (1982). Least squares quantization in PCM. IEEE Transactions on Information Theory, 28(2), 129–137. DOI ↗ | Ng, A. Y., Jordan, M. I., & Weiss, Y. (2002). On Spectral Clustering: Analysis and an Algorithm. Advances in Neural Information Processing Systems, 14, 849–856. link ↗ |
| Další názvy≠ | HDBSCAN*, Robust HDBSCAN*, robust hierarchical density clustering, robust single-linkage HDBSCAN | DBSCAN Kümeleme, density-based clustering, density-based spatial clustering | HDBSCAN, Hierarchical DBSCAN, hierarchical density-based clustering, HDBSCAN* | k-means clustering, Lloyd's algorithm, k-means partitioning, hard k-means | NJW spectral clustering, graph Laplacian clustering, normalized spectral clustering, spectral graph clustering |
| Příbuzné≠ | 4 | 3 | 3 | 4 | 5 |
| Shrnutí≠ | Robust HDBSCAN (HDBSCAN*) extends the original HDBSCAN algorithm with a robust single-linkage framework that handles noise, outliers, and clusters of varying densities more reliably. Introduced by Campello et al. (2015), it converts any density-based hierarchy into a stable flat clustering while explicitly modeling noise points — without requiring the user to pre-specify the number of clusters. | DBSCAN is a density-based clustering algorithm, introduced by Ester, Kriegel, Sander and Xu in 1996, that groups together points lying in dense regions and flags points in sparse regions as noise. It is effective on noisy data and on clusters of irregular, non-spherical shapes. | HDBSCAN (Hierarchical Density-Based Spatial Clustering of Applications with Noise) is a density-based clustering algorithm introduced by Campello, Moulavi, and Sander in 2013. It extends DBSCAN by building a full hierarchy of density-based clusters across all density scales and then extracting a stable flat partition, making it robust to datasets where cluster densities vary substantially across regions. | K-means is a classic unsupervised partitional clustering algorithm that divides a dataset into K non-overlapping groups by iteratively assigning each observation to its nearest centroid and updating centroids as the mean of their assigned points. It is one of the most widely used exploratory tools in machine learning and data analysis. | Spectral Clustering is a graph-based unsupervised learning algorithm, formalized by Ng, Jordan, and Weiss in 2002, that maps data points into a low-dimensional eigenspace derived from the similarity graph's Laplacian before applying k-means. This spectral embedding makes it possible to recover clusters of arbitrary shape — rings, crescents, interleaved spirals — that Euclidean distance-based methods consistently fail to separate. |
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