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Autori principali: Güttel, Stefan, Roy, Kaustubh
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2601.08781
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author Güttel, Stefan
Roy, Kaustubh
author_facet Güttel, Stefan
Roy, Kaustubh
contents The CLASSIX algorithm is a fast and explainable approach to data clustering. In its original form, this algorithm exploits the sorting of the data points by their first principal component to truncate the search for nearby data points, with nearness being defined in terms of the Euclidean distance. Here we extend CLASSIX to other distance metrics, including the Manhattan distance and the Tanimoto distance. Instead of principal components, we use an appropriate norm of the data vectors as the sorting criterion, combined with the triangle inequality for search termination. In the case of Tanimoto distance, a provably sharper intersection inequality is used to further boost the performance of the new algorithm. On a real-world chemical fingerprint benchmark, CLASSIX Tanimoto is about 30 times faster than the Taylor--Butina algorithm, and about 80 times faster than DBSCAN, while computing higher-quality clusters in both cases.
format Preprint
id arxiv_https___arxiv_org_abs_2601_08781
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Fast and explainable clustering in the Manhattan and Tanimoto distance
Güttel, Stefan
Roy, Kaustubh
Machine Learning
The CLASSIX algorithm is a fast and explainable approach to data clustering. In its original form, this algorithm exploits the sorting of the data points by their first principal component to truncate the search for nearby data points, with nearness being defined in terms of the Euclidean distance. Here we extend CLASSIX to other distance metrics, including the Manhattan distance and the Tanimoto distance. Instead of principal components, we use an appropriate norm of the data vectors as the sorting criterion, combined with the triangle inequality for search termination. In the case of Tanimoto distance, a provably sharper intersection inequality is used to further boost the performance of the new algorithm. On a real-world chemical fingerprint benchmark, CLASSIX Tanimoto is about 30 times faster than the Taylor--Butina algorithm, and about 80 times faster than DBSCAN, while computing higher-quality clusters in both cases.
title Fast and explainable clustering in the Manhattan and Tanimoto distance
topic Machine Learning
url https://arxiv.org/abs/2601.08781