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Main Authors: Dreveton, Maximilien, Gözeten, Alperen, Grossglauser, Matthias, Thiran, Patrick
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2402.15432
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author Dreveton, Maximilien
Gözeten, Alperen
Grossglauser, Matthias
Thiran, Patrick
author_facet Dreveton, Maximilien
Gözeten, Alperen
Grossglauser, Matthias
Thiran, Patrick
contents Clustering is a pivotal challenge in unsupervised machine learning and is often investigated through the lens of mixture models. The optimal error rate for recovering cluster labels in Gaussian and sub-Gaussian mixture models involves ad hoc signal-to-noise ratios. Simple iterative algorithms, such as Lloyd's algorithm, attain this optimal error rate. In this paper, we first establish a universal lower bound for the error rate in clustering any mixture model, expressed through a Chernoff divergence, a more versatile measure of model information than signal-to-noise ratios. We then demonstrate that iterative algorithms attain this lower bound in mixture models with sub-exponential tails, notably emphasizing location-scale mixtures featuring Laplace-distributed errors. Additionally, for datasets better modelled by Poisson or Negative Binomial mixtures, we study mixture models whose distributions belong to an exponential family. In such mixtures, we establish that Bregman hard clustering, a variant of Lloyd's algorithm employing a Bregman divergence, is rate optimal.
format Preprint
id arxiv_https___arxiv_org_abs_2402_15432
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Universal Lower Bounds and Optimal Rates: Achieving Minimax Clustering Error in Sub-Exponential Mixture Models
Dreveton, Maximilien
Gözeten, Alperen
Grossglauser, Matthias
Thiran, Patrick
Statistics Theory
Machine Learning
62H30, 62F12, 62B10
Clustering is a pivotal challenge in unsupervised machine learning and is often investigated through the lens of mixture models. The optimal error rate for recovering cluster labels in Gaussian and sub-Gaussian mixture models involves ad hoc signal-to-noise ratios. Simple iterative algorithms, such as Lloyd's algorithm, attain this optimal error rate. In this paper, we first establish a universal lower bound for the error rate in clustering any mixture model, expressed through a Chernoff divergence, a more versatile measure of model information than signal-to-noise ratios. We then demonstrate that iterative algorithms attain this lower bound in mixture models with sub-exponential tails, notably emphasizing location-scale mixtures featuring Laplace-distributed errors. Additionally, for datasets better modelled by Poisson or Negative Binomial mixtures, we study mixture models whose distributions belong to an exponential family. In such mixtures, we establish that Bregman hard clustering, a variant of Lloyd's algorithm employing a Bregman divergence, is rate optimal.
title Universal Lower Bounds and Optimal Rates: Achieving Minimax Clustering Error in Sub-Exponential Mixture Models
topic Statistics Theory
Machine Learning
62H30, 62F12, 62B10
url https://arxiv.org/abs/2402.15432