Non-Euclidean Geometries and Fairness Constraints in Advanced Clustering

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Date

2026-06-23

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Indian Statistical Institute

Abstract

A fundamental challenge in modern unsupervised learning is adapting classical clustering algorithms to handle complex, real-world data constraints. Traditional models often assume data resides in a flat, Euclidean space and optimize strictly for cluster cohesion, thereby failing to capture intrinsic hierarchical structures and ignoring sociotechnical demographic biases. This thesis addresses these critical limitations by extending generalized mean-shift dynamics into two novel clustering frameworks. First, to natively accommodate data with tree-like structures (e.g., taxonomies and social networks), we propose Hyperbolic Gaussian Blurring Mean Shift (HypeGBMS). By projecting data into the Poincar´e ball model and utilizing M¨obius vector space operations, HypeGBMS successfully generalizes density-based clustering to non-Euclidean manifolds. Second, to tackle algorithmic bias in noisy datasets, we introduce Fair Possibilistic C-Means (F-PCM). By embedding a group-fairness Kullback-Leibler divergence penalty into the possibilistic objective function, F-PCM explicitly enforces demographic parity without sacrificing the outlier-robust nature of possibilistic typicalities. We provide rigorous theoretical proofs for both methodologies, including convergence guarantees, statistical consistency, and optimization bounds via Majorization-Minimization. Extensive experiments on complex real-world datasets demonstrate that HypeGBMS dramatically improves cluster quality on hierarchical data, while F-PCM maintains strict fairness criteria while matching the computational efficiency of traditional baselines.

Description

This dissertation has been completed under the supervision of Dr. Swagatam Das

Keywords

Generalized Mean Shift, Hyperbolic Geometry, Poincar´e Ball, Possibilistic C-Means, Algorithmic Fairness, Demographic Parity, Non-Euclidean Clustering.

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60p.

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