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Erschienen in:
Rho-Tau Embedding of Statistical Models Kapitel lesen Erstes Kapitel lesen

2019 | OriginalPaper | Buchkapitel

Clustering in Hilbert’s Projective Geometry: The Case Studies of the Probability Simplex and the Elliptope of Correlation Matrices

verfasst von : Frank Nielsen, Ke Sun

Erschienen in: Geometric Structures of Information

Verlag: Springer International Publishing

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Abstract

Clustering categorical distributions in the probability simplex is a fundamental task met in many applications dealing with normalized histograms. Traditionally, differential-geometric structures of the probability simplex have been used either by (i) setting the Riemannian metric tensor to the Fisher information matrix of the categorical distributions, or (ii) defining the dualistic information-geometric structure induced by a smooth dissimilarity measure, the Kullback–Leibler divergence. In this work, we introduce for this clustering task a novel computationally-friendly framework for modeling the probability simplex termed Hilbert simplex geometry. In the Hilbert simplex geometry, the distance function is described by a polytope. We discuss the pros and cons of those different statistical modelings, and benchmark experimentally these geometries for center-based k-means and k-center clusterings. Furthermore, since a canonical Hilbert metric distance can be defined on any bounded convex subset of the Euclidean space, we also consider Hilbert’s projective geometry of the elliptope of correlation matrices and study its clustering performances.

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Vorheriges Kapitel Warped Riemannian Metrics for Location-Scale Models
Nächstes Kapitel Jean-Louis Koszul and the Elementary Structures of Information Geometry
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Fußnoten
1
To contrast with this result, let us mention that infinitesimal small balls in Riemannian geometry have Euclidean ellipsoidal shapes (visualized as Tissot’s indicatrix in cartography).
 
2
For positive values a and b, the arithmetic-geometric mean inequality states that \(\sqrt{ab}\le \frac{a+b}{2}\).
 
3
Consider \(A = (1/3,1/3,1/3)\), \(B = (1/6,1/2,1/3)\), \(C = (1/6,2/3,1/6)\) and \(D = (1/3,1/2,1/6)\). Then \(2AB^2 +2BC^2 = 4.34\) but \(AC^2 + BD^2 = 3.84362411135\).
 
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Metadaten
Titel
Clustering in Hilbert’s Projective Geometry: The Case Studies of the Probability Simplex and the Elliptope of Correlation Matrices
verfasst von
Frank Nielsen
Ke Sun
Copyright-Jahr
2019
Buch
Geometric Structures of Information

Print ISBN: 978-3-030-02519-9

Electronic ISBN: 978-3-030-02520-5

Copyright-Jahr: 2019

DOI
https://doi.org/10.1007/978-3-030-02520-5_11

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