Differential geometry with extreme eigenvalues in the positive semidefinite cone
Differential geometry with extreme eigenvalues in the positive semidefinite cone
Differential geometric approaches to the analysis and processing of data in the form of symmetric positive definite (SPD) matrices have had notable successful applications to numerous fields including computer vision, medical imaging, and machine learning. The dominant geometric paradigm for such applications has consisted of a few Riemannian geometries associated with spectral computations that are costly at high scale and in high dimensions. We present a route to a scalable geometric framework for the analysis and processing of SPD-valued data based on the efficient computation of extreme generalized eigenvalues through the Hilbert and Thompson geometries of the semidefinite cone. We explore a particular geodesic space structure based on Thompson geometry in detail and establish several properties associated with this structure. Furthermore, we define a novel iterative mean of SPD matrices based on this geometry and prove its existence and uniqueness for a given finite collection of points. Finally, we state and prove a number of desirable properties that are satisfied by this mean.
math.DG, stat.CO, stat.ML
Mostajeran, Cyrus
7b47a1d5-00df-4575-8828-1e473d58f82d
Costa, Nathaël Da
2647f5a7-c5f1-46bb-bfea-2c34880816bd
Goffrier, Graham Van
18877be8-d9be-4c90-a625-8f1c11b9cb84
Sepulchre, Rodolphe
84b23c9e-f6b9-4145-873e-55c9ac4b42af
Mostajeran, Cyrus
7b47a1d5-00df-4575-8828-1e473d58f82d
Costa, Nathaël Da
2647f5a7-c5f1-46bb-bfea-2c34880816bd
Goffrier, Graham Van
18877be8-d9be-4c90-a625-8f1c11b9cb84
Sepulchre, Rodolphe
84b23c9e-f6b9-4145-873e-55c9ac4b42af
[Unknown type: UNSPECIFIED]
Abstract
Differential geometric approaches to the analysis and processing of data in the form of symmetric positive definite (SPD) matrices have had notable successful applications to numerous fields including computer vision, medical imaging, and machine learning. The dominant geometric paradigm for such applications has consisted of a few Riemannian geometries associated with spectral computations that are costly at high scale and in high dimensions. We present a route to a scalable geometric framework for the analysis and processing of SPD-valued data based on the efficient computation of extreme generalized eigenvalues through the Hilbert and Thompson geometries of the semidefinite cone. We explore a particular geodesic space structure based on Thompson geometry in detail and establish several properties associated with this structure. Furthermore, we define a novel iterative mean of SPD matrices based on this geometry and prove its existence and uniqueness for a given finite collection of points. Finally, we state and prove a number of desirable properties that are satisfied by this mean.
Text
2304.07347v1
- Author's Original
More information
Submitted date: 14 April 2023
Keywords:
math.DG, stat.CO, stat.ML
Identifiers
Local EPrints ID: 482369
URI: http://eprints.soton.ac.uk/id/eprint/482369
PURE UUID: 196cf707-3f4b-4355-b542-6d2ef5d74002
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Date deposited: 28 Sep 2023 16:38
Last modified: 18 Mar 2024 04:16
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Contributors
Author:
Cyrus Mostajeran
Author:
Nathaël Da Costa
Author:
Graham Van Goffrier
Author:
Rodolphe Sepulchre
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