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Main Authors: Karacam, Ece, Mio, Washington, Okutan, Osman Berat
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.04003
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author Karacam, Ece
Mio, Washington
Okutan, Osman Berat
author_facet Karacam, Ece
Mio, Washington
Okutan, Osman Berat
contents Datasets consisting of objects such as shapes, networks, images, or signals overlaid on such geometric objects permeate data science. Such datasets are often equipped with metrics that quantify the similarity or divergence between any pair of elements turning them into metric spaces $(X,d)$, or a metric measure space $(X,d,μ)$ if data density is also accounted for through a probability measure $μ$. This paper develops a Lipschitz geometry approach to analysis of metric measure spaces based on metric observables; that is, 1-Lipschitz scalar fields $f \colon X \to \mathbb{R}$ that provide reductions of $(X,d,μ)$ to $\mathbb{R}$ through the projected measure $f_\sharp (μ)$. Collectively, metric observables capture a wealth of information about the shape of $(X,d,μ)$ at all spatial scales. In particular, we can define stable statistics such as the observable mean and observable covariance operators $M_μ$ and $Σ_μ$, respectively. Through a maximization of variance principle, analogous to principal component analysis, $Σ_μ$ leads to an approach to vectorization, dimension reduction, and visualization of metric measure data that we term principal observable analysis. The method also yields basis functions for representation of signals on $X$ in the observable domain.
format Preprint
id arxiv_https___arxiv_org_abs_2506_04003
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Observable Covariance and Principal Observable Analysis for Data on Metric Spaces
Karacam, Ece
Mio, Washington
Okutan, Osman Berat
Statistics Theory
62R20 (Primary), 51F30, 55N31 (Secondary)
Datasets consisting of objects such as shapes, networks, images, or signals overlaid on such geometric objects permeate data science. Such datasets are often equipped with metrics that quantify the similarity or divergence between any pair of elements turning them into metric spaces $(X,d)$, or a metric measure space $(X,d,μ)$ if data density is also accounted for through a probability measure $μ$. This paper develops a Lipschitz geometry approach to analysis of metric measure spaces based on metric observables; that is, 1-Lipschitz scalar fields $f \colon X \to \mathbb{R}$ that provide reductions of $(X,d,μ)$ to $\mathbb{R}$ through the projected measure $f_\sharp (μ)$. Collectively, metric observables capture a wealth of information about the shape of $(X,d,μ)$ at all spatial scales. In particular, we can define stable statistics such as the observable mean and observable covariance operators $M_μ$ and $Σ_μ$, respectively. Through a maximization of variance principle, analogous to principal component analysis, $Σ_μ$ leads to an approach to vectorization, dimension reduction, and visualization of metric measure data that we term principal observable analysis. The method also yields basis functions for representation of signals on $X$ in the observable domain.
title Observable Covariance and Principal Observable Analysis for Data on Metric Spaces
topic Statistics Theory
62R20 (Primary), 51F30, 55N31 (Secondary)
url https://arxiv.org/abs/2506.04003