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Main Authors: Robinett, Ryan A., Orecchia, Lorenzo, Riesenfeld, Samantha J.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.12678
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author Robinett, Ryan A.
Orecchia, Lorenzo
Riesenfeld, Samantha J.
author_facet Robinett, Ryan A.
Orecchia, Lorenzo
Riesenfeld, Samantha J.
contents We present a framework for efficiently approximating differential-geometric primitives on arbitrary manifolds via construction of an atlas graph representation, which leverages the canonical characterization of a manifold as a finite collection, or atlas, of overlapping coordinate charts. We first show the utility of this framework in a setting where the manifold is expressed in closed form, specifically, a runtime advantage, compared with state-of-the-art approaches, for first-order optimization over the Grassmann manifold. Moreover, using point cloud data for which a complex manifold structure was previously established, i.e., high-contrast image patches, we show that an atlas graph with the correct geometry can be directly learned from the point cloud. Finally, we demonstrate that learning an atlas graph enables downstream key machine learning tasks. In particular, we implement a Riemannian generalization of support vector machines that uses the learned atlas graph to approximate complex differential-geometric primitives, including Riemannian logarithms and vector transports. These settings suggest the potential of this framework for even more complex settings, where ambient dimension and noise levels may be much higher.
format Preprint
id arxiv_https___arxiv_org_abs_2501_12678
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Manifold learning and optimization using tangent space proxies
Robinett, Ryan A.
Orecchia, Lorenzo
Riesenfeld, Samantha J.
Machine Learning
Optimization and Control
I.5.0
We present a framework for efficiently approximating differential-geometric primitives on arbitrary manifolds via construction of an atlas graph representation, which leverages the canonical characterization of a manifold as a finite collection, or atlas, of overlapping coordinate charts. We first show the utility of this framework in a setting where the manifold is expressed in closed form, specifically, a runtime advantage, compared with state-of-the-art approaches, for first-order optimization over the Grassmann manifold. Moreover, using point cloud data for which a complex manifold structure was previously established, i.e., high-contrast image patches, we show that an atlas graph with the correct geometry can be directly learned from the point cloud. Finally, we demonstrate that learning an atlas graph enables downstream key machine learning tasks. In particular, we implement a Riemannian generalization of support vector machines that uses the learned atlas graph to approximate complex differential-geometric primitives, including Riemannian logarithms and vector transports. These settings suggest the potential of this framework for even more complex settings, where ambient dimension and noise levels may be much higher.
title Manifold learning and optimization using tangent space proxies
topic Machine Learning
Optimization and Control
I.5.0
url https://arxiv.org/abs/2501.12678