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Bibliographic Details
Main Authors: Garg, Sachin, Dereziński, Michał
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.17556
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author Garg, Sachin
Dereziński, Michał
author_facet Garg, Sachin
Dereziński, Michał
contents The Nyström method is a popular low-rank approximation technique for large matrices that arise in kernel methods and convex optimization. Yet, when the data exhibits heavy-tailed spectral decay, the effective dimension of the problem often becomes so large that even the Nyström method may be outside of our computational budget. To address this, we propose Block-Nyström, an algorithm that injects a block-diagonal structure into the Nyström method, thereby significantly reducing its computational cost while recovering strong approximation guarantees. We show that Block-Nyström can be used to construct improved preconditioners for second-order optimization, as well as to efficiently solve kernel ridge regression for statistical learning over Hilbert spaces. Our key technical insight is that, within the same computational budget, combining several smaller Nyström approximations leads to stronger tail estimates of the input spectrum than using one larger approximation. Along the way, we provide a novel recursive preconditioning scheme for efficiently inverting the Block-Nyström matrix, and provide new statistical learning bounds for a broad class of approximate kernel ridge regression solvers.
format Preprint
id arxiv_https___arxiv_org_abs_2506_17556
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Faster Low-Rank Approximation and Kernel Ridge Regression via the Block-Nyström Method
Garg, Sachin
Dereziński, Michał
Data Structures and Algorithms
Machine Learning
The Nyström method is a popular low-rank approximation technique for large matrices that arise in kernel methods and convex optimization. Yet, when the data exhibits heavy-tailed spectral decay, the effective dimension of the problem often becomes so large that even the Nyström method may be outside of our computational budget. To address this, we propose Block-Nyström, an algorithm that injects a block-diagonal structure into the Nyström method, thereby significantly reducing its computational cost while recovering strong approximation guarantees. We show that Block-Nyström can be used to construct improved preconditioners for second-order optimization, as well as to efficiently solve kernel ridge regression for statistical learning over Hilbert spaces. Our key technical insight is that, within the same computational budget, combining several smaller Nyström approximations leads to stronger tail estimates of the input spectrum than using one larger approximation. Along the way, we provide a novel recursive preconditioning scheme for efficiently inverting the Block-Nyström matrix, and provide new statistical learning bounds for a broad class of approximate kernel ridge regression solvers.
title Faster Low-Rank Approximation and Kernel Ridge Regression via the Block-Nyström Method
topic Data Structures and Algorithms
Machine Learning
url https://arxiv.org/abs/2506.17556