Algorithm-agnostic low-rank approximation of operator monotone matrix functions
Abstract
Low-rank approximation of a matrix function, , is an important task in computational mathematics. Most methods require direct access to , which is often considerably more expensive than accessing . Persson and Kressner (SIMAX 2023) avoid this issue for symmetric positive semidefinite matrices by proposing funNystr\"om, which first constructs a Nystr\"om approximation to using subspace iteration, and then uses the approximation to directly obtain a low-rank approximation for . They prove that the method yields a near-optimal approximation whenever is a continuous operator monotone function with . We significantly generalize the results of Persson and Kressner beyond subspace iteration. We show that if is a near-optimal low-rank Nystr\"om approximation to then is a near-optimal low-rank approximation to , independently of how is computed. Further, we show sufficient conditions for a basis to produce a near-optimal Nystr\"om approximation . We use these results to establish that many common low-rank approximation methods produce near-optimal Nystr\"om approximations to and therefore to .
Cite
@article{arxiv.2311.14023,
title = {Algorithm-agnostic low-rank approximation of operator monotone matrix functions},
author = {David Persson and Raphael A. Meyer and Christopher Musco},
journal= {arXiv preprint arXiv:2311.14023},
year = {2024}
}