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Main Authors: Alcala, James, Chow, Yat Tin, Sunkula, Mahesh
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.07290
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author Alcala, James
Chow, Yat Tin
Sunkula, Mahesh
author_facet Alcala, James
Chow, Yat Tin
Sunkula, Mahesh
contents Since their introduction, anchoring methods in extragradient-type saddlepoint problems have inspired a flurry of research due to their ability to provide order-optimal rates of accelerated convergence in very general problem settings. Such guarantees are especially important as researchers consider problems in artificial intelligence (AI) and machine learning (ML), where large problem sizes demand immense computational power. Much of the more recent works explore theoretical aspects of this new acceleration framework, connecting it to existing methods and order-optimal convergence rates from the literature. However, in practice introducing stochastic oracles allows for more computational efficiency given the size of many modern optimization problems. To this end, this work provides the moving anchor variants [1] of the original anchoring algorithms [36] with stochastic implementations and robust analyses to bridge the gap from deterministic to stochastic algorithm settings. In particular, we demonstrate that an accelerated convergence rate theory for stochastic oracles also exists for our moving anchor scheme, itself a generalization of the original fixed anchor algorithms, and provide numerical results that validate our theoretical findings. We also develop a tentative moving anchor Popov scheme based on the work in [33], with promising numerical results pointing towards an as-of-yet uncovered general convergence theory for such methods.
format Preprint
id arxiv_https___arxiv_org_abs_2506_07290
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Stochastic Moving Anchor Algorithms and a Popov's Scheme with Moving Anchor
Alcala, James
Chow, Yat Tin
Sunkula, Mahesh
Optimization and Control
90C47
Since their introduction, anchoring methods in extragradient-type saddlepoint problems have inspired a flurry of research due to their ability to provide order-optimal rates of accelerated convergence in very general problem settings. Such guarantees are especially important as researchers consider problems in artificial intelligence (AI) and machine learning (ML), where large problem sizes demand immense computational power. Much of the more recent works explore theoretical aspects of this new acceleration framework, connecting it to existing methods and order-optimal convergence rates from the literature. However, in practice introducing stochastic oracles allows for more computational efficiency given the size of many modern optimization problems. To this end, this work provides the moving anchor variants [1] of the original anchoring algorithms [36] with stochastic implementations and robust analyses to bridge the gap from deterministic to stochastic algorithm settings. In particular, we demonstrate that an accelerated convergence rate theory for stochastic oracles also exists for our moving anchor scheme, itself a generalization of the original fixed anchor algorithms, and provide numerical results that validate our theoretical findings. We also develop a tentative moving anchor Popov scheme based on the work in [33], with promising numerical results pointing towards an as-of-yet uncovered general convergence theory for such methods.
title Stochastic Moving Anchor Algorithms and a Popov's Scheme with Moving Anchor
topic Optimization and Control
90C47
url https://arxiv.org/abs/2506.07290