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Auteurs principaux: Wu, Fangzhou, Shah, Rikhav, Silwal, Sandeep, Zhang, Qiuyi
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2605.17109
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author Wu, Fangzhou
Shah, Rikhav
Silwal, Sandeep
Zhang, Qiuyi
author_facet Wu, Fangzhou
Shah, Rikhav
Silwal, Sandeep
Zhang, Qiuyi
contents In recent years, Muon has emerged as the dominant method for training large language models, and transformers more broadly. The essential difference, when compared to standard gradient descent methods, is to replace the usual update matrix $M=UΣV^\top$ with its polar factor $UV^\top$. In this work, we consider a class of Muon-like updates, where we replace the update $M$ with $UΣ^p V^\top$ for some parameter $p$. We call this a "spectral-shaping" operation, and develop a theory of how to pick $p$ which depends on (a) local curvature of the loss function, (b) noise stemming from stochastic gradients and label noise, and (c) training stage. Our theory and experimentation reveal a previously overlooked behavior: positive $p$ helps early by emphasizing high-curvature directions and accelerating signal contraction, while mildly negative $p$ helps later by reallocating update strength toward low-curvature directions that still contain useful training signals. Building on the insight, we propose DynMuon, an efficient dynamic spectral shaping method that schedules $p$ from positive to mildly negative over training. Extensive experiments across model sizes, architectures, and training settings show that DynMuon consistently achieves lower validation loss than Muon, while requiring 10.6-26.5% fewer steps to reach the same target loss. Our code is available at https://github.com/fzwark/DynMuon.
format Preprint
id arxiv_https___arxiv_org_abs_2605_17109
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle DynMuon: A Dynamic Spectral Shaping View of Muon
Wu, Fangzhou
Shah, Rikhav
Silwal, Sandeep
Zhang, Qiuyi
Machine Learning
Artificial Intelligence
In recent years, Muon has emerged as the dominant method for training large language models, and transformers more broadly. The essential difference, when compared to standard gradient descent methods, is to replace the usual update matrix $M=UΣV^\top$ with its polar factor $UV^\top$. In this work, we consider a class of Muon-like updates, where we replace the update $M$ with $UΣ^p V^\top$ for some parameter $p$. We call this a "spectral-shaping" operation, and develop a theory of how to pick $p$ which depends on (a) local curvature of the loss function, (b) noise stemming from stochastic gradients and label noise, and (c) training stage. Our theory and experimentation reveal a previously overlooked behavior: positive $p$ helps early by emphasizing high-curvature directions and accelerating signal contraction, while mildly negative $p$ helps later by reallocating update strength toward low-curvature directions that still contain useful training signals. Building on the insight, we propose DynMuon, an efficient dynamic spectral shaping method that schedules $p$ from positive to mildly negative over training. Extensive experiments across model sizes, architectures, and training settings show that DynMuon consistently achieves lower validation loss than Muon, while requiring 10.6-26.5% fewer steps to reach the same target loss. Our code is available at https://github.com/fzwark/DynMuon.
title DynMuon: A Dynamic Spectral Shaping View of Muon
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2605.17109