Paper Detail

LoRA-Muon: Spectral Steepest Descent on the Low-Rank Manifold

Franz Louis Cesista, Katherine Crowson, Cédric Simal, Stella Biderman

arxiv Score 5.3

Published 2026-06-11 · First seen 2026-06-13

General AI

Abstract

Low-Rank Adaptation (LoRA) significantly reduces compute and memory costs for finetuning Deep Learning models but is often harder to tune than dense training: when using factor-wise optimizers such as AdamW, it is sensitive to initialization choices, its optimal learning rates transfer poorly across ranks, and it often fails to beat dense baselines. We derive LoRA-Muon by applying the Muon optimizer's spectral steepest-descent rule to the low-rank setting. Along with our split weight-decay rule, our main claim is that LoRA-Muon is a good low-rank proxy for full-rank Muon and Shampoo-family optimizers. Its optimal learning rates transfer across rank, width, depth, and factor-rescaling. In our compute-matched TinyShakespeare study, a rank-$2$ proxy recovers the dense best tested learning rate, and a rank-$32$ LoRA-Muon run attains lower mean validation loss than the dense baseline in the seed-averaged sweep. We further show that the Spectron optimizer depends on arbitrary factor scaling, so it would likely be a poor fit when finetuning starts from badly imbalanced factors, and that LoRA-RITE's simplified QR-coordinate core implements the same spectral update. LoRA-Muon computes that update without QR-decomposition and avoids storing second moments, making it more accelerator-friendly and memory-efficient.

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BibTeX

@article{cesista2026lora,
  title = {LoRA-Muon: Spectral Steepest Descent on the Low-Rank Manifold},
  author = {Franz Louis Cesista and Katherine Crowson and Cédric Simal and Stella Biderman},
  year = {2026},
  abstract = {Low-Rank Adaptation (LoRA) significantly reduces compute and memory costs for finetuning Deep Learning models but is often harder to tune than dense training: when using factor-wise optimizers such as AdamW, it is sensitive to initialization choices, its optimal learning rates transfer poorly across ranks, and it often fails to beat dense baselines. We derive LoRA-Muon by applying the Muon optimizer's spectral steepest-descent rule to the low-rank setting. Along with our split weight-decay rule,},
  url = {https://arxiv.org/abs/2606.12921},
  keywords = {cs.LG, cs.AI},
  eprint = {2606.12921},
  archiveprefix = {arXiv},
}

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