Muon$^p$: Muon with Fractional Spectral Powers
Abstract: Muon is an increasingly widely used optimizer that replaces a gradient $G=USV\top$ with its polar factor $UV\top$, thereby flattening the singular spectrum. However, full flattening discards singular-value information that may matter for adaptation. We introduce Muon$p$, a Muon-style optimizer that instead uses fractional spectral-power updates $USpV\top$ for rational $p\in(0,1)$, interpolating between Muon and gradient descent. To make it practical, we prove that fractional spectral powers cannot be computed by any fixed univariate polynomial iteration, and furthermore derive low-degree odd bivariate recurrences that approximate $USpV\top$ using only matrix multiplications, preserving Muon's matrix-multiplication-only structure and compute complexity. We show that Muon$p$ maximizes the linear improvement in loss under the Schatten $q$-norm for $q=1+\frac{1}{p}$. Empirically, Muon$p$ is especially effective for finetuning: on billion-scale models, Muon$p$ improves validation perplexity and downstream task performance. We further analyze when Muon$p$ is less suitable, through the lens of spectral geometry. Our results reveal important insights on when preserving the singular spectrum can bring significant gains, and introduce a principled way to achieve them.
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