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Power-Law Spectrum of the Random Feature Model

Published 15 Mar 2026 in stat.ML, cs.LG, and math.PR | (2603.14578v1)

Abstract: Scaling laws for neural networks, in which the loss decays as a power-law in the number of parameters, data, and compute, depend fundamentally on the spectral structure of the data covariance, with power-law eigenvalue decay appearing ubiquitously in vision and language tasks. A central question is whether this spectral structure is preserved or destroyed when data passes through the basic building block of a neural network: a random linear projection followed by a nonlinear activation. We study this question for the random feature model: given data $x \sim N(0,H)\in \mathbb{R}v$ where $H$ has $α$-power-law spectrum ($λj(H ) \asymp j{-α}$, $α> 1$), a Gaussian sketch matrix $W \in \mathbb{R}{v\times d}$, and an entrywise monomial $f(y) = y{p}$, we characterize the eigenvalues of the population random-feature covariance $\mathbb{E}{x }[\frac{1}{d}f(W\top x ){\otimes 2}]$. We prove matching upper and lower bounds: for all $1 \leq j \leq c_1 d \log{-(p+1)}(d)$, the $j$-th eigenvalue is of order $\left(\log{p-1}(j+1)/j\right)α$. For $ c_1 d \log{-(p+1)}(d)\leq j\leq d$, the $j$-th eigenvalue is of order $j{-α}$ up to a polylog factor. That is, the power-law exponent $α$ is inherited exactly from the input covariance, modified only by a logarithmic correction that depends on the monomial degree $p$. The proof combines a dyadic head-tail decomposition with Wick chaos expansions for higher-order monomials and random matrix concentration inequalities.

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