The Spectral Dimension of NTKs is Constant: A Theory of Implicit Regularization, Finite-Width Stability, and Scalable Estimation

Abstract

Modern deep networks are heavily overparameterized yet often generalize well, suggesting a form of low intrinsic complexity not reflected by parameter counts. We study this complexity at initialization through the effective rank of the Neural Tangent Kernel (NTK) Gram matrix, reff(K) = (tr(K))2/\|K\|F2. For i.i.d. data and the infinite-width NTK k, we prove a constant-limit law n∞ E[reff(Kn)] = E[k(x, x)]2 / E[k(x, x')2] =: r∞, with sub-Gaussian concentration. We further establish finite-width stability: if the finite-width NTK deviates in operator norm by Op(m-1/2) (width m), then reff changes by Op(m-1/2). We design a scalable estimator using random output probes and a CountSketch of parameter Jacobians and prove conditional unbiasedness and consistency with explicit variance bounds. On CIFAR-10 with ResNet-20/56 (widths 16/32) across n ∈ \103, 5×103, 104, 2.5×104, 5×104\, we observe reff ≈ 1.0--1.3 and slopes ≈ 0 in n, consistent with the theory, and the kernel-moment prediction closely matches fitted constants.

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