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Abstract Supervised deep learning involves the training of neural networks with a large number N of parameters. For large enough N , in the so-called over-parametrized regime, one can essentially fit the training data points. Sparsity-based arguments would suggest that the generalization error increases as N grows past a certain threshold N * . Instead, empirical studies have shown that in the over-parametrized regime, generalization error keeps decreasing with N . We resolve this paradox through a new framework. We rely on the so-called Neural Tangent Kernel, which connects large neural nets to kernel methods, to show that the initialization causes finite-size random fluctuations of the neural net output function f N around its expectation . These affect the generalization error for classification: under natural assumptions, it decays to a plateau value in a power-law fashion ∼ N −1/2 . This description breaks down at a so-called jamming transition N = N * . At this threshold, we argue that diverges. This result leads to a plausible explanation for the cusp in test error known to occur at N * . Our results are confirmed by extensive empirical observations on the MNIST and CIFAR image datasets. Our analysis finally suggests that, given a computational envelope, the smallest generalization error is obtained using several networks of intermediate sizes, just beyond N * , and averaging their outputs.
Geiger et al. (Sat,) studied this question.