Mike Nguyen, Nicole Mücke
Published 2023-09-14Version 1
We analyze the generalization properties of two-layer neural networks in the neural tangent kernel (NTK) regime, trained with gradient descent (GD). For early stopped GD we derive fast rates of convergence that are known to be minimax optimal in the framework of non-parametric regression in reproducing kernel Hilbert spaces. On our way, we precisely keep track of the number of hidden neurons required for generalization and improve over existing results. We further show that the weights during training remain in a vicinity around initialization, the radius being dependent on structural assumptions such as degree of smoothness of the regression function and eigenvalue decay of the integral operator associated to the NTK.
Stability & Generalisation of Gradient Descent for Shallow Neural Networks without the Neural Tangent Kernel
The Neural Tangent Kernel in High Dimensions: Triple Descent and a Multi-Scale Theory of Generalization
Beyond the Universal Law of Robustness: Sharper Laws for Random Features and Neural Tangent Kernels
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