Curse of Dimensionality in Neural Network Optimization
Abstract
This paper demonstrates that when a shallow neural network with a Lipschitz continuous activation function is trained using either empirical or population risk to approximate a target function that is r times continuously differentiable on [0,1]d, the population risk may not decay at a rate faster than t-4rd-2r, where t denotes the time parameter of the gradient flow dynamics. This result highlights the presence of the curse of dimensionality in the optimization computation required to achieve a desired accuracy. Instead of analyzing parameter evolution directly, the training dynamics are examined through the evolution of the parameter distribution under the 2-Wasserstein gradient flow. Furthermore, it is established that the curse of dimensionality persists when a locally Lipschitz continuous activation function is employed, where the Lipschitz constant in [-x,x] is bounded by O(xδ) for any x ∈ R. In this scenario, the population risk is shown to decay at a rate no faster than t-(4+2δ)rd-2r. Understanding how function smoothness influences the curse of dimensionality in neural network optimization theory is an important and underexplored direction that this work aims to address.
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