Learning a Single Neuron Robustly to Distributional Shifts and Adversarial Label Noise
Abstract
We study the problem of learning a single neuron with respect to the L22-loss in the presence of adversarial distribution shifts, where the labels can be arbitrary, and the goal is to find a ``best-fit'' function. More precisely, given training samples from a reference distribution p0, the goal is to approximate the vector w* which minimizes the squared loss with respect to the worst-case distribution that is close in 2-divergence to p0. We design a computationally efficient algorithm that recovers a vector w satisfying Ep* (σ(w · x) - y)2 ≤ C \, Ep* (σ(w* · x) - y)2 + ε, where C>1 is a dimension-independent constant and (w*, p*) is the witness attaining the min-max risk w~:~\|w\| ≤ W p E(x, y) p (σ(w · x) - y)2 - 2(p, p0). Our algorithm follows a primal-dual framework and is designed by directly bounding the risk with respect to the original, nonconvex L22 loss. From an optimization standpoint, our work opens new avenues for the design of primal-dual algorithms under structured nonconvexity.
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