Subgradient Methods for Nonsmooth Convex Functions with Adversarial Errors

Abstract

We consider minimizing nonsmooth convex functions with bounded subgradients. However, instead of directly observing a subgradient at every step k∈ [0, …, N-1], we assume that the optimizer receives an adversarially corrupted subgradient. The adversary's power is limited to a finite corruption budget, but allows the adversary to strategically time its perturbations. We show that the classical averaged subgradient descent method, which is optimal in the noiseless case, has worst-case performance that deteriorates quadratically with the corruption budget. Using performance optimization programming, (i) we construct and analyze the performance of three novel subgradient descent methods, and (ii) propose a novel lower bound on the worst-case suboptimality gap of any first-order method satisfying a mild cone condition proposed by Fatkhullin et al. (2025). The worst-case performance of each of our methods degrades only linearly with the corruption budget. Furthermore, we show that the relative difference between their worst-case suboptimality gap and our lower bound decays as O((N)/N), so that all three proposed subgradient descent methods are near-optimal. Our methods achieve such near-optimal performance without a need for momentum or averaging. This suggests that these techniques are not necessary in this context, which is in line with recent results by Zamani and Glineur (2025).

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