Tight Lower Bounds and Optimal Algorithms for Stochastic Nonconvex Optimization with Heavy-Tailed Noise
Abstract
We study stochastic nonconvex optimization under heavy-tailed noise. In this setting, the stochastic gradients only have bounded p-th central moment (p-BCM) for some p ∈ (1,2]. Building on the foundational work of Arjevani et al. (2022) in stochastic optimization, we establish tight sample complexity lower bounds for all first-order methods under relaxed mean-squared smoothness (q-WAS) and δ-similarity ((q, δ)-S) assumptions, allowing any exponent q ∈ [1,2] instead of the standard q = 2. These results substantially broaden the scope of existing lower bounds. To complement them, we show that Normalized Stochastic Gradient Descent with Momentum Variance Reduction (NSGD-MVR), a known algorithm, matches these bounds in expectation. Beyond expectation guarantees, we introduce a new algorithm, Double-Clipped NSGD-MVR, which allows the derivation of high-probability convergence rates under weaker assumptions than in previous works. Finally, for second-order methods with stochastic Hessians satisfying bounded q-th central moment assumptions for some exponent q ∈ [1, 2] (allowing q ≠ p), we establish sharper lower bounds than previous works while improving over Sadiev et al. (2025) (where only p = q is considered) and yielding stronger convergence exponents. Together, these results provide a nearly complete complexity characterization of stochastic nonconvex optimization in heavy-tailed regimes.
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