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arxiv: 2505.02281 · v3 · pith:3JY4EUYWnew · submitted 2025-05-04 · 🧮 math.OC · cs.AI· cs.LG· cs.NA· math.NA

Minimisation of Quasar-Convex Functions Using Random Zeroth-Order Oracles

classification 🧮 math.OC cs.AIcs.LGcs.NAmath.NA
keywords functionsquasar-convexunconstrainedalgorithmcomplexityconstrainedconvergenceglobal
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This paper explores the performance of a random Gaussian smoothing zeroth-order (ZO) scheme for minimising quasar-convex (QC) and strongly quasar-convex (SQC) functions in both unconstrained and constrained settings. For the unconstrained problem, we establish the ZO algorithm's convergence to a global minimum along with its complexity when applied to both QC and SQC functions. For the constrained problem, we introduce the new notion of proximal-quasar-convexity and prove analogous results to the unconstrained case. Specifically, we derive complexity bounds and prove convergence of the algorithm to a neighbourhood of a global minimum whose size can be controlled under a variance reduction scheme. Beyond the theoretical guarantees, we demonstrate the practical implications of our results on several machine learning problems where quasar-convexity naturally arises, including linear dynamical system identification and generalised linear models.

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Cited by 2 Pith papers

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  1. From Cursed to Competitive: Closing the ZO-FO Gap via Input-to-State Stability

    math.OC 2026-04 unverdicted novelty 6.0

    Zeroth-order methods achieve the same expected convergence rate as first-order methods without extra dimension dependence by treating them as input-to-state stable systems with controllable perturbations.

  2. Robust Learning Meets Quasar-Convex Optimization: Inexact High-Order Proximal-Point Methods

    math.OC 2026-05 unverdicted novelty 5.0

    Robust learning problems are formulated as quasar-convex optimization, and HiPPA is proposed as an inexact high-order proximal method with global and superlinear convergence guarantees.