Explicit and Non-asymptotic Query Complexities of Rank-Based Zeroth-order Algorithms on Smooth Functions
Abstract
Rank-based zeroth-order (ZO) optimization -- which relies only on the ordering of function evaluations -- offers strong robustness to noise and monotone transformations, and underlies many successful algorithms such as CMA-ES, natural evolution strategies, and rank-based genetic algorithms. Despite its widespread use, the theoretical understanding of rank-based ZO methods remains limited: existing analyses provide only asymptotic insights and do not yield explicit convergence rates for algorithms selecting the top-k directions. This work closes this gap by analyzing a simple rank-based ZO algorithm and establishing the first explicit, and non-asymptotic query complexities. For a d-dimension problem, if the function is L-smooth and μ-strongly convex, the algorithm achieves O\!(dLμ\!dLμδ\!1) to find an -suboptimal solution, and for smooth nonconvex objectives it reaches O\!(dL\!1). Notation (·) hides constant terms and O(·) hides extra 1 term. These query complexities hold with a probability at least 1-δ with 0<δ<1. The analysis in this paper is novel and avoids classical drift and information-geometric techniques. Our analysis offers new insight into why rank-based heuristics lead to efficient ZO optimization.
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