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Nearly Tight Sample Complexity for Matroid Online Contention Resolution

Data Structures and Algorithms 2025-07-15 v1 Discrete Mathematics Computer Science and Game Theory

Abstract

Due to their numerous applications, in particular in Mechanism Design, Prophet Inequalities have experienced a surge of interest. They describe competitive ratios for basic stopping time problems where random variables get revealed sequentially. A key drawback in the classical setting is the assumption of full distributional knowledge of the involved random variables, which is often unrealistic. A natural way to address this is via sample-based approaches, where only a limited number of samples from the distribution of each random variable is available. Recently, Fu, Lu, Gavin Tang, Wu, Wu, and Zhang (2024) showed that sample-based Online Contention Resolution Schemes (OCRS) are a powerful tool to obtain sample-based Prophet Inequalities. They presented the first sample-based OCRS for matroid constraints, which is a heavily studied constraint family in this context, as it captures many interesting settings. This allowed them to get the first sample-based Matroid Prophet Inequality, using O(log4n)O(\log^4 n) many samples (per random variable), where nn is the number of random variables, while obtaining a constant competitiveness of 14ε\frac{1}{4}-\varepsilon. We present a nearly optimal sample-based OCRS for matroid constraints, which uses only O(logρlog2logρ)O(\log \rho \cdot \log^2\log\rho) many samples, almost matching a known lower bound of Ω(logρ)\Omega(\log \rho), where ρn\rho \leq n is the rank of the matroid. Through the above-mentioned connection to Prophet Inequalities, this yields a sample-based Matroid Prophet Inequality using only O(logn+logρlog2logρ)O(\log n + \log\rho \cdot \log^2\log\rho) many samples, and matching the competitiveness of 14ε\frac{1}{4}-\varepsilon, which is the best known competitiveness for the considered almighty adversary setting even when the distributions are fully known.

Keywords

Cite

@article{arxiv.2507.09507,
  title  = {Nearly Tight Sample Complexity for Matroid Online Contention Resolution},
  author = {Moran Feldman and Ola Svensson and Rico Zenklusen},
  journal= {arXiv preprint arXiv:2507.09507},
  year   = {2025}
}

Comments

24 pages

R2 v1 2026-07-01T03:58:23.068Z