English

Competition Versus Complexity in Multiple-Selection Prophet Inequalities

Computer Science and Game Theory 2026-02-25 v1 Optimization and Control

Abstract

Competition complexity formalizes a compelling intuition: rather than refining the mechanism, how much additional competition is sufficient for a simple mechanism to compete with an optimal one? We begin the study of this question in multi-unit pricing for welfare maximization using prophet inequalities. An online decision-maker observes mkm \geq k nonnegative values drawn independently from a known distribution, may select up to kk of them, and aims to maximize the expected sum of selected values. The benchmark is a prophet who observes a sequence of length nkn \geq k and selects the kk largest values. We focus on the widely adopted class of single-threshold algorithms and fully characterize their (1ε)(1-\varepsilon)-competition complexity. Notably, our results reveal a sharp competition-induced phase transition: in the absence of competition, single-threshold algorithms are fundamentally limited to a 11/2kπ1-1/\sqrt{2k\pi} fraction of the prophet value, whereas even a 1%1\% multiplicative increase beyond nn observations suffices to achieve a 1exp(Θ(k))1-\exp(-\Theta(k)) fraction. Another notable result happens when k=1k=1: we show that the (1ε)(1-\varepsilon)-competition complexity is exactly ln(1/ε)\ln(1/\varepsilon), fully resolving an open question by Brustle et al. [Math. Oper. Res. 2024]. Our analysis is based on infinite-dimensional linear programming and duality arguments.

Keywords

Cite

@article{arxiv.2602.20398,
  title  = {Competition Versus Complexity in Multiple-Selection Prophet Inequalities},
  author = {Eugenio Cruz-Ossa and Sebastian Perez-Salazar and Victor Verdugo},
  journal= {arXiv preprint arXiv:2602.20398},
  year   = {2026}
}
R2 v1 2026-07-01T10:48:55.188Z