Variable Decomposition for Prophet Inequalities and Optimal Ordering
Abstract
We introduce a new decomposition technique for random variables that maps a generic instance of the prophet inequalities problem to a new instance where all but a constant number of variables have a tractable structure that we refer to as -smallness. Using this technique, we make progress on several outstanding problems in the area: - We show that, even in the case of non-identical distributions, it is possible to achieve (arbitrarily close to) the optimal approximation ratio of as long as we are allowed to remove a small constant number of distributions. - We show that for frequent instances of prophet inequalities (where each distribution reoccurs some number of times), it is possible to achieve the optimal approximation ratio of (improving over the previous best-known bound of ). - We give a new, simpler proof of Kertz's optimal approximation guarantee of for prophet inequalities with i.i.d. distributions. The proof is primal-dual and simultaneously produces upper and lower bounds. - Using this decomposition in combination with a novel convex programming formulation, we construct the first Efficient PTAS for the Optimal Ordering problem.
Cite
@article{arxiv.2004.10163,
title = {Variable Decomposition for Prophet Inequalities and Optimal Ordering},
author = {Allen Liu and Renato Paes Leme and Martin Pal and Jon Schneider and Balasubramanian Sivan},
journal= {arXiv preprint arXiv:2004.10163},
year = {2020}
}