Constant-competitiveness for random assignment Matroid secretary without knowing the Matroid.

IF 2.2 2区数学 Q2 COMPUTER SCIENCE, SOFTWARE ENGINEERING Mathematical Programming Pub Date : 2025-01-01 Epub Date: 2025-01-15 DOI:10.1007/s10107-024-02177-x

Richard Santiago, Ivan Sergeev, Rico Zenklusen

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Abstract

The Matroid Secretary Conjecture is a notorious open problem in online optimization. It claims the existence of an O(1)-competitive algorithm for the Matroid Secretary Problem (MSP). Here, the elements of a weighted matroid appear one-by-one, revealing their weight at appearance, and the task is to select elements online with the goal to get an independent set of largest possible weight. O(1)-competitive MSP algorithms have so far only been obtained for restricted matroid classes and for MSP variations, including Random-Assignment MSP (RA-MSP), where an adversary fixes a number of weights equal to the ground set size of the matroid, which then get assigned randomly to the elements of the ground set. Unfortunately, these approaches heavily rely on knowing the full matroid upfront. This is an arguably undesirable requirement, and there are good reasons to believe that an approach towards resolving the MSP Conjecture should not rely on it. Thus, both Soto (SIAM Journal on Computing 42(1): 178-211, 2013.) and Oveis Gharan and Vondrák (Algorithmica 67(4): 472-497, 2013.) raised as an open question whether RA-MSP admits an O(1)-competitive algorithm even without knowing the matroid upfront. In this work, we answer this question affirmatively. Our result makes RA-MSP the first well-known MSP variant with an O(1)-competitive algorithm that does not need to know the underlying matroid upfront and without any restriction on the underlying matroid. Our approach is based on first approximately learning the rank-density curve of the matroid, which we then exploit algorithmically.

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矩阵秘书猜想（Matroid Secretary Conjecture）是在线优化领域一个臭名昭著的开放性问题。该猜想声称存在针对矩阵秘书问题（MSP）的 O(1)-competitive 算法。在这里，一个加权矩阵的元素会一个接一个地出现，在出现时显示它们的权重，任务是在线选择元素，目标是得到一个权重最大的独立集合。O(1)-competitive MSP 算法迄今只适用于受限制的 matroid 类和 MSP 变体，包括随机分配 MSP (RA-MSP)，其中对手固定了与 matroid 地面集大小相等的权重数，然后将其随机分配给地面集的元素。遗憾的是，这些方法在很大程度上依赖于预先知道完整的 matroid。可以说，这是一个不可取的要求，我们有充分的理由相信，解决 MSP 猜想的方法不应依赖于此。因此，Soto (SIAM Journal on Computing 42(1)：178-211, 2013.) 以及 Oveis Gharan 和 Vondrák (Algorithmica 67(4)：472-497, 2013. ）提出了一个开放性问题：即使不预先知道矩阵，RA-MSP 是否也能实现 O(1)-competitive 算法。在这项工作中，我们肯定地回答了这个问题。我们的结果使 RA-MSP 成为第一个具有 O(1)-competitive 算法的著名 MSP 变体，它不需要预先知道底层 matroid，而且对底层 matroid 没有任何限制。我们的方法基于首先近似学习 Matroid 的秩密度曲线，然后在算法上加以利用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Mathematical Programming 数学-计算机：软件工程

CiteScore

5.70

自引率

11.10%

发文量

160

审稿时长

4-8 weeks

期刊介绍： Mathematical Programming publishes original articles dealing with every aspect of mathematical optimization; that is, everything of direct or indirect use concerning the problem of optimizing a function of many variables, often subject to a set of constraints. This involves theoretical and computational issues as well as application studies. Included, along with the standard topics of linear, nonlinear, integer, conic, stochastic and combinatorial optimization, are techniques for formulating and applying mathematical programming models, convex, nonsmooth and variational analysis, the theory of polyhedra, variational inequalities, and control and game theory viewed from the perspective of mathematical programming.