Secretary Problems with Non-Uniform Arrival Order

Thomas Kesselheim, Robert D. Kleinberg, Rad Niazadeh
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引用次数: 34

Abstract

For a number of problems in the theory of online algorithms, it is known that the assumption that elements arrive in uniformly random order enables the design of algorithms with much better performance guarantees than under worst-case assumptions. The quintessential example of this phenomenon is the secretary problem, in which an algorithm attempts to stop a sequence at the moment it observes the maximum value in the sequence. As is well known, if the sequence is presented in uniformly random order there is an algorithm that succeeds with probability 1/e, whereas no non-trivial performance guarantee is possible if the elements arrive in worst-case order. In many of the applications of online algorithms, it is reasonable to assume there is some randomness in the input sequence, but unreasonable to assume that the arrival ordering is uniformly random. This work initiates an investigation into relaxations of the random-ordering hypothesis in online algorithms, by focusing on the secretary problem and asking what performance guarantees one can prove under relaxed assumptions. Toward this end, we present two sets of properties of distributions over permutations as sufficient conditions, called the (p,q,δ)-block-independence property} and (k,δ)-uniform-induced-ordering property}. We show these two are asymptotically equivalent by borrowing some techniques from the celebrated approximation theory. Moreover, we show they both imply the existence of secretary algorithms with constant probability of correct selection, approaching the optimal constant 1/e as the related parameters of the property tend towards their extreme values. Both of these properties are significantly weaker than the usual assumption of uniform randomness; we substantiate this by providing several constructions of distributions that satisfy (p,q,δ)-block-independence. As one application of our investigation, we prove that Θ(log log n) is the minimum entropy of any permutation distribution that permits constant probability of correct selection in the secretary problem with $n$ elements. While our block-independence condition is sufficient for constant probability of correct selection, it is not necessary; however, we present complexity-theoretic evidence that no simple necessary and sufficient criterion exists. Finally, we explore the extent to which the performance guarantees of other algorithms are preserved when one relaxes the uniform random ordering assumption to (p,q,δ)-block-independence, obtaining a negative result for the weighted bipartite matching algorithm of Korula and Pal.
秘书关于不统一到货单的问题
对于在线算法理论中的许多问题,已知元素以均匀随机顺序到达的假设使算法设计具有比最坏情况假设更好的性能保证。这种现象的典型例子是秘书问题,在这个问题中,算法试图在它观察到序列中的最大值时停止序列。众所周知,如果序列以均匀随机顺序呈现,则存在一种算法,其成功概率为1/e,而如果元素以最坏情况顺序到达,则不可能有非平凡的性能保证。在许多在线算法的应用中,假设输入序列存在一定的随机性是合理的,但假设到达顺序是均匀随机是不合理的。这项工作启动了对在线算法中随机排序假设松弛的调查,通过关注秘书问题并询问在松弛假设下可以证明的性能保证。为此,我们提出了排列上分布的两组性质作为充分条件,分别称为(p,q,δ)-块无关性和(k,δ)-均匀诱导排序性。我们通过借用著名的近似理论中的一些技巧来证明这两者是渐近等价的。此外,我们还证明了它们都暗示了秘书算法的存在,当属性的相关参数趋于极值时,秘书算法的正确选择概率为常数,逼近最优常数1/e。这两个属性都明显弱于通常的均匀随机性假设;我们通过提供几个满足(p,q,δ)块独立性的分布结构来证实这一点。作为我们研究的一个应用,我们证明Θ(log log n)是任何排列分布的最小熵,它允许在有$n$个元素的秘书问题中有恒定的正确选择概率。虽然我们的块无关条件是足够的,正确选择的概率恒定,但不是必要的;然而,我们提出了复杂性理论证据,证明不存在简单的充分必要判据。最后,我们探讨了当将一致随机排序假设放宽到(p,q,δ)块无关时,其他算法的性能保证在多大程度上保持不变,得到了Korula和Pal的加权二部匹配算法的否定结果。
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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