The Value of Ambiguous Commitments in Multi-Follower Games

arXiv - CS - Computer Science and Game Theory Pub Date : 2024-09-09 DOI:arxiv-2409.05608

Natalie Collina, Rabanus Derr, Aaron Roth

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Abstract

We study games in which a leader makes a single commitment, and then multiple followers (each with a different utility function) respond. In particular, we study ambiguous commitment strategies in these games, in which the leader may commit to a set of mixed strategies, and ambiguity-averse followers respond to maximize their worst-case utility over the set of leader strategies. Special cases of this setting have previously been studied when there is a single follower: in these cases, it is known that the leader can increase her utility by making an ambiguous commitment if the follower is restricted to playing a pure strategy, but that no gain can be had from ambiguity if the follower may mix. We confirm that this result continues to hold in the setting of general Stackelberg games. We then develop a theory of ambiguous commitment in games with multiple followers. We begin by considering the case where the leader must make the same commitment against each follower. We establish that -- unlike the case of a single follower -- ambiguous commitment can improve the leader's utility by an unboundedly large factor, even when followers are permitted to respond with mixed strategies and even. We go on to show an advantage for the leader coupling the same commitment across all followers, even when she has the ability to make a separate commitment to each follower. In particular, there exist general sum games in which the leader can enjoy an unboundedly large advantage by coupling her ambiguous commitment across multiple followers rather than committing against each individually. In zero-sum games we show there can be no such coupling advantage. Finally, we give a polynomial time algorithm for computing the optimal leader commitment strategy in the special case in which the leader has 2 actions (and k followers may have m actions), and prove that in the general case, the problem is NP-hard.

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多追随者博弈中模糊承诺的价值

我们研究了领导者做出单一承诺，然后多个追随者（每个追随者都有不同的效用函数）做出回应的博弈。特别是，我们研究了这些博弈中的模糊承诺策略，其中领导者可能承诺采取一组混合策略，而模糊规避型追随者的回应是在领导者策略集上最大化他们的最坏情况效用。在这种情况下，众所周知，如果追随者只能采取纯策略，那么领导者可以通过做出模棱两可的承诺来增加自己的效用；但如果追随者可以采取混合策略，那么领导者就无法从模棱两可中获得收益。我们证实，这一结果在一般斯塔克尔伯格博弈中依然成立。然后，我们建立了一个多追随者博弈中的模糊承诺理论。我们首先考虑领导者必须对每个追随者做出相同承诺的情况。我们发现，与单个追随者的情况不同，模棱两可的承诺能以无限大的系数提高领导者的效用，即使在允许追随者以混合策略做出回应的情况下也是如此。我们进而证明，即使领导者有能力对每个追随者做出单独的承诺，对所有追随者做出相同的承诺也是有优势的。特别是，在一般和博弈中，领导者可以通过在多个追随者之间做出模糊承诺，而不是对每个追随者单独做出承诺，从而获得无限大的优势。在零和博弈中，我们证明不可能存在这种耦合优势。最后，在领导者有 2 个行动（k 个追随者可能有 m 个行动）的特殊情况下，我们给出了计算最优领导者承诺策略的多项式时间算法，并证明在一般情况下，这个问题是 NP 难的。

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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arXiv - CS - Computer Science and Game Theory

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