More Information Is Not Always Better: Connections Between Zero-Sum Local Nash Equilibria in Feedback and Open-Loop Information Patterns

IF 2 Q2 AUTOMATION & CONTROL SYSTEMS

IEEE Control Systems Letters Pub Date : 2025-06-26 DOI:10.1109/LCSYS.2025.3583329

Kushagra Gupta;Ross E. Allen;David Fridovich-Keil;Ufuk Topcu

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引用次数: 0

Abstract

Noncooperative dynamic game theory provides a principled approach to modeling sequential decision-making among multiple noncommunicative agents. A key focus is on finding Nash equilibria in two-agent zero-sum dynamic games under various information structures. A well-known result states that in linear-quadratic games, unique Nash equilibria under feedback and open-loop information structures yield identical trajectories. Motivated by two key perspectives—(i) real-world problems extend beyond linear-quadratic settings and lack unique equilibria, making only local Nash equilibria computable, and (ii) local open-loop Nash equilibria (OLNE) are easier to compute than local feedback Nash equilibria (FBNE)—it is natural to ask whether a similar result holds for local equilibria in zero-sum games. To this end, we establish that for a broad class of zero-sum games with potentially nonconvex-nonconcave objectives and nonlinear dynamics: (i) the state/control trajectory of a local FBNE satisfies local OLNE first-order optimality conditions, and vice versa, (ii) a local FBNE trajectory satisfies local OLNE second-order necessary conditions, (iii) a local FBNE trajectory satisfying feedback sufficiency conditions also constitutes a local OLNE, and (iv) with additional hard constraints on agents’ actuations, a local FBNE where strict complementarity holds satisfies local OLNE first-order optimality conditions, and vice versa.

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信息越多并不总是越好：反馈和开环信息模式中零和局部纳什均衡之间的联系

非合作动态博弈论为多个非沟通主体之间的顺序决策建模提供了一种原则性的方法。研究了不同信息结构下双智能体零和动态博弈的纳什均衡问题。一个众所周知的结果表明，在线性二次博弈中，反馈和开环信息结构下的唯一纳什均衡产生相同的轨迹。在两个关键观点的激励下——(i)现实世界的问题超出了线性二次设定，缺乏唯一的均衡，使得只有局部纳什均衡是可计算的，（ii）局部开环纳什均衡（OLNE）比局部反馈纳什均衡（FBNE）更容易计算——很自然地要问，在零和博弈中，类似的结果是否适用于局部均衡。为此，我们建立了一类具有潜在非凸非凹目标和非线性动力学的零和博弈：(i)局部FBNE的状态/控制轨迹满足局部OLNE的一阶最优性条件，反之亦然；（ii）局部FBNE轨迹满足局部OLNE的二阶必要条件；（iii）满足反馈充足性条件的局部FBNE轨迹也构成局部OLNE；（iv）由于对代理的驱动有额外的硬约束，严格互补成立的局部FBNE满足局部OLNE的一阶最优性条件，反之亦然。

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

IEEE Control Systems Letters Mathematics-Control and Optimization

CiteScore

4.40

自引率

13.30%

发文量

471