Multi-Player Non-Cooperative Game Strategy of a Nonlinear Stochastic System with Time-Varying Parameters

IF 1.9 3区数学 Q1 MATHEMATICS, APPLIED

Axioms Pub Date : 2023-12-20 DOI:10.3390/axioms13010003

Xiangyun Lin, Tongtong Zhang, Meilin Li, Rui Zhang, Weihai Zhang

引用次数: 0

Abstract

This paper discusses the multi-player non-cooperative game of nonlinear stochastic time-varying systems described by Itô-type differential equations in a finite time interval. Multi-player non-cooperative game problems are represented by multi-objective Pareto (MOP) control problems to describe the fact that each player has their own goals. By applying Hamilton–Jacobi inequalities (HJIs), the criterion of upper bounds of the MOP boundary is obtained for nonlinear stochastic systems, and the corresponding strategies are designed for such games, so the MOP problem is transformed into a HJI-constrained MOP problem. In order to overcome the difficulty of solving HJIs, a global linearization method is proposed to approximate the nonlinear systems. By the proposed global linearization method, multi-player non-cooperative game problems are transformed into Riccati equation-constrained MOP problems, and the approximate solutions of HJI-constrained MOP problems are obtained. Finally, a practical example is given to illustrate the effectiveness of the proposed method.

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具有时变参数的非线性随机系统的多人非合作博弈策略

本文讨论在有限时间间隔内，由 Itô 型微分方程描述的非线性随机时变系统的多人非合作博弈。多玩家非合作博弈问题用多目标帕累托（MOP）控制问题来表示，以描述每个玩家都有自己的目标这一事实。通过应用汉密尔顿-雅各比不等式（HJIs），得到了非线性随机系统的 MOP 边界上限准则，并为此类博弈设计了相应的策略，从而将 MOP 问题转化为 HJI 约束 MOP 问题。为了克服求解 HJI 的困难，提出了一种全局线性化方法来逼近非线性系统。通过提出的全局线性化方法，将多人非合作博弈问题转化为里卡提方程约束的澳门金沙国际网上娱乐问题，并得到了 HJI 约束澳门金沙国际网上娱乐问题的近似解。最后，给出了一个实际例子来说明所提方法的有效性。

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

Axioms Mathematics-Algebra and Number Theory

自引率

10.00%

发文量

604

审稿时长

11 weeks

期刊介绍： Axiomatic theories in physics and in mathematics (for example, axiomatic theory of thermodynamics, and also either the axiomatic classical set theory or the axiomatic fuzzy set theory) Axiomatization, axiomatic methods, theorems, mathematical proofs Algebraic structures, field theory, group theory, topology, vector spaces Mathematical analysis Mathematical physics Mathematical logic, and non-classical logics, such as fuzzy logic, modal logic, non-monotonic logic. etc. Classical and fuzzy set theories Number theory Systems theory Classical measures, fuzzy measures, representation theory, and probability theory Graph theory Information theory Entropy Symmetry Differential equations and dynamical systems Relativity and quantum theories Mathematical chemistry Automata theory Mathematical problems of artificial intelligence Complex networks from a mathematical viewpoint Reasoning under uncertainty Interdisciplinary applications of mathematical theory.