论非线性随机系统松弛控制问题的最大原则

IF 3.1 3区数学 Q1 MATHEMATICS Advances in Difference Equations Pub Date : 2024-03-20 DOI:10.1186/s13662-024-03803-w

Meriem Mezerdi, Brahim Mezerdi

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引用次数: 0

摘要

我们考虑一个由 d 维布朗运动驱动的随机微分方程所支配的系统的最优控制问题，其中漂移和扩散系数都是受控的。众所周知，如果没有额外的凸性条件，严格控制问题就无法实现最优控制。为了克服这一困难，我们考虑了松弛模型，在该模型中，可接受的控制是度量值过程，松弛状态过程受连续正交马廷格度量驱动的随机微分方程控制。这种松弛模型允许一种最优控制，而这种最优控制可以通过所谓的喋喋不休阶梯（chattering lemma）由一系列严格控制来近似。我们用两个邻接过程建立了最优性必要条件，将彭氏最大原则扩展到松弛控制问题。我们证明，像在确定性控制中那样直接放松漂移和扩散马氏部分并不会导致真正的放松模型，因为得到的受控动力学在控制变量中并不连续。

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On the maximum principle for relaxed control problems of nonlinear stochastic systems

We consider optimal control problems for a system governed by a stochastic differential equation driven by a d-dimensional Brownian motion where both the drift and the diffusion coefficient are controlled. It is well known that without additional convexity conditions the strict control problem does not admit an optimal control. To overcome this difficulty, we consider the relaxed model, in which admissible controls are measure-valued processes and the relaxed state process is governed by a stochastic differential equation driven by a continuous orthogonal martingale measure. This relaxed model admits an optimal control that can be approximated by a sequence of strict controls by the so-called chattering lemma. We establish optimality necessary conditions, in terms of two adjoint processes, extending Peng’s maximum principle to relaxed control problems. We show that relaxing the drift and diffusion martingale parts directly as in deterministic control does not lead to a true relaxed model as the obtained controlled dynamics is not continuous in the control variable.

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来源期刊

Advances in Difference Equations MATHEMATICS, APPLIED-MATHEMATICS

CiteScore

8.60

自引率

0.00%

发文量

审稿时长

4-8 weeks

期刊介绍： The theory of difference equations, the methods used, and their wide applications have advanced beyond their adolescent stage to occupy a central position in applicable analysis. In fact, in the last 15 years, the proliferation of the subject has been witnessed by hundreds of research articles, several monographs, many international conferences, and numerous special sessions. The theory of differential and difference equations forms two extreme representations of real world problems. For example, a simple population model when represented as a differential equation shows the good behavior of solutions whereas the corresponding discrete analogue shows the chaotic behavior. The actual behavior of the population is somewhere in between. The aim of Advances in Difference Equations is to report mainly the new developments in the field of difference equations, and their applications in all fields. We will also consider research articles emphasizing the qualitative behavior of solutions of ordinary, partial, delay, fractional, abstract, stochastic, fuzzy, and set-valued differential equations. Advances in Difference Equations will accept high-quality articles containing original research results and survey articles of exceptional merit.