Data-driven optimal prediction with control

IF 3.8 2区数学 Q1 MATHEMATICS, APPLIED Communications in Nonlinear Science and Numerical Simulation Pub Date : 2025-04-01 Epub Date: 2025-01-29 DOI:10.1016/j.cnsns.2025.108641

Aleksandr Katrutsa , Ivan Oseledets , Sergey Utyuzhnikov

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Abstract

This study presents the extension of the data-driven optimal prediction approach to the dynamical system with control. The optimal prediction is used to analyze dynamical systems in which the states consist of resolved and unresolved variables. The latter variables cannot be measured explicitly. They may have smaller amplitudes and affect the resolved variables that can be measured. The optimal prediction approach recovers the averaged trajectories of the resolved variables by computing conditional expectations, while the distribution of the unresolved variables is assumed to be known. We consider such dynamical systems and introduce their additional control functions. To predict the targeted trajectories numerically, we develop a data-driven method based on the dynamic mode decomposition. The proposed approach takes the measured trajectories of the resolved variables, constructs an approximate linear operator from the Mori–Zwanzig decomposition, and reconstructs the averaged trajectories of the same variables. It is demonstrated that the method is much faster than the Monte Carlo simulations and it provides a reliable prediction. We experimentally confirm the efficacy of the proposed method for two Hamiltonian dynamical systems.

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数据驱动的最优预测与控制

将数据驱动的最优预测方法推广到带控制的动态系统。最优预测用于分析状态由已解变量和未解变量组成的动态系统。后一个变量不能明确地测量。它们可能具有较小的振幅，并影响可测量的已分解变量。最优预测方法通过计算条件期望来恢复已解变量的平均轨迹，同时假设未解变量的分布是已知的。我们考虑了这样的动力系统，并引入了它们的附加控制函数。为了对目标轨迹进行数值预测，我们开发了一种基于动态模态分解的数据驱动方法。该方法采用求解变量的实测轨迹，利用Mori-Zwanzig分解构造近似线性算子，重构相同变量的平均轨迹。结果表明，该方法比蒙特卡罗模拟快得多，预测结果可靠。实验证实了该方法对两个哈密顿动力系统的有效性。

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来源期刊

Communications in Nonlinear Science and Numerical Simulation MATHEMATICS, APPLIED-MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

CiteScore

6.80

自引率

7.70%

发文量

378

审稿时长

78 days

期刊介绍： The journal publishes original research findings on experimental observation, mathematical modeling, theoretical analysis and numerical simulation, for more accurate description, better prediction or novel application, of nonlinear phenomena in science and engineering. It offers a venue for researchers to make rapid exchange of ideas and techniques in nonlinear science and complexity. The submission of manuscripts with cross-disciplinary approaches in nonlinear science and complexity is particularly encouraged. Topics of interest: Nonlinear differential or delay equations, Lie group analysis and asymptotic methods, Discontinuous systems, Fractals, Fractional calculus and dynamics, Nonlinear effects in quantum mechanics, Nonlinear stochastic processes, Experimental nonlinear science, Time-series and signal analysis, Computational methods and simulations in nonlinear science and engineering, Control of dynamical systems, Synchronization, Lyapunov analysis, High-dimensional chaos and turbulence, Chaos in Hamiltonian systems, Integrable systems and solitons, Collective behavior in many-body systems, Biological physics and networks, Nonlinear mechanical systems, Complex systems and complexity. No length limitation for contributions is set, but only concisely written manuscripts are published. Brief papers are published on the basis of Rapid Communications. Discussions of previously published papers are welcome.